T1610G-YB-31-DB - LSI CORPORATION

DB08-000275-03 May 2006 1 of 30

LSISAS1064E PCI Express to 4-Port

Serial Attached SCSI Controller

Datasheet

Version 2.0

The LSISAS1064E is a four-port, 3.0 Gbit/s SAS/SATA controller that is

compliant with the Fusion-MPT™(Message Passing Technology)

architecture, provides an eight-lane PCI Express interface, and supports

Integrated RAID™technology. The PCI Express software is backward

compatible with previous revisions of the PCI bus and PCI-X bus. The

LSISAS1064E supports the PCI Express Base Speciﬁcation, Revision

1.0a, and the ANSI Serial Attached SCSI Standard, Revision 1.1.

Figure 1 and Figure 2 provide examples of LSISAS1064E applications.

The point-to-point interconnect feature of the PCI Express bus limits the

electrical load on links, allowing increased transmission and reception

frequencies. The PCI Express transmission and reception data rates for

each full-duplex interconnect is 2.5 Gbits/s. The LSISAS1064E has eight

PCI Express phys, which provide host-side possible maximum

transmission and reception rates of 4.0 Gbytes/s. The LSISAS1064E

supports x8, x4, and x1 PCI Express link widths, and automatically

downshifts if plugged into either a x4 connector or into a x8 connector

that is wired as a x4 connector. The serial PCI Express interconnect

between devices lowers the number of pins per device, which reduces

both the PCI Express board design costs and the overall board design

complexity. The serial connection also makes the PCI Express

performance highly scalable.

Figure 1 LSISAS1064E Direct-Connect Example

Flash ROM/

LSISAS1064E

PCI Express to SAS Controller

NVSRAM

I2C

PCI Express Interface 32-bit Memory

Address/Data

Bus

SAS/SATA

Drives

Serial

Interface

2 of 30 LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller

Figure 2 LSISAS1064E Controller and LSISASx12 Expander

Example

PCI Express implements a switch-based technology to interconnect a

large number of devices. Communication over the serial interconnect is

accomplished using packet-based communication protocol. Quality of

Service (QOS) features provide differentiated transmission performance

for different applications. Hot Plug/Hot Swap support enables “always-on”

systems. Enhanced error handling features, such as end-to-end CRC

(ECRC) and Advanced Error Reporting, make PCI Express suitable for

robust, high-end server applications. Hot Plug, power management, error

handling, and interrupt signaling are accomplished using packet-based

messaging rather than sideband signals. This keeps the device pin count

low and reduces the system cost.

Each of the four SAS phys on the LSISAS1064E is capable of SAS/SATA

link rates of 3.0 Gbits/s and 1.5 Gbits/s. The user can conﬁgure ports as

wide or narrow. Narrow ports have one phy per port. Wide ports have

two, three, or four phys per port. Each port supports the SSP, SMP, STP,

and SATA protocols.

LSISAS1064E

LSISASx12

Flash ROM/

32-bit Memory

Address/Data

Bus NVSRAM

I2C

LSISASx12

SAS/SATA

Drives

PCI Express Interface

SAS/SATA

Drives

SAS/SATA

Drives SAS/SATA

Drives

Serial

Interface

LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller 3 of 30

The SAS interface uses the proven SCSI command set to ensure reliable

data transfers, while providing the connectivity and ﬂexibility of

point-to-point serial data transfers. The SAS interface provides improved

performance, simpliﬁed cabling, smaller connectors, lower pin count, and

lower power requirements when compared to parallel SCSI. SAS

controllers leverage an electrical and physical connection interface that

is compatible with SATA technology.

The LSISAS1064E supports the Integrated RAID solution, which is a

highly integrated, low cost RAID implementation. It is designed for

systems requiring redundancy and high availability, but not needing a

full-featured RAID implementation. Integrated RAID technology supports

up to two volumes and ten drives. Each volume can contain up to eight

drives. The Integrated RAID solution includes Integrated Mirroring™(IM)

technology, Integrated Mirroring Enhanced (IME), and

Integrated Striping™(IS) technology. IM provides physical mirroring of

two physical drives, plus a hot spare drive. IME supports 3–8 drives plus

a hot spare drive. IM and IME require an NVSRAM to support write

journaling. IS enables data striping across up to eight physical drives.

The Integrated RAID solution is OS independent, easy to install and

conﬁgure, supports up to eight drives at RAID Level 0, and does not

require a special driver. The run-time operation of the Integrated RAID

solution is transparent to the operating system. A single ﬁrmware build

supports all Integrated RAID capabilities.

The LSISAS1064E uses the Fusion-MPT architecture, which features a

performance based message passing protocol that ofﬂoads the host

CPU by completely managing all I/Os and minimizes system bus

overhead by coalescing interrupts. The proven Fusion-MPT architecture

requires only thin, easy-to-develop device drivers that are independent of

the I/O bus. LSI Logic provides these device drivers.

To meet its ﬂexibility and data transfer requirements, the LSISAS1064E

uses an ARM966 processor that operates at 225 MHz. LSI manufactures

the LSISAS1064E using Gﬂx™technology.

4 of 30 LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller

Features

This section lists the features of the LSISAS1064E.

SSP and SAS Features

This section describes the SSP and SAS features.

•Each phy supports 3.0 Gbit/s and 1.5 Gbit/s SAS data transfers

•Provides a serial, point-to-point, enterprise-level storage interface

•Supports wide transfers consisting of two, three, or four phys

•Supports narrow ports consisting of a single phy

•Transfers data using SCSI information units

•Is compatible with SATA target devices

SATA and STP Features

This section describes the SATA and STP features.

•Each phy supports 3.0 Gbit/s and 1.5 Gbit/s SATA data transfers

•Each phy supports 3.0 Gbit/s and 1.5 Gbit/s STP data transfers

•Allows addressing of multiple SATA targets through an expander

•Allows multiple initiators to address a single target (in a fail-over

conﬁguration) through an expander

PCI Express Features

The LSISAS1064E supports these PCI Express features.

•Provides eight PCI Express phys

•Supports a single-phy (1 lane) link transfer rate up to 2.5 Gbits/s in

each direction

•Supports x8, x4, and x1 link widths

•Automatically downshifts to a x4 link width if plugged into a x4

connector or into a x8 connector that is wired as a x4 connector

LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller 5 of 30

•Provides a scalable interface

– Single-lane aggregate bandwidth of up to 0.5 Gbytes/s

(500 Mbytes/s)

– Quad-lane aggregate bandwidth of up to 2.0 Gbytes/s

(2000 Mbytes/s)

– 8-lane aggregate bandwidth of up to 4.0 Gbytes/s

(4000 Mbytes/s)

