AD9142-M5372-EBZ [ADI]
Dual, 16-Bit, 1600 MSPS, TxDAC Digital-to-Analog Converter; 双通道, 16位, 1600 MSPS , TxDAC系列数位类比转换器型号: | AD9142-M5372-EBZ |
厂家: | ADI |
描述: | Dual, 16-Bit, 1600 MSPS, TxDAC Digital-to-Analog Converter |
文件: | 总65页 (文件大小:1113K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
Dual, 16-Bit, 1600 MSPS, TxDAC+
Digital-to-Analog Converter
Data Sheet
AD9142
FEATURES
GENERAL DESCRIPTION
Very small inherent latency variation: <2 DAC clock cycles
Proprietary low spurious and distortion design
6-carrier GSM ACLR = 79 dBc at 200 MHz IF
SFDR > 85 dBc (bandwidth = 300 MHz) at ZIF
Flexible 16-bit LVDS interface
Supports word and byte load
Multiple chip synchronization
Fixed latency and data generator latency compensation
Selectable 2×, 4×, 8× interpolation filter
Low power architecture
fS/4 power saving coarse mixer
Input signal power detection
Emergency stop for downstream analog circuitry
protection
FIFO error detection
The AD9142 is a dual, 16-bit, high dynamic range digital-to-
analog converter (DAC) that provides a sample rate of 1600 MSPS,
permitting a multicarrier generation up to the Nyquist frequency.
The AD9142 TxDAC+® includes features optimized for direct
conversion transmit applications, including complex digital mod-
ulation, input signal power detection, and gain, phase, and offset
compensation. The DAC outputs are optimized to interface
seamlessly with analog quadrature modulators, such as the
ADL537x F-MOD series and the ADRF670x series from Analog
Devices, Inc. A 3-wire serial port interface provides for the pro-
gramming/readback of many internal parameters. Full-scale
output current can be programmed over a range of 9 mA to 33 mA.
The AD9142 is available in a 72-lead LFCSP.
PRODUCT HIGHLIGHTS
1. Advanced low spurious and distortion design techniques
provide high quality synthesis of wideband signals from
baseband to high intermediate frequencies.
2. Very small inherent latency variation simplifies both software
and hardware design in the system. It allows easy multichip
synchronization for most applications.
On-chip numeric control oscillator allows carrier placement
anywhere in the DAC Nyquist bandwidth
Transmit enable function for extra power saving
High performance, low noise PLL clock multiplier
Digital gain and phase adjustment for sideband suppression
Digital inverse sinc filter
3. New low power architecture improves power efficiency
(mW/MHz/channel) by 30%.
4. Input signal power and FIFO error detection simplify
designs for downstream analog circuitry protection.
5. Programmable transmit enable function allows easy design
balance between power consumption and wakeup time.
Supports single DAC mode
Low power: 2.0 W at 1.6 GSPS, 1.7 W at 1.25 GSPS, full
operating conditions
72-lead LFCSP
APPLICATIONS
Wireless communications: 3G/4G and MC-GSM base stations,
wideband repeaters, software defined radios
Wideband communications: point-to-point, LMDS/MMDS
Transmit diversity/MIMO
Instrumentation
Automated test equipment
Rev. 0
Document Feedback
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responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other
rightsof third parties that may result fromits use. Specifications subject to change without notice. No
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One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700
©2012 Analog Devices, Inc. All rights reserved.
Technical Support
www.analog.com
AD9142
Data Sheet
TABLE OF CONTENTS
Features .............................................................................................. 1
Input Signal Power Detection and Protection........................ 30
Transmit Enable Function......................................................... 31
Digital Function Configuration ............................................... 31
Multidevice Synchronization and Fixed Latency....................... 32
Very Small Inherent Latency Variation................................... 32
Further Reducing the Latency Variation................................. 32
Synchronization Implementation ............................................ 33
Synchronization Procedures..................................................... 33
Interrupt Request Operation ........................................................ 34
Interrupt Working Mechanism ................................................ 34
Interrupt Service Routine.......................................................... 34
Temperature Sensor ....................................................................... 35
DAC Input Clock Configurations ................................................ 36
Driving the DACCLK and REFCLK Inputs ........................... 36
Direct Clocking .......................................................................... 36
Clock Multiplication .................................................................. 36
PLL Settings ................................................................................ 37
Configuring the VCO Tuning Band ........................................ 37
Automatic VCO Band Select .................................................... 37
Manual VCO Band Select ......................................................... 37
Analog Outputs............................................................................... 38
Transmit DAC Operation.......................................................... 38
Interfacing to Modulators ......................................................... 39
Reducing LO Leakage and Unwanted Sidebands .................. 40
Example Start-Up Routine ............................................................ 41
Device Configuration Register Map and Description............... 42
SPI Configure Register .............................................................. 44
Power-Down Control Register................................................. 44
Interrupt Enable0 Register........................................................ 44
Interrupt Enable1 Register........................................................ 44
Interrupt Flag0 Register............................................................. 45
Interrupt Flag1 Register............................................................. 45
Interrupt Select0 Register.......................................................... 45
Interrupt Select1 Register.......................................................... 46
DAC Clock Receiver Control Register .................................... 46
Ref Clock Receiver Control Register ....................................... 46
PLL Control Register ................................................................. 47
PLL Control Register ................................................................. 47
PLL Control Register ................................................................. 47
PLL Status Register..................................................................... 48
Applications....................................................................................... 1
General Description ......................................................................... 1
Product Highlights ........................................................................... 1
Revision History ............................................................................... 3
Functional Block Diagram .............................................................. 4
Specifications..................................................................................... 5
DC Specifications ......................................................................... 5
Digital Specifications ................................................................... 6
DAC Latency Specifications........................................................ 7
Latency Variation Specifications ................................................ 7
AC Specifications.......................................................................... 7
Operating Speed Specifications.................................................. 8
Absolute Maximum Ratings ....................................................... 9
Thermal Resistance ...................................................................... 9
ESD Caution.................................................................................. 9
Pin Configuration and Function Descriptions........................... 10
Typical Performance Characteristics ........................................... 12
Terminology .................................................................................... 17
Serial Port Operation ..................................................................... 18
Data Format ................................................................................ 18
Serial Port Pin Descriptions...................................................... 18
Serial Port Options..................................................................... 18
Data Interface.................................................................................. 20
LVDS Input Data Ports .............................................................. 20
Word Interface Mode................................................................. 20
Byte Interface Mode ................................................................... 20
Data Interface Configuration Options .................................... 20
Interface Delay Line ................................................................... 22
FIFO Operation .............................................................................. 23
Resetting the FIFO ..................................................................... 24
Serial Port Initiated FIFO Reset ............................................... 24
Frame Initiated FIFO Reset....................................................... 24
Digital Datapath.............................................................................. 26
Interpolation Filters ................................................................... 26
Digital Modulation..................................................................... 28
Datapath Configuration ............................................................ 29
Digital Quadrature Gain and Phase Adjustment................... 29
DC Offset Adjustment............................................................... 29
Inverse Sinc Filter....................................................................... 30
Rev. 0 | Page 2 of 64
Data Sheet
AD9142
PLL Status Register .....................................................................48
IDAC FS Adjust LSB Register....................................................48
IDAC FS Adjust MSB Register ..................................................48
QDAC FS Adjust LSB Register..................................................48
QDAC FS Adjust MSB Register ................................................49
Die Temperature Sensor Control Register...............................49
Die Temperature LSB Register ..................................................49
Die Temperature MSB Register.................................................49
Chip ID Register..........................................................................49
Interrupt Configuation Register ...............................................50
Sync CTRL Register....................................................................50
Frame Reset CTRL Register.......................................................50
FIFO Level Configuration Register ..........................................51
FIFO Level Readback Register ..................................................51
FIFO CTRL Register...................................................................51
Data Format Select Register.......................................................52
Datapath Control Register .........................................................52
Interpolation Control Register..................................................52
Over Threshold CTRL0 Register ..............................................53
Over Threshold CTRL1 Register ..............................................53
Over Threshold CTRL2 Register ..............................................53
Input Power Readback LSB Register ........................................53
Input Power Readback MSB Register.......................................53
NCO Control Register................................................................54
NCO_FREQ_TUNING_WORD0 Register.............................54
NCO_FREQ_TUNING_WORD1 Register.............................54
NCO_FREQ_TUNING_WORD2 Register.............................54
NCO_FREQ_TUNING_WORD3 Register.............................54
NCO_PHASE_OFFSET0 Register............................................54
NCO_PHASE_OFFSET1 Register............................................55
IQ_PHASE_ADJ0 Register........................................................55
IQ_PHASE_ADJ1 Register........................................................55
IDAC_DC_OFFSET0 Register..................................................55
IDAC_DC_OFFSET1 Register..................................................55
QDAC_DC_OFFSET0 Register................................................55
QDAC_DC_OFFSET1 Register................................................56
IDAC_GAIN_ADJ Register.......................................................56
QDAC_GAIN_ADJ Register.....................................................56
Gain Step Control0 Register......................................................56
Gain Step Control1 Register......................................................56
TX Enable Control Register ......................................................57
DAC Output Control Register ..................................................57
Data Receiver Test Control Register.........................................57
Data Receiver Test Control Register.........................................57
Device Configuration0 Register................................................58
Version Register ..........................................................................58
Device Configuration1 Register................................................58
Device Configuration2 Register................................................58
DAC Latency and System Skews...................................................59
DAC Latency Variations.............................................................59
FIFO Latency Variation..............................................................59
Clock Generation Latency Variation........................................60
Correcting System Skews...........................................................60
Packaging and Ordering Information..........................................61
Outline Dimensions....................................................................61
Ordering Guide ...........................................................................61
REVISION HISTORY
11/12—Revision 0: Initial Version
Rev. 0 | Page 3 of 64
AD9142
Data Sheet
FUNCTIONAL BLOCK DIAGRAM
INPUT POWER
DCIP/DCIN
AD9142
DETECTION
16
IOUT1P
IOUT1N
COMPLEX
D15P/D15N
DAC 1
16-BIT
MODULATION
NCO
HB1
2×
HB2
2×
HB3
2×
DAC CLK
16
D0P/D0N
fDAC/4
MOD
FRAMEP/
FRAMEN
IOUT2P
IOUT2N
DAC 2
16-BIT
REF
REFIO
FSADJ
AND
10
10
BIAS
INTERNAL CLOCK TIMING AND CONTROL LOGIC
DACCLKP
DACCLKN
PROGRAMMING
REGISTERS
SERIAL
INPUT/OUTPUT
PORT
CLK
RCVR
POWER-ON
RESET
MULTICHIP
SYNCHRONIZATION
DAC_CLK
REFP/SYNCP
REFN/SYNCN
CLOCK
MULTIPLIER
REF
RCVR
SYNC
Figure 1.
Rev. 0 | Page 4 of 64
Data Sheet
AD9142
SPECIFICATIONS
DC SPECIFICATIONS
TMIN to TMAX, AVDD33 = 3.3 V, DVDD18 = 1.8 V, CVDD18 = 1.8 V, IOUTFS = 20 mA, maximum sample rate, unless otherwise noted.
Table 1.
Parameter
Test Conditions/Comments
Min
Typ
Max
Unit
RESOLUTION
16
Bits
ACCURACY
Differential Nonlinearity (DNL)
Integral Nonlinearity (INL)
MAIN DAC OUTPUTS
Offset Error
2.1
3.7
LSB
LSB
−0.001
−3.2
0
2
+0.001 % FSR
Gain Error
With internal reference
4.7
+20.6
+1.0
% FSR
mA
V
Full-Scale Output Current
Output Compliance Range
Output Resistance
Gain DAC Monotonicity
Settling Time to Within 0.5 LSB
MAIN DAC TEMPERATURE DRIFT
Offset
Based on a 10 kΩ external resistor between FSADJ and AVSS 19.06
−1.0
19.8
10
MΩ
Guaranteed
20
ns
0.04
100
30
ppm/°C
ppm/°C
ppm/°C
Gain
Reference Voltage
REFERENCE
Internal Reference Voltage
Output Resistance
ANALOG SUPPLY VOLTAGES
AVDD33
1.17
1.19
V
kΩ
5
3.13
1.71
3.3
1.8
3.47
1.89
V
V
CVDD18
DIGITAL SUPPLY VOLTAGES
DVDD18
1.71
1.8
1.89
V
POWER CONSUMPTION
2× Mode
fDAC = 491.52 MSPS
NCO OFF
NCO ON
700
870
mW
mW
4× Mode
NCO OFF
NCO ON
4× Mode
NCO OFF
NCO ON
8× Mode
fDAC = 737.28 MSPS
fDAC = 983.04 MSPS
fDAC = 1600 MSPS
836
1085
mW
mW
1030
1365
mW
mW
NCO OFF
NCO ON
Phase-Lock Loop
Inverse Sinc
Reduced Power Mode (Power Down)
AVDD33
1315
1815
70
mW
mW
mW
mW
mW
mA
mA
mA
°C
fDAC = 1474.56 MSPS
113
96.6
1.5
42.3
8.6
CVDD18
DVDD18
OPERATING RANGE
−40
+25
+85
Rev. 0 | Page 5 of 64
AD9142
Data Sheet
DIGITAL SPECIFICATIONS
TMIN to TMAX, AVDD33 = 3.3 V, DVDD18 = 1.8 V, CVDD18 = 1.8 V, IOUTFS = 20 mA, maximum sample rate, unless otherwise noted.
Table 2.
