© Freescale Semiconductor, Inc., 2009. All rights reserved.
Freescale Semiconductor
Technical Data
1Overview
The MPC8640 processor family integrates either one or two
Power Architecture™ e600 processor cores with system
logic required for networking, storage, wireless
infrastructure, and general-purpose embedded applications.
The MPC8640 integrates one e600 core while the
MPC8640D integrat es two cores.
This section provides a high-level overview of the MPC8640
and MPC8640D features. When referring to the MPC8640
throughout the document, the functionality described applies
to both the MPC8640 and the MPC8640D. Any differences
specific to the MPC8640D are noted.
Figure 1 shows the major functional units within the
MPC8640 and MPC8640D. The major difference between
the MPC8640 and MPC8640D is that there are two cores on
the MPC8640D.
Contents
1. Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
2. Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . 6
3. Power Characteristics . . . . . . . . . . . . . . . . . . . . . . . . 13
4. Input Clocks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
5. RESET Initialization . . . . . . . . . . . . . . . . . . . . . . . . . 18
6. DDR and DDR2 SDRAM . . . . . . . . . . . . . . . . . . . . . 19
7. DUART . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
8. Ethernet: Enhanced Three-Speed Ethernet (eTSEC),
MII Management . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
9. Et hernet Manage ment Int erface E lectrical
Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
10. Local Bus . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
11. JTAG . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52
12. I2C . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54
13. High-Speed Serial Inte r faces (HSSI) . . . . . . . . . . . . 57
14. PCI Express . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68
15. Serial RapidIO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 75
16. Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87
17. Signal Listings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 91
18. Clocking . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 104
19. Thermal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 107
20. System Design Information . . . . . . . . . . . . . . . . . . 116
21. Ordering Information . . . . . . . . . . . . . . . . . . . . . . . 126
22. Document Revision History . . . . . . . . . . . . . . . . . . 128
MPC8640 and MPC8640D
Integrated Host Processor
Hardware Specifications
Document Number: MPC8640DEC
Rev. 3, 07/2009
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
2Freescale Semiconductor
Overview
Figure 1. MPC8640 and MPC8640D
AND 1x/4x SRIO (2.5 GB/s) ]
[ x1/x2/x4/x8 PCI Exp (4 GB/s)
OR [2-x1/x2/x4/x8 PCI Express
(8 GB/S) ]
32-Kbyte
L1 Instruction Cache
e600 Core
32-Kbyte
L1 Data Cache
e600 Core Block
Local Bus Controller
Multiprocessor
Programmable Interrupt
DDR SDRAM Controller
SDRAM
IRQs
External
Control
DDR SDRAM Controller
(LBC)
Controller
(MPIC)
SDRAM
ROM,
GPIO
Dual Universal
Asynchronous
Receiver/Transmitter
(DUART)
Serial
I2C ControllerI2C
I2C ControllerI2C
Enhanced TSEC
Controller
10/100/1Gb
Enhanced TSEC
Controller
10/100/1Gb
Enhanced TSEC
Controller
10/100/1Gb
PCI Express
Interface
Four-Channel
DMA Controller
Enhanced TSEC
Controller
10/100/1Gb
OCeaN
Switch
Fabric
MPX Coherency Module (MCM)
1-Mbyte
L2 Cache
Platform
MPX Bus
RMII, GMII,
MII, RGMII,
TBI, RTBI
RMII, GMII,
MII, RGMII,
TBI, RTBI
RMII, GMII,
MII, RGMII,
TBI, RTBI
RMII, GMII,
MII, RGMII,
TBI, RTBI
Platform Bus
e600 Core
e600 Core Block
L2 Cache
32-Kbyte
L1 Instruction Cache
32-Kbyte
L1 Data Cache
1-Mbyte
Serial RapidIO
Interface
or
PCI Express
Interface
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 3
Overview
1.1 Key Features
The following lists the MPC8640 key feature set:
• Major features of the e600 core are as follows:
— High-performance, 32-bit superscalar microprocessor tha t implements the PowerPC
instruction set architecture (ISA)
— Eleven independent execution units and three register files
– Branch processing unit ( BPU)
– Four integer units (IUs) that share 32 GPRs for integer operands
– 64-bit floating-point unit (FPU)
– Four vector units and a 32-entry vector register file (VRs)
– Three-stage load/store unit (LSU)
— Three issue queues, FIQ, VIQ, and GIQ, can accept as many as one, two, and three instructions,
respectively, in a cycle.
— Rename buffers
— Dispatch unit
— Completion unit
— Two separate 32-Kbyte instruction and data level 1 (L1) caches
— Integrated 1-Mbyte, eight-way set-associative unified instruction and data level 2 (L2) cache
with ECC
— 36-bit real addressing
— Separate memory ma nagement units (MMUs) for instructions and data
— Multipr ocessing support feature s
— Power and thermal management
— Perfor m ance monitor
— In-system testability and debugging features
— Reliability and service ability
• MPX coherency module (MCM)
— Ten local address windows plus two default windows
— Optional low memory of fs et mode for core 1 to allow for address disambiguation
• Address translation and mapping units (ATMUs)
— Eight local access windows define mapping within local 36-bit address space
— Inbound and outbound ATMUs map to larger external address spaces
— Three inbound windows plus a configuration window on PCI Express® interface unit
— Four inbound windows plus a default window on serial RapidIO interface unit
— Four outbound windows plus default translation for PCI Express interface unit
— Eight outbound windows plus default translation for serial RapidIO® interface unit with
segmentation and subsegmentation support
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
4Freescale Semiconductor
Overview
• DDR memory controllers
— Dual 64-bit memory controlle rs (72-bit with ECC)
— Support of up to a 266 MHz clock rate and a 533 MHz DDR2 SDRAM
— Support for DDR, DDR2 SDRAM
— Up to 16 Gbytes per memory controller
— Cache line and page interleaving between memory controllers.
• Serial RapidIO interf ace unit
— Supports RapidIO Interconnect Specification, Revision 1.2
— Both 1× and 4× LP-Serial link interf aces
— T r a nsmission r ates of 1. 25-, 2. 5-, and 3. 125-Gbaud ( data rates of 1.0-, 2. 0-, and 2. 5-Gbps) per
lane
— Message unit compliant with RapidIO specifications
— RapidIO atomic transactions to the memory controller
• PCI Express i n terface
— PCI Express 1.0a compatible
— Supports ×1, ×2, ×4, and ×8 link widths
— 2.5 Gbaud, 2.0 Gbps lane
• Four enhanced three-speed Ethernet controllers (e TSECs)
— Three-speed support (10/100/1000 Mbps)
— Four controllers that comply with IEEE St d. 802.3®, 802.3u®, 802.3x®, 802.3z®, 802.3ac®,
802.3ab® standards
— Support for the following physical interfaces: MII, RMII, GMII, RGMII, TBI, and RTBI
— Support for a full-duplex FIFO mode for high-efficiency ASIC connectivity
— TCP /IP of f-load
— Header pars ing
— Quality of service support
— VLAN insertion and deletion
— MAC address recognition
— Buffer descriptors are backward compatible with PowerQUICC II and PowerQUICC III
programming models
— RMON statistics support
— MII management interface for control and status
• Programmable interrupt controller (PIC)
— Programming model is complia nt with the OpenPI C architecture
— Supports 16 programmable interrupt and processor task priority levels
— Supports 12 discrete external interrupts and 48 internal interrupts
— Eight global high resolution timers/counters that can generate inter r upts
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 5
Overview
— Allows processo rs to interrupt each other with 32b messages
— Support for PCI-Express message-shared interrupts (MSIs)
• Local bus controller (LBC)
— Multiplexed 32-bit address and data operating at up to 125 MHz
— Eight chip selects support eight external slaves
• Integrated DMA controller
— Four-channel controller
— All channels accessible by both the local and the remote masters
— Supports transfers to or from any local memory or I/O port
— Ability to start and flow control each DMA channel from external 3-pin interface
• Device performance moni tor
— Supports eight 32-bit counters that count the occurrence of selected events
— Ability to count up to 512 counter-specific events
— Supports 64 reference events that can be counted on any of the 8 counters
— Supports duration and quantity threshold counting
— Burstiness feature that permits counting of burst events with a programmable time between
bursts
— Triggering and chaining capability
— Ability to generate an int errupt on overflow
• Dual I2C controllers
— Two-wire interface
— Multiple master support
— Master or slave I2C mode support
— On-chip digital filter ing rejects spikes on t he bus
• Boot sequencer
— Optionally loads configuration data from serial ROM at reset via the I2C interface
— Can be used to initialize configuration registers and/or memory
— Supports extended I2C addressing mode
— Data integrity checked with preamble signature and CRC
• DUART
— Two 4-wire interfaces (SIN, SOUT, RTS, CTS )
— Programming model compatibl e with the original 16450 UART and the PC16550D
• IEEE 1149.1™-compliant, JTAG boundary scan
• Available as 1023 pin Hi-CTE flip chip ceramic ball grid array (FC-CBGA)
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
6Freescale Semiconductor
Electrical Characteristics
2 Electrical Characteristics
This section provides th e AC and DC electrical speci f icat ions and the rmal char acter i stics f or the
MPC8640. The MPC8640 is currently targeted to these specifications.
2.1 Overall DC Electrical Characteristics
This section covers the ratings, conditions, and other characteristics.
2.1.1 Absolute Maximum Ratings
Table 1 provides the absolute maximum ratings .
Table 1. Absolute Maximum Ratings1
Parameter Symbol Absolute Maximum
Value Unit Notes
Cores supply voltages VDD_Core0,
VDD_Core1
–0.3 to 1.21 V V 2
Cores PLL supply AVDD_Core0,
AVDD_Core1
–0.3 to 1.21 V V —
SerDes Transceiver Supply (Ports 1 and 2) SVDD –0.3 to 1.21 V V —
SerDes Serial I/O Supply Port 1 XVDD_SRDS1 –0.3 to 1.21 V V —
SerDes Serial I/O Supply Port 2 XVDD_SRDS2 –0.3 to 1.21 V V —
SerDes DLL and PLL supply voltage for Port 1 and Port 2 AVDD_SRDS1,
AVDD_SRDS2
–0.3 to 1.21V V —
Platform Supply voltage VDD_PLAT –0.3 to 1.21V V —
Local Bus and Platform PLL supply voltage AVDD_LB,
AVDD_PLAT
–0.3 to 1.21V V —
DDR and DDR2 SDRAM I/O supply voltages D1_GVDD,
D2_GVDD
–0.3 to 2.75 V V 3
–0.3 to 1.98 V V 3
eTSEC 1 and 2 I/O supply voltage LVDD –0.3 to 3.63 V V 4
–0.3 to 2.75 V V 4
eTSEC 3 and 4 I/O supply voltage TVDD –0.3 to 3.63 V V 4
–0.3 to 2.75 V V 4
Local Bus, DUART, DMA, Multiprocessor Interrupts, System
Control & Clocking, Debug, Test, Power management, I2C,
JTAG and Miscellaneous I/O voltage
OVDD –0.3 to 3.63V V —
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 7
Electrical Characteristics
2.1.2 Recommended Operating Conditions
Table 2 provides the recommended operating conditions for the MPC8640. Note that the values in Table 2
are the recommended and tested operating conditions. Proper device oper ation outs ide of these conditions
is not guaranteed. For details on order information and specifi c operating conditions for parts, see
Section 21, “Ordering Information.”
Input voltage DDR and DDR2 SDRAM signals D
n
_MVIN –0.3 to (D
n
_GVDD + 0.3) V 5
DDR and DDR2 SDRAM reference D
n
_MVREF –0.3 to (D
n
_GVDD ÷2 +
0.3)
V—
Three-speed Ethernet signals LVIN
TVIN
GND to (LVDD + 0.3)
GND to (TVDD + 0.3)
V 5
DUART, Local Bus, DMA,
Multiprocessor Interrupts, System
Control and Clocking, Debug, Test,
Power management, I2C, JTAG
and Miscellaneous I/O voltage
OVIN GND to (OVDD + 0.3) V 5
Storage temperature range TSTG –55 to 150 oC—
Notes:
1. Functional and tested operating conditions are given in Ta b l e 2 . Absolute maximum ratings are stress ratings only, and
functional operation at the maxima is not guaranteed. Stresses beyond those listed may affect device reliability or cause
permanent damage to the device.
2. Core 1 characteristics apply only to MPC8640D. If two separate power supplies are used for VDD_Core0 and VDD_Core1,
they must be kept within 100 mV of each other during normal run time.
3. The –0.3 to 2.75 V range is for DDR and –0.3 to 1.98 V range is for DDR2.
4. The 3.63 V maximum is only supported when the port is configured in GMII, MII, RMII, or TBI modes; otherwise the 2.75 V
maximum applies. See Section 8.2, “FIFO, GMII, MII, TBI, RGMII, RMII, and RTBI AC Timing Specifications,” for details on
the recommended operating conditions per protocol.
5. During run time (M,L,T,O)VIN and D
n
_MVREF may overshoot/undershoot to a voltage and for a maximum duration as shown
in Figure 2.
Table 2. Recommended Operating Conditions
Parameter Symbol Recommended
Value Unit Notes
Cores supply voltages VDD_Core0,
VDD_Core1
1.05 ± 50 mV V 1, 2
0.95 ± 50 mV 1, 2, 10
Cores PLL supply AVDD_Core0,
AVDD_Core1
1.05 ± 50 mV V 11
0.95 ± 50 mV 10, 11
SerDes Transceiver Supply (Ports 1 and 2) SVDD 1.05 ± 50 mV V 9
SerDes Serial I/O Supply Port 1 XVDD_SRDS1 1.05 ± 50 mV V —
SerDes Serial I/O Supply Port 2 XVDD_SRDS2 1.05 ± 50 mV V —
SerDes DLL and PLL supply voltage for Port 1 and Port 2 AVDD_SRDS1,
AVDD_SRDS2
1.05 ± 50 mV V —
Table 1. Absolute Maximum Ratings1 (continued)
Parameter Symbol Absolute Maximum
Value Unit Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
8Freescale Semiconductor
Electrical Characteristics
Platform supply voltage VDD_PLAT 1.05 ± 50 mV V —
Local Bus and Platform PLL supply voltage AVDD_LB,
AVDD_PLAT
1.05 ± 50 mV V —
DDR and DDR2 SDRAM I/O supply voltages D1_GVDD,
D2_GVDD
2.5 V ± 125 mV V 7
1.8 V ± 90 mV 7
eTSEC 1 and 2 I/O supply voltage LVDD 3.3 V ± 165 mV V 8
2.5 V ± 125 mV V 8
eTSEC 3 and 4 I/O supply voltage TVDD 3.3 V ± 165 mV V 8
2.5 V ± 125 mV V 8
Local Bus, DUART, DMA, Multiprocessor Interrupts, System
Control & Clocking, Debug, Test, Power management, I2C,
JTAG and Miscellaneous I/O voltage
OVDD 3.3 V ± 165 mV V 5
Input voltage DDR and DDR2 SDRAM signals D
n
_MVIN GND to D
n
_GVDD V3, 6
DDR and DDR2 SDRAM reference D
n
_MVREF D
n
_GVDD/2 ± 1% V —
Three-speed Ethernet signals LVIN
TVIN
GND to LVDD
GND to TVDD
V4, 6
DUART, Local Bus, DMA,
Multiprocessor Interrupts, System
Control & Clocking, Debug, Test,
Power management, I2C, JTAG
and Miscellaneous I/O voltage
OVIN GND to OVDD V5,6
Junction temperature range TJ0 to 105 oC—
–40 to 105 12
Notes:
1. Core 1 characteristics apply only to MPC8640D
2. If two separate power supplies are used for VDD_Core0 and VDD_Core1, they must be at the same nominal voltage and the
individual power supplies must be tracked and kept within 100 mV of each other during normal run time.
3. Caution: D
n
_MVIN must meet the overshoot/undershoot requirements for D
n
_GVDD as shown in Figure 2.
4. Caution: L/TVIN must meet the overshoot/undershoot requirements for L/TVDD as shown in Figure 2 during regular run time.
5. Caution: OVIN must meet the overshoot/undershoot requirements for OVDD as shown in Figure 2 during regular run time.
6. Timing limitations for M,L,T,O)VIN and D
n
_MVREF during regular run time is provided in Figure 2
7. The 2.5 V ± 125 mV range is for DDR and 1.8 V ± 90 mV range is for DDR2.
8. See Section 8.2, “FIFO, GMII, MII, TBI, RGMII, RMII, and RTBI AC Timing Specifications,” for details on the recommended
operating conditions per protocol.
9. The PCI Express interface of the device is expected to receive signals from 0.175 to 1.2 V. For more information refer to
Section 14.4.3, “Differential Receiver (Rx) Input Specifications.”
10. Applies to Part Number MC8640wxx1067Nz only. VDD_Core
n
= 0.95 V and VDD_PLAT = 1.05 V devices. Refer to Ta ble 7 4
Part Numbering Nomenclature to determine if the device has been marked for VDD_Core
n
= 0.95 V.
11. This voltage is the input to the filter discussed in Section 20.2, “Power Supply Design and Sequencing,” and not necessarily
the voltage at the AVDD_Core
n
pin, which may be reduced from VDD_Core
n
by the filter.
12. Applies to part number MC8640DTxxyyyyaz. Refer to Ta b l e 7 4 Part Numbering Nomenclature to determine if the device
has been marked for extended operating temperature range.
Table 2. Recommended Operating Conditions (continued)
Parameter Symbol Recommended
Value Unit Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 9
Electrical Characteristics
Figure 2 shows the undershoot and overshoot voltages at the interfaces of the MPC8640.
Figure 2. Overshoot/Undershoot Voltage for D
n
_M/O/L/TVIN
The MPC8640 core voltage must always be provided at nominal VDD_Coren (See Table 2 for act ual
recommended core voltage). Voltage to the processor interface I/Os are provided through separate sets of
supply pins and m ust be provided at the voltages shown in Table 2. The input voltage threshold scales with
respect to the associated I/O supply voltage. OVDD and L/TVDD based receivers are simple CMOS I/O
circuits and satisfy appropriate LVCMOS type spec ificat ions. The DDR SDRAM int er fac e uses a
single-ended differential receiver referenced to each externally supplied Dn_MVREF signal (nominally set
to Dn_GVDD/2) as is appropriate for the (SSTL-18 and SSTL-25) electrical signaling standards.
GND
GND – 0.3 V
GND – 0.7 V Not to Exceed 10%
L/T/D
n
_G/O/X/SVDD + 20%
L/T/D
n
_G/O/X/SVDD
L/T/D
n
_G/O/X/SVDD + 5%
of tCLK1
1. tCLK references clocks for various functional blocks as follows:
VIH
VIL
Note:
DDRn = 10% of Dn_MCK period
eTSECn = 10% of ECn_GTX_CLK125 period
Local Bus = 10% of LCLK[0:2] period
I2C = 10% of SYSCLK
JTAG = 10% of SYSCLK
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
10 Freescale Semiconductor
Electrical Characteristics
2.1.3 Output Driver Characteristics
Table 3 provides information on the characteristics of the output driver strengths. The values are
prelimina ry estimates .
Table 3. Output Drive Capability
Driver Type
Programmable
Output Impedance
(Ω)
Supply
Voltage Notes
DDR1 signal 18
36 (half strength mode)
D
n
_GVDD = 2.5 V 4, 9
DDR2 signal 18
36 (half strength mode)
D
n
_GVDD = 1.8 V 1, 5, 9
Local Bus signals 45
25
OVDD = 3.3 V 2, 6
eTSEC/10/100 signals 45 T/LVDD = 3.3 V 6
30 T/LVDD = 2.5 V 6
DUART, DMA, Multiprocessor Interrupts, System Control &
Clocking, Debug, Test, Power management, JTAG and
Miscellaneous I/O voltage
45 OVDD = 3.3 V 6
I2C 150 OVDD = 3.3 V 7
SRIO, PCI Express 100 SVDD = 1.1/1.05 V 3, 8
Notes:
1. See the DDR Control Driver registers in the MPC8641D reference manual for more information.
2. Only the following local bus signals have programmable drive strengths: LALE, LAD[0:31], LDP[0:3], LA[27:31], LCKE,
LCS[1:2], LWE[0:3], LGPL1, LGPL2, LGPL3, LGPL4, LGPL5, LCLK[0:2]. The other local bus signals have a fixed drive
strength of 45 Ω. See the POR Impedance Control register in the MPC8641D reference manual for more information about
local bus signals and their drive strength programmability.
3. See Section 17, “Signal Listings,” for details on resistor requirements for the calibration of SD
n
_IMP_CAL_TX and
SD
n
_IMP_CAL_RX transmit and receive signals.
4. Stub Series Terminated Logic (SSTL-25) type pins.
5. Stub Series Terminated Logic (SSTL-18) type pins.
6. Low Voltage Transistor-Transistor Logic (LVTTL) type pins.
7. Open Drain type pins.
8. Low Voltage Differential Signaling (LVDS) type pins.
9. The drive strength of the DDR interface in half strength mode is at Tj = 105C and at D
n
_GVDD (min).
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 11
Electrical Characteristics
2.2 Power-Up/Down Sequence
The MPC8640 requires its power rails to be applied in a specific sequence to ensure proper device
operation.
NOTE
The recommended maximum ramp up time for power supplies is 20
milliseconds.
The chronological order of power up is:
1. All power rails other than DDR I/O (Dn_GVDD, and Dn_MVREF).
NOTE
There is no required order sequence between the individual rails for this
item (# 1). However, VDD_PLAT, AVDD_PLAT rails must reach 90% of
their recommended value before the rail for Dn_GVDD, and Dn_MVREF (in
next step) reaches 10% of their recommended value. AVDD type supplies
must be delayed with respect to their source supplies by t he RC time
constant of the PLL filter circuit described in Section 20.2.1, “PLL Power
Supply Filtering.”
2. Dn_GVDD, Dn_MVREF
NOTE
It is possible to leave the related power supply (Dn_GVDD, Dn_MVREF)
turned off at reset for a DDR port that will not be used. Note that these power
supplies can only be powered up again at reset for functionality to occur on
the DDR port.
3. 3. SYSCLK
The recommended order of power down is as follows:
1. Dn_GVDD, Dn_MVREF
2. All power rails other than DDR I/O (Dn_GVDD, Dn_MVREF).
NOTE
SYSCLK may be powered down simultaneous to either of item # 1 or # 2 in
the power down sequence. Beyond this, the power supplies may power
down simultaneously if the preservation of DDRn memory is not a concern.
See Figure 3 for more details on the power and reset sequencing details.
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
12 Freescale Semiconductor
Electrical Characteristics
Figure 3 illus trates the power up sequence as described above.
Figure 3. MPC8640 Power-Up and Reset Sequence
VDD_PLAT, AVDD_PLAT
L/T/OVDD
Time
2.5 V
3.3 V
1.2 V
0
DC Power Supply Voltage
Reset
Configuration Pins
HRESET (& TRST)
100 µs Platform PLL
Asserted for
100 μs after
Power Supply Ramp Up 2
Notes:
1. Dotted waveforms correspond to optional supply values for a specified power supply. See Ta b le 2 .
2. The recommended maximum ramp up time for power supplies is 20 milliseconds.
3. Refer to Section 5, “RESET Initialization,” for additional information on PLL relock and reset signal
assertion timing requirements.
4. Refer to Table 11 for additional information on reset configuration pin setup timing requirements. In
addition see Figure 68 regarding HRESET and JTAG connection details including TRST.
5. e600 PLL relock time is 100 microseconds maximum plus 255 MPX_clk cycles.
6. Stable PLL configuration signals are required as stable SYSCLK is applied. All other POR configuration
inputs are required 4 SYSCLK cycles before HRESET negation and are valid at least 2 SYSCLK cycles
after HRESET has negated (hold requirement). See Section 5, “RESET Initialization,” for more
information on setup and hold time of reset configuration signals.
7. VDD_PLAT, AVDD_PLAT must strictly reach 90% of their recommended voltage before the rail for
D
n
_GVDD, and D
n
_MVREF reaches 10% of their recommended voltage.
8. SYSCLK must be driven only AFTER the power for the various power supplies is stable.
9. In device sleep mode, the reset configuration signals for DRAM types (TSEC2_TXD[4],TSEC2_TX_ER)
must be valid BEFORE HRESET is asserted.
e600
5
AV
DD
_LB, SV
DD
, XV
DD
_SRDS
n
VDD_Core
n
, AVDD_Core
n
AVDD_SRDS
n
1.8 V
D
n
_GVDD, = 1.8/2.5 V
D
n
_MVREF
If
SYSCLK
8
(not drawn to scale)
Relock Time 3
L/TVDD=2.5 V
1
7
PLL
9
SYSCLK is functional 4
Cycles Setup and hold Time 6
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 13
Power Characteristics
3 Power Characteristics
The power dissipation for the dual cor e MPC8640D device is shown in Table 4.
The power dissipation for individual power supplies of the MPC8640D is shown in Table 5.
Table 4. MPC8640D Power Dissipation (Dual Core)
Power Mode Core Frequency
(MHz)
Platform
Frequency (MHz)
VDD_Coren,
VDD_PLAT
(Volts)
Junction
Temperature
Power
(Watts) Notes
Typ i ca l
1250 MHz 500 MHz 1.05 V
65 oC21.71, 2
Thermal
105 oC
27.3 1, 3
Maximum 31 1, 4
Typ i ca l
1000 MHz 500 MHz 1.05 V
65 oC18.91, 2
Thermal
105 oC
23.8 1, 3
Maximum 27 1, 4
Typ i ca l
1067 MHz 533 MHz 0.95/1.05 V
65 oC 15.7 1, 2, 5
Thermal
105 oC
19.5 1, 3, 5
Maximum 22 1, 4, 5
Notes:
1. These values specify the power consumption at nominal voltage and apply to all valid processor bus frequencies and
configurations. The values do not include power dissipation for I/O supplies.
2. Typical power is an average value measured at the nominal recommended core voltage (VDD_Core
n
) and 65 °C junction
temperature (see Ta b le 2 )while running the Dhrystone 2.1 benchmark and achieving 2.3 Dhrystone MIPs/MHz with one core
at 100% efficiency and the second core at 65% efficiency.
3. Thermal power is the average power measured at nominal core voltage (VDD_Core
n
) and maximum operating junction
temperature (see Ta b l e 2 ) while running the Dhrystone 2.1 benchmark and achieving 2.3 Dhrystone MIPs/MHz on both cores
and a typical workload on platform interfaces.
4. Maximum power is the maximum power measured at nominal core voltage (VDD_Core
n
) and maximum operating junction
temperature (see Table 2) while running a test which includes an entirely L1-cache-resident, contrived sequence of instructions
which keep all the execution units maximally busy on both cores.
5. These power numbers are for Part Number MC8640Dwxx1067Nz and MC8640wxx1067Nz only. VDD_Core
n
= 0.95 V and
VDD_PLAT = 1.05 V.
Table 5. MPC8640D Individual Supply Maximum Power Dissipation 1
Component Description Supply Voltage
(Volts)
Power
(Watts) Notes
Per Core voltage Supply VDD_Core0/VDD_Core1 = 1.05 V at 1250 MHz 17.00 —
Per Core PLL voltage supply AVDD_Core0/AVDD_Core1 = 1.05 V at 1250 MHz 0.0125 —
Per Core voltage Supply VDD_Core0/VDD_Core1 = 1.05 V at 1000 MHz 15.00 —
Per Core PLL voltage supply AVDD_Core0/AVDD_Core1 = 1.05 V at 1000 MHz 0.0125 —
Per Core voltage Supply VDD_Core0/VDD_Core1 = 0.95 V at 1067 MHz 11.50 5
Per Core PLL voltage supply AVDD_Core0/AVDD_Core1 = 0.95 V at 1067 MHz 0.0125 5
DDR Controller I/O voltage supply D
n
_GVDD = 2.5 V at 400 MHz 0.80 2, 6
D
n
_GVDD = 1.8 V at 533 MHz 0.68 2, 6
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
14 Freescale Semiconductor
Power Characteristics
The power dissipation for the MPC8640 single core device is shown in Table 6.
16-bit FIFO @ 200 MHz
eTsec 1&2/3&4 Voltage Supply
L/TVDD = 3.3 V 0.11 2, 3, 6
non-FIFO eTsec
n
Voltage Supply L/TVDD = 3.3 V 0.08 2, 6
x8 SerDes transceiver Supply SVDD = 1.05 V 0.70 2, 6
x8 SerDes I/O Supply XVDD_SRDS
n
= 1.05 V 0.66 2, 6
SerDes PLL voltage supply Port 1 or 2 AVDD_SRDS1/AVDD_SRDS2 = 1.05 V 0.10 2, 6
Platform I/O Supply OVDD = 3.3 V 0.45 4, 6
Platform source Supply VDD_PLAT = 1.05 V at 533 MHz 3.5 —
Platform source Supply VDD_PLAT = 1.05 Vn at 500 MHz 3.5 5
Platform, Local Bus PLL voltage Supply AVDD_PLAT, AVDD_LB = 1.1 V 0.0125 —
Notes:
1. This is a maximum power supply number which is provided for power supply and board design information. The numbers are
based on 100% bus utilization for each component. The components listed are not expected to have 100% bus usage
simultaneously for all components. Actual numbers may vary based on activity.
2. Number is based on a per port/interface value.
3. This is based on one eTSEC port used. Since 16-bit FIFO mode involves two ports, the number will need to be multiplied by
two for the total. The other eTSEC protocols dissipate less than this number per port. Note that the power needs to be
multiplied by the number of ports used for the protocol for the total eTSEC port power dissipation.
4.Platform I/O includes local bus, DUART, I2C, DMA, multiprocessor interrupts, system control and clocking, debug, test, power
management, JTAG and miscellaneous I/O voltage.
5. Power numbers with VDD_Core
n
= 0.95 V and VDD_PLAT = 1.05 V are for Part Number MC8640xxx1067Nz only.
6. The maximum power supply number for the I/Os are estimates.
Table 6. MPC8640 Power Dissipation (Single Core)
Power Mode Core Frequency
(MHz)
Platform
Frequency (MHz)
VDD_Coren,
VDD_PLAT
(Volts)
Junction
Temperature
Power
(Watts) Notes
Ty p i c a l
1250 MHz 500 MHz 1.05 V
65 oC 13.3 1, 2
Thermal
105 oC
16.5 1, 3
Maximum 19 1, 4
Ty p i c a l
1000 MHz 500 MHz 1.05 V
65 oC 11.9 1, 2
Thermal
105 oC
14.8 1, 3
Maximum 17 1, 4
Table 5. MPC8640D Individual Supply Maximum Power Dissipation (continued)1
Component Description Supply Voltage
(Volts)
Power
(Watts) Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 15
Input Clocks
4 Input Clocks
Table provides the system clock (SYSCLK) DC specifications for the MPC8640.
4.1 System Clock Timing
Table 8 provides the system clock (SYSCLK) AC timing specifications for the MPC8640.
Ty p i c a l
1067 MHz 533 MHz 0.95 V,
1.05 V
65 oC 10.1 1, 2, 5
Thermal
105 oC
12.3 1, 3, 5
Maximum 14 1, 4, 5
Notes:
1. These values specify the power consumption at nominal voltage and apply to all valid processor bus frequencies and
configurations. The values do not include power dissipation for I/O supplies.
2. Typical power is an average value measured at the nominal recommended core voltage (VDD_Core
n
) and 65 °C junction
temperature (see Tab le 2) while running the Dhrystone 2.1 benchmark and achieving 2.3 Dhrystone MIPs/MHz.
3. Thermal power is the average power measured at nominal core voltage (VDD_Core
n
) and maximum operating junction
temperature (see Table 2) while running the Dhrystone 2.1 benchmark and achieving 2.3 Dhrystone MIPs/MHz and a typical
workload on platform interfaces.
4. Maximum power is the maximum power measured at nominal core voltage (VDD_Core
n
) and maximum operating junction
temperature (see Tab le 2) while running a test which includes an entirely L1-cache-resident, contrived sequence of
instructions which keep all the execution units maximally busy.