•Offers a maximum payload of 2 Kbytes

•Supports serial, point-to-point interconnections between devices

– Reduces the electrical load of the connection

– Enables higher transmission and reception frequencies

•Supports lane reversal and polarity inversion

•Supports PCI Express Hot Plug

•Supports Power Management

– Supports the PCI Power Management 1.2 speciﬁcation

– Supports Active State Power Management, including the L0, L0s,

and L1 states, by placing links in a power-savings mode during

times of no link activity

•Uses a packetized and layered architecture

•Achieves a high bandwidth per pin with low overhead and low latency

•PCI Express is software compatible with PCI and PCI-X software

– Leverages existing PCI device drivers

– Supports the Memory, I/O, and Conﬁguration address spaces

– Supports memory read/write transactions, I/O read/write

transactions, and conﬁguration read/write transactions

•Provides 4 Kbytes of PCI Conﬁguration address space per device

•Supports posted and nonposted transactions

•Provides quality of service (QOS) link conﬁguration and arbitration

policies

•Supports Trafﬁc Class 0 and one virtual channel

•Supports Message Signaled Interrupts (both MSI and MSI-X) as well

as INTx interrupt signaling for legacy PCI support

•Supports end-to-end CRC (ECRC) and Advanced Error Reporting

6 of 30 LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller

Integration

These features make the LSISAS1064E easy to integrate:

•Leverages the proven Fusion-MPT technology

•PCI Express device can use PCI-based device drivers, which

reduces integration challenges and risks

•Provides unequaled performance through the Fusion-MPT

architecture

•Reduces time to market with the Fusion-MPT architecture

– Single driver binary for SAS/SATA, Ultra320 SCSI, and

Fibre Channel products

– One ﬁrmware build supports all Integrated RAID capabilities

– Thin, easy to develop drivers

– Reduced integration and certiﬁcation effort

Usability

These usability features are incorporated into the design:

•Simpliﬁes cabling with point-to-point, serial architecture

•Provides drive spin-up sequencing control

•Provides up to two LED signals for each SAS/SATA phy to indicate

drive activity and faults

•Provides a serialized general purpose I/O (SGPIO) interface

Flexibility

These features increase the ﬂexibility of the LSISAS1064E:

•Supports an 8-bit ﬂash ROM interface and an 8-bit nonvolatile RAM

(NVSRAM) interface

•Offers a ﬂexible programming interface to tune I/O performance

•Allows mixed connections to SAS or SATA targets

•Allows a grouping of up to four phys in a wide port

•Leverages compatible connectors for SAS and SATA connections

LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller 7 of 30

•Supports Integrated RAID technology, which provides for

Integrated Mirroring technology and/or Integrated Striping technology

•Provides 17 LED signals

•Provides four independent GPIO signals

Reliability

These features enhance the reliability of the LSISAS1064E:

•Uses proven GigaBlaze®transceivers on both the SAS/SATA phys

and the PCI Express phys

•Isolates the power and ground of I/O pads and internal chip logic

•Provides ESD protection

•Provides latch-up protection

•Has a high proportion of power and ground pins

•Integrated Mirroring technology provides physical mirroring of the

boot volume

Testability

These features enhance the testability of the LSISAS1064E:

•Offers JTAG boundary scan

•Offers ARM®Multi-ICE®technology for debugging the ARM966

processor

Block Diagram Description

Figure 3 provides the block diagram for the LSISAS1064E. The following

subsections discuss the block diagram. There is a single Host Interface

module and a Quad Port module. The Host Interface module supports

the 8-lane PCI Express interface. The Quad Port module supports four

SAS phys.

8 of 30 LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller

Figure 3 LSISAS1064E Block Diagram

Host Interface Module

The LSISAS1064E interfaces with the host through the host interface

module. The host interface module contains the PCI Express interface,

system interface, IOP (ARM966) processor, timer and conﬁguration,

DMA arbiter, PCI timer and conﬁguration, SIO, external memory, I2C, and

UART blocks.

DMA Arbiter

PCI

TimerConﬁg

IRQ Controller

Context RAM

AHB Arbiter

System Interface

UART

(ARM966)

IOP

PCI

PCI Express TimerConﬁg

ICE I/F

GPIO/LED

I2C

Primary AHB Bus

Quad Port Context AHB Bus

SIO A

Host Interface Module

External

Memory

Interface

Express

SAS Phy

SAS Link

AHB Bridge

Port Layer Connection

AHB Interface

SECONDARY

Queue SATA Engine

Manager

Transport Modules

Manager and Switch

SAS Phy

SAS Link

SAS Phy

SAS Link

SAS Phy

SAS Link

Quad Port

DMA Arbiter

AHB Interface

CONTEXT

Quad Port Module

Processor

SIO A

UART

XMEM Bus

LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller 9 of 30

PCI Express Interface

The PCI Express interface block supports an 8-lane PCI Express

interface. This is a high bandwidth, serial interface that features

point-to-point interconnects between devices and an advanced

packetized and layered protocol architecture. The PCI Express software

is backward compatible with previous implementations of the PCI

speciﬁcation.

System Interface

In combination with the IOP, the system interface supports the

Fusion-MPT architecture. The system interface efﬁciently passes

messages between the LSISAS1064E and the host interface using a

high-performance, packetized mailbox architecture. The LSISAS1064E

system interface takes advantage of PCI Express point-to-point

connections, thereby allowing a dedicated connection to each device with

no sharing.

IOP (ARM966) Processor

The LSISAS1064E I/O processor (IOP) controls the system interface and

manages the host side of the Fusion-MPT architecture without host

processor intervention, which frees the host processor for other tasks.

Timer and Conﬁguration

This block supports the LSISAS1064E LED and GPIO interfaces. There

are nine LED signals. The GPIO interface contains four independent

GPIO signals. This block also supports internal timing adjustments and

power-on sense conﬁguration options.

DMA Arbiter

The LSISAS1064E provides the ability to transfer system memory blocks

to and from local memory through the descriptor-based DMA arbiter and

router. The DMA channel includes a system DMA FIFO and the internal

bus interface logic.

PCI Timer and Conﬁguration

This PCI timer and conﬁguration module supports the PCI conﬁguration

10 of 30 LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller

SIO

The LSISAS1064E provides an SGPIO interface that is compliant with

the SFF-8485 speciﬁcation. A typical use of the serial I/O (SIO) module

is to provide control of LEDs. The SIO module is SFF-8485 compliant.

External Memory

The external memory controller block provides an interface for ﬂash ROM

and NVSRAM devices. The external memory bus provides a 32-bit

memory bus, parity checking, and chip select signals for NVSRAM and

ﬂash ROM. The ﬂash ROM and NVSRAM are capable of 8-bit accesses.

Typical system conﬁgurations require a ﬂash ROM to store ﬁrmware,

conﬁguration information, and persistent data information.

I2C

The LSISAS1064E contains an Inter-IC (I2C) block that communicates

with peripherals. The I2C block operates as either a master or a slave on

the bus and sustains data rates up to 400 Kbits/s. The I2C block

accomplishes byte-wise bidirectional data transfers by using either an

interrupt or a polling handshake at the completion of each byte. The I2C

block controls all bus timing and performs bus-speciﬁc sequences.

UART

The UART provides test and debug access to the LSISAS1064E.

Quad Port Module

The Quad Port module in the LSISAS1064E implements the SSP, SMP,

and STP/SATA protocols, and manages the SAS/SATA phys. The

Quad Port module supports four phys. The following subsections

describe the Quad Port module.

Transport Modules

The transport modules transmit frames to and from the port layer and

implement the STP, SSP, and SMP protocols. The Quad Port module has

four instances of the transport module, one for each SAS/SATA phy on

the LSISAS1064E. The transport modules also manage DMA transfers.

LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller 11 of 30

Queue Manager

The queue manager is responsible for managing various queue

structures that support the SSP, SMP, and SATA/STP protocols. The

queue structures are the primary means for the IOP to initiate I/Os to the

hardware, and for the hardware to notify the IOP of I/O status.

SATA Engine

The SATA engine provides information to the transport modules to enable

handling of SATA commands. The SATA engine tracks queued

commands per device and provides these tags to the SATA transport

layer blocks.

Port Layer Connection Manager and Switch

The port layer connection manager and switch handles transmission

requests from the transport modules and originates connection requests

to the SAS links. It is also responsible for handling SAS wide port

conﬁgurations.

SAS Link

The SAS link layer manages SAS connections between initiator and

target ports, data clocking, and CRC checking on transmitted data. The

SAS link is also responsible for starting a link reset sequence.

SAS Phys

The SAS phys interface to the physical layer, perform serial-to-parallel

conversion of received data and parallel-to-serial conversion of transmit

data, manage phy reset sequences, and perform 8b/10b encoding.

Quad Port DMA Arbiter

The quad port arbiter interfaces with the host interface DMA arbiter and

determines bus priority between the quad port phys for DMA transfers.

Context RAM

The context RAM is a memory that is shared between the host interface

module and the quad port module. The context RAM holds a portion of

the ﬁrmware.

12 of 30 LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller

Signal Descriptions

The following subsections provide the signal descriptions for the

LSISAS1064E. A ‘/’ following the signal indicates an active LOW signal.

PCI Express Signals

This section describes the PCI Express signals. Refer to the PCI Express

speciﬁcation for detailed signal descriptions.

PCI Express System Signals

This section describes the PCI Express system signals.

P_REFCLK_P PCI Express Differential Clock Input

This signal provides half of the PCI Express differential

clock input signal.

P_REFCLK_N PCI Express Differential Clock Input

This signal provides half of the PCI Express differential

clock input signal.

RST/ Reset Input

Asserting the RST/ signal causes a reset.

PCI Express Data Signals

This section describes the PCI Express transmit and receive signals.

P_RX[7:0]+ PCI Express Receive Differential Data Input

P_RX[x]+provides the positive differential data receiver

for PCI Express phy[x].

P_RX[7:0]−PCI Express Receive Differential Data Input

P_RX[x]−provides the negative differential data receiver

for PCI Express phy[x].

P_TX[7:0]+ PCI Express Transmit Differential Data Output

P_TX[x]+provides the positive differential data

transmitter for PCI Express phy[x].

P_TX[7:0]−PCI Express Transmit Differential Data Output

P_TX[x]−provides the negative differential data

transmitter for PCI Express phy[x].

LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller 13 of 30

SAS Signals

This section describes the SAS interface signals.

REFCLK_P, REFCLK_N Input

These pins provide the serial differential clock. Connect

a 75 MHz oscillator with an accuracy of at least 50ppm

to these pins. To use a single-ended crystal, tie the

crystal to REFCLK_P and tie REFCLK_N to a resistor

termination.

RTRIM Resistor Reference Analog

This pin provides the analog resistor reference for the

GigaBlaze transceivers. The resistor provides a reference

to calibrate the 50 Ωtermination.

RX[3:0]−Receive Negative Differential Data Input

RX[x]−provides the negative differential data receiver for

SAS/SATA phy[x].

RX[3:0]+ Receive Positive Differential Data Input

RX[x]+ provides the positive differential data receiver for

SAS/SATA phy[x].

TX[3:0]−Transmit Negative Differential Data Output

TX[x]−provides the negative differential data transmit

signal for SAS/SATA phy[x].

TX[3:0]+ Transmit Positive Differential Data Output

TX[x]+ provides the positive differential data transmit

signal for SAS/SATA phy[x].

I2C and UART Signals

This section describes the I2C and UART signals.

ISTWI_CLK I2C Clock Input/Output

This signal provides the I2C clock signal.

ISTWI_DATA I2C Data Input/Output

This signal provides the I2C data signal.

UART_RX UART Receive Input

This signal provides the UART receive signal.

14 of 30 LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller

UART_TX UART Transmit Output

This signal provides the UART transmit signal.

Memory Interface Signals

This section describes the memory interface signals.

MCLK Memory Clock Output

All synchronous RAM control/data signals reference the

rising edge of this clock.

ADSC/ Address-Strobe-Controller Output

Asserting this active LOW signal initiates read, write, or

chip deselect cycles.

ADV/ Advance Output

Asserting this active LOW signal increments the burst

address counter of the selected synchronous SRAM.

MAD[31:0] Multiplexed Address/Data Input/Output

These signals provide the address and data bus for the

ﬂash ROM and NVSRAM. These signals also provide

Power-On Sense conﬁguration functions to the

LSISAS1064E. These signals are internally pulled LOW.

MADP[3:0] Memory Parity Input/Output

These signals provide parity checking for MAD[31:0].

These signals are internally pulled HIGH.

MOE[1:0]/ Memory Output Enables Output

Asserting these active LOW signals enable the selected

ﬂash ROM or NVSRAM device to drive data. MOE1/

enables ﬂash ROM devices. MOE0/ enables NVSRAM

devices.

MWE[1:0]/ Memory Write Enables Output

The MWE[1:0]/ signals provide memory enable signals.

BWE[3:0]/ Memory Byte Write Enables Output

BWE[3]/ and BWE[2]/ enable partial word writes to the

ﬂash ROM and the NVSRAM if FLASH_CS/ or

NVSRAM_CS/ is asserted.

LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller 15 of 30

NVSRAM_CS/ NVSRAM Chip Select Output

Asserting this active LOW signal selects the NVSRAM

device.

FLASH_CS/ Flash Chip Select Output

Asserting this active LOW signal selects the ﬂash ROM.

The LSISAS1064E maps ﬂash ROM address space into

system memory space.

SIO Signals

This section describes the SIO signals.

SIO_CLK_A SIO Clock Input/Output

This signal provides the clock signal for SIO A.

SIO_DIN_A SIO Data In A Input

This signal provides the data input signal to SIO A.

SIO_DOUT_A SIO Data Out A Output

This signal provides the data output signal to SIO A and

can control the Quad Port LED drives.

SIO_END_A SIO End Control Input/Output

The SIO module drives this output to end control of the

SIO bus.

Conﬁguration and General Purpose Signals

This section describes the conﬁguration and general purpose pins.

TST_RST/ Test Reset Input

Asserting this signal forces the chip into a

Power-On-Reset (POR) state. This signal has an internal

pull-up. The LSISAS1064E does not have an internal

POR.

REFCLK_B ARM Reference Clock Input

This pin provides the ARM reference clock.

MODE[7:0] Mode Select Input

This 8-bit bus deﬁnes operational and test modes for the

chip. These pins have internal pull-downs.

16 of 30 LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller

FAULT_LED[3:0]/

Fault LED Input/Output

These output signals indicate a SAS link fault.

ACTIVE_LED[3:0]/

Activity LED Input/Output

These output signals indicate SAS link activity.

GPIO[3:0] General Purpose I/O Input/Output

These signals provide general purpose input/output

signals. These signals have internal pull-ups.

HB_LED/ Heartbeat LED Output

Firmware intermittently asserts this signal to indicate that

the IOP is operational.