Parameter
Symbol
Test Conditions/Comments
Min
Typ
Max
0.6
Unit
CMOS INPUT LOGIC LEVEL
Input
Logic High
Logic Low
DVDD18 = 1.8 V
DVDD18 = 1.8 V
1.2
V
V
CMOS OUTPUT LOGIC LEVEL
Output
Logic High
Logic Low
DVDD18 = 1.8 V
DVDD18 = 1.8 V
1.4
V
V
0.4
LVDS RECEIVER INPUTS
Input Voltage Range
Input Differential Threshold
VIA or VIB
VIDTH
825
−100
−225
1675
+100
+225
mV
mV
mV
Data and FRAME inputs
DCI input
Input Differential Hysteresis
Receiver Differential Input Impedance
DAC UPDATE RATE
VIDTHH to VIDTHL
RIN
20
120
mV
Ω
1600
250
MSPS
MSPS
DAC Adjusted Update Rate
DAC CLOCK INPUT (DACCLKP, DACCLKN)
Differential Peak-to-Peak Voltage
Common-Mode Voltage
REFCLK/SYNCCLK INPUT (REFP/SYNCP, REFN/SYNCN)
Differential Peak-to-Peak Voltage
Common-Mode Voltage
Input Clock Frequency
SERIAL PORT INTERFACE
Maximum Clock Rate
2× interpolation
100
100
500
1.25
2000
mV
V
Self biased input, ac-coupled
500
1.25
2000
450
mV
V
MHz
1 GHz ≤ fVCO ≤ 2.1 GHz
SCLK
40
MHz
Minimum Pulse Width
High
Low
Setup Time
Hold Time
tPWH
tPWL
tDS
tDH
tDCSB
12.5
12.5
ns
ns
ns
ns
ns
SDIO to SCLK
SDIO to SCLK
CS to SCLK
1.5
0.68
2.38
Setup Time
1.4
Rev. 0 | Page 6 of 64
Data Sheet
AD9142
DAC LATENCY SPECIFICATIONS
TMIN to TMAX, AVDD33 = 3.3 V, DVDD18 = 1.8 V, CVDD18 = 1.8 V, IOUTFS = 20 mA, FIFO level is set to 4 (half of the FIFO depth), unless
otherwise noted.
Table 3.
Parameter
Test Conditions/Comments
Min Typ Max Unit
WORD INTERFACE MODE
2× Interpolation
4× Interpolation
8× Interpolation
BYTE INTERFACE MODE
2× Interpolation
4× Interpolation
8× Interpolation
INDIVIDUAL FUNCTION BLOCKS
Modulation
Fine/coarse modulation, inverse sinc, gain/phase compensation off
134
244
481
DACCLK cycles
DACCLK cycles
DACCLK cycles
Fine/coarse modulation, inverse sinc, gain/phase compensation off
145
271
506
DACCLK cycles
DACCLK cycles
DACCLK cycles
Fine
Coarse
Inverse Sinc
Phase Compensation
Gain Compensation
17
10
20
12
16
DACCLK cycles
DACCLK cycles
DACCLK cycles
DACCLK cycles
DACCLK cycles
LATENCY VARIATION SPECIFICATIONS1
Table 4.
Parameter
Min
Typ
Max
Unit
DAC LATENCY VARIATION
SYNC Off
SYNC On
2
1
DACCLK cycles
DACCLK cycles
1 DAC latency is defined as the elapsed time from a data sample clocked at the input to the AD9142 until the analog output begins to change.
AC SPECIFICATIONS
TMIN to TMAX, AVDD33 = 3.3 V, DVDD18 = 1.8 V, CVDD18 = 1.8 V, IOUTFS = 20 mA, maximum sample rate, unless otherwise noted.
Table 5.
Parameter
Test Conditions/Comments
−14 dBFS single tone
fOUT = 200 MHz
Min Typ
Max Unit
SPURIOUS-FREE DYNAMIC RANGE (SFDR)
fDAC = 737.28 MSPS
BW = 125 MHz
85
80
dBc
dBc
BW = 270 MHz
fDAC = 983.04 MSPS
BW = 360MHz
fDAC = 1228.8 MSPS
BW = 200MHz
fOUT = 200 MHz
fOUT = 280 MHz
85
dBc
85
75
dBc
dBc
BW = 500MHz
fDAC = 1474.56 MSPS
BW = 737MHz
BW = 400MHz
fOUT = 10 MHz
85
80
dBc
dBc
fOUT = 280 MHz
−6 dBFS each tone
fOUT = 200 MHz
fOUT = 200 MHz
fOUT = 280 MHz
fOUT = 10 MHz
TWO-TONE INTERMODULATION DISTORTION (IMD)
fDAC = 737.28 MSPS
fDAC = 983.04 MSPS
fDAC = 1228.8 MSPS
fDAC = 1474.56 MSPS
80
82
80
85
79
dBc
dBc
dBc
dBc
dBc
fOUT = 280 MHz
Rev. 0 | Page 7 of 64
AD9142
Data Sheet
Parameter
Test Conditions/Comments
Eight-tone, 500 kHz tone spacing
fOUT = 200 MHz
fOUT = 200 MHz
fOUT = 280 MHz
fOUT = 10 MHz
fOUT = 280 MHz
Single carrier
fOUT = 200 MHz
fOUT = 20 MHz
fOUT = 280 MHz
fOUT = 20 MHz
fOUT = 280 MHz
Single carrier
fOUT = 200 MHz
fOUT = 20 MHz
fOUT = 280 MHz
fOUT = 20 MHz
Min Typ
Max Unit
NOISE SPECTRAL DENSITY (NSD)
fDAC = 737.28 MSPS
fDAC = 983.04 MSPS
fDAC = 1228.8 MSPS
fDAC = 1474.56 MSPS
−160
−161.5
−164.5
−166
−162.5
dBm/Hz
dBm/Hz
dBm/Hz
dBm/Hz
dBm/Hz
W-CDMA ADJACENT CHANNEL LEAKAGE RATIO (ACLR)
fDAC = 983.04 MSPS
fDAC = 1228.8 MSPS
81
83
80
81
80
dBc
dBc
dBc
dBc
dBc
fDAC = 1474.56 MSPS
W-CDMA SECOND (ACLR)
fDAC = 983.04 MSPS
fDAC = 1228.8 MSPS
85
86
86
86
85
dBc
dBc
dBc
dBc
dBc
fDAC = 1474.56 MSPS
fOUT = 280 MHz
OPERATING SPEED SPECIFICATIONS
Table 6.
DVDD18, CVDD18 = 1.8 V 5%
DVDD18, CVDD18 = 1.8 V 2% or 1.9 V 5%
Interpolation
Factor
fINTERFACE (Mbps) Max
fDAC (Mbps) Max
fINTERFACE (Mbps) Max
fDAC (Mbps) Max
2×
4×
8×
250
250
187.5
500
1000
1500
250
250
200
500
1000
1600
Rev. 0 | Page 8 of 64
Data Sheet
AD9142
ABSOLUTE MAXIMUM RATINGS
THERMAL RESISTANCE
Table 7.
The exposed pad (EPAD) must be soldered to the ground plane
(AVSS) for the 72-lead LFCSP. The EPAD provides an electrical,
thermal, and mechanical connection to the board.
Parameter
Rating
AVDD33 to AVSS, EPAD, CVSS, DVSS
DVDD18, CVDD18 to AVSS, EPAD,
CVSS, DVSS
AVSS to EPAD, CVSS, DVSS
EPAD to AVSS, CVSS, DVSS
CVSS to AVSS, EPAD, DVSS
DVSS to AVSS, EPAD, CVSS
FSADJ, REFIO, IOUT1P/IOUT1N,
IOUT2P/IOUT2N to AVSS
−0.3 V to +3.6 V
−0.3 V to +2.1 V
Typical θJA, θJB, and θJC values are specified for a 4-layer board in
still air. Airflow increases heat dissipation, effectively reducing
−0.3 V to +0.3 V
−0.3 V to +0.3 V
−0.3 V to +0.3 V
−0.3 V to +0.3 V
θ
JA and θJB.
Table 8. Thermal Resistance
−0.3 V to AVDD33 + 0.3 V
Package θJA θJB
θJC
Unit Conditions
72-Lead LFCSP 20.7 10.9 1.1
°C/W EPAD soldered
to ground plane
D[15:0]P/D[15:0]N, FRAMEP/FRAMEN, −0.3 V to DVDD18 + 0.3 V
DCIP/DCIN to EPAD, DVSS
DACCLKP/DACCLKN,
−0.3 V to CVDD18 + 0.3 V
REFP/SYNCP/REFN/SYNCN to CVSS
RESET, IRQ1, IRQ2, CS, SCLK, SDIO
to EPAD, DVSS
ESD CAUTION
−0.3 V to DVDD18 + 0.3 V
Junction Temperature
125°C
Storage Temperature Range
−65°C to +150°C
Stresses above those listed under Absolute Maximum Ratings
may cause permanent damage to the device. This is a stress
rating only; functional operation of the device at these or any
other conditions above those indicated in the operational
section of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect
device reliability.
Rev. 0 | Page 9 of 64
AD9142
Data Sheet
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
CVDD18
REFP/SYNCP
REFN/SYNCN
CVDD18
1
2
3
4
5
6
7
8
9
54 CS
53 SCLK
52 SDIO
51 IRQ1
50 IRQ2
49 DVDD18
48 DVDD18
47 D0N
46 D0P
45 D1N
44 D1P
43 DVDD18
42 D2N
RESET
TXEN
DVDD18
FRAMEP
FRAMEN
D15P 10
D15N 11
DVDD18 12
D14P 13
D14N 14
D13P 15
D13N 16
D12P 17
D12N 18
AD9142
TOP VIEW
(Not to Scale)
41 D2P
40 D3N
39 D3P
38 D4N
37 D4P
NOTES
1. EXPOSED PAD (EPAD) MUST BE SOLDERED TO THE GROUND
PLANE (AVSS). THE EPAD PROVIDES AN ELECTRICAL, THERMAL,
AND MECHANICAL CONNECTION TO THE BOARD.
2. EPAD IS THE GROUND CONNECTION FOR CVSS AND DVSS.
Figure 2. Pin Configuration
Table 9. Pin Function Descriptions
Pin No. Mnemonic Description
1
2
3
4
5
6
CVDD18
REFP/SYNCP
1.8 V PLL Supply. CVDD18 supplies the clock receivers, clock multiplier, and clock distribution.
PLL Reference Clock Input, Positive.
REFN/SYNCN PLL Reference Clock Input, Negative.
CVDD18
RESET
TXEN
1.8 V PLL Supply. CVDD18 supplies the clock receivers, clock multiplier, and clock distribution.
Reset, Active Low. CMOS levels with respect to DVDD18. Recommended reset pulse length is 1 μs.
Active High Transmit Path Enable. CMOS levels with respect to DVDD18. A low level on this pin triggers three
selectable actions in the DAC. See Register 0x43 in Table 77 for details.
7
DVDD18
1.8 V Digital Supply. Pin 7 supplies power to the digital core, digital data ports, serial port input/output pins, RESET, IRQ1,
and IRQ2.
8
9
FRAMEP
FRAMEN
D15P
D15N
DVDD18
D14P
D14N
D13P
D13N
D12P
Frame Input, Positive.
Frame Input, Negative.
Data Bit 15 (MSB), Positive.
Data Bit 15 (MSB), Negative.
10
11
12
13
14
15
16
17
18
19
1.8 V Digital Supply. Pin 12 supplies the power to the digital core and digital data ports.
Data Bit 14, Positive.
Data Bit 14, Negative.
Data Bit 13, Positive.
Data Bit 13, Negative.
Data Bit 12, Positive.
Data Bit 12, Negative.
D12N
DVDD18
1.8 V Digital Supply. Pin 19 supplies power to the digital core, digital data ports, serial port input/output pins,
RESET, IRQ1, and IRQ2.
20
21
22
23
24
D11P
D11N
D10P
D10N
D9P
Data Bit 11, Positive.
Data Bit 11, Negative.
Data Bit 10, Positive.
Data Bit 10, Negative.
Data Bit 9, Positive.
Rev. 0 | Page 10 of 64
Data Sheet
AD9142
Pin No. Mnemonic
Description
25
26
27
28
29
30
31
32
33
34
35
36
D9N
D8P
D8N
DCIP
DCIN
D7P
D7N
D6P
D6N
D5P
Data Bit 9, Negative.
Data Bit 8, Positive.
Data Bit 8, Negative.
Data Clock Input, Positive.
Data Clock Input, Negative.
Data Bit 7, Positive.
Data Bit 7, Negative.
Data Bit 6, Positive.
Data Bit 6, Negative.
Data Bit 5, Positive.
Data Bit 5, Negative.
D5N
DVDD18
1.8 V Digital Supply. Pin 36 supplies power to the digital core, digital data ports, serial port input/output pins,
RESET, IRQ1, and IRQ2.
37
38
39
40
41
42
43
D4P
D4N
D3P
D3N
D2P
D2N
DVDD18
Data Bit 4, Positive.
Data Bit 4, Negative.
Data Bit 3, Positive.
Data Bit 3, Negative.
Data Bit 2, Positive.
Data Bit 2, Negative.
1.8 V Digital Supply. Pin 43 supplies power to the digital core, digital data ports, serial port input/output pins,
RESET, IRQ1, and IRQ2.
44
45
46
47
48
D1P
D1N
D0P
D0N
Data Bit 1, Positive.
Data Bit 1, Negative.
Data Bit 0 (LSB), Positive.
Data Bit 0 (LSB), Negative.
DVDD18
1.8 V Digital Supply. Pin 48 supplies power to the digital core, digital data ports, serial port input/output pins,
RESET, IRQ1, and IRQ2.
49
DVDD18
1.8 V Digital Supply. Pin 49 supplies power to the digital core, digital data ports, serial port input/output
pins, RESET, IRQ1, and IRQ2.
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
IRQ2
Second Interrupt Request. Open-drain, active low output. Connect an external pull-up to DVDD18 through a 10 kΩ resistor.
First Interrupt Request. Open-drain, active low output. Connect an external pull-up to DVDD18 through a 10 kΩ resistor.
Serial Port Data Input/Output. CMOS levels with respect to DVDD18.
Serial Port Clock Input. CMOS levels with respect to DVDD18.
Serial Port Chip Select. Active low (CMOS levels with respect to DVDD18).
3.3 V Analog Supply.
QDAC Positive Current Output.
QDAC Negative Current Output.
3.3 V Analog Supply.
IRQ1
SDIO
SCLK
CS
AVDD33
IOUT2P
IOUT2N
AVDD33
CVDD18
CVDD18
DACCLKN
DACCLKP
CVDD18
CVDD18
AVDD33
IOUT1N
IOUT1P
AVDD33
FSADJ
1.8 V Clock Supply. Supplies clock receivers and clock distribution.
1.8 V Clock Supply. Supplies clock receivers and clock distribution.
DAC Clock Input, Negative.
DAC Clock Input, Positive.
1.8 V Clock Supply. Supplies clock receivers and clock distribution.
1.8 V Clock Supply. Supplies clock receivers and clock distribution.
3.3 V Analog Supply.
IDAC Negative Current Output.
IDAC Positive Current Output.