5. These power numbers are for Part Number MC8640Dwxx1067Nz and MC8640wxx1067Nz only. VDD_Core
n
= 0.95 V and
VDD_PLAT = 1.05 V.
Table 7. SYSCLK DC Electrical Characteristics (OVDD = 3.3 V ± 165 mV)
Parameter Symbol Min Max Unit
High-level input voltage VIH 2OV
DD + 0.3 V
Low-level input voltage VIL –0.3 0.8 V
Input current
(VIN 1 = 0 V or VIN = VDD)
IIN —±5μA
Note:
1. Note that the symbol VIN, in this case, represents the OVIN symbol referenced in Ta ble 1 and Table 2.
Table 8. SYSCLK AC Timing Specifications
At recommended operating conditions (see Ta bl e 2 ) with OVDD = 3.3 V ± 165 mV.
Parameter Symbol Min Typical Max Unit Notes
SYSCLK frequency fSYSCLK 66 — 166.66 MHz 1
SYSCLK cycle time tSYSCLK 6——ns—
SYSCLK rise and fall time tKH, tKL 0.6 1.0 1.2 ns 2
Table 6. MPC8640 Power Dissipation (Single Core) (continued)
Power Mode Core Frequency
(MHz)
Platform
Frequency (MHz)
VDD_Coren,
VDD_PLAT
(Volts)
Junction
Temperature
Power
(Watts) Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
16 Freescale Semiconductor
Input Clocks
4.1.1 SYSCLK and Spread Spectrum Sources
Spread spectrum clock sources are an increasingly popular way to control electromagnetic interference
emissions (EMI) by spreading the emitted noise to a wider spectrum and reducing the peak noise
magnitude in order to meet industry and government requirements. These clock sources intentionally add
long-term jitter to diffuse the EMI spectral content. The jitter specification given in Table 8 considers
short-term (cycle-to-cycle) jitter only and the clock generator’ s cycle-to-cycle output jitter should meet the
MPC8640 input cycle-to-cycle jitter requirement. Frequency modulation and spread are separate concerns,
and the MPC8640 is compatible with spread spectrum sources if the recommendations listed in Table 9 are
observed.
It is imperative to note that the processor’ s minimum and maximum SYSCLK, core, and VCO frequencies
must not be exceeded regardless of the type of clock source. Therefore, systems in which the processor is
operated at its maximum rated e600 core f r equency should avoid violating the stated limits by using
down-spreading only.
SDn_REF_CLK and SDn_REF_CLK were designed to wor k with a spread spectrum clock (+0 to 0.5%
spreading at 30-33 kHz rate is allowed), assuming both ends have same reference clock. For better results,
use a source without significant unintended modulation.
SYSCLK duty cycle tKHK/tSYSCLK 40 — 60 % 3
SYSCLK jitter — — — 150 ps 4, 5
Notes:
1. Caution: The MPX clock to SYSCLK ratio and e600 core to MPX clock ratio settings must be chosen such that the resulting
SYSCLK frequency, e600 (core) frequency, and MPX clock frequency do not exceed their respective maximum or minimum
operating frequencies. Refer to Section 18.2, “MPX to SYSCLK PLL Ratio,” and Section 18.3, “e600 to MPX clock PLL
Ratio,” for ratio settings.
2. Rise and fall times for SYSCLK are measured at 0.4 V and 2.7 V.
3. Timing is guaranteed by design and characterization.
4. This represents the short term jitter only and is guaranteed by design.
5. The SYSCLK driver’s closed loop jitter bandwidth should be <500 kHz at –20 dB. The bandwidth must be set low to allow
cascade-connected PLL-based devices to track SYSCLK drivers with the specified jitter. Note that the frequency modulation
for SYSCLK reduces significantly for the spread spectrum source case. This is to guarantee what is supported based on
design.
Table 9. Spread Spectrum Clock Source Recommendations
At recommended operating conditions. See Table 2.
Parameter Min Max Unit Notes
Frequency modulation — 50 kHz 1
Frequency spread — 1.0 % 1, 2
Notes:
1. Guaranteed by design.
2. SYSCLK frequencies resulting from frequency spreading, and the resulting core and VCO frequencies, must meet the
minimum and maximum specifications given in Table 8.
Table 8. SYSCLK AC Timing Specifications (continued)
At recommended operating conditions (see Ta bl e 2 ) with OVDD = 3.3 V ± 165 mV.
Parameter Symbol Min Typical Max Unit Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 17
Input Clocks
4.2 Real Time Clock Timing
The RTC input is sampled by the platform clock (MPX clock). The output of the sampling latch is then
used as an input to the counters of the PI C. There is no jitter specification. The minimum pulse width of
the R T C signal should be greater than 2× the period of the MP X clock. That is, minimum clock high time
is 2 × tMPX, a nd minimum cloc k low time is 2 × tMPX. There is no minimum R TC frequency; R TC may be
grounded if not needed.
4.3 eTSEC Gigabit Reference Clock Timing
Table 10 provides the eTSEC gigabit reference clocks (EC1_GTX_CLK125 and EC2_G TX_CLK125) AC
timing specifications for the MPC8640.
NOTE
The phase between the output clocks TSEC1_GTX_CLK and
TSEC2_GTX_CLK (ports 1 and 2) is no mor e than 100 ps. The phase
between the output clocks TSEC3_GTX_CLK and TSEC4_GTX_CLK
(ports 3 and 4) is no more than 100 ps.
4.4 Platform Frequency Requirements for PCI-Express and Serial
RapidIO
The MPX platform clock frequency must be considered for proper operation of the high-speed PCI
Express and Serial RapidIO interfaces as described below.
For proper PCI Express operation, the MPX clock frequency must be greater than or equal to:
527 MHz x (PCI-Express link width)
16 / (1 + cfg_plat_freq)
Table 10. EC
n
_GTX_CLK125 AC Timing Specifications
Parameter Symbol Min Typical Max Unit Notes
EC
n
_GTX_CLK125 frequency fG125 — 125 ± 100
ppm
—MHz3
EC
n
_GTX_CLK125 cycle time tG125 —8—ns—
EC
n
_GTX_CLK125 peak-to-peak jitter tG125J — — 250 ps 1
EC
n
_GTX_CLK125 duty cycle
GMII, TBI
1000Base-T for RGMII, RTBI
tG125H/tG125
45
47
—
55
53
%1, 2
Notes:
1. Timing is guaranteed by design and characterization.
2. EC
n
_GTX_CLK125 is used to generate the GTX clock for the eTSEC transmitter with 2% degradation. EC
n
_GTX_CLK125
duty cycle can be loosened from 47/53% as long as the PHY device can tolerate the duty cycle generated by the eTSEC
GTX_CLK. See Section 8.2.6, “RGMII and RTBI AC Timing Specifications,” for duty cycle for 10Base-T and 100Base-T
reference clock.
3. ±100 ppm tolerance on EC
n
_GTX_CLK125 frequency.
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
18 Freescale Semiconductor
RESET Initialization
Note that at MPX = 400 MHz, cfg_plat_freq = 0 and at MPX > 400 MHz, cfg_plat_freq = 1. Therefore,
when operating PCI Express in x8 link width, the MPX platform frequency must be 400 MHz with
cfg_plat_freq = 0 or greater than or equal to 527 MHz with cfg_plat_freq = 1.
For proper Serial RapidIO operation, the MPX clock frequency must be greater than:
2 × (0.80) × (Serial RapidIO interface frequency) × (Serial RapidIO link width)
64
4.5 Other Input Clocks
For information on the input clocks of other functional blocks of the platform such as SerDes, and eTSEC,
see the specific section of this document.
5 RESET Initialization
This section describes the AC electrical s pecifications for the RESET initialization timing r equirements of
the MPC8640. Table 11 provides the RESET initialization AC timing specifications.
Table 12 provid es the PLL lock times.
Table 11. RESET Initialization Timing Specifications
Parameter Min Max Unit Notes
Required assertion time of HRESET 100 — μs—
Minimum assertion time for SRESET_0 & SRESET_1 3 — SYSCLKs 1
Platform PLL input setup time with stable SYSCLK before HRESET
negation
100 — μs2
Input setup time for POR configs (other than PLL config) with respect to
negation of HRESET
4 — SYSCLKs 1
Input hold time for all POR configs (including PLL config) with respect to
negation of HRESET
2 — SYSCLKs 1
Maximum valid-to-high impedance time for actively driven POR configs
with respect to negation of HRESET
— 5 SYSCLKs 1
Notes:
1. SYSCLK is the primary clock input for the MPC8640.
2 This is related to HRESET assertion time. Stable PLL configuration inputs are required when a stable SYSCLK is applied. See
the
MPC8641D Integrated Host Processor Reference Manual
for more details on the power-on reset sequence.
Table 12. PLL Lock Times
Parameter Min Max Unit Notes
(Platform and E600) PLL lock times — 100 μs1
Local bus PLL — 50 μs—
Notes:
1.The PLL lock time for e600 PLLs require an additional 255 MPX_CLK cycles.
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 19
DDR and DDR2 SDRAM
6 DDR and DDR2 SDRAM
This section describes the DC and AC electrical specifications for the DDR SDRAM interface of the
MPC8640. Note that DDR SDRAM is Dn_GVDD(typ) = 2.5 V and DDR2 SDRAM is
Dn_GVDD(typ) = 1.8 V.
6.1 DDR SDRAM DC Electrical Characteristics
Table 13 provides the recommended operating conditions for the DDR2 SDRAM component(s) of the
MPC8640 when Dn_GVDD(typ) = 1.8 V.
Table 14 provides the DDR2 capacitance when Dn_GVDD(typ) =1.8V.
Table 13. DDR2 SDRAM DC Electrical Characteristics for D
n
_GVDD(typ) = 1.8 V
Parameter Symbol Min Max Unit Notes
I/O supply voltage D
n
_GVDD 1.71 1.89 V 1
I/O reference voltage D
n
_MVREF 0.49 ×D
n
_GVDD 0.51 × D
n
_GVDD V2
I/O termination voltage VTT D
n
_MVREF –0.04 D
n
_MVREF + 0.04 V 3
Input high voltage VIH D
n
_MVREF + 0.125 D
n
_GVDD +0.3 V —
Input low voltage VIL –0.3 D
n
_MVREF – 0.125 V —
Output leakage current IOZ –50 50 μA4
Output high current (VOUT = 1.420 V) IOH –13.4 — mA —
Output low current (VOUT = 0.280 V) IOL 13.4 — mA —
Notes:
1. D
n
_GVDD is expected to be within 50 mV of the DRAM D
n
_GVDD at all times.
2. D
n
_MVREF is expected to be equal to 0.5 × D
n
_GVDD, and to track D
n
_GVDD DC variations as measured at the receiver.
Peak-to-peak noise on D
n
_MVREF may not exceed ±2% of the DC value.
3. VTT is not applied directly to the device. It is the supply to which far end signal termination is made and is expected to be
equal to D
n
_MVREF
. This rail should track variations in the DC level of D
n
_MVREF
.
4. Output leakage is measured with all outputs disabled, 0 V ≤ VOUT ≤ D
n
_GVDD.
Table 14. DDR2 SDRAM Capacitance for D
n
_GVDD(typ)=1.8 V
Parameter Symbol Min Max Unit Notes
Input/output capacitance: DQ, DQS, DQS CIO 68pF1
Delta input/output capacitance: DQ, DQS, DQS CDIO —0.5pF1
Note:
1. This parameter is sampled. D
n
_GVDD = 1.8 V ± 0.090 V, f = 1 MHz, TA = 25°C, VOUT = D
n
_GVDD ÷2,
VOUT(peak-to-peak) =0.2V.
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
20 Freescale Semiconductor
DDR and DDR2 SDRAM
Table 15 provides the recommended operating conditions for the DDR SDRAM component(s) when
Dn_GVDD(typ) = 2.5 V.
Table 16 provides the DDR capacitance when Dn_GVDD (typ) = 2.5 V.
Table 17 provide s th e current draw charact er isti cs f or MVREF.
Table 15. DDR SDRAM DC Electrical Characteristics for D
n
_GVDD (typ) = 2.5 V
Parameter Symbol Min Max Unit Notes
I/O supply voltage D
n
_GVDD 2.375 2.625 V 1
I/O reference voltage D
n
_MVREF 0.49 × D
n
_GVDD 0.51 × D
n
_GVDD V2
I/O termination voltage VTT D
n
_MVREF – 0.04 D
n
_MVREF + 0.04 V 3
Input high voltage VIH D
n
_MVREF + 0.15 D
n
_GVDD + 0.3 V —
Input low voltage VIL –0.3 D
n
_MVREF – 0.15 V —
Output leakage current IOZ –50 50 μA4
Output high current (VOUT = 1.95 V) IOH –16.2 — mA —
Output low current (VOUT = 0.35 V) IOL 16.2 — mA —
Notes:
1. D
n
_GVDD is expected to be within 50 mV of the DRAM D
n
_GVDD at all times.
2. MVREF is expected to be equal to 0.5 × D
n
_GVDD, and to track D
n
_GVDD DC variations as measured at the receiver.
Peak-to-peak noise on D
n
_MVREF may not exceed ±2% of the DC value.
3. VTT is not applied directly to the device. It is the supply to which far end signal termination is made and is expected to be
equal to D
n
_MVREF
. This rail should track variations in the DC level of D
n
_MVREF
.
4. Output leakage is measured with all outputs disabled, 0 V ≤ VOUT ≤ D
n
_GVDD
.
Table 16. DDR SDRAM Capacitance for D
n
_GVDD (typ) = 2.5 V
Parameter Symbol Min Max Unit Notes
Input/output capacitance: DQ, DQS CIO 68pF1
Delta input/output capacitance: DQ, DQS CDIO —0.5pF1
Note:
1. This parameter is sampled. D
n
_GVDD = 2.5 V ± 0.125 V, f = 1 MHz, T
A =25°C, V
OUT = D
n
_GVDD/2,
VOUT (peak-to-peak) = 0.2 V.
Table 17. Current Draw Characteristics for MVREF
Parameter Symbol Min Max Unit Note
Current draw for MVREF IMVREF —500 μA1
1. The voltage regulator for MVREF must be able to supply up to 500 μA current.
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 21
DDR and DDR2 SDRAM
6.2 DDR SDRAM AC Electrical Characteristics
This section provides the AC electr ical characteristic s for the DDR S DRAM interfac e.
6.2.1 DDR SDRAM Input AC Timing Specifications
Table 18 provides the input AC timing specifications for the DDR2 SDRAM when Dn_GVDD(typ) =1.8 V.
Table 19 provides the input AC timing s pecifications for the DDR SDRAM when Dn_GVDD(typ) =2.5 V.
Table 20 provides the input AC timing specifications for the DDR SDRAM interface.
Table 18. DDR2 SDRAM Input AC Timing Specifications for 1.8-V Interface
At recommended operating conditions (see Ta ble 2 )
Parameter Symbol Min Max Unit Notes
AC input low voltage VIL —D
n
_MVREF – 0.25 V —
AC input high voltage VIH D
n
_MVREF + 0.25 — V —
Table 19. DDR SDRAM Input AC Timing Specifications for 2.5-V Interface
At recommended operating conditions (see Table 2)
Parameter Symbol Min Max Unit Notes
AC input low voltage VIL —D
n
_MVREF – 0.31 V —
AC input high voltage VIH D
n
_MVREF + 0.31 — V —
Table 20. DDR SDRAM Input AC Timing Specifications
At recommended operating conditions (see Table 2)
Parameter Symbol Min Max Unit Notes
Controller Skew for
MDQS—MDQ/MECC
tCISKEW — — ps 1, 2
533 MHz — –300 300 — 3
400 MHz — –365 365 — —
Note:
1. tCISKEW represents the total amount of skew consumed by the controller between MDQS[n] and any corresponding bit that
will be captured with MDQS[n]. This should be subtracted from the total timing budget.
2. The amount of skew that can be tolerated from MDQS to a corresponding MDQ signal is called tDISKEW.This can be
determined by the following equation: tDISKEW = ±(T ³ 4 – abs(tCISKEW)) where T is the clock period and abs(tCISKEW) is the
absolute value of tCISKEW.
3. Maximum DDR1 frequency is 400 MHz.
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
22 Freescale Semiconductor
DDR and DDR2 SDRAM
Figure 4 shows the DDR SDRAM input timing for the MDQS to MDQ skew measurement (tDISKEW).
Figure 4. DDR Input Timing Diagram for tDISKEW
6.2.2 DDR SDRAM Output AC Timing Specifications
Table 21. DDR SDRAM Output AC Timing Specifications
At recommended operating conditions (see Table 2).
Parameter Symbol 1Min Max Unit Notes
MCK[n] cycle time, MCK[n]/MCK[n] crossing tMCK 310ns2
MCK duty cycle
533 MHz
400 MHz
tMCKH/tMCK
47
47
53
53
%
8
8
ADDR/CMD output setup with respect to MCK tDDKHAS ns 3
533 MHz 1.48 — 7
400 MHz 1.95 —
ADDR/CMD output hold with respect to MCK tDDKHAX ns 3
533 MHz 1.48 — 7
400 MHz 1.95 —
MCS[n] output setup with respect to MCK tDDKHCS ns 3
533 MHz 1.48 — 7
400 MHz 1.95 —
MCS[n] output hold with respect to MCK tDDKHCX ns 3
533 MHz 1.48 — 7
400 MHz 1.95 —
MCK to MDQS Skew tDDKHMH –0.6 0.6 ns 4
MCK[n]
MCK[n] tMCK
MDQ[x]
MDQS[n]
tDISKEW
D1D0
tDISKEW
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 23
DDR and DDR2 SDRAM
NOTE
For the ADDR/CMD setup and hold specificati ons in Table 21, it is
assumed that the C lock Control register is set to adjust the memory clocks
by 1/2 applied cycle.
MDQ/MECC/MDM output setup with respect to
MDQS
tDDKHDS,
tDDKLDS
ps 5
533 MHz 590 — 7
400 MHz 700 —
MDQ/MECC/MDM output hold with respect to
MDQS
tDDKHDX,
tDDKLDX
ps 5
533 MHz 590 — 7
400 MHz 700 —
MDQS preamble start tDDKHMP –0.5 × tMCK – 0.6 –0.5 × tMCK +0.6 ns 6
MDQS epilogue end tDDKHME –0.6 0.6 ns 6
Note:
1. The symbols used for timing specifications follow the pattern of t(first two letters of functional block)(signal)(state) (reference)(state) for
inputs and t(first two letters of functional block)(reference)(state)(signal)(state) for outputs. Output hold time can be read as DDR timing
(DD) from the rising or falling edge of the reference clock (KH or KL) until the output went invalid (AX or DX). For example,
tDDKHAS symbolizes DDR timing (DD) for the time tMCK memory clock reference (K) goes from the high (H) state until
outputs (A) are setup (S) or output valid time. Also, tDDKLDX symbolizes DDR timing (DD) for the time tMCK memory clock
reference (K) goes low (L) until data outputs (D) are invalid (X) or data output hold time.
2. All MCK/MCK referenced measurements are made from the crossing of the two signals ±0.1 V.
3. ADDR/CMD includes all DDR SDRAM output signals except MCK/MCK, MCS, and MDQ/MECC/MDM/MDQS.
4. Note that tDDKHMH follows the symbol conventions described in note 1. For example, tDDKHMH describes the DDR timing
(DD) from the rising edge of the MCK[n] clock (KH) until the MDQS signal is valid (MH). tDDKHMH can be modified through
control of the DQS override bits (called WR_DATA_DELAY) in the TIMING_CFG_2 register. This will typically be set to the
same delay as the clock adjust in the CLK_CNTL register. The timing parameters listed in the table assume that these 2
parameters have been set to the same adjustment value. See the
MPC8641 Integrated Processor Reference Manual
for a
description and understanding of the timing modifications enabled by use of these bits.
5. Determined by maximum possible skew between a data strobe (MDQS) and any corresponding bit of data (MDQ), ECC
(MECC), or data mask (MDM). The data strobe should be centered inside of the data eye at the pins of the microprocessor.
6. All outputs are referenced to the rising edge of MCK[n] at the pins of the microprocessor. Note that tDDKHMP follows the
symbol conventions described in note 1.
7. Maximum DDR1 frequency is 400 MHz
8. Per the JEDEC spec the DDR2 duty cycle at 400 and 533 MHz is the low and high cycle time values.
Table 21. DDR SDRAM Output AC Timing Specifications (continued)
At recommended operating conditions (see Table 2).
Parameter Symbol 1Min Max Unit Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
24 Freescale Semiconductor
DDR and DDR2 SDRAM
Figure 5 s hows the DDR SDRAM output timing for the MCK to MDQS skew measurement (tDDKHMH).
Figure 5. Timing Diagram for tDDKHMH
Figure 6 shows the DDR SDRAM output timing diagram.
Figure 6. DDR SDRAM Output Timing Diagram
MDQS
MCK[n]
MCK[n]
tMCK
tDDKHMHmax) = 0.6 ns
tDDKHMH(min) = –0.6 ns
MDQS
ADDR/CMD
tDDKHAS ,tDDKHCS
tDDKHMH
tDDKLDS
tDDKHDS
MDQ[x]
MDQS[n]
MCK[n]
MCK[n] tMCK
tDDKLDX
tDDKHDX
D1D0
tDDKHAX ,tDDKHCX
Write A0 NOOP
tDDKHME
tDDKHMP
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 25
DUART
Figure 7 provides the AC test load for the DDR bus.
Figure 7. DDR AC Test Load
7DUART
This section describes the DC and AC electrical specifications for the DUAR T interface of the MPC8640.
7.1 DUART DC Electrical Characteristics
Table 22 provides the DC electrical characteristics for the DUART interface.
7.2 DUART AC Electrical Specifications
Table 23 provides the AC timing parameters for the DUART interface.
Table 22. DUART DC Electrical Characteristics
Parameter Symbol Min Max Unit
High-level input voltage VIH 2OV
DD + 0.3 V
Low-level input voltage VIL –0.3 0.8 V
Input current
(VIN 1 = 0 V or VIN = VDD)
IIN —±5 μA
High-level output voltage
(OVDD = min, IOH = –100 μA)
VOH OVDD – 0.2 — V
Low-level output voltage
(OVDD = min, IOL = 100 μA)
VOL —0.2 V
Note:
1. Note that the symbol VIN, in this case, represents the OVIN symbol referenced in Table 1 and Ta ble 2.
Table 23. DUART AC Timing Specifications
Parameter Value Unit Notes
Minimum baud rate MPX clock/1,048,576 baud 1,2
Maximum baud rate MPX clock/16 baud 1,3
Oversample rate 16 — 1,4
Notes:
1. Guaranteed by design.
2. MPX clock refers to the platform clock.
3. Actual attainable baud rate will be limited by the latency of interrupt processing.
4. The middle of a start bit is detected as the 8th sampled 0 after the 1-to-0 transition of the start bit. Subsequent bit values are
sampled each 16th sample.
Output Z0 = 50 Ω
RL = 50 Ω
Dn_GVDD/2
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
26 Freescale Semiconductor
Ethernet: Enhanced Three-Speed Ethernet (eTSEC), MII Management
8 Ethernet: Enhanced Three-Speed Ethernet (eTSEC),
MII Management
This section provides the AC and DC electrical chara cter isti cs for enhanced th ree-s peed and MII
management.
8.1 Enhanced Three-Speed Ethernet Controller (eTSEC)
(10/100/1Gb Mbps)—GMII/MII/TBI/RGMII/RTBI/RMII Electrical
Characteristics
The electrical characteristics specified here apply to all gigabit media independent interface (GMII), media
independent interface (MII), ten-bit interface (TBI), reduced gigabit media independent interface
(RGMII), reduced ten-bit interface (RTBI), and reduced media independent interface (RMII) signals
except management data input/output (MDIO) and management data clock (MDC). The RGMII and R TBI
interfaces are defined for 2.5 V, while the GMII and TBI interfaces can be operated at 3.3 or 2.5 V. Whether
the GMII or TBI interface is operated at 3.3 or 2.5 V, the timing is compliant with the IEEE 802.3 standard.
The RGMII and RTBI inte rfaces follo w the Reduced Gigabit Media- I ndependent Interfa ce (R GMI I)
Specification Version 1.3 (12/10/2000). The RMII interface follows the RMII Consortium RMII
Specification Version 1.2 (3/20/1998). The electrical characteristics for MDIO and MDC are specified in
Sectio n 9 , “E t her net Management Interface Electr i cal Char acter i stics.”
8.1.1 eTSEC DC Electrical Characteristics
All GMII, MII, TBI, RGMII, RMII and RTBI drivers and receivers comply with the DC parametric
attributes specified in Table 24 and Table 25. The potential applied to the input of a GMII, MII, TBI,
RGMII, RMII or RTBI receiver may exceed the potential of the receiver’s power supply (that is, a GMII
driver powered from a 3.6-V supply driving VOH into a GMII receiver powered from a 2.5-V supply).
Tolerance for dissimilar GMII dr iver and receiv er s upply potentials is im plicit in these specifications. The
RGMII and RTBI signals are based on a 2.5-V CMOS interface voltage as defined by JEDEC
EIA/JESD8-5.
Table 24. GMII, MII, RMII, TBI and FIFO DC Electrical Characteristics
Parameter Symbol Min Max Unit Notes
Supply voltage 3.3 V LVDD
TVDD
3.135 3.465 V 1, 2
Output high voltage
(LVDD/TVDD = Min, IOH = –4.0 mA)
VOH 2.40 — V —
Output low voltage
(LVDD/TVDD = Min, IOL = 4.0 mA)
VOL —0.50 V—
Input high voltage VIH 2.0 — V —
Input low voltage VIL —0.90 V—
Input high current
(VIN = LVDD, VIN = TVDD)
IIH —40 μA 1, 2, 3
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 27
Ethernet: Enhanced Three-Speed Ethernet (eTSEC), MII Management
8.2 FIFO, GMII, MII, TBI, RGMII, RMII, and RTBI AC Timing
Specifications
The AC timing specifications for FIFO, GMII, MII, TBI, RGMII, RMII and RTBI are presented in this
section.
8.2.1 FIFO AC Specifications
The basis for the AC s pecifications for the eTSEC’ s FIFO modes is the double data rate RGMII and RTBI
specifications because they have similar performance and are described in a source-synchronous fashion
like FIF O modes. However, the FIFO i nterface provides deliberate skew between the transmitted data and
source clock in GMII fashion.
When the eTSEC is configured for FIFO modes, all clocks are supplied from external sources to the
relevant eTSEC interface. That is, the transmit clock must be applied to the eTSECn’ s TSECn_TX_CLK,
while the receive clock must be applied to pin TSECn_RX_C LK. The eTSEC inte rnally uses the tr ansmit
Input low current
(VIN = GND)
IIL –600 — μA3
Notes:
1. LVDD supports eTSECs 1 and 2
2. TVDD supports eTSECs 3 and 4
3. The symbol VIN, in this case, represents the LVIN and TVIN symbols referenced in Table 1 and Ta b l e 2
Table 25. GMII, RGMII, RTBI, TBI and FIFO DC Electrical Characteristics
Parameter Symbol Min Max Unit Notes
Supply voltage 2.5 V LVDD/TVDD 2.375 2.625 V 1, 2
1LV DD supports eTSECs 1 and 2.
2TVDD supports eTSECs 3 and 4.
Output high voltage
(LVDD/TVDD = Min, IOH = –1.0 mA)
VOH 2.00 — V —
Output low voltage
(LVDD/TVDD = Min, IOL = 1.0 mA)
VOL —0.40V—
Input high voltage VIH 1.70 — V —
Input low voltage VIL —0.90V—
Input high current
(VIN = LVDD, VIN = TVDD)
IIH —10μA1, 2, 3
3Note that the symbol VIN, in this case, represents the LVIN and TVIN symbols referenced in Table 1 and Ta ble 2.
Input low current
(VIN = GND)
IIL –15 — μA3
Note:
Table 24. GMII, MII, RMII, TBI and FIFO DC Electrical Characteristics (continued)
Parameter Symbol Min Max Unit Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
28 Freescale Semiconductor
Ethernet: Enhanced Three-Speed Ethernet (eTSEC), MII Management
clock to synchronously generate transmit data and outputs an echoed copy of the transmit clock back out
onto the TSECn_GTX_CLK pin (while transmit data appears on TSECn_TXD[7:0], for exampl e). It is
intended that external receivers capture eTSEC transmit data using the clock on TSE Cn_GTX_CLK as a
source- synchronous timing refer ence. Typically, the clock edge that launched the data can be us ed, since
the clock is delayed by the eTSEC to allow acceptable set-up margin at the receiver. Note that there is
relationship between the maximum FIFO speed and the platform speed. For more information, see
Section 18.4.2, “Platfor m to FIFO Restrictions.”
NOTE
The phase between the output clocks TSEC1_GTX_CLK and
TSEC2_GTX_CLK (ports 1 and 2) is no mor e than 100 ps. The phase
between the output clocks TSEC3_GTX_CLK and TSEC4_GTX_CLK
(ports 3 and 4) is no more than 100 ps.
A summary of the FIFO AC specificat ions appear s i n Table 26 and Table 27.
Table 26. FIFO Mode Transmit AC Timing Specification
At recommended operating conditions with L/TVDD of 3.3 V ± 5% and 2.5 V ± 5%.
Parameter Symbol Min Typ Max Unit
TX_CLK, GTX_CLK clock period (GMII mode) tFIT 8.4 8.0 100 ns
TX_CLK, GTX_CLK clock period (Encoded mode) tFIT 6.4 8.0 100 ns
TX_CLK, GTX_CLK duty cycle tFITH/tFIT 45 50 55 %
TX_CLK, GTX_CLK peak-to-peak jitter tFITJ — — 250 ps
Rise time TX_CLK (20%–80%) tFITR — — 0.75 ns
Fall time TX_CLK (80%–20%) tFITF — — 0.75 ns
FIFO data TXD[7:0], TX_ER, TX_EN setup time to
GTX_CLK
tFITDV 2.0 — — ns
GTX_CLK to FIFO data TXD[7:0], TX_ER, TX_EN hold
time
tFITDX 0.5 — 3.0 ns
Table 27. FIFO Mode Receive AC Timing Specification
At recommended operating conditions with L/TVDD of 3.3 V ± 5% and 2.5 V ± 5%.
Parameter Symbol Min Typ Max Unit
RX_CLK clock period (GMII mode) tFIR18.4 8.0 100 ns
RX_CLK clock period (Encoded mode) tFIR 16.4 8.0 100 ns
RX_CLK duty cycle tFIRH/tFIR 45 50 55 %
RX_CLK peak-to-peak jitter tFIRJ — — 250 ps
Rise time RX_CLK (20%–80%) tFIRR — — 0.75 ns
Fall time RX_CLK (80%–20%) tFIRF — — 0.75 ns
RXD[7:0], RX_DV, RX_ER setup time to RX_CLK tFIRDV 1.5 — — ns
RXD[7:0], RX_DV, RX_ER hold time to RX_CLK tFIRDX 0.5 — — ns
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 29
Ethernet: Enhanced Three-Speed Ethernet (eTSEC), MII Management
Timing diagrams for FIFO appear in Figure 8 and Figure 9.
.
Figure 8. FIFO Transmit AC Timing Diagram
Figure 9. FIFO Receive AC Timing Diagram
8.2.2 GMII AC Timing Specifications
This section describes the GMII transmit and receive AC timing specifications.
8.2.2.1 GMII Transmit AC Timing Specifications
Table 28 provides the GMII transmit AC timing specifications.
1±100 ppm tolerance on RX_CLK frequency
Table 28. GMII Transmit AC Timing Specifications
At recommended operating conditions with L/TVDD of 3.3 V ± 5% and 2.5 V ± 5%.
