Dual PLL Precision Synthesizer
Data Sheet AD9578
Rev. B Document Feedback
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FEATURES
Any output frequency precision synthesis
11.8 MHz to 919 MHz
Better than 0.1 ppb frequency resolution
Ultralow rms jitter (12 kHz to 20 MHz)
<300 fs rms using integer synthesis
<405 fs rms using fractional synthesis
Dual reference inputs support LVPECL, LVDS, 1.8 V LVCMOS,
or fundamental mode AT cut crystals from 22 MHz to
54 MHz or reference clocks from 20 MHz to 60 MHz
Numerical (NCO) frequency control
Dynamically pullable output frequency enables FPGA-
based PLLs (HDL available)
Fast serial peripheral interface (SPI) bus write speeds up to
100 MHz
On-the-fly frequency changes
Dual PLL in compact 7 mm × 7 mm package
Replaces multiple large clock ICs, PLLs, fanout buffers,
crystal oscillators (XOs), and voltage controlled crystal
oscillators (VCXOs)
Mix and match output buffers
In-circuit programmable LVPECL/LVDS/HCSL/LVCMOS
Independent buffer (VDDOx) drives multiple technologies
Enhanced power supply noise rejection
APPLICATIONS
FPGA-based jitter attenuators and low jitter PLLs
Precision disciplined clocks and clock synthesizers
Multirate clock synthesizers
Optical: OTN/SDH/SONET
Broadcast video: 3G SDI, HD SDI, SDI
Networking and storage: Ethernet/SAS/Fibre Channel
Wireless infrastructure: OBSAI/CPRI
Industrial: IEEE 1588
Numerically controlled oscillators (NCOs)
GENERAL DESCRIPTION
The AD9578 is a programmable synthesizer intended for jitter
attenuation and asynchronous clocking applications in high
performance telecommunications, networking, data storage,
serializer/deserializer (SERDES), and physical layer (PHY)
applications. The device incorporates two low jitter PLLs that
provide any frequency with precision better than 0.1 ppb, each
with two separate output dividers, for a total of four programmable
outputs, delivering maximum flexibility and jitter performance.
Each output is independently programmable to provide frequen-
cies of up to 919 MHz with <410 fs typical rms jitter (12 kHz to
20 MHz) utilizing compact, low cost fundamental mode crystals
(XTALs) that enable a robust supply chain. Using integer
frequency synthesis, the AD9578 is capable of achieving rms
jitter as low as 290 fs.
The AD9578 is packaged with a factory programmed default
power-on configuration. After power-on, all settings including
output frequency are reconfigurable through a fast SPI.
The AD9578 architecture permits it to be used as a numerically
controlled oscillator (NCO). This allows the user to dynamically
change the frequency using the fast SPI bus. FPGAs and other
devices can take advantage of this function to implement digital
PLLs with configurable loop bandwidths for jitter attenuation
applications, precision disciplined clocks that lock to tight
stability references, or digitally controlled precision timing
applications, such as network timing and IEEE 1588 applications.
The SPI bus can operate up to 50 MHz, enabling fast FPGA
loops while multiple devices share the same bus. The AD9578
can also be used in multirate precision applications, such as
broadcast video or OTN. HDL FPGA code for digital PLL
applications is available from Analog Devices, Inc.
SIMPLIFIED FUNCTIONAL BLOCK DIAGRAM
OPTIONAL
NOTES
1. IF SUPPLYING A SINGLE-ENDED 1.8V CMOS SIGNAL, CONNECT THE SIGNAL TO EITHER
XO2 OR XO4.
OPTIONAL
XO4
XO3
XO2
XO1
REF1
AD9578
REF2
REF
INPUT
MUX
POWER
SUPPLIES
OUTPUT
ENABLE
LOGIC
SPI AND OTP
PROGRAMMABLE
LOGIC CONTROL
FRACTIONAL
PLL2
FRACTIONAL
PLL1
DIVIDER OUT1,
DIVIDER
REFOUT,
OUT2,
DIVIDER OUT3,
DIVIDER OUT4,
OUT1
REFOUT
OUT2
OUT3
OUT4
11356-001
Figure 1.
AD9578 Data Sheet
Rev. B | Page 2 of 44
TABLE OF CONTENTS
Features .....................................................................................1
Applications...............................................................................1
General Description ..................................................................1
Simplified Functional Block Diagram........................................1
Revision History ........................................................................3
Specifications .............................................................................4
Supply Voltage and Current (2.5 V Operation) ......................4
Supply Voltage and Current (3.3 V Operation) ......................4
Power Dissipation ..................................................................4
Logic Inputs (CS, PD1, OEREF, OE1, OE2, OE3, OE4) .........5
Reference Inputs (XO1, XO2, XO3, XO4) ..............................5
Distribution Clock Outputs (Including REFOUT/REFOUT) 6
Serial Port ..............................................................................9
Digital PLL...........................................................................10
Digital Functions Timing.....................................................10
Jitter Generation Using 49.152 MHz Crystal........................10
Jitter Generation Using 25 MHz Square wave ......................11
Absolute Maximum Ratings ....................................................12
ESD Caution ........................................................................12
Pin Configuration and Function Descriptions.........................13
Typical Performance Characteristics .......................................15
Test Setup and Configuration Circuits.....................................18
Input/Output Termination Recommendations ........................19
Getting Started.........................................................................20
Chip Power Monitor and Startup .........................................20
Device Register Programming Using a Register Setup File ..20
OTP Programming ..............................................................20
Theory of Operation................................................................21
Overview..............................................................................21
PLL and Output Driver Control ..............................................22
Overview..............................................................................22
PLL Enable/Disable..............................................................22
Output Driver Format..........................................................23
Output Configuration Example ...........................................23
Reference Input........................................................................24
Overview..............................................................................24
Reference Input ....................................................................24
Crystal Oscillator Amplifier Enable .....................................24
REFOUT/REFOUT Source Selection...................................24
Crystal Oscillator Inputs..........................................................25
Overview ............................................................................. 25
Crystal Oscillator Gain ........................................................ 25
Crystal Load Capacitors....................................................... 25
PLLs ........................................................................................ 26
Overview ............................................................................. 26
PLL Modes of Operation ..................................................... 26
VCO .................................................................................... 27
Charge Pump....................................................................... 27
Output Dividers................................................................... 27
Loss of Lock Indicator ......................................................... 27
Resets................................................................................... 27
Example Values for 49.152 MHz crystal .............................. 28
SPI Programming .................................................................... 29
Overview ............................................................................. 29
SPI Description.................................................................... 29
OTP Programming .............................................................. 30
Register Map ........................................................................... 32
Register Map Bit Descriptions ................................................. 34
Chip and Manufacturer ID (Register 0, Address 0x00)........ 34
Product ID, Chip ID, and User Programing Space (Register 1,
Address 0x01) ...................................................................... 34
External Pin Readback and Override (Register 2, Address
0x02).................................................................................... 34
REFOUT/OUTPUT Divider Enable (Register 3, Address
0x03).................................................................................... 36
XTAL1 and Output Buffer Configuration (Register 4,
Address 0x04) ...................................................................... 37
Output Driver Configuration (Register 5, Address 0x05) .... 38
PLL1 Configuration (Register 6, Address 0x06) .................. 38
PLL1 Configuration (Register 7, Address 0x07) .................. 39
PLL2 Configuration (Register 8, Address 0x08) .................. 40
PLL2 Configuration (Register 9, Address 0x09) .................. 40
XTAL2 Configuration (Register 10, Address 0x0A)............. 42
Reserved (Register 11, Address 0x0B).................................. 42
PLL1 KVCO Ban d (Register 12, Address 0x0C)...................... 42
Reserved (Register 13, Address 0x0D) ................................. 42
PLL2 KVCO Ban d (Register 14, Address 0x0E) ...................... 43
PLL Lock Detect (Register 15, Address 0x0F)...................... 43
Outline Dimensions ................................................................ 44
Ordering Guide ................................................................... 44
Data Sheet AD9578
Rev. B | Page 3 of 44
REVISION HISTORY
1/2017—Rev. A to Rev. B
Change to Table 31 .......................................................................... 32
10/2016—Rev. 0 to Rev. A
Changes to Figure 3 ......................................................................... 13
Changes to Table 29 ........................................................................ 28
Added Exposed Pad Notation to Outline Dimensions .............. 44
10/2014—Revision 0: Initial Version
AD9578 Data Sheet
Rev. B | Page 4 of 44
SPECIFICATIONS
SUPPLY VOLTAGE AND CURRENT (2.5 V OPERATION)
VDD = 2.5 V ± 5%, TA = −25°C to +85°C.
Table 1.
Parameter Symbol Min Typ Max Unit Test Conditions/Comments
SUPP LY VO LTAGE VDD 2.375 2.50 2.625 V
SUPPLY CURRENT IDD 229 247 265 mA Using typical configuration in Tabl e 3
337 365 388 mA Using all blocks running configuration in Ta b l e 3
SUPPLY VOLTAGE AND CURRENT (3.3 V OPERATION)
VDD = 3.3 V ± 10%, TA = 25°C to +85°C.
Table 2.
Parameter Symbol Min Typ Max Unit Test Conditions/Comments
SUPPLY V O LTA G E VDD 2.97 3.30 3.63 V
VPROG 5.25 5.5 VDD + 2.5 V CS
pin only; used only for one time programmable (OTP) programming;
perform OTP programming only with VDD = 3.3 V
SUPPLY CURRENT IDD 252 268 mA Using typical configuration in Ta b l e 3
373 397 mA Using all blocks running configuration in Tabl e 3
POWER DISSIPATION
VDD = 2.5 V ± 5%, TA = 25°C to +85°C. Maximum power is at VDD = 2.625 V and is usually 11% higher than typical.
Table 3.
Parameter
Min
Ty p
Max
Unit
Test Conditions/Comments
POWER DISSIPATION
Typical Configuration 618 696 mW XTA L : 25 MHz
REFOUT driver: disabled
PLL1: one LVPECL driver at 644.53125 MHz
PLL2: one single-ended LVCM O S driver (with 80 pF load)
at 100 MHz
All Blocks Running
913 1018 mW
XTAL: 49.152 MHz
XTA L
on both
XTA L inputs
REFOUT driver: LVPECL mode, 49.152 MHz
PLL1: two LVPECL drivers at 693.812 MHz
PLL2: two LVPECL drivers at 693.812 MHz
Full Power-Down 67 75 mW PD1 pin grounded; Register 0x02 = 0x015555 to disable
remainder of chip
Incremental Power Dissipation Starting with typical configuration; change in power due
to the indicated operation
Crystal Reference On/Off 25 mW
PLL On/Off 259 mW
PLL1 or PLL2 on/off, including output drivers or channel
dividers
Output Distribution Driver On/Off
HCSL (at 644.53 MHz) 75 mW Each output of a differential pair has 50 Ω to ground
LVDS (at 644.53 MHz) 43 mW 100 Ω across differential pair
LVPECL (at 644.53 MHz) 107 mW 50 Ω to VDD2 V
3.3 V LVCM O S (at 25 MHz) 75 mW A single 3.3 V LVCM O S output with an 80 pF load
Data Sheet AD9578
Rev. B | Page 5 of 44
LOGIC INPUTS (CS, PD1, OEREF, OE1, OE2, OE3, OE4)
Table 4.
Parameter Min Ty p Max Unit Test Conditions/Comments
LOGIC INPUTS (CS in OTP
FUNCTION)
Specifications apply to the CS pin while in OTP programming mode
Input Voltage (VPROG) 5.25 5.5 VDD + 2.5 V
See V
PROG
definition in Tabl e 1; OTP programming must be done
with VDD = 3.3 V
Input Current 20 25 mA Current consumed during OTP programming
Time to OTP Program 800 µs Time required per bit programmed
LOGIC INPUTS (PD1,OEREF, OE1,
OE2, OE3, OE4, CS)
Numbers are valid for VDD = 2.5 V and 3.3 V
Input Voltage
High (VIH) 2.2 V
Low (VIL) 0.8 V
Input Current (IINH, IINL) 38 60 µA
Input Capacitance (CIN) 3 pF
REFERENCE INPUTS (XO1, XO2, XO3, XO4)
Table 5.
Parameter Min Ty p Max Unit Test Conditions/Comments
REFERENCE INPUT DRIVEN BY
CRYSTAL RESONATOR
Crystal Resonator
Frequency Range
20 60 MHz Fundamental mode, AT cut crystal
Crystal Motional Resistance 100 Guaranteed by design
REFERENCE INPUT DRIVEN BY
A DIFFERENTIAL CLOCK
LVCM O S on the XO2 or XO4 pin, or ac-coupled
Input Frequency Range 20 60 MHz Assumes ac-coupled LVDS (494 mV p-p across the differential pair)
Input Slew Rate 133 V/μs Minimum limit imposed for jitter performance
Differential Input Voltage
Sensitivity
250 mV p-p Minimum voltage across pins required to ensure switching between
logic states; the instantaneous voltage on either pin must not
exceed the supply rails; can accommodate single-ended input by ac
grounding of complementary input
REFERENCE INPUT DRIVEN BY
A SINGLE-ENDED CLOCK
The XO2 pin (for PLL1) and XO4 pin (for PLL2) input accepts dc-
coupled 1.8 V LVCMOS
Input Frequency Range 20 60 MHz DC-coupled
Input Slew Rate 67 V/μs Minimum limit imposed for jitter performance
Single-Ended Input (XO2,
XO4 Pins Only)
Input Voltage V
High (VIH) 1.48
Low (VIL) 0.98 V
AD9578 Data Sheet
Rev. B | Page 6 of 44
DISTRIBUTION CLOCK OUTPUTS (INCLUDING REFOUT/REFOUT)
Table 6.