3.3 V Analog Supply.
Full-Scale Current Output Adjust. Place a 10 kΩ resistor from this pin to AVSS.
Voltage Reference. Nominally 1.2 V output. Decouple REFIO to AVSS.
1.8 V Clock Supply. Pin 71 supplies the clock receivers, clock multiplier, and clock distribution.
1.8 V Clock Supply. Pin 72 supplies the clock receivers, clock multiplier, and clock distribution.
Exposed Pad. The exposed pad (EPAD) must be soldered to the ground plane (AVSS). The EPAD provides an
electrical, thermal, and mechanical connection to the board.
Rev. 0 | Page 11 of 64
REFIO
CVDD18
CVDD18
EPAD
AD9142
Data Sheet
TYPICAL PERFORMANCE CHARACTERISTICS
0
–60
–65
BW = 80MHz, –6dBFS
BW = 80MHz, –12dBFS
BW = 300MHz, –6dBFS
BW = 300MHz, –12dBFS
fDAC = 737.28MHz
fDAC = 983.04MHz
fDAC = 1228.8MHz
–10
fDAC = 1474.56MHz
–20
–30
–40
–50
–60
–70
–80
–90
–70
–75
–80
–85
–85 MEANS ≤ –85
< –85
0
100
200
300
400
500
600
700
800
0
20
40
60
80
100 120 140 160 180 200
fOUT (MHz)
fOUT (MHz)
Figure 3. Single-Tone (0 dBFS) SFDR vs. fOUT in the First Nyquist Zone over fDAC
Figure 6. Single-Tone SFDR (Excluding 2nd Harmonic) vs. fOUT in 80 MHz and
300 MHz Bandwidths, fDAC = 737.28 MHz
0
–60
BW = 80MHz, –6dBFS
BW = 80MHz, –12dBFS
BW = 300MHz, –6dBFS
0dBFS
–6dBFS
–12dBFS
–16dBFS
–10
–20
–30
–40
–50
–60
–70
–80
–90
–100
–65
–70
BW = 300MHz, –12dBFS
–75
–80
–85
–85 MEANS ≤ –85
< –85
0
100
200
300
400
500
600
700
800
0
50
100
150
200
250
300
fOUT (MHz)
fOUT (MHz)
Figure 4. Single-Tone Second Harmonic vs. fOUT in the First Nyquist Zone
over Digital Back Off, fDAC = 1474.56 MHz
Figure 7. Single-Tone SFDR (Excluding 2nd Harmonic) vs. fOUT in 80 MHz and
300 MHz BW, fDAC = 983.04 MHz
0
–60
BW = 80MHz, –6dBFS
BW = 80MHz, –12dBFS
BW = 300MHz, –6dBFS
0dBFS
–6dBFS
–12dBFS
–16dBFS
–10
–20
–30
–40
–50
–60
–70
–80
–90
–100
–65
–70
BW = 300MHz, –12dBFS
–75
–80
–85
–85 MEANS ≤ –85
< –85
0
100
200
300
400
500
600
700
800
0
50
100
150
200
250
300
350
fOUT (MHz)
fOUT (MHz)
Figure 5. Single-Tone Third Harmonic vs. fOUT in the First Nyquist Zone
over Digital Back Off, fDAC = 1474.56 MHz
Figure 8. Single-Tone SFDR (Excluding 2nd Harmonic) vs. fOUT in 80 MHz and
300 MHz Bandwidths, fDAC = 1228.8 MHz
Rev. 0 | Page 12 of 64
Data Sheet
AD9142
–60
0
–20
BW = 80MHz, –6dBFS
0.6MHz TONE SPACING
16MHz TONE SPACING
35MHz TONE SPACING
BW = 80MHz, –12dBFS
BW = 300MHz, –6dBFS
BW = 300MHz, –12dBFS
–65
–70
–40
–75
–60
–80
–80
–85
–100
–120
–85 MEANS ≤ –85
< –85
0
50
100
150
200
250
300
350
0
100
200
300
400
500
600
700
800
fOUT (MHz)
fOUT (MHz)
Figure 9. Single-Tone SFDR (Excluding 2nd Harmonic) vs. fOUT in 80 MHz and
300 MHz Bandwidths, fDAC = 1474.56 MHz
Figure 12. Two-Tone Third IMD vs. fOUT over Tone Spacing,
DAC = 1474.56 MHz
f
0
–152
–154
–156
–158
–160
–162
–164
–166
–168
fDAC = 737.28MHz
fDAC = 983.04MHz
fDAC = 1228.8MHz
fDAC = 1474.56MHz
fDAC = 737.28MHz
fDAC = 983.04MHz
fDAC = 1228.8MHz
fDAC = 1474.56MHz
–10
–20
–30
–40
–50
–60
–70
–80
–90
0
100
200
300
400
500
600
700
800
0
100
200
300
400
500
600
700
800
fOUT (MHz)
fOUT (MHz)
Figure 10. Two-Tone Third IMD vs. fOUT over fDAC
Figure 13. Single-Tone (0 dBFS) NSD vs. fOUT over fDAC
–152
–154
–156
–158
–160
–162
–164
–166
–168
0
–20
0dBFS
0dBFS
–6dBFS
–9dBFS
–6dBFS
–12dBFS
–16dBFS
–40
–60
–80
–100
–120
0
100
200
300
400
500
600
700
800
0
100
200
300
400
500
600
700
800
fOUT (MHz)
fOUT (MHz)
Figure 14. Single-Tone NSD vs. fOUT over Digital Back Off,
DAC = 1474.56 MHz
Figure 11. Two-Tone Third IMD vs. fOUT over Digital Back Off,
DAC = 1474.56 MHz
f
f
Rev. 0 | Page 13 of 64
AD9142
Data Sheet
–150
–152
–154
–156
–158
–160
–162
–164
–166
–168
–60
–65
–70
–75
–80
–85
–90
737.2MHz
fDAC = 1474.56MHz, PLL OFF, 0dBFS
fDAC = 1474.56MHz, PLL ON, 0dBFS
fDAC = 1228.8MHz, PLL OFF, 0dBFS
fDAC = 1228.8MHz, PLL ON, 0dBFS
983.04MHz
1228.8MHz
1474.56MHz
–170
0
100
200
300
400
500
600
700
800
0
100
200
300
400
500
600
700
800
fOUT (MHz)
fOUT (MHz)
Figure 15. 1C WCDMA NSD vs. fOUT, over fDAC
Figure 18. 1C WCDMA 2nd Adjacent ACLR vs. fOUT, PLL On and Off
–150
–152
–154
–156
–158
–160
–162
–164
–166
PLL OFF
PLL ON
–168
0
100
200
300
400
500
600
700
800
fOUT (MHz)
Figure 16. Single-Tone NSD vs. fOUT, fDAC = 1474.28 MHz, PLL On and Off
Figure 19. Two-Tone Third IMD Performance,
IF = 280 MHz, fDAC = 1474.28 MHz
–60
fDAC = 1474.56MHz, PLL OFF, 0dBFS
fDAC = 1474.56MHz, PLL ON, 0dBFS
fDAC = 1228.8MHz, PLL OFF, 0dBFS
fDAC = 1228.8MHz, PLL ON, 0dBFS
–65
–70
–75
–80
–85
0
100
200
300
400
500
600
700
800
fOUT (MHz)
Figure 17. 1C WCDMA 1st Adjacent ACLR vs. fOUT, PLL On and Off
Figure 20. 1C WCDMA ACLR Performance, IF = 280 MHz, fDAC = 1474.28 MHz
Rev. 0 | Page 14 of 64
Data Sheet
AD9142
1.4
1.2
1.0
0.8
0.6
0.4
0.2
0
2× INTERPOLATION
4× INTERPOLATION
8× INTERPOLATION
0
200
400
600
800 1000 1200 1400 1600 1800
fDAC (MHz)
Figure 21. Single-Tone fDAC = 1474.56 MHz,
OUT = 280 MHz, −14 dBFS
Figure 24. Total Power Consumption vs. fDAC over Interpolation
f
450
2× INTERPOLATION
4× INTERPOLATION
8× INTERPOLATION
400
350
300
250
200
150
100
50
0
0
200
400
600
800 1000 1200 1400 1600 1800
fDAC (MHz)
Figure 22. 4C WCDMA ACLR Performance,
IF = 280 MHz, fDAC = 1474.28 MHz
Figure 25. DVDD18 Current vs. fDAC over Interpolation
0.30
0.25
0.20
0.15
0.10
0.05
0
NCO
INV SINC
DIG GAIN, PHASE, AND OFFSET
0
200
400
600
800
1000
1200
1400
1600
fDAC (MHz)
Figure 23. Single-Tone SFDR fDAC = 1474.56 MHz,
4× Interpolation, fOUT = 10 MHz, −14 dBFS
Figure 26. DVDD18 Current vs. fDAC over Digital Functions
Rev. 0 | Page 15 of 64
AD9142
Data Sheet
250
200
150
100
50
CVDD18 PLL OFF
AVDD33
CVDD18 PLL ON
0
0
200
400
600
800
1000
1200
1400
1600
fDAC (MHz)
Figure 27. CVDD18, AVDD33 Current vs. fDAC
Rev. 0 | Page 16 of 64
Data Sheet
AD9142
TERMINOLOGY
Integral Nonlinearity (INL)
Settling Time
INL is the maximum deviation of the actual analog output from
the ideal output, determined by a straight line drawn from zero
scale to full scale.
Settling time is the time required for the output to reach and
remain within a specified error band around its final value,
measured from the start of the output transition.
Differential Nonlinearity (DNL)
Spurious Free Dynamic Range (SFDR)
DNL is the measure of the variation in analog value, normalized
to full scale, associated with a 1 LSB change in digital input code.
SFDR is the difference, in decibels, between the peak amplitude
of the output signal and the peak spurious signal within the dc
to Nyquist frequency of the DAC. Typically, the interpoloation
filters reject energy in this band. This specification, therefore,
defines how well the interpolation filters work and the effect of
other parasitic coupling paths on the DAC output.
Offset Error
Offset error is the deviation of the output current from the ideal
of 0 mA. For IOUT1P, 0 mA output is expected when all inputs
are set to 0. For IOUT1N, 0 mA output is expected when all
inputs are set to 1.
Signal-to-Noise Ratio (SNR)
SNR is the ratio of the rms value of the measured output signal
to the rms sum of all other spectral components below the Nyquist
frequency, excluding the first six harmonics and dc. The value
for SNR is expressed in decibels.
Gain Error
Gain error is the difference between the actual and ideal output
span. The actual span is determined by the difference between
the output when all inputs are set to 1 and the output when all
inputs are set to 0.
Interpolation Filter
If the digital inputs to the DAC are sampled at a multiple rate of
Output Compliance Range
f
DATA (interpolation rate), a digital filter can be constructed that
The output compliance range is the range of allowable voltage
at the output of a current output DAC. Operation beyond the
maximum compliance limits can cause either output stage
saturation or breakdown, resulting in nonlinear performance.
has a sharp transition band near fDATA/2. Images that typically
appear around fDAC (output data rate) can be greatly suppressed.
Adjacent Channel Leakage Ratio (ACLR)
ACLR is the ratio in decibels relative to the carrier (dBc) between
the measured power within a channel relative to its adjacent
channel.
Temperature Drift
Temperature drift is specified as the maximum change from
the ambient (25°C) value to the value at either TMIN or TMAX
.
For offset and gain drift, the drift is reported in ppm of full-
scale range (FSR) per degree Celsius. For reference drift, the
drift is reported in ppm per degree Celsius.
Complex Image Rejection
In a traditional two-part upconversion, two images are created
around the second IF frequency. These images have the effect
of wasting transmitter power and system bandwidth. By placing
the real part of a second complex modulator in series with the
first complex modulator, either the upper or lower frequency
image near the second IF can be rejected.
Power Supply Rejection (PSR)
PSR is the maximum change in the full-scale output as the
supplies are varied from minimum to maximum specified
voltages.
Rev. 0 | Page 17 of 64
AD9142
Data Sheet
SERIAL PORT OPERATION
The serial port is a flexible, synchronous serial communications
port that allows easy interfacing to many industry standard micro-
controllers and microprocessors. The serial I/O is compatible
with most synchronous transfer formats, including both the
Motorola SPI and Intel® SSR protocols. The interface allows
read/write access to all registers that configure the AD9142.
MSB-first or LSB-first transfer formats are supported. The serial
port interface is a 3-wire only interface. The input and output
share a single pin input/output (SDIO).
A14 to A0 (Bit 14 to Bit 0 of the instruction word) determine
the register that is accessed during the data transfer portion of
the communication cycle. For multibyte transfers, A14 is the
starting address; the device generates the remaining register
addresses based on the SPI_LSB_FIRST bit.
SERIAL PORT PIN DESCRIPTIONS
Serial Clock (SCLK)
The serial clock pin synchronizes data to and from the device
and runs the internal state machines. The maximum frequency
of SCLK is 40 MHz. All data input is registered on the rising edge
of SCLK. All data is driven out on the falling edge of SCLK.
54
53
52
CS
SPI
PORT
SCLK
SDIO
CS
Chip Select (
)
Figure 28. Serial Port Interface Pins
CS
is an active low input that starts and gates a communication
cycle. It allows more than one device to be used on the same serial
communications line. The SDIO pins enter a high impedance
There are two phases to a communication cycle with the AD9142.
Phase 1 is the instruction cycle (the writing of an instruction
byte into the device), coincident with the first 16 SCLK rising
edges. The instruction word provides the serial port controller
with information regarding the data transfer cycle, Phase 2, of
the communication cycle. The Phase 1 instruction word defines
whether the upcoming data transfer is a read or write, along with
the starting register address for the following data transfer.
CS
state when the
input is high. During the communication
should stay low.
CS
cycle,
Serial Data I/O (SDIO)
The SDIO pin is a bidirectional data line.
SERIAL PORT OPTIONS
CS
A logic high on the
pin, followed by a logic low, resets the
The serial port can support both MSB-first and LSB-first data
formats. This functionality is controlled by the SPI_LSB_FIRST bit
(Register 0x00, Bit 6). The default is MSB first (LSB_FIRST = 0).
serial port timing to the initial state of the instruction cycle.
From this state, the next 16 rising SCLK edges represent the
instruction bits of the current I/O operation.