Parameter Symbol 1Min Typ Max Unit
GMII data TXD[7:0], TX_ER, TX_EN setup time tGTKHDV 2.5 — — ns
GTX_CLK to GMII data TXD[7:0], TX_ER, TX_EN delay tGTKHDX 0.5 — 5.0 ns
GTX_CLK data clock rise time (20%–80%) tGTXR2——1.0ns
tFIT
tFITH
tFITF
tFITDX
TXD[7:0]
TX_EN
GTX_CLK
TX_ER
tFITDV
tFITR
tFIR
tFIRH tFIRF
tFIRR
RX_CLK
RXD[7:0]
RX_DV
RX_ER
valid data
tFIRDX
tFIRDV
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
30 Freescale Semiconductor
Ethernet: Enhanced Three-Speed Ethernet (eTSEC), MII Management
Figure 10 s hows the GMII transmit AC timing diagram.
Figure 10. GMII Transmit AC Timing Diagram
8.2.2.2 GMII Receive AC Timing Specifications
Table 29 provid es the GMII receive AC timing specifications.
GTX_CLK data clock fall time (80%–20%) tGTXF2——1.0ns
Notes:
1. The symbols used for timing specifications herein follow the pattern t(first two letters of functional block)(signal)(state) (reference)(state)
for inputs and t(first two letters of functional block)(reference)(state)(signal)(state) for outputs. For example, tGTKHDV symbolizes GMII
transmit timing (GT) with respect to the tGTX clock reference (K) going to the high state (H) relative to the time date input
signals (D) reaching the valid state (V) to state or setup time. Also, tGTKHDX symbolizes GMII transmit timing (GT) with respect
to the tGTX clock reference (K) going to the high state (H) relative to the time date input signals (D) going invalid (X) or hold
time. Note that, in general, the clock reference symbol representation is based on three letters representing the clock of a
particular functional. For example, the subscript of tGTX represents the GMII(G) transmit (TX) clock. For rise and fall times,
the latter convention is used with the appropriate letter: R (rise) or F (fall).
2. Guaranteed by design.
Table 29. GMII Receive AC Timing Specifications
At recommended operating conditions with L/TVDD of 3.3 V ± 5% and 2.5 V ± 5%.
Parameter Symbol1Min Typ Max Unit
RX_CLK clock period tGRX3—8.0— ns
RX_CLK duty cycle tGRXH/tGRX 40 — 60 ns
RXD[7:0], RX_DV, RX_ER setup time to RX_CLK tGRDVKH 2.0 — — ns
RXD[7:0], RX_DV, RX_ER hold time to RX_CLK tGRDXKH 0.5 — — ns
RX_CLK clock rise time (20%–80%) tGRXR2——1.0ns
Table 28. GMII Transmit AC Timing Specifications (continued)
At recommended operating conditions with L/TVDD of 3.3 V ± 5% and 2.5 V ± 5%.
Parameter Symbol 1Min Typ Max Unit
GTX_CLK
TXD[7:0]
tGTKHDX
tGTX
tGTXH
tGTXR
tGTXF
tGTKHDV
TX_EN
TX_ER
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 31
Ethernet: Enhanced Three-Speed Ethernet (eTSEC), MII Management
Figure 11 provides the AC test load for eTSEC.
Figure 11. eTSEC AC Test Load
Figure 12 shows the GMII receive AC timing diagram.
Figure 12. GMII Receive AC Timing Diagram
8.2.3 MII AC Timing Specifications
This section describes the MII transm it and receive AC timing specifications.
RX_CLK clock fall time (80%-20%) tGRXF2——1.0ns
Note:
1. The symbols used for timing specifications herein follow the pattern of t(first two letters of functional block)(signal)(state) (reference)(state)
for inputs and t(first two letters of functional block)(reference)(state)(signal)(state) for outputs. For example, tGRDVKH symbolizes GMII
receive timing (GR) with respect to the time data input signals (D) reaching the valid state (V) relative to the tRX clock
reference (K) going to the high state (H) or setup time. Also, tGRDXKL symbolizes GMII receive timing (GR) with respect to
the time data input signals (D) went invalid (X) relative to the tGRX clock reference (K) going to the low (L) state or hold time.
Note that, in general, the clock reference symbol representation is based on three letters representing the clock of a particular
functional. For example, the subscript of tGRX represents the GMII (G) receive (RX) clock. For rise and fall times, the latter
convention is used with the appropriate letter: R (rise) or F (fall).
2. Guaranteed by design.
3. ±100 ppm tolerance on RX_CLK frequency
Table 29. GMII Receive AC Timing Specifications (continued)
At recommended operating conditions with L/TVDD of 3.3 V ± 5% and 2.5 V ± 5%.
Parameter Symbol1Min Typ Max Unit
Output LVDD/2
RL = 50 Ω
Z0 = 50 Ω
RX_CLK
RXD[7:0]
tGRDXKH
tGRX
tGRXH
tGRXR
tGRXF
tGRDVKH
RX_DV
RX_ER
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
32 Freescale Semiconductor
Ethernet: Enhanced Three-Speed Ethernet (eTSEC), MII Management
8.2.3.1 MII Transmit AC Timing Specifications
Table 30 provides the MII transmit AC timing specifications.
Figure 13 s hows the MII transmit AC timing diagram.
Figure 13. MII Transmit AC Timing Diagram
8.2.3.2 MII Receive AC Timing Specifications
Table 31 provid es the MII receive AC timing specificati ons.
Table 30. MII Transmit AC Timing Specifications
At recommended operating conditions with L/TVDD of 3.3 V ± 5%.
Parameter Symbol 1Min Typ Max Unit
TX_CLK clock period 10 Mbps tMTX2— 400 — ns
TX_CLK clock period 100 Mbps tMTX —40—ns
TX_CLK duty cycle tMTXH/tMTX 35 — 65 %
TX_CLK to MII data TXD[3:0], TX_ER, TX_EN delay tMTKHDX 1 5 15 ns
TX_CLK data clock rise time (20%–80%) tMTXR21.0 — 4.0 ns
TX_CLK data clock fall time (80%–20%) tMTXF21.0 — 4.0 ns
Note:
1. The symbols used for timing specifications herein follow the pattern of t(first two letters of functional block)(signal)(state) (reference)(state)
for inputs and t(first two letters of functional block)(reference)(state)(signal)(state) for outputs. For example, tMTKHDX symbolizes MII
transmit timing (MT) for the time tMTX clock reference (K) going high (H) until data outputs (D) are invalid (X). Note that, in
general, the clock reference symbol representation is based on two to three letters representing the clock of a particular
functional. For example, the subscript of tMTX represents the MII(M) transmit (TX) clock. For rise and fall times, the latter
convention is used with the appropriate letter: R (rise) or F (fall).
2. Guaranteed by design.
Table 31. MII Receive AC Timing Specifications
At recommended operating conditions with L/TVDD of 3.3 V ± 5%.
Parameter Symbol 1Min Typ Max Unit
RX_CLK clock period 10 Mbps tMRX2,3 —400— ns
RX_CLK clock period 100 Mbps tMRX3—40—ns
RX_CLK duty cycle tMRXH/tMRX 35 — 65 %
TX_CLK
TXD[3:0]
tMTKHDX
tMTX
tMTXH
tMTXR
tMTXF
TX_EN
TX_ER
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 33
Ethernet: Enhanced Three-Speed Ethernet (eTSEC), MII Management
Figure 14 provides the AC test load for eTSEC.
Figure 14. eTSEC AC Test Load
Figure 15 shows the MII rec eiv e AC timing diagram.
Figure 15. MII Receive AC Timing Diagram
8.2.4 TBI AC Timing Specifications
This section describes the TBI transmit and receive AC timing spec ifications.
RXD[3:0], RX_DV, RX_ER setup time to RX_CLK tMRDVKH 10.0 — — ns
RXD[3:0], RX_DV, RX_ER hold time to RX_CLK tMRDXKH 10.0 — — ns
RX_CLK clock rise time (20%–80%) tMRXR21.0—4.0ns
RX_CLK clock fall time (80%–20%) tMRXF21.0—4.0ns
Note:
1. The symbols used for timing specifications herein follow the pattern of t(first two letters of functional block)(signal)(state) (reference)(state)
for inputs and t(first two letters of functional block)(reference)(state)(signal)(state) for outputs. For example, tMRDVKH symbolizes MII receive
timing (MR) with respect to the time data input signals (D) reach the valid state (V) relative to the tMRX clock reference (K)
going to the high (H) state or setup time. Also, tMRDXKL symbolizes MII receive timing (GR) with respect to the time data input
signals (D) went invalid (X) relative to the tMRX clock reference (K) going to the low (L) state or hold time. Note that, in general,
the clock reference symbol representation is based on three letters representing the clock of a particular functional. For
example, the subscript of tMRX represents the MII (M) receive (RX) clock. For rise and fall times, the latter convention is used
with the appropriate letter: R (rise) or F (fall).
2. Guaranteed by design.
3. ±100 ppm tolerance on RX_CLK frequency
Table 31. MII Receive AC Timing Specifications (continued)
At recommended operating conditions with L/TVDD of 3.3 V ± 5%.
Parameter Symbol 1Min Typ Max Unit
Output Z0 = 50 ΩLV DD/2
RL = 50 Ω
RX_CLK
RXD[3:0]
tMRDXKL
tMRX
tMRXH
tMRXR
tMRXF
RX_DV
RX_ER
tMRDVKH
Valid Data
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
34 Freescale Semiconductor
Ethernet: Enhanced Three-Speed Ethernet (eTSEC), MII Management
8.2.4.1 TBI Transmit AC Timing Specifications
Table 32 provid es the TBI transmit AC timing specific a tions .
Table 32. TBI Transmit AC Timing Specifications
At recommended operating conditions with L/TVDD of 3.3 V ± 5% and 2.5 V ± 5%.
Parameter Symbol 1Min Typ Max Unit
TCG[9:0] setup time GTX_CLK going high tTTKHDV 2.0 — — ns
TCG[9:0] hold time from GTX_CLK going high tTTKHDX 1.0 — — ns
GTX_CLK rise time (20%–80%) tTTXR2——1.0ns
GTX_CLK fall time (80%–20%) tTTXF2——1.0ns
Notes:
1. The symbols used for timing specifications herein follow the pattern of t(first two letters of functional block)(signal)(state )(reference)(state)
for inputs and t(first two letters of functional block)(reference)(state)(signal)(state) for outputs. For example, tTTKHDV symbolizes the TBI
transmit timing (TT) with respect to the time from tTTX (K) going high (H) until the referenced data signals (D) reach the valid
state (V) or setup time. Also, tTTKHDX symbolizes the TBI transmit timing (TT) with respect to the time from tTTX (K) going high
(H) until the referenced data signals (D) reach the invalid state (X) or hold time. Note that, in general, the clock reference
symbol representation is based on three letters representing the clock of a particular functional. For example, the subscript
of tTTX represents the TBI (T) transmit (TX) clock. For rise and fall times, the latter convention is used with the appropriate
letter: R (rise) or F (fall).
2. Guaranteed by design.
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 35
Ethernet: Enhanced Three-Speed Ethernet (eTSEC), MII Management
Figure 16 shows the TBI trans mit AC timing diagram.
Figure 16. TBI Transmit AC Timing Diagram
8.2.4.2 TBI Receive AC Timing Specifications
Table 33 provides the TBI receive AC timing specifications.
Table 33. TBI Receive AC Timing Specifications
At recommended operating conditions with L/TVDD of 3.3 V ± 5% and 2.5 V ± 5%.
Parameter Symbol 1Min Typ Max Unit
PMA_RX_CLK[0:1] clock period tTRX3— 16.0 — ns
PMA_RX_CLK[0:1] skew tSKTRX 7.5—8.5ns
PMA_RX_CLK[0:1] duty cycle tTRXH/tTRX 40 — 60 %
RCG[9:0] setup time to rising PMA_RX_CLK tTRDVKH 2.5 — — ns
RCG[9:0] hold time to rising PMA_RX_CLK tTRDXKH 1.5 — — ns
PMA_RX_CLK[0:1] clock rise time (20%–80%) tTRXR20.7—2.4ns
PMA_RX_CLK[0:1] clock fall time (80%–20%) tTRXF20.7—2.4ns
Note:
1. The symbols used for timing specifications herein follow the pattern of t(first two letters of functional block)(signal)(state) (reference)(state)
for inputs and t(first two letters of functional block)(reference)(state)(signal)(state) for outputs. For example, tTRDVKH symbolizes TBI
receive timing (TR) with respect to the time data input signals (D) reach the valid state (V) relative to the tTRX clock reference
(K) going to the high (H) state or setup time. Also, tTRDXKH symbolizes TBI receive timing (TR) with respect to the time data
input signals (D) went invalid (X) relative to the tTRX clock reference (K) going to the high (H) state. Note that, in general, the
clock reference symbol representation is based on three letters representing the clock of a particular functional. For example,
the subscript of tTRX represents the TBI (T) receive (RX) clock. For rise and fall times, the latter convention is used with the
appropriate letter: R (rise) or F (fall). For symbols representing skews, the subscript is skew (SK) followed by the clock that
is being skewed (TRX).
2. Guaranteed by design.
3. ±100 ppm tolerance on PMA_RX_CLK[0:1] frequency
GTX_CLK
TCG[9:0]
tTTXR
tTTX
tTTXH
tTTXR
tTTXF
tTTKHDV
tTTKHDX
tTTXF
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
36 Freescale Semiconductor
Ethernet: Enhanced Three-Speed Ethernet (eTSEC), MII Management
Figure 17 s hows the TBI receive AC timing diagr am.
Figure 17. TBI Receive AC Timing Diagram
8.2.5 TBI Single-Clock Mode AC Specifications
When the eTSEC is configured for TBI modes, all clocks are supplied from external sources to the relevant
eTSEC interface. I n single-clock TBI mode, when TBICON[CLKSEL] = 1 a 125-MHz TBI receive clock
is supplied on TSECn_RX_CLK pin (no receive clock is used on TSECn_TX_CLK in this mode, whereas
for the dual-clock mode this is the PMA1 receive clock). The 125-MHz transmit clock is applied on the
TSEC_GTX_CLK125 pin in all TBI modes.
A summary of the single-clock TBI mode AC specificat ions for receive appears in Table 34.
Table 34. TBI single-clock Mode Receive AC Timing Specification
At recommended operating conditions with L/TVDD of 3.3 V ± 5% and 2.5 V ± 5%.
Parameter Symbol Min Typ Max Unit
RX_CLK clock period tTRR1
1±100 ppm tolerance on RX_CLK frequency
7.5 8.0 8.5 ns
RX_CLK duty cycle tTRRH/tTRR 40 50 60 %
RX_CLK peak-to-peak jitter tTRRJ — — 250 ps
Rise time RX_CLK (20%–80%) tTRRR ——1.0ns
Fall time RX_CLK (80%–20%) tTRRF ——1.0ns
RCG[9:0] setup time to RX_CLK rising edge tTRRDVKH 2.0 — — ns
RCG[9:0] hold time to RX_CLK rising edge tTRRDXKH 1.0 — — ns
PMA_RX_CLK1
RCG[9:0]
tTRX
tTRXH
tTRXR
tTRXF
tTRDVKH
PMA_RX_CLK0
tTRDXKH
tTRDVKH
tTRDXKH
tSKTRX
tTRXH
Valid Data Valid Data
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 37
Ethernet: Enhanced Three-Speed Ethernet (eTSEC), MII Management
A timing diagram for TBI re cei ve appears in Figure 18.
Figure 18. TBI Single-Clock Mode Receive AC Timing Diagram
8.2.6 RGMII and RTBI AC Timing Specifications
Table 35 prese nts the RGMII and RTBI AC timing specifica tions .
Table 35. RGMII and RTBI AC Timing Specifications
At recommended operating conditions with L/TVDD of 2.5 V ± 5%.
Parameter Symbol 1Min Typ Max Unit
Data to clock output skew (at transmitter) tSKRGT5–500 0 500 ps
Data to clock input skew (at receiver) 2tSKRGT 1.0 — 2.8 ns
Clock period duration 3tRGT5,6 7.2 8.0 8.8 ns
Duty cycle for 10BASE-T and 100BASE-TX 3, 4 tRGTH/tRGT540 50 60 %
Rise time (20%–80%) tRGTR5— — 0.75 ns
Fall time (80%–20%) tRGTF5— — 0.75 ns
Notes:
1. Note that, in general, the clock reference symbol representation for this section is based on the symbols RGT to represent
RGMII and RTBI timing. For example, the subscript of tRGT represents the TBI (T) receive (RX) clock. Note also that the
notation for rise (R) and fall (F) times follows the clock symbol that is being represented. For symbols representing skews,
the subscript is skew (SK) followed by the clock that is being skewed (RGT).
2. This implies that PC board design will require clocks to be routed such that an additional trace delay of greater than 1.5 ns
will be added to the associated clock signal.
3. For 10 and 100 Mbps, tRGT scales to 400 ns ± 40 ns and 40 ns ± 4 ns, respectively.
4. Duty cycle may be stretched/shrunk during speed changes or while transitioning to a received packet's clock domains as
long as the minimum duty cycle is not violated and stretching occurs for no more than three tRGT of the lowest speed
transitioned between.
5. Guaranteed by characterization
6. ±100 ppm tolerance on RX_CLK frequency.
tTRR
tTRRH tTRRF
tTRRR
RX_CLK
RCG[9:0]
valid data
tTRRDXKH
tTRRDVKH
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
38 Freescale Semiconductor
Ethernet: Enhanced Three-Speed Ethernet (eTSEC), MII Management
Figure 19 s hows the RGMII and RTBI AC timing and multiplexing diagrams.
Figure 19. RGMII and RTBI AC Timing and Multiplexing Diagrams
8.2.7 RMII AC Timing Specifications
This section describes the RMII transmit and receive AC timing specifications .
8.2.7.1 RMII Transmit AC Timing Specifications
The RMII transm it AC timing spec ificat ions are in Table 36.
Table 36. RMII Transmit AC Timing Specifications
At recommended operating conditions with L/TVDD of 3.3 V ± 5%.
Parameter Symbol 1Min Typ Max Unit
REF_CLK clock period tRMT — 20.0 — ns
REF_CLK duty cycle tRMTH/tRMT 35 50 65 %
REF_CLK peak-to-peak jitter tRMTJ — — 250 ps
Rise time REF_CLK (20%–80%) tRMTR 1.0 — 2.0 ns
Fall time REF_CLK (80%–20%) tRMTF 1.0 — 2.0 ns
GTX_CLK
tRGT
tRGTH
tSKRGT
TX_CTL
TXD[8:5]
TXD[7:4]
TXD[9]
TXERR
TXD[4]
TXEN
TXD[3:0]
(At Transmitter)
TXD[8:5][3:0]
TXD[7:4][3:0]
TX_CLK
(At PHY)
RX_CTL
RXD[8:5]
RXD[7:4]
RXD[9]
RXERR
RXD[4]
RXDV
RXD[3:0]
RXD[8:5][3:0]
RXD[7:4][3:0]
RX_CLK
(At PHY)
tSKRGT
tSKRGT
tSKRGT
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 39
Ethernet: Enhanced Three-Speed Ethernet (eTSEC), MII Management
Figure 20 s hows the RMII transmit AC timing diagram.
Figure 20. RMII Transmit AC Timing Diagram
8.2.7.2 RMII Receive AC Timing Specifications
Table 37 shows the RMII re ceive AC timing specifications.
REF_CLK to RMII data TXD[1:0], TX_EN delay tRMTDX 1.0 — 10.0 ns
Note:
1. The symbols used for timing specifications herein follow the pattern of t(first two letters of functional block)(signal)(state) (reference)(state)
for inputs and t(first two letters of functional block)(reference)(state)(signal)(state) for outputs. For example, tMTKHDX symbolizes MII
transmit timing (MT) for the time tMTX clock reference (K) going high (H) until data outputs (D) are invalid (X). Note that, in
general, the clock reference symbol representation is based on two to three letters representing the clock of a particular
functional. For example, the subscript of tMTX represents the MII(M) transmit (TX) clock. For rise and fall times, the latter
convention is used with the appropriate letter: R (rise) or F (fall).
Table 37. RMII Receive AC Timing Specifications
At recommended operating conditions with L/TVDD of 3.3 V ± 5%.
Parameter Symbol1Min Typ Max Unit
REF_CLK clock period tRMR 15.0 20.0 25.0 ns
REF_CLK duty cycle tRMRH/tRMR 35 50 65 %
REF_CLK peak-to-peak jitter tRMRJ — — 250 ps
Rise time REF_CLK (20%–80%) tRMRR 1.0 — 2.0 ns
Fall time REF_CLK (80%–20%) tRMRF 1.0 — 2.0 ns
RXD[1:0], CRS_DV, RX_ER setup time to REF_CLK rising edge tRMRDV 4.0 — — ns
Table 36. RMII Transmit AC Timing Specifications (continued)
At recommended operating conditions with L/TVDD of 3.3 V ± 5%.
Parameter Symbol 1Min Typ Max Unit
REF_CLK
TXD[1:0]
tRMTDX
tRMT
tRMTH
tRMTR
tRMTF
TX_EN
TX_ER
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
40 Freescale Semiconductor
Ethernet Management Interface Electrical Characteristics
Figure 21 provides the AC test load for eTSEC.
Figure 21. eTSEC AC Test Load
Figure 22 shows the RMII receive AC timing diagram.
Figure 22. RMII Receive AC Timing Diagram
9 Ethernet Management Interface Electrical
Characteristics
The electri cal char act er isti cs specified here apply to MII management interf ace si gnal s MDIO
(managem ent data input/output) and MDC (manage ment data clock). The electri cal char act er isti cs for
GMII, RGMII, RMII, TBI and RTBI are specifie d in “Section 8, “Ethernet: Enhanced Three-Speed
Ethernet (eTSEC ), MII M anagem ent. ”
RXD[1:0], CRS_DV, RX_ER hold time to REF_CLK rising edge tRMRDX 2.0 — — ns
Note:
1. The symbols used for timing specifications herein follow the pattern of t(first two letters of functional block)(signal)(state) (reference)(state)
for inputs and t(first two letters of functional block)(reference)(state)(signal)(state) for outputs. For example, tMRDVKH symbolizes MII
receive timing (MR) with respect to the time data input signals (D) reach the valid state (V) relative to the tMRX clock reference
(K) going to the high (H) state or setup time. Also, tMRDXKL symbolizes MII receive timing (GR) with respect to the time data
input signals (D) went invalid (X) relative to the tMRX clock reference (K) going to the low (L) state or hold time. Note that, in
general, the clock reference symbol representation is based on three letters representing the clock of a particular functional.
For example, the subscript of tMRX represents the MII (M) receive (RX) clock. For rise and fall times, the latter convention is
used with the appropriate letter: R (rise) or F (fall).
Table 37. RMII Receive AC Timing Specifications (continued)
At recommended operating conditions with L/TVDD of 3.3 V ± 5%.
Parameter Symbol1Min Typ Max Unit
Output Z0 = 50 ΩLV DD/2
RL = 50 Ω
REF_CLK
RXD[1:0]
tRMRDX
tRMR
tRMRH
tRMRR
tRMRF
CRS_DV
RX_ER
tRMRDV
Valid Data
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 41
Ethernet Management Interface Electrical Characteristics
9.1 MII Management DC Electrical Characteristics
The MDC and MDIO are defined to operate at a supply voltage of 3.3 V. The DC electrical characteristics
for MDIO and MDC are provided in Table 38.
9.2 MII Management AC Electrical Specifications
Table 39 provid es the MII management AC timing specifications.
Table 38. MII Management DC Electrical Characteristics
Parameter Symbol Min Max Unit
Supply voltage (3.3 V) OVDD 3.135 3.465 V
Output high voltage
(OVDD = Min, IOH = –1.0 mA)
VOH 2.10 — V
Output low voltage
(OVDD = Min, IOL = 1.0 mA)
VOL —0.50V
Input high voltage VIH 1.70 — V
Input low voltage VIL —0.90V
Input high current
(OVDD = Max, VIN 1 = 2.1 V)
IIH —40μA
Input low current
(OVDD = Max, VIN = 0.5 V)
IIL –600 — μA
Note:
1. Note that the symbol VIN, in this case, represents the OVIN symbol referenced in Table 1 and Table 2.
Table 39. MII Management AC Timing Specifications
At recommended operating conditions with OVDD is 3.3 V ± 5%.
Parameter Symbol 1Min Typ Max Unit Notes
MDC frequency fMDC 2.5 — 9.3 MHz 2, 4
MDC period tMDC 80 — 400 ns —
MDC clock pulse width high tMDCH 32 — — ns —
MDC to MDIO valid tMDKHDV 16 ×tMPXCLK ——ns5
MDC to MDIO delay tMDKHDX 10 — 16 ×tMPXCLK ns 3, 5
MDIO to MDC setup time tMDDVKH 5——ns—
MDIO to MDC hold time tMDDXKH 0——ns—
MDC rise time tMDCR — — 10 ns 4
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
42 Freescale Semiconductor
Ethernet Management Interface Electrical Characteristics
Figure 23 provides the AC test load for eTSEC.
Figure 23. eTSEC AC Test Load
NOTE
Output will see a 50 Ω load since what it sees is the transmission line.
Figure 24 shows the MII management AC timing diagram.
Figure 24. MII Management Interface Timing Diagram
MDC fall time tMDHF — — 10 ns 4
Notes:
1. The symbols used for timing specifications herein follow the pattern of t(first two letters of functional block)(signal)(state) (reference)(state)
for inputs and t(first two letters of functional block)(reference)(state)(signal)(state) for outputs. For example, tMDKHDX symbolizes
management data timing (MD) for the time tMDC from clock reference (K) high (H) until data outputs (D) are invalid (X) or data
hold time. Also, tMDDVKH symbolizes management data timing (MD) with respect to the time data input signals (D) reach the
valid state (V) relative to the tMDC clock reference (K) going to the high (H) state or setup time. For rise and fall times, the
latter convention is used with the appropriate letter: R (rise) or F (fall).
2. This parameter is dependent on the system clock speed. (The maximum frequency is the maximum platform frequency
divided by 64.)
3. This parameter is dependent on the system clock speed. (That is, for a system clock of 267 MHz, the maximum frequency is
8.3 MHz and the minimum frequency is 1.2 MHz; for a system clock of 375 MHz, the maximum frequency is 11.7 MHz and
the minimum frequency is 1.7 MHz.)
4. Guaranteed by design.
5. tMPXCLK is the platform (MPX) clock
Table 39. MII Management AC Timing Specifications (continued)
At recommended operating conditions with OVDD is 3.3 V ± 5%.
Parameter Symbol 1Min Typ Max Unit Notes
Output Z0 = 50 ΩOVDD/2
RL = 50 Ω
MDC
tMDDXKH
tMDC
tMDCH
tMDCR
tMDCF
tMDDVKH
tMDKHDX
MDIO
MDIO
(Input)
(Output)
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 43
Local Bus
10 Local Bus
This section describes the DC and AC electrical specifications for the local bus interface of the MPC8640.
10.1 Local Bus DC Electrical Characteristics
Table 40 provides the DC electrical characteristics for the local bus interface operating at OVDD = 3.3 V
DC.
10.2 Local Bus AC Timing Specifications
Table 41 describes the timing paramete rs of the local bus interf ace at OVDD = 3.3 V with PLL enabled.
For information about the frequency range of local bus see Section 18.1, “Clock Ranges.”
Table 40. Local Bus DC Electrical Characteristics (3.3 V DC)
Parameter Symbol Min Max Unit
High-level input voltage VIH 2OV
DD + 0.3 V
Low-level input voltage VIL –0.3 0.8 V
Input current
(VIN 1 = 0 V or VIN = OVDD)
IIN —±5 μA
High-level output voltage
(OVDD = min, IOH = –2 mA)
VOH OVDD – 0.2 — V
Low-level output voltage
(OVDD = min, IOL = 2 mA)
VOL —0.2 V
Note:
1. Note that the symbol VIN, in this case, represents the OVIN symbol referenced in Tab le 1 and Table 2.
Table 41. Local Bus Timing Specifications (OVDD = 3.3 V)—PLL Enabled
Parameter Symbol 1Min Max Unit Notes
Local bus cycle time tLBK 8—ns2
Local bus duty cycle tLBKH/tLBK 45 55 % —
LCLK[n] skew to LCLK[m] or LSYNC_OUT tLBKSKEW — 150 ps 7, 8
Input setup to local bus clock (except LGTA/LUPWAIT) tLBIVKH1 1.8 — ns 3, 4
LGTA/LUPWAIT input setup to local bus clock tLBIVKH2 1.7 — ns 3, 4
Input hold from local bus clock (except LGTA/LUPWAIT) tLBIXKH1 1.0 — ns 3, 4
LGTA/LUPWAIT input hold from local bus clock tLBIXKH2 1.0 — ns 3, 4
LALE output transition to LAD/LDP output transition (LATCH hold time) tLBOTOT 1.5 — ns 6
Local bus clock to output valid (except LAD/LDP and LALE) tLBKHOV1 —2.0ns —
Local bus clock to data valid for LAD/LDP tLBKHOV2 —2.2ns —
Local bus clock to address valid for LAD tLBKHOV3 —2.3ns —
Local bus clock to LALE assertion tLBKHOV4 —2.3ns 3
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
44 Freescale Semiconductor
Local Bus
Figure 25 provides the AC test load for the local bus.
Figure 25. Local Bus AC Test Load
Output hold from local bus clock (except LAD/LDP and LALE) tLBKHOX1 0.7 — ns —
Output hold from local bus clock for LAD/LDP tLBKHOX2 0.7 — ns 3
Local bus clock to output high Impedance (except LAD/LDP and LALE) tLBKHOZ1 —2.5ns 5
Local bus clock to output high impedance for LAD/LDP tLBKHOZ2 —2.5ns 5
Note:
1. The symbols used for timing specifications herein follow the pattern of t(First two letters of functional block)(signal)(state) (reference)(state)
for inputs and t(First two letters of functional block)(reference)(state)(signal)(state) for outputs. For example, tLBIXKH1 symbolizes local bus
timing (LB) for the input (I) to go invalid (X) with respect to the time the tLBK clock reference (K) goes high (H), in this case for
clock one(1). Also, tLBKHOX symbolizes local bus timing (LB) for the tLBK clock reference (K) to go high (H), with respect to the
output (O) going invalid (X) or output hold time.
2. All timings are in reference to LSYNC_IN for PLL enabled and internal local bus clock for PLL bypass mode.
3. All signals are measured from OVDD ÷2 of the rising edge of LSYNC_IN for PLL enabled or internal local bus clock for PLL
bypass mode to 0.4 ×OVDD of the signal in question for 3.3-V signaling levels.
4. Input timings are measured at the pin.
5. For purposes of active/float timing measurements, the Hi-Z or off state is defined to be when the total current delivered
through the component pin is less than or equal to the leakage current specification.
6. tLBOTOT is a measurement of the minimum time between the negation of LALE and any change in LAD. tLBOTOT is
programmed with the LBCR[AHD] parameter.
7. Maximum possible clock skew between a clock LCLK[m] and a relative clock LCLK[
n
]. Skew measured between
complementary signals at BVDD ÷2.
8. Guaranteed by design.
Table 41. Local Bus Timing Specifications (OVDD = 3.3 V)—PLL Enabled (continued)
Parameter Symbol 1Min Max Unit Notes
Output Z0 = 50 ΩOVDD/2
RL = 50 Ω
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 45
Local Bus
Figure 26 shows the local bus signals with PLL enabled.
Figure 26. Local Bus Signals (PLL Enabled)
NOTE
PLL bypass mod e is recommended when LBIU frequency is at or below
83 MHz. When LBIU operates above 83 MHz, LBIU PLL is recommended
to be enabled.
Table 42 describes the general timing parameters of the local bus interface at OVDD = 3.3 V with PLL
bypassed.