JTAG and Test Signals

This section describes the JTAG and test signals.

FSELA Clock Select Input

This is a test signal. Pull this signal LOW.

SCAN_ENABLE

Scan Enable Input

SCAN_MODE Scan Mode Input

TCK JTAG Debug Clock Input

TRST/ JTAG Debug Reset Input

TDI JTAG Debug Test Data In Input

TDO JTAG Debug Test Data Out Output

TMS JTAG Debug Test Mode Select Input

TCK_ICE Multi-ICE Debug Clock Input

RTCK_ICE Multi-ICE Debug Return Clock Output

TRST_ICE/ Multi-ICE Debug Reset Input

TDI_ICE Multi-ICE Debug Test Data In Input

TDO_ICE Multi-ICE Debug Test Data Out Output

LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller 17 of 30

TMS_ICE Multi-ICE Debug Test Mode Select Input

IDDT IDDQ Test Mode Enable Input

This signal is active HIGH.

TN/ 3-State Output Enable Control Input

This signal is active LOW.

PROCMON Process Monitor Test Output Driver Output

TDIODE_P Anode Connection of the Thermal Diode Input

TDIODE_VSS Cathode Connection of the Thermal Diode Output

Power and Ground Signals

This section describes the power and ground signals.

REFPLL_VDD Power

These signals provide 1.2 V power.

REFPLL_VSS Ground

These signals provide ground.

VDD2 Power

These signals provide 1.2 V core power.

VDDIO33 Power

These signals provide 3.3 V I/O power.

VSS Ground

These signals provide ground.

RX_VSS[3:0], RXB_VSS[3:0], TX_VSS[3:0], TXB_VSS[3:0] Ground

These signals provide ground for the SAS GigaBlaze

core.

RX_VDD[3:0], RXB_VDD[3:0], TX_VDD[3:0], TXB_VDD[3:0] Power

These signals provide 1.2 V power for the SAS

GigaBlaze core.

P_RX_VDD[7:0], P_RXB_VDD[7:0], P_TX_VDD[7:0],

P_TXB_VDD[7:0] Power

These signals provide 1.2 V power for the PCI Express

GigaBlaze core.

18 of 30 LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller

P_RX_VSS[7:0], P_RXB_VSS[7:0], P_TX_VSS[7:0],

P_TXB_VSS[7:0] Ground

These signals provide ground for the PCI Express

GigaBlaze core.

Pin Listing

Table 1 provides the signal listing by signal name. Table 2 provides the

signal listing by pin name. Figure 4 provides a BGA diagram.

LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller 19 of 30

(This page left intentionally blank.)