When SPI_LSB_FIRST = 0 (MSB first), the instruction and data
bits must be written from MSB to LSB. Multibyte data transfers
in MSB-first format start with an instruction word that includes the
register address of the most significant data byte. Subsequent data
bytes must follow from high address to low address. In MSB-first
mode, the serial port internal word address generator decrements
for each data byte of the multibyte communication cycle.
The remaining SCLK edges are for Phase 2 of the communication
cycle. Phase 2 is the actual data transfer between the device and
the system controller. Phase 2 of the communication cycle is a
transfer of one data byte. Registers change immediately upon
writing to the last bit of each transfer byte, except for the frequency
tuning word and NCO phase offsets, which change only when
the frequency tuning word (FTW) update bit is set.
When SPI_LSB_FIRST = 1 (LSB first), the instruction and data
bits must be written from LSB to MSB. Multibyte data transfers
in LSB-first format start with an instruction word that includes the
register address of the least significant data byte. Subsequent data
bytes must follow from low address to high address. In LSB-first
mode, the serial port internal word address generator increments
for each data byte of the multibyte communication cycle.
DATA FORMAT
The instruction byte contains the information shown in Table 10.
Table 10. Serial Port Instruction Word
I15 (MSB)
I[14:0]
R/W
A[14:0]
If the MSB-first mode is active, the serial port controller data
address decrements from the data address written toward 0x00
for multibyte I/O operations. If the LSB-first mode is active, the
serial port controller data address increments from the data
address written toward 0xFF for multibyte I/O operations.
W
R/ (Bit 15 of the instruction word) determines whether a read
or a write data transfer occurs after the instruction word write.
Logic 1 indicates a read operation and Logic 0 indicates a write
operation.
Rev. 0 | Page 18 of 64
Data Sheet
AD9142
tDCSB
tSCLK
INSTRUCTION CYCLE
DATA TRANSFER CYCLE
CS
CS
tPWH
tPWL
SCLK
SCLK
tDS
tDH
SDIO
R/W A14 A13
A3 A2 A1 A0 D7 D6 D5
D3 D2 D1 D0
0 0 0 0
N
N
N
SDIO
INSTRUCTION BIT 15 INSTRUCTION BIT 14
Figure 29. Serial Register Interface Timing, MSB First
Figure 31. Timing Diagram for Serial Port Register Write
CS
INSTRUCTION CYCLE
DATA TRANSFER CYCLE
CS
SCLK
SCLK
tDV
SDIO
DATA BIT n
DATA BIT n – 1
SDIO
A0 A1 A2
A12 A13 A14 R/W D00 D10 D20
D4N D5N D6N D7N
Figure 32. Timing Diagram for Serial Port Register Read
Figure 30. Serial Register Interface Timing, LSB First
Rev. 0 | Page 19 of 64
AD9142
Data Sheet
DATA INTERFACE
LVDS INPUT DATA PORTS
BYTE INTERFACE MODE
In byte mode, the required sequence of the input data stream is
I[15:8], I[7:0], Q[15:8], Q[7:0]. A frame signal is required to
align the order of input data bytes properly. Time align both the
DCI signal and frame signal with the data. The rising edge of
the frame indicates the start of the sequence. The frame can be
either a one shot or periodical signal as long as its first rising
edge is correctly captured by the device. For a one shot frame,
the frame pulse needs to hold at high for at least one DCI cycle.
For a periodical frame, the frequency needs to be
The AD9142 has a 16-bit LVDS bus that accepts 16-bit I and Q
data either in word wide (16-bit) or byte wide (8-bit) formats. In
the word wide interface mode, the data is sent over the entire
16-bit data bus. In the byte wide interface mode, the data is sent
over the lower 8-bit (D7 to D0) LVDS bus. Table 11 lists the pin
assignment of the bus and the SPI register configuration for
each mode.
Table 11. LVDS Data Input Modes
Interface Mode Pin Assignment SPI Register Configuration
f
DCI/(2 × n)
Word
Byte
D15 to D0
D7 to D0
Register 0x26, Bit 0 = 0
Register 0x26, Bit 0 = 1
where n is a positive integer, that is, 1, 2, 3, …
Figure 34 is an example of signal timing in byte mode.
WORD INTERFACE MODE
BYTE MODE
In word mode, the digital clock input (DCI) signal is a reference
bit that generates a double data rate (DDR) data sampling clock.
Time align the DCI signal with the data. The IDAC data follows
the rising edge of the DCI, and the QDAC data follows the
falling edge of the DCI, as shown in Figure 33.
I
I
Q
Q
0[7:0]
INPUT DATA[7:0]
0[15:8]
0[7:0]
0[15:8]
DCI
FRAME
WORD MODE
Figure 34. Timing Diagram for Byte Mode
I
Q
I
Q
1
INPUT DATA[15:0]
0
0
1
DATA INTERFACE CONFIGURATION OPTIONS
To provide more flexibility for the data interface, some
additional options are listed in Table 12.
DCI
Figure 33. Timing Diagram for Word Mode
Table 12. Data Interface Configuration Options
Register 0x26
Function
Data Format (Bit 7)
Select between binary and twos
complement formats.
Data Pairing (Bit 6)
Data Bus Invert (Bit 5)
Indicate I/Q data pairing on data input.
This allows the I and Q data that is
received to be paired in various ways.
Swaps the bit order of the data input
port. Remaps the input data from
D[15:0] to D[0:15].
Rev. 0 | Page 20 of 64
Data Sheet
AD9142
LVDS Input Level Requirements
receiver requires a minimum of 225 mV swing at its input.
Figure 35 shows the LVDS input configuration and the required
swing levels. Because the DCI is typically generated from the
same bank as the data in the data source, it is recommended
that the output swing of the LVDS driver be larger than the
required DCI input level, thus meeting both input data and DCI
requirements.
There are two types of LVDS receivers in the AD9142. The
16-bit data bus and the frame input share the same LVDS
receiver design. The DCI uses a different LVDS design. The
main difference between the two LVDS receivers is the required
input differential swing level. The data bus and frame receiver
require a minimum of 100 mV swing at the input. The DCI
AD9142
+
DATA
RECEIVER
TO INTERNAL
DIGITAL
100Ω
Dn
DnP
–
DnN
GND
V
= (V P + V N)/2 = 1.2V
CM
IN
IN
+
DCI
RECEIVER
TO INTERNAL
DIGITAL
100Ω
DCI
DCIP
–
DCIN
GND
AD9142 LVDS INPUT CONFIGURATION
1.25V
1.15V
DCIP
DCIN
DnP
DnN
1.32V
1.1V
+225mV
0V
+100mV
0V
–100mV
DCI
Dn
–225mV
AD9142 DATA AND
FRAME INPUT LVDS LEVEL
AD9142 DCI INPUT LVDS LEVEL
Figure 35. Data Interface Voltage Swing Requirements
Rev. 0 | Page 21 of 64
AD9142
Data Sheet
INTERFACE DELAY LINE
Interface Timing Requirements
A four-tap delay line is provided for the user to adjust the
timing between the data bus and the DCI. Table 13 specifies the
setup and hold times for each delay tap.
The following example illustrates how to calculate the optimal
delay at the data source to achieve the best sampling timing in
the delay line-based mode:
There is a fixed 1.9 ns delay on the DCI when the delay line is
enabled. Each tap adds a nominal delay of 300 ps to the fixed
delay. To achieve the best timing margin, that is, to center the
setup and hold window in the middle of the data eye, the user
may need to add a delay on the data bus with respect to the DCI
in the data source. Figure 36 is an example of calculating the
optimal external delay.
•
•
f
DCI = 200 MHz
Delay setting = 0
The shadow area in Figure 36 is the interface setup and hold
time window set to 0. To optimize the interface timing, this
window must be placed in the middle of the data transitions.
Because the input is double data rate, the available data period
is 2.5 ns. Therefore, the optimal data bus delay, with respect to
the DCI at the data source, can be calculated as
Table 13. Setup and Hold Times
Delay Setting
Register 0x5E[7:0]
Register 0x5F[2:0]
tS (ns)1
tH (ns)
|tS + tH| (ns)
0
1
2
3
t DATAPERIOD
(|t S | + | t H |)
0x00
0x0
−1.25
2.51
1.26
0x07
0x0
−1.50
2.82
1.32
0x7F
0x0
−1.70
3.23
1.53
0xFF
0x5
−1.93
3.64
1.71
t DELAY
=
−
=1.88 −1.25 = 0.63ns
2
2
SPI Sequence to Enable Delay Line-Based Mode
It is recommended that the following SPI sequence be used to
enable the delay line-based mode:
1 The negative sign indicates the direction of the setup time. The setup time is
defined as positive when it is on the left side of the clock edge and negative
when it is on the right side of the clock edge.
1. 0x79 → 0x18 /* Configure Data Interface */
2. 0x5E → 0x00 /* Delay setting 0 */
0x5F → 0x00
3. 0x5F[3] → 1b /* Enable the delay line */
tDELAY = 0.63ns
tDATA PERIOD = 2.5ns
INPUT DATA [15:0]
WITH OPTIMIZED DELAY
DATA EYE
|tS| = 1.25ns
|tH| = 2.51ns
DCI = 200MHz
NO DATA TRANSITION
Figure 36. Example of Interfacing Timing in the Delay Line-Based Mode
Rev. 0 | Page 22 of 64
Data Sheet
AD9142
FIFO OPERATION
As is shown in the Data Interface section, the AD9142 adopts
source synchronous clocking in the data receiver. The nature of
source synchronous clocking is the creation of a separate clock
domain at the receiving device. In the DAC, it is the DAC clock
domain, that is, the DACCLK. Therefore, there are two clock
domains inside of the DAC: the DCI and the DACCLK. Often,
these two clock domains are not synchronous, requiring an
additional stage to adjust the timing for proper data transfer. In
the AD9142, a FIFO stage is inserted between the DCI and
DACCLK domains to transfer the received data into the core
clock domain (DACCLK) of the DAC.
is read from the FIFO register, which is determined by the read
pointer, and fed into the digital datapath. The value of the read
pointer is incremented every time data is read into the datapath
from the FIFO. The FIFO pointers are incremented at the data
rate, which is the DACCLK rate divided by the interpolation rate.
Valid data is transmitted through the FIFO as long as the FIFO
does not overflow (full) or underflow (empty). An overflow or
underflow condition occurs when the write pointer and read
pointer point to the same FIFO slot. This simultaneous access of
data leads to unreliable data transfer through the FIFO and must be
avoided.
The AD9142 contains a 2-channel, 16-bit wide, 8-word deep
FIFO. The FIFO acts as a buffer that absorbs timing variations
between the two clock domains. The timing budget between the
two clock domains in the system is significantly relaxed due to
the depth of the FIFO.
Normally, data is written to and read from the FIFO at the same
rate to maintain a constant FIFO depth. If data is written to the
FIFO faster than data is read, the FIFO depth increases. If data
is read from the FIFO faster than data is written to it, the FIFO
depth decreases. For optimal timing margin, maintain the FIFO
depth near half full (a difference of four between the write
pointer and read pointer values). The FIFO depth represents the
FIFO pipeline delay and is part of the overall latency of the
AD9142.
Figure 37 shows the block diagram of the datapath through the
FIFO. The input data is latched into the device, formatted, and
then written into the FIFO register, which is determined by the
FIFO write pointer. The value of the write pointer is incremented
every time a new word is loaded into the FIFO. Meanwhile, data
FIFO WRITE CLOCK
FIFO READ CLOCK
DACCLK
I DAC
÷INT
FIFO
I[15:0]
I[15:0]
FIFO SLOT 0
I DATA PATH
FIFO SLOT 1
FIFO SLOT 2
FIFO SLOT 3
FIFO SLOT 4
FIFO SLOT 5
FIFO SLOT 6
FIFO SLOT 7
RETIMED DCI
DCI
READ
POINTER
DATA
RECEIVER
DATA
FORMAT
LATCHED
DATA [15:0]
INPUT DATA [15:0]
FRAME
I/Q[31:0]
Q[15:0]
Q[15:0]
WRITE
POINTER
Q DATA PATH
Q DAC
RESET
LOGIC
SPI FIFO RESET
REG 0x25[0]
FIFO LEVEL
FIFO LEVEL REQUEST
REG 0x23
Figure 37. Block Diagram of FIFO
Rev. 0 | Page 23 of 64
AD9142
Data Sheet
RESETTING THE FIFO
SERIAL PORT INITIATED FIFO RESET
Upon power-on of the device, the read and write pointers start
to roll around the FIFO from an arbitrary slot; consequently, the
FIFO depth is unknown. To avoid a concurrent read and write
to the same FIFO address and to assure a fixed pipeline delay
from power-on to power-on, it is important to reset the FIFO
pointers to a known state each time the device powers on or
wakes up. This state is specified in the requested FIFO level
(FIFO depth and FIFO level are used interchangeably in this
document), which consists of two parts: the integral FIFO level
and the fractional FIFO level.
A SPI initiated FIFO reset is the most common method to reset
the FIFO. To initialize the FIFO level through the serial port,
toggle FIFO_SPI_RESET_REQUEST (Register 0x25[0]) from
0 to 1 and back to 0. When the write to this register is complete,
the FIFO level is initialized to the requested FIFO level and the
readback of FIFO_SPI_RESET_ACK (Register 0x25[1]) is set
to 1. The FIFO level readback, in the same format as the FIFO
level request, should be within 1 DACCLK cycle of the
requested level. For example, if the requested value is 0x40 in
4× interpolation, the readback value should be one of the
following: 0x33, 0x40, or 0x41. The range of 1 DACCLK cycle
indicates the default DAC latency uncertainty from power-on
to power-on without turning on synchronization.
The integer FIFO level represents the difference of the states
between the read and write point in the unit of input data period
(1/fDATA). The fractional FIFO level represents the difference of
the FIFO pointers smaller than the input data period. The
resolution of the fractional FIFO level is the input data period
divided by the interpolation ratio and, thus, it is equal to one
DACCLK cycle.
The recommended procedure for a serial port FIFO reset is as
follows:
1. Configure the DAC in the desired interpolation mode
(Register 0x28[1:0]).
The exact FIFO level, that is, the FIFO latency, can be calculated
by
2. Ensure that the DACCLK and DCI are running and stable
at the clock inputs.
3. Program Register 0x23 to the customized value, if the
desired value is not 0x40.