Parameter Min Ty p Max Unit Test Conditions/Comments
3.3 V LVP ECL MO DE
V
DD
= 3.3V ; 50 Ω to V
DD
− 2 V termination at output
pins
Output Frequency 11.8 919 MHz REFOUT/REFOU T limited to 60 MHz
Rise Time (20% to 80%) 130 183 ps
Fall Time (80% to 20%) 142 203 ps
Duty Cycle, OUTPUT1 and OUTPUT4
111.8 ≤ fOUT 357 MHz 50 52 54 % Output divider settings other than 4.5
357 < fOUT ≤ 919 MHz 43 47 51 % Output divider settings other than 4.5
Output Divider = 4.5 46 50 54 % Measured at 765 MHz
Duty Cycle, OUTPUT2 and OUTPUT3
111.8 ≤ fOUT 357 MHz 49 51 53 % Output divider settings other than 4.5
357 < fOUT ≤ 919 MHz 45 49 51 % Output divider settings other than 4.5
Output Divider = 4.5 51 57 63 % Measured at 765 MHz
Differential Output Voltage Swing 700 850 1000 mV
Voltage across pins at minimum output frequency; if
a differential probe is used, peak-to-peak voltage (VPP
)
is 2× this value
Common-Mode Output Voltage 1.81 1.91 2.01 V
2.5 V LVPECL MODE
V
DD
= 2.5 V; 50 Ω to V
DD
− 2 V termination at output
pins
Output Frequency 11.8 919 MHz REFOUT/REFOU T limited to 60 MHz
Rise Time (20% to 80%) 137 186 ps
Fall Time (80% to 20%) 148 209 ps
Duty Cycle, OUTPUT1 and OUTPUT4
111.8 ≤ fOUT 357 MHz 50 52 54 % Output divider settings other than 4.5
357 < fOUT ≤ 919 MHz 49 51 54 % Output divider settings other than 4.5
Output Divider = 4.5 46 50 54 % Measured at 765 MHz
Duty Cycle, OUTPUT2 and OUTPUT3
111.8 ≤ fOUT 357 MHz 43 48 51 % Output divider settings other than 4.5
357 < fOUT ≤ 919 MHz 44 48 52 % Output divider settings other than 4.5
Output Divider
= 4.5 51 57 63 %
Measured at 765 MHz
Differential Output Voltage Swing 700 850 1000 mV Voltage across pins at minimum output frequency; if
a differential probe is used, VPP is 2× this value
Common-Mode Output Voltage 1.05 1.15 1.25 V
3.3 V HCSL MODE 50 Ω to ground termination at output pins
Output Frequency 11.8 919 MHz REFOUT/REFOU T limited to 60 MHz
Rise Time (20% to 80%) 180 266 ps
Fall Time (80% to 20%) 186 286 ps
Duty Cycle, OUTPUT1 and OUTPUT4
111.8 ≤ fOUT 357 MHz 51 52 54 % Output divider settings other than 4.5
357 < fOUT ≤ 919 MHz 48 51 54 % Output divider settings other than 4.5
Output Divider = 4.5 49 52 56 % Measured at 765 MHz
Duty Cycle, OUTPUT2 and OUTPUT3
111.8 ≤ fOUT 357 MHz 50 53 54 % Output divider settings other than 4.5
357 < fOUT ≤ 919 MHz 48 51 53 % Output divider settings other than 4.5
Output Divider = 4.5 53 59 67 % Measured at 765 MHz
Output High Voltage 624 750 850 mV
Output Low Voltage 50 0 +50 mV
Output Voltage Swing (VSW IN G ) 624 750 850 mV
Voltage across pins at minimum output frequency;
when a differential probe is used, VPP is 2× this value
Absolute Crossing Point (VOX) 295 360 400 mV
Short-Circuit Output Current 14 17 mA
Data Sheet AD9578
Rev. B | Page 7 of 44
Parameter Min Ty p Max Unit Test Conditions/Comments
2.5 V HCSL MODE 50 Ω to ground termination at output pins
Output Frequency 11.8 919 MHz REFOUT/REFOU T limited to 60 MHz
Rise Time (20% to 80%)
OUTPUT1, OUTPUT2, OUTPUT3 199 275 ps Output divider settings other than 4.5
OUTPUT4 243 370 ps Output divider settings other than 4.5
Fall Time (80% to 20%)
OUTPUT1, OUTPUT2, OUTPUT3 191 287 ps Output divider settings other than 4.5
OUTPUT4 226 329 ps Output divider settings other than 4.5
Duty Cycle, OUTPUT1 and OUTPUT4
111.8 ≤ fOUT 357 MHz 50 52 54 % Output divider settings other than 4.5
357 < fOUT ≤ 919 MHz 47 50 53 % Output divider settings other than 4.5
Output Divider = 4.5 39 52 55 % Measured at 765 MHz
Duty Cycle, OUTPUT2 and OUTPUT3
111.8 ≤ fOUT 357 MHz 50 52 54 % Output divider settings other than 4.5
357 < fOUT ≤ 919 MHz 48 50 53 % Output divider settings other than 4.5
Output Divider
= 4.5 45 59 65 %
Measured at 765 MHz
Output High Voltage
624 750 850 mV
Output Low Voltage -50 0 50 mV
Output Voltage Swing (VSW IN G ) 624 750 850 mV Voltage across pins at minimum output frequency; if
a differential probe is used, VPP is 2× this value
Absolute Crossing Point (VOX) 295 360 400 mV
Short-Circuit Output Current 14 17 mA
LVDS MODE
(VDD
= 3.3 V and 2.5 V)
100 Ω termination across the output pair
Output Frequency 11.8 919 MHz REFOUT/REFOU T limited to 54 MHz
Rise Time (20% to 80%) 173 215 ps
Fall Time (80% to 20%) 177 223 ps
OUTPUT1 and OUTPUT4 Duty Cycle
111.8 ≤ fOUT 357 MHz 50 52 54 % Output divider settings other than 4.5
357 < fOUT ≤ 919 MHz 46 50 54 % Output divider settings other than 4.5
Output Divider = 4.5 49 52 55 % Measured at 765 MHz
OUTPUT2 and OUTPUT3 Duty Cycle
111.8 ≤ fOUT 357 MHz 50 52 54 % Output divider settings other than 4.5
357 < fOUT ≤ 919 MHz 46 50 53 % Output divider settings other than 4.5
Output Divider = 4.5 51 59 66 % Measured at 765 MHz
Differential Output Voltage Swing
Balanced, VOD 247 454 mV
Voltage across pins at minimum output frequency; if
a differential probe is used, VPP is 2× this value
Unbalanced, ΔVOD 50 mV
Absolute difference between voltage swing of true
pin and complementary pin
Offset Voltage
Common Mode, VOS
1.08
1.26
1.375
V
Common-Mode Difference, ΔVOS 50 mV Voltage difference between pins at minimum
output frequency
Short-Circuit Output Current 16 24 mA
LVCMOS MODE (VDD = 3.3 V and 2.5 V)
Output Frequency 11.8 250 MHz REFOUT limited to 60 MHz
Rise Time (20% to 80%) Capacitor load (CLOAD) = 10 pF
330 Ω Pull-Down Resistor 1.3 1.9 ns
3.3 kPull-Down Resistor
1.2
1.7
ns
Fall Time (20% to 80%)
CLOAD = 10 pF
330 Ω Pull-Down Resistor 1.3 2 ns
3.3 k Pull-Down Resistor 1.5 2.4 ns
AD9578 Data Sheet
Rev. B | Page 8 of 44
Parameter Min Ty p Max Unit Test Conditions/Comments
Duty Cycle (20% to 80%) ns CLOAD = 10 pF
330 Ω Pull-Down Resistor 43 52 62 %
3.3 kPull-Down Resistor 44 53 63 %
Output Voltage High (VOH) At minimum output frequency; outputs terminated
50 Ω to VDD/2
VDD = 3.3 V 3.0 3.1 3.35 V
VDD = 2.5 V 1.9 2.0 2.1 V
Output Voltage Low (VOL)
At minimum output frequency; outputs terminated
50 Ω to VDD/2
VDD = 3.3 V 0.22 0.32 0.42 V
VDD = 2.5 V 0.2 0.3 0.4 V
OUTPUT TIMING SKEW OUTPUT2 lags OUTPUT1; OUTPUT3 lags OUTPUT4
LVPECL
Between OUTPUT1 and OUTPUT2
Drivers
90 ps
LVPECL mode on both drivers; rising edge only;
any divide value
Between OUTPUT3 and OUTPUT4
Drivers
102 ps
LVPECL mode on both drivers; rising edge only;
any divide value
LVDS
Between OUTPUT1 and OUTPUT2
Drivers
94 ps
LVDS mode on both drivers; rising edge only;
any divide value
Between OUTPUT3 and OUTPUT4
Drivers
100 ps
LVDS mode on both drivers; rising edge only;
any divide value
HCSL
Between OUTPUT1 and OUTPUT2
Drivers
48 ps HCSL mode on both drivers; rising edge only;
any divide value
Between OUTPUT3 and OUTPUT4
Drivers
59 ps
HCSL mode on both drivers; rising edge only;
any divide value
LVCM O S
Between OUTPUT1 and OUTPUT2
Drivers
64 ps
LVCMOS mode on both drivers; rising edge only;
any divide value
Between OUTPUT3 and OUTPUT4
Drivers
59 ps
LVCMOS mode on both drivers; rising edge only;
any divide value
Data Sheet AD9578
Rev. B | Page 9 of 44
SERIAL PORT
Table 7.
Parameter
Min
Ty p
Max
Unit
Test Conditions/Comments
CS See Tab l e 4 for using CS while in OTP programming mode
Input Voltage
Logic 1 2.2 V
Logic 0 1.2 V
Input Current 44 µA
Logic 1
Logic 0 88 µA
Input Capacitance 2 pF
SCK Internal 30 kΩ pull-down resistor
Input Voltage
Logic 1 2.2 V
Logic 0 0.8 1.2 V
Input Current
Logic 1 200 µA
Logic 0 1 µA
Input Capacitance 2 pF
SDI
Input Voltage
Logic 1 2.2 V
Logic 0 1.2 V
Input Current
Logic 1 1 µA
Logic 0 1 µA
Input Capacitance 2 pF
SDO/LOL
Output Logic 1 Voltage VDD 0.6 V 1 mA load current
Output Logic 0 Voltage
0.4 V
1 mA load current
TIMING See Figure 2
SCK
Clock Rate, 1/tCLK 50 MHz
SDO/LOL pin maximum speed may be limited by excess
capacitance on the receiver connected to the SDO/LOL pin
Write Only 100 MHz
Pulse Width High, t
HIGH 2 ns
Pulse Width Low, tLOW 2 ns
SDI to SCK Setup, tDS 1.5 ns
SCK to SDI Hold, tDH 2 ns
SCK to Valid SDO, tDV 8 ns SDO function of SDO/LOL pin (see Figure 33)
CS to SCK Setup, tS 65 ns CS is normally held low during a complete SPI transaction
CS to SCK Hold, tC 0 ns
CS
Minimum Pulse Width High 65 ns
Timing Diagram
tS
DON' T CARE
DON'T CARE
DON' T CARE
DON' T CARE
tDS
tDH
tHIGH
tLOW
tCLK tC
CS
SCK
SDIO
DATA[7]ADDR[0] DATA[6] DATA[5] DATA[4] DATA[3] DATA[2] DATA[1] DATA[0]
OP[3] OP[2] OP[1] OP[0] ADDR[3] ADDR[2] ADDR[1]
11356-131
Figure 2. Serial Port Timing Diagram
AD9578 Data Sheet
Rev. B | Page 10 of 44
DIGITAL PLL
Table 8.
Parameter
Min
Ty p
Max
Unit
Test Conditions/Comments
FREQUENCY STEP SIZE 0.1 ppb
DIGITAL FUNCTIONS TIMING
Table 9.
Parameter Min Ty p Max Unit Test Conditions/Comments
OTP PROGRAMMING TIME, PER BIT 0.8 1 2 ms See Tabl e 4 for using CS while in OTP programming mode (the AD9578
has 444 bits; therefore, the total programming time is <1 sec)
POWER-ON RESET TIME 4 ms Do not access serial port during power-on reset.
JITTER GENERATION USING 49.152 MHZ CRYSTAL
Both PLLs are generating the same output frequency and use a 49.152 MHz crystal for the input reference. The loop bandwidth is set to
the default value of 300 kHz. Where multiple driver types are listed, there is no significant difference between driver types.
Table 10.
Parameter Min Ty p Max Unit Test Conditions/Comments
JITTER GENERATION Fractional mode on, fREF = 49.152 MHz XTAL
LVPECL, HCSL, LVDS Dr i ve r
fOUT = 622.08 MHz
Bandwidth: 12 kHz to 20 MHz 320 fs rms
Bandwidth: 20 kHz to 80 MHz
370 fs rms
fOUT
= 693.48 MHz
Bandwidth: 12 kHz to 20 MHz 403 fs rms
Bandwidth: 20 kHz to 80 MHz
408 fs rms
fOUT = 174.703 MHz
Bandwidth: 12 kHz to 20 MHz 403 fs rms
Bandwidth: 20 kHz to 80 MHz 410 fs rms
fOUT = 161.1328 MHz
Bandwidth: 12 kHz to 20 MHz 361 fs rms
Bandwidth: 20 kHz to 80 MHz 363 fs rms
LVPECL, HCSL, LVDS, LVCM O S Dr ive r
fOUT = 156.25 MHz
Bandwidth: 12 kHz to 20 MHz 350 fs rms
Bandwidth: 1.875 MHz to 20 MHz 77 fs rms
Bandwidth: 20 kHz to 80 MHz 352 fs rms
Data Sheet AD9578
Rev. B | Page 11 of 44
JITTER GENERATION USING 25 MHZ SQUARE WAVE
Both PLLs are generating the same output frequency and use a 25 MHz square wave for the input reference. The loop bandwidth is set to
the default value of 300 kHz. Where multiple driver types are listed, there is no significant difference between driver types. Fractional
mode turned on, unless otherwise stated.
Table 11.
Parameter Min Ty p Max Unit Test Conditions/Comments
JITTER GENERATION fR EF = 25 MHz square wave
LVPECL, HCSL, LVDS Dr i ve r
fOUT = 622.08 MHz
Bandwidth: 12 kHz to 20 MHz 515 fs rms
Bandwidth: 20 kHz to 80 MHz 516 fs rms
fOUT = 693.48 MHz
Bandwidth: 12 kHz to 20 MHz 504 fs rms
Bandwidth: 20 kHz to 80 MHz 505 fs rms
fOUT = 174.703 MHz
Bandwidth: 12 kHz to 20 MHz 517 fs rms
Bandwidth: 20 kHz to 80 MHz 523 fs rms
fOUT = 161.1328 MHz
Bandwidth: 12 kHz to 20 MHz 527 fs rms
Bandwidth: 20 kHz to 80 MHz
530 fs rms
LVPECL, HCSL, LVDS, LVCM O S Dr ive r
fOUT =
156.25 MHz
Integer mode operation
Bandwidth: 12 kHz to 20 MHz 290 fs rms
Bandwidth: 1.875 MHz to 20 MHz 61 fs rms
Bandwidth: 20 kHz to 80 MHz 292 fs rms
AD9578 Data Sheet
Rev. B | Page 12 of 44
ABSOLUTE MAXIMUM RATINGS
Table 12.
Parameter
Rating
Supply Voltage ( VDD) 4.6 V
Inputs ( VIN) (Except for CS Pin) 0.50 V to VDD + 0.5 V
CS Pin VDD + 2.5 V
Outputs (VOUT) 0.50 V to VDD + 0.5 V
Operating Temperature Range (T
A
)
Industrial
25°C to +85°C
Storage Temperature Range (TS) 65°C to +150°C
Stresses at or above those listed under Absolute Maximum
Ratings may cause permanent damage to the product. This is a
stress rating only; functional operation of the product at these
or any other conditions above those indicated in the operational
section of this specification is not implied. Operation beyond
the maximum operating conditions for extended periods may
affect product reliability.
ESD CAUTION
Data Sheet AD9578
Rev. B | Page 13 of 44
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
11356-002
1
2
3
4
5
6
7
24
23
22
21
20
19
18
17
16
15
14
13
44
45
46
47
48
43
42
41
40
39
38
37
TOP VIEW
(No t t o Scal e)
AD9578
25
26
27
28
29
30
31
32
33
34
35
36
8
9
10
11
12
Figure 3. Pin Configuration
Table 13. Pin Function Descriptions
Pin No. Mnemonic Ty p e Description
1 VSSO1
Negative power
Return Path Ground for Clock Output 1.
2 OUT1 Output Clock Output 1 Derived from PLL1. Supports frequencies up to the device maximum. OUT1
is a selectable 1 pin. When used in LVCMOS mode, OUT1 is the active pin.
3 OUT1 Output
Active Low Clock Output 1 Derived from PLL1. Supports frequencies up to the device
maximum. OUT1 is a selectable1 pin. OUT1 is not used in LVCMOS mode; it is high-Z in
LVCMOS mode.
4 VDDO1
Supply,
positive power
Power Supply for Clock Output 1.
5, 12, 25,
31, 37, 48
VDDA
Supply, positive
power
2.5 V or 3.3 V Analog Power Supply.
6 VDDO2 Supply, positive
power
Power Supply for Clock Output 2.
7 OUT2 Output
Clock Output 2 Derived from PLL1. Supports frequencies up to the device maximum. OUT2
is a selectable1 pin. When used in LVCMOS mode, OUT2 is the active pin.
8 OUT2 Output
Active Low Clock Output 2 Derived from PLL1. Supports frequencies up to the device
maximum. OUT1 is a selectable1 pin. OUT2 is not used in LVCMOS mode; it is high-Z in
LVCMO S mo de .
9 VSSO2 Negative power Return Path Ground for Clock Output 2.
10, 36 VSS Negative power Device Ground.
11 OEREF Input Output Enable for REFOUT and REFOUT P i ns, LVCM O S. Active high. This pin has an internal
75 kpull-down resistor.
13 FI LTER 1 + Filter
Phase-Locked Loop 1 (PLL1) Filter Node, Positive Side. Connect a 220 nF capacitor between
this pin and Pin 14.
14 FI LTER 1 Filter PLL1 Filter Node, Negative Side. Connect a 220 nF capacitor between this pin and Pin 13.
15 OE1 Input Output Enable 1 for Clock Output 1, LVCMO S. Places OUT1 and OUT1 in a high-Z state.
Active high. This pin has an internal 75 kΩ pull-up resistor.
16 OE2 Input Output Enable 2 for Clock Output 2, LVCMO S. Places OUT2 and OUT2 in a high-Z state.
Active high. This pin has an internal 75 kΩ pull-up resistor.
17 SDO/LOL Output Serial Data Output for SPI Control/Loss of Lock, LVCM O S.
18 CS Input
Chip Select for SPI Control, LVCMO S. Active low. When this pin is set to 5 V, OTP
programming is enabled (see Tabl e 4 and the OTP Programming section). This pin has an
internal 75 kΩ pull-up resistor.
19 SCK Input Serial Clock Input for SPI Control, LVCM O S.
AD9578 Data Sheet
Rev. B | Page 14 of 44
Pin No. Mnemonic Ty p e Description
20 SDI Input Serial Data Input for SPI Control, LVCMO S.
21 OE3 Input Output Enable 3 for Clock Output 3, LVCMO S. Places OUT3 and OUT3 in a high-Z state.
Active high is the default but active low is programmable. This pin has an internal 75 kΩ
pull-up resistor.
22 OE4 Input Output Enable 4 for Clock Output 4, LVCMO S. Places OUT4 and OUT4 in a high-Z state.
Active high is the default but active low is programmable. This pin has an internal 75 kΩ
pull-up resistor.
23 FI LTER 2 Filter PLL2 Filter Node, Negative Side. Connect a 220 nF capacitor between this pin and Pin 24.
24 FI LTER 2 + Filter PLL2 Filter Node, Positive Side. Connect a 220 nF capacitor between this pin and Pin 23.
26 PD1 Input Active Low Power-Down for PLL1, LVCM O S. This pin has an internal 75 kΩ pull-up resistor.
27 VSSO3 Negative power Return Path Ground for Clock Output 3.
28 OUT3 Output
Active Low Clock Output 3 Derived from PLL2. Supports frequencies up to the device
maximum. OUT3 is a selectable1 pin. OUT3 is not used in LVCMOS mode; it is high-Z in
LVCMO S mo de .
29 OUT3 Output
Clock Output 3 Derived from PLL2. Supports frequencies up to the device maximum. OUT3
is a selectable1 pin. When used in LVCMOS mode, OUT3 is the active pin.