Table 42. Local Bus Timing Parameters—PLL Bypassed
Parameter Symbol1Min Max Unit Notes
Local bus cycle time tLBK 12 — ns 2
Local bus duty cycle tLBKH/tLBK 45 55 % —
Internal launch/capture clock to LCLK delay tLBKHKT 2.3 3.9 ns 8
Input setup to local bus clock (except LGTA/LUPWAIT) tLBIVKH1 5.7 — ns 4, 5
LGTA/LUPWAIT input setup to local bus clock tLBIVKL2 5.6 — ns 4, 5
Input hold from local bus clock (except LGTA/LUPWAIT) tLBIXKH1 –1.8 — ns 4, 5
Output Signals:
LA[27:31]/LBCTL/LBCKE/LOE/
LSDA10/LSDWE/LSDRAS/
LSDCAS/LSDDQM[0:3]
tLBKHOV1
tLBKHOV2
tLBKHOV3
LSYNC_IN
Input Signals:
LAD[0:31]/LDP[0:3]
Output (Data) Signals:
LAD[0:31]/LDP[0:3]
Output (Address) Signal:
LAD[0:31]
LALE
tLBIXKH1
tLBIVKH1
tLBIVKH2
tLBIXKH2
tLBKHOX1
tLBKHOZ1
tLBKHOX2
tLBKHOZ2
Input Signal:
LGTA
tLBOTOT
tLBKHOZ2
tLBKHOX2
tLBKHOV4
LUPWAIT
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
46 Freescale Semiconductor
Local Bus
LGTA/LUPWAIT input hold from local bus clock tLBIXKL2 –1.3 — ns 4, 5
LALE output transition to LAD/LDP output transition (LATCH hold
time)
tLBOTOT 1.5 — ns 6
Local bus clock to output valid (except LAD/LDP and LALE) tLBKLOV1 — –0.3 ns
Local bus clock to data valid for LAD/LDP tLBKLOV2 — –0.1 ns 4
Local bus clock to address valid for LAD tLBKLOV3 —0ns4
Local bus clock to LALE assertion tLBKLOV4 —0ns4
Output hold from local bus clock (except LAD/LDP and LALE) tLBKLOX1 –3.2 — ns 4
Output hold from local bus clock for LAD/LDP tLBKLOX2 –3.2 — ns 4
Local bus clock to output high Impedance (except LAD/LDP and
LALE)
tLBKLOZ1 —0.2ns7
Local bus clock to output high impedance for LAD/LDP tLBKLOZ2 —0.2ns7
Notes:
1. The symbols used for timing specifications herein follow the pattern of t(First two letters of functional block)(signal)(state) (reference)(state)
for inputs and t(First two letters of functional block)(reference)(state)(signal)(state) for outputs. For example, tLBIXKH1 symbolizes local bus
timing (LB) for the input (I) to go invalid (X) with respect to the time the tLBK clock reference (K) goes high (H), in this case
for clock one(1). Also, tLBKHOX symbolizes local bus timing (LB) for the tLBK clock reference (K) to go high (H), with respect
to the output (O) going invalid (X) or output hold time.
2. All timings are in reference to local bus clock for PLL bypass mode. Timings may be negative with respect to the local bus
clock because the actual launch and capture of signals is done with the internal launch/capture clock, which precedes LCLK
by tLBKHKT
.
3. Maximum possible clock skew between a clock LCLK[m] and a relative clock LCLK[n]. Skew measured between
complementary signals at BVDD ÷2.
4. All signals are measured from BVDD ÷2 of the rising edge of local bus clock for PLL bypass mode to 0.4 ×BVDD of the signal
in question for 3.3-V signaling levels.
5. Input timings are measured at the pin.
6. The value of tLBOTOT is the measurement of the minimum time between the negation of LALE and any change in LAD
7. For purposes of active/float timing measurements, the Hi-Z or off state is defined to be when the total current delivered
through the component pin is less than or equal to the leakage current specification.
8. Guaranteed by characterization.
Table 42. Local Bus Timing Parameters—PLL Bypassed (continued)
Parameter Symbol1Min Max Unit Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 47
Local Bus
Figure 27 shows the local bus signals in PLL bypass mode.
Figure 27. Local Bus Signals (PLL Bypass Mode)
NOTE
In PL L bypass mode, LCLK[n] is the inverted version of the internal clock
with the delay of tLBKHKT. I n this mode, signals are launched at the rising edge
of the internal clock and are captured at falling edge of the internal clock,
with the exc eption of the L GTA/LUPWAIT signa l, which is c ap tured a t the
rising edge of the internal clock.
Output Signals:
LA[27:31]/LBCTL/LBCKE/LOE/
LSDA10/LSDWE/LSDRAS/
LSDCAS/LSDDQM[0:3]
tLBKLOV2
LCLK[n]
Input Signals:
LAD[0:31]/LDP[0:3]
Output (Data) Signals:
LAD[0:31]/LDP[0:3]
LALE
tLBIXKH1
Input Signal:
LGTA
Output (Address) Signal:
LAD[0:31]
tLBIVKH1
tLBIXKL2
tLBIVKL2
tLBKLOX1
tLBKLOZ2
tLBOTOT
Internal launch/capture clock
tLBKLOX2
tLBKLOV1
tLBKLOV3
tLBKLOZ1
tLBKHKT
tLBKLOV4
LUPWAIT
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
48 Freescale Semiconductor
Local Bus
Figure 28–Figure 31 show the local bus signals and GPCM/UPM signals for LCRR[CLKDIV] at cl ock
ratios of 4, 8, and 16 with PLL enabl ed or bypassed.
Figure 28. Local Bus Signals, GPCM/UPM Signals for LCRR[CLKDIV] = 2 (clock ratio of 4) (PLL Enabled)
LSYNC_IN
UPM Mode Input Signal:
LUPWAIT
tLBIXKH2
tLBIVKH2
tLBIVKH1
tLBIXKH1
tLBKHOZ1
T1
T3
Input Signals:
LAD[0:31]/LDP[0:3]
UPM Mode Output Signals:
LCS[0:7]/LBS[0:3]/LGPL[0:5]
GPCM Mode Output Signals:
LCS[0:7]/LWE
tLBKHOV1
tLBKHOV1 tLBKHOZ1
GPCM Mode Input Signal:
LGTA
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 49
Local Bus
Figure 29. Local Bus Signals, GPCM/UPM Signals for LCRR[CLKDIV] = 2 (clock ratio of 4)
(PLL Bypass Mode)
tLBIVKH1
tLBIXKL2
Internal launch/capture clock
UPM Mode Input Signal:
LUPWAIT
T1
T3
Input Signals:
LAD[0:31]/LDP[0:3]
UPM Mode Output Signals:
LCS[0:7]/LBS[0:3]/LGPL[0:5]
GPCM Mode Output Signals:
LCS[0:7]/LWE
tLBKLOV1
tLBKLOZ1
LCLK
tLBKLOX1
tLBIXKH1
GPCM Mode Input Signal:
LGTA
tLBIVKL2
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
50 Freescale Semiconductor
Local Bus
Figure 30. Local Bus Signals, GPCM/UPM Signals for LCRR[CLKDIV] = 4 or 8 (clock ratio of 8 or 16)
(PLL Enabled)
LSYNC_IN
UPM Mode Input Signal:
LUPWAIT
tLBIXKH2
tLBIVKH2
tLBIVKH1
tLBIXKH1
tLBKHOZ1
T1
T3
UPM Mode Output Signals:
LCS[0:7]/LBS[0:3]/LGPL[0:5]
GPCM Mode Output Signals:
LCS[0:7]/LWE
tLBKHOV1
tLBKHOV1 tLBKHOZ1
T2
T4
Input Signals:
LAD[0:31]/LDP[0:3]
GPCM Mode Input Signal:
LGTA
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 51
Local Bus
Figure 31. Local Bus Signals, GPCM/UPM Signals for LCRR[CLKDIV] = 4 or 8 (clock ratio of 8 or 16)
(PLL Bypass Mode)
tLBIXKL2
tLBIVKH1
Internal launch/capture clock
UPM Mode Input Signal:
LUPWAIT
T1
T3
UPM Mode Output Signals:
LCS[0:7]/LBS[0:3]/LGPL[0:5]
GPCM Mode Output Signals:
LCS[0:7]/LWE
T2
T4
Input Signals:
LAD[0:31]/LDP[0:3]
LCLK
tLBKLOV1
tLBKLOZ1
tLBKLOX1
tLBIXKH1
GPCM Mode Input Signal:
LGTA
tLBIVKL2
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
52 Freescale Semiconductor
JTAG
11 JTAG
This section describes the DC and AC electrical specifications for the IEEE 1149.1 (JTAG) interface of
the MPC8640/D.
11.1 JTAG DC Electrical Characteristics
Table 43 provides the DC electrical characteristics for the JTAG interface.
11.2 JTAG AC Electrical Specifications
Table 44 provides the JTAG AC timing spec ifications as defined in Figure 33 through Figure 35.
Table 43. JTAG DC Electrical Characteristics
Parameter Symbol Min Max Unit
High-level input voltage VIH 2OV
DD + 0.3 V
Low-level input voltage VIL –0.3 0.8 V
Input current
(VIN 1 = 0 V or VIN = VDD)
IIN —±5 μA
High-level output voltage
(OVDD = min, IOH = –100 μA)
VOH OVDD – 0.2 — V
Low-level output voltage
(OVDD = min, IOL = 100 μA)
VOL —0.2 V
Note:
1. Note that the symbol VIN, in this case, represents the OVIN symbol referenced in Ta ble 1 and Table 2.
Table 44. JTAG AC Timing Specifications (Independent of SYSCLK)1
At recommended operating conditions (see Ta ble 3 ).
Parameter Symbol2Min Max Unit Notes
JTAG external clock frequency of operation fJTG 0 33.3 MHz —
JTAG external clock cycle time t JTG 30 — ns —
JTAG external clock pulse width measured at 1.4 V tJTKHKL 15 — ns —
JTAG external clock rise and fall times tJTGR & tJTGF 02ns6
TRST assert time tTRST 25 — ns 3
Input setup times:
Boundary-scan data
TMS, TDI
tJTDVKH
tJTIVKH
4
0
—
—
ns
4
Input hold times:
Boundary-scan data
TMS, TDI
tJTDXKH
tJTIXKH
20
25
—
—
ns
4
Valid times:
Boundary-scan data
TDO
tJTKLDV
tJTKLOV
4
4
20
25
ns
5
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 53
JTAG
Figure 32 provides the AC test load for TDO and the boundary-scan outputs.
Figure 32. AC Test Load for the JTAG Interface
Figure 33 provides the JTAG clock input timing diagram.
Figure 33. JTAG Clock Input Timing Diagram
Output hold times:
Boundary-scan data
TDO
tJTKLDX
tJTKLOX
30
30
—
—
ns
5, 6
JTAG external clock to output high impedance:
Boundary-scan data
TDO
tJTKLDZ
tJTKLOZ
3
3
19
9
ns
5, 6
Notes:
1. All outputs are measured from the midpoint voltage of the falling/rising edge of tTCLK to the midpoint of the signal in question.
The output timings are measured at the pins. All output timings assume a purely resistive 50-Ω load (see Figure 32).
Time-of-flight delays must be added for trace lengths, vias, and connectors in the system.
2. The symbols used for timing specifications herein follow the pattern of t(first two letters of functional block)(signal)(state) (reference)(state)
for inputs and t(first two letters of functional block)(reference)(state)(signal)(state) for outputs. For example, tJTDVKH symbolizes JTAG
device timing (JT) with respect to the time data input signals (D) reaching the valid state (V) relative to the tJTG clock
reference (K) going to the high (H) state or setup time. Also, tJTDXKH symbolizes JTAG timing (JT) with respect to the time
data input signals (D) went invalid (X) relative to the tJTG clock reference (K) going to the high (H) state. Note that, in general,
the clock reference symbol representation is based on three letters representing the clock of a particular functional. For rise
and fall times, the latter convention is used with the appropriate letter: R (rise) or F (fall).
3. TRST is an asynchronous level sensitive signal. The setup time is for test purposes only.
4. Non-JTAG signal input timing with respect to tTCLK.
5. Non-JTAG signal output timing with respect to tTCLK.
6. Guaranteed by design.
Table 44. JTAG AC Timing Specifications (Independent of SYSCLK)1 (continued)
At recommended operating conditions (see Ta ble 3 ).
Parameter Symbol2Min Max Unit Notes
Output Z0 = 50 ΩOVDD/2
RL = 50 Ω
JTAG
tJTKHKL tJTGR
External Clock VMVMVM
tJTG tJTGF
VM = Midpoint Voltage (OVDD/2)
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
54 Freescale Semiconductor
I2C
Figure 34 pr ovides the TRST timing diagram.
Figure 34. TRST Timing Diagram
Figure 35 provides the boundary-scan timing diagram.
Figure 35. Boundary-Scan Timing Diagram
12 I2C
This section describes the DC and AC electrical characteristics for the I2C interfaces of the MPC8640.
12.1 I2C DC Electrical Characteristics
Table 45 provides the DC electrical characteristics for the I2C interfaces.
Table 45. I2C DC Electrical Characteristics
At recommended operating conditions with OVDD of 3.3 V ± 5%.
Parameter Symbol Min Max Unit Notes
Input high voltage level VIH 0.7 × OVDD OVDD +0.3 V —
Input low voltage level VIL –0.3 0.3 × OVDD V—
Low level output voltage VOL 00.2 × OVDD V1
Pulse width of spikes which must be suppressed by the input
filter
tI2KHKL 050ns2
TRST
VM = Midpoint Voltage (OVDD/2)
VM VM
tTRST
VM = Midpoint Voltage (OVDD/2)
VM VM
tJTDVKH
tJTDXKH
Boundary
Data Outputs
Boundary
Data Outputs
JTAG
External Clock
Boundary
Data Inputs
Output Data Valid
tJTKLDX
tJTKLDZ
tJTKLDV
Input
Data Valid
Output Data Valid
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 55
I2C
12.2 I2C AC Electrical Specifications
Table 46 provid es the AC timing parameters for the I2C interf aces .
Input current each I/O pin (input voltage is between
0.1 ×OVDD and 0.9 × OVDD (max)
II–10 10 μA3
Capacitance for each I/O pin CI—10pF—
Notes:
1. Output voltage (open drain or open collector) condition = 3 mA sink current.
2. Refer to the
MPC8641
Integrated Host Processor Reference Manual
for information on the digital filter used.
3. I/O pins will obstruct the SDA and SCL lines if OVDD is switched off.
Table 46. I2C AC Electrical Specifications
All values refer to VIH (min) and VIL (max) levels (see Table 45).
Parameter Symbol1Min Max Unit
SCL clock frequency fI2C 0 400 kHz
Low period of the SCL clock tI2CL 4 1.3 — μs
High period of the SCL clock tI2CH 4 0.6 — μs
Setup time for a repeated START condition tI2SVKH 4 0.6 — μs
Hold time (repeated) START condition (after this period, the first
clock pulse is generated)
tI2SXKL 4 0.6 — μs
Data setup time tI2DVKH 4 100 — ns
Data input hold time:
CBUS compatible masters
I2C bus devices
tI2DXKL
—
0 2
—
—μs
Rise time of both SDA and SCL signals tI2CR 20 + 0.1 CB5300 ns
Fall time of both SDA and SCL signals tI2CF 20 + 0.1 Cb 5300 ns
Data output delay time tI2OVKL —0.9
3μs
Set-up time for STOP condition tI2PVKH 0.6 — μs
Bus free time between a STOP and START condition tI2KHDX 1.3 — μs
Noise margin at the LOW level for each connected device (including
hysteresis)
VNL 0.1 × OVDD —V
Table 45. I2C DC Electrical Characteristics (continued)
At recommended operating conditions with OVDD of 3.3 V ± 5%.
Parameter Symbol Min Max Unit Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
56 Freescale Semiconductor
I2C
Figure 32 provides the AC test load for the I2C.
Figure 36. I2C AC Test Load
Noise margin at the HIGH level for each connected device (including
hysteresis)
VNH 0.2 × OVDD —V
Note:
1. The symbols used for timing specifications herein follow the pattern of t(first two letters of functional block)(signal)(state) (reference)(state)
for inputs and t(first two letters of functional block)(reference)(state)(signal)(state) for outputs. For example, tI2DVKH symbolizes I2C timing
(I2) with respect to the time data input signals (D) reach the valid state (V) relative to the tI2C clock reference (K) going to the
high (H) state or setup time. Also, tI2SXKL symbolizes I2C timing (I2) for the time that the data with respect to the start condition
(S) went invalid (X) relative to the tI2C clock reference (K) going to the low (L) state or hold time. Also, tI2PVKH symbolizes I2C
timing (I2) for the time that the data with respect to the stop condition (P) reaching the valid state (V) relative to the tI2C clock
reference (K) going to the high (H) state or setup time. For rise and fall times, the latter convention is used with the appropriate
letter: R (rise) or F (fall).
2. As a transmitter, the MPC8640 provides a delay time of at least 300 ns for the SDA signal (referred to the Vihmin of the SCL
signal) to bridge the undefined region of the falling edge of SCL to avoid unintended generation of Start or Stop condition.
When MPC8640 acts as the I2C bus master while transmitting, MPC8640 drives both SCL and SDA. As long as the load on
SCL and SDA are balanced, MPC8640 would not cause unintended generation of Start or Stop condition. Therefore, the 300
ns SDA output delay time is not a concern. If, under some rare condition, the 300 ns SDA output delay time is required for
MPC8640 as transmitter, the following setting is recommended for the FDR bit field of the I2CFDR register to ensure both the
desired I2C SCL clock frequency and SDA output delay time are achieved, assuming that the desired I2C SCL clock frequency
is 400 KHz and the Digital Filter Sampling Rate Register (I2CDFSRR) is programmed with its default setting of 0x10 (decimal
16):
I2C Source Clock Frequency 333 MHz 266 MHz 200 MHz 133 MHz
FDR Bit Setting 0x2A 0x05 0x26 0x00
Actual FDR Divider Selected 896 704 512 384
Actual I2C SCL Frequency Generated 371 KHz 378 KHz 390 KHz 346 KHz
For the detail of I2C frequency calculation, refer to the application note AN2919 “Determining the I2C Frequency Divider Ratio
for SCL.” Note that the I2C Source Clock Frequency is half of the MPX clock frequency for MPC8640.
3. The maximum tI2DXKL has only to be met if the device does not stretch the LOW period (tI2CL) of the SCL signal.
4. Guaranteed by design.
5. CB = capacitance of one bus line in pF.
Table 46. I2C AC Electrical Specifications (continued)
All values refer to VIH (min) and VIL (max) levels (see Table 45).
Parameter Symbol1Min Max Unit
Output Z0 = 50 ΩOVDD/2
RL = 50 Ω
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 57
High-Speed Serial Interfaces (HSSI)
Figure 37 shows the AC timing diagram for the I2C bus.
Figure 37. I2C Bus AC Timing Diagram
13 High-Speed Serial Interfaces (HSSI)
The MPC8640D f eatures two Serializer/D eserializer (SerDes) interfaces to be used for high-speed serial
interconnect applications. The SerDes1 interface is dedicated for PCI Express data transfers. The SerDes2
can be used for PCI Express and/or serial RapidIO data transfers.
This section describes the common portion of SerDes DC electric al specifications, which is the DC
requi reme nt for SerDe s Refer ence Clocks . The SerDes data lane’s trans mitte r and receive r refe r ence
circuits are also shown.
13.1 Signal Terms Definition
The SerDes utilizes dif ferential signaling to transfer data across the serial link. This section defines terms
used in the description and specification of diffe rential signals.
SrS
SDA
SCL
tI2CF
tI2SXKL
tI2CL
tI2CH
tI2DXKL
tI2DVKH
tI2SXKL
tI2SVKH
tI2KHKL
tI2PVKH
tI2CR
tI2CF
PS
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
58 Freescale Semiconductor
High-Speed Serial Interfaces (HSSI)
Figure 38 shows how the signals are define d. For illustration purpos e, only one SerDes lane is used for
description. The figure shows wavef orm for e ither a transmitte r output (SDn_TX and SDn_TX) or a
receiver input (SDn_RX and SDn_RX). Each signal swings between A volts and B volts where A > B .
Figure 38. Differential Voltage Definitions for Transmitter or Receiver
Using this waveform, the definitions are as follows. To simplify illustration, the following definitions
assume that the SerDes transmitter and receiver operate in a fully symmetrical differential signaling
environment.
Si ngle-E nde d Sw ing
The transmitter output signals and the receiver input signals SDn_TX, SDn_TX,
SDn_RX and SDn_RX each have a peak-to-peak swing of A – B volts. This is also
referred as each signal wire’s single-ended swing.
Differential Output Voltage, VOD (or Differential Output Swing):
The differential output voltage (or swing) of the transmitter , VOD, is defined as the
difference of the two complimentary output voltages: VSDn_TX – VSDn_TX. The
VOD value can be either positive or negative.
Differ ential Input Voltage, VID (or Differen tia l Input Swing):
The differential input voltage (or swing) of the r eceiver, V ID, is defined as the
difference of the two complimentary input voltages: VSDn_RX – VSDn_RX. The
VID value can be either positive or negative.
Differ en tial Peak Voltage, VDIFFp
The peak value of the differential transmitter output s ignal or the differential
receiver input signal is defined as differential peak voltage, VDIFFp = |A – B| volts.
Differ ential Peak-to-Peak, VDIFFp-p
Since the differential output signal of the transmitter and the differential input
signal of the receiver each range from A – B to –(A – B) volts , the peak-to-peak
value of the diff erential transmitter output signal or the dif ferential receiver input
Differential Swing, VID or VOD = A – B
A Volts
B Volts
SDn_TX or
SDn_RX
SDn_TX or
SDn_RX
Differential Peak Voltage, VDIFFp = |A - B|
Differential Peak-Peak Voltage, VDIFFpp = 2 ×VDIFFp (not shown)
Vcm = (A + B) ÷ 2
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 59
High-Speed Serial Interfaces (HSSI)
signal is defined as differential peak-to-peak voltage,
VDIFFp-p =2×VDIFFp =2×|(A – B)| volts, which is twice of differential swing in
amplitude, or twice of the differential peak. For example, the output differential
peak-peak voltage can also be calculated as VTX-DIFFp-p = 2 ×|VOD|.
Differ ential Waveform
The differential waveform is constructed by subtracting the inverting signal
(SDn_TX, for example) from the non-inverting signal (SDn_TX, for example)
within a differential pair. There is only one signal trace curve in a differential
waveform. The voltage represented in the dif ferential waveform is not referenced
to ground. Refer to Figure 47 as an example for differential waveform.
Common Mode Voltage, Vcm
The common mode voltage is equal to one half of the sum of the voltages between
each conductor of a balanced interchange circuit and ground. In this example, for
SerDes output, V cm_out = (VSDn_TX + V
SDn_TX)÷2 = (A + B) ÷2, which is the
arithmetic mean of the two complimentary output voltages within a differential
pair. In a system, the common mode voltage may often differ from one
component’s output to the other’s input. Sometimes, it may be even different
between the receiver input and driver output circuits within the same component.
It is also referred as the DC offset in some occasion.
To illustrate these definitions using real values, consider the case of a current mode logic (CML)
transmitter that has a common mode voltage of 2.25 V and each of its outputs, TD and TD, has a swing
that goes between 2.5 V and 2.0 V. Using these values, the peak-to-peak voltage swing of each signal (TD
or TD) is 500 mV p-p, which is referred as the single-ended swing for each signal. In this example, since
the differential signaling environment is fully symmetrical, the transmitter output’s differential swing
(VOD) has the same amplitude as each signal’s single-ended swing. The differential output signal ranges
between 500 mV and –500 mV, in other words, VOD is 500 mV in one phase and –500 mV in the other
phase. The peak dif ferential voltage (VDIFFp) i s 500 mV. The peak-to-peak dif ferential voltage (VDIFFp-p)
is 1000 mV p-p.
13.2 SerDes Reference Clocks
The SerDes reference clock inputs are applied to an internal PLL whose output creates the clock used by
the corresponding SerDes lanes. The SerDes reference clocks inputs are SDn_REF_CLK and
SDn_REF_CLK for PCI Express and Serial RapidIO.
The following sect ions describe the SerDes re ference clock requi rements and some application
information.
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
60 Freescale Semiconductor
High-Speed Serial Interfaces (HSSI)
13.2.1 SerDes Reference Clock Receiver Characteristics
Figure 39 shows a receiver reference diagram of the SerDes reference clocks.
• The supply voltage r equirements for XVDD_SRDSn are specified in Table 1 and Table 2.
• SerDes Ref er ence Cl ock Recei ver Ref er ence Cir cui t Structure
—The SDn_RE F_CLK and SDn_REF_CLK are internally AC-coupled dif ferential inputs as
shown in Figure 39. Each differential clock input (SDn_REF_CLK or SDn_REF_CLK) ha s a
50-Ω termination to SGND followed by on-ch ip AC-coupling.
— The external reference clock driver must be able to drive this termination.
— The SerDes reference clock input can be either differential or single-ended. Refer to the
Dif ferential Mode and Single-ended Mode description below for further detailed requirements.
• The maximum average current requir em ent that also determines the common mode voltage range
— When the SerDes reference clock differential inputs are DC coupled externally with the clock
driver chip, the maximum average current allowed for each input pin is 8 mA. In this case, the
exact common mode input voltage is not critical as long as it is within the range allowed by the
maximum average current of 8 mA (refer to the following bullet for more detail ), since the
input is AC-coupled on-chip.
— This current limitation sets the maximum common mode input voltage to be less than 0.4 V
(0.4 V ÷50 = 8 mA) while the minimum common mode input level is 0.1 V above SGND. For
example, a clock with a 50/50 duty cycle can be produced by a clock driver with output driven
by its current source from 0 mA to 16 mA (0–0.8 V), such that each phase of the differ ential
input has a single-ended swing from 0 V to 800 mV with the common mode voltage at 400 mV.
— If the device driving the SDn_REF_CLK and SD n_REF_CLK inputs cannot drive 50 Ω to
SGND DC, or it exceeds the maximum input current limitations, then it must be AC-coupled
off-chip.
• The input amplitude requirement
— This requirement is described in detail in the following sections.
Figure 39. Receiver of SerDes Reference Clocks
Input
Amp
50 W
50 W
SD
n
_REF_CLK
SD
n
_REF_CLK
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 61
High-Speed Serial Interfaces (HSSI)
13.2.2 DC Level Requirement for SerDes Reference Clocks
The DC level r equirement for the MPC8640D SerDes reference clock inputs is different depending on the
signaling mode used to connect the clock driver chip and SerDes reference clock inputs as described
below.
• Differential Mode
— The input amplitude of the differential clock must be between 400 mV and 1600 mV
differential peak-peak (or between 200 mV and 800 mV differential peak). In other words,
each signal wire of the differential pair must have a single-ended swing less than 800 mV and
greater than 200 mV. This requirement is the same for both external DC-coupled or
AC-coupled connection.
— For external DC-coupled connection, as described in section 13.2.1, the maximum aver age
curr e nt require me nts sets the requireme nt for average voltage (common mode voltage) to be
between 100 mV and 400 mV. Figure 40 shows the SerDes reference clock input requirement
for DC-coupled connection scheme.
— For external AC-coupled connection, there is no common mode voltage requirement for the
clock driver. Since the external AC- coupli ng capacitor blocks the DC level, the clock driver
and the SerDes reference clock receiver operate in different command mode voltages. The
SerDes reference clock receiver in this connection scheme has its common mode voltage set to
SGND. Each signal wire of the diff e rential inputs is allowed to swing below and above the
command mode voltage (SGND). Figure 41 shows the SerDes reference clock input
requirement for AC-coupled connection scheme.
• Si ngle -ende d Mo de
— The reference clock can also be single-ended. The SDn_R EF_CLK input amplitude
(single-ended swing) must be between 400 mV and 800 mV peak-peak (from Vmin to Vmax)
with SDn_REF_CLK either left unconnected or tied to ground.
—The SDn_REF_CLK input average voltage must be between 200 and 400 mV. Figure 42 shows
the SerDes reference clock input requirement for single-ended signaling mode.
— To meet the input amplit ude requirement, the reference clock inputs might need to be DC or
AC-coupled externally . For the best noise performance, the reference of the clock could be DC
or AC-coupled int o the unused phase (SDn_REF_CLK) through the same source impedance as
the clock input (SDn_REF_CLK) in use.
Figure 40. Differential Reference Clock Input DC Requirements (External DC-Coupled)
SD
n
_REF_CLK
SD
n
_REF_CLK
Vmax < 800mV
Vmin > 0V
100mV < Vcm < 400mV
200mV < Input Amplitude or Differential Peak < 800mV
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
62 Freescale Semiconductor
High-Speed Serial Interfaces (HSSI)
Figure 41. Differential Reference Clock Input DC Requirements (External AC-Coupled)
Figure 42. Single-Ended Reference Clock Input DC Requirements
13.2.3 Interfacing With Other Differential Signaling Levels
The following list explains characteristics of interfacing with other differential signaling levels.
• W ith on-chip termination to SGND, the dif ferential reference clocks inputs are HCSL (high-speed
current steering logic) compatible DC-coupled.
• Many other low voltage differential type outputs like LVDS (low voltage differential signaling) can
be used but may need to be AC-coupled due to the limited common mode input range allowed (100
to 400 mV) for DC-coupled connection.
• LVPECL outputs can produce signal with too large amplitude. It may need to be DC-biased at
clock driver output first and followed with series attenuation resistor to reduce the amplitude, in
addition to AC-coupling.
SD
n
_REF_CLK
SD
n
_REF_CLK
Vcm
200mV < Input Amplitude or Differential Peak < 800mV
Vmax < Vcm + 400 mV
Vmin > Vcm – 400 mV
SD
n
_REF_CLK
SD
n
_REF_CLK
400 mV < SD
n
_REF_CLK Input Amplitude < 800 mV
0V
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 63
High-Speed Serial Interfaces (HSSI)
Figure 43 shows the SerDes reference clock connection reference circuits for HCSL type clock driver. It
assumes that the DC levels of the clock driver chip is compatible with MPC8640D SerDes reference clock
input’s DC requirement.
NOTE
Figure 43–Figure 46 are for conceptual reference only. Due to the
differences in the cloc k driver chip’s interna l struct ur e, output impedance,
and termination requirements among various clock driver chip
manufacturers, the clock circuit reference designs provided by clock driver
chip vendor may be different from what is shown above. They may also vary
from one vendor to the other. Therefore, Freescale Semiconductor can
neither provide the optimal clock driver reference circuits, nor guarantee the
correctness of the following clock driver connection reference circuits. The
system designer is recommended to contact the selected clock driver chip
vendor for the optimal reference circuits with the MPC8640D SerDes
reference clock receiver requirement provided in this document.
Figure 43. DC-Coupled Differential Connection with HCSL Clock Driver (Reference Only)
Figure 44 shows the SerDes reference clock connection reference circuits for LVDS type clock driver.
Since LVDS clock driver’s common mode voltage is higher than the MPC8640D SerDes reference clock
input’s allowed range (100 to 400mV), AC-coupled connection scheme must be used. It assumes the
50 Ω
50 Ω
SD
n
_REF_CLK
SD
n
_REF_CLK
Clock Driver 100 Ω differential PWB trace
Clock driver vendor dependent
source termination resistor
SerDes Refer.
CLK Receiver
Clock Driver
CLK_Out
CLK_Out
HCSL CLK Driver Chip
33 Ω
33 Ω
Total 50 Ω. Assume clock driver’s
output impedance is about 16 Ω.
MPC8640D
CLK_Out
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
64 Freescale Semiconductor
High-Speed Serial Interfaces (HSSI)
LVDS output driver features 50-Ω termination res istor. It also assumes that the LVDS transmitter
establishes its own common mode level without relying on the receiver or other external component.
Figure 44. AC-Coupled Differential Connection with LVDS Clock Driver (Reference Only)
Figure 45 shows the SerDes reference clock connection reference circuits for LVPECL type clock driver.