4. Request the FIFO level reset by setting Register 0x25[0] to 1.
5. Verify that the part acknowledges the request by setting
Register 0x25[1] to 1.
6. Remove the request by setting Register 0x25[0] to 0.
7. Verify that the part drops the acknowledge signal by setting
Register 0x25[1] to 0.
8. Read back Register 0x24 multiple times to verify that the
actual FIFO level is set to the requested level and that the
readback values are stable. By design, the readback should
be within 1 DACCLK around the requested level.
FIFO Latency = Integral Level + Fractional Level
Because the FIFO has eight data slots, there are eight possible
FIFO integral levels. The maximum supported interpolation
rate in the AD9142 is 8× interpolation. Therefore, there are eight
possible FIFO fractional levels. Two 3-bit registers in Register
0x23 are assigned to represent each level separately; Bits[6:4]
represent the FIFO integral level and Bits[2:0] represent the FIFO
fractional level. For example, if the interpolation rate is 4× and
the desired total FIFO depth is 4.5 input data periods, set the
FIFO_LEVEL_CONFIG (Register 0x23) to 0x42 (4 here means
four data cycles and 2 means two DAC cycles, which is half of a
data cycle). Note that there are only four possible fractional
levels in the case of 4× interpolation. Table 14 shows additional
examples of configuring the desired FIFO level in various
interpolation rate modes.
FRAME INITIATED FIFO RESET
The frame input has two functions. One function is to indicate
the beginning of a byte stream in the byte interface mode, as
discussed in the Data Interface section. The other function is
to initialize the FIFO level by asserting the frame signal high
for at least the time interval required to load complete data to
the I and QDACs. This corresponds to one DCI period in word
mode and two DCI periods in byte mode. Note that this
requirement of the frame pulse length is longer than that of the
frame signal when it serves only to assemble the byte stream.
The device accepts either a continuous frame or a one shot
frame signal.
Table 14. Examples of FIFO Level Configuration
Inter-
Example
polation FIFO Level Integer Level
Fractional Level
(Register 0x23[6:4]) (Register 0x23[2:0])
Rate
2×
4×
(1/fDATA)
3 + 1/2
4 + 1/4
4 + 3/8
3
4
4
1
1
3
8×
By default, the FIFO level is 4.0. It can be programmed to any
allowed value from 0.0 to 7.x. The maximum allowed number
for x is the interpolation rate minus 1. For example, in 8×
interpolation, the maximum allowed for x is 7.
In the continuous reset mode, the FIFO responds to every valid
frame pulse and resets itself. In the one shot reset mode, the
FIFO responds only to the first valid frame pulse after the
FRAME_RESET_MODE bits (Register 0x22[1:0]) are set.
Therefore, even with a continuous frame input, the FIFO resets
one time only; this prevents the FIFO from toggling between
the two states from periodic resets. The one shot frame reset
mode is the default and the recommended mode.
The following two ways are used to reset the FIFO and initialize
the FIFO level:
•
•
Serial port (SPI) initiated FIFO reset.
Frame initiated FIFO reset.
Rev. 0 | Page 24 of 64
Data Sheet
AD9142
The recommended procedure for a frame initiated FIFO reset is
as follows:
Monitoring the FIFO Status
The real-time FIFO status can be monitored from the SPI
Register 0x24 and reflects the real-time FIFO depth after a FIFO
reset. Without timing drifts in the system, this readback should
not change from that which resulted from the FIFO reset. When
there is a timing drift or other abnormal clocking situation, the
FIFO level readback can change. However, as long as the FIFO
does not overflow or underflow, there is no error in data trans-
mission. Three status bits in Register 0x06, Bits[2:0], indicate if
there are FIFO underflows, overflows, or similar situations. The
status of the three bits can be latched and used to trigger
1. Configure the DAC in the desired interpolation mode
(Register 0x28[1:0]).
2. Ensure that the DACCLK and DCI are running and stable at
the clock inputs.
3. Program Register 0x23 to the customized value, if the
desired value is not 0x40.
4. Configure the FRAME_RESET_MODE bits (Register
0x22[1:0])to 00b.
5. Choose whether continuous or one shot mode is desired by
writing 0 or 1 to EN_CON_FRAME_RESET (Register
0x22[2]).
6. Toggle the frame input from 0 to 1 and back to 0. The pulse
width needs to be longer than the minimum requirement.
a. If the frame input is a continuous clock, turn on the
signal.
IRQ1
IRQ2
hardware interrupts,
and
. To enable latching and
interrupts, configure the corresponding bits in Register 0x03
and Register 0x04.
7. Read back FRAME_RESET_ACK, Register 0x22[3], to
verify that the reset is complete.
8. Read back Register 0x24 multiple times to verify that the
actual FIFO level is set to the requested level and the
readback values are stable. By design, the readback should be
within 1 DACCLK around the requested level.
Rev. 0 | Page 25 of 64
AD9142
Data Sheet
DIGITAL DATAPATH
INPUT
DIGITAL GAIN
AND PHASE
AND OFFSET
ADJUSTMENT
POWER
DETECTION
AND
COARSE AND
FINE
MODULATION
INV
SINC
HB1
HB2
HB3
PROTECTION
Figure 38. Block Diagram of Digital Datapath
0.02
The block diagram in Figure 38 shows the functionality of the
digital datapath. The digital processing includes
0
–0.02
–0.04
–0.06
–0.08
–0.10
•
•
•
An input power detection block
Three half-band interpolation filters
A quadrature modulator consisting of a fine resolution
NCO and an fS/4 coarse modulation block
An inverse sinc filter
•
•
A gain and phase and offset adjustment block
The interpolation filters accept I and Q data streams and
process them as two independent data streams, whereas the
quadrature modulator and phase adjustment block accepts I
and Q data streams as a quadrature data stream. Therefore,
quadrature input data is required when digital modulation and
phase adjustment functions are used.
0
0.05 0.10 0.15 0.20 0.25 0.30 0.35 0.40 0.45
FREQUENCY (Hz)
Figure 39. Pass-Band Detail of 2× Mode
10
0
INTERPOLATION FILTERS
The transmit path contains three interpolation filters. Each of
the three interpolation filters provides a 2× increase in output data
rate and a low-pass function. The half-band (HB) filters are cas-
caded to provide 4× or 8× interpolation ratios.
–10
–20
–30
–40
–50
–60
–70
–80
–90
–100
The AD9142 provides three interpolation modes (see Table 6).
Each mode offers a different usable signal bandwidth in an
operating mode. Which mode to select depends on the required
signal bandwidth and the DAC update rate. Refer to Table 6 for
the maximum speed and signal bandwidth of each interpolation
mode.
0
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
2.0
The usable bandwidth is defined as the frequency band over
which the filters have a pass-band ripple of less than 0.001 dB
and a stop band rejection of greater than 85 dB.
FREQUENCY (Hz)
Figure 40. All-Band Response of 2× Mode
2× Interpolation Mode
Figure 39 and Figure 40 show the pass-band and all-band filter
response for 2× mode. Note that the transition from the
transition band to the stop band is much sharper than the tran-
sition from the pass band to the transition band. Therefore, when
the desired output signal moves out of the defined pass band,
the signal image, which is supposed to be suppressed by the stop
band, grows faster than the droop of the signal itself due to the
degraded pass-band flatness. In cases where the degraded image
rejection is acceptable or can be compensated by the analog
low-pass filter at the DAC output, it is possible to let the output
signal extend beyond the specified usable signal bandwidth.
Rev. 0 | Page 26 of 64
Data Sheet
AD9142
10
0
4× Interpolation Mode
Figure 41 and Figure 42 show the pass-band and all-band filter
–10
–20
–30
–40
–50
–60
–70
–80
–90
–100
responses for 4× mode.
0.02
0
–0.02
–0.04
–0.06
–0.08
–0.10
0
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
2.0
FREQUENCY (Hz)
Figure 44. All-Band Response of 8× Mode
0
0.05 0.10 0.15 0.20 0.25 0.30 0.35 0.40 0.45
FREQUENCY (Hz)
Table 15. Half-Band Filter 1 Coefficient
Lower Coefficient
Upper Coefficient
H(55)
H(54)
H(53)
H(52)
H(51)
H(50)
H(49)
H(48)
H(47)
H(46)
H(45)
H(44)
H(43)
H(42)
H(41)
H(40)
H(39)
H(38)
H(37)
H(36)
H(35)
H(34)
H(33)
H(32)
H(31)
H(30)
H(29)
Integer Value
Figure 41. Pass-Band Detail of 4× Mode
H(1)
H(2)
H(3)
H(4)
H(5)
H(6)
H(7)
H(8)
−4
0
+13
0
−32
0
+69
0
−134
0
+239
0
−401
0
+642
0
−994
0
+1512
0
10
0
–10
–20
–30
–40
–50
–60
–70
–80
–90
–100
H(9)
H(10)
H(11)
H(12)
H(13)
H(14)
H(15)
H(16)
H(17)
H(18)
H(19)
H(20)
H(21)
H(22)
H(23)
H(24)
H(25)
H(26)
H(27)
H(28)
0
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
2.0
FREQUENCY (Hz)
Figure 42. All-Band Response of 4× Mode
8× Interpolation Mode
Figure 43 and Figure 44 show the pass-band and all-band filter
responses for 8× mode. The maximum DAC update rate is 1.6 GHz,
and the maximum input data rate that is supported in this mode is
200 MHz (1.6 GHz/8).
−2307
0
+3665
0
−6638
0
+20,754
+32,768
0.02
0
–0.02
–0.04
–0.06
–0.08
–0.10
0
0.05 0.10 0.15 0.20 0.25 0.30 0.35 0.40 0.45
FREQUENCY (Hz)
Figure 43. Pass-Band Detail of 8× Mode
Rev. 0 | Page 27 of 64
AD9142
Data Sheet
I DATA OUT
I DATA IN
Table 16. Half-Band Filter 2 Coefficient
Lower Coefficient
Upper Coefficient
Integer Value
H(1)
H(2)
H(3)
H(4)
H(5)
H(6)
H(7)
H(8)
H(9)
H(10)
H(11)
H(12)
H(23)
H(22)
H(21)
H(20)
H(19)
H(18)
H(17)
H(16)
−2
0
+17
0
−75
0
+238
0
−660
0
+2530
+4096
FTW[31:0]
COSINE
~
SINE
NCO
PHASE[15:0]
Q DATA IN
Q DATA OUT
Figure 45. NCO Modulator Block Diagram
H(15)
H(14)
H(13)
The NCO modulator mixes the carrier signal generated by the
NCO with the I and Q signals. The NCO produces a quadrature
carrier signal to translate the input signal to a new center fre-
quency. A complex carrier signal is a pair of sinusoidal waveforms
of the same frequency, offset 90 degrees from each other. The
frequency of the complex carrier signal is set via NCO_FREQ_
TUNING_WORD[31:0] in Register 0x31 through Register 0x34.
Table 17. Half-Band Filter 3 Coefficient
Lower Coefficient
Upper Coefficient
Integer Value
H(1)
H(2)
H(3)
H(4)
H(5)
H(6)
H(11)
H(10)
H(9)
H(8)
H(7)
+29
0
−214
0
+1209
+2048
The NCO operating frequency, fNCO, is always equal to fDAC, the
DACCLK frequency. The frequency of the complex carrier
signal can be set from dc up to 0.5 × fNCO
.
The frequency tuning word (FTW) is in twos complement
format. It can be calculated as
fDAC
2
fDAC
2
DIGITAL MODULATION
−
≤ fCARRIER
≤
The AD9142 provides two modes to modulate the baseband
quadrature signal to the desired DAC output frequency.
fCARRIER
FTW =
×
(
232
)
(
fCARRIER ≥ 0
)
fDAC
•
•
Coarse (fS/4) modulation
Fine (NCO) modulation
fCARRIER
FTW = (1−
)× (232 )
(
fCARRIER < 0
)
fDAC
fS/4 Modulation
The generated quadrature carrier signal is mixed with the I and
Q data. The quadrature products are then summed into the I
and Q data paths, as shown in Figure 45.
The fS/4 modulation is a convenient and low power modulation
mode to translate the input baseband frequency to a fixed fS/4
IF frequency, fS being the DAC sampling rate. When modulation
frequencies other than this frequency are required, the NCO
modulation mode must be used.
Updating the Frequency Tuning Word
The frequency tuning word registers are not updated immediately
upon writing, as are other configuration registers. Similar to
FIFO reset, the NCO update can be triggered in two ways.
NCO Modulation
The NCO modulation mode makes use of a numerically
controlled oscillator (NCO), a phase shifter, and a complex
modulator to provide a means for modulating the signal by a
programmable carrier signal. A block diagram of the digital
modulator is shown in Figure 45. The NCO modulation allows
the DAC output signal to be placed anywhere in the output
spectrum with very fine frequency resolution.
•
•
SPI initiated update
Frame initiated update
Rev. 0 | Page 28 of 64
Data Sheet
AD9142
quadrature gain and phase adjust values optimizes image
rejection in single sideband radios.
SPI Initiated Update
In the SPI initiated update method, the user simply toggles
Register 0x30[0] (NCO_SPI_UPDATE_REQ) after configuring
the NCO settings. The NCO is updated on the rising edge (from
0 to 1) in this bit. Register 0x30[1] (NCO_SPI_UPDATE_ACK)
goes high when the NCO is updated. A falling edge (from 1 to
0) in Register 0x30[0] clears Bit 1 of Register 0x30 and prepares
the NCO for the next update operation. This update method is
recommended when there is no requirement to align the DAC
output from multiple devices because SPI writes to multiple
devices are asynchronous.
Quadrature Gain Adjustment
Ordinarily, the I and Q channels have the same gain or signal
magnitude. The quadrature gain adjustment is used to balance the
gain between the I and Q channels. The digital gain of the I and Q
channels can be adjusted independently through two 6-bit registers,
IDAC_GAIN_ADJ (Register 0x3F[5:0]) and QDAC_GAIN_ADJ
(Register 0x40[5:0]). The range of the adjustment is [0, 2] or [−∞,
6 dB] with a step size of 2−5 (−30 dB). The default setting is 0x20,
corresponding to a gain equal to 1 or 0 dB.