20 of 30 LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller

Table 1 LSISAS1064E Pin Assignments Listed by Signal Name1

RX_VSS3 F15

RX0- B25

RX0+ B24

RX1- B21

RX1+ B20

RX2- A20

RX2+ A19

RX3- B17

RX3+ A17

RXB_VDD0 C23

RXB_VDD1 C19

RXB_VDD2 F17

RXB_VDD3 E15

RXB_VSS0 F21

RXB_VSS1 F19

RXB_VSS2 E17

RXB_VSS3 G16

SCAN_ENABLE E4

SCAN_MODE F5

SIO_CLK_A H22

SIO_DIN_A J21

SIO_DOUT_A D25

SIO_END_A E25

TCK AB2

TCK_ICE U3

TDI AC1

TDI_ICE T5

TDIODE_P V26

TDIODE_VSS T22

TDO AC2

TDO_ICE V3

TMS AC3

TMS_ICE U4

TN/ AD2

TRST_ICE/ W1

TRST/ Y4

TST_RST/ C2

TX_VDD0 A23

TX_VDD1 D18

TX_VDD2 C17

TX_VDD3 D14

TX_VSS0 E19

TX_VSS1 G18

TX_VSS2 D16

TX_VSS3 E14

TX0- B23

TX0+ B22

TX1- A21

TX1+ A22

TX2- A18

TX2+ B18

TX3- A15

TX3+ A16

TXB_VDD0 F20

TXB_VDD1 E18

TXB_VDD2 F16

TXB_VDD3 A14

TXB_VSS0 E20

TXB_VSS1 B19

TXB_VSS2 E16

TXB_VSS3 F14

UART_RX E26

UART_TX F26

VDD2 A12

VDD2 B10

VDD2 C4

VDD2 C8

VDD2 C10

VDD2 D7

VDD2 D8

VDD2 D9

VDD2 D10

VDD2 E5

VDD2 E6

VDD2 E9

VDD2 E10

VDD2 F12

Signal PinSignal Pin

ACTIVE_LED[0]/ H1

ACTIVE_LED[1]/ H2

ACTIVE_LED[2]/ G1

ACTIVE_LED[3]/ H3

ADSC/ V22

ADV/ V23

BWE[0]/ T21

BWE[1]/ U24

BWE[2]/ R23

BWE[3]/ W25

FAULT_LED[0]/ N1

FAULT_LED[1]/ N3

FAULT_LED[2]/ M1

FAULT_LED[3]/ L1

FLASH_CS/ P25

FSELA E2

GPIO[0] V4

GPIO[1] Y1

GPIO[2] W3

GPIO[3] AB1

HB_LED/ P4

IDDT AB4

ISTWI_CLK G26

ISTWI_DATA K21

MAD[0] J26

MAD[1] H26

MAD[2] K24

MAD[3] J24

MAD[4] J23

MAD[5] M26

MAD[6] M23

MAD[7] J25

MAD[8] K25

MAD[9] L26

MAD[10] L23

MAD[11] K23

MAD[12] K26

MAD[13] N23

MAD[14] R26

MAD[15] P23

MAD[16] V21

MAD[17] Y26

MAD[18] W24

MAD[19] U21

MAD[20] AA26

MAD[21] W23

MAD[22] AA23

MAD[23] Y23

MAD[24] AB25

MAD[25] AB23

MAD[26] AB24

MAD[27] Y21

MAD[28] AC25

MAD[29] AC26

MAD[30] AB22

MAD[31] AD25

MADP[0] L21

MADP[1] U26

MADP[2] W26

MADP[3] AA22

MCLK U23

MODE[0] J6

MODE[1] H4

MODE[2] D1

MODE[3] G4

MODE[4] G5

MODE[5] D2

MODE[6] F4

MODE[7] G6

MOE0/ U25

MOE1/ N24

MWE0/ T23

MWE1/ P24

N/C B14

N/C C24

N/C C25

N/C D3

N/C D23

N/C E1

N/C E3

N/C E13

N/C E22

N/C E23

N/C E24

N/C F1

N/C F6

N/C F22

N/C F23

N/C G20

N/C G21

N/C H5

N/C H6

N/C H21

N/C H23

N/C H25

N/C J1

N/C J2

N/C J3

N/C J4

N/C J5

N/C J22

N/C K1

N/C K5

N/C K6

N/C L4

N/C L5

N/C L6

N/C L22

N/C M5

N/C M6

N/C M21

N/C M22

N/C N6

N/C N21

N/C N22

N/C N25

N/C P2

N/C P6

N/C P21

N/C P22

N/C P26

N/C R1

N/C R4

N/C R5

N/C R6

N/C R22

N/C T6

N/C T26

N/C U1

N/C U2

N/C U5

N/C U6

N/C U22

N/C V1

N/C V2

N/C V5

N/C V6

N/C V24

N/C V25

N/C W2

N/C W4

N/C W5

N/C W6

N/C W7

N/C W21

N/C W22

N/C Y5

N/C Y6

N/C Y22

N/C AA1

N/C AA5

N/C AA6

N/C AB13

N/C AB26

N/C AC12

N/C AC13

N/C AC24

N/C AD1

N/C AD3

N/C AD13

N/C AE3

N/C AE13

N/C AF13

NVSRAM_CS/ N26

P_REFCLK_N AD14

P_REFCLK_P AE14

P_RX_VDD0 AB6

P_RX_VDD1 AC7

P_RX_VDD2 AC9

P_RX_VDD3 AE10

P_RX_VDD4 AC15

P_RX_VDD5 AD18

P_RX_VDD6 AC19

P_RX_VDD7 AB21

P_RX_VSS0 AB7

P_RX_VSS1 AA9

P_RX_VSS2 AD9

P_RX_VSS3 AB12

P_RX_VSS4 AA15

P_RX_VSS5 AC17

P_RX_VSS6 AA18

P_RX_VSS7 AC22

P_RX0- AF4

P_RX0+ AF3

P_RX1- AE7

P_RX1+ AE6

P_RX2- AF8

P_RX2+ AE8

P_RX3- AF11

P_RX3+ AF10

P_RX4- AE17

P_RX4+ AF17

P_RX5- AF20

P_RX5+ AF19

P_RX6- AE21

P_RX6+ AE20

P_RX7- AE25

P_RX7+ AE24

P_RXB_VDD0 Y8

P_RXB_VDD1 AB9

P_RXB_VDD2 AD10

P_RXB_VDD3 AF12

P_RXB_VDD4 AB15

P_RXB_VDD5 AA17

P_RXB_VDD6 AD19

P_RXB_VDD7 AD23

P_RXB_VSS0 AD7

P_RXB_VSS1 Y10

P_RXB_VSS2 AA11

P_RXB_VSS3 AA13

P_RXB_VSS4 Y16

P_RXB_VSS5 AB17

P_RXB_VSS6 AA19

P_RXB_VSS7 AA21

P_TX_VDD0 AB5

P_TX_VDD1 AD4

P_TX_VDD2 AC8

P_TX_VDD3 AC10

P_TX_VDD4 AC14

P_TX_VDD5 AD17

P_TX_VDD6 AC18

P_TX_VDD7 AF23

P_TX_VSS0 AA7

P_TX_VSS1 AA8

P_TX_VSS2 AF7

P_TX_VSS3 AB11

P_TX_VSS4 AB14

P_TX_VSS5 AC16

P_TX_VSS6 Y18

P_TX_VSS7 AB19

P_TX0- AE2

P_TX0+ AF2

P_TX1- AE5

P_TX1+ AE4

P_TX2- AF5

P_TX2+ AF6

P_TX3- AE9

P_TX3+ AF9

P_TX4- AF15

P_TX4+ AF16

P_TX5- AF18

P_TX5+ AE18

P_TX6- AF21

P_TX6+ AF22

P_TX7- AE23

P_TX7+ AE22

P_TXB_VDD0 Y7

P_TXB_VDD1 AD8

P_TXB_VDD2 AB10

P_TXB_VDD3 AA12

P_TXB_VDD4 AF14

P_TXB_VDD5 AA16

P_TXB_VDD6 AB18

P_TXB_VDD7 AA20

P_TXB_VSS0 AC4

P_TXB_VSS1 AB8

P_TXB_VSS2 AA10

P_TXB_VSS3 AC11

P_TXB_VSS4 AA14

P_TXB_VSS5 AB16

P_TXB_VSS6 AE19

P_TXB_VSS7 AB20

PROCMON AA4

REFCLK_B B13

REFCLK_N D12

REFCLK_P C13

REFPLL_VDD D13

REFPLL_VSS A13

RESERVED A3

RESERVED A4

RESERVED A5

RESERVED A6

RESERVED A8

RESERVED A9

RESERVED A10

RESERVED A11

RESERVED B3

RESERVED B4

RESERVED B5

RESERVED B6

RESERVED B7

RESERVED B8

RESERVED B9

RESERVED C3

RESERVED D24

RESERVED D26

RESERVED H24

RESERVED K2

RESERVED K3

RESERVED K4

RESERVED K22

RESERVED G22

RESERVED G23

RESERVED M4

RESERVED N2

RESERVED N4

RESERVED N5

RESERVED P1

RESERVED P3

RESERVED P5

RESERVED R21

RESERVED T1

RST/ AB3

RTCK_ICE T4

RTRIM C14

RX_VDD0 E21

RX_VDD1 D19

RX_VDD2 C18

RX_VDD3 D15

RX_VSS0 D22

RX_VSS1 F18

RX_VSS2 D17

Signal Pin Signal Pin Signal Pin

1. N/C pins are not connected.

LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller 21 of 30

Table 1 LSISAS1064E Pin Assignments Listed by Signal Name1(Cont.)