Since LVPECL driver’ s DC levels (both common mode voltages and output swing) are incompatible with
MPC8640D SerDes reference clock input’s DC requirement, AC-coupling has to be used. Figure 45
assumes that the LVPEC L clock driver’s output impedance is 50 Ω. R1 is used to DC-bias the LVPECL
outputs prior to AC-coupling. Its value could be ranged from 140 Ω to 240 Ω depending on clock driver
vendor’s requirement. R2 is used together with the SerDes reference clock receiver’s 50-Ω termination
resistor to attenuate the LVPECL output’ s differential peak level such that it meets the MPC8640D SerDes
reference clock’s differential input amplitude requirement (between 200 mV and 800 mV differential
peak). For example, if the LVPECL output’s differential peak is 900 mV and the desired SerDes reference
clock input amplitude is selected as 600 mV, the attenuation factor is 0. 67, which requires R2 = 25 Ω.
50 Ω
50 Ω
SD
n
_REF_CLK
SD
n
_REF_CLK
Clock Driver 100 Ω differential PWB trace SerDes Refer.
CLK Receiver
Clock Driver
CLK_Out
CLK_Out
LVDS CLK Driver Chip
10 nF
10 nF
MPC8640D
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 65
High-Speed Serial Interfaces (HSSI)
Please consult with the clock dr iver chip manufacturer to verify whether this connection scheme is
compatible with a particular clock driver chip.
Figure 45. AC-Coupled Differential Connection with LVPECL Clock Driver (Reference Only)
Figure 46 s hows the SerDes reference clock connection reference circuits for a single-ended clock driver.
It assumes the DC levels of the clock driver are compatible with MPC8640D SerDes reference clock
input’s DC requirement.
Figure 46. Single-Ended Connection (Reference Only)
13.2.4 AC Requirements for SerDes Reference Clocks
The clock driver selected should provide a high quality reference clock with low phase noise and
cycle-to-cycle jitter . Phase noise less than 100 kHz can be tracked by the PLL and data recovery loops and
is less of a problem. P hase noise above 15 MHz is filtered by the PLL. The most problematic phase noise
50 Ω
50 Ω
SD
n
_REF_CLK
SD
n
_REF_CLK
Clock Driver 100 Ω differential PWB trace SerDes Refer.
CLK Receiver
Clock Driver
CLK_Out
CLK_Out
LVPECL CLK
Driver Chip
R2
R2
R1
MPC8640D
R1
10nF
10nF
10nF
50 Ω
50 Ω
SD
n
_REF_CLK
SD
n
_REF_CLK
100 Ω differential PWB trace SerDes Refer.
CLK Receiver
Clock Driver
CLK_Out
Single-Ended
CLK Driver Chip MPC8640D
33 Ω
Tot a l 50 Ω. Assume clock driver’s
output impedance is about 16 Ω.
50 Ω
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
66 Freescale Semiconductor
High-Speed Serial Interfaces (HSSI)
occurs in the 1–15 MHz range. The source impedance of the clock driver should be 50 Ω to match the
transmission line and reduce reflections which are a source of noise to the system.
Table 47 describes some AC parameters common to PCI Express and Serial RapidIO protocols.
Figure 47. Differential Measurement Points for Rise and Fall Time
Table 47. SerDes Reference Clock Common AC Parameters
At recommended operating conditions with XVDD_SRDS1 or XVDD_SRDS2 = 1.1 V ± 5% and 1.05 V ± 5%.
Parameter Symbol Min Max Unit Notes
Rising Edge Rate Rise Edge Rate 1.0 4.0 V/ns 2, 3
Falling Edge Rate Fall Edge Rate 1.0 4.0 V/ns 2, 3
Differential Input High Voltage VIH +200 — mV 2
Differential Input Low Voltage VIL — –200 mV 2
Rising edge rate (SD
n
_REF_CLK) to falling edge rate
(SD
n
_REF_CLK) matching
Rise-Fall
Matching
—20%1, 4
Notes:
1. Measurement taken from single-ended waveform.
2. Measurement taken from differential waveform.
3. Measured from –200 mV to +200 mV on the differential waveform (derived from SD
n
_REF_CLK minus SD
n
_REF_CLK). The
signal must be monotonic through the measurement region for rise and fall time. The 400 mV measurement window is centered
on the differential zero crossing. See Figure 47.
4. Matching applies to the rising edge rate for SD
n
_REF_CLK and falling edge rate for SD
n
_REF_CLK. It is measured using a
200 mV window centered on the median cross point where SDn_REF_CLK rising meets SD
n
_REF_CLK falling. The median
cross point is used to calculate the voltage thresholds the oscilloscope is to use for the edge rate calculations. The rising edge
rate of SD
n
_REF_CLK should be compared to the falling edge rate of SD
n
_REF_CLK, and the maximum allowed difference
should not exceed 20% of the slowest edge rate. See Figure 48.
VIH = +200 mV
VIL = –200 mV
0.0 V
SD
n
_REF_CLK
minus
SD
n
_REF_CLK
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 67
High-Speed Serial Interfaces (HSSI)
Figure 48. Single-Ended Measurement Points for Rise and Fall Time Matching
The other detailed AC requirements of the SerD es re ference clocks is defined by each interface protocol
based on application usage. Refer to the following sections for detailed information:
•Section 14.2, “AC Requirements for PCI Express SerDes Clocks”
•Section 15.2, “AC Requirements for Serial RapidIO SDn_REF_CLK and SDn_REF_CLK”
13.3 SerDes Transmitter and Receiver Reference Circuits
Figure 49 s hows t he refere nce circuits for SerDes data lane’s transm itter and receiver.
Figure 49. SerDes Transmitter and Receiver Reference Circuits
The DC and AC specification of SerDes data lanes are defined in each interf ace protocol sec t ion below
(PCI Express or Serial Rapid IO) in this document based on the application usage:
•Section 14, “PCI Express”
•Section 15, “Serial RapidIO”
Note that external AC Coupling capacitor is required for the above two serial transmission protocols with
the capacitor value defi ned in specification of each protocol section.
SD
n
_REF_CLK
SD
n
_REF_CLK
SD
n
_REF_CLK
SD
n
_REF_CLK
50 Ω
50 ΩReceiver
Transmitter
SD1_TX
n
or
SD2_TX
n
SD1_TX
n
or
SD2_TX
n
SD1_RX
n
or
SD2_RX
n
SD1_RX
n
or
SD2_RX
n
50 Ω
50 Ω
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
68 Freescale Semiconductor
PCI Express
14 PCI Express
This section describes the DC and AC electrical specifications for the PCI Express bus of the MPC8640.
14.1 DC Requirements for PCI Express SD
n
_REF_CLK and
SD
n
_REF_CLK
Fo r more i nform a t i on, se e Section 13.2, “SerDes Reference Clocks.”
14.2 AC Requirements for PCI Express SerDes Clocks
Table 48 lists AC requirement s.
14.3 Clocking Dependencies
The ports on the two ends of a link must transmit data at a rate that is within 600 parts per million (ppm)
of each other at all times. This is specified to allow bit rate clock sources with a ± 300 ppm tolerance.
14.4 Physical Layer Specifications
The following is a summary of the speci fications for the physical layer of PCI Express on this device. For
furthe r deta ils a s well as the spec if ications of the tra nsport and data link la ye r plea s e u se the PC I E xpre s s
Base Specification, Rev. 1.0a document.
14.4.1 Differential Transmitter (Tx) Output
Table 49 defines the specifications for the differential output at all transmitters. The parameters are
specified at the component pins .
Table 48. SD
n
_REF_CLK and SD
n
_REF_CLK AC Requirements
Parameter Symbol Min Typical Max Units Notes
REFCLK cycle time tREF —10 —ns —
REFCLK cycle-to-cycle jitter. Difference in the period of any two
adjacent REFCLK cycles
tREFCJ ——100ps —
Phase jitter. Deviation in edge location with respect to mean edge
location
tREFPJ –50 — 50 ps —
Table 49. Differential Transmitter Output Specifications
Parameter Symbol Min Nom Max Units Notes
Unit Interval UI 399.88 400 400.12 ps Each UI is 400 ps ± 300 ppm. UI does not account for
spread spectrum clock dictated variations. See Note 1.
Differential
Peak-to-Peak
Output Voltage
VTX-DIFFp-p 0.8 — 1.2 V VTX-DIFFp-p = 2 ×|VTX-D+ –V
TX-D-| See Note 2.
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 69
PCI Express
De- Emphasized
Differential
Output Voltage
(Ratio)
VTX-DE-RATIO –3.0 –3.5 –4.0 dB Ratio of the VTX-DIFFp-p of the second and following bits
after a transition divided by the VTX-DIFFp-p of the first
bit after a transition. See Note 2.
Minimum TX Eye
Width
TTX-EYE 0.70 — — UI The maximum Transmitter jitter can be derived as
TTX-MAX-JITTER = 1 – TTX-EYE = 0.3 UI.
See Notes 2 and 3.
Maximum time
between the jitter
median and
maximum
deviation from
the median.
TTX-EYE-MEDIAN-to-
MAX-JITTER
— — 0.15 UI Jitter is defined as the measurement variation of the
crossing points (VTX-DIFFp-p = 0 V) in relation to a
recovered Tx UI. A recovered Tx UI is calculated over
3500 consecutive unit intervals of sample data. Jitter is
measured using all edges of the 250 consecutive UI in
the center of the 3500 UI used for calculating the Tx UI.
See Notes 2 and 3.
D+/D– Tx Output
Rise/Fall Time
TTX-RISE, TTX-FALL 0.125 — — UI See Notes 2 and 5
RMS AC Peak
Common Mode
Output Voltage
VTX-CM-ACp ——20mVV
TX-CM-ACp = RMS(|VTXD+ + VTXD-|/2 – VTX-CM-DC)
VTX-CM-DC = DC(avg) of |VTX-D+ + VTX-D–|/2
See Note 2
Absolute Delta of
DC Common
Mode Voltage
During L0 and
Electrical Idle
VTX-CM-DC-ACTIVE-
IDLE-DELTA
0 — 100 mV |VTX-CM-DC (during L0) – VTX-CM-Idle-DC (During Electrical
Idle)|≤100 mV
VTX-CM-DC = DC(avg) of |VTX-D+ + VTX-D-|/2 [L0]
VTX-CM-Idle-DC = DC(avg) of |VTX-D+ + VTX-D–|/2
[Electrical Idle]
See Note 2.
Absolute Delta of
DC Common
Mode between
D+ and D–
VTX-CM-DC-LINE-DELTA 0—25mV|V
TX-CM-DC-D+ – VTX-CM-DC-D-| ≤ 25 mV
VTX-CM-DC-D+ = DC(avg) of |VTX-D+|
VTX-CM-DC-D– = DC(avg) of |VTX-D–|
See Note 2.
Electrical Idle
differential Peak
Output Voltage
VTX-IDLE-DIFFp 0—20mVV
TX-IDLE-DIFFp = |VTX-IDLE-D+ -VTX-IDLE-D–| ≤ 20 mV
See Note 2.
The amount of
voltage change
allowed during
Receiver
Detection
VTX-RCV-DETECT — — 600 mV The total amount of voltage change that a transmitter
can apply to sense whether a low impedance receiver
is present. See Note 6.
The Tx DC
Common Mode
Voltage
VTX-DC-CM 0 — 3.6 V The allowed DC common mode voltage under any
conditions. See Note 6.
Tx Short Circuit
Current Limit
ITX-SHORT — 90 mA The total current the transmitter can provide when
shorted to its ground
Minimum time
spent in
electrical idle
TTX-IDLE-MIN 50 — UI Minimum time a transmitter must be in electrical idle.
Utilized by the receiver to start looking for an electrical
idle exit after successfully receiving an electrical idle
ordered set.
Table 49. Differential Transmitter Output Specifications (continued)
Parameter Symbol Min Nom Max Units Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
70 Freescale Semiconductor
PCI Express
Maximum time to
transition to a
valid electrical
idle after sending
an electrical idle
ordered set
TTX-IDLE-SET-TO-IDLE — — 20 UI After sending an electrical idle ordered set, the
transmitter must meet all electrical idle specifications
within this time. This is considered a debounce time for
the transmitter to meet electrical idle after transitioning
from L0.
Maximum time to
transition to valid
Tx specifications
after leaving an
electrical idle
condition
TTX-IDLE-TO-DIFF-DATA — — 20 UI Maximum time to meet all Tx specifications when
transitioning from electrical idle to sending differential
data. This is considered a debounce time for the Tx to
meet all Tx specifications after leaving electrical idle
Differential
Return Loss
RLTX-DIFF 12 — — dB Measured over 50 MHz to 1.25 GHz. See Note 4
Common Mode
Return Loss
RLTX-CM 6 — — dB Measured over 50 MHz to 1.25 GHz. See Note 4
DC Differential
TX Impedance
ZTX-DIFF-DC 80 100 120 ΩTX DC differential mode low impedance
Transmitter DC
Impedance
ZTX-DC 40 — — ΩRequired TX D+ as well as D– DC impedance during
all states
Lane-to-Lane
Output Skew
LTX-SKEW — — 500 +
2 UI
ps Static skew between any two transmitter lanes within a
single link
AC Coupling
Capacitor
CTX 75 — 200 nF All transmitters shall be AC coupled. The AC coupling
is required either within the media or within the
transmitting component itself. See Note 8.
Crosslink
Random
Timeout
Tcrosslink 0 — 1 ms This random timeout helps resolve conflicts in crosslink
configuration by eventually resulting in only one
downstream and one upstream port. See Note 7.
Notes:
1. No test load is necessarily associated with this value.
2. Specified at the measurement point into a timing and voltage compliance test load as shown in Figure 52 and measured over
any 250 consecutive Tx UIs. (Also refer to the transmitter compliance eye diagram shown in Figure 50)
3. A TTX-EYE = 0.70 UI provides for a total sum of deterministic and random jitter budget of TTX-JITTER-MAX = 0.30 UI for the
transmitter collected over any 250 consecutive Tx UIs. The TTX-EYE-MEDIAN-to-MAX-JITTER median is less than half of the total
TX jitter budget collected over any 250 consecutive Tx UIs. It should be noted that the median is not the same as the mean.
The jitter median describes the point in time where the number of jitter points on either side is approximately equal as opposed
to the averaged time value.
4. The transmitter input impedance shall result in a differential return loss greater than or equal to 12 dB and a common mode
return loss greater than or equal to 6 dB over a frequency range of 50 MHz to 1.25 GHz. This input impedance requirement
applies to all valid input levels. The reference impedance for return loss measurements is 50 Ω to ground for both the D+ and
D– line (that is, as measured by a Vector Network Analyzer with 50 Ω probes—see Figure 52). Note that the series capacitors
CTX is optional for the return loss measurement.
5. Measured between 20–80% at transmitter package pins into a test load as shown in Figure 52 for both VTX-D+ and VTX-D–.
6. See Section 4.3.1.8 of the PCI Express Base Specifications Rev 1.0a
7. See Section 4.2.6.3 of the PCI Express Base Specifications Rev 1.0a
8. MPC8640D SerDes transmitter does not have CTX built-in. An external AC coupling capacitor is required.
Table 49. Differential Transmitter Output Specifications (continued)
Parameter Symbol Min Nom Max Units Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 71
PCI Express
14.4.2 Transmitter Compliance Eye Diagrams
The Tx eye diagram in Figure 50 is specified using the passive compliance/test measurement load (see
Figure 52) in place of any real PCI Express interconnect + Rx co mponent.
There are two eye diagrams that must be met for the transmitter. Both e ye diagrams must be a ligned in
time using the jitter median to locat e the ce nte r of the ey e dia gr am. T h e diff ere nt ey e dia gra ms will differ
in voltage depending whether it is a transition bit or a de-emphasized bit. The exact reduced voltage level
of the de -emphasized bit will always be relative to the transition bit.
The eye diagram must be valid for any 250 consecutive UIs.
A recovered Tx UI is calculated over 3500 consecutive unit intervals of sample data. The eye diagram is
created using all edges of the 250 consecutive UI in the center of the 3500 UI used for calculating the TX
UI.
NOTE
It is recommended that the r ecovered Tx UI is calculated using all edges in
the 3500 consecutive UI interval with a fit algorithm using a minimization
merit function (that is, least squares and median deviation fits).
Figure 50. Minimum Transmitter Timing and Voltage Output Compliance Specifications
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
72 Freescale Semiconductor
PCI Express
14.4.3 Differential Receiver (Rx) Input Specifications
Table 50 defines the specifications for the dif ferential input at all receivers. The parameters are specified
at the component pins.
Table 50. Differential Receiver Input Specifications
Parameter Symbol Min Nom Max Units Comments
Unit Interval UI 399.88 400 400.12 ps Each UI is 400 ps ± 300 ppm. UI does not
account for spread spectrum clock dictated
variations. See Note 1.
Differential
Peak-to-Peak
Output Voltage
VRX-DIFFp-p 0.175 — 1.200 V VRX-DIFFp-p = 2 ×|VRX-D+ – VRX-D–|
See Note 2.
Minimum
Receiver Eye
Width
TRX-EYE 0.4 — — UI The maximum interconnect media and
transmitter jitter that can be tolerated by the
receiver can be derived as TRX-MAX-JITTER =
1 – TRX-EYE = 0.6 UI.
See Notes 2 and 3.
Maximum time
between the jitter
median and
maximum
deviation from
the median.
TRX-EYE-MEDIAN-to-MAX
-JITTER
— — 0.3 UI Jitter is defined as the measurement variation
of the crossing points (VRX-DIFFp-p = 0 V) in
relation to a recovered Tx UI. A recovered Tx
UI is calculated over 3500 consecutive unit
intervals of sample data. Jitter is measured
using all edges of the 250 consecutive UI in
the center of the 3500 UI used for calculating
the Tx UI. See Notes 2, 3 and 7.
AC Peak
Common Mode
Input Voltage
VRX-CM-ACp ——150 mVV
RX-CM-ACp = |VRXD+ – VRXD-|/2 – VRX-CM-DC
VRX-CM-DC = DC(avg) of |VRX-D+ – VRX-D–|/2
See Note 2
Differential
Return Loss
RLRX-DIFF 15 — — dB Measured over 50 MHz to 1.25 GHz with the
D+ and D– lines biased at +300 mV and
–300 mV, respectively.
See Note 4
Common Mode
Return Loss
RLRX-CM 6 — — dB Measured over 50 MHz to 1.25 GHz with the
D+ and D– lines biased at 0 V. See Note 4
DC Differential
Input Impedance
ZRX-DIFF-DC 80 100 120 ΩRx DC Differential mode impedance. See
Note 5
DC Input
Impedance
ZRX-DC 40 50 60 ΩRequired Rx D+ as well as D– DC impedance
(50 ± 20% tolerance). See Notes 2 and 5.
Powered Down
DC Input
Impedance
ZRX-HIGH-IMP-DC 200 — — kΩRequired Rx D+ as well as D– DC impedance
when the receiver terminations do not have
power. See Note 6.
Electrical Idle
Detect Threshold
VRX-IDLE-DET-DIFFp-p 65 — 175 mV VRX-IDLE-DET-DIFFp-p = 2 ×|VRX-D+ –VRX-D–|
Measured at the package pins of the receiver
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 73
PCI Express
14.5 Receiver Compliance Eye Diagrams
The Rx eye diagram in Figure 51 is specified using the passive compliance/t est me asur ement loa d (see
Figure 52) in place of any real PCI Express Rx component.
Note tha t i n gene ral, the minimum receiver eye diagram me as ure d with the complianc e/te st mea sur ement
load (see Figure 52) is larger than the minimum receiver eye diagram measured over a r ange of systems at
the input receiver of any real PCI Express component. The degraded eye diagram at the input receiver is
due to traces internal to the package as well as silicon parasitic characteristics which cause the real PCI
Express component to vary in impedance from the compliance/test measurement load. T he i nput receiver
eye diagram is implementation specific and is not s pecified. A Rx component designer should provide
Unexpected
Electrical Idle
Enter Detect
Threshold
Integration Time
TRX-IDLE-DET-DIFF-
ENTERTIME
— — 10 ms An unexpected electrical Idle (VRX-DIFFp-p <
VRX-IDLE-DET-DIFFp-p) must be recognized no
longer than TRX-IDLE-DET-DIFF-ENTERING to
signal an unexpected idle condition.
Tot a l Skew LTX-SKEW — — 20 ns Skew across all lanes on a link. This includes
variation in the length of SKP ordered set (for
example, COM and one to five symbols) at
the Rx as well as any delay differences arising
from the interconnect itself.
Notes:
1. No test load is necessarily associated with this value.
2. Specified at the measurement point and measured over any 250 consecutive UIs. The test load in Figure 52 should be used
as the Rx device when taking measurements (also refer to the Receiver compliance eye diagram shown in Figure 51). If the
clocks to the Rx and Tx are not derived from the same reference clock, the Tx UI recovered from 3500 consecutive UI must
be used as a reference for the eye diagram.
3. A TRX-EYE = 0.40 UI provides for a total sum of 0.60 UI deterministic and random jitter budget for the transmitter and
interconnect collected any 250 consecutive UIs. The TRX-EYE-MEDIAN-to-MAX-JITTER specification ensures a jitter distribution in
which the median and the maximum deviation from the median is less than half of the total. UI jitter budget collected over any
250 consecutive Tx UIs. It should be noted that the median is not the same as the mean. The jitter median describes the point
in time where the number of jitter points on either side is approximately equal as opposed to the averaged time value. If the
clocks to the Rx and Tx are not derived from the same reference clock, the Tx UI recovered from 3500 consecutive UI must
be used as the reference for the eye diagram.
4. The receiver input impedance shall result in a differential return loss greater than or equal to 15 dB with the D+ line biased to
300 mV and the D– line biased to –300 mV and a common mode return loss greater than or equal to 6 dB (no bias required)
over a frequency range of 50 MHz to 1.25 GHz. This input impedance requirement applies to all valid input levels. The
reference impedance for return loss measurements for is 50 Ω to ground for both the D+ and D– line (that is, as measured by
a vector network analyzer with 50-Ω probes, see Figure 52). Note that the series capacitors CTX is optional for the return loss
measurement.
5. Impedance during all LTSSM states. When transitioning from a fundamental reset to detect (the initial state of the LTSSM)
there is a 5 ms transition time before receiver termination values must be met on all unconfigured lanes of a port.
6. The Rx DC common mode impedance that exists when no power is present or fundamental reset is asserted. This helps
ensure that the receiver detect circuit will not falsely assume a receiver is powered on when it is not. This term must be
measured at 300 mV above the Rx ground.
7. It is recommended that the recovered Tx UI is calculated using all edges in the 3500 consecutive UI interval with a fit algorithm
using a minimization merit function. Least squares and median deviation fits have worked well with experimental and simulated
data.
Table 50. Differential Receiver Input Specifications (continued)
Parameter Symbol Min Nom Max Units Comments
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
74 Freescale Semiconductor
PCI Express
additional margin to adequately compensate for the degraded minimum Rx eye diagram (shown in
Figure 51) expected at the input receiver based on some adequate combination of system simulations and
the re turn loss m easure d looking into the Rx pa cka ge and s ilic on. T he Rx ey e dia gram must be a ligned in
time using the jitter media n to locate the center of the eye diagram.
The eye diagram must be valid for any 250 consecutive UIs.
A recovered TX UI is calculated over 3500 consecutive unit intervals of sample data. The eye diagram is
created using all edges of the 250 consecutive UI in the center of the 3500 UI used for calculating the TX
UI.
NOTE
The reference impedance for return loss measurements is 50Ω to ground for
both the D+ and D– line (th at is, as measured by a vector network analyzer
with 50-Ω probes—see Figure 52). Note that the series capacitors, CTX, ar e
optional for the return loss measureme nt.
Figure 51. Minimum Receiver Eye Timing and Voltage Compliance Specification
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 75
Serial RapidIO
14.5.1 Compliance Test and Measurement Load
The AC timing and voltage parameters must be verified at the measurement point, as specified within 0.2
inches of the package pins, into a test/measurement load shown in Figure 52.
NOTE
The allowance of the measurement point to be within 0.2 inches of the
package pins is meant to acknowledge that package/board routing may
benefit from D+ and D– not being exactly matched in length a t the package
pin boundary.
Figure 52. Compliance Test/Measurement Load
15 Serial RapidIO
This section describes the DC and AC electrical specifications for the RapidIO int erface of the MPC8640 ,
for the LP-Serial physical layer. The electrical specifications cover both single and multiple-lane links.
Two transmitter types (short run and long run) on a single receiver are specified for each of three baud
rates, 1.25, 2.50, and 3.125 GBaud.
Two transm itter specifications allow for solutions ranging from simple board-to-board interconnect to
driving t wo connectors across a backplane. A single r eceiver specification is given that will accept signals
from both the short run and long run transmitter specifications.
The short run transmitter specifications should be used mainly for chip-to-chip connections on either the
same printed circuit board or across a single connector. This covers the case where connections are made
to a mezzanine (daughter) card. The minimum swings of the short run specification reduce the overall
power used by the transceivers.
The long run transmitter specifications use larger voltage swings t hat are capable of driving s ignals across
backplanes. This allows a user to drive signals across two connectors and a backplane. The specifications
allow a distance of at least 50 cm at all baud rates.
All unit intervals are specified with a tolerance of ± 100 ppm. The worst case frequency difference between
any transmit and receive clock will be 200 ppm.
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
76 Freescale Semiconductor
Serial RapidIO
To ensure interoperability between drivers and receivers of diff erent vendors and technologies, AC
coupling at the r ece iver input must be used.
15.1 DC Requirements for Serial RapidIO SD
n
_REF_CLK and
SD
n
_REF_CLK
Fo r more i nform a t i on, se e Section 13.2, “SerDes Reference Clocks.”
15.2 AC Requirements for Serial RapidIO SD
n
_REF_CLK and
SD
n
_REF_CLK
Table 51 lists AC requirement s.
15.3 Signal Definitions
LP-Ser ia l links use differentia l signaling . This section defines terms used in the description and
specification of differ ential signals. Figure 53 shows how the signals are defined. The figures show
wavefor ms for eithe r a transmitte r output (T D and TD) or a receiver input (RD and RD). Each signal
swings between A volts and B volts where A > B . Using these waveforms, the definitions are as follows:
1. The transmitter output signals and the receiver input signals TD, TD, RD and RD each have a
peak-to-peak swing of A – B volts
2. The differential output signal of the trans mitter, VOD, is defined as VTD –V
TD
3. The differential input signal of the r ece iver, VID, is defined as VRD –V
RD
4. The differential output signal of the transmitter and the dif ferential input signal of the receiver
each range from A – B to –(A – B) volts
Table 51. SD
n
_REF_CLK and SD
n
_REF_CLK AC Requirements
Symbol Parameter Description Min Typical Max Units Comments
tREF REFCLK cycle time — 10(8) — ns 8 ns applies only to serial RapidIO
with 125-MHz reference clock
tREFCJ REFCLK cycle-to-cycle jitter. Difference in the
period of any two adjacent REFCLK cycles
— — 80 ps —
tREFPJ Phase jitter. Deviation in edge location with
respect to mean edge location
–40 — 40 ps —
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 77
Serial RapidIO
5. The peak value of the differential transmitter output signal and the differential receiver input
signal is A – B volts
6. The peak-to-peak value of the dif ferentia l tran sm itter output signal and the differe ntial re cei ver
input signal is 2 ×(A – B) volts
Figure 53. Differential Peak-Peak Voltage of Transmitter or Receiver
To illustrate these definitions using real values, consider the case of a current mode logic (CML)
transmitter that has a common mode voltage of 2.25 V and each of its outputs, TD and TD, has a swing
that goes between 2.5 V and 2.0 V. Using these values, the peak-to-peak voltage swing of the signals TD
and TD is 500 mV p-p. The differential output signal ranges between 500 mV and –500 mV. The peak
differential voltage is 500 mV. The peak-to-peak differential voltage is 1000 mV p-p.
15.4 Equalization
With the use of high speed serial links, t he interconnect media causes degradation of the signal at the
receiver. Effects such as inter-symbol interference (ISI) or data-dependent jitter are produced. This loss
can be large enough to degrade the eye opening at the receiver beyond what is allowed in the specification.
To negate a portion of these effects, equalization can be used. The most common equalization techni ques
that can be used are:
• A passive high pass filter network placed at the receiver, often referred to as passi ve equalizat ion.
• The use of active circuits in the receiver, often referred to as adaptive equalization.
15.5 Explanatory Note on Transmitter and Receiver Specifications
AC electrical specifications are given for transmitter and receiver. Long run and short run interfaces at
three baud rates (a total of six cases) are described.
The parameters for the AC electrical specifications are guided by the XAUI electrical interface specified
in clause 47 of IEEE 802.3ae-2002.
XAUI has similar application goals to the serial RapidIO interface. The goal of this standard is that
electrical designs for the serial RapidIO interface can reuse electrical designs for XAUI, suitably modified
for applications at the baud intervals and reaches described herein.
Differential Peak-Peak = 2 * (A-B)
A Volts TD or RD
TD or RD
B Volts
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
78 Freescale Semiconductor
Serial RapidIO
15.6 Transmitter Specifications
LP-Serial transmitter electrica l and timing specifi cations are stated in the text and Table 52 through
Table 57.
The diff ere ntial re turn loss, S11, of the transmitter in each case sha ll be better than
• –10 dB for (Baud Frequency)/10 < Freq(f) < 625 MHz
• –10 dB + 10log(f/625 MHz) dB for 625 MHz ≤ Freq( f) ≤ B aud Frequency
The reference impedance for the differential return loss measurements is 100-Ω res isti v e. Dif fere ntia l
return loss includes contributions from on-chip circuitry, chip packaging and any off-chip components
related to the driver. The output impedance requireme nt applie s to all valid output levels .
It is recommended that the 20%–80% rise/fall time of the transmitter , as measured at the transmitter output,
in each case have a minimum value 60 ps.
It is recomme nded that the timing skew at the output of an LP-Ser ia l transmit ter between the two signals
that comprise a differential pair not exceed 25 ps at 1.25 GB, 20 ps at 2.50 GB and 15 ps at 3.125 GB.
Table 52. Short Run Transmitter AC Timing Specifications—1.25 GBaud
Parameter Symbol
Range
Unit Notes
Min Max
Output Voltage VO–0.40 2.30 Volts Voltage relative to COMMON of
either signal comprising a
differential pair
Differential Output Voltage VDIFFPP 500 1000 mV p-p —
Deterministic Jitter JD— 0.17 UI p-p —
Total Jitter JT— 0.35 UI p-p —
Multiple output skew SMO — 1000 ps Skew at the transmitter output
between lanes of a multilane link
Unit Interval UI 800 800 ps ± 100 ppm
Table 53. Short Run Transmitter AC Timing Specifications—2.5 GBaud
Parameter Symbol
Range
Unit Notes
Min Max
Output Voltage VO–0.40 2.30 Volts Voltage relative to COMMON of
either signal comprising a
differential pair
Differential Output Voltage VDIFFPP 500 1000 mV p-p —
Deterministic Jitter JD—0.17 UI p-p —
Total Jitter JT—0.35 UI p-p —
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 79
Serial RapidIO
TC: What was this? Was there a figure here?