Frame Initiated Update
Quadrature Phase Adjustment
When the DAC output from multiple devices needs to be well
aligned with NCO turned on, the frame initiated update is
recommended. In this method, the NCOs from multiple devices
are updated at the same time upon the rising edge of the frame
signal. To use this update method, the FRAME_RESET_MODE
(Register 0x22[1:0]) needs to be set in NCO only or FIFO and
NCO, depending on whether FIFO reset is needed at the same
time. The second step is to ensure that the reset mode is in one
shot mode (EN_CON_FRAME_RESET, Register 0x22[2] = 0).
When this second step is completed, the NCO waits for a valid
frame pulse and updates the FTW accordingly. The user can verify
if the frame pulse is correctly received by reading Register 0x30[6]
(NCO_FRAME_ UPDATE_ACK) wherein a 1 indicates a
complete update operation. See the FIFO Operation section for
information to generate a valid frame pulse.
Under normal circumstances, I and Q channels have an angle of
precisely 90 degrees between them. The quadrature phase adjust-
ment is used to change the angle between the I and Q channels.
IQ_PHASE_ADJ[12:0] (Register 0x37 and Register 0x38) provide
an adjustment range of 14 degrees with a resolution of 0.0035
degrees. If the original angle is precisely 90 degrees, setting
IQ_PHASE_ADJ[12:0] to 0x0FFF adds approximately 14 degrees
between I and QDAC outputs, creating an angle of 104 degrees
between the channels. Likewise, if the original angle is precisely
90 degrees, setting IQ_PHASE_ADJ[12:0] to 0x1000 adds
approximately −14 degrees between the I and QDAC outputs,
creating an angle of 76 degrees between the channels.
DC OFFSET ADJUSTMENT
The dc value of the I datapath and the Q datapath can be controlled
independently by adjusting the values in the two 16-bit registers,
IDAC_DC_OFFSET, Bits[15:0] and QDAC_DC_OFFSET,
Bits[15:0] (Register 0x3B through Register 0x3E). These values
are added directly to the datapath values. Care should be taken
not to overrange the transmitted values.
DATAPATH CONFIGURATION
Configuring the AD9142 datapath starts with the following four
parameters:
•
•
•
•
The application requirements of the input data rate
The interpolation ratio
The output signal center frequency
The output signal bandwidth
As shown in Figure 46, the DAC offset current varies as a function
of the I/QDAC_DC_OFFSET values. Figure 46 shows the
nominal current of the positive node of the DAC output, IOUTP
when the digital inputs are fixed at midscale (0x0000, twos
,
Given these four parameters, the first step in configuring the
datapath is to verify that the device supports the desired input
data rate, the DAC sampling rate, and the bandwidth requirements.
After this verification, the modes of the interpolation filters can be
chosen. If the output signal center frequency is different from the
baseband input center frequency, additional frequency offset
requirements are determined and applied with on-chip digital
modulation.
complement data format) and the DAC offset value is swept from
0x0000 to 0xFFFF. Because IOUTP and IOUTN are complementary
current outputs, the sum of IOUTP and IOUTN is always 20 mA.
20
15
10
5
0
5
DIGITAL QUADRATURE GAIN AND PHASE
ADJUSTMENT
10
15
The digital quadrature gain and phase adjustment function
enables compensation of the gain and phase imbalance of the I
and Q paths caused by analog mismatches between DAC I/Q
outputs, quadrature modulator I/Q baseband inputs, and
DAC/modulator interface I/Q paths. The undesired imbalances
cause unwanted sideband signal to appear at the quadrature
modulator output with significant energy. Tuning the
0
20
0x0000
0x4000
0x8000
0xC000
0xFFFF
DAC OFFSET VALUE
Figure 46. DAC Output Currents vs. DAC Offset Value
Rev. 0 | Page 29 of 64
AD9142
Data Sheet
INVERSE SINC FILTER
INPUT SIGNAL POWER DETECTION AND
PROTECTION
The AD9142 provides a digital inverse sinc filter to compensate
for the DAC rolloff over frequency. The inverse sinc (sinc−1) filter
is a seven tap FIR filter. Figure 47 shows the frequency response
of sin(x)/x rolloff, the inverse sinc filter, and their composite
response. The composite response has less than 0.05 dB pass-
The input signal power detection and protection function detects
the average power of the DAC input signal and prevents overrange
signals from being passed to the next stage. An overrange DAC
output signal can cause destructive breakdown on power sensitive
devices, such as power amplifiers. The power detection and
protection feature of the AD9142 detects overrange signals in
the DAC. When an overrange signal is detected, the protection
function either attenuates or mutes the signal to protect the
downstream devices from abnormal power surges in the signal.
band ripple up to a frequency of 0.4 × fDAC
.
To provide the necessary peaking at the upper end of the pass
band, the inverse sinc filter has an intrinsic insertion loss of about
3.8 dB. The loss of the digital gain can be offset by increasing the
quadrature gain adjustment setting on both the I and Q data paths
to minimize the impact on the output signal-to-noise ratio. How-
ever, care is needed to ensure that the additional digital gain does
not cause signal saturation, especially at high output frequencies.
The sinc−1 filter is disabled by default; it can be enabled by setting
the INVSINC_ENABLE bit to 1 in Register 0x27[7]).
1
Figure 48 shows the block diagram of the power detection and
protection function. The protection block is at the very last
stage of the data path and the detection block uses a separate
path from the data path. The design of the detection block
guarantees that the worst-case latency of power detecting is
shorter than that of the data path. This ensures that the
protection circuit initiates before the overrange signal reaches
the analog DAC core. The sum of I2 and Q2 is calculated as a
representation of the input signal power. Only the upper six
MSBs, D[15:10], of data samples are used in the calculation;
consequently, samples whose power is 36 dB below the full-
scale peak power are not detected. The calculated sample power
numbers accumulate through a moving average filter. Its output
is the average of the input signal power in a certain number of
data clock cycles. The length of the filter is configurable through
the SAMPLE_WINDOW_LENGTH (Register 0x2B[3:0]). To
determine whether the input average power is over range, the
device averages the power of the samples in the filter and
compares the average power with a user defined threshold,
OVER_THRESHOLD_LEVEL[11:0] (Register 0x29 and
Register 0x2A). When the output of the averaging filter is larger
than the threshold, the DAC output is either attenuated or muted.
0
–1
–2
–3
–4
–5
0
0.05 0.10 0.15 0.20 0.25 0.30 0.35 0.40 0.45 0.50
FREQUENCY (Hz)
Figure 47. Responses of sin(x)/x Roll Off (Blue), the Sinc−1 Filter (Red), and the
Composite of Both (Black)
Table 18. Inverse Sinc Filter
The appropriate filter length and average power threshold for
effective protection are application dependent. It is recommended
that experiments be performed with real-world vectors to
determine the values of these parameters.
Lower Coefficient
Upper Coefficient
Integer Value
H(1)
H(2)
H(3)
H(4)
H(7)
H(6)
H(5)
−1
+4
−16
+192
POWER
SIGNAL
PROCESSING
ENGINE
PROTECTION
(ATTENUATE
OR MUTE)
DAC
CORE
FIFO
POWER DETECTION
AVE POWER
2
2
+ Q
I
REG 0x2C AND
0x2D[4:0]
AVERAGING
FILTER
FILTER LENGTH USER-DEFINED THRESHOLD
SETTINGS
REG 0x2B[3:0]
REG 0x29 AND 0x2A[4:0]
Figure 48. Block Diagram of Input Signal Power Detection and Protection Function
Rev. 0 | Page 30 of 64
Data Sheet
AD9142
DIGITAL FUNCTION CONFIGURATION
TRANSMIT ENABLE FUNCTION
Each of the digital gain and phase adjust functions and the
inverse sinc filter can be enabled and adjusted independently.
The pipeline latencies these blocks add into the data path are
different between enabled and disabled. If fixed DAC pipeline
latency is desired during operation, leave these functions always
on or always off after initial configuration.
The transmit enable (TXEN) function provides the user a
hardware switch of the DAC output. The function accepts a
CMOS signal via Pin 6 (TXEN). When this signal is detected
high, the transmit path is enabled and the DAC transmits the
data normally. When this signal is detected low, one of the three
actions related to the DAC output is triggered.
The digital dc adjust function is always on. The default value is
0; that is, there is no additional dc offset. The pipeline latency that
this block adds is a constant, no matter the value of the dc
offset.
1. The DAC output is gradually attenuated from full scale gain
to 0. The attenuation step size is set in Register 0x42[5:0].
2. The DAC is put in sleep mode and the output current is
turned off. Other parts of the DAC are still running in this
mode.
3. The DAC is put in power-down mode. In this mode, not
only the DAC output current is turned off but the rest of
the DAC is powered down. This minimizes the power
consumption of the DAC when the data is not transmitting
but it takes a bit longer than the first two modes to start to
re-transmit data due to the device power-up time.
There is also a latency difference between using and not using
the input signal power detection and protection function.
Therefore, to keep the overall latency fixed, leave this function
always on or always off after the initial configuration.
The TXEN function also provides a gain ramp-up function that
lets the user turn on the DAC output gradually when the TXEN
signal switches from low to high. The ramp-up gain step can be
configured using Register 0x41[5:0]. Although all of these actions
can be taken through SPI writes, TXEN provides a much faster
way to turn on and off the DAC output. The response time of a SPI
write command is dominated by the SPI port communication
time. This feature is useful when the user must turn off the
DAC very quickly.
Rev. 0 | Page 31 of 64
AD9142
Data Sheet
MULTIDEVICE SYNCHRONIZATION AND FIXED LATENCY
FURTHER REDUCING THE LATENCY VARIATION
A DAC introduces a variation of pipeline latency to a system.
The latency variation causes the phase of a DAC output to vary
from power-on to power-on. Therefore, the output from
different DAC devices may not be perfectly aligned even with
well aligned clocks and digital inputs. The skew between
multiple DAC outputs varies from power-on to power-on.
For applications that require finer synchronization accuracy
(DAC latency variation < 2 DAC clock cycles), the AD9142 has
a provision for enabling multiple devices to be synchronized to
each other within a single DAC clock cycle.
To further reduce the latency variation in the DAC, the
synchronization machine needs to be turned on and two
external clocks (frame and sync) need to be generated in the
system and fed to all the DAC devices.
In applications such as transmit diversity or digital pre-
distortion, where deterministic latency is desired, the variation
of the pipeline latency must be minimized. Deterministic
latency in this document is defined as a fixed time delay from
the digital input to the analog output in a DAC from power-on
to power-on. Multiple DAC devices are considered synchronized
to each other when each DAC in this group has the same
constant latency from power-on to power-on. Three conditions
must be identical in all of the ready-to-sync devices before these
devices are considered synchronized:
Set Up and Hold Timing Requirement
The sync clock (fSYNC) serves as a reference clock in the system
to reset the clock generation circuitry in multiple AD9142 devices
simultaneously. Inside the DAC, the sync clock is sampled by the
DACCLK to generate a reference point for aligning the internal
clocks, so there is a setup and hold timing requirement between
the sync clock and the DAC clock.
•
•
•
The phase of DAC internal clocks
The FIFO level
The alignment of the input data
If the user adopts the continuous frame reset mode, that is, the
FIFO and sync engine periodically reset, the timing requirements
between the sync clock and the DAC clock must be met.
Otherwise, the device can lose lock and corrupt the output. In
the one shot frame reset mode, it is still recommended that this
timing be met at the time when the sync routine is run because
not meeting the timing can degrade the sync alignment
accuracy by one DAC cycle, as shown in Table 19.
VERY SMALL INHERENT LATENCY VARIATION
The innovative architecture of the AD9142 minimizes the
inherent latency variation. The worst-case variation in the
AD9142 is two DAC clock cycles. For example, in the case of a
1.5 GHz sample rate, the variation is less than 1.4 ns under any
scenario. Therefore, without turning on the synchronization
engine, the DAC outputs from multiple AD9142 devices are
guaranteed to be aligned within two DAC clock cycles, regardless
of the timing between the DCI and the DACCLK. No additional
clocks are required to achieve this accuracy. The user must reset
the FIFO in each DAC device through the SPI at start-up.
Therefore, the AD9142 can decrease the complexity of system
design in multi transmit channel applications.
For users who want to synchronize the device in a one-shot
manner and continue to monitor the synchronization status,
the AD9142 provides a sync monitoring mode. It provides a
continuous sync and frame clock to synchronize the part once
and ignore the clock cycles after the first valid frame pulse is
detected. In this way, the user can monitor the sync status
without periodically resynchronizing the device; to engage the
sync monitoring mode, set Register 0x22[1:0] (FRAME_RESET_
MODE) to 11b.
Note the alignment of the DCI signals in the design. The DCI is
used as a reference in the AD9142 design to align the FIFO and
the phase of internal clocks in multiple parts. The achieved
DAC output alignment depends on how well the DCIs are
aligned at the input of each device. The equation below is the
expression of the worst-case DAC output alignment accuracy in
the case of DCI mismatches.
Table 19. Sync Clock and DAC Clock Setup and Hold Times
Falling Edge Sync Timing (default)
Max
246
−11
235
Unit
tS (ns)
tH (ns)
|tS + tH| (ns)
ps
ps
ps
t
SK (OUT) = tSK (DCI) + 2/fDAC
where:
SK (OUT) is the worst case skew between the DAC output from
two AD9142 devices.
SK (DCI) is the skew between two DCIs at the DCI input of the
two AD9142 devices.
DAC is the DACCLK frequency.
t
t
f
The better the alignment of the DCIs, the smaller is the overall
skew between two DAC outputs.
Rev. 0 | Page 32 of 64
Data Sheet
AD9142
Synchronization Procedure for PLL Off
SYNCHRONIZATION IMPLEMENTATION
1. Configure the DAC interpolation mode and, if NCO is
used, configure the NC O F T W.
The AD9142 lets the user choose either the rising or falling
edge of the DAC clock to sample the sync clock, which makes it
2. Set up the DAC data interface according to the procedure
outlined in the Data Interface section and verify that the
DLL is locked.
easier to meet the timing requirements. The sync clock, fSYNC
should be 1/8 × fDATA or slower by a factor of 2n, n being an
integer (1, 2, 3…). Note that there is a limit on how slow the
,
3. Choose the appropriate mode in FRAME_RESET_MODE.
a. If NCO is not used, choose FIFO only mode.
b. If NCO is used, it must be synchronized. FIFO and
NCO mode can then be used.
sync clock can be because of the ac coupling nature of the sync
clock receiver. Choose an appropriate value of the ac coupling
capacitors to ensure that the signal swing meets the data sheet
specification, as listed in Table 2.