VSS R17

VSS R19

VSS R24

VSS T3

VSS T8

VSS T10

VSS T12

VSS T14

VSS T16

VSS T19

VSS T24

VSS U8

VSS U11

VSS U13

VSS U15

VSS U17

VSS U19

VSS V8

VSS V19

VSS W8

VSS W9

VSS W10

VSS W11

VSS W12

VSS W13

VSS W14

VSS W15

VSS W16

VSS W17

VSS W18

VSS W19

VSS Y3

VSS Y24

VSS AA3

VSS AA24

VSS AC5

VSS AC6

VSS AC20

VSS AC21

VSS AD11

VSS AD12

VSS AD15

VSS AD16

VSS AD22

VSS AE1

VSS AE26

VSS AF25

Signal PinSignal Pin

VDD2 G7

VDD2 G8

VDD2 K11

VDD2 K13

VDD2 K15

VDD2 K17

VDD2 L10

VDD2 L12

VDD2 L14

VDD2 L16

VDD2 M11

VDD2 M13

VDD2 M15

VDD2 M17

VDD2 N10

VDD2 N12

VDD2 N14

VDD2 N16

VDD2 P11

VDD2 P13

VDD2 P15

VDD2 P17

VDD2 R10

VDD2 R12

VDD2 R14

VDD2 R16

VDD2 T11

VDD2 T13

VDD2 T15

VDD2 T17

VDD2 U10

VDD2 U12

VDD2 U14

VDD2 U16

VDDIO33 A24

VDDIO33 B2

VDDIO33 B11

VDDIO33 B12

VDDIO33 B15

VDDIO33 B16

VDDIO33 C1

VDDIO33 C5

VDDIO33 C6

VDDIO33 C20

VDDIO33 C21

VDDIO33 C26

VDDIO33 F2

VDDIO33 F25

VDDIO33 G2

VDDIO33 G9

VDDIO33 G11

VDDIO33 G12

VDDIO33 G13

VDDIO33 G14

VDDIO33 G15

VDDIO33 G17

VDDIO33 G19

VDDIO33 G25

VDDIO33 H7

VDDIO33 H20

VDDIO33 J7

VDDIO33 J20

VDDIO33 K7

VDDIO33 K20

VDDIO33 L2

VDDIO33 L7

VDDIO33 L20

VDDIO33 L25

VDDIO33 M2

VDDIO33 M7

VDDIO33 M20

VDDIO33 M25

VDDIO33 N7

VDDIO33 N20

VDDIO33 P7

VDDIO33 P20

VDDIO33 R2

VDDIO33 R7

VDDIO33 R20

VDDIO33 R25

VDDIO33 T2

VDDIO33 T7

VDDIO33 T20

VDDIO33 T25

VDDIO33 U7

VDDIO33 U20

VDDIO33 V7

VDDIO33 V20

VDDIO33 W20

VDDIO33 Y2

VDDIO33 Y9

VDDIO33 Y11

VDDIO33 Y12

VDDIO33 Y13

VDDIO33 Y14

VDDIO33 Y15

VDDIO33 Y17

VDDIO33 Y19

VDDIO33 Y20

VDDIO33 Y25

VDDIO33 AA2

VDDIO33 AA25

VDDIO33 AC23

VDDIO33 AD5

VDDIO33 AD6

VDDIO33 AD20

VDDIO33 AD21

VDDIO33 AD24

VDDIO33 AD26

VDDIO33 AE11

VDDIO33 AE12

VDDIO33 AE15

VDDIO33 AE16

VDDIO33 AF24

VSS A2

VSS A7

VSS A25

VSS B1

VSS B26

VSS C7

VSS C9

VSS C11

VSS C12

VSS C15

VSS C16

VSS C22

VSS D4

VSS D5

VSS D6

VSS D11

VSS D20

VSS D21

VSS E7

VSS E8

VSS E11

VSS E12

VSS F3

VSS F7

VSS F8

VSS F9

VSS F10

VSS F11

VSS F13

VSS F24

VSS G3

VSS G10

VSS G24

VSS H8

VSS H9

VSS H10

VSS H11

VSS H12

VSS H13

VSS H14

VSS H15

VSS H16

VSS H17

VSS H18

VSS H19

VSS J8

VSS J19

VSS K8

VSS K10

VSS K12

VSS K14

VSS K16

VSS K19

VSS L3

VSS L8

VSS L11

VSS L13

VSS L15

VSS L17

VSS L19

VSS L24

VSS M3

VSS M8

VSS M10

VSS M12

VSS M14

VSS M16

VSS M19

VSS M24

VSS N8

VSS N11

VSS N13

VSS N15

VSS N17

VSS N19

VSS P8

VSS P10

VSS P12

VSS P14

VSS P16

VSS P19

VSS R3

VSS R8

VSS R11

VSS R13

VSS R15

Signal Pin Signal Pin Signal Pin

1. N/C pins are not connected.

22 of 30 LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller

Table 2 LSISAS1064E Pin Assignments Listed by Pin Number1

N21 N/C

N22 N/C

N23 MAD[13]

N24 MOE1/

N25 N/C

N26 NVSRAM_CS/

P1 RESERVED

P2 N/C

P3 RESERVED

P4 HB_LED/

P5 RESERVED

P6 N/C

P7 VDDIO33

P8 VSS

P10 VSS

P11 VDD2

P12 VSS

P13 VDD2

P14 VSS

P15 VDD2

P16 VSS

P17 VDD2

P19 VSS

P20 VDDIO33

P21 N/C

P22 N/C

P23 MAD[15]

P24 MWE1/

P25 FLASH_CS/

P26 N/C

R1 N/C

R2 VDDIO33

R3 VSS

R4 N/C

R5 N/C

R6 N/C

R7 VDDIO33

R8 VSS

R10 VDD2

R11 VSS

R12 VDD2

R13 VSS

R14 VDD2

R15 VSS

R16 VDD2

R17 VSS

R19 VSS

R20 VDDIO33

R21 RESERVED

R22 N/C

R23 BWE[2]/

R24 VSS

R25 VDDIO33

R26 MAD[14]

T1 RESERVED

T2 VDDIO33

T3 VSS

T4 RTCK_ICE

T5 TDI_ICE

T6 N/C

T7 VDDIO33

T8 VSS

T10 VSS

T11 VDD2

T12 VSS

T13 VDD2

T14 VSS

T15 VDD2

T16 VSS

T17 VDD2

T19 VSS

T20 VDDIO33

T21 BWE[0]/

T22 TDIODE_VSS

T23 MWE0/

T24 VSS

T25 VDDIO33

T26 N/C

Pin SignalPin Signal

A2 VSS

A3 RESERVED

A4 RESERVED

A5 RESERVED

A6 RESERVED

A7 VSS

A8 RESERVED

A9 RESERVED

A10 RESERVED

A11 RESERVED

A12 VDD2

A13 REFPLL_VSS

A14 TXB_VDD3

A15 TX3-

A16 TX3+

A17 RX3+

A18 TX2-

A19 RX2+

A20 RX2-

A21 TX1-

A22 TX1+

A23 TX_VDD0

A24 VDDIO33

A25 VSS

B1 VSS

B2 VDDIO33

B3 RESERVED

B4 RESERVED

B5 RESERVED

B6 RESERVED

B7 RESERVED

B8 RESERVED

B9 RESERVED

B10 VDD2

B11 VDDIO33

B12 VDDIO33

B13 REFCLK_B

B14 N/C

B15 VDDIO33

B16 VDDIO33

B17 RX3-

B18 TX2+

B19 TXB_VSS1

B20 RX1+

B21 RX1-

B22 TX0+

B23 TX0-

B24 RX0+

B25 RX0-

B26 VSS

C1 VDDIO33

C2 TST_RST/

C3 RESERVED

C4 VDD2

C5 VDDIO33

C6 VDDIO33

C7 VSS

C8 VDD2

C9 VSS

C10 VDD2

C11 VSS

C12 VSS

C13 REFCLK_P

C14 RTRIM

C15 VSS

C16 VSS

C17 TX_VDD2

C18 RX_VDD2

C19 RXB_VDD1

C20 VDDIO33

C21 VDDIO33

C22 VSS

C23 RXB_VDD0

C24 N/C

C25 N/C

C26 VDDIO33

D1 MODE[2]

D2 MODE[5]

D3 N/C

D4 VSS

D5 VSS

D6 VSS

D7 VDD2

D8 VDD2

D9 VDD2

D10 VDD2

D11 VSS

D12 REFCLK_N

D13 REFPLL_VDD

D14 TX_VDD3

D15 RX_VDD3

D16 TX_VSS2

D17 RX_VSS2

D18 TX_VDD1

D19 RX_VDD1

D20 VSS

D21 VSS

D22 RX_VSS0

D23 N/C

D24 RESERVED

D25 SIO_DOUT_A

D26 RESERVED

E1 N/C

E2 FSELA

E3 N/C

E4 SCAN_ENABLE

E5 VDD2

E6 VDD2

E7 VSS

E8 VSS

E9 VDD2

E10 VDD2

E11 VSS

E12 VSS

E13 N/C

E14 TX_VSS3

E15 RXB_VDD3

E16 TXB_VSS2

E17 RXB_VSS2

E18 TXB_VDD1

E19 TX_VSS0

E20 TXB_VSS0

E21 RX_VDD0

E22 N/C

E23 N/C

E24 N/C

E25 SIO_END_A

E26 UART_RX

F1 N/C

F2 VDDIO33

F3 VSS

F4 MODE[6]