Multiple Output skew SMO — 1000 ps Skew at the transmitter output
between lanes of a multilane link
Unit Interval UI 400 400 ps ± 100 ppm
Table 54. Short Run Transmitter AC Timing Specifications—3.125 GBaud
Parameter Symbol
Range
Unit Notes
Min Max
Output Voltage, VO–0.40 2.30 Volts Voltage relative to COMMON of
either signal comprising a
differential pair
Differential Output Voltage VDIFFPP 500 1000 mV p-p —
Deterministic Jitter JD—0.17 UI p-p —
Total Jitter JT—0.35 UI p-p —
Multiple output skew SMO — 1000 ps Skew at the transmitter output
between lanes of a multilane link
Unit Interval UI 320 320 ps ± 100 ppm
Table 55. Long Run Transmitter AC Timing Specifications—1.25 GBaud
Parameter Symbol
Range
Unit Notes
Min Max
Output Voltage, VO–0.40 2.30 Volts Voltage relative to COMMON of
either signal comprising a
differential pair
Differential Output Voltage VDIFFPP 800 1600 mV p-p —
Deterministic Jitter JD— 0.17 UI p-p —
Total Jitter JT— 0.35 UI p-p —
Multiple output skew SMO — 1000 ps Skew at the transmitter output
between lanes of a multilane link
Unit Interval UI 800 800 ps ± 100 ppm
Table 53. Short Run Transmitter AC Timing Specifications—2.5 GBaud (continued)
Parameter Symbol
Range
Unit Notes
Min Max
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
80 Freescale Semiconductor
Serial RapidIO
For each baud rate at which an LP-Serial transmitter is specified to operate, the output eye pattern of the
transmitter shall fall entirely within the unshaded portion of the transmitter output compliance mask shown
in Figure 54. This figure should be used with the parameters specified in Table 58 when m easur ed at the
output pins of the device and the device is driving a 100-Ω ± 5% differential resistive load. The output eye
pattern of an LP-Ser ia l transmitter that implements pre-emphas is (to equaliz e the link and reduce
Table 56. Long Run Transmitter AC Timing Specifications—2.5 GBaud
Parameter Symbol
Range
Unit Notes
Min Max
Output Voltage, VO–0.40 2.30 Volts Voltage relative to COMMON of
either signal comprising a
differential pair
Differential Output Voltage VDIFFPP 800 1600 mV p-p —
Deterministic Jitter JD—0.17 UI p-p —
Total Jitter JT—0.35 UI p-p —
Multiple output skew SMO — 1000 ps Skew at the transmitter output
between lanes of a multilane link
Unit Interval UI 400 400 ps ± 100 ppm
Table 57. Long Run Transmitter AC Timing Specifications—3.125 GBaud
Parameter Symbol
Range
Unit Notes
Min Max
Output Voltage, VO–0.40 2.30 Volts Voltage relative to COMMON
of either signal comprising a
differential pair
Differential Output Voltage VDIFFPP 800 1600 mV p-p —
Deterministic Jitter JD— 0.17 UI p-p —
Total Jitter JT— 0.35 UI p-p —
Multiple output skew SMO — 1000 ps Skew at the transmitter output
between lanes of a multilane
link
Unit Interval UI 320 320 ps ± 100 ppm
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 81
Serial RapidIO
inter-symbol interference ) need only comply with the transmitter output compliance mask when
pre-emphasis is disabled or minimized.
Figure 54. Transmitter Output Compliance Mask
Table 58 specifies the parameters for the transmitter differential output eye diagram.
15.7 Receiver Specifications
LP-Serial receiver electrical and timing specifications are stated in the text and Table 59 through Table 61.
Receiver input impedance shall result in a differential return loss better that 10 dB and a common mode
return loss better than 6 dB from 100 MHz to (0.8) ×(Baud Frequency). This includes contributions from
on-chip circuitry, the chip package and any off- chip components related to the receiver. AC-coupling
Table 58. Transmitter Differential Output Eye Diagram Parameters
Transm itte r Type VDIFFmin (mV) VDIFFmax (mV) A (UI) B (UI)
1.25 GBaud short range 250 500 0.175 0.39
1.25 GBaud long range 400 800 0.175 0.39
2.5 GBaud short range 250 500 0.175 0.39
2.5 GBaud long range 400 800 0.175 0.39
3.125 GBaud short range 250 500 0.175 0.39
3.125 GBaud long range 400 800 0.175 0.39
0
VDIFF min
VDIFF max
–VDIFF min
–VDIFF max
0B1-B1
Time in UI
Transmitter Differential Output Voltage
A1-A
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
82 Freescale Semiconductor
Serial RapidIO
components are included in this requirement. The reference impedance for re turn loss measurements is
100-Ω resistive for differential return loss and 25-Ω r esistive for common mode.
Table 59. Receiver AC Timing Specifications—1.25 GBaud
Parameter Symbol
Range
Unit Notes
Min Max
Differential Input Voltage VIN 200 1600 mV p-p Measured at receiver
Deterministic Jitter Tolerance JD0.37 — UI p-p Measured at receiver
Combined Deterministic and Random
Jitter Tolerance
JDR 0.55 — UI p-p Measured at receiver
Total Jitter Tolerance1JT0.65 — UI p-p Measured at receiver
Multiple Input Skew SMI — 24 ns Skew at the receiver input
between lanes of a multilane
link
Bit Error Rate BER — 10–12 ——
Unit Interval UI 800 800 ps +/– 100 ppm
Note:
1. Total jitter is composed of three components, deterministic jitter, random jitter and single frequency sinusoidal jitter. The
sinusoidal jitter may have any amplitude and frequency in the unshaded region of Figure 55. The sinusoidal jitter component
is included to ensure margin for low frequency jitter, wander, noise, crosstalk and other variable system effects.
Table 60. Receiver AC Timing Specifications—2.5 GBaud
Parameter Symbol
Range
Unit Notes
Min Max
Differential Input Voltage VIN 200 1600 mV p-p Measured at receiver
Deterministic Jitter Tolerance JD0.37 — UI p-p Measured at receiver
Combined Deterministic and Random
Jitter Tolerance
JDR 0.55 — UI p-p Measured at receiver
Total Jitter Tolerance1JT0.65 — UI p-p Measured at receiver
Multiple Input Skew SMI — 24 ns Skew at the receiver input
between lanes of a multilane
link
Bit Error Rate BER — 10–12 ——
Unit Interval UI 400 400 ps ± 100 ppm
Note:
1. Total jitter is composed of three components, deterministic jitter, random jitter and single frequency sinusoidal jitter. The
sinusoidal jitter may have any amplitude and frequency in the unshaded region of Figure 55. The sinusoidal jitter component
is included to ensure margin for low frequency jitter, wander, noise, crosstalk and other variable system effects.
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 83
Serial RapidIO
Table 61. Receiver AC Timing Specifications—3.125 GBaud
Characteristic Symbol
Range
Unit Notes
Min Max
Differential Input Voltage VIN 200 1600 mV p-p Measured at receiver
Deterministic Jitter Tolerance JD0.37 — UI p-p Measured at receiver
Combined Deterministic and Random
Jitter Tolerance
JDR 0.55 — UI p-p Measured at receiver
Total Jitter Tolerance1JT0.65 — UI p-p Measured at receiver
Multiple Input Skew SMI — 22 ns Skew at the receiver input
between lanes of a multilane
link
Bit Error Rate BER — 10-12 ——
Unit Interval UI 320 320 ps ± 100 ppm
Note:
1. Total jitter is composed of three components, deterministic jitter, random jitter and single frequency sinusoidal jitter. The
sinusoidal jitter may have any amplitude and frequency in the unshaded region of Figure 55. The sinusoidal jitter component
is included to ensure margin for low frequency jitter, wander, noise, crosstalk, and other variable system effects.
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
84 Freescale Semiconductor
Serial RapidIO
Figure 55 shows the single frequency sinusoidal jitter limits .
Figure 55. Single Frequency Sinusoidal Jitter Limits
8.5 UI p-p
0.10 UI p-p
Sinusoidal
Jitter
Amplitude
22.1 kHz 1.875 MHz 20 MHz
Frequency
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 85
Serial RapidIO
15.8 Receiver Eye Diagrams
For each baud rate at which an LP-Serial recei ver is specified to operate, the receiver shall meet the
corresponding bit er ror rate specification (Table 59 thr ough Table 61) when the eye pattern of the receiver
test signal (exclusive of sinusoidal jitter) falls entirely within the unshaded portion of the shown in
Figure 56 with t he parameters specified in Table 62. The eye pattern of the receiver test signal is measured
at the input pins of the receiving dev ice with the device replaced with a 100 Ω ± 5% dif fere ntial re s istive
load.
Figure 56. Receiver Input Compliance Mask
Table 62 shows the parameters for the receiver input compliance mask exclusive of sinusoidal jitter.
Table 62. Receiver Input Compliance Mask Parameters Exclusive of Sinusoidal Jitter
Receiver Type VDIFFmin (mV) VDIFFmax (mV) A (UI) B (UI)
1.25 GBaud 100 800 0.275 0.400
2.5 GBaud 100 800 0.275 0.400
3.125 GBaud 100 800 0.275 0.400
10
VDIFF max
–VDIFF max
VDIFF min
–VDIFF min
Time (UI)
Receiver Differential Input Voltage
0
AB 1-B1-A
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
86 Freescale Semiconductor
Serial RapidIO
15.9 Measurement and Test Requirements
Since the LP-Serial electrical specificat ion are guided by the XAUI electrical interface specified in clause
47 of IEEE 802.3ae-2002, the measurement and test requirements defined here are similarly guided by
clause 47. In addition, t he CJPAT test pattern defined in Annex 48A of IEEE802.3ae-2002 is sp ecified as
the test pattern for use in eye pattern and jitter measurements. Annex 48B of IEEE802.3ae-2002 is
recommended as a reference for additional information on jitter test methods.
15.9.1 Eye Template Measurements
For the purpose of eye template measurements, the effects of a single-pole high pass filter with a 3 dB point
at (Baud Frequency) ÷1667 is applied to the jitter. The data pattern for template measurements is the
continuous jitter test pattern (CJPAT) defined in Annex 48A of IEEE802.3ae. All lanes of the LP-Serial
link shall be active in both the transmit and receive directions, and opposite ends of the links shall use
asynchronous clocks. Four lane implementations shall use CJPAT as defined in Annex 48A. Single lane
implem entation s shall use the CJPAT sequenc e specifi ed in Annex 48A for transmission on lane 0. The
amount of data represented in the eye shall be adequate to ensure that the bit error ratio is less than 10-12.
The eye pattern shall be measured wit h AC coupling and the compliance template centered at 0 V
dif ferential. The left and right edges of the t emp lat e shall be aligned with the m ean zero crossing points of
the measured data eye. The load for this test shall be 100-Ω resistive ± 5% differential to 2.5 GHz.
15.9.2 Jitter Test Measurements
For the purpose of jitter measurement, the effects of a single-pole high pass filter with a 3 dB point at (Baud
Frequency) ÷1667 is applied to the jitter. The data pattern for jitter measurements is the conti nuous jitter
test pattern (CJPAT ) pattern defined in Annex 48A of IEEE802.3ae. All lanes of the LP-Serial link shall
be active in both the transmit and receive directions, and opposite ends of the links shall use asynchronous
clocks. Four lane implementations shall use CJPAT as defined in Annex 48A. Single lane implementations
shall use the CJPAT sequence specified in Annex 48A for t ransmission on lane 0. Jitt er shall be measured
with AC coupling and at 0 V differential. Jitter measurement for the transmitter (or for calibration of a jitter
tolerance setup) shall be performed with a test procedure resulting in a BER curve such as that described
in Annex 48B of IEEE802.3ae.
15.9.3 Transmit Jitter
Transmit jitter is measured at the driver output when terminated into a load of 100-Ω resistive ± 5%
differential to 2.5 GHz.
15.9.4 Jitter Tolerance
Jitter tolerance is measured at the receiver using a jitter tolerance test signal. This signal is obtained by first
producing the sum of deterministic and random jitter defined in Section 15. 7, “Receiver Specifications,”
and then adjusting the signal amplitude until the data eye contacts the six points of the minimum eye
opening of the receive template shown in Figure 56 and Table 62. Note that for this to occur , the test signal
must have vertical waveform symmetry about the average value and have hor izontal symmetry (in cludi ng
jitter) about the mean zero crossing. Eye template measurement requirements are as defined above.
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 87
Package
Random jitter is calibrated using a high pass filter with a low frequency corner at 20 MHz and a 20
dB/decade roll- off below this. The required sinusoidal jitter specified in Section 15.7, “Receiver
Specifications,” is then added to the signal and the test load is replaced by the receiver being tested.
16 Package
This section details package parameters and dimensions.
16.1 Package Parameters for the MPC8640
The package parameters are as provided in the f ollowing list. The package type is 33 mm × 33 mm, 1023
pins. There are two package options: high-lead flip chip-ceramic ball grid array (FC-CBGA) and lead-free
(FC-CBGA).
For all pack age types:
Die size 12.1 mm × 14.7 mm
Package outline 33 mm × 33 mm
Interconnects 1023
Pitch 1 mm
Total Capacitor count 43 caps; 100 nF each
For high-lead FC-CBGA (package option: HCTE1 HX)
Maximum module height 2.97 mm
Minimum module height 2.47 mm
Solder Balls 89.5% Pb 10.5% Sn
Ball diameter (typical2) 0.60 mm
For RoHS lead-free FC-CBGA (package option: HCTE1 VU)
Maximum module height 2.77 mm
Minimum module height 2.27 mm
Solder Balls 95.5% Sn 4.0% Ag 0.5% Cu
Ball diameter (typical2) 0.60 mm
1 High-coefficient of thermal expansion
2 Typical ball diameter is before reflow
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
88 Freescale Semiconductor
Package
16.2 Mechanical Dimensions of the MPC8640 FC-CBGA
The mechanical dimensions and bottom surface nomenclature of the MPC8640D (dual core) and
MPC8640 (single core) high-lead FC-CBGA (package option: HCTE HX) and lead-free FC-CBGA
(package option: HCTE VU) are shown respectf ully in Figure 57 and Figure 58.
Figure 57. MPC8640D High-Lead FC-CBGA Dimensions
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 89
Package
NOTES for Figure 57
1. All dimensions are in millimeters.
2. Dimensions and tolerances per ASME Y14.5M-1994.
3. Maximum solder ball diameter measured parallel to datum A.
4. Datum A, the seating plane, is defined by the spherical crowns of the solder balls.
5. Capacitors may not be present on all devices.
6. Caution must be taken not to short capacitors or expose metal capacitor pads on package top.
7. All dimensions symmetrical about centerlines unless otherwise specified.
8. Note that for MPC8640 (single core) the solder balls for the following signals/pins are not populated in the package:
VDD_Core1 (R16, R18, R20, T17, T19, T21, T23, U16, U18, U22, V17, V19, V21, V23, W16, W18, W20, W22, Y17,
Y19, Y21, Y23, AA16, AA18, AA20, AA22, AB23, AC24) and SENSEVDD_Core1 (U20).
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
90 Freescale Semiconductor
Package
Figure 58. MPC8640D Lead-Free FC-CBGA Dimensions
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 91
Signal Listings
NOTES for Figure 58
1. All dimensions are in millimeters.
2. Dimensions and tolerances per ASME Y14.5M-1994.
3. Maximum solder ball diameter measured parallel to datum A.
4. Datum A, the seating plane, is defined by the spherical crowns of the solder balls.
5. Capacitors may not be present on all devices.
6. Caution must be taken not to short capacitors or expose metal capacitor pads on package top.
7. All dimensions symmetrical about centerlines unless otherwise specified.
8. Note that for MPC8640 (single core) the solder balls for the following signals/pins are not populated in the package:
VDD_Core1 (R16, R18, R20, T17, T19, T21, T23, U16, U18, U22, V17, V19, V21, V23, W16, W18, W20, W22, Y17,
Y19, Y21, Y23, AA16, AA18, AA20, AA22, AB23, AC24) and SENSEVDD_Core1 (U20).
17 Signal Listings
Table 63 provides the pin assignments for the signals. Notes for the signal changes on the s ingle core
device (MPC8640) are italicized and prefixed by S.
Table 63. MPC8640 Signal Reference by Functional Block
Name1Package Pin Number Pin Type Power Supply Notes
DDR Memory Interface 1 Signals2,3
D1_MDQ[0:63] D15, A14, B12, D12, A15, B15, B13, C13,
C11, D11, D9, A8, A12, A11, A9, B9, F11,
G12, K11, K12, E10, E9, J11, J10, G8, H10,
L9, L7, F10, G9, K9, K8, AC6, AC7, AG8,
AH9, AB6, AB8, AE9, AF9, AL8, AM8,
AM10, AK11, AH8, AK8, AJ10, AK10, AL12,
AJ12, AL14, AM14, AL11, AM11, AM13,
AK14, AM15, AJ16, AK18, AL18, AJ15,
AL15, AL17, AM17
I/O D1_GVDD —
D1_MECC[0:7] M8, M7, R8, T10, L11, L10, P9, R10 I/O D1_GVDD —
D1_MDM[0:8] C14, A10, G11, H9, AD7, AJ9, AM12, AK16,
N10
O D1_GVDD —
D1_MDQS[0:8] A13, C10, H12, J7, AE8, AM9, AK13, AK17,
N9
I/O D1_GVDD —
D1_MDQS[0:8] D14, B10, H13, J8, AD8, AL9, AJ13, AM16,
P10
I/O D1_GVDD —
D1_MBA[0:2] AA8, AA10, T9 O D1_GVDD —
D1_MA[0:15] Y10, W8, W9, V7, V8, U6, V10, U9, U7, U10,
Y9, T6, T8, AE12, R7, P6
O D1_GVDD —
D1_MWE AB11 O D1_GVDD —
D1_MRAS AB12 O D1_GVDD —
D1_MCAS AC10 O D1_GVDD —
D1_MCS[0:3] AB9, AD10, AC12, AD11 O D1_GVDD —
D1_MCKE[0:3] P7, M10, N8, M11 O D1_GVDD 23
D1_MCK[0:5] W6, E13, AH11, Y7, F14, AG10 O D1_GVDD —
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
92 Freescale Semiconductor
Signal Listings
D1_MCK[0:5] Y6, E12, AH12, AA7, F13, AG11 O D1_GVDD —
D1_MODT[0:3] AC9, AF12, AE11, AF10 O D1_GVDD —
D1_MDIC[0:1] E15, G14 IO D1_GVDD 27
D1_MVREF AM18 DDR Port 1
reference
voltage
D1_GVDD /2 3
DDR Memory Interface 2 Signals2,3
D2_MDQ[0:63] A7, B7, C5, D5, C8, D8, D6, A5, C4, A3, D3,
D2, A4, B4, C2, C1, E3, E1, H4, G1, D1, E4,
G3, G2, J4, J2, L1, L3, H3, H1, K1, L4, AA4,
AA2, AD1, AD2, Y1, AA1, AC1, AC3, AD5,
AE1, AG1, AG2, AC4, AD4, AF3, AF4, AH3,
AJ1, AM1, AM3, AH1, AH2, AL2, AL3, AK5,
AL5, AK7, AM7, AK4, AM4, AM6, AJ7
I/O D2_GVDD —
D2_MECC[0:7] H6, J5, M5, M4, G6, H7, M2, M1 I/O D2_GVDD —
D2_MDM[0:8] C7, B3, F4, J1, AB1, AE2, AK1, AM5, K6 O D2_GVDD —
D2_MDQS[0:8] B6, B1, F1, K2, AB3, AF1, AL1, AL6, L6 I/O D2_GVDD —
D2_MDQS[0:8] A6, A2, F2, K3, AB2, AE3, AK2, AJ6, K5 I/O D2_GVDD —
D2_MBA[0:2] W5, V5, P3 O D2_GVDD —
D2_MA[0:15] W1, U4, U3, T1, T2, T3, T5, R2, R1, R5, V4,
R4, P1, AH5, P4, N1
O D2_GVDD —
D2_MWE Y4 O D2_GVDD —
D2_MRAS W3 O D2_GVDD —
D2_MCAS AB5 O D2_GVDD —
D2_MCS[0:3] Y3, AF6, AA5, AF7 O D2_GVDD —
D2_MCKE[0:3] N6, N5, N2, N3 O D2_GVDD 23
D2_MCK[0:5] U1, F5, AJ3, V2, E7, AG4 O D2_GVDD —
D2_MCK[0:5] V1, G5, AJ4, W2, E6, AG5 O D2_GVDD —
D2_MODT[0:3] AE6, AG7, AE5, AH6 O D2_GVDD —
D2_MDIC[0:1] F8, F7 IO D2_GVDD 27
D2_MVREF A18 DDR Port 2
reference
voltage
D2_GVDD /2 3
High Speed I/O Interface 1 (SERDES 1)4
SD1_TX[0:7] L26, M24, N26, P24, R26, T24, U26, V24 O SVDD —
SD1_TX[0:7] L27, M25, N27, P25, R27, T25, U27, V25 O SVDD —
SD1_RX[0:7] J32, K30, L32, M30, T30, U32, V30, W32 I SVDD —
Table 63. MPC8640 Signal Reference by Functional Block (continued)
Name1Package Pin Number Pin Type Power Supply Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 93
Signal Listings
SD1_RX[0:7] J31, K29, L31, M29, T29, U31, V29, W31 I SVDD —
SD1_REF_CLK N32 I SVDD —
SD1_REF_CLK N31 I SVDD —
SD1_IMP_CAL_TX Y26 Analog SVDD 19
SD1_IMP_CAL_RX J28 Analog SVDD 30
SD1_PLL_TPD U28 O SVDD 13, 17
SD1_PLL_TPA T28 Analog SVDD 13, 18
SD1_DLL_TPD N28 O SVDD 13, 17
SD1_DLL_TPA P31 Analog SVDD 13, 18
High Speed I/O Interface 2 (SERDES 2)4
SD2_TX[0:3] Y24, AA27, AB25, AC27 O SVDD —
SD2_TX[4:7] AE27, AG27, AJ27, AL27 O SVDD 34
SD2_TX[0:3] Y25, AA28, AB26, AC28 O SVDD —
SD2_TX[4:7] AE28, AG28, AJ28, AL28 O SVDD 34
SD2_RX[0:3] Y30, AA32, AB30, AC32 I SVDD 32
SD2_RX[4:7] AH30, AJ32, AK30, AL32 I SVDD 32, 35
SD2_RX[0:3] Y29, AA31, AB29, AC31 I SVDD —
SD2_RX[4:7] AH29, AJ31, AK29, AL31 I SVDD 35
SD2_REF_CLK AE32 I SVDD —
SD2_REF_CLK AE31 I SVDD —
SD2_IMP_CAL_TX AM29 Analog SVDD 19
SD2_IMP_CAL_RX AA26 Analog SVDD 30
SD2_PLL_TPD AF29 O SVDD 13, 17
SD2_PLL_TPA AF31 Analog SVDD 13, 18
SD2_DLL_TPD AD29 O SVDD 13, 17
SD2_DLL_TPA AD30 Analog SVDD 13, 18
Special Connection Requirement pins
No Connects K24, K25, P28, P29, W26, W27, AD25,
AD26
—— 13
Reserved H30, R32, V28, AG32 — — 14
Reserved H29, R31, W28, AG31 — — 15
Reserved AD24, AG26 — — 16
Ethernet Miscellaneous Signals5
Table 63. MPC8640 Signal Reference by Functional Block (continued)
Name1Package Pin Number Pin Type Power Supply Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
94 Freescale Semiconductor
Signal Listings
EC1_GTX_CLK125 AL23 I LVDD 39
EC2_GTX_CLK125 AM23 I TVDD 39
EC_MDC G31 O OVDD —
EC_MDIO G32 I/O OVDD —
eTSEC Port 1 Signals5
TSEC1_TXD[0:7]/
GPOUT[0:7]
AF25, AC23,AG24, AG23, AE24, AE23,
AE22, AD22
OLV
DD 6, 10
TSEC1_TX_EN AB22 O LVDD 36
TSEC1_TX_ER AH26 O LVDD —
TSEC1_TX_CLK AC22 I LVDD 40
TSEC1_GTX_CLK AH25 O LVDD 41
TSEC1_CRS AM24 I/O LVDD 37
TSEC1_COL AM25 I LVDD —
TSEC1_RXD[0:7]/
GPIN[0:7]
AL25, AL24, AK26, AK25, AM26, AF26,
AH24, AG25
ILV
DD 10
TSEC1_RX_DV AJ24 I LVDD —
TSEC1_RX_ER AJ25 I LVDD —
TSEC1_RX_CLK AK24 I LVDD 40
eTSEC Port 2 Signals5
TSEC2_TXD[0:3]/
GPOUT[8:15]
AB20, AJ23, AJ22, AD19 O LVDD 6, 10
TSEC2_TXD[4]/
GPOUT[12]
AH23 O LVDD 6,10, 38
TSEC2_TXD[5:7]/
GPOUT[13:15]
AH21, AG22, AG21 O LVDD 6, 10
TSEC2_TX_EN AB21 O LVDD 36
TSEC2_TX_ER AB19 O LVDD 6, 38
TSEC2_TX_CLK AC21 I LVDD 40
TSEC2_GTX_CLK AD20 O LVDD 41
TSEC2_CRS AE20 I/O LVDD 37
TSEC2_COL AE21 I LVDD —
TSEC2_RXD[0:7]/
GPIN[8:15]
AL22, AK22, AM21, AH20, AG20, AF20,
AF23, AF22
ILV
DD 10
TSEC2_RX_DV AC19 I LVDD —
TSEC2_RX_ER AD21 I LVDD —
Table 63. MPC8640 Signal Reference by Functional Block (continued)
Name1Package Pin Number Pin Type Power Supply Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 95
Signal Listings
TSEC2_RX_CLK AM22 I LVDD 40
eTSEC Port 3 Signals5
TSEC3_TXD[0:3] AL21, AJ21, AM20, AJ20 O TVDD 6
TSEC3_TXD[4]/ AM19 O TVDD —
TSEC3_TXD[5:7] AK21, AL20, AL19 O TVDD 6
TSEC3_TX_EN AH19 O TVDD 36
TSEC3_TX_ER AH17 O TVDD —
TSEC3_TX_CLK AH18 I TVDD 40
TSEC3_GTX_CLK AG19 O TVDD 41
TSEC3_CRS AE15 I/O TVDD 37
TSEC3_COL AF15 I TVDD —
TSEC3_RXD[0:7] AJ17, AE16, AH16, AH14, AJ19, AH15,
AG16, AE19
ITV
DD —
TSEC3_RX_DV AG15 I TVDD —
TSEC3_RX_ER AF16 I TVDD —
TSEC3_RX_CLK AJ18 I TVDD 40
eTSEC Port 4 Signals5
TSEC4_TXD[0:3] AC18, AC16, AD18, AD17 O TVDD 6
TSEC4_TXD[4] AD16 O TVDD 25
TSEC4_TXD[5:7] AB18, AB17, AB16 O TVDD 6
TSEC4_TX_EN AF17 O TVDD 36
TSEC4_TX_ER AF19 O TVDD —
TSEC4_TX_CLK AF18 I TVDD 40
TSEC4_GTX_CLK AG17 O TVDD 41
TSEC4_CRS AB14 I/O TVDD 37
TSEC4_COL AC13 I TVDD —
TSEC4_RXD[0:7] AG14, AD13, AF13, AD14, AE14, AB15,
AC14, AE17
ITV
DD —
TSEC4_RX_DV AC15 I TVDD —
TSEC4_RX_ER AF14 I TVDD —
TSEC4_RX_CLK AG13 I TVDD 40
Table 63. MPC8640 Signal Reference by Functional Block (continued)
Name1Package Pin Number Pin Type Power Supply Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
96 Freescale Semiconductor
Signal Listings
Local Bus Signals5
LAD[0:31] A30, E29, C29, D28, D29, H25, B29, A29,
C28, L22, M22, A28, C27, H26, G26, B27,
B26, A27, E27, G25, D26, E26, G24, F27,
A26, A25, C25, H23, K22, D25, F25, H22
I/O OVDD 6
LDP[0:3] A24, E24, C24, B24 I/O OVDD 6, 22
LA[27:31] J21, K21, G22, F24, G21 O OVDD 6, 22
LCS[0:4] A22, C22, D23, E22, A23 O OVDD 7
LCS[5]/DMA_DREQ[2] B23 O OVDD 7, 9, 10
LCS[6]/DMA_DACK[2] E23 O OVDD 7, 10
LCS[7]/DMA_DDONE[2] F23 O OVDD 7, 10
LWE[0:3]/
LSDDQM[0:3]/
LBS[0:3]
E21, F21, D22, E20 O OVDD 6
LBCTL D21 O OVDD —
LALE E19 O OVDD —
LGPL0/LSDA10 F20 O OVDD 25
LGPL1/LSDWE H20 O OVDD 25
LGPL2/LOE/
LSDRAS
J20 O OVDD —
LGPL3/LSDCAS K20 O OVDD 6
LGPL4/LGTA/
LUPWAIT/LPBSE
L21 I/O OVDD 42
LGPL5 J19 O OVDD 6
LCKE H19 O OVDD —
LCLK[0:2] G19, L19, M20 O OVDD —
LSYNC_IN M19 I OVDD —
LSYNC_OUT D20 O OVDD —
DMA Signals5
DMA_DREQ[0:1] E31, E32 I OVDD —
DMA_DREQ[2]/LCS[5] B23 I OVDD 9, 10
DMA_DREQ[3]/IRQ[9] B30 I OVDD 10
DMA_DACK[0:1] D32, F30 O OVDD —
DMA_DACK[2]/LCS[6] E23 O OVDD 10
DMA_DACK[3]/IRQ[10] C30 O OVDD 9, 10
Table 63. MPC8640 Signal Reference by Functional Block (continued)
Name1Package Pin Number Pin Type Power Supply Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 97
Signal Listings
DMA_DDONE[0:1] F31, F32 O OVDD —
DMA_DDONE[2]/LCS[7] F23 O OVDD 10
DMA_DDONE[3]/IRQ[11] D30 O OVDD 9, 10
Programmable Interrupt Controller Signals5
MCP_0 F17 I OVDD —
MCP _1 H17 I OVDD 12,
S4
IRQ[0:8] G28, G29, H27, J23, M23, J27, F28, J24,
L23
IOV
DD —
IRQ[9]/DMA_DREQ[3] B30 I OVDD 10
IRQ[10]/DMA_DACK[3] C30 I OVDD 9, 10
IRQ[11]/DMA_DDONE[3] D30 I OVDD 9, 10
IRQ_OUT J26 O OVDD 7, 11
DUART Signals5
UART_SIN[0:1] B32, C32 I OVDD —
UART_SOUT[0:1] D31, A32 O OVDD —
UART_CTS[0:1] A31, B31 I OVDD —
UART_RTS[0:1] C31, E30 O OVDD —
I2C Signals
IIC1_SDA A16 I/O OVDD 7, 11
IIC1_SCL B17 I/O OVDD 7, 11
IIC2_SDA A21 I/O OVDD 7, 11
IIC2_SCL B21 I/O OVDD 7, 11
System Control Signals5
HRESET B18 I OVDD —
HRESET_REQ K18 O OVDD —
SMI_0 L15 I OVDD —
SMI_1 L16 I OVDD 12,
S4
SRESET_0 C20 I OVDD —
SRESET_1 C21 I OVDD 12,
S4
CKSTP_IN L18 I OVDD —
CKSTP_OUT L17 O OVDD 7, 11
READY/TRIG_OUT J13 O OVDD 10, 25
Table 63. MPC8640 Signal Reference by Functional Block (continued)
Name1Package Pin Number Pin Type Power Supply Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
98 Freescale Semiconductor
Signal Listings
Debug Signals5
TRIG_IN J14 I OVDD —
TRIG_OUT/READY J13 O OVDD 10, 25
D1_MSRCID[0:1]/LB_SR
CID[0:1]
F15, K15 O OVDD 6, 10
D1_MSRCID[2]/LB_SRCI
D[2]
K14 O OVDD 10, 25
D1_MSRCID[3:4]/LB_SR
CID[3:4]
H15, G15 O OVDD 10
D2_MSRCID[0:4] E16, C17, F16, H16, K16 O OVDD —
D1_MDVAL/LB_DVAL J16 O OVDD 10
D2_MDVAL D19 O OVDD —
Power Management Signals5
ASLEEP C19 O OVDD —
System Clocking Signals5
SYSCLK G16 I OVDD —
RTC K17 I OVDD 32
CLK_OUT B16 O OVDD 23
Test Signals5
LSSD_MODE C18 I OVDD 26
TEST_MODE[0:3] C16, E17, D18, D16 I OVDD 26
JTAG Signals5
TCK H18 I OVDD —
TDI J18 I OVDD 24
TDO G18 O OVDD 23
TMS F18 I OVDD 24
TRST A17 I OVDD 24
Miscellaneous5
Spare J17 — — 13
GPOUT[0:7]/
TSEC1_TXD[0:7]
AF25, AC23, AG24, AG23, AE24, AE23,
AE22, AD22
OOV
DD 6, 10
GPIN[0:7]/
TSEC1_RXD[0:7]
AL25, AL24, AK26, AK25, AM26, AF26,
AH24, AG25
IOV
DD 10
GPOUT[8:15]/
TSEC2_TXD[0:7]
AB20, AJ23, AJ22, AD19, AH23, AH21,
AG22, AG21
OOV
DD 10
Table 63. MPC8640 Signal Reference by Functional Block (continued)
Name1Package Pin Number Pin Type Power Supply Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 99
Signal Listings
GPIN[8:15]/
TSEC2_RXD[0:7]
AL22, AK22, AM21, AH20, AG20, AF20,
AF23, AF22
IOV
DD 10
Additional Analog Signals
TEMP_ANODE AA11 Thermal — —
TEMP_CATHODE Y11 Thermal — —
Sense, Power and GND Signals
SENSEVDD_Core0 M14 VDD_Core0
sensing pin
—31
SENSEVDD_Core1 U20 VDD_Core1
sensing pin
— 12,31,
S1
SENSEVSS_Core0 P14 Core0 GND
sensing pin
—31
SENSEVSS_Core1 V20 Core1 GND
sensing pin
— 12, 31,
S3
SENSEVDD_PLAT N18 VDD_PLAT
sensing pin
—28
SENSEVSS_PLAT P18 Platform GND
sensing pin
—29
D1_GVDD B11, B14, D10, D13, F9, F12, H8, H11, H14,
K10, K13, L8, P8, R6, U8, V6, W10, Y8,
AA6, AB10, AC8, AD12, AE10, AF8, AG12,
AH10, AJ8, AJ14, AK12, AL10, AL16
SDRAM 1 I/O
supply
D1_GVDD
• 2.5 DDR
• 1.8 DDR2
—
D2_GVDD B2, B5, B8, D4, D7, E2, F6, G4, H2, J6, K4,
L2, M6, N4, P2, T4, U2, W4, Y2, AB4, AC2,
AD6, AE4, AF2, AG6, AH4, AJ2, AK6, AL4,
AM2
SDRAM 2 I/O
supply
D2_GVDD
• 2.5 V DDR
• 1.8 V DDR2
—
OVDD B22, B25, B28, D17, D24, D27, F19, F22,
F26, F29, G17, H21, H24, K19, K23, M21,
AM30