4. Configure Bit 2 in Register 0x22 for continuous or one shot
reset mode. One shot reset mode is recommended.
5. Ensure that the DACCLK, DCI, and sync clock to all of the
AD9142 devices are running and stable.
6. Enable the sync engine by writing 1 to Register 0x21[0].
7. Send a valid frame pulse(s) to all of the AD9142 devices.
8. Verify that the frame pulse is received by each device by
reading back Register 0x22[3]. All the readback values are 1.
At this point, the devices should be synchronized.
The frame clock resets the FIFO in multiple AD9142 devices.
The frame can be either a one shot or continuous clock. In either
case, the pulse width of the frame must be longer than one DCI
cycle in the word mode and two DCI cycles in the byte mode.
When the frame is a continuous clock, fFRAME should be at 1/8 ×
fDATA or slower by a factor of 2n, n being an integer (1, 2, 3…).
Table 20 lists the requirements of the frame clock in various
conditions.
Table 20. Frame Clock Speed and Pulse Width Requirement
Synchronization Procedure for PLL On
Maximum
Note that, because the sync clock and PLL reference clock share
the same clock and the maximum sync clock rate is fDATA/8, the
same limit also applies to the reference clock. Therefore, only
2× interpolation is supported for synchronization with PLL on.
Sync Clock Speed
Minimum Pulse Width
One Shot
Continuous fDATA/8
N/A1
For both one shot and continuous
sync clocks, word mode = one DCI
cycle and byte mode = two DCI cycles.
1 N/A means not applicable.
1. Set up the PLL according to the procedure in the Clock
Multiplication section and ensure that the PLL is locked.
2. Configure the DAC interpolation mode and, if NCO is
used, configure the NC O F T W.
3. Set up the DAC data interface according to the procedure
in the Data Interface section and verify that the DLL is
locked.
SYNCHRONIZATION PROCEDURES
When the sync accuracy of an application is looser than two
DAC clock cycles, it is recommended to turn off the synchro-
nization machine because there are no additional steps required,
other than the regular start-up procedure sequence.
For applications that require finer than two-DAC clock cycle
sync accuracy, it is recommended that the procedure in the
Synchronization Procedure for PLL Off or Synchronization
Procedure for PLL On sections be followed to set up the system
and configure the device. For more information about the
details of the synchronization scheme in the AD9142 and using
the synchronization function to correct system skews and drifts,
see the DAC Latency and System Skews section.
4. Choose the appropriate mode in FRAME_RESET_MODE.
a. If NCO is not used, choose the FIFO only mode.
b. If NCO is used, it must be synchronized. FIFO and
NCO mode can then be used.
5. Configure Bit 2 in Register 0x22 for continuous or one shot
reset mode. One shot reset mode is recommended.
6. Ensure that DACCLK, DCI, and sync clock to all of the
AD9142 devices are running.
7. Enable the sync engine by writing 1 to Register 0x21[0].
8. Send a valid frame pulse(s) to all of the AD9142 devices.
9. Verify that the frame pulse is received by each device by
reading back Register 0x22[3]. All the readback values are 1.
At this point, the devices should be synchronized.
Rev. 0 | Page 33 of 64
AD9142
Data Sheet
INTERRUPT REQUEST OPERATION
The AD9142 provides an interrupt request output signal on
method is by writing 1 to the corresponding event flag bit. The
second method is to use a hardware or software reset to clear the
INTERRUPT_SOURCE signal.
IRQ2
Pin 50 and Pin 51 (
IRQ1
and
, respectively) that can be used
to notify an external host processor of significant device events.
Upon assertion of the interrupt, query the device to determine
IRQ2
IRQ1
circuitry.
The
Any one or multiple event flags can be enabled to trigger
IRQ1 IRQ2
circuitry works in the same way as the
IRQ1
the precise event that occurred. The
pin is an open-drain,
IRQ1
active low output. Pull the
pin high external to the device.
the
and
pins. The user can select one or both
This pin can be tied to the interrupt pins of other devices with
open-drain outputs to wire-OR these pins together.
hardware interrupt pins for the enabled event flags. Register 0x07
and Register 0x08 determine the pin to which each event flag is
IRQ1
routed. Set Register 0x07 and Register 0x08 to 0 for
IRQ2
and set
Ten event flags provide visibility into the device. These flags are
located in the two event flag registers, Register 0x05 and
Register 0x06. The behavior of each event flag is independently
selected in the interrupt enable registers, Register 0x03 and
Register 0x04. When the flag interrupt enable is active, the event
flag latches and triggers an external interrupt. When the flag
interrupt is disabled, the event flag monitors the source signal,
these registers to 1 for
.
INTERRUPT SERVICE ROUTINE
Interrupt request management starts by selecting the set of
event flags that require host intervention or monitoring. Enable
the events that require host action so that the host is notified
when they occur. For events requiring host intervention
IRQ1
IRQ2
but the
and
pin remain inactive.
IRQx
upon
activation, run the following routine to clear an
INTERRUPT WORKING MECHANISM
interrupt request:
Figure 49 shows the interrupt related circuitry and how the event
1. Read the status of the event flag bits that are being
monitored.
IRQx
flag signals propagate to the
output. The INTERRUPT_
ENABLE signal represents one bit from the interrupt enable
register. The EVENT_FLAG_SOURCE signal represents one bit
from the event flag register. The EVENT_FLAG_SOURCE signal
represents one of the device signals that can be monitored, such as
the PLL_LOCK signal from the PLL phase detector or the
FIFO_WARNING_1 signal from the FIFO controller.
2. Set the interrupt enable bit low so that the unlatched
EVENT_FLAG_SOURCE can be monitored directly.
3. Perform any actions that may be required to clear the
EVENT_FLAG_SOURCE. In many cases, no specific
actions may be required.
4. Read the event flag to verify that the actions taken have
cleared the EVENT_FLAG_SOURCE.
5. Clear the interrupt by writing 1 to the event flag bit.
6. Set the interrupt enable bits of the events to be monitored.
When an interrupt enable bit is set high, the corresponding event
flag bit reflects a positively tripped version of the EVENT_FLAG_
SOURCE signal; that is, the event flag bit is latched on the rising
edge of the EVENT_FLAG_SOURCE signal. This signal also
Note that some EVENT_FLAG_SOURCE signals are latched
signals. These signals are cleared by writing to the correspon-
ding event flag bit. For more information about each of the
event flags, see the Device Configuration Register Map and
Description section.
IRQ
asserts the external
pins.
When an interrupt enable bit is set low, the event flag bit reflects
the present status of the EVENT_FLAG_SOURCE signal, and
IRQ
the event flag has no effect on the external
pins.
Clear the latched version of an event flag (the INTERRUPT_
SOURCE signal) in one of two ways. The recommended
0
1
EVENT_FLAG
IRQ
INTERRUPT_
SOURCE
INTERRUPT_ENABLE
OTHER
INTERRUPT
SOURCES
EVENT_FLAG_SOURCE
WRITE_1_TO_EVENT_FLAG
DEVICE_RESET
IRQ
Figure 49. Simplified Schematic of
Circuitry
Rev. 0 | Page 34 of 64
Data Sheet
AD9142
TEMPERATURE SENSOR
The AD9142 has a diode-based temperature sensor for measuring
the temperature of the die. The temperature reading is accessed
using Register 0x1D and Register 0x1E. The temperature of the
die can be calculated as
Estimates of the ambient temperature can be made if the power
dissipation of the device is known. For example, if the device
power dissipation is 800 mW and the measured die temperature
is 50°C, then the ambient temperature can be calculated as
TA = TDIE – PD × θJA = 50 – 0.8 × 20.7 = 33.4°C
( DieTemp[15:0]− 41,237)
TDIE
=
where:
106
TA is the ambient temperature in degrees Celsius.
where TDIE is the die temperature in degrees Celsius. The
temperature accuracy is 7°C typical over the +85°C to −40°C
range with one point temperature calibration against a known
temperature. A typical plot of the die temperature vs. die
temperature code readback is shown in Figure 50.
θ
JA is the thermal resistance from junction to ambient of the
AD9142 as shown in Table 8.
To use the temperature sensor, it must be enabled by setting Bit 0,
Register 0x1C to 1. In addition, to get accurate readings, the die
temperature control register (Register 0x1C) should be set to 0x03.
51000
49000
47000
45000
43000
41000
39000
37000
35000
–40 –30 –20 –10
0
10 20 30 40 50 60 70 80 90
TEMPERATURE (°C)
Figure 50. Die Temperature vs. Die Temperature Code Readback
Rev. 0 | Page 35 of 64
AD9142
Data Sheet
DAC INPUT CLOCK CONFIGURATIONS
The AD9142 DAC sample clock (DACCLK) can be sourced
directly or by clock multiplying. Clock multiplying employs the
on-chip phase-locked loop (PLL) that accepts a reference clock
operating at a submultiple of the desired DACCLK rate. The
PLL then multiplies the reference clock up to the desired DACCLK
frequency, which can then be used to generate all of the internal
clocks required by the DAC. The clock multiplier provides a
high quality clock that meets the performance requirements of
most applications. Using the on-chip clock multiplier removes
the burden of generating and distributing the high speed DACCLK.
DIRECT CLOCKING
Direct clocking with a low noise clock produces the lowest noise
spectral density at the DAC outputs. To select the differential
CLK inputs as the source for the DAC sampling clock, set the
PLL enable bit (Register 0x12[7]) to 0. This powers down the
internal PLL clock multiplier and selects the input from the
DACCLKP and DACCLKN pins as the source for the internal
DAC sampling clock. The REFCLK input can remain floating.
The device also has clock duty cycle correction circuitry and
differential input level correction circuitry. Enabling these circuits
can provide improved performance in some cases. The control
bits for these functions are in Register 0x10 and Register 0x11.
The second mode bypasses the clock multiplier circuitry and lets
DACCLK be sourced directly to the DAC core. This mode lets the
user source a very high quality clock directly to the DAC core.
CLOCK MULTIPLICATION
DRIVING THE DACCLK AND REFCLK INPUTS
The on-chip PLL clock multiplier circuit generates the DAC
sample rate clock from a lower frequency reference clock. When
the PLL enable bit (Register 0x12[7]) is set to 1, the clock
multiplication circuit generates the DAC sampling clock from
the lower rate REFCLK input and the DACCLK input is left
floating. The functional diagram of the clock multiplier is
shown in Figure 52.
The DACCLK and REFCLK differential inputs share similar
clock receiver input circuitry. Figure 51 shows a simplified circuit
diagram of the input. The on-chip clock receiver has a differential
input impedance of about 10 kΩ. It is self biased to a common-
mode voltage of about 1.25 V. The inputs can be driven by
differential PECL or LVDS drivers with ac coupling between the
clock source and the receiver.
The clock multiplication circuit operates such that the VCO
outputs a frequency, fVCO, equal to the REFCLK input signal
frequency multiplied by N1 × N0. N1 is the divide ratio of the
loop divider; N0 is the divide ratio of the VCO divider.
RECOMMENDED
EXTERNAL
CIRCUITRY
AD9142
DACCLKP/
REFP/SYNCP
1~100nF
f
VCO = fREFCLK × (N1 × N0)
The DAC sample clock frequency, fDACCLK, is equal to
DACCLK = fREFCLK × N1
5kΩ
100Ω
1.25V
5kΩ
1~100nF
f
DACCLKN/
REFN/SYNCN
The output frequency of the VCO must be chosen to keep fVCO
in the optimal operating range of 1.0 GHz to 2.1 GHz. It is
important to select a frequency of the reference clock and values
of N1 and N0 so that the desired DACCLK frequency can be
synthesized and the VCO output frequency is in the correct range.
Figure 51. Clock Receiver Input Simplified Equivalent Circuit
The minimum input drive level to the differential clock input is
100 mV p-p differential. The optimal performance is achieved
when the clock input signal is between 800 mV p-p differential
and 1.6 V p-p differential. Whether using the on-chip clock
multiplier or sourcing the DACCLK directly, the input clock
signal to the device must have low jitter and fast edge rates to
optimize the DAC noise performance.
VCO CONTROL
VOLTAGE
ADC
PLL CHARGE
REG 0x16[3:0]
PUMP CURRENT PLL LOOP BW
REFP/SYNCP
(PIN 2)
REG 0x14[4:0]
REG 0x14[7:5]
PHASE
FREQUENCY
DETECTION
CHARGE
PUMP
ON-CHIP
LOOP FILTER
VCO
(1GHz~2.1GHz)
REFN/SYNCN
(PIN 3)
LOOP DIVIDER
REG 0x15[1:0]
VCO DIVIDER
REG 0x15[3:2]
DIVIDE BY
2, 4, 8, OR 16
DIVIDE BY
1, 2, OR 4
DACCLKN
(PIN 62)
DACCLK
DACCLKP
(PIN 61)
PLL ENABLE
REG 0x12[7]
Figure 52. PLL Clock Multiplication Circuit
Rev. 0 | Page 36 of 64
Data Sheet
AD9142
61
57
53
49
45
41
37
33
29
25
21
17
13
9
PLL SETTINGS
The PLL circuitry requires three settings to be programmed to
their nominal values. The PLL values shown in Table 21 are the
recommended settings for these parameters.
Table 21. PLL Settings
PLL SPI Control
Register
Register
Address
Optimal Setting
(Binary)
PLL Loop Bandwidth
PLL Charge Pump Current 0x14[4:0]
PLL Cross Control Enable 0x15[4]
0x14[7:5]
111
00111
0
5
1
950
1150
1350
1550
1750
1950
2150
CONFIGURING THE VCO TUNING BAND
VCO FREQUENCY (MHz)
The PLL VCO has a valid operating range from approximately
1.0 GHz to 2.1 GHz covered in 64 overlapping frequency bands.
For any desired VCO output frequency, there may be several
valid PLL band select values. The frequency bands of a typical
device are shown in Figure 53. Device-to-device variations and
operating temperature affect the actual band frequency range.
Therefore, it is required that the optimal PLL band select value
be determined for each individual device.
Figure 53. PLL Lock Range for a Typical Device
MANUAL VCO BAND SELECT
The device includes a manual band select mode (PLL auto
manual enable, Register 0x12[6] = 1) that lets the user select the
VCO tuning band. In manual mode, the VCO band is set
directly with the value written to the manual VCO band bits
(Register 0x12[5:0]).