30 VDDO3 Supply, positive
power
Power Supply for Clock Output 3.
32 VDDO4
Supply, positive
power
Power Supply for Clock Output 4.
33 OUT4 Output Clock Output 4 Derived from PLL2. Supports frequencies up to the device maximum. OUT4
is not used in LVCMOS mode and is high-Z. OUT4 is a selectable1 pin.
34 OUT4 Output
Clock Output 4 Derived from PLL2. Supports frequencies up to the device maximum. OUT4
is a selectable1 pin. When used in LVCMOS mode, OUT4 is the active pin.
35 VSSO4 Negative power Return Path Ground for Clock Output 4.
38 XO2 Input Reference Input 1. Connect a crystal across this pin and XO1. Alternatively, the user can
connect a 1.8 V LVCMOS clock to this pin only, or connect a differential, ac-coupled LVDS or
LVPECL signal across this pin and the XO1 pin. This pin can be a crystal or reference input.
39 XO1 Input
Complementary Reference Input 1. Connect a crystal across this pin and XO2. Alternatively,
the user can connect a differential, ac-coupled LVDS or LVPECL signal to this pin and the
XO2 pin. This pin can be a crystal or reference input.
40, 41, 42 NIC No Internal Connection. Leave these pins unconnected.
43 REFOU T Output
Active Low Reference Clock Output. This pin provides a copy of the reference input or
crystal input frequency. REFOUT is a selectable1 pin.
44 REFOUT Output
Reference Clock Output. This pin provides a copy of the reference input or crystal input
frequency. REFOUT is a selectable1 pin.
45 XO4 Input
Reference Input 2. Connect a crystal across this pin and XO3. Alternatively, connect a 1.8 V
LVCMO S clock to this pin only, or connect a differential, ac-
coupled LVDS or LVPECL signal
across this pin and the XO3 pin. This pin can be a crystal or reference input.
46 XO3 Input
Complementary Reference Input 2. Connect a crystal across this pin and XO4. Alternatively,
connect a differential, ac-coupled LVDS or LVPECL signal to this pin and the XO4 pin.
47 VDD
Supply, positive
power
2.5 V or 3.3 V Power Supply for Device Core. This pin can be a crystal or reference input.
EPAD Exposed Pad. The exposed pad on the bottom of the package must be connected to
ground for proper operation.
1 Selectable pins are factory programmed to a default power-up configuration. The user can override the default programming to support LVCMOS, LVDS, LVPECL, or
HCSL mode after power-up using the SPI.
Data Sheet AD9578
Rev. B | Page 15 of 44
TYPICAL PERFORMANCE CHARACTERISTICS
fR is the input reference clock frequency; fOUT is the output clock frequency; VDD at nominal supply voltage (3.3 V). 25 MHz square wave
input is a dc-coupled 3.3 V LVCMOS signal with 0.8 ns (20% to 80%) rise time.
PHASE NOISE (dBc/Hz)
70
–160
–80
–90
–100
–110
–120
–130
–140
–150
–170
1k
10010M
100k
10k1M100M
FREQUENCY (Hz)
INTEGRATED RMS JITTER
(12kHz TO 20MHz): 290
fs
PHASE NOISE (dBc/Hz):
OFFSET
100Hz
1kHz
10kHz
100kHz
1MHz
10MHz
FLOOR
LEVEL
–116
–125
–132
–133
–142
–163
–164
11356-003
Figure 4. Absolute Phase Noise (Output Driver = LVDS),
fR = 25 MHz Square Wave, fOUT = 156.25 MHz on Both PLLs
PHASE NOISE (dBc/Hz)
70
–170
–80
–90
–100
–110
–120
–130
–140
–150
–160
100 1k 10M100k10k 1M 100M
FREQUENCY (Hz)
INTEGRATED RMS JITTER
(12kHz TO 20MHz): 527
fs
PHASE NOISE (dBc/Hz):
OFFSET
100Hz
1kHz
10kHz
100kHz
1MHz
10MHz
FLOOR
LEVEL
–113
–123
–127
–122
–144
–163
–163
11356-004
Figure 5. Absolute Phase Noise (Output Driver = LVCMOS),
fR = 25 MHz Square Wave, fOUT = 161.1328125 MHz on Both PLLs
PHASE NOISE (dBc/Hz)
70
–170
–80
–90
–100
–110
–120
–130
–140
–150
–160
1k
10010M
100k
10k1M100M
FREQUENCY (Hz)
INTEGRATED RMS JITTER
(12kHz TO 20MHz): 517fs
PHASE NOISE (dBc/Hz):
OFFSET
100Hz
1kHz
10kHz
100kHz
1MHz
10MHz
FLOOR
LEVEL
–114
–123
–128
–125
–137
–162
–163
11356-005
Figure 6. Absolute Phase Noise (Output Driver = LVPECL),
fR = 25 MHz Square Wave, fOUT = 174.703 MHz on Both PLLs
1k
10010M
100k
10k1M100M
PHASE NOISE (dBc/Hz)
70
–170
–80
–90
–100
–110
–120
–130
–140
–150
–160
INTEGRATED RMS JITTER
(12kHz TO 20MHz): 350fs
PHASE NOISE (dBc/Hz):
OFFSET
100Hz
1kHz
10kHz
100kHz
1MHz
10MHz
FLOOR
LEVEL
–116
–121
–129
–130
–141
–162
–164
11356-006
FREQUENCY (Hz)
Figure 7. Absolute Phase Noise (Output Driver = LVDS),
fR = 49.152 MHz Crystal, fOUT = 156.25 MHz on Both PLLs
PHASE NOISE (dBc/Hz)
70
–170
–80
–90
–100
–110
–120
–130
–140
–150
–160
FREQUENCY (Hz)
INTEGRATED RMS JITTER
(12kHz TO 20MHz): 361fs
PHASE NOISE (dBc/Hz):
OFFSET
100Hz
1kHz
10kHz
100kHz
1MHz
10MHz
FLOOR
LEVEL
–104
–122
–127
–129
–140
–161
–163
11356-007
1k
10010M
100k
10k1M100M
Figure 8. Absolute Phase Noise (Output Driver = 3.3.V LVCMOS),
fR = 49.152 MHz Crystal, fOUT = 161.1328125 MHz on Both PLLs
1k
10010M
100k
10k1M100M
PHASE NOISE (dBc/Hz)
70
–170
–80
–90
–100
–110
–120
–130
–140
–150
–160
FREQUENCY (Hz)
INTEGRATED RMS JITTER
(12kHz TO 20MHz): 403fs
PHASE NOISE (dBc/Hz):
OFFSET
100Hz
1kHz
10kHz
100kHz
1MHz
10MHz
FLOOR
LEVEL
–105
–121
–127
–126
–141
–163
–165
11356-008
Figure 9. Absolute Phase Noise (Output Driver = LVPECL),
fR = 49.152 MHz Crystal, fOUT = 174.703 MHz on Both PLLs
AD9578 Data Sheet
Rev. B | Page 16 of 44
PHASE NOISE (dBc/Hz)
–60
–70
–160
–80
–90
–100
110
–120
–130
–140
–150
FREQUENCY (Hz)
INTEGRAT ED RM S JITTER
(12kHz TO 20MHz) : 515f s
PHASE NO ISE ( d Bc /Hz):
OFFSET
100Hz
1kHz
10kHz
100kHz
1MHz
10MHz
FLOOR
LEVEL
–102
–112
–115
–110
–128
–155
–159
11356-009
1k
100 10M
100k
10k 1M 100M
Figure 10. Absolute Phase Noise (Output Driver = LVPECL),
fR = 25 MHz 3.3 V LVC MOS Square Wave, fOUT = 622.08 MHz on Both PLLs
1k
100 10M
100k
10k 1M 100M
PHASE NOISE (dBc/Hz)
–70
–170
–80
–90
–100
–110
–120
–130
–140
–150
–160
FREQUENCY (Hz)
INTEGRATED RM S J ITTER
(12kHz TO 20MHz) : 504f s
PHASE NO ISE (dBc/Hz ):
OFFSET
100Hz
1kHz
10kHz
100kHz
1MHz
10MHz
FLOOR
LEVEL
–101
111
–114
–110
–127
–153
–154
11356-010
Figure 11. Absolute Phase Noise (Output Driver = LVPECL),
fR = 25 MHz Square Wave, fOUT = 693.482991 MHz on Both PLLs
PHASE NOISE (dBc/Hz)
–70
–170
–80
–90
–100
–110
–120
–130
–140
–150
–160
FREQUENCY (Hz)
INTEGRATED RM S J ITTER
(12kHz TO 20MHz) : 506f s
PHASE NO ISE (dBc/Hz ):
OFFSET
100Hz
1kHz
10kHz
100kHz
1MHz
10MHz
FLOOR
LEVEL
–101
–110
–114
–110
–108
–154
–160
11356-011
1k
100 10M
100k
10k 1M 100M
Figure 12. Absolute Phase Noise (Output Driver = LVPECL),
fR = 25 MHz Square Wave on XO1/XO2 Pins, fOUT = 919 MHz on Both PLLs
1k
100 10M
100k
10k 1M 100M
PHASE NOISE (dBc/Hz)
–60
–70
–160
–80
–90
–100
110
–120
–130
–140
–150
FREQUENCY (Hz)
INTEGRAT ED RM S JITTER
(12kHz TO 20MHz) : 327f s
PHASE NO ISE ( d Bc /Hz):
OFFSET
100Hz
1kHz
10kHz
100kHz
1MHz
10MHz
FLOOR
LEVEL
–95
–110
–116
–118
–132
–155
–158
11356-012
Figure 13. Absolute Phase Noise (Output Driver = LVPECL),
fR = 49.152 MHz Crystal, fOUT = 622.08 MHz on Both PLLs
PHASE NOISE (dBc/Hz)
–60
–70
–160
–80
–90
–100
110
–120
–130
–140
–150
FREQUENCY (Hz)
INTEGRATED RM S J ITTER
(12kHz TO 20MHz) : 392f s
PHASE NO ISE (dBc/Hz ):
OFFSET
100Hz
1kHz
10kHz
100kHz
1MHz
10MHz
FLOOR
LEVEL
–93
–110
–116
–118
–125
–153
–155
11356-013
1k
100 10M
100k
10k 1M 100M
Figure 14. Absolute Phase Noise (Output Driver = LVPECL),
fR = 49.152 MHz Crystal, fOUT = 693.482991 MHz on Both PLLs
PHASE NOISE (dBc/Hz)
–70
–170
–80
–90
–100
–110
–120
–130
–140
–150
–160
FREQUENCY (Hz)
INTEGRATED RM S J ITTER
(12kHz TO 20MHz) : 361f s
PHASE NO ISE (dBc/Hz ):
OFFSET
100Hz
1kHz
10kHz
100kHz
1MHz
10MHz
FLOOR
LEVEL
–93
–107
–114
–116
–122
–152
–159
11356-014
1k
100 10M
100k
10k 1M 100M
Figure 15. Absolute Phase Noise (Output Driver = LVPECL),
fR = 49.152 MHz Crystal, fOUT = 919 MHz on Both PLLs
Data Sheet AD9578
Rev. B | Page 17 of 44
PHASE NOISE (dBc/Hz)
–60
–70
–80
–90
–100
–110
–120
–130
–140
–150
–160
FREQUENCY (Hz)
INTEGRATED RMS JITTER
(12kHz TO 5MHz ) : 5.8p s
PHASE NOI SE (d Bc/Hz):
OFFSET
100Hz
1kHz
10kHz
100kHz
1MHz
10MHz
FLOOR
LEVEL
–100
–110
–118
–127
–130
–131
–131
11356-015
1k
100 10M
100k
10k 1M 100M
Figure 16. Phase Noise of 25 MHz, 3.3 V LVCMOS Input Clock Used
DIFFERENTIALAMPLI T UDE (V)
TIME (ns)
–0.4
–0.3
–0.2
–0.1
0
0.1
0.2
0.3
0.4
2.0
1.5
1.0
0.5 00.5 1.0 1.5 2.0 2.5 3.0
11356-023
Figure 17. Output Waveform, LVDS (400 MHz)
DIFFERENTIALAMPLITUDE (V)
TIME (ns)
–1.0
–0.8
–0.6
–0.4
–0.2
0
0.2
0.4
0.6
0.8
1.0
2.0
1.5
1.0
0.5 00.5 1.0 1.5 2.0 2.5 3.0
11356-024
Figure 18. Output Waveform, HCSL (400 MHz)
11356-025
–0.5
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
0 1 2 3 4 5 6 7 8 9 10 11 12
AMPLITUDE (V)
TIME (ns)
10pF LOAD
2pF LOAD
Figure 19. Output Waveform, 3.3 V CMOS (100 MHz)
–0.4
–0.3
–0.2
–0.1
0
0.1
0.2
0.3
0.4
00.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2
DIFFERENTIALAMPLITUDE (V)
TIME (ns)
11356-040
Figure 20. Output Waveform, LVDS (900 MHz)
–1.2
–1.0
–0.8
–0.6
–0.4
–0.2
0
0.2
0.4
0.6
0.8
1.0
1.2
–2.0 –1.5 –1.0 –0.5 00.5 1.0 1.5 2.0 2.5 3.0
DIFFERENTIALAMPLI T UDE (V)
TIME (ns)
11356-041
Figure 21. Output Waveform, LVPECL (400 MHz)
AD9578 Data Sheet
Rev. B | Page 18 of 44
TEST SETUP AND CONFIGURATION CIRCUITS
VDD VSS
50Ω
OSCILLOSCOPE
50Ω
OSCILLOSCOPE
VDDOx OUTx
AD9578
OUTx
VSS
VSS POW E R = –1.3V
LEAVE VDD FI XED AT 2.0V AND ADJUST V SS.
VDD PO W ER
VDD = 2.0V
11356-030
Figure 22. LVPECL Test Circuit
VDD VSS
VSS POW E R = –1.65V
ADJUST VSS AND VDD TOGETHER.
VDD PO W ER
VDD = 1.65V OPEN
50Ω
OSCILLOSCOPE
11356-031
VDDOx OUTx
AD9578
OUTx
VSS
Figure 23. LVCMOS Test Circuit
VDD
50Ω
OSCILLOSCOPE
ADJUST VDD.
VDD PO W ER
VDD = 3.3V
50Ω
OSCILLOSCOPE
11356-032
VDDOx OUTx
AD9578
OUTx
VSS
Figure 24. LVDS Test Circuit
V
DD
V
SS
V
DD
POWER
V
DD
= 3.3V
50Ω
OSCILLOSCOPE
50Ω
OSCILLOSCOPE
11356-033
VDDOx OUTx
AD9578
OUTx
VSS
Figure 25. HCSL Test Circuit
Data Sheet AD9578
Rev. B | Page 19 of 44
INPUT/OUTPUT TERMINATION RECOMMENDATIONS
See Figure 26 to Figure 30 for recommendations on how to connect the outputs.
R1 R1
R2
R2
LVPECL LVPECL
VDD
VDD
VDD
VDD 3.3V 2.5V
R1
R2
240Ω130Ω
82Ω82Ω
Z0 = 50Ω
Z0 = 50Ω
11356-026
Figure 26. Thevenin Equivalent DC-Coupled LVPECL Termination
V
DD
V
DD
AD9578
LVPECL
MODE
LVPECL
RECEIVER
100Ω
200Ω 200Ω
Z
0
= 50Ω
Z
0
= 50Ω
11356-027
Figure 27. AC-Coupled LVPECL Termination
V
DD
V
DD
AD9578
LVDS LVDS
RECEIVER
100Ω
Z
0
= 50Ω
Z
0
= 50Ω
11356-028
Figure 28. AC-Coupled LVDS
VDD VDD
AD9578
HCSLHCSL
RECEIVER
50Ω
50Ω
33Ω
(OPTIONAL)
(OPTIONAL)
33Ω
Z0 = 50Ω
Z0 = 50Ω
11356-128
NOTES
1. THE 50Ω PULL-DOWN RESISTORS CAN BE P LACED
IMMEDIATELY AFTER 33Ω SERIES RESISTORS, AND DOI NG
SOALL O W S T HE USER TO PLACE MULTIPLE HIGH
IMP E DANCE LO ADS AT THE DESTINATION. FOR DRIVING A
SINGLE LOAD, THE 50 Ω PULL-DOWN RESISTORS CAN BE
PLACE D NE AR THE DRIVER OR NEAR THE DES TI NATION.
EITHER IMPLEMENTATION IS FINE.
Figure 29. DC-Coupled HCSL
33Ω
AD9578 CMOS
(HIGH-Z)
Z
0
= 50Ω
V
DD
= 2. 5V OR 3.3V V
DD
= 2. 5V OR 3.3V
(SAME AS AD9578)
11356-029
Figure 30. DC-Coupled LVCMOS Termination
AD9578 Data Sheet
Rev. B | Page 20 of 44
GETTING STARTED
CHIP POWER MONITOR AND STARTUP
The AD9578 monitors the voltage on the power supplies at
power-up. When power supplies are greater than 2.1 V ± 0.1 V,
the device generates an internal reset pulse, at which time, the
AD9578 loads the values programmed in OTP memory. Do not
use the SPI until 4 ms after power-up to ensure that all registers
are correctly loaded from the OTP memory and that all internal
voltages are stable.