F5 SCAN_MODE

F6 N/C

F7 VSS

F8 VSS

F9 VSS

F10 VSS

F11 VSS

F12 VDD2

F13 VSS

F14 TXB_VSS3

F15 RX_VSS3

F16 TXB_VDD2

F17 RXB_VDD2

F18 RX_VSS1

F19 RXB_VSS1

F20 TXB_VDD0

F21 RXB_VSS0

F22 N/C

F23 N/C

F24 VSS

F25 VDDIO33

F26 UART_TX

G1 ACTIVE_LED[2]/

G2 VDDIO33

G3 VSS

G4 MODE[3]

G5 MODE[4]

G6 MODE[7]

G7 VDD2

G8 VDD2

G9 VDDIO33

G10 VSS

G11 VDDIO33

G12 VDDIO33

G13 VDDIO33

G14 VDDIO33

G15 VDDIO33

G16 RXB_VSS3

G17 VDDIO33

G18 TX_VSS1

G19 VDDIO33

G20 N/C

G21 N/C

G22 RESERVED

G23 RESERVED

G24 VSS

G25 VDDIO33

G26 ISTWI_CLK

H1 ACTIVE_LED[0]/

H2 ACTIVE_LED[1]/

H3 ACTIVE_LED[3]/

H4 MODE[1]

H5 N/C

H6 N/C

H7 VDDIO33

H8 VSS

H9 VSS

H10 VSS

H11 VSS

H12 VSS

H13 VSS

H14 VSS

H15 VSS

H16 VSS

H17 VSS

H18 VSS

H19 VSS

H20 VDDIO33

H21 N/C

H22 SIO_CLK_A

H23 N/C

H24 RESERVED

H25 N/C

H26 MAD[1]

J1 N/C

J2 N/C

J3 N/C

J4 N/C

J5 N/C

J6 MODE[0]

J7 VDDIO33

J8 VSS

J19 VSS

J20 VDDIO33

J21 SIO_DIN_A

J22 N/C

J23 MAD[4]

J24 MAD[3]

J25 MAD[7]

J26 MAD[0]

K1 N/C

K2 RESERVED

K3 RESERVED

K4 RESERVED

K5 N/C

K6 N/C

K7 VDDIO33

K8 VSS

K10 VSS

K11 VDD2

K12 VSS

K13 VDD2

K14 VSS

K15 VDD2

K16 VSS

K17 VDD2

K19 VSS

K20 VDDIO33

K21 ISTWI_DATA

K22 RESERVED

K23 MAD[11]

K24 MAD[2]

K25 MAD[8]

K26 MAD[12]

L1 FAULT_LED[3]/

L2 VDDIO33

L3 VSS

L4 N/C

L5 N/C

L6 N/C

L7 VDDIO33

L8 VSS

L10 VDD2

L11 VSS

L12 VDD2

L13 VSS

L14 VDD2

L15 VSS

L16 VDD2

L17 VSS

L19 VSS

L20 VDDIO33

L21 MADP[0]

L22 N/C

L23 MAD[10]

L24 VSS

L25 VDDIO33

L26 MAD[9]

M1 FAULT_LED[2]/

M2 VDDIO33

M3 VSS

M4 RESERVED

M5 N/C

M6 N/C

M7 VDDIO33

M8 VSS

M10 VSS

M11 VDD2

M12 VSS

M13 VDD2

M14 VSS

M15 VDD2

M16 VSS

M17 VDD2

M19 VSS

M20 VDDIO33

M21 N/C

M22 N/C

M23 MAD[6]

M24 VSS

M25 VDDIO33

M26 MAD[5]

N1 FAULT_LED[0]/

N2 RESERVED

N3 FAULT_LED[1]/

N4 RESERVED

N5 RESERVED

N6 N/C

N7 VDDIO33

N8 VSS

N10 VDD2

N11 VSS

N12 VDD2

N13 VSS

N14 VDD2

N15 VSS

N16 VDD2

N17 VSS

N19 VSS

N20 VDDIO33

Pin Signal Pin Signal Pin Signal

1. N/C pins are not connected.

LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller 23 of 30

Table 2 LSISAS1064E Pin Assignments Listed by Pin Number1(Cont.)

AE5 P_TX1-

AE6 P_RX1+

AE7 P_RX1-

AE8 P_RX2+

AE9 P_TX3-

AE10 P_RX_VDD3

AE11 VDDIO33

AE12 VDDIO33

AE13 N/C

AE14 P_REFCLK_P

AE15 VDDIO33

AE16 VDDIO33

AE17 P_RX4-

AE18 P_TX5+

AE19 P_TXB_VSS6

AE20 P_RX6+

AE21 P_RX6-

AE22 P_TX7+

AE23 P_TX7-

AE24 P_RX7+

AE25 P_RX7-

AE26 VSS

AF2 P_TX0+

AF3 P_RX0+

AF4 P_RX0-

AF5 P_TX2-

AF6 P_TX2+

AF7 P_TX_VSS2

AF8 P_RX2-

AF9 P_TX3+

AF10 P_RX3+

AF11 P_RX3-

AF12 P_RXB_VDD3

AF13 N/C

AF14 P_TXB_VDD4

AF15 P_TX4-

AF16 P_TX4+

AF17 P_RX4+

AF18 P_TX5-

AF19 P_RX5+

AF20 P_RX5-

AF21 P_TX6-

AF22 P_TX6+

AF23 P_TX_VDD7

AF24 VDDIO33

AF25 VSS

Pin SignalPin Signal

U1 N/C

U2 N/C

U3 TCK_ICE

U4 TMS_ICE

U5 N/C

U6 N/C

U7 VDDIO33

U8 VSS

U10 VDD2

U11 VSS

U12 VDD2

U13 VSS

U14 VDD2

U15 VSS

U16 VDD2

U17 VSS

U19 VSS

U20 VDDIO33

U21 MAD[19]

U22 N/C

U23 MCLK

U24 BWE[1]/

U25 MOE0/

U26 MADP[1]

V1 N/C

V2 N/C

V3 TDO_ICE

V4 GPIO[0]

V5 N/C

V6 N/C

V7 VDDIO33

V8 VSS

V19 VSS

V20 VDDIO33

V21 MAD[16]

V22 ADSC/

V23 ADV/

V24 N/C

V25 N/C

V26 TDIODE_P

W1 TRST_ICE/

W2 N/C

W3 GPIO[2]

W4 N/C

W5 N/C

W6 N/C

W7 N/C

W8 VSS

W9 VSS

W10 VSS

W11 VSS

W12 VSS

W13 VSS

W14 VSS

W15 VSS

W16 VSS

W17 VSS

W18 VSS

W19 VSS

W20 VDDIO33

W21 N/C

W22 N/C

W23 MAD[21]

W24 MAD[18]

W25 BWE[3]/

W26 MADP[2]

Y1 GPIO[1]