DUART, Local
Bus, DMA,
Multiprocessor
Interrupts,
System Control
& Clocking,
Debug, Test,
JTAG, Power
management,
I2C, JTAG and
Miscellaneous
I/O voltage
OVDD
3.3 V
—
LVDD AC20, AD23, AH22 TSEC1 and
TSEC2 I/O
voltage
LVDD
2.5/3.3 V
—
TVDD AC17, AG18, AK20 TSEC3 and
TSEC4 I/O
voltage
TVDD
2.5/3.3 V
—
Table 63. MPC8640 Signal Reference by Functional Block (continued)
Name1Package Pin Number Pin Type Power Supply Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
100 Freescale Semiconductor
Signal Listings
SVDD H31, J29, K28, K32, L30, M28, M31, N29,
R30, T31, U29, V32, W30, Y31, AA29,
AB32, AC30, AD31, AE29, AG30, AH31,
AJ29, AK32, AL30, AM31
Transceiver
Power Supply
SerDes
SVDD
1.05/1.1 V
—
XVDD_SRDS1 K26, L24, M27, N25, P26, R24, R28, T27,
U25, V26
Serial I/O
Power Supply
for SerDes
Port 1
XVDD_SRDS1
1.05/1.1 V
XVDD_SRDS2 AA25, AB28, AC26, AD27, AE25, AF28,
AH27, AK28, AM27, W24, Y27
Serial I/O
Power Supply
for SerDes
Port 2
XVDD_SRDS2
1.05/1.1 V
—
VDD_Core0 L12, L13, L14, M13, M15, N12, N14, P11,
P13, P15, R12, R14, T11, T13, T15, U12,
U14, V11, V13, V15, W12, W14, Y12, Y13,
Y15, AA12, AA14, AB13
Core 0 voltage
supply
VDD_Core0
0.95/1.05/1.1
V
—
VDD_Core1 R16, R18, R20, T17, T19, T21, T23, U16,
U18, U22, V17, V19, V21, V23, W16, W18,
W20, W22, Y17, Y19, Y21, Y23, AA16,
AA18, AA20, AA22, AB23, AC24
Core 1 voltage
supply
VDD_Core1
0.95/1.05/1.1
V
12,
S1
VDD_PLAT M16, M17, M18, N16, N20, N22, P17, P19,
P21, P23, R22
Platform supply
voltage
VDD_PLAT
1.05/1.1 V
—
AVDD_Core0 B20 Core 0 PLL
Supply
AVDD_Core0
0.95/1.05/
1.1 V
—
AVDD_Core1 A19 Core 1 PLL
Supply
AVDD_Core1
0.95/1.05/
1.1 V
12,
S2
AVDD_PLAT B19 Platform PLL
supply voltage
AVDD_PLAT
1.05/1.1 V
—
AVDD_LB A20 Local Bus PLL
supply voltage
AVDD_LB
1.05/1.1 V
—
AVDD_SRDS1 P32 SerDes Port 1
PLL & DLL
Power Supply
AVDD_SRDS1
1.05/1.1 V
—
AVDD_SRDS2 AF32 SerDes Port 2
PLL & DLL
Power Supply
AVDD_SRDS2
1.05/1.1 V
—
Table 63. MPC8640 Signal Reference by Functional Block (continued)
Name1Package Pin Number Pin Type Power Supply Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 101
Signal Listings
GND C3, C6, C9, C12, C15, C23, C26, E5, E8,
E11, E14, E18, E25, E28, F3, G7, G10, G13,
G20, G23, G27, G30, H5, J3, J9, J12, J15,
J22, J25, K7, L5, L20, M3, M9, M12, N7,
N11, N13, N15, N17, N19, N21, N23, P5,
P12, P16, P20, P22, R3, R9, R11, R13, R15,
R17, R19, R21, R23, T7, T12, T14, T16,
T18, T20, T22, U5, U11,U13, U15, U17,
U19, U21, U23, V3, V9, V12, V14, V16, V18,
V22, W7, W11, W13, W15, W17, W19, W21,
W23,Y5, Y14, Y16, Y18, Y20, Y22, AA3,
AA9, AA13, AA15, AA17, AA19, AA21,
AA23, AB7, AB24, AC5, AC11, AD3, AD9,
AD15, AE7, AE13, AE18, AF5, AF11, AF21,
AF24, AG3, AG9, AH7, AH13, AJ5, AJ11,
AK3, AK9, AK15, AK19, AK23, AL7, AL13
GND — —
AGND_SRDS1 P30 SerDes Port 1
Ground pin for
AVDD_SRDS1
——
AGND_SRDS2 AF30 SerDes Port 2
Ground pin for
AVDD_SRDS2
——
SGND H28, H32, J30, K31, L28, L29, M32, N30,
R29, T32, U30, V31, W29,Y32 AA30, AB31,
AC29, AD32, AE30, AG29, AH32, AJ30,
AK31, AL29, AM32
Ground pins for
SVDD
——
XGND K27, L25, M26, N24, P27, R25, T26, U24,
V27, W25, Y28, AA24, AB27, AC25, AD28,
AE26, AF27, AH28, AJ26, AK27, AL26,
AM28
Ground pins for
XVDD_SRDS
n
——
Reset Configuration Signals20
TSEC1_TXD[0] /
cfg_alt_boot_vec
AF25 — LVDD —
TSEC1_TXD[1]/
cfg_platform_freq
AC23 — LVDD 21
TSEC1_TXD[2:4]/
cfg_device_id[5:7]
AG24, AG23, AE24 — LVDD —
TSEC1_TXD[5]/
cfg_tsec1_reduce
AE23 — LVDD —
TSEC1_TXD[6:7]/
cfg_tsec1_prtcl[0:1]
AE22, AD22 — LVDD —
TSEC2_TXD[0:3]/
cfg_rom_loc[0:3]
AB20, AJ23, AJ22, AD19 — LVDD —
TSEC2_TXD[4],
TSEC2_TX_ER/
cfg_dram_type[0:1]
AH23,
AB19
—LV
DD 38
Table 63. MPC8640 Signal Reference by Functional Block (continued)
Name1Package Pin Number Pin Type Power Supply Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
102 Freescale Semiconductor
Signal Listings
TSEC2_TXD[5]/
cfg_tsec2_reduce
AH21 — LVDD —
TSEC2_TXD[6:7]/
cfg_tsec2_prtcl[0:1]
AG22, AG21 — LVDD —
TSEC3_TXD[0:1]/
cfg_spare[0:1]
AL21, AJ21 O TVDD 33
TSEC3_TXD[2]/
cfg_core1_enable
AM20 O TVDD —
TSEC3_TXD[3]/
cfg_core1_lm_offset
AJ20 — LVDD —
TSEC3_TXD[5]/
cfg_tsec3_reduce
AK21 — LVDD —
TSEC3_TXD[6:7]/
cfg_tsec3_prtcl[0:1]
AL20, AL19 — LVDD —
TSEC4_TXD[0:3]/
cfg_io_ports[0:3]
AC18, AC16, AD18, AD17 — LVDD —
TSEC4_TXD[5]/
cfg_tsec4_reduce
AB18 — LVDD —
TSEC4_TXD[6:7]/
cfg_tsec4_prtcl[0:1]
AB17, AB16 — LVDD —
LAD[0:31]/
cfg_gpporcr[0:31]
A30, E29, C29, D28, D29, H25, B29, A29,
C28, L22, M22, A28, C27, H26, G26, B27,
B26, A27, E27, G25, D26, E26, G24, F27,
A26, A25, C25, H23, K22, D25, F25, H22
—OV
DD —
LWE[0]/
cfg_cpu_boot
E21 — OVDD —
LWE[1]/
cfg_rio_sys_size
F21 — OVDD —
LWE[2:3]/
cfg_host_agt[0:1]
D22, E20 — OVDD —
LDP[0:3], LA[27] /
cfg_core_pll[0:4]
A24, E24, C24, B24,
J21
—OV
DD 22
LA[28:31]/
cfg_sys_pll[0:3]
K21, G22, F24, G21 — OVDD 22
LGPL[3],
LGPL[5]/
cfg_boot_seq[0:1]
K20,
J19
—OV
DD —
D1_MSRCID[0]/
cfg_mem_debug
F15 — OVDD —
D1_MSRCID[1]/
cfg_ddr_debug
K15 — OVDD —
Table 63. MPC8640 Signal Reference by Functional Block (continued)
Name1Package Pin Number Pin Type Power Supply Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 103
Signal Listings
Note:
1. Multi-pin signals such as D1_MDQ[0:63] and D2_MDQ[0:63] have their physical package pin numbers listed in order
corresponding to the signal names.
2. Stub Series Terminated Logic (SSTL-18 and SSTL-25) type pins.
3. If a DDR port is not used, it is possible to leave the related power supply (Dn_GVDD, Dn_MVREF) turned off at reset. Note
that these power supplies can only be powered up again at reset for functionality to occur on the DDR port.
4. Low Voltage Differential Signaling (LVDS) type pins.
5. Low Voltage Transistor-Transistor Logic (LVTTL) type pins.
6. This pin is a reset configuration pin and appears again in the Reset Configuration Signals section of this table. See the Reset
Configuration Signals section of this table for config name and connection details.
7. Recommend a weak pull-up resistor (1–10 kΩ) be placed from this pin to its power supply.
8. Recommend a weak pull-down resistor (2–10 kΩ) be placed from this pin to ground.
9. This multiplexed pin has input status in one mode and output in another
10. This pin is a multiplexed signal for different functional blocks and appears more than once in this table.
11. This pin is open drain signal.
12. Functional only on the MPC8640D.
13. These pins should be left floating.
14. These pins should be connected to SVDD
.
15. These pins should be pulled to ground with a strong resistor (270-Ω to 330-Ω).
16. These pins should be connected to OVDD.
17.This is a SerDes PLL/DLL digital test signal and is only for factory use.
18. This is a SerDes PLL/DLL analog test signal and is only for factory use.
19. This pin should be pulled to ground with a 100-Ω resistor.
20. The pins in this section are reset configuration pins. Each pin has a weak internal pull-up P-FET which is enabled only when
the processor is in the reset state. This pull-up is designed such that it can be overpowered by an external 4.7-kΩ pull-down
resistor. However, if the signal is intended to be high after reset, and if there is any device on the net which might pull down
the value of the net at reset, then a pullup or active driver is needed.
21. Should be pulled down at reset if platform frequency is at 400 MHz.
22. These pins require 4.7-kΩ pull-up or pull-down resistors and must be driven as they are used to determine PLL configuration
ratios at reset.
23. This output is actively driven during reset rather than being released to high impedance during reset.
24 These JTAG pins have weak internal pull-up P-FETs that are always enabled.
25. This pin should NOT be pulled down (or driven low) during reset.
26.These are test signals for factory use only and must be pulled up (100-Ω to 1- kΩ.) to OVDD for normal machine operation.
27. Dn_MDIC[0] should be connected to ground with an 18-Ω resistor ± 1-Ω and Dn_MDIC[1] should be cLonnected Dn_GVDD
with an 18-Ω resistor ± 1-Ω. These pins are used for automatic calibration of the DDR IOs.
28. Pin N18 is recommended as a reference point for determining the voltage of VDD_PLAT and is hence considered as the
VDD_PLAT sensing voltage and is called SENSEVDD_PLAT.
29. Pin P18 is recommended as the ground reference point for SENSEVDD_PLAT and is called SENSEVSS_PLAT.
30.This pin should be pulled to ground with a 200-Ω resistor.
31.These pins are connected to the power/ground planes internally and may be used by the core power supply to improve
tracking and regulation.
32. Must be tied low if unused
33. These pins may be used as defined functional reset configuration pins in the future. Please include a resistor pull-up/down
option to allow flexibility of future designs.
34. Used as serial data output for serial RapidIO 1×/4× link.
35. Used as serial data input for serial RapidIO 1×/4× link.
36.This pin requires an external 4.7-kΩ pull-down resistor to prevent PHY from seeing a valid transmit enable before it is actively
driven.
Table 63. MPC8640 Signal Reference by Functional Block (continued)
Name1Package Pin Number Pin Type Power Supply Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
104 Freescale Semiconductor
Clocking
18 Clocking
This section describes the PLL configuration of t he MPC8640. Note t hat the plat form clock is identical to
the MP X clock.
18.1 Clock Ranges
Table 64 provides the clocking specifications for the processor cores, and Table 65 provides the clocking
specifications for the memory bus. Table 66 provides the clocking for the Platform/MPX bus, and Table 67
provides the clocking for the local bus .
37.This pin is only an output in FIFO mode when used as Rx Flow Control.
38.This pin functions as cfg_dram_type[0 or 1] at reset. Note: This pin must be valid before HRESET assertion in device sleep
mode.
39. Should be pulled to ground if unused (such as in FIFO, MII and RMII modes).
40. See Section 18.4.2, “Platform to FIFO Restrictions” for clock speed limitations for this pin when used in FIFO mode.
41. The phase between the output clocks TSEC1_GTX_CLK and TSEC2_GTX_CLK (ports 1 and 2) is no more than 100 ps.
The phase between the output clocks TSEC3_GTX_CLK and TSEC4_GTX_CLK (ports 3 and 4) is no more than 100 ps.
42. For systems which boot from Local Bus (GPCM)-controlled flash, a pullup on LGPL4 is required.
Special Notes for Single Core Device:
S1
. Solder ball for this signal will not be populated in the single core package.
S2
. The PLL filter from VDD_Core1 to AVDD_Core1 should be removed. AVDD_Core1 should be pulled to ground with a weak
(2–10 kΩ) resistor. See Section 20.2.1, “PLL Power Supply Filtering” for more details.
S3
. This pin should be pulled to GND for the single core device.
S4
. No special requirement for this pin on single core device. Pin should be tied to power supply as directed for dual core.
Table 64. Processor Core Clocking Specifications
Parameter
Maximum Processor Core Frequency
Unit Notes1000 MHz 1067 MHz 1250MHz
Min Max Min Max Min Max
e600 core processor frequency 800 1000 800 1067 800 1250 MHz 1, 2
Notes:
1. Caution: The MPX clock to SYSCLK ratio and e600 core to MPX clock ratio settings must be chosen such that the resulting
SYSCLK frequency, e600 (core) frequency, and MPX clock frequency do not exceed their respective maximum or minimum
operating frequencies. Refer to Section 18.2, “MPX to SYSCLK PLL Ratio,” and Section 18.3, “e600 to MPX clock PLL Ratio,”
for ratio settings.
2. The minimum e600 core frequency is based on the minimum platform clock frequency of 400 MHz.
Table 63. MPC8640 Signal Reference by Functional Block (continued)
Name1Package Pin Number Pin Type Power Supply Notes
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 105
Clocking
18.2 MPX to SYSCLK PLL Ratio
The MPX clock is the clock that drives the MPX bus, and is also called the platform clock. The frequency
of the MPX is set usi ng the following reset signals, as shown in Table 68:
• S YSCLK input signal
Table 65. Memory Bus Clocking Specifications
Parameter
Maximum Processor Core
Frequency
Unit Notes
1000, 1067, 1250 MHz
Min Max
Memory bus clock frequency 200 266 MHz 1, 2
Notes:
1. Caution: The MPX clock to SYSCLK ratio and e600 core to MPX clock ratio settings must be chosen such that the resulting
SYSCLK frequency, e600 (core) frequency, and MPX clock frequency do not exceed their respective maximum or minimum
operating frequencies. Refer to Section 18.2, “MPX to SYSCLK PLL Ratio,” and Section 18.3, “e600 to MPX clock PLL Ratio,”
for ratio settings.
2. The memory bus clock speed is half the DDR/DDR2 data rate, hence, half the MPX clock frequency.
Table 66. Platform/MPX bus Clocking Specifications
Parameter
Maximum Processor Core
Frequency
Unit Notes
1000, 1067, 1250 MHz
Min Max
Platform/MPX bus clock frequency 400 533 MHz 1, 2
Notes:
1. Caution: The MPX clock to SYSCLK ratio and e600 core to MPX clock ratio settings must be chosen such that the resulting
SYSCLK frequency, e600 (core) frequency, and MPX clock frequency do not exceed their respective maximum or minimum
operating frequencies. Refer to Section 18.2, “MPX to SYSCLK PLL Ratio,” and Section 18.3, “e600 to MPX clock PLL Ratio,”
for ratio settings.
2. Platform/MPX frequencies between 400 and 500 MHz are not supported.
Table 67. Local Bus Clocking Specifications
Parameter
Maximum Processor Core
Frequency
Unit Notes
1000, 1067, 1250 MHz
Min Max
Local bus clock speed (for Local Bus Controller) 25 133 MHz 1
Notes:
1. The Local bus clock speed on LCLK[0:2] is determined by MPX clock divided by the Local Bus PLL ratio programmed in
LCRR[CLKDIV]. See the reference manual for the MPC8641D for more information on this.
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
106 Freescale Semiconductor
Clocking
• Binary value on LA[28:31] at power up
Note that there is no default for this PLL ratio; t hese signals must be pulled to the des ired values. Also note
that the DDR data rate is the determining factor in selecting the MPX bus frequency because the MPX
frequency must equal the DDR data rate.
18.3 e600 to MPX clock PLL Ratio
Table 69 describes the clock ratio between the platform and the e600 core clock. This ratio is determined
by the binary value of LDP[0:3], LA[27](cfg_core_pll[0:4] - reset config name) at power up, as shown in
Table 69.
18.4 Frequency Options
This section discusses the frequency options for the MPC8640.
Table 68. MPX:SYSCLK Ratio
Binary Value of
LA[28:31] Signals MPX:SYSCLK Ratio
0000 Reserved
0001 Reserved
0010 2:1
0011 3:1
0100 4:1
0101 5:1
0110 6:1
0111 Reserved
1000 8:1
1001 Reserved
Table 69. e600 Core to MPX Clock Ratio
Binary Value of
LDP[0:3], LA[27] Signals e600 core: MPX Clock Ratio
01000 2:1
01100 2.5:1
10000 3:1
11100 Reserved
10100 Reserved
01110 Reserved
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 107
Thermal
18.4.1 SYSCLK to Platform Frequency Options
Table 70 shows some SYSCLK frequencies and the expected MPX frequency values based on the MPX
clock to SYSCLK ratio. Note that frequencies between 400 MHz and 500 MHz are not supported on the
platform. See note regarding cfg_platform_freq in Section 17, “Signal Listings,” becaus e it is a reset
configuration pin that is related to platform frequency.
18.4.2 Platform to FIFO Restrictions
Please note the following FIFO maximum speed restrictions based on platform speed:
For FI FO GMII mode:
FIFO TX/RX clock frequency ≤ platform clock frequency ÷ 4.2
For example, if the platform frequency is 500 MHz, the FIFO Tx/Rx clock frequency should be no
more than 119 MHz.
For FIFO encoded mode:
FIFO TX/RX clock frequency ≤ platform clock frequency ÷ 3.2
For example, if the platform frequency is 500 MHz, the FIFO Tx/Rx clock frequency should be no
more than 156 MHz.
19 Thermal
This section describes the thermal specifications of the MPC8640 .
Table 70. Frequency Options of SYSCLK with Respect to Platform/MPX Clock Speed
MPX to
SYSCLK
Ratio
SYSCLK (MHz)
66 83 100 133 167
Platform/MPX Frequency (MHz)1
1SYSCLK frequency range is 66-167 MHz. Platform clock/MPX
frequency range is 400 MHz, 500-533 MHz.
2
3400 500
4400 533
5500
6400 500
8533
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
108 Freescale Semiconductor
Thermal
19.1 Thermal Characteristics
Table 71 provides the package thermal characteristics for the MPC8640.
19.2 Thermal Management Information
This section provides thermal management information for the high coef ficient of thermal expansion
(HCTE) package for air- c ooled applications. Pr oper thermal contr ol design is primar ily dependent on the
system-level design—the heat sink, airflow, and thermal interface material. The MPC8640 implements
several feature s designed to assist with thermal management, including the temperature diode. The
temperat ure diode allows an external device to monitor the die temperat ure in order to detect excess ive
temperature conditions and alert the system; see Section 19.2.4, “Temperature Diode,” for more
information.
T o reduce the die-junction temperature, heat sinks are required. Due to the potential l ar ge mass of the heat
sink, attachment through the printed-circuit board is suggested. In any implementation of a heat sink
solution, the force on the die should not exceed ten pounds force (45 newtons). Figure 59 shows a spring
Table 71. Package Thermal Characteristics1
Characteristic Symbol Value Unit Notes
Junction-to-ambient thermal resistance, natural convection, single-layer (1s) board RθJA 18 °C/W 1, 2
Junction-to-ambient thermal resistance, natural convection, four-layer (2s2p) board RθJA 13 °C/W 1, 3
Junction-to-ambient thermal resistance, 200 ft/min airflow, single-layer (1s) board RθJMA 13 °C/W 1, 3
Junction-to-ambient thermal resistance, 200 ft/min airflow, four-layer (2s2p) board RθJMA 9°C/W1, 3
Junction-to-board thermal resistance RθJB 5°C/W4
Junction-to-case thermal resistance RθJC < 0.1 °C/W 5
Notes:
1. Junction temperature is a function of die size, on-chip power dissipation, package thermal resistance, mounting site (board)
temperature, ambient temperature, air flow, power dissipation of other components on the board, and board thermal
resistance.
2. Per JEDEC JESD51-2 with the single-layer board (JESD51-3) horizontal.
3. Per JEDEC JESD51-6 with the board (JESD51-7) horizontal.
4. Thermal resistance between the die and the printed-circuit board per JEDEC JESD51-8. Board temperature is measured on
the top surface of the board near the package.
5. This is the thermal resistance between die and case top surface as measured by the cold plate method (MIL SPEC-883
Method 1012.1) with the calculated case temperature. Actual thermal resistance is less than 0.1 °C/W.
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 109
Thermal
clip through the board. Occasionally the s pr ing clip is attached to soldered hooks or to a plastic backing
structure. Screw and spring arrangements are also frequently used.
Figure 59. FC-CBGA Package Exploded Cross-Sectional View with Several Heat Sink Options
There are several commercially-available heat sinks for the MPC8640 provided by the following vendors:
Aavid Thermalloy 603-224-9988
80 Commercial St.
Concord, NH 03301
Internet: www.aavidthermalloy.com
Advanced Thermal Solutions 781-769-2800
89 Access Road #27.
Norwood, MA02062
Internet: www.qats.com
Alpha Novatech 408-749-7601
473 Sapena Ct. #12
Santa Clara, CA 95054
Internet: www.alphanovatech.com
Calgreg Thermal Solutions 888-732-6100
60 Alhambra Road, Suite 1
Warwick, RI 02886
Internet: www.calgreg. com
International Electronic Researc h Corporation (IERC) 818- 842- 7277
413 North Moss St.
Burbank, CA 91502
Internet: www.ctscorp.com
Thermal
Heat Sink HCTE FC-CBGA Package
Heat Sink
Clip
Printed-Circuit Board
Interface Material
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
110 Freescale Semiconductor
Thermal
Millennium Electronics (MEI) 408-436-8770
Loroco Sites
671 East Brokaw Road
San Jose, CA 95112
Internet: www.mei-thermal.com
Tyco Electronics 800-522-6752
Chip Coolers™
P.O . Box 3668
Harrisbur g, PA 17105-3668
Internet: www.chipcoolers.com
Wakefield Engineering 603-635-5102
33 Bridge St.
Pelham, NH 03076
Internet: www.wakefield.com
Ultimately, the final selection of an appropriate heat sink depends on many factors, such as thermal
performance at a given air velocity, spatial volume, mass, attachment method, assembly, and cost.
19.2.1 Internal Package Conduction Resistance
For the exposed-die packaging technology described in Table 71, the intrinsic conduction thermal
resistance paths are as follows:
• The die junction-to-case thermal resistance (the case is actually the top of the exposed silicon die)
• The die junction-to-board thermal resistance
Figure 60 depicts the primary heat transfer path for a package with an attached heat sink mounted to a
printed-circuit board.
Figure 60. C4 Package with Heat Sink Mounted to a Printed-Circuit Board
External Resistance
External Resistance
Internal Resistance
Radiation Convection
Radiation Convection
Heat Sink
Printed-Circuit Board
Thermal Interface Material
Package/Leads
Die Junction
Die/Package
(Note the internal versus external package resistance.)
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 111
Thermal
Heat generated on the active side of the chip is conduc ted through the silicon, then the heat sink attach
material (or thermal interface material), and finally to the heat sink where it is removed by forced-air
convection.
Because the silicon thermal res istance is quite small, the temperature dr op in the silicon ma y be neglected
for a first-order analysis. Thus the thermal interf ace mater ial and the heat sink conduction/convective
therma l resi stances ar e the domi nant term s.
19.2.2 Thermal Interface Materials
A thermal interface material is recommended at the package-to-heat sink interface to minimize the thermal
contact resi stance. Figure 61 shows the thermal performance of three thin-sheet thermal-interface
materials (silicone, graphite/oil, floroether oil), a bare joint, and a joint with thermal grease as a function
of contact pressure. As shown, the performance of these thermal interface materials improves with
increasing contact pressure. The use of thermal grease significantly reduces the interface thermal
resis tance. Tha t is, the ba re joint r esults i n a thermal resistanc e approximately seven times gr eater than the
thermal grease joint.
Often, heat sinks are attached to the package by means of a spring clip to holes in the printed-circuit board
(see Figure 59). Therefore, synthetic grease offers the best thermal performance, considering the low
interface pressure, and is recommended due to the high power dissipation of the MPC8640. Of course, the
selection of any thermal interface material depends on many factors—thermal performance requirements,
manufacturability, service temperature, dielectric properties, cost, and so on.
Figure 61. Thermal Performance of Select Thermal Interface Material
0
0.5
1
1.5
2
0 1020304050607080
Silicone Sheet (0.006 in.)
Bare Joint
Fluoroether Oil Sheet (0.007 in.)
Graphite/Oil Sheet (0.005 in.)
Synthetic Grease
Contact Pressure (psi)
Specific Thermal Resistance (K-in.2/W)
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
112 Freescale Semiconductor
Thermal
The board designer can choose between several types of thermal interface. Heat sink adhesive materials
should be selected based on high conductivity and mechanical strength to meet equipment shock/vibration
requirements. There are several commercially available thermal interfaces and adhesive materials
provided by the following vendors:
The Bergquist Company 800-347-4572
18930 West 78th St.
Chanhassen, MN 55317
Internet: www.bergquistcompany.com
Chomerics, Inc. 781-935-4850
77 Dragon Ct.
Woburn, MA 01801
Internet: www.chomerics.com
Dow-Corning Corporat ion 800-248-2481
Corporate Center
PO Box 994
Midland, MI 48686-0994
Internet: www.dowcorning.com
Shin-Etsu MicroSi, Inc. 888-642-7674
10028 S. 51st St.
Phoenix, AZ 85044
Internet: www.microsi.com
Thermagon Inc. 888-246-9050
4707 Detroit Ave.
Cleveland, OH 44102
Internet: www.thermagon.com
The following section provides a heat sink selection example using one of the commercially available heat
sinks.
19.2.3 Heat Sink Selection Example
For preliminary heat sink sizing, the die-junction temperature can be expressed as follows:
Tj = T i + Tr + (R θJC + Rθint + Rθsa) × Pd
where:
Tj is the die-junction temperature
Ti is the inlet cabinet ambient temperature
Tr is the air temperature rise within the computer cabinet
RθJC is the junction-to-case thermal resistance
Rθint is the adhesive or interface material thermal resistance
Rθsa is the heat sink base-to- am bient thermal res istance
Pd is the power dissipated by the device
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 113
Thermal
During oper ation, the die-junction temperatures ( Tj) should be maintained less than the value specified in
Table 2. The temperature of air cooling the component greatly depends on the ambient inlet air temperature
and the air temperature rise within the electronic cabinet. An electronic cabinet inlet-air temperature (T i)
may range from 30 to 40 °C. The air temperature rise within a cabinet (Tr) may be in the range of
5to10°C. The thermal resistance of t he thermal interface material (Rθint) is typically about 0.2 °C/W. For
example, assuming a T i of 30 °C, a Tr of 5 °C, a package RθJC = 0.1, and a typical power consumption (Pd)
of 43.4 W, the following expression for Tj is obtained:
Die-junction temperature: Tj = 30 °C + 5 °C + ( 0 .1 °C/W + 0.2 °C/W + θsa) × 43.4 W
For this example, a Rθsavalue of 1.32 °C/W or less is required to maintain the die junction temperature
below the maximum value of Table 2.
Though the die junction-to-ambient and the heat sink-to-ambient thermal resistances are a common
figure-of-merit used for comparing the thermal performance of various microelectronic packaging
technologies, one should exercise caution when only using this metric in determining thermal management
because no single parameter can adequate ly describe three-dimens ional heat flow. The final die-junction
operating temperature is not only a function of the component-level the rmal resistance, but the
system-level design and its operating conditions. In addition to the component's power consumption, a
number of factors affect the final operating die-junction temperature—airflow, board population (local
heat flux of adjacent components), heat sink efficiency, heat sink placement, next-level interconnect
technology, system air temperature rise, altitude, and so on.
Due to the complexity and variety of system-leve l boundary conditions for today's microelectronic
equipment, the combi ned ef fects of the heat transfer mechanisms (radiation, co nvection, and conduction)
may vary widely. For these reasons, we recommend using conjugate heat tr ansfer models f or the boar d as
well as system-level designs.