It is possible for the user to overwrite any value stored in the
OTP memory if the security bits in Register 0x00 were not set at
the time the OTP programming occurred. Tak e c are not to
overwrite the factory programmed calibrations (Register 11
through Register 14).
When programming the device through the serial port, write
unused or reserved bits to their default values as listed in the
register map.
DEVICE REGISTER PROGRAMMING USING
A REGISTER SETUP FILE
The evaluation software contains a programming wizard and
a convenient graphical user interface that assists the user in
determining the optimal configuration for the device. It
generates a register setup file with a .STP extension that is easily
readable using a text editor. These registers can be loaded
directly into the AD9578.
OTP PROGRAMMING
The AD9578 has 444 bits of OTP memory. OTP stores the
nonvolatile default configuration used on power-up.
The default configuration is determined and programmed by
the user. Use the SPI to overwrite these bits and change the
operation of the AD9578 after power-up. The SPI Programming
section describes how the bits affect the device operation and
how to use the SPI to modify them.
Data Sheet AD9578
Rev. B | Page 21 of 44
THEORY OF OPERATION
AD9578
FRACTIONAL
PLL2
(3053MHz TO 3677MHz)
FRACTIONAL
PLL1
(3053MHz TO 3677MHz)
OUT1
DIVIDER
÷4 TO ÷259
OUT2
DIVIDER
÷4 TO ÷259
OUT3
DIVIDER
÷4 TO ÷259
OUT4
DIVIDER
÷4 TO ÷259
REFOUT
REFOUT
OUT1
OUT1
OEREF
OE1
OUT2
OUT2
OE2
OUT3
OUT3
OE3
OUT4
OUT4
OE4
PD1
CS SCK SDI SDO/
LOL
FILTER2+ FILTER2
REFERENCE
MUX SELECT
REFSEL2
REFSEL1
SPI AND OTP
PROGRAMMABLE
LOGIC CONTROL
FILTER1+ FILTER1
OPTIONAL
OPTIONAL
XO3
XO4
XO1
XO2
REF1
REF2
NOTES
1. IF SUPPLYING A SINGLE-ENDED 1.8V CMOS SIGNAL, CONNECT THE SIGNAL TO EITHER XO2 OR XO4.
11356-034
Figure 31. Detailed Block Diagram
OVERVIEW
The AD9578 is a dual synthesizer with four programmable
outputs. Two PLLs, with either a crystal or external reference
input frequency, produce up to four unique output frequencies.
Output format standards on each output include LVCMOS, LVDS,
LVPECL, and HCSL. The input crystal is a low cost fundamental
mode type, and the AD9578 provides programmable gain and
load capacitors. Alternatively, an input reference clock can be
used for either or both PLLs. The crystal or external reference
frequency is available on the REFOUT/REFOUT pins.
The PLLs operate independently but may share the input
reference, if desired. Three modes of operation can be selected:
integer mode, fractional mode, and rational mode. The integer
mode provides the lowest noise and behaves like a conventional
PLL with whole number dividers. The fractional mode allows
the feedback divider to have an 8-bit integer part and a 28-bit
fractional part, resulting in a frequency resolution of 0.1 ppb or
better. Rotary traveling wave oscillator (RTWO)-based VCOs
operate at rates from 3053 MHz to 3677 MHz. Rational mode is
similar to fractional mode, but allows the user to specify the
feedback divider in terms of one integer divided by another.
There are two output dividers on each VCO, with a range of 4 to
259. To prevent an output frequency gap between 750.8 MHz
and 777.25 MHz, a special divide by 4.5 mode is also included.
Any output frequency between 11.8 MHz and 919 MHz can be
produced with a frequency error of 0.1 ppb or better.
Additional features include loss of lock indicators, smooth change
of output frequency for small frequency steps, and SPI control.
The AD9578 can be configured through the SPI, factory
programmed, user programmed, or any combination thereof.
The AD9578 ships with a default power-up configuration pro-
grammed into OTP memory. All settings can be reprogrammed
after power-up using the SPI.
At offset frequencies below the PLL bandwidth (which is
typically 300 kHz), the PLL tracks and multiplies the reference
phase noise. The crystal input offers a very low phase noise
reference, ensuring that the output phase noise near the carrier
is low. When selecting the reference input signal, ensure that the
phase noise of the reference input is low enough to meet the
system noise requirements.
AD9578 Data Sheet
Rev. B | Page 22 of 44
PLL AND OUTPUT DRIVER CONTROL
Table 14. Register 2 Bits
Bits Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
[23:16] Unused MR
(master
reset)
MR enable
(set to 1 to
enable MR)
REFOUT REFOUT enable
(override OEREF
pin)
[15:8] OUTPUT4 Override OE4 pin OUTPUT3 Override OE3 pin OUTPUT2
Override OE2
pin
OUTPUT1
Override OE1
pin
[7:0] REFSEL2 REFSEL2 enable
(set to 1 to enable
REFSEL2)
REFSEL1 REFSEL1 enable
(set to 1 to enable
REFSEL1)
PLL2 PLL2 enable (set
to 1 to enable
PLL2)
PLL1 PLL1 enable
(override PD1
pin)
Table 15. Register 4 Bits
Bits Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
[15:8] XTA L frequency trim XTA L Capacitance Value[2:0] Unused XTA L Gain[2:0]
[7:0] OUTPUT4 Mode[1:0] OUTPUT3 Mode[1:0] OUTPUT2 Mode[1:0] OUTPUT1 Mode[1:0]
OVERVIEW
The AD9578 has five output drivers: OUTPUT1, OUTPUT2,
OUTPUT3, OUTPUT4, and REFOUT. Each output can be
individually configured as LVC M OS , LVD S , LVP E CL, or HCSL.
Each output has an output enable pin (OEx). Pin control of the
outputs is enabled when the corresponding override OEx pin bit
in Register 2 is low. When configured this way, the OUTPUTx bit
is read only and indicates the status of the OEx pin.
When the override OEx pin (where x = 1 to 4) bit is high, the
OUTPUTx bit in Register 2 turns OUTPUTx on and off. See
Tabl e 14 for the contents of Register 2.
The AD9578 ships with the default start-up output enable and
output format functionality selected by the user. After power-
up, the user can override the default programming through the
SPI.
PLL ENABLE/DISABLE
Each output is enabled only if the associated PLL is powered up.
Bits[3:0] in Register 2 control this function. There are two ways
to power up/down PLL1. If the PLLx enable bit is 0, the user can
power down PLL1 by pulling the PD1 pin low. If the PLLx
enable bit is high, PLL1 is powered up/down using the PLL1 bit
(Bit 1). PLL2 is under software control only. Therefore, always
set Bit 2 to 1. The PLL2 bit (Bit 3) powers up/down PLL2.
Reading the Hardware OEx Pin States
By default, the AD9578 OEx pins determine which outputs are
enabled. If the corresponding override OEx pin bits are not set
in Register 2, the user can read the states of these pins by
reading Register 2. Note that the OE1, OE2, OE3, and OE4 pins
have 75 kΩ pull-up resistors.
Disabling Hardware OEx Pin Control
To disable the hardware pin control, the associated override
OEx pin bit can be set in Register 2 (see Tab le 14). The override
OEx pin bits are OTP, allowing the device to power up with
any output forced on, forced off, or controlled by the OEx pin.
In Register 2, when the override OEx pin bit is set to 1, the
corresponding OEx pin is ignored, and the OUTPUTx bit
enables or disables an input or output. To enable an output, both
the override OEx pin bit and the OUTPUTx bit in Register 2 must
be set to 1.
Glitch-Free Output Enable
When an output changes from disabled to enabled, there is an
approximate 2 µs delay before switching begins. During this
delay, the outputs settle to the appropriate dc differential levels
according to the configured mode. After this initial delay, the
outputs begin toggling without glitches or runt pulses.
Output Disable Sequence
When an output changes from enabled to disabled, it stops
switching at the appropriate dc levels according to the
configured mode. After it has stopped switching, the biases are
disabled and the output is set to high impedance.
Data Sheet AD9578
Rev. B | Page 23 of 44
OUTPUT DRIVER FORMAT
The default power-up output mode is factory programmed to
single-ended LVC M O S . The user can override the defaults
using the serial port, and the drivers can be programmed
simultaneously.
Table 16. Output Driver Modes1
OUTPUTx Mode[1:0] Output Mode
00 LVCM O S
01 LVDS
10 LVPECL
11 HCSL
1 To disable any output through the SPI, the corresponding override OEx pin
bit and OUTPUTx bit must be set to 1 and 0, respectively. This prevents any
condition of the external OEx pin from affecting the state of the output
driver. In OTP programming, setting the override bit to 1 disables the output
pin permanently.
Note that all of the output modes are differential except
LVCMOS mode. When LVCMOS is selected, the positive
output pin is LVC M O S , and the negative (complementary)
output pin is high impedance. The LV C M O S output driver
mode can be used for output frequencies 250 MHz, and a
series termination resistor is recommended (see Figure 30).
Place a series termination 33 resistor within 7 mm of the
AD9578. A 50 transmission line configured this way is
impedance matched. However, differential output modes are
preferred over single-ended modes to preserve the high
performance of the AD9578 and to reduce noise pickup and
generation.
OUTPUT CONFIGURATION EXAMPLE
Tabl e 17 and Table 18 show how Register 2 and Register 4,
respectively, are used to configure the AD9578 inputs and
outputs.
PLL1 and PLL2 are enabled so that the output drivers
connected to them are also enabled.
The OE1 and OE2 pins are ignored, OUTPUT1 is enabled and
in LVC M O S mode, and OUTPUT2 is disabled. The OE3 and
OE4 pins determine the state of OUTPUT3 and OUTPUT4,
respectively. The REFOUT driver is disabled, OUTPUT3 is
LVDS, and OUTPUT4 is LVP EC L.
The X in Table 17 and Table 18 indicates that the register bit is
not related to output driver configuration.
Table 17. Example of Output Driver Configuration Using Register 2
Bits
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
[23:16]
Unused = XXXX
MR (master
reset) = 0
MR enable
= 1
REFOUT =
0
REFOUT enable
(override OEREF pin) = 1
[15:8]
O UTP UT4 =
X
Override OE4
pin = 0
O UTP UT3 =
X
Override
OE3 pin = 0
OUTPUT2 = 0
Override
OE2 pin = 1
OUTPUT1
= 1
Override OE1 pin = 1
[7:0]
REFSEL2 =
X
REFSEL2
enable = X
REFSEL1 =
X
REFSEL1
enable = X
PLL2 = 1
PLL2
enable =1
PLL1 = 1
PLL enable (override
PD1 pin) = 1
Table 18. Example of Output Driver Configuration Using Register 4
Bits Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
[15:8] XTA L 1 frequency trim = X XTA L1 Capacitance Value[2:0] = XXX Unused = X X TA L1 Gain[2:0] = XXX
[7:0] OUTPUT4 Mode[1:0] = 10 OUTPUT3 Mode[1:0] = 01 OUTPUT2 Mode[1:0] = XX OUTPUT1 Mode[1:0] = 00
AD9578 Data Sheet
Rev. B | Page 24 of 44
REFERENCE INPUT
Table 19. Register 2 Bits
Bits Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
[23:16] Unused MR
(master
reset)
MR enable (set
to 1 to enable
MR bit)
REFOUT REFOUT enable
(override OEREF
pin)
[15:8] OUTPUT4 Override OE4 pin OUTPUT3 Override OE3 pin OUTPUT2
Override OE2
pin
OUTPUT1 Override OE1 pin
[7:0] REFSEL2 REFSEL2 enable
(set to 1 to
enable REFSEL2
bit)
REFSEL1 REFSEL1 enable
(set to 1 to
enable REFSEL1
bit)
PLL2 PLL2 enable
(set to 1 to
enable PLL2
bit)
PLL1 PLL1 enable
(override PD1 pin)
(set to 1 to enable
PLL1 bit)
Table 20. Register 3 Bits
Bits Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
[31:24]
REFOUT
mode[1:0]
Unused
Enable activity
detect (set to 1)
Reference mux
select
Enabl e XTA L1 Unused
[23:16] Unused
Enable OUTPUT4
divider
Enable OUTPUT3
divider
Enable OUTPUT2
divider
Enable OUTPUT1
divider
[15:8] Unused LVCM O S Edge Trim[2:0]
Enable OUTPUT4
4.5 mode
Enable OUTPUT3
4.5 mode
Enable OUTPUT2
4.5 mode
Enable OUTPUT1
4.5 mode
[7:0] Exponent[3:0] Mantissa[3:0]
OVERVIEW
Two reference inputs are available for the PLLs. The user can
connect either a crystal or an input clock to the XO1/XO2 pins
or the XO3/XO4 pins. The allowable reference input logic types
are 1.8 V LV C M O S , ac-coupled LVDS, and ac-coupled LVP E C L.
The crystal oscillators accept standard crystals from 22 MHz to
54 MHz. Either reference can be used by either PLL through the
internal selectors. Likewise, either reference can be buffered to
the REFOUT driver, which supports LVC M O S, LVD S , LVP E C L ,
or HCSL format. OTP fuses are available to automatically load
the user settings loaded each time the chip powers up or resets.
Register 2 contains the reference input control bits, Bits[7:4],
and is shown in Tabl e 19. Register 3 contains the configuration
bits for the input reference buffer, and reference output, shown in
Table 20. See the PLL and Output Driver Control section for
information about the control of the reference output buffer.
REFERENCE INPUT
Table 21. PLL1 Reference Selection
Register 2 Register 3
REFSEL1
Enable REFSEL1
Enable
X TAL 1 PLLx Reference
0 X1 X1 Reference 1 (XO1, XO2)
1
0
X
1
Reference 1 (XO1, XO2)
1 1 X1 Reference 2 (XO3, XO4)
1 X = don’t care.
Table 22. PLL2 Reference Selection
Register 2
Register 10
REFSEL2
Enable REFSEL2
Enable
XTAL 2 PLLx Reference
0 X1 X1 Reference 1 (XO1, XO2)
1 0 X1 Reference 1 (XO1, XO2)
1 1 X1 Reference 2 (XO3, XO4)
1 X = don’t care.
CRYSTAL OSCILLATOR AMPLIFIER ENABLE
The crystal oscillator amplifier is automatically enabled when
either the PLLx or REFOUT bit in Register 2 uses the crystal
oscillator for either Reference 1 or Reference 2. Otherwise, the
crystal oscillator amplifier is disabled if neither the PLLx nor
REFOUT bit selects that input. However, this setting can be
overridden with the enable X TA L1 bit in Register 3 and enable
X TAL2 bit in Register 10. Setting these bits forces the
corresponding crystal oscillator on.
These bits are useful to allow a crystal to power up and stabilize
before it is needed. However, these bits are usually set to 0
under normal operation.
REFOUT/REFOUT SOURCE SELECTION
The REFOUT/REFOUT pins can be used to buffer the crystal
oscillator signal. Like the other outputs, it can be set to
LVP E C L, LVDS, HCSL, or LVCMOS format (see the PLL and
Output Driver Control section for more information).
Data Sheet AD9578
Rev. B | Page 25 of 44
CRYSTAL OSCILLATOR INPUTS
Table 23. Register 4 Bits
Bit Range Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
[15:8] XTA L 1 frequency trim XTA L 1 Capacitance Value[2:0] Unused XTA L1 Gain[2:0]
[7:0] OUTPUT4 Mode[1:0] OUTPUT3 Mode[1:0] OUTPUT2 Mode[1:0] OUTPUT1 Mode[1:0]
Table 24. Register 10 Bits
Bit Range Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
[15:8] XTAL2 frequency trim XTAL2 Capacitance Value[2:0] XTAL2 Gain[2:0] XTA L2 En abl e
[7:0] Sync Step[3:0] Sync DIVN[3:0]
OVERVIEW
The quartz crystal inputs, XO1/XO2 and XO3/XO4, accept
standard 8 pF to 12 pF AT cut crystals from 22 M Hz t o 54 MHz.
These inputs have programmable gain and programmable
on-chip load capacitors so that a wide range of crystals can be
used.
In general, use the highest frequency crystal for lowest phase
noise. If integer modes of PLL operation are possible, select the
crystal such that the overall frequency multiplication is an
integer value for lowest noise.
XTAL Enable
Setting the enable X TAL1 bit in Register 3 (for the crystal
connected to the XO1/XO2 pins), or enable X TA L2 in Regist er 10
(for the crystal connected to the XO3/XO4 pins), and the
REFSELx bit in Register 2 enables the second crystal oscillator.
The second crystal oscillator (OSC2) is on Pin 45 and Pin 46,
XO4 and XO3, respectively. OSC2 is useful if the crystal
frequency on the first crystal oscillator (OSC1) results in an
integer boundary spur; OSC2 can be set to a different frequency
that does not cause an integer boundary. OSC2 is automatically
enabled if it is selected and is disabled otherwise.
CRYSTAL OSCILLATOR GAIN
Set the X TALx frequency trim bit in Register 4 and Register 10
if the crystal frequency is 33 MHz or lower. The recommended
values for the bits in Register 4 and Register 10 are given in
Table 25.