Y2 VDDIO33

Y3 VSS

Y4 TRST/

Y5 N/C

Y6 N/C

Y7 P_TXB_VDD0

Y8 P_RXB_VDD0

Y9 VDDIO33

Y10 P_RXB_VSS1

Y11 VDDIO33

Y12 VDDIO33

Y13 VDDIO33

Y14 VDDIO33

Y15 VDDIO33

Y16 P_RXB_VSS4

Y17 VDDIO33

Y18 P_TX_VSS6

Y19 VDDIO33

Y20 VDDIO33

Y21 MAD[27]

Y22 N/C

Y23 MAD[23]

Y24 VSS

Y25 VDDIO33

Y26 MAD[17]

AA1 N/C

AA2 VDDIO33

AA3 VSS

AA4 PROCMON

AA5 N/C

AA6 N/C

AA7 P_TX_VSS0

AA8 P_TX_VSS1

AA9 P_RX_VSS1

AA10 P_TXB_VSS2

AA11 P_RXB_VSS2

AA12 P_TXB_VDD3

AA13 P_RXB_VSS3

AA14 P_TXB_VSS4

AA15 P_RX_VSS4

AA16 P_TXB_VDD5

AA17 P_RXB_VDD5

AA18 P_RX_VSS6

AA19 P_RXB_VSS6

AA20 P_TXB_VDD7

AA21 P_RXB_VSS7

AA22 MADP[3]

AA23 MAD[22]

AA24 VSS

AA25 VDDIO33

AA26 MAD[20]

AB1 GPIO[3]

AB2 TCK

AB3 RST/

AB4 IDDT

AB5 P_TX_VDD0

AB6 P_RX_VDD0

AB7 P_RX_VSS0

AB8 P_TXB_VSS1

AB9 P_RXB_VDD1

AB10 P_TXB_VDD2

AB11 P_TX_VSS3

AB12 P_RX_VSS3

AB13 N/C

AB14 P_TX_VSS4

AB15 P_RXB_VDD4

AB16 P_TXB_VSS5

AB17 P_RXB_VSS5

AB18 P_TXB_VDD6

AB19 P_TX_VSS7

AB20 P_TXB_VSS7

AB21 P_RX_VDD7

AB22 MAD[30]

AB23 MAD[25]

AB24 MAD[26]

AB25 MAD[24]

AB26 N/C

AC1 TDI

AC2 TDO

AC3 TMS

AC4 P_TXB_VSS0

AC5 VSS

AC6 VSS

AC7 P_RX_VDD1

AC8 P_TX_VDD2

AC9 P_RX_VDD2

AC10 P_TX_VDD3

AC11 P_TXB_VSS3

AC12 N/C

AC13 N/C

AC14 P_TX_VDD4

AC15 P_RX_VDD4

AC16 P_TX_VSS5

AC17 P_RX_VSS5

AC18 P_TX_VDD6

AC19 P_RX_VDD6

AC20 VSS

AC21 VSS

AC22 P_RX_VSS7

AC23 VDDIO33

AC24 N/C

AC25 MAD[28]

AC26 MAD[29]

AD1 N/C

AD2 TN/

AD3 N/C

AD4 P_TX_VDD1

AD5 VDDIO33

AD6 VDDIO33

AD7 P_RXB_VSS0

AD8 P_TXB_VDD1

AD9 P_RX_VSS2

AD10 P_RXB_VDD2

AD11 VSS

AD12 VSS

AD13 N/C

AD14 P_REFCLK_N

AD15 VSS

AD16 VSS

AD17 P_TX_VDD5

AD18 P_RX_VDD5

AD19 P_RXB_VDD6

AD20 VDDIO33

AD21 VDDIO33

AD22 VSS

AD23 P_RXB_VDD7

AD24 VDDIO33

AD25 MAD[31]

AD26 VDDIO33

AE1 VSS

AE2 P_TX0-

AE3 N/C

AE4 P_TX1+

Pin Signal Pin Signal Pin Signal

1. N/C pins are not connected.

24 of 30 LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller

Figure 4 LSISAS1064E 636 EPBGA-T – Top View (Sheet 1 of 2)

LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller 25 of 30

Figure 4 LSISAS1064E 636 EPBGA-T – Top View (Sheet 2 of 2)

26 of 30 LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller

Package Drawing

The LSISAS1064E uses a 636 EPBGA-T package. The package code

is 8C. Figure 5 provides the package drawing.

LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller 27 of 30

Figure 5 636-Ball EPBGA-T (8C) Mechanical Drawing (Sheet 1 of 3)

Important: This drawing may not be the latest version. For board layout and manufacturing,

obtain the most recent engineering drawings from your LSI marketing

representative by requesting the outline drawing for package code 8C.

28 of 30 LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller

Figure 5 636-Ball EPBGA-T (8C) Mechanical (Sheet 2 of 3); Bottom View (Cont.)

Important: This drawing may not be the latest version. For board layout and manufacturing,

obtain the most recent engineering drawings from your LSI marketing

representative by requesting the outline drawing for package code 8C.

LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller 29 of 30

Figure 5 636-Ball EPBGA-T (8C) Mechanical (Sheet 3 of 3); Bottom View (Cont.)

Important: This drawing may not be the latest version. For board layout and manufacturing,

obtain the most recent engineering drawings from your LSI marketing

representative by requesting the outline drawing for package code 8C.

30 of 30 LSISAS1064E PCI Express to 4-Port Serial Attached SCSI Controller

LSI Logic products are not intended for use in life-support

appliances, devices, or systems. Use of any LSI Logic

product in such applications without written consent of the

appropriate LSI Logic ofﬁcer is prohibited.

LSI Logic Corporation reserves the right to make changes

to any products and services herein at any time without

notice. LSI Logic does not assume any responsibility or

liability arising out of the application or use of any product

or service described herein, except as expressly agreed to

inwriting by LSI Logic; nor doesthe purchase, lease,or use

of a product or service from LSI Logic convey a license

underanypatentrights,copyrights,trademarkrights,orany

other of the intellectual property rights of LSI Logic or of

third parties.

Purchase of I2C components of LSI Logic Corporation, or

one of its sublicensed Associated Companies, conveys a

license under the Philips I2C Patent Rights to use these

components in an I2C system, provided that the system

conforms to the I2C standard Speciﬁcation as deﬁned by

Philips.

LSI Logic, the LSI Logic logo design, Fusion-MPT, Gﬂx,

GigaBlaze, Integrated Mirroring, Integrated RAID, and

Integrated Striping are trademarks or registered trademarks

of LSI Logic Corporation. ARM and Multi-ICE are registered

trademarks of ARM Ltd., used under license. PCI-X is a

registered trademark of PCI SIG. All other brand and

product names may be trademarks of their respective

companies.

Doc. No. DB08-000275-03

Headquarters

LSI Logic Corporation

North American Headquarters

Milpitas CA

Tel: 408.433.8000

LSI Logic Europe Ltd.

European Headquarters

Bracknell England

Tel: 44.1344.413200

Fax: 44.1344.413254

LSI Logic K.K.

Headquarters

Tokyo Japan

Tel: 81.3.5463.7821

Fax: 81.3.5463.7820

ISO 9000 Certified

To receive product literature, visit us at http://www.lsilogic.com.

Foracurrent list of ourdistributors,sales ofﬁces,anddesign resource centers,viewour webpagelocated at

http://www.lsilogic.com/contacts/index.html.

Notes