For system thermal modeling, the MPC8640 thermal model is shown in Figure 62. Four cuboids are used
to represent this device. The die is modeled as 12.4 ×15.3 mm at a thickness of 0.86 mm. See Section 3,
“Power Characteristics,” for power dissipation details. The substrate is modeled as a single block
33×33×1.2 mm with orthotropic conductivity: 13.5 W/(m • K) in the xy-plane and 5.3 W/(m • K) in the
z-direction. The die is centered on the substrate. The bump/underfil l layer is modeled as a collapsed
thermal resistance between the die and substrate with a conductivity of 5.3 W/(m • K) in the thickness
dimension of 0.07 mm. Because the bump/underfill is modeled with zero physical dimension (collapsed
height), the die thickness was slightly enlar ged to provide the correct height. The C5 solder layer is
modeled as a cuboid with dimensions 33x33x0.4 mm and orthotropic thermal conductivity of 0.034 W/(m
• K) in the xy-plane and 9.6 W/(m • K) in the z-direction. An LGA solder layer would be modeled as a
collapsed thermal resistance with thermal conductivity of 9.6W/(m • K) and an effective height of 0 .1 mm.
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
114 Freescale Semiconductor
Thermal
The thermal model uses a pproximate dimensions to reduc e gri d. Please refer to the case outline for a ct ual
dimensions.
Figure 62. Recommended Thermal Model of MPC8640
19.2.4 Temperature Diode
The MPC8640 has a temperature diode on the microprocessor that can be used in conjunction with other
system temperature monitoring devices (such as Analog Devices, ADT7461™). These devices use the
negative temperature coefficient of a diode operated at a constant current to determine th e temperature of
the microprocessor and its environment. For proper operation, the monitoring device used should
auto-calibrate the device by canceling out the VBE variation of each MPC8640’s internal diode.
The following are the specifications of the MPC8640 on-board temperature diode:
Vf > 0.40 V
Vf < 0.90 V
Operating range 2–300 μA
Diode leakage < 10 nA at 125 °C
Ideality factor over 5–150 μA at 60 °C: n = 1.0275 ± 0.9%
Bump and Underfill
Die
Substrate
C5 solder layer
Die
Substrate
Side View of Model (Not to Scale)
Top View of Model (Not to Scale)
x
y
z
Conductivity Value Unit
Die (12.4 ×15.3 ×0.86 mm)
Silicon Temperature
dependent
Bump and Underfill (12.4 × 15.3 × 0.07 mm)
Collapsed Resistance
kz5.3 W/(m • K)
Substrate (33 × 33 × 1.2 mm)
kx13.5 W/(m • K)
ky13.5
kz5.3
C5 Solder layer (33 × 33 × 0.4 mm)
kx0.034 W/(m • K)
ky0.034
kz9.6
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 115
Thermal
Ideality factor is defined as the deviation from the ideal diode equation:
Another useful equation is:
Where:
Ifw = Forward current
Is= Satu ratio n c u rre nt
Vd= Voltage at diode
Vf= Voltage forward biased
VH= Diode voltage while IH is flowing
VL= Diode voltage while IL is flowing
IH= Larger diode bias current
IL= Smaller diode bias current
q = Charge of electron (1.6 x 10 –19 C)
n = Ideality fa ctor (normally 1.0)
K = Boltzman’s constant (1.38 x 10–23 Joules/K)
T = Temperature (Kelvins)
The ratio of IH to IL is usually selected to be 10:1. The above simplifies to the following:
Solving for T, the equation becomes:
Ifw = Is e – 1
qVf___
nKT
VH – VL = n
ln
KT
__
q
IH__
IL
VH – VL = 1.986 × 10–4 × nT
nT = VH – VL
__________
1.986 × 10–4
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
116 Freescale Semiconductor
System Design Information
20 System Design Information
This section provides electrical and thermal design recommendations for successful application of the
MPC8640.
20.1 System Clocking
This device includes six PLLs, as follows:
• The platform PLL generates the platform clock from the externally supplied SYSCLK input . The
frequency ratio between the platform and SYSCLK is selected using the platform PLL ratio
configuration bits as described in Section 18.2, “MPX to SYSCLK PLL Ratio.”
• The dual e600 Core PLLs generate the e600 clock from the externally supplied input.
• The local bus PLL generates the clock for the local bus.
• There ar e two internal PLLs for the SerDes block.
20.2 Power Supply Design and Sequencing
This section describes the power supply design and sequencing.
20.2.1 PLL Power Supply Filtering
Each of the PLLs listed in Section 20.1, “System C locking,” is provided with power through independent
power supply pins.
There are a number of ways to reliably provid e power to the PLLs, but the recommended solution is to
provide independent filter circuits per PLL power supply as illustrated in Figure 64, one to each of the
AVDD type pins. By providing independent filters to each PLL the opportunity to cause noise injection
from one PLL to the other is reduced.
This circuit is intended to filter noise in the PLLs resonant frequency range from a 500 kHz to 10 MHz
range. It should be built with surface mount capacitors with minimum Ef f ective Series Inductance (ESL).
Consistent with the recommendations of Dr . Howard Johnson in High Speed Digital Design: A Handbook
of Black Magic (Prentice Hall, 1993), multiple small capacitors of equal value are recommended over a
single large value capacitor.
Each circuit should be placed as close as possible to the specific AVDD type pin being supplied to minimize
noise coupled from nearby circuits. It should be pos sible to route directly f rom the capacitors to the AVDD
type pin, which is on the periphe ry of the footprint, without the inductance of vias.
Figure 63 and Figure 64 show the PLL power supply filter circuits for the platform and cores, respectively .
Figure 63. MPC8640 PLL Power Supply Filter Circuit (for platform and Local Bus)
2.2 µF 2.2 µF
GND
Low ESL Surface Mount Capacitors
10 Ω
AVDD_PLAT, AVDD_LB;
VDD_PLAT
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 117
System Design Information
Figure 64. MPC8640 PLL Power Supply Filter Circuit (for cores)
The AV DD_SRDSn signals provide power for the analog portions of the SerDes PLL. To ensure stabilit y
of the internal clock, the power supplied to the PLL is filtered using a circuit similar to the one shown in
following figure. For maximum effe ctive ne ss, the filter circuit is placed as closely as possible to the
AVDD_SRDSn balls to ensure it filters out as much noise as possible. The ground connection should be
near the AVDD_SRDSn balls. The 0.003-µF capacitor is closest to the balls, followed by the two 2.2-µF
capacitors, and finally the 1-Ω resistor to the board supply plane. The capacitors are connected from
AVDD_SRDSn to the ground plane. Use ceramic chip capacitors with the highest possible self-resonant
frequency. All traces should be kept short, wide, and direct.
Figure 65. SerDes PLL Power Supply Filter
Note the following:
•AV
DD_SRDSn should be a filtered version of SVDD.
• Signals on the SerDes interface are fed from the SVDD power plan.
20.2.2 PLL Power Supply Sequencing
For details on power sequencing for the AVDD type and supplies refer to S ecti on 2.2, “Power-Up/Down
Sequence.”
20.3 Decoupling Recommendations
Due to large address and data buses, and high operating frequencies, the device can generate transient
power surges and high frequency noise in its power supply , especially while driving large capacitive loads.
This noise must be prevented from reaching other components in the MPC8640 system, and the device
itself requires a clean, tightly regulated source of power. Therefore, it is recommended that the system
VDD_Core0/1 AVDD_Core0/1
2.2 µF 2.2 µF
GND Low ESL Surface Mount Capacitors
10 Ω
Filter Circuit (should not be used for Single core device)
Note: For single core device the filter circuit (in the dashed box) should
be removed and AVDD_Core1 should be tied to ground with a weak
(2–10 kΩ) pull-down resistor.
2.2 µF 10.003 µF
GND
1.0 Ω
AVDD_SRDS
n
1. An 0805 sized capacitor is recommended for system initial bring-up.
SVDD
2.2 µF 1
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
118 Freescale Semiconductor
System Design Information
designer place at least one decoupling capacitor at each OVDD, Dn_GVDD, LVDD, TVDD, V DD_Coren,
and VDD_PLAT pin of the device. These decoupling capacitors should receive their power from separate
OVDD, Dn_GVDD, LVDD, TVDD, VDD_Coren, and VDD_PLAT and GND power planes in the PCB,
utilizing short traces to minimize inductance. Capacitors may be placed directly under the device using a
standard escape pattern. Others may surround the part.
These capacitors should have a value of 0.01 or 0.1 µF. Only ceramic SMT (surface mount technology)
capacitors should be used to minimize lead inductance, preferably 0402 or 0603 s izes.
In addition, it is recommended that there be several bulk storage capacitors distributed around the PCB,
feeding the OVDD, Dn_GVDD, LVDD, TVDD, V DD_Coren, and V DD_PLAT planes , to enable quick
recharging of the smaller chip capacitors. They should also be connected to the power and ground planes
through two vias to minimize inductance. Suggested bulk capacitors—100–330 µF (AVX TPS tantalum
or Sanyo OSCON).
20.4 SerDes Block Power Supply Decoupling Recommendations
The SerDes block requires a clean, tightly regulated source of power (SVDD and XVDD_SRDSn) to ensure
low jitter on transmit and reliable recovery of data in the receiver. An appropriate decoupling s cheme is
outlined below.
Only surface mount technology (SMT) capacitors should be used to minimize inductance. Connections
from all capacitors to power and ground should be done with multiple vias to further reduce inductance.
• First, the board should have at least 10 × 10-nF SMT ceramic chip capacitors as close as possible
to the s upply balls of the d evice. Where the board has blind vias, these capacitors should be placed
directly below the chip supply and ground connections. Where the board does not have blind vias,
these capacitors should be placed in a ring around the device as close to the supply and ground
connections as possible.
• Second, there should be a 1-µF ceramic chip capacitor on each side of the device. This should be
done for all SerDes supplies.
• Third, between the device and any SerDes voltage regulator there should be a 10-µF, low
equivalent series re sistance (ESR) SMT tantalum chip capacitor and a 100-µF, low ESR SMT
tantalum chip capacitor. This should be done for all SerDes supplies.
20.5 Connection Recommendations
To ensure reliable operation, it is highly recommended to connect unused inputs to an appropriate signal
level. In general all unused active low inputs should be tied to OVDD, Dn_GVDD, LVDD, TV DD,
VDD_Coren, and VDD_PLAT , XVDD_SRDSn, and SVDD as r equired and unused active high inputs should
be connected to GND. All NC (no-connect) signals must remain unconnected.
The following list explains the special cases:
• DDR—If one of the DDR ports is not being us ed the power supply pins for that port can be
connected to ground so that there is no need to connect the individual unused inputs of that port to
ground. Note that these power supplies can only be powered up again at reset for functionality to
occur on the DDR port. Power supplies for other functional buses should remain powered.
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 119
System Design Information
• Local Bus—If parity is not used, tie LDP[0:3] to ground via a 4.7-kΩ resistor , tie LPBSE to OVDD
via a 4.7-kΩ resistor (pull-up resistor). For systems which boot from Local Bus
(GPCM)-co ntrolled flash, a pull-up on LGPL4 is required.
• SerDes—Receiver lanes configured for PCI Express are allowed to be disconnected (as woul d
occur when a PCI Express slot is connected but not populated). Directions for terminating the
SerDes signals is discussed in Section 20.5.1, “Guidelines for High-Speed Interface T e rmination.”
20.5.1 Guidelines for High-Speed Interface Termination
This section provides the guidelines for high-spe e d interfac e termination.
20.5.1.1 SerDes Interface
The high-speed SerDes interface can be disabled through the POR input cfg_io_ports[0:3] and through the
DEVDISR register in software. If a SerDes port is disabl ed through the POR input the user cannot enable
it through the DEVDISR r egi ster in s oftware. However , if a SerDes port is enabled through the POR input
the user can disable it through the DEVDISR register in software. Disabling a SerDes port through
software should be done on a temporary basis. Power is always required for the SerDes interface, even if
the port is disabled through either mechanism. Table 72 describes the possible enabled/disabled scenarios
for a SerDes port. The termination rec omme ndations must be followed for each port.
If the high-speed SerDes port requires complete or partial termination, t he unused pins should be
termina ted as described in this section.
Table 72. SerDes Port Enabled/Disabled Configurations
Disabled Through POR Input Enabled Through POR Input
Enabled through DEVDISR
SerDes port is disabled (and cannot
be enabled through DEVDISR)
Complete termination required
(Reference Clock not required)
SerDes port is enabled
Partial termination may be required1
(Reference Clock is required)
1Partial Termination when a SerDes port is enabled through both POR input and DEVDISR is determined by the SerDes
port mode. If the port is in ×8 PCI Express mode, no termination is required because all pins are being used. If the port
is in ×1/×2/×4 PCI Express mode, termination is required on the unused pins. If the port is in ×4 serial RapidIO mode,
termination is required on the unused pins.
Disabled through DEVDISR
SerDes port is disabled (through
POR input)
Complete termination required
(Reference Clock not required)
SerDes port is disabled after software
disables port
Same termination requirements as when the
port is enabled through POR input2
(Reference Clock is required)
2If a SerDes port is enabled through the POR input and then disabled through DEVDISR, no hardware changes are
required. Termination of the SerDes port should follow what is required when the port is enabled through both POR
input and DEVDISR. See Note 1 for more information.
Note:
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
120 Freescale Semiconductor
System Design Information
The following pins must be left unconnected (floating):
•SDn_TX[7:0]
•SDn_TX[7:0]
The following pins must be connected to GND:
•SDn_RX[7:0]
•SD
n_RX[7:0]
•SDn_REF_CLK
•SDn_REF_CLK
NOTE
It is recommended to power down the unused lane through SRDS1CR1[0:7]
register (offset = 0xE_0F08) and SRDS2CR1[0:7] register
(of fset = 0xE_0F44.) (This prevents the oscillations and holds the receiver
output in a fixed state.) that maps to SERDES lane 0 to lane 7 accordingly.
For other directions on reserved or no-connects pins see Section 17, “Signal Listings.”
20.6 Pull-Up and Pull-Down Resistor Requirements
The MPC8640 requires weak pull-up resistors (2–10 kΩ is recommended) on all open drain type pins.
The following pins must not be pulled down during power -on reset: TSEC4_TXD[4], LGPL0/L SDA10,
LGPL1/LSDWE, TRIG_OUT/READY, and D1_MSRCID[2].
The following are factory test pins and require strong pull-up resistors (100Ω –1 kΩ) to OVDD
LSSD_MODE, TEST_MODE[0:3].The following pins require weak pull-up resistors (2–10 kΩ) to their
specific power supplies: LCS[0: 4 ], LCS [5]/DMA_DREQ2, LCS[6]/DMA_DACK[2],
LCS[7]/DMA_DDONE[2], IRQ_OUT, IIC1_SDA, IIC1_SCL, IIC2_SDA, IIC2_SCL, and
CKSTP_OUT.
The following pins should be pulled to ground with a 100-Ω resistor: SD1_IMP_CAL_TX,
SD2_IMP_CAL_TX. The following pins should be pulled to ground with a 200-Ω re si st o r:
SD1_IMP_CAL_RX, SD2_IMP_CAL_RX
TSECn_TX_EN signals require an external 4.7-kΩ pull down resistor to prevent PHY from seeing a valid
Tr an smit Enable before it is actively driven.
When the platform frequency is 400 MHz, TSEC1_TXD[1] must be pulled down at reset.
TSEC2_TXD[4] and TSEC2_TX_ER pins function as cfg_dram_type[0 or 1] at reset and MUST BE
VAL I D BEFORE HRESET ASSERT ION when coming out of device sleep mode.
20.6.1 Special instructions for Single Core device
The mechanical drawing for the single core device does not have all the solder balls that exist on the single
core device. This includes all the balls for VDD_Core1 and SENS EVDD_Core1 which exist on the
package for the dual core device, but not on the single core package. A solder ball is present for
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 121
System Design Information
SENSEVSS_Core1 and needs to be connected to ground with a weak (2–10 kΩ) pull down resistor.
Lik ew i se , AVDD_Core1 needs to be pulled to ground as shown in Figure 64.
The mechanical drawing for the single core device is located in Section 16.2, “Mechanical Dimensions of
the MPC8640 FC-CBGA.”
For other pin pull-up or pull-down recommendations of si gnals, please see Section 17, “Signal Listings.”
20.7 Output Buffer DC Impedance
The MPC8640 dr ivers are character ized over process, voltage, and temperature. For all buses, the driver
is a push-pull single-ended driver type (open drain for I2C).
To measure Z0 for the single-ended drivers, an external resistor is connected from the chip pad to OVDD
or GND. Then, the value of each resistor is varied until the pad voltage is OVDD/2 (see Figure 66). The
output impedance is the average of two components, the resistances of the pull-up and pull -down devices.
When data is held high, SW1 is closed (SW2 is open) and RP is trimmed until the voltage at the pad equals
OVDD/2. RP then becomes the resistance of the pull-up devices. RP and RN are designed to be close to each
other in value. Then, Z0 = (RP + RN)÷2.
Figure 66. Driver Impedance Measurement
Table 73 summa rizes the signal impe dance targe ts. The driver impedances are targeted at minimum VDD,
nominal OVDD, 105 °C.
Table 73. Impedance Characteristics
Impedance
DUART, Control,
Configuration, Power
Management
PCI
Express DDR DRAM Symbol Unit
RN43 Target 25 Target 20 Target Z0W
RP43 Target 25 Target 20 Target Z0W
Note: Nominal supply voltages. See Ta b le 1 , Tj = 105 °C.
OVDD
OGND
RP
RN
Pad
Data
SW1
SW2
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
122 Freescale Semiconductor
System Design Information
20.8 Configuration Pin Muxing
The MPC8640 provides the user with power- on configuration options whi ch can be set through the use of
external pull-up or pull-down resistors of 4.7 kΩ on certain output pins (see customer visible configuration
pins). These pins are generally used as output only pins in normal operation.
While HRESET is asserted however, these pins are treate d as inputs. The value presented on these pins
while HRESET is asserted, is latched when HRESET deasserts, at which time the input receiver is disabled
and the I/O circuit takes on its normal function. Most of these sampled configuration pins are equipped
with an on-chip gated resistor of approximately 20 kΩ. This value should permit the 4.7-kΩ resistor to pull
the configuration pin to a valid logic low level. The pull-up resistor is enabled only du ring HRESET (and
for platform/system clocks after HRESET deassertion to ensure capture of t he reset value). When the input
receiver is disabled, the pull-up is also, thus allowing functional operation of the pin as an output with
minima l signal quality or delay disrupti on. The def aul t value for all configuration bits treated this way has
been encoded such that a high voltage level puts the device into the default state and external resistors are
needed only when non-default settings are required by the user.
Careful board layout with stubless connections to these pull-down resistors coupled with the large value
of the pull-down resistor should minimize the disruption of signal quality or speed for output pins thus
configured.
The platform PLL ratio and e600 PLL ratio configuration pins are not equipped with these default pul l-up
devices.
20.9 JTAG Configuration Signals
Correct operation of the JTAG interface requires configuration of a group of system control pin s as
demonstrated in Figure 68. Care must be taken to ensure that these pins are maintained at a valid deasserted
state under normal operating conditions as most have asynchronous behavior and spurious assertion will
give unpredictable results.
Boundar y- scan testi ng is enabl ed th rough the JTAG interface signals. The TRST sign al is optional in th e
IEEE 1149.1 specification, but is provided on all pr ocessors that implement the Power Architecture
techno logy. The device requires TRST to be as serted dur ing res et conditi ons to ensur e the JTA G boundary
logic does not interfere wit h nor mal chip op eration . While it is possible to force the TAP controller to the
reset state using only the TCK and TMS signals, more reliable power-on reset performance will be obtained
if the TRST signa l is asse rte d during power -on reset. Beca use the JTAG interface is also us ed for accessin g
the common on-chip pr oces s or (COP) function, s imply tying TRST to HRESET is not practical.
The COP function of these processors allows a remote computer system (typically a PC with dedicated
hardware and debugging software) to access and control the internal operations of the processor . The COP
port connects primarily through the JTAG interface of the processor, with some additional status
monitoring signals. T he COP port r equire s the a bility to independently assert HR ESET or T RST in order
to fully control the processor. If the target system has independent reset sources, such as voltage monitors,
watchdog timers, power supply failures, or push-button switches, then the COP reset signals must be
merge d into these signals with logic.
The arrangement shown in Figure 67 allows the COP port to independently assert HRESET or TRST,
while ensuring that the target can drive HRESET as well.
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 123
System Design Information
The COP interface has a standard header, shown in Figure 67, for connection to the target system, and is
based on the 0.025" square-post, 0.100" centered header assembly (often called a Berg header). The
connector typically has pin 14 removed as a connector key.
The COP header adds many benefits such as breakpoints, watchpoints, register and memory
examination/modification, and other standard debugger features. An inexpensive option can be to leave
the COP header unpopulated until needed.
There is no standardized way to number the COP header shown in Figure 67; consequently , many different
pin numbers have been observed from emulator vendors. Some are numbered top- to- bottom then
left-to-right, while others use left-to-right then top-to-bottom, while still others number the pins counter
clockwise from pin 1 (as with an IC). Regardless of the numbering, the signal placement recommended in
Figure 67 is common to all known emulators.
For a m ulti-processor non-daisy chain configuration, Figure 68, can be dupli cated for each processor. The
recommended daisy chain configuration is shown in Figure 69. Please consult with your tool vendor to
determine which configuration is supported by their emulato r.
20.9.1 Termination of Unused Signals
If the JTAG interface and COP header will not be used, Freescale recommends the following connections:
•TRST should be tied to HRESET through a 0 kΩ isolation resistor so that it is asserted when the
system reset signal (HRESET) is asserted, ens u ring that the JTAG scan chain is initia lize d during
the power- on reset flow. Freescale recommends that the COP header be designed into the system
as shown in Figure 68. If this is not possible, the isolation resistor will allow future access to TRST
in case a JTAG interface may need to be wire d onto the system in future debug situations.
• Tie TC K to OV DD through a 10 kΩ resistor. This will prevent TCK from changing state and
reading incorr ect data into the device.
• No connection is required for TDI, TMS, or TDO.
Figure 67. COP Connector Physical Pinout
3
13
9
5
1
6
10
15
11
7
16
12
8
4
KEY
No pin
12
COP_TDO
COP_TDI
NC
NC
COP_TRST
COP_VDD_SENSE
COP_CHKSTP_IN
NC
NC
GND
COP_TCK
COP_TMS
COP_SRESET
COP_HRESET
COP_CHKSTP_OUT
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
124 Freescale Semiconductor
System Design Information
Figure 68. JTAG/COP Interface Connection for one MPC8640 device
HRESET
From Target
Board Sources
COP_HRESET
13
COP_SRESET
SRESET1
NC
11
COP_VDD_SENSE2
6
5
15
10 Ω
10 kΩ
10 kΩ
COP_CHKSTP_IN CKSTP_IN
8
COP_TMS
COP_TDO
COP_TDI
COP_TCK
TMS
TDO
TDI
9
1
3
4COP_TRST
7
16
2
10
12
(if any)
COP Header
14 3
3. The KEY location (pin 14) is not physically present on the COP header.
10 kΩ
TRST1
10 kΩ
10 kΩ
10 kΩ
CKSTP_OUT
COP_CHKSTP_OUT
3
13
9
5
1
6
10
15
11
7
16
12
8
4
KEY
No pin
COP Connector
Physical Pinout
1
2
NC
SRESET1
NC
OVDD
10 kΩ
10 kΩHRESET1
4. Although pin 12 is defined as a No-Connect, some debug tools may use pin 12 as an additional GND pin for
improved signal integrity.
TCK
4
5
5.
This switch is included as a precaution for BSDL testing. The switch should be open during BSDL testing to avoid
accidentally asserting the TRST line. If BSDL testing is not being performed, this switch should be closed or removed.
10 kΩ
SRESET010 kΩSRESET0
2. Populate this with a 10 Ω resistor for short-circuit/current-limiting protection.
1. The COP port and target board should be able to independently assert HRESET and TRST to the processor
in order to fully control the processor as shown here.
Notes:
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 125
System Design Information
Figure 69. JTAG/COP Interface Connection for Multiple MPC8640 Devices in Daisy Chain Configuration
COP_SRESET
COP_TRST
COP_HRESET
JTAG/COP
SRESET1
SRESET0
TDI
Header
HRESET
TRST
CHKSTP_OUT
CHKSTP_IN
TMS
TCK
TDO
10k
Ω
10k
Ω
SRESET1
HRESET
From Target
Board Sources
(if any)
COP_TDI 11
13
3
COP_CHKSTP_OUT
COP_CHKSTP_IN
SRESET1
SRESET0
TDI
TRST
CHKSTP_OUT
CHKSTP_IN
TMS
TCK
TDO
4
15
8
COP_TMS
2
10
COP_TCK
GND
14
9
7
6
NC
NC
COP_VDD_SENSE
16
COP_TDO
1
3
12
2HRESET
OV
DD
SRESET0
4
4
4
4
10 k
Ω
Notes:
1. Populate this with a 10-
Ω
resistor for short circuit/current-limiting protection.
2. KEY location; pin 14 is not physically present on the COP header.
3. Use a AND gate with sufficient drive strength to drive two inputs.
4. The COP port and target board should be able to independently assert HRESET and TRST to the processor in order
to fully control the processor as shown above.
10k
Ω
10k
Ω
10k
Ω
10k
Ω
10k
Ω
10k
Ω
10k
Ω
6
5
10
Ω
MPC8640
MPC8640
3
5. This switch is included as a precaution for BSDL testing. The switch should be open during BSDL testing to avoid
accidentally asserting the TRST line. If BSDL testing is not being performed, this switch should be closed or removed.
6. Although pin 12 is defined as a No-Connect, some debug tools may use pin 12 as an additional GND pin for
improved signal integrity.
5NC
1
OV
DD
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
126 Freescale Semiconductor
Ordering Information
21 Ordering Information
Ordering information for the parts fully covered by this specification document is provided in
Section 21.1, “Part Numbers Fully Addressed by This Document.”
21.1 Part Numbers Fully Addressed by This Document
Table 74 provides the Freescale part numbering nomenclature for the MPC8640. Note that the individual
part numbers correspond to a maximum processor core frequency. For available frequencies, contact your
local Freescale sales office. In addition to the processor frequency, the part numbering scheme also
includes an appli cation modifier which may specify special application conditions. Each part num ber also
contains a revision code which refers to the die mask revision number.
Table 74. Part Numbering Nomenclature
uu nnnn D w xx yyyy a z
Product
Code
Part
Identifier
Core
Count Temp Package1
Core
Processor
Frequency 2
(MHz)
DDR speed
(MHz) Product Revision Level
MC58640
Blank =
Single Core
Blank:
0°C to 105°C
T:
–40 °C to
105 °C
HX = High-lead
HCTE FC-CBGA
VU = RoHS lead-f
ree HCTE
FC-CBGA
1000, 1067,
1250
N = 533 MHz4
H = 500 MHz
Revision C = 2.1
System Version Register
Value for Rev C:
0x8090_0021 MPC8640
0x8090_0121 MPC8640D
Revision E = 3.0
System Version Register
Value for Rev E:
0x8090_0030 MPC8640
0x8090_0130 MPC8640D
D =
Dual Core
Notes:
1. See Section 16, “Package,” for more information on available package types.
2. Processor core frequencies supported by parts addressed by this specification only. Not all parts described in this specification
support all core frequencies. Additionally, parts addressed by part number specifications may support other maximum core
frequencies.
3. The P prefix in a Freescale part number designates a “Pilot Production Prototype” as defined by Freescale SOP 3-13. These parts
have only preliminary reliability and characterization data. Before pilot production prototypes may be shipped, written
authorization from the customer must be on file in the applicable sales office acknowledging the qualification status and the fact
that product changes may still occur while shipping pilot production prototypes.
4. Part Number MC8640xxx1067Nz is our low VDD_Core
n
device. VDD_Core
n
= 0.95 V and VDD_PLAT = 1.05 V.
5. MC - Qualified production
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 127
Ordering Information
Table 75 shows the parts that are available for ordering and their operating conditions.
Table 75. Part Offerings and Operating Conditions
Part Offerings1
1Note that the “w” represents the operating temperature range. The “xx” in the part marking represents the
package option. The “z” represents the product revision level. For more information see Ta b l e 7 4 .
Operating Conditions
MC8640Dwxx1250Hz Dual core
Max CPU speed = 1250 MHz,
Max DDR = 500 MHz
Core Voltage = 1.05 volts
MC8640Dwxx1000Hz Dual core
Max CPU speed = 1000 MHz,
Max DDR = 500 MHz
Core Voltage = 1.05 volts
MC8640Dwxx1067Nz Dual core
MAX CPU speed = 1067 MHz,
MAX DDR = 533 MHz
Core Voltage = 0.95 volts
MC8640wxx1250Hz Single core
Max CPU speed = 1250 MHz,
Max DDR = 500 MHz
Core Voltage = 1.05 volts
MC8640wxx1000Hz Single core
Max CPU speed = 1000 MHz,
Max DDR = 500 MHz
Core Voltage = 1.05 volts
MC8640wxx1067Nz Single core
Max CPU speed = 1067 MHz,
Max DDR = 533 MHz
Core Voltage = 0.95 volts
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
128 Freescale Semiconductor
Document Revision History
21.2 Part Marking
Parts are marked as the example shown in Figure 70.
Figure 70. Part Marking for FC-CBGA Device
22 Document Revision History
Table 76 provides a revision history for the MPC8640D hardware specification.
Table 76. Document Revision History
Revision Date Substantive Change(s)
3 07/2009 • Updated Ta bl e 7 4 , “Part Numbering Nomenclature,” and Ta b l e 7 5 , “Part Offerings and Operating
Conditions,” to include silicon revision 3.0 part markings.
2 06/2009 • Added Table 5 , “MPC8640D Individual Supply Maximum Power Dissipation 1.”
• Added Note 8 to Ta b le 4 9 , “Differential Transmitter Output Specifications.”
MC8640x
xxnnnnxx
TWLYYWW
MMMMMM
YWWLAZ
YWWLAZ is the assembly traceability code.
MMMMMM is the M00 (mask) number.
TWLYYWW is the test code
NOTE:
8640D
MPC8640 and MPC8640D Integrated Host Processor Hardware Specifications, Rev. 3
Freescale Semiconductor 129
Document Revision History
1 11/2008 • Removed voltage option of 1.10 V from Ta bl e 2 because it is not supported by MPC8640D or MPC8640
• Updated Table 4 and Ta b l e 6 with the new 1067/533 MHz device offering. This includes updated Power
Specifications.
• Added Section 4.4, “Platform Frequency Requirements for PCI-Express and Serial RapidIO”
• Updated Section 6, “DDR and DDR2 SDRAM” to include 533 MHz.
• Added core frequency of 1067 to Ta ble 6 4, Ta b le 6 5 , Ta b l e 6 6 and Ta bl e 6 7
• Changed Max Memory clock frequency from 250 MHz to 266 MHz in Ta bl e 6 5
• Changed Max MPX/Platform clock Frequency from 500 MHz to 533 MHz in Ta bl e 6 6
• Changed Max Local Bus clock speed from 1 MHz to 133 MHz in Ta b l e 6 7
• Added MPX:Sysclk Ratio of 8:1 to Ta b l e 6 8
• Added Core:MPX Ratio of 3:1 to Ta b l e 6 9
• Updated Ta bl e 7 0 to include 533 MPX clock frequency
• Changed the Extended Temp range part numbering ‘w’ to be T instead of an H in Ta ble 7 4
• Changed the DDR speed part numbering N to stand for 533 MHz instead of 500 MHz in Table 7 4
• Removed the statement “Note that core processor speed of 1500 MHz is only available for the
MPC8640D (dual core)” from Note 2 in Table 74 because MPC8640D is not offered at 1500 MHz core.
• Removed the part offering MC8640Dwxx1000NC which is replaced with MC8640Dwxx1067NC and
removed MC8640wxx1000NC replaced with MC8640wxx1067NC in Table 75
• Added Note 8 to Figure 57 and Figure 58.
0 07/2008 • Initial Release
Table 76. Document Revision History
Revision Date Substantive Change(s)
Document Number: MPC8640DEC
Rev. 3
07/2009
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