Table 25. XTALx Gain[2:0] Values
Crystal
Frequency (MHz)
X TAL x Gain[2:0] X TAL x
Frequency
Trim Bit
ESR =
25 Ω
ESR =
35 Ω
ESR =
45 Ω
22 0 1 3 1
27 1 2 4 1
33 2 3 5 1
34 1 2 3 0
39 2 3 4 0
44 3 4 5 0
49 4 5 6 0
54 5 6 7 0
CRYSTAL LOAD CAPACITORS
The AD9578 has internal crystal load capacitors that are used as
the load capacitance for an external crystal. X TALx Capacitance
Value [2:0], Bits[14:12] in Register 4 (for the crystal connected
to the XO1/XO2 pins) or Register 10 (for the crystal connected
to the XO3/XO4 pins), set the on-chip load capacitance, as
shown in Table 36.
AD9578 Data Sheet
Rev. B | Page 26 of 44
PLLs
OVERVIEW
The two PLLs in the AD9578 operate independently. Each PLL
consists of an input reference frequency (which can be shared),
a phase/frequency detector, loop filter, RTWO-based VCO,
complex feedback divider and phase selector, and two output
dividers. The feedback divider can operate in two distinct
modes: integer and fractional.
Using the AD9578 evaluation software is the easiest way to
configure the AD9578. See the PLL Modes of Operation section
for more information on the various register settings.
In the PLL Modes of Operation section, the possible feedback
divider settings is expressed in Q notation, QN.M, where N (the
integer part) is eight bits and M (the fractional part) is 28 bits.
The S[1:0] value represents the amount of phase interpolation
used to represent a portion of the fractional part of the divider
value. When S[1:0] = 3, there is no phase interpolation. When
S[1:0] = 0, there is phase interpolation in 1/8 increments.
PLL MODES OF OPERATION
The PLLs on the AD9578 have three modes of operation:
integer, fractional, and rational. In this section, PLLx refers to
either PLL1 (whose settings are in Register 6 and Register 7) or
PLL2 (whose settings are Register 8 and Register 9).
The feedback divider has two parts: an 8-bit integer part and a
28-bit fractional part. The fractional part is modulated by a
multistage noise shaping (MASH) modulator. The order of the
MASH modulator is set in PLLx MASH[2:0] in Register 7 and
Register 9, Bits[31:29].
Set the value of MASH[2:0] to 0 for integer mode, and 1 to 4 for
fractional mode. Setting PLLx MASH[2:0] = 2 usually provides the
lowest jitter for settings of PLLx Fractional Feedback
Divider[27:0] greater than 2% from an integer. The value of S[1:0]
is as follows: S[1:0] = 0, 1, and 2 results in eight, four, and two
phases, respectively. Typically, a value of 0 for S[1:0] is best.
Fractional Mode
The fractional mode allows the feedback divider to take on a
value of the Q notation, QN.M, where N (the integer part) is
eight bits and M (the fractional part) is 28 bits. The VCO
frequency divided by the feedback divider must always equal
the reference frequency.
+×=
28
2
FRAC
INTff
IN
VCO
where:
INT is PLLx Integer Feedback Divider[7:0] in Register 6 (for
PLL1) or Register 8 (for PLL2).
FRAC is PLLx Fractional Feedback Divider[27:0] in Register 6
(for PLL1) or Register 8 (for PLL2)
Rational Mode
Rational mode allows the user to express the feedback divider as
a ratio of rational numbers. Rational mode is enabled by setting
the rational mode bit (Bit 2 in Register 7 (for PLL1) or Register 9
(for PLL2)) to 1.
Table 26. Rational Mode Feedback Divider Calculation
S[1:0]
Feedback Divider
(FBDIV)1
PLLx Fractional
Feedback Divider[27:25]
S = 0 FBDIV = A + (1/8)(B + C/D) B = 0, 1, … , 7 (Bits[27:25])
S = 1 FBDIV = A + (1/4)(B + C/D) B = 0, 1, 2, 3 (Bits[27:26])
S = 2 FBDIV = A + (1/2)(B + C/D) B = 0, 1 (Bit 27)
S = 3 FBDIV = A + C/D
B ignored (Bits[27:25] =
000b)
1 A is PLLx Integer Feedback Divider[7:0], C is PLLx Fractional Feedback
Divider[24:9], D is PLLx Modulus Value[15:0].
Integer Mode
Integer mode provides the lowest possible phase noise and
behaves like a traditional integer PLL in which the feedback
divisor is an integer. Integer mode is a special case of rational
mode in which the rational mode bit is zero, and the C and D
terms in Table 26 are 0.
Integer mode is set when the following conditions are met:
PLLx MASH[2:0] = 000b
PLLx Fractional Feedback Divider[24:0] = 0x000
If PLLx S[1:0] = 3 (no phase interpolation),
PLLx Fractional Feedback Divider[27:25] must be zero.
If PLLx S[1:0] = 2 (phase interpolation of ½ or 0)
PLLx Fractional Feedback Divider[26:25] must be zero.
If PLLx S[1:0] = 1, (phase interpolation of 1/4, 1/2, 3/4, or 0)
PLLx Fractional Feedback Divider[25] must be zero.
When programming integer mode with S[1:0] = 0, the AD9578
is in integer mode (with better noise performance), even though
the feedback divider has a fraction (for example, 1/8, 2/8, 3/8).
When using this mode, the user must reset the feedback divider
by writing a 1 to Bit 14 of Register 7 (for PLL1) or Register 9
(for PLL2).
NCO Functionality
Fractional mode allows operation as a precision NCO, which
offers the capability of digitally pulling the output frequency
using precise numerical control. A digital alternative to analog
VCXOs that pull the crystal using varactors, NCO functionality
enables completely digitally controlled PLLs that trim the output
frequency through the fast SPI bus. Precise numerical control
enables PLL applications to be implemented digitally within
FPGAs and other digital ICs. Writing the AD9578 registers
using an SPI bus that runs at 100 MHz allows the AD9578
output frequency to be updated frequently. The continuous
trimming range of the output is greater than 1000 ppm, resulting
Data Sheet AD9578
Rev. B | Page 27 of 44
in better tracking range than is possible with analog VCXO-
based PLLs.
The output frequencies change smoothly with no sudden phase
step when the change to the feedback divider is small (for ex ample,
a change in phase or a few parts per million in frequency.) The
change in the feedback divider is instantaneous, but the PLL
response causes the PLL to change its frequency gradually.
Thus, any changes small enough not to cause lock disturbance
are smooth and continuous.
VCO
The VCO has 28 frequency bands. PLLx Frequency Select[4:0]
in Register 7 (for PLL1) or Register 9 (for PLL2) selects the
VCO band according to Table 27. Using the AD9578 evaluation
software is the easiest way to ensure that these bits are set
correctly.
Table 27. VCO Frequencies and KVCO Band Settings
PLLx Frequency
Select[4:0]
1 VCO Min
(MHz)
VCO
Nom
(MHz)
VCO
Max
(MHz)
PLLx
KVCO
Band2
Dec
Binary
0 00000 3642 3654 3677 0
1 00001 3615 3623 3642 0
2 00010 3583 3597 3615 0
3 00011 3556 3568 3583 0
4
00100
3532
3542
3556
0
5
00101
3509
3518
3532
0
6
00110
3486
3496
3509
0
7
00111
3463
3473
3486
0
8
01000
3440
3450
3463
0
9
01001
3416
3426
3440
0
10 01010 3391 3402 3416 0
11 01011 3375 3382 3391 0
12
01100
3360
3366
3375
0
13 01101 3345 3350 3360 0
14
01110
3307
3322
3345
1
15
01111
3290
3298
3307
1
16
10000
3268
3278
3290
1
17
10001
3249
3256
3268
1
18
10010
3228
3237
3249
1
19
10011
3209
3217
3228
1
20 10100 3189 3198 3209 1
21 10101 3171 3179 3189 1
22
10110
3154
3161
3171
1
23 10111 3135 3143 3154 1
24
11000
3119
3126
3135
1
25
11001
3100
3108
3119
1
26
11010
3084
3091
3100
1
27
11011
3053
3072
3084
1
1 PLLx Frequency Select[4:0] is in Register 0x07 for PLL1 and Register 0x09 for
PLL2.
2 The PLLx KVCO band bits are in Register 0x0C for PLL1 and Register 0x0E for
PLL2.
The PLLx KVCO band bit (Bit 31 in Register 0x0C for PLL1 and
Bit 31 in Register 0x0E for PLL2) must be set to 1 for PLLx
Frequency Select[4:0] values between 14 and 27, and must be 0
for Frequency Select[4:0] values between 0 and 13. The reserved
bits in Register 11, Register 12, Register 13, and Register 14 are
factory calibrated values, and must not be changed.
CHARGE PUMP
The PLL charge pump current is programmed in Register 7 and
Register 9, Bits[20:16], the CUR[4:0] value. CUR[4:0] can optimize
the PLL bandwidth for minimum integrated phase noise. For
crystals of approximately 50 MHz, CUR[4:0] values near 15
often produce the lowest noise. The AD9578 evaluation software
generates these values for the user.
See Table 29 for a variety of output frequencies and settings for
PLLx MASH[2:0], S[1:0], and CUR[4:0] when using a
49.152 MHz crystal.
OUTPUT DIVIDERS
The output divider divides the RTWO frequency down to the
required output frequency. There is one divider per output, and
the divide ratios are located in Register 5 (see Table 28).
Table 28. Output Divider Locations in Register 5
Bits Bits[7:0]
[31:24]
OUTPUT4 Divider[7:0]
[23:16]
OUTPUT3 Divider[7:0]
[15:8] OUTPUT2 Divider[7:0]
[7:0] OUTPUT1 Divider[7:0]
The output divider has a range of 4 to 259. Writing 0x04 to
Address 0xFF to the output divider results in a divide ratio that
is the same as the value stored in the register. Writing 0x00 to
Address 0x03 to the output divider results in a divide ratio of
256 to 259, respectively.
For the special case of frequencies between 750 MHz and
778 MHz, which cannot be accessed with divide by 4 or divide
by 5, a divide by 4.5 is provided. To divide by 4.5, set the enable
OUTPUTx 4.5 mode bit in Register 3, Bits[11:8]. When the
OUTPUTx 4.5 mode bit is set, the associated output divider
ignores the value in Register 5 and divides by 4.5.
LOSS OF LOCK INDICATOR
The lock status of a PLL can be monitored via the PLLx lock
detect bit in Register 0x0F, Bit 21 (for PLL1) or Bit 23 (for
PLL2). A value of 1 indicates lock and is the normal condition.
A value of 0 indicates out of lock, or the absence of an input
reference. If the user programs Bit 0 of Register 6 (PLL1) and/or
Register 8 (PLL2) to 1, the SDO/LOL pin changes function to
the logical AND of the PLL1 and PLL2 loss of lock (LOL) f un c t ion.
RESETS
If the PLLx MASH (Bits[31:29] in Register 7 for PLL1 or
Register 9 for PLL2) is changed, issue a reset by toggling the
reset feedback divider bit in Register 7 or Register 9, Bit 14.
AD9578 Data Sheet
Rev. B | Page 28 of 44
EXAMPLE VALUES FOR 49.152 MHZ CRYSTAL
Table 29 shows the output frequency settings when using a 49.152 MHz crystal, TXC Part Number 8Z49100001, 2.5 mm × 2.0 mm,
49.152 MHz, ±30 ppm, CL = 9 pF, maximum ESR = 50 Ω.
Table 29. Register Settings for Various Output Frequencies with a 49.152 MHz Crystal
Output
Frequency
(MHz)
PLLx Feedback
Divider
OUTPUTx
Divider[7:0]
Frequency
Select[4:0]
PLLx
KVCO
Band
PLLx
MASH[2:0] S[1:0] CUR[4:0]
VCO
Frequency
(MHz)
125.000000 71.207682292 28 6 0 2 0 17 3500
155.520000 69.609375 22 9 0 2 0 16 3421.44
156.250000 66.757202148 21 16 1 2 0 16 3281.25
159.375000 68.092346191 21 13 0 2 0 16 3346.875
161.132813 72.121620402 22 4 0 2 0 16 3544.92189
164.355469 70.220232117 21 8 0 2 0 19 3451.46485
166.628571 74.581473023 22 0 0 2 0 19 3665.82856
167.331646 68.087421061 20 13 0 2 0 19 3346.63292
168.040678 71.79472327 21 5 0 2 0 15 3528.85424
172.642299 73.760747864 21 1 0 2 0 19 3625.48828
173.370748
74.071974854
21 1 0 2 0 22
3640.78571
174.105369 74.385838806 21 0 0 2 0 19 3656.21275
174.153733 70.863335368 20 7 0 2 0 19 3483.07466
174.703084 71.086866862 20 6 0 2 0 16 3494.06168
176.095145 71.653297933 20 5 0 2 0 15 3521.9029
176.838163 64.760069458 18 21 1 2 0 15 3183.08693
212.500000 69.173177083 16 10 0 2 0 14 3400
425.000000 69.173177083 8 10 0 2 0 14 3400
622.080000 63.281250000 5 25 1 2 0 16 3110.4
625.000000 63.57828776 5 24 1 2 0 14 3125
637.500000 64.849853516 5 21 1 2 0 13 3187.5
644.531250 65.565109253 5 19 1 2 0 12 3222.65625
657.421875 66.876411438 5 16 1 2 0 7 3287.10938
666.514286 67.801339315 5 14 1 3 0 15 3332.57143
669.326582 68.087420858 5 13 0 2 0 19 3346.63291
672.162712 68.375926921 5 12 0 2 0 9 3360.81356
690.569196 70.248331299 5 8 0 3 0 15 3452.84598
693.482991 70.544737854 5 7 0 2 0 12 3467.41495
696.421478 63.759290588 4.5 24 1 2 0 16 3133.89665
696.614931 70.863335266 5 7 0 2 0 19 3483.07465
698.812335 71.086866760 5 6 0 2 0 18 3494.06167
704.380580 71.653297933 5 5 0 2 0 15 3521.9029
707.352650
64.760069275
4.5
21
1
2
0
15
3183.08693
Data Sheet AD9578
Rev. B | Page 29 of 44
SPI PROGRAMMING
OVERVIEW
The AD9578 SPI bus transfers data in byte multiples. All
transfers are most significant byte and most significant bit first.
At power-up, the AD9578 loads the values programmed in OTP
memory. Thereafter, the SPI can be used to overwrite any value.
Write 0 to unused or reserved bits, and do not overwrite factory
programmed calibrations in Register 11 through Register 14.
Note that throughout this data sheet, the multifunction SDO/LOL
pin is referred to either by the entire pin name or by a single
function of the pin, for example, SDO, when only that function
is relevant.
SPI DESCRIPTION
The SPI is in reset on power-up. All fuse values are loaded into
the SPI and those become the default configuration for the device.
The SPI is inaccessible for the duration of the fuse reset cycle.
Setting the CS pin high disables the SPI controller and resets it
to its idle state. SDO is high impedance when CS is high. Setting
CS to 0 enables the SPI controller (awaiting the control/address
byte). In this mode, the controller responds to events on SCK.
SCK is the clock input to the SPI. SDI is the data input to the
SPI. Data must be valid on the rising edge of SCK. SDO is the
data output from the SPI.
On the falling edge of CS, the SPI controller expects to see a
series of eight SCK clock pulses and eight bits of data on SDI,
valid through the rising edge of the clock. As shown in Figure 32,
the first four bits are the operation code (opcode), and the last
four bits are the register to be addressed. Table 30 contains the
AD9578 opcodes that are used by the interface.
The default state on startup and when CS = high is Opcode 0
(OP[3:0] = 0000), or no operation. Opcode 2, the read opcode
(OP[3:0] = 0010), is followed by one or more series of eight
SCK pulses. Data from the register addressed by ADDR[3:0]
appear on SDO most significant bit (MSB) first. The number of
eight-pulse cycles is determined by the type of register defined
at ADDR[3:0]. Opcode 1, the write opcode (OP[3:0] = 0001), is
followed by one or more series of eight SCK pulses, with data to
be written to the addressed register placed on SDI and valid at
the rising edge of SCK. The new values take effect immediately
after a write operation on the falling edge of the last SCK pulse.
CS
SCK
SDI
SDO
OP[2] OP[1] OP[0] ADDR[3] ADDR[2] ADDR[1] ADDR[0]
SDO IS LOW DURING THE COMMAND AND ADDRESS INPUT CYCLES.
OP[3]
11356-035
Figure 32. Control and Address Byte Format
CS
SCK
SDI
S
DO
CS MUST BE HELD LOW THROUGH THE ENTIRE OPERATION
t
DV
ANY DATA ON SDI ARE IGNORED
...REPEAT AS
NECESSARY
READ (OPCODE 2) CYCLE:
DATA[0]
DATA[7] DATA[6] DATA[5] DATA[4] DATA[3] DATA[2] DATA[1]
11356-036
Figure 33. Opcode 2, Read Cycle
...REPEAT AS
NECESSARY
WRITE (OPCODE 1) CYCLE:
CS
SCK
SDI
S
D
O
CS MUST BE HELD LOW THROUGH THE ENTIRE OPERATION
SDO IS LOW DURING THE COMMAND AND ADDRESS INPUT CYCLES.
DATA[0]
DATA[6]DATA[5]DATA[4]DATA[3]DATA[2]DATA[1]
DATA[7]
11356-037
Figure 34. Opcode 1, Write Cycle
AD9578 Data Sheet
Rev. B | Page 30 of 44
Table 30. Opcode x Settings
Name OP[3:0] ADDR[3:0] Operation/Command
Opcode 0 0000 Ignored No operation
Opcode 1 0001 Register to
be written
Write data
Opcode 2 0010
Register to
be read
Read data
Opcode 3 0011 Ignored Do not use
Opcode 4 0100 0000
Fuse reset (reloads OTP
programmed values)
Opcode 5 0100 0001 OTP program
Opcode 6 0100 1110 OTP program enable
Opcode 7 0100 1111 OTP program disable
Opcode 8 0101
Register to
be queried
Query register length
OTP PROGRAMMING
The AD9578 has OTP registers so that a desired configuration can
be programmed as the power-on default. All OTP programmable
registers (except for those set at the factory) are initially set to the
default values in the register map. The desired start-up configura-
tion is programmed into the OTP bits by sending the OTP
program command after the registers are set to their desired
values. Note that the AD9578 must be powered at VDD = 3.3 V
to perform OTP programming because the CS pin must never
be more than 2.5 V above VDD.
The CS pin has two functions: serial port chip select and OTP
programming enable. To access the SPI normally, use the CS
pin at normal digital LVCMOS levels (between 0 V and VDD.)
To program the OTP, follow the OTP program procedure:
1. Enable OTP programming by setting the CS pin to 5.5 V.
2. Configure the SPI registers to the desired configuration.
3. Send the OTP program enable command, Opcode 6.
4. Send the OTP program command, Opcode 5.
5. Send the OTP program disable command, Opcode 7.
6. Set the CS pin back to 0 V.
7. Send the fuse reset command, Opcode 4, to load the new
register values. This final step is a verification of the OTP
programming procedure.
The precise timing of the OTP programming sequence is
ensured by on-board circuitry, and is 800 μs minimum per
register. While either the OTP program or the fuse reset
commands are executing, the SDO/LOL pin goes high, and it
returns to zero at the end of the fuse reset or OTP program
cycle. The host controlling the AD9578 must monitor the state
of the SDO/LOL pin to determine when it may continue SPI
communication. SPI communication from the host is ignored
during OTP programming.
Registers labeled read only have no associated fuses. The
Register Map Bit Descriptions section has details about which
registers are read only.
Security[15:0] are per register security bits. Setting the security
bit for a register disables writing to that register so that values in
the register can no longer be changed with SPI write
commands. By disabling writing, OTP programing is also
disabled. All OTP programing, including the security bits, can
be performed at the same time. The new configuration settings
for read/program bits, such as the security bits, is not applied
until a fuse reset cycle or power cycle to the chip. That is,
writing a 1 to Security[15:0] does not change the security
setting, but writing a 1 to Security[15:0] followed by the OTP
program and fuse reset commands does. Note that OTP
programming the Security0 bit prevents further writing to
Security[15:0] and, therefore, prevents any other security bits
from being set in the future. Other than the security bit settings,
there is no limitation to the number of times that the OTP
program command can be executed. This allows an incremental
approach in which certain registers are factory calibrated,
preprogrammed, and optionally secured to prevent further
modification.
Changing the OTP default for a single register is difficult
because the OTP programming sequence is not random access.
To blow the fuse of a single bit, it is necessary to first send a fuse
reset command to ensure that all registers contain default
values. Then, change a single register bit and send the OTP
program command, Opcode 5 (see Table 30).
TRIP POINT AT 1.6V
TRIP POINT
AT 4.1V
CS
INTERNAL SIGNAL
VOLTAGE (V)
VOLTAGE ON PIN (V)
5.0
5.0
3.3
3.30
0
V
PROG
INTERNAL SIGNAL
VOLTAGE (V)
VOLTAGE ON PIN (V)
5.0
5.0
3.3
3.30
0
11356-039
Figure 35. CS Pin Function
Data Sheet AD9578
Rev. B | Page 31 of 44
SPI Configuration
The AD9578 can be programmed after power-up through the
SPI. This section describes how to set a specific configuration in
the SPI registers.
1. Prepare default values. The AD9578 evaluation software is
an ideal way to determine the optimal default values of the
AD9578 registers. Note that Register 0 and Register 1 are
read only and cannot be changed.
2. Enable all subsystems. This normally includes the per PLL
values found in Register 0x06 (for PLL1) and Register 0x08
(for PLL2). They are the feedback divider PU (Bit 1), VCO
PU (Bit 2), and ENPFD (Bit 3), as well as the enable activity
detect bit, which is a global bit (Register 0x03, Bit 28).
3. The enable X TA L1 (in Register 3) and enable X TAL2 (in
Register 10) bits are normally set to 0 because the crystals
are enabled as necessary. Setting these to 1 forces the
corresponding input on permanently.
4. The following bits are internal resets, and cannot be OTP
programmed. These bits are in three groups (global, PLL1,
and PLL2) and must be 0 for normal device operation.
The internal reset global bits are in Register 15.
The PLL1 bits are in Register 7, Bits[11:15].
The PLL2 bits are in Register 9, Bits[11:15].
5. For each output to be used (OUTPUT1 through
OUTPUT4 and REFOUT), select the mode according to
Table 16, as well as the corresponding enable bits in
Register 2 and Register 3.
AD9578 Data Sheet
Rev. B | Page 32 of 44
REGISTER MAP
The shaded cells in Table 31 indicate bit(s) that can be OTP programmed. See the OTP Programming section for more information.
Table 31.
Addr Name Bits D7 D6 D5 D4 D3 D2 D1 D0 Default
Register 0
0x00 Chip and
manu-
facturer ID
[31:24] Chip ID[3:0] Unused Manufacturer ID[10:8] 0x03
[23:16]
Manufacturer ID[7:0]
0x10
[15:8] Security[15:8] 0x00
[7:0] Security[7:0] 0x00
Register 1
0x01 Product
ID, chip ID
and user
pro-
gramming
space
[47:40] Product ID[7:0] 0x7A
[39:32] Chip ID[7:4] Produ ct Revision[3:0] 0x08
[31:24]
User ID[31:24]
0x00
[23:16]
User ID[23:16]
0x00
[15:8] User ID[15:8] 0x00
[7:0]
User ID[7:0]
0x00
Register 2
0x02 External
pin
readback
and
override
[23:16] Unused MR
(master
reset)
MR enable
(set to 1
to enable
MR)
REFOUT REFOUT
enable
(override
OEREF pin)
0x00
[15:8] OUTPUT4 Override
OE4 pin
OUTPUT3 Override
OE3 pin
OUTPUT2 Override
OE2 pin
OUTPUT1 Override OE1
pin
0x00
[7:0] REFSEL2 REFSEL2
enable
(set to 1)
REFSEL1 REFSEL1
enable
(set to 1)
PLL2 PLL2
enable
(set to 1)
PLL1 PLL1 enable
(override PD1
pin)
0x00
Register 3
0x03 Reference
buffer and
divider,
inter-
polated
value
increment
[31:24] REFOUT Mode[1:0] Unused Enable
activity
detect
Reference
mux
select
Enable
XTAL1
Unused 0x10
[23:16] Unused Enable
OUTPUT4
divider
Enable
OUTPUT3
divider
Enable
OUTPUT2
divider
Enable
OUTPUT1
divider
0x0F
[15:8] Unused Enable
OUTPUT4
4.5 mode
Enable
OUTPUT3
4.5 mode
Enable
OUTPUT2
4.5 mode
Enable
OUTPUT1 4.5
mode
0x00
[7:0] Exponent[3:0] Mantissa[3:0] 0x00
Register 4
0x04 XTAL1 and
output
buffer
config-
uration
[15:8] XTAL1
f r e q u ency
trim
XTAL1 Capacitance Value[2:0] Unused XTAL1 Gain[2:0] 0x00
[7:0] OUTPUT4 Mode[1:0] OUTPUT3 Mode[1:0] OUTPUT2 Mode[1:0] OUTPUT1 Mode[1:0] 0x00
Register 5
0x05 Output
driver
config-
uration
[31:24] OUTPUT4 Divider[7:0] 0x00
[23:16] OUTPUT3 Divider[7:0] 0x00
[15:8] OUTPUT2 Divider[7:0] 0x00
[7:0] OUTPUT1 Divider[7:0] 0x00
Register 6
0x06 PLL1
config-
uration
[39:32] PLL1 Integer Feedback Divider[7:0] 0x00
[31:24] PLL1 Fractional Feedback Divider[27:20] 0x00
[23:16] PLL1 Fractional Feedback Divider[19:12] 0x00
[15:8] PLL1 Fractional Feedback Divider[11:6] PLL1 Fractional Feedback
Divider[5:4]; PLL1 Modulus
Value[5:4]
0x00
[7:0] PLL1 Fractional Feedback Divider[3:0];
PLL1 Modulus Value[3:0]
ENPFD VCO PU Feedback
divider PU
PLL1 lock IRQ 0x0E
Data Sheet AD9578
Rev. B | Page 33 of 44
Addr Name Bits D7 D6 D5 D4 D3 D2 D1 D0 Default
Register 7
0x07 PLL1
config-
uration
[39:32] PLL1 Dither[2:0] Dither Scale[4:0] 0x00
[31:24] PLL1 MASH[2:0] PLL1 Frequency Select[4:0] 0x00
[23:16] Power-on
override
S[1:0] CUR[4:0] 0x00
[15:8] PLL1
phase
advance
Reset
feedback
divider
OUTPUT1_2
reset
Force
reset
PLL1
phase
retard
Rational
mode
PLL1 Modulus Value[15:14] 0x00
[7:0]
PLL1 Modulus Value[13:6]
0x00
Register 8
0x08 PLL2
config-
uration
[39:32] PLL2 Integer Feedback Divider[7:0] 0x00
[31:24] PLL2 Fractional Feedback Divider[27:20] 0x00
[23:16] PLL2 Fractional Feedback Divider[19:12] 0x00
[15:8] PLL2 Fractional Feedback Divider[11:6] PLL2 Fractional Feedback
Divider[5:4], PLL2 Modulus
Value[5:4]
0x00
[7:0] PLL2 Fractional Feedback Divider[3:0],
PLL2 Modulus Value[3:0]
ENPFD VCO PU Feedback
divider PU
PLL2 lock IRQ
(SDO changes
to IRQ)
0x0E
Register 9
0x09 PLL2
config-
uration
[39:32] PLL2 Dither[2:0] Dither Scale[4:0] 0x00
[31:24] PLL2 MASH[2:0] PLL2 Frequency Select[4:0] 0x00
[23:16] Power-on
override
S[1:0] CUR[4:0] 0x00
[15:8]
PLL2
phase
advance
Reset
feedback
divider
OUTPUT3_4
reset
Force
reset
PLL2
phase
retard
Rational
mode
PLL2 Modulus Value[15:14]
0x00
[7:0] PLL2 Modulus Value[13:6] 0x00
Register 10
0x0A XTAL2
config-
uration
[15:8] XTAL2
f r e q u ency
trim
XTAL2 Capacitance Value[2:0] XTAL2 Gain[2:0] Enable XTAL2 0x00
[7:0] Reserved 0x00
Register 11
0x0B Reserved [31:24] Reserved (factory configured; do not change) Varies
[23:16] Reserved (factory configured; do not change) Varies
[15:8] Reserved (factory configured; do not change) Varies
[7:0] Reserved (factory configured; do not change) Varies
Register 12
0x0C PLL1 KVCO
band
[31:24] PLL1 KVCO
band
Reserved Reserved (factory
configured; do not change)
Varies
[23:16] Reserved (factory configured; do not change) Varies
[15:8]
Reserved (factory configured; do not change)
Varies
[7:0] Reserved (factory configured; do not change) Varies
Register 13
0x0D Reserved [31:24] Reserved (factory configured; do not change) Varies
[23:16] Reserved (factory configured; do not change) Varies
[15:8] Reserved (factory configured; do not change) Varies
[7:0] Reserved (factory configured; do not change) Varies
Register 14
0x0E
PLL2 K
VCO
band
[31:24]
PLL2 K
VCO
band
Reserved
Reserved (factory
configured; do not change)
Varies
[23:16] Reserved (factory configured; do not change) Varies
[15:8] Reserved (factory configured; do not change)
[7:0]
Reserved (factory configured; do not change)
Register 15
0x0F PLL lock
detect
(read only)
[23:16] PLL2 lock
detect
Reserved PLL1 lock
detect
Reserved Revision Subcode[1:0] Reserved Varies
[15:8] Unused 0x00
[7:0] Unused 0x00
AD9578 Data Sheet
Rev. B | Page 34 of 44
REGISTER MAP BIT DESCRIPTIONS
CHIP AND MANUFACTURER ID (REGISTER 0, ADDRESS 0x00)
Table 32. Chip and Manufacturer ID
Bits Bit Name Description
31:28 Chip ID[3:0]
This register has no effect on device operation. The customer can use it for tracking different versions of device
programming or identifying a chip on a printed circuit board. Including the four bits in Register 0x01, there are a
total of eight bits for this function, and these values can be OTP programmed.
27 Unused Default = 0b.
26:16
Manufacturer
ID[10:0]
Manufacturer ID. These bits identify this chip as an Analog Devices IC and have no effect on device operation.
15:0 Security[15:0]
During the process of OTP programming, these bits control whether a given register becomes read only during
future operation. There is one bit for each register. If the security bit for a given register is 1 during an OTP
programming sequence, the corresponding register becomes read only, and the user can make no additional
modifications to that register through the serial port.
PRODUCT ID, CHIP ID, AND USER PROGRAMING SPACE (REGISTER 1, ADDRESS 0x01)
Table 33. Product ID, Chip ID, and User Programing Space
Bits Bit Name Description
47:40 Product ID[7:0] Product ID.
39:36 Chip ID[7:4]
This register has no effect on device operation. The customer can use it for tracking different versions of device
programming or identifying a chip on a printed circuit board. Including the four bits in Register 0x00, there are a
total of eight bits for this function, and these values can be OTP programmed.
35:32 Product
Revision[3:0]
This read only register contains the AD9578 silicon revision information.
31:0 User ID[31:0] Additional OTP programmable bits to program up to 32 bits of user assigned information.
EXTERNAL PIN READBACK AND OVERRIDE (REGISTER 2, ADDRESS 0x02)
Table 34. External Pin Readback and Override
Bits Bit Name Description
23:20 Unused Default = 0x0.
19 MR (master reset) This bit resets the chip. This bit is not self clearing.
1: the
AD9578
is held in reset. MR enable (Bit 18 in this register) must be 1 for this bit to take effect.
0 (default): normal operation.
18 MR enable This bit enables the MR (master reset) bit (Bit 19 in this register).
1: master reset is enabled.
0 (default): master reset (Bit 19 of this register) is disabled.
17 REFOUT This bit enables/disables the REFOUT driver.
If REFOUT enable (Bit 16 in this register) = 1, this bit enables the REFOUT driver, as follows:
1: the REFOUT driver is enabled.
0 (default): the REFOUT driver is disabled.
If REFOUT enable (Bit 16 in this register) = 0, this is a read only register, as follows:
1: the OEREF pin is high and the REFOUT driver is enabled.
0 (default): the OEREF pin is low and the REFOUT driver is disabled.
16
REFOUT enable
(override OEREF pin)
This bit enables REFOUT (Bit 17 in this register).
1: the REFOUT bit controls the on/off state of the REFOUT driver.
0 (default): the OEREF pin controls the on/off state of the REFOUT driver.
Data Sheet AD9578
Rev. B | Page 35 of 44
Bits Bit Name Description
15 OUTPUT4 This bit enables/disables the OUTPUT4 driver. Note that the user must enable PLL2 for the OUTPUT4 driver
to be enabled.
If override OE4 pin (Bit 14 in this register) = 1, this bit enables the OUTPUT4 driver, as follows:
1: the OUTPUT4 driver is enabled.
0 (default): the OUTPUT4 driver is disabled.
If override OE4 pin (Bit 14 in this register) = 0, this is a read only register, as follows:
1: the OE4 pin is high and the OUTPUT4 driver is enabled.
0 (default): the OE4 pin is low and the OUTPUT4 driver is disabled.
14 Override OE4 pin This bit enables the OUTPUT4 bit (Bit 15 in this register).
1: the OUTPUT4 bit controls the on/off state of the OUTPUT4 driver.
0 (default): the OE4 pin controls the on/off state of the OUTPUT4 driver.
13 OUTPUT3
This bit enables/disables the OUTPUT3 driver. Note that the user must enable PLL2 for the OUTPUT3 driver
to be enabled.
If override OE3 pin (Bit 12 in this register) = 1, this bit enables the OUTPUT3 driver, as follows:
1: the OUTPUT3 driver is enabled.
0 (default): the OUTPUT3 driver is disabled.
If override OE3 pin (Bit 12 in this register) = 0, this is a read only register, as follows:
1: the OE3 pin is high and the OUTPUT3 driver is enabled.
0 (default): the OE3 pin is low and the OUTPUT3 driver is disabled.
12 Override OE3 pin This bit enables the OUTPUT3 bit (Bit 13 in this register).
1: the OUTPUT3 bit controls the on/off state of the OUTPUT3 driver.
0 (default): the OE3 pin controls the on/off state of the OUTPUT3 driver.
11 OUTPUT2
This bit enables/disables the OUTPUT2 driver. Note that the user must enable PLL2 for the OUTPUT2 driver
to be enabled.
If override OE2 pin (Bit 10 in this register) = 1, this bit enables the OUTPUT2 driver, as follows:
1: the OUTPUT2 driver is enabled.
0 (default): the OUTPUT2 driver is disabled.
If override OE2 pin (Bit 10 in this register) = 0, this is a read only register, as follows:
1: the OE2 pin is high and the OUTPUT2 driver is enabled.
0 (default): the OE2 pin is low and the OUTPUT2 driver is disabled.
10 Override OE2 pin This bit enables the OUTPUT2 bit (Bit 11 in this register).
1: the OUTPUT2 bit controls the on/off state of the OUTPUT2 driver.
0 (default): the OE2 pin controls the on/off state of the OUTPUT2 driver.
9 OUTPUT1
This bit enables/disables the OUTPUT1 driver. Note that the user must enable PLL2 for the OUTPUT1 driver
to be enabled.
If override OE1 pin (Bit 8 in this register) = 1, this bit enables the OUTPUT1 driver, as follows:
1: the OUTPUT1 driver is enabled.
0 (default): the OUTPUT1 driver is disabled.
If override OE1 pin (Bit 8 in this register) = 0, this is a read only register, as follows:
1: the OE1 pin is high and OUTPUT1 is enabled.
0 (default): the OE1 pin is low and the OUTPUT1 driver is disabled.
8 Override OE1 pin This bit enables the OUTPUT1 bit (Bit 9 in this register).
1: the OUTPUT1 bit controls the on/off state of the OUTPUT1 driver.
0 (default): the OE1 pin controls the on/off state of the OUTPUT1 driver.
7 REFSEL2 This bit controls which input is used by PLL2, provided that REFSEL2 enable (Bit 6 of this register) is 1.
1: PLL2 uses Reference 2 (which corresponds to the XO3/XO4 pins).
0: (default) PLL2 uses Reference 1 (which corresponds to the XO1/XO2 pins).
6 REFSEL2 enable This bit enables the REFSEL2 bit, and must be set to 1 for Bit 7 to function.
1: the REFSEL1 bit is enabled.
0 (default): the REFSEL1 bit is disabled. PLL2 uses Reference 1.
5 REFSEL1 This bit controls which input is used by PLL1, provided that REFSEL1 enable (Bit 4 of this register) is 1.
1: PLL1 uses Reference 2 (which corresponds to the XO3/XO4 pins).
0 (default): PLL1 uses Reference 1 (which corresponds to the XO1/XO2 pins).
AD9578 Data Sheet
Rev. B | Page 36 of 44
Bits Bit Name Description
4 REFSEL1 enable This bit enables the REFSEL1 bit, and must be set to 1 for Bit 5 to function.
1: the REFSEL1 bit is enabled.
0 (default): the REFSEL1 bit is disabled. PLL1 uses Reference 1.
3 PLL2 This bit enables/disables PLL2 when PLL2 enable (Bit 2 of this register) is 1.
1: PLL2 is enabled.
0 (default): PLL2 is disabled.
2 PLL2 enable This bit enables the PLL2 bit, and must be set to 1 for Bit 3 to function.
1: the PLL2 bit is enabled.
0 (default): the PLL2 bit is disabled. PLL2 is powered down.
1 PLL1 This bit enables/disables PLL1.
If PLL1 enable (Bit 0 in this register) = 1, this bit enables PLL1, as follows:
1: PLL1 is enabled.
0 (default): PLL1 is disabled.
If PLL1 enable (Bit 0 in this register) = 0, this is a read only register, as follows:
1: the PD1 pin is high and PLL1 is enabled.
0 (default): the PD1 pin is low and PLL1 is disabled.
0 PLL1 enable This bit enables the PLL1 bit (Bit 1 in this register).
(override PD1 pin) 1: the PLL1 bit controls the on/off state of PLL1.
0 (default): the PD1
pin controls the on/off state of PLL1. In this case, the PLL1 bit is read only and its value
is the same as the state of the PD1 pin.
REFOUT/OUTPUT DIVIDER ENABLE (REGISTER 3, ADDRESS 0x03)
Table 35. Reference Buffer and Divider, Interpolated Value Increment
Bits
Bit Name
Description
31:30 REFOUT These bits set the mode of the REFOUT driver.
Mode[1:0] 00 (default): 3.3 V LVCMO S (normal output only; complementary output is high-Z).
01: LVDS.
10: 3.3 V LVPECL.
11: HCSL.
29 Unused Set to 0.
28
Enable activity
detect
This bit enables the activity detectors. Always set this bit to 1 for normal operation. The activity detectors
determine when an active clock signal is passing through a circuit inside of the chip.
1 (default): spot activity detector enabled.
0: spot activity detector disabled. (Do not use.)
27 Reference mux This bit controls which input is buffered to the REFOUT driver.
select 1: REFOUT uses Reference 2 (which corresponds to the XO3/XO4 pins).
0: (default) REFOUT uses Reference 1 (which corresponds to the XO1/XO2 pins).
26 Enabl e XTA L1
Set to 0 for normal operation. This bit enables the crystal oscillator connected to the XO1 and XO2 pins when
this bit is set to 1. Note that the crystal oscillator is automatically enabled when Reference Input 1 is selected.
Setting this bit to 1 keeps the oscillator enabled at all times, avoiding the crystal start-up delay when switching
between crystal and reference inputs.
25:20 Unused Set to 0.
19
Enable
OUTPUT4
divider
This bit enables the OUTPUT4 divider. Set this bit whenever the corresponding output buffer is enabled.
18
Enable
OUTPUT3
divider
This bit enables the OUTPUT3 divider. Set this bit whenever the corresponding output buffer is enabled.
17
Enable
OUTPUT2
divider
This bit enables the OUTPUT2 divider. Set this bit whenever the corresponding output buffer is enabled.
Data Sheet AD9578
Rev. B | Page 37 of 44
Bits Bit Name Description
16 Enable
OUTPUT1
divider
This bit enables the OUTPUT1 divider. Set this bit whenever the corresponding output buffer is enabled.
15:12 Unused Set to 0.
11:8
Enable OUTPUTx
4.5 mode
For the special case of frequencies between 750 MHz and 778 MHz, which cannot be accessed with divide by 4
or divide by 5, a divide by 4.5 is provided. To divide by 4.5, set the enable OUTPUTx 4.5 mode bit (where x is an
integer from 1 to 4). When the OUTPUTx 4.5 mode bit is set, the associated output divider ignores the OUTPUTx
Divider[7:0] value in Register 5 and divides by 4.5.
7:4 Exponent[3:0]
If a new value is presented to the fractional-N divider, the change is interpolated in steps equal in size to the
value of mantissa << exponent, that is, the value of the Mantissa[3:0] bits shifted up by the exponent bits. If
Mantissa[3:0] is 0, the new value takes effect immediately. Allowable values are 0d to 15d for Exponent[3:0],
with 1d having the smallest step size and the most gradual change in the fractional feedback divider.
3:0 Mantissa[3:0] If a new value is presented to the fractional-N divider, the change is interpolated in steps equal in size to the
value of mantissa << exponent, that is, the value of the mantissa bits shifted up by the exponent bits. If
Mantissa[3:0] is 0, the new value takes effect immediately. Allowable values are 0d to 15d for Mantissa[3:0] with
1d having the smallest step size and the most gradual change in the fractional feedback divider.
XTAL1 AND OUTPUT BUFFER CONFIGURATION (REGISTER 4, ADDRESS 0x04)
Table 36. XTAL1 and Output Buffer Configuration
Bits Bit Name Description
15
XTA L1
frequency trim
This is an additional gain trim bit for the crystal oscillator. Setting XTAL frequency trim = 1 is recommended for
optimal performance with crystal frequencies33 MHz. See Tabl e 25.
14:12 XTA L 1
Capacitance
Value[2:0]
These register bits control the amount of internal load capacitance on the XO1 and XO2 pins. The correct setting
can be determined using the following equation: 2 × (CLOAD CS T R AY ) where CLOAD is the specified load
capacitance of the crystal used, and CSTR AY is the stray capacitance (usually 2 pF to 5 pF) on the circuit board.
XTAL1 Capacitance
Value[2:0]
CLOAD of Crystal
(pF)
Recommended Internal Capacitance on XO1/XO2 Pins
(Assuming 3 pF Stray Capacitance) (pF)
000 8 10
001 9 12
010 10 14
011 11 16
100 12 18
101 13 20
110 14 22
111 15 24
11 Unused
10:8 XTA L 1 Gain[2:0]
These are gain trim bits for the crystal oscillator. Optimal performance is achieved when the gain is
programmed according to the ESR of the crystal. See Tabl e 25.
7:6
OUTPUT4
Mode[1:0]
These bits set the mode of OUTPUT4.
00 (default): 3.3 V LVCMOS (normal output only; complementary output is high-Z).
01: LVDS.
10: 3.3 V LVPECL.
11: HCSL.
5:4
OUTPUT3
Mode[1:0]
These bits set the mode of OUTPUT3.
00 (default): 3.3 V LVCMOS (normal output only; complementary output is high-Z).
01: LVDS.
10: 3.3 V LVPECL.
11: HCSL.
3:2
OUTPUT2
Mode[1:0]
These bits set the mode of OUTPUT2.
00 (default): 3.3 V LVCMOS (normal output only; complementary output is high-Z).
01: LVDS.
10: 3.3 V LVPECL.
11: HCSL.
AD9578 Data Sheet
Rev. B | Page 38 of 44
Bits Bit Name Description
1:0 OUTPUT1
Mode[1:0]
These bits set the mode of OUTPUT1.
00 (default): 3.3 V LVCMOS (normal output only; complementary output is high-Z).
01: LVDS.
10: 3.3 V LVPECL.
11: HCSL.
OUTPUT DRIVER CONFIGURATION (REGISTER 5, ADDRESS 0x05)
Table 37. Output Driver Configuration
Bits Bit Name Description
31:24 OUTPUT4 Divider[7:0] The value of the OUTPUT4 divider. As an 8-
bit decimal value, n, the VCO frequency is divided by n, where
n = 4 to 255, and divided by 256 + n, where n = 0 to 3.
23:16 OUTPUT3 Divider[7:0]
The value of the OUTPUT3 divider. As an 8-bit decimal value, n, the VCO frequency is divided by n, where
n = 4 to 255, and divided by 256 + n, where n = 0 to 3.
15:8 OUTPUT2 Divider[7:0]
The value of the OUTPUT2 divider. As an 8-bit decimal value, n, the VCO frequency is divided by n, where
n = 4 to 255, and divided by 256 + n, where n = 0 to 3.
7:0 OUTPUT1 Divider[7:0] The value of the OUTPUT1 divider. As an 8-
bit decimal value, n, the VCO frequency is divided by n, where
n = 4 to 255, and divided by 256 + n, where n = 0 to 3.
PLL1 CONFIGURATION (REGISTER 6, ADDRESS 0x06)
Table 38. PLL1 Configuration
Bits Bit Name Description
39:32
PLL1 Integer Feedback
Divider[7:0]
PLL1 integer feedback divider. This is a fixed point value that contains the integer portion of the
feedback divider. The smallest allowable value of the PLL1 feedback divider is 23.
31:10 PLL1 Fractional
Feedback Divider[27:6]
PLL1 fractional feedback divider, Bits[27:6]. If PLL1 is in fractional mode, all 28 bits in the PLL1 fractional
feedback divider are used. If PLL1 is in integer mode, the first three bits in this register
can be used either
for phase interpolation or for MASH modulation, according to the value of S[1:0]. In fractional mode, at
full phase interpolation, the fractional portion of the PLL1 feedback divider is 28 bits, for a resolution of
1/(228), or 3.7 × 10−9, or approximately 4 ppb.
9:4
PLL1 Fractional
Feedback Divider[5:0],
PLL1 Modulus
Value[5:0]
In fractional mode, this register contains Bits[5:0] of the PLL1 fractional feedback divider. In rational
mode, this register contains Bits[5:0] of the PLL1 modulus value. This register is not used in integer mode;
do not set the bits in this register to 0 in integer mode.
3 ENPFD
This bit controls the power supplies to the charge pump and phase frequency detector. Keep this bit set
to 1, the default setting. These subsystems are automatically disabled whenever the corresponding PLL
is powered down via the PD1 pin.
2 VCO PU
This bit controls the power supplies to the VCO. Keep this bit set to 1, the default setting. This subsystem
is automatically disabled whenever the corresponding PLL is powered down via the PD1 pin.
1 Feedback divider PU
This bit controls the power supplies to the feedback divider. Keep this bit set to 1, the default setting.
This subsystem is automatically disabled whenever the corresponding PLL is powered down via the PD1
pin.
0 PLL1 lock IRQ This bit sets the function of the SDO/LOL pin.
0 (default): the SDO/LOL pin function is serial data output (SDO).
1: the SDO/LOL pin function is IRQ, which is used as a loss of lock (LOL) indicator.
Data Sheet AD9578
Rev. B | Page 39 of 44
PLL1 CONFIGURATION (REGISTER 7, ADDRESS 0x07)
Table 39. PLL1 Configuration
Bits Bit Name Description
39:37 PLL1 Dither[2:0] Order of dither generation. When PLL1 Dither[2:0] is 0, there is no dithering. All nonzero values create dither of
the value stored in PLL1 Dither[2:0]. Dither is a noise shaped random value that is added to the divider fractional
value at each calculation of the modulation, which helps to disperse harmonic spurs resulting from short
modulation sequences. The time average value of dither is always zero, so that the use of dither does not change
the divider value. The use of dither is highly dependent upon the choice of value for Dither Scale[4:0]. For normal
operation, always set PLL1 Dither[2:0] to zero when PLL1 MASH[2:0] is zero. The largest usable value of PLL1
Dither[2:0] is 5. Typically, the value of PLL1 Dither[2:0] is set equal to the value of PLL1 MASH[2:0].
36:32
Dither
Scale[4:0]
Dither scale. The dither scale, in bits. The dither value is a signed value of one to five bits in length, depending on
the value chosen for PLL1 Dither[2:0]. To be effective, this value must be scaled up until the amount of dither is
equal to 1/2 LSB of the divider value. The proper dither scale value for the dither is therefore equal to the
number of zeros following the last bit set to 1 in the feedback divider value. Because the dither is a signed value,
Dither Scale[4:0] must always be larger than the PLL1 Dither[2:0] setting.
31:29 PLL1 MASH[2:0]
The order of MASH modulation. When PLL1 MASH[2:0] = 0, there is no modulation. Any fractional value given to
the feedback divider that is at a finer resolution than the phase interpolation, S[1:0], results in an inaccurate
output frequency. For all nonzero values of PLL1 MASH[2:0], modulation is
used unless the feedback divider does
not require modulation to be represented exactly (for example, if the feedback divider is an integer number).
Modulation means that the feedback divider alternates between floor(PLL1 Fractional Feedback Divider[27:0])
and ceiling(PLL1 Fractional Feedback Divider[27:0]) according to a pattern whose time averaged value is PLL1
Fractional Feedback Divider[27:0]. When PLL1 MASH[2:0] = 1, first-order modulation is used. First-order
modulation typically has large noise spurs
due to the short length of the modulation patterns. Noise decreases
as a function of PLL1 MASH[2:0], although for values of PLL1 MASH[2:0] greater than 2, this effect may not be
measurable. The largest usable value of PLL1 MASH[2:0] is 4.
28:24 PLL1 Frequency
Select[4:0]
This 5-bit value sets the frequency range of the VCO. Smaller values correspond to higher frequency. The
evaluation software sets the optimal value; therefore, the user does not normally need to change this register.
Tabl e 27 contains the frequency ranges for each register setting. Note that the PLL1 KVCO band bit in
Register 0x0C must be set to 1 for Frequency Select[4:0] = 14 through 27 (decimal).
23 Power-on
override
When set to 1, this bit, one for each PLL, disables the simultaneous synchronization pulses sent to PLL1 and PLL2
during the power-up cycle. Otherwise, both PLL outputs are synchronized at startup.
22:21 S[1:0]
The order of phase interpolation. When S[1:0] = 0, a fractional divider is interpolated among eight phases;
therefore, values down to 1/8 can be represented exactly, without modulation. When S[1:0] = 1, the value is
interpolated among four phases. When S[1:0] = 2, the value is interpolated between two phases, and when S[1:0]
= 3, there is no phase interpolation. For example, the feedback divider of 64.5 can be represented either by PLL1
MASH[2:0] = 0, S[1:0] = 2; or by PLL1 MASH[2:0] = 1, S[1:0] = 3. In both cases, the output frequency is the same.
However, the phase noise characteristics of the two representations differ. The use of phase interpolation allows
up to three bits greater precision in the feedback divider. A consequence of reducing the phase interpolation is
the loss of bits at the end of PLL1 Fractional Feedback Divider[27:0]. For example, when S[1:0] = 2, the last bit of
PLL1 Fractional Feedback Divider[27:0] is ignored.
20:16 CUR[4:0] Each PLL has a current trim for the charge pump, with the current given by the equation (3.125 × (1 + CUR)) μA,
for a minimum current of 3.125 μA at CUR[4:0] = 0, and a maximum current of 100 μA at CUR[4:0] = 31.
15
PLL1 phase
advance
This bit, one for each PLL, is an active control that shifts the output of the VCO forward one of eight phases (1/8
cycle). This phase shift happens regardless of the S[1:0] setting for the PLL. The phase advance is edge triggered;
therefore, no further phase advancement occurs until this bit is set back to 0 and raised again. This feature can
be used to precisely align the phases of the two PLLs.
14
Reset feedback
divider
This bit resets the feedback divider. Set and clear this bit if the order of the MASH is changed or if the feedback
divider in Register 6 is changed.
13
OUTPUT1_2
reset
This bit resets the OUTPUT1 and OUTPUT2 output driver. This bit is normally set to 0, although it can be set and
cleared to reset the OUTPUT1 and OUTPUT2 output drivers.
12 Force reset This active signal forces a reset cycle that generates synchronization pulses for the outputs of each PLL.
11 PLL1 phase
retard
This bit is similar to the advance bit but shifts the output of the VCO backward one of eight phases.
10 Rational mode
This bit sets the rational mode, the use of which is described in detail in the PLLs section. In rational mode, the
feedback divider fractional part is a ratio of integers, with the numerator encoded in PLL1 Fractional Feedback
Divider[24:9] in Register 6and the denominator encoded in PLL1 Modulus Value[15:6] of this register.
AD9578 Data Sheet
Rev. B | Page 40 of 44
Bits Bit Name Description
9:0 PLL1 Modulus
Value[15:6]
The first 10 bits of the 16-bit modulus value. When the 16-bit binary value is 0, the PLL1 Fractional Feedback
Divider[27:0] value is interpreted as a 28-bit fixed point value. When PLL1 Modulus Value[15:0] is nonzero, and
the rational mode bit is set, the feedback divider ratio is calculated by a complicated expression (see Tab l e 26). In
the simplest case, S[1:0] is set to 3 (no phase interpolation), and the feedback divider expression is PLL1
Fractional Feedback Divider[24:9] + (PLL1 Feedback Divider[24:9]/modulus), generating a feedback divider that
is an exact ratio of integers. Note that having a numerator that is larger than the denominator is an invalid
configuration. Also, note that the lower six bits of the modulus value are shared with the lowest six bits of PLL1
Feedback Divider[27:0], which are not otherwise used in rational mode.
PLL2 CONFIGURATION (REGISTER 8, ADDRESS 0x08)
Table 40. PLL2 Configuration
Bits Bit Name Description
39:32
PLL2 Integer
Feedback
Divider[7:0]
PLL2 integer feedback divider. This is a fixed point value that contains the integer portion of the feedback
divider. The smallest allowable value of the PLL1 feedback divider is 23.
31:10
PLL2 Fractional
Feedback
Divider[27:6]
PLL2 fractional feedback divider, Bits[27:6]. If PLL2 is in fractional mode, all 28 bits in the PLL2 fractional
feedback divider are used. If PLL1 is in integer mode, the first three bits in this register can be used either for
phase interpolation or for MASH modulation, according to the value of S[1:0]. In fractional mode at full phase
interpolation, the fractional part of the PLL1 feedback divider is 28 bits, for a resolution of 1/(228), or 3.7 × 10−9,
or approximately 4 ppb.
9:4 PLL2 Fractional
Feedback
Divider[5:0],
PLL2 Modulus
Value[5:0]
In fractional mode, this register contains Bits[5:0] of the PLL2 fractional feedback divider. In rational mode, this
register contains Bits[5:0] of the PLL2 modulus value. This register is not used in integer mode; do not set the
bits in this register to 0 in integer mode.
3 ENPFD
This bit controls the power supplies to the charge pump and phase frequency detector. Keep this bit set to 1,
the default setting. These subsystems are automatically disabled whenever the corresponding PLL is powered
down via the PD1 pin.
2 VCO PU This bit controls the power supplies to the VCO. Keep this bit set to 1, the default setting. This subsystem is
automatically disabled whenever the corresponding PLL is powered down via the PD1 pin.
1
Feedback divider
PU
This bit controls the power supplies to the feedback divider. Keep this bit set to 1, the default setting. This
subsystem is automatically disabled whenever the corresponding PLL is powered down via the PD1 pin.
0 PLL2 lock IRQ This bit sets the function of the SDO/LOL pin.
(SDO changes to
0 (default): the SDO/LOL pin function is serial data output (SDO).
IRQ) 1: the SDO/LOL pin function is IRQ, which is used as a loss of lock (LOL) indicator.
PLL2 CONFIGURATION (REGISTER 9, ADDRESS 0x09)
Table 41. PLL2 Configuration
Bits Bit Name Description
39:37 PLL2 Dither[2:0]
Order of dither generation. When PLL2 Dither[2:0] is 0, there is no dithering. All nonzero values create dither of
the value stored in PLL2
Dither[2:0]. Dither is a noise shaped random value that is added to the divider fractional
value at each calculation of the modulation, which helps to disperse harmonic spurs resulting from short
modulation sequences. The time average value of dither is always zero, so that the use of dither does not change
the divider value. The use of dither is highly dependent upon the choice of value for Dither Scale[4:0]. For normal
operation, always set PLL2 Dither[2:0] to zero when PLL2 MASH[2:0] is zero. The largest usable value of PLL2
Dither[2:0] is 5. Typically, the value of PLL2 Dither[2:0] is set equal to the value of PLL2 MASH[2:0].
36:32 Dither
Scale[4:0]
Dither scale. The dither scale, in bits. The dither value is a signed value of one to five bits in length, depending on
the value chosen for PLL2
Dither[2:0]. To be effective, this value must be scaled up until the amount of dither is
equal to 1/2 LSB of the divider value. The proper dither scale value for the dither is therefore equal to the
number of zeros following the last bit set to 1 in the feedback divider value. Because the dither is a signed value,
Dither Scale[4:0] must always be larger than the PLL2 Dither[2:0] setting.
Data Sheet AD9578
Rev. B | Page 41 of 44
Bits Bit Name Description
31:29 PLL2 MASH[2:0] The order of MASH modulation. When PLL2 MASH[2:0] = 0, there is no modulation. Any fractional value given to
the feedback divider that is at a finer resolution than the phase interpolation, S[1:0], results in an inaccurate
output frequency. For all nonzero values of PLL2 MASH[2:0], modulation i
s used unless the feedback divider does
not require modulation to be represented exactly (for example, if the feedback divider is an integer number).
Modulation means that the feedback divider alternates between floor(PLL2 Fractional Feedback Divider[27:0])
and ceiling(PLL2 Fractional Feedback Divider[27:0]) according to a pattern whose time averaged value is PLL2
Fractional Feedback Divider[27:0]. When PLL2 MASH[2:0] = 1, first-order modulation is used. First-order
modulation typically has large noise spur
s due to the short length of the modulation patterns. Noise decreases
as a function of PLL2 MASH[2:0], although for values of PLL2 MASH[2:0] greater than 2, this effect may not be
measurable. The largest usable value of PLL2 MASH[2:0] is 4.
28:24 PLL2 Frequency
Select[4:0]
This 5-bit value sets the frequency range of the VCO. Smaller values correspond to higher frequency. The
evaluation software sets the optimal value; therefore, the user does not normally need to change this register.
Tabl e 27 contains the frequency ranges for each register setting. Note that the PLL2 KVCO band bit in
Register 0x0E must be set to 1 for PPL2 Frequency Select[4:0] = 14 through 27 (decimal).
23
Power-on
override
When set to 1, this bit, one for each PLL, disables the simultaneous synchronization pulses sent to PLL1 and PLL2
during the power-up cycle. Otherwise, both PLL outputs are synchronized at startup.
22:21 S[1:0]
The order of phase interpolation. When S[1:0] = 0, a fractional divider is interpolated among eight phases;
therefore, values down to 1/8 can be represented exactly, without modulation. When S[1:0] = 1, the value is
interpolated among four phases. When S[1:0] = 2, the value is interpolated between two phases, and when S[1:0]
= 3, there is no phase interpolation. For example, the feedback divider of 64.5 can be represented either by PLL
2
MASH[2:0] = 0, S[1:0] = 2; or by PLL2 MASH[2:0] = 1, S[1:0] = 3.
In both cases, the output frequency is the same.
However, the phase noise characteristics of the two representations differ. The use of phase interpolation allows
up to three bits greater precision in the feedback divider. A consequence of reducing the phase interpolation is
the loss of bits at the end of PLL2 Fractional Feedback Divider[27:0]. For example, when S[1:0] = 2, the last bit of
PLL2 Fractional Feedback Divider[27:0] is ignored.
20:16 CUR[4:0] Each PLL has a current trim for the charge pump, with the current given by the equation (3.125 × (1 + CUR)) μA,
for a minimum current of 3.125 μA at CUR[4:0] = 0, and a maximum current of 100 μA at CUR[4:0] = 31.
15 PLL2 phase
advance
This bit, one for each PLL, is an active control that shifts the output of the VCO forward one of eight phases (1/8
cycle). This phase shift happens regardless of the S[1:0] setting for the PLL. The phase advance is edge triggered;
therefore, no further phase advancement occurs until this bit is set back to 0 and raised again. This feature can
be used to precisely align the phases of the two PLLs.
14
Reset feedback
divider
This bit resets the feedback divider. Set and clear this bit if the order of the MASH is changed or if the feedback
divider in Register 8 is changed.
13
OUTPUT3_4
reset
This bit resets the OUTPUT3 and OUTPUT4 output driver. This bit is normally set to 0, although it can be set and
cleared to reset the OUTPUT3 and OUTPUT4 output drivers.
12 Force reset This active signal forces a reset cycle that generates synchronization pulses for the outputs of each PLL.
11
PLL2 phase
retard This bit is similar to the advance bit but shifts the output of the VCO backward one of eight phases.
10 Rational mode
This bit sets the rational mode, the use of which is described in detail in the PLLs section. In rational mode, the
feedback divider fractional part is a ratio of integers, with the numerator encoded in PLL2 Fractional Feedback
Divider[24:9] in Register 8and the denominator encoded in PLL2 Modulus Value[15:6] of this register.
9:0 PLL2 Modulus
Value[15:6]
The first 10 bits of the 16-bit modulus value. When the 16-bit binary value is 0, the PLL1 Fractional Feedback
Divider[27:0] value is interpreted as a 28-bit fixed point value. When PLL1 Modulus Value[15:0] is nonzero, and
the rational mode bit is set, the feedback divider ratio is calculated by a complicated expression (see Tabl e 26 ). In
the simplest case, S[1:0] is set to 3 (no phase interpolation), and the feedback divider expression is PLL1
Fractional Feedback Divider[24:9] + (PLL1 Feedback Divider[24:9]/modulus), generating a feedback divider that
is an exact ratio of integers. Note that having a numerator that is larger than the denominator is an invalid
configuration. Also, note that the lower six bits of the modulus value are shared with the lowest six bits of PLL1
Feedback Divider[27:0], which are not otherwise used in rational mode.
AD9578 Data Sheet
Rev. B | Page 42 of 44
XTAL2 CONFIGURATION (REGISTER 10, ADDRESS 0x0A)
Table 42. XTAL2 Configuration
Bits Bit Name Description
15 XTAL2 frequency trim This is an additional gain trim bit for the second crystal oscillator. X TA L2 frequency trim = 1 is
recommended for optimal performance with crystal frequencies 33 MHz. See Tab l e 25.
14:12 XTAL1 Capacitance
Value[2:0]
These register bits control the amount of internal load capacitance on the XO3 and XO4 pins. The correct
setting can be determined using the following equation: 2 × (CLOAD − CS T R AY ) where CLOAD is the specified
load capacitance of the crystal used, and CST R AY is the stray capacitance (usually 2 pF to 5 pF) on the circuit
board.
X TAL 2 Capacitance
Value[2:0]
CLOAD of Crystal
(pF)
Recommended Internal Capacitance on XO3/XO4 Pins
(Assuming 3 pF Stray Capacitance) (pF)
000 8 10
001 9 12
010 10 14
011 11 16
100 12 18
101 13 20
110 14 22
111 15 24
14:12
XTA L 2 Capacitance
Value[2:0]
These register bits are identical to the ones in Register 3, except that they apply to XTAL2, which is
connected to the XO3 and XO4 pins.
11:9 XTA L2 Gain[2:0]
These are gain trim bits for the second crystal oscillator. Optimal performance is achieved when the gain is
programmed according to the ESR of the crystal. See Tabl e 25.
8 Enable XTA L 2
Setting the enable XTAL2 bit and the REFSELx bit allows the second crystal oscillator to be used as the PLLx
reference.
7:0 Reserved Reserved. Set to 0.
RESERVED (REGISTER 11, ADDRESS 0x0B)
Table 43. Reserved
Bits Bit Name Description
31:0
Reserved
Factory configured; do not change.
PLL1 KVCO BAND (REGISTER 12, ADDRESS 0x0C)
Table 44. PLL1 KVCO Band
Bits Bit Name Description
31
PLL1 K
VCO
band
K
VCO
band for PLL1. When changing the PLL1 K
VCO
band bit, it is best to first read the entire register and then write
the same values for other bits in this register.
0 (default): set to 0 if PLL1 Frequency Select[4:0] (Register 7, Bits[28:24]) is between 0 and 13.
1: set to 1 if PLL1 Frequency Select[4:0] (Register 7, Bits[28:24]) is between 14 and 27.
30:0 Reserved Factory configured; do not change. Default: varies.
RESERVED (REGISTER 13, ADDRESS 0x0D)
Table 45. Reserved
Bits Bit Name Description
31:0 Reserved Factory configured; do not change.
Data Sheet AD9578
Rev. B | Page 43 of 44
PLL2 KVCO BAND (REGISTER 14, ADDRESS 0x0E)
Table 46. PLL2 KVCO Band
Bits Bit Name Description
31 PLL2 KVCO
band
KVCO band for PLL2. When changing the PLL2 KVCO band bit, it is best to first read the entire register and then write the
same values for other bits in this register.
0 (default): set to 0 if PLL2 Frequency Select[4:0] (Register 9, Bits[28:24]) is between 0 and 13.
1: set to 1 if PLL2 Frequency Select[4:0] (Register 9, Bits[28:24]) is between 14 and 27.
30:0 Reserved Factory configured; do not change. Default: varies.
PLL LOCK DETECT (REGISTER 15, ADDRESS 0x0F)
Table 47. PLL Lock Detect (Read Only)
Bits Bit Name Description
23 PLL2 lock detect PLL2 lock detect.
0: PLL2 is not locked, possibly indicating the absence of an input reference, or that the PLL is
misconfigured.
1: PLL2 is locked.
22 Reserved
21 PLL1 lock detect PLL1 lock detect.
0: PLL1 is not locked, possibly indicating the absence of an input reference, or that the PLL is
misconfigured.
1: PLL1 is locked.
20:19 Reserved Set to 00b.
18:17
Revision
Subcode[1:0]
This 2-bit value gives the mask variant of the AD9578. Default: 01b
6 Reserved Default: 0x00
15:0 Unused Set to 0.
AD9578 Data Sheet
Rev. B | Page 44 of 44
OUTLINE DIMENSIONS
COMPLIANT TO JEDEC STANDARDS MO-220-WKKD-4.
FOR PROPER CONNECTION OF
THE EXPOSED PAD, REFER TO
THE PIN CONFIGURATION AND
FUNCTION DESCRIPTIONS
SECTION OF THIS DATA SHEET.
1
0.50
BSC
BOTTOM VIEW
TOP VIEW
PIN 1
INDICATOR
48
13
24
36
37
PIN 1
INDICATOR
5.70
5.60 SQ
5.50
0.50
0.40
0.30
SEATING
PLANE
0.80
0.75
0.70 0.05 MAX
0.02 NOM
0.203 REF
COPLANARITY
0.08
0.30
0.25
0.18
02-29-2016-A
7.10
7.00 SQ
6.90
0.20 MIN
5.50 REF
END VIEW
EXPOSED
PAD
PKG-004452
Figure 36. 48-Lead Lead Frame Chip Scale Package [LFCSP_VQ]
7 mm × 7 mm Body, Very Very Thin Quad
(CP-48-13)
Dimensions shown in millimeters
ORDERING GUIDE
Model1 Temperature Range Package Description Package Option
AD9578BCPZ −25°C to +85°C 48-Lead LFCSP_VQ Tube CP-48-13
AD9578BCPZ-REEL7 −25°C to +85°C 48-Lead LFCSP_VQ Tape and Reel CP-48-13
AD9578/PCBZ −25°C to +85°C Evaluation Board CP-48-13
1 Z = RoHS Compliant Part.
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D11356-0-1/17(B)