AUTOMATIC VCO BAND SELECT
PLL ENABLE SEQUENCE
The device has an automatic VCO band select feature on chip.
Using the automatic VCO band select feature is a simple and
reliable method of configuring the VCO frequency band. This
feature is enabled by starting the PLL in manual mode, and then
placing the PLL in autoband select mode by setting Register
0x12 to a value of 0xC0 and then to a value of 0x80. When these
values are written, the device executes an automated routine
that determines the optimal VCO band setting for the device.
To enable the PLL in automatic or manual mode properly, the
following sequence must be followed:
Automatic Mode Sequence
1. Configure the loop divider and the VCO divider registers
for the desired divide ratios.
2. Set 00111b to PLL charge pump current and 111b to PLL
loop bandwidth for the best performance.
3. Set the PLL mode to manual using Register 0x12[6] = 1b.
4. Enable the PLL using Register 0x12[7] = 1b.
5. Set the PLL mode to automatic using Register 0x12[6] = 0b.
6. Enable the PLL using Register 0x12[7] = 1b.
The setting selected by the device ensures that the PLL remains
locked over the full −40°C to +85°C operating temperature
range of the device without further adjustment. The PLL
remains locked over the full temperature range even if the
temperature during initialization is at one of the temperature
extremes.
Manual Mode
1. Configure the loop divider and the VCO divider registers
for the desired divide ratios.
2. Set 00111b to PLL charge pump current and 111b to PLL
loop bandwidth for the best performance.
3. Select the desired band.
4. Set the PLL mode to manual using Register 0x12[6] = 1b.
5. Enable the PLL using Register 0x12[7] = 1b.
6. Enable the PLL one more time using Register 0x12[7] = 1b.
Rev. 0 | Page 37 of 64
AD9142
Data Sheet
ANALOG OUTPUTS
For nominal values of VREF (1.2 V), RSET (10 kΩ), and DAC gain
(512), the full-scale current of the DAC is typically 20.16 mA. The
DAC full-scale current can be adjusted from 8.64 mA to 31.68 mA
by setting the DAC gain parameter, as shown in Figure 55.
35
TRANSMIT DAC OPERATION
Figure 54 shows a simplified block diagram of the transmit path
DACs. The DAC core consists of a current source array, a switch
core, digital control logic, and full-scale output current control.
The DAC full-scale output current (IOUTFS) is nominally 20 mA.
The output currents from the IOUT1P/IOUT2P and IOUT1N/
IOUT2N pins are complementary, meaning that the sum of the
two currents always equals the full-scale current of the DAC.
The digital input code to the DAC determines the effective
differential current delivered to the load.
30
25
20
15
10
5
I DAC FS ADJUST
1.2V
REG 0x18, 0x19
IOUT1P
I DAC
5kΩ
IOUT1N
REFIO
CURRENT
SCALING
0.1µF
FSADJ
10kΩ
IOUT2N
IOUT2P
0
R
Q DAC
SET
0
200
400
600
800
1000
Q DAC FS ADJUST
REG 0x1A, 0x1B
DAC GAIN CODE
Figure 55. DAC Full-Scale Current vs. DAC Gain Code
Figure 54. Simplified Block Diagram of DAC Core
Transmit DAC Transfer Function
The DAC has a 1.2 V band gap reference with an output imped-
ance of 5 kΩ. The reference output voltage appears on the REFIO
pin. When using the internal reference, decouple the REFIO pin
to AVSS with a 0.1 µF capacitor. Use the internal reference only
for external circuits that draw dc currents of 2 µA or less. For
dynamic loads or static loads greater than 2 µA, buffer the REFIO
pin. If desired, the internal reference can be overdriven by
applying an external reference (from 1.10 V to 1.30 V) to the
REFIO pin.
The output currents from the IOUT1P/IOUT2P and IOUT1N/
IOUT2N pins are complementary, meaning that the sum of the
two currents always equals the full-scale current of the DAC. The
digital input code to the DAC determines the effective differen-
tial current delivered to the load. IOUT1P/IOUT2P provide
maximum output current when all bits are high. The output
currents vs. DACCODE for the DAC outputs is expressed as
DACCODE
(1)
(2)
IOUTP
=
× IOUTFS
2N
A 10 kΩ external resistor, RSET, must be connected from the
FSADJ pin to AVSS. This resistor, together with the reference
control amplifier, sets up the correct internal bias currents for
the DAC. Because the full-scale current is inversely proportional to
this resistor, the tolerance of RSET is reflected in the full-scale
output amplitude.
IOUTN = IOUTFS – IOUTP
where DACCODE = 0 to 2N − 1.
Transmit DAC Output Configurations
The optimum noise and distortion performance of the AD9142
is realized when it is configured for differential operation. The
common-mode rejection of a transformer or differential amplifier
significantly reduces the common-mode error sources of the DAC
outputs. These common-mode error sources include even-order
distortion products and noise. The enhancement in distortion
performance becomes more significant as the frequency content of
the reconstructed waveform increases and/or its amplitude
increases. This is due to the first-order cancellation of various
dynamic common-mode distortion mechanisms, digital feed-
through, and noise.
The full-scale current equation, where the DAC gain is set
individually for the Q and IDACs in Register 0x40 and Register
0x44, respectively, is as follows:
VREF
RSET
3
16
IFS
=
× 72 +
× DAC gain
Rev. 0 | Page 38 of 64
Data Sheet
AD9142
Figure 56 shows the most basic DAC output circuitry. A pair of
resistors, RO, convert each of the complementary output currents to
a differential voltage output, VOUT. Because the current outputs
of the DAC are high impedance, the differential driving point
impedance of the DAC outputs, ROUT, is equal to 2 × RO. See
Figure 57 for the output voltage waveforms.
AD9142
ADL537x
67
IOUT1P
IBBP
RBIP
50Ω
RLI
100Ω
RBIN
50Ω
66
59
IOUT1N
IOUT2N
IBBN
V
+
IP
IOUT1P
QBBN
RBQN
R
O
O
50Ω
RLQ
100Ω
V
OUTI
RBQP
50Ω
58
R
V
–
IOUT2P
QBBP
IN
IOUT1N
Figure 58. Typical Interface Circuitry Between the AD9142 and the ADL537x
Family of Modulators
V
+
QP
IOUT2P
The baseband inputs of the ADL537x family require a dc bias
of 500 mV. The nominal midscale output current on each output of
the DAC is 10 mA (one-half the full-scale current). Therefore,
a single 50 Ω resistor to ground from each of the DAC outputs
results in the desired 500 mV dc common-mode bias for the
inputs to the ADL537x. The addition of the load resistor in
parallel with the modulator inputs reduces the signal level. The
peak-to-peak voltage swing of the transmitted signal is
R
O
O
V
OUTQ
–
R
V
QN
IOUT2N
Figure 56. Basic Transmit DAC Output Circuit
+V
PEAK
(2×RB ×RL )
V
CM
0
VSIGNAL = IFS
×
V
(2×RB + RL )
V
P
N
Baseband Filter Implementation
Most applications require a baseband anti-imaging filter between
the DAC and the modulator to filter out Nyquist images and
broadband DAC noise. The filter can be inserted between the
I-V resistors at the DAC output and the signal level setting resistor
across the modulator input. This configuration establishes the
input and output impedances for the filter.
V
OUT
–V
PEAK
Figure 57. Output Voltage Waveforms
Figure 59 shows a fifth-order, low-pass filter. A common-mode
choke is placed between the I-V resistors and the remainder of
the filter to remove the common-mode signal produced by the
DAC and to prevent the common-mode signal from being
converted to a differential signal, which can appear as unwanted
spurious signals in the output spectrum. Splitting the first filter
capacitor into two and grounding the center point creates a
common-mode low-pass filter, which provides additional
common-mode rejection of high frequency signals. A purely
differential filter can pass common-mode signals.
The common-mode signal voltage, VCM, is calculated as
IFS
2
VCM
=
× RO
The peak output voltage, VPEAK, is calculated as
PEAK = IFS × RO
V
In this circuit configuration, the single-ended peak voltage is
the same as the peak differential output voltage.
INTERFACING TO MODULATORS
For more details about interfacing the AD9142 DAC to an IQ
modulator, refer to the Circuits from the Lab CN-0205, Interfacing
the ADL5375 I/Q Modulator to the AD9122 Dual Channel,
1.2 GSPS High Speed DAC on the Analog Devices website.
The AD9142 interfaces to the ADL537x family of modulators
with a minimal number of components. An example of the
recommended interface circuitry is shown in Figure 58.
22pF
50Ω
3pF
33nH
33nH
3.6pF
6pF
3pF
140Ω ADL537x
AD9142
33nH
33nH
50Ω
22pF
Figure 59. DAC Modulator Interface with Fifth-Order, Low-Pass Filter
Rev. 0 | Page 39 of 64
AD9142
Data Sheet
(Register 0x37 and Register 0x38) and the DAC FS adjust
REDUCING LO LEAKAGE AND UNWANTED
SIDEBANDS
registers (Register 0x18 through Register 0x1B) can be used to
calibrate the I and Q transmit paths to optimize sideband
suppression.
Analog quadrature modulators can introduce unwanted signals
at the local oscillator (LO) frequency due to dc offset voltages in
the I and Q baseband inputs, as well as feedthrough paths from
the LO input to the output. The LO feedthrough can be nulled
by applying the correct dc offset voltages at the DAC output
using the digital dc offset adjustments (Register 0x3B through
Register 0x3E).
For more information about suppressing LO leakage and
sideband image, refer to Application Note AN-1039, Correcting
Imperfections in IQ Modulators to Improve RF Signal Fidelity
and Application Note AN-1100, Wireless Transmitter IQ Balance
and Sideband Suppression from the Analog Devices website.
Effective sideband suppression requires both gain and phase
matching of the I and Q signals. The I/Q phase adjust registers
Rev. 0 | Page 40 of 64
Data Sheet
AD9142
EXAMPLE START-UP ROUTINE
To ensure reliable start-up of the AD9142, certain sequences
must be followed. This section shows an example start-up
routine.
/* Configure PLL */
0x14 → 0xE3 /* Configure PLL loop BW and charge
pump current */
0x15 → 0xC2 /* Configure VCO divider and Loop
divider */
Device Configuration and Start-Up Sequence
0x12 → 0xC0 /*Enable the PLL */
0x12 → 0x80
•
•
•
•
•
•
fDATA = 200 MHz, interpolation is 8×.
Input data is baseband data.
fOUT = 350 MHz.
PLL is enabled, fREF = 200 MHz.
Fine NCO is enabled, inverse sinc filter is enabled.
A delay line-based mode is used with an interface delay
setting of 0.
/* Configure Data Interface */
0x5E → 0x00 /* Delay setting 0 */
0x5F → 0x08 /* Enable the delay line */
/* Configure Interpolation filter */
Derived PLL Settings
0x28 → 0x03 /* 8× interpolation */
The following PLL settings can be derived from the device
configuration:
/* Reset FIFO */
•
•
•
•
f
DAC = 200 × 8 = 1600 MHz.
0x25 → 0x01
fVCO= fDAC = 1600 MHz (1 GHz < fVCO < 2 GHz).
Read 0x25[1] /* Expect 1b if the FIFO reset is
complete */
VCO divider = fVCO/fDAC = 1.
Loop divider = fDAC/fREF = 8.
Read 0x24 /* The readback should be one of the
three values: 0x37, 0x40, or 0x41 */
Derived NCO Settings
The following NCO settings can be derived from the device
configuration:
/* Configure NCO */
0x27→ 0x40 /* Enable NCO */
0x31 → 0x00
•
•
•
fDAC = 200 × 8 = 1600 MHz.
CARRIER = fOUT = 350 MHz.
FTW = fCARRIER/fDAC × 232 = 0x38000000.
f
0x32 → 0x00
0x33 → 0x00
Start-Up Sequence
0x34 → 0x38
0x30 → 0x01
1. Power up the device (no specific power supply sequence is
required).
2. Apply stable DAC clock.
3. Apply stable DCI clock.
Read 0x30[1] /* Expect 1b if the NCO update is
complete */
4. Feed stable input data.
/* Enable Inverse SINC filter */
5. Issue H/W reset (optional).
0x27 → 0xC0
/* Device configuration register write
sequence. Must be written in sequence for every
device after reset*/
/* Power up DAC outputs */
0x01 → 0x00
0x00 → 0x20 /* Issue software reset */
0x20 → 0x01 /* Device Startup Configuration */
0x79 → 0x18 /* Device Startup Configuration */
0x80 → 0xAD /* Device Startup Configuration */
0xE1 → 0x1A /* Device Startup Configuration */
Rev. 0 | Page 41 of 64
AD9142
Data Sheet
DEVICE CONFIGURATION REGISTER MAP AND DESCRIPTION
Table 22. Device Configuration Register Map
Reg Name
Bits Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Reserved
PD_DEVICE
Bit 1
Bit 0
PD_FRAME
Reset RW
0x00 RW
0xC0 RW
0x00 RW
0x00 Common
0x01 PD_CONTROL
[7:0] Reserved
[7:0] PD_IDAC
[7:0] Reserved
SPI_LSB_FIRST DEVICE_RESET
PD_QDAC
PD_DATARCV
ENABLE_
SYNC_LOCKED SYNC_DONE
Reserved
PD_DACCLK
0x03 INTERRUPT_
ENABLE0
ENABLE_
ENABLE_
ENABLE_PLL_
LOST
ENABLE_PLL_ ENABLE_OVER_ ENABLE_
LOCKED
SYNC_LOST
THRESHOLD
DACOUT_
MUTED
0x04 INTERRUPT_
ENABLE1
[7:0]
Reserved
ENABLE_FIFO_ ENABLE_FIFO_ ENABLE_FIFO_ 0x00 RW
UNDERFLOW OVERFLOW
WARNING
0x05 INTERRUPT_
FLAG0
[7:0] Reserved
[7:0]
SYNC_LOST
SYNC_LOCKED SYNC_DONE
Reserved
PLL_LOST
PLL_LOCKED OVER_
THRESHOLD
DACOUT_
MUTED
0x00
0x00
R
R
0x06 INTERRUPT_
FLAG1
FIFO_
FIFO_OVER-
FIFO_
WARNING
UNDERFLOW FLOW
0x07 IRQ_SEL0
[7:0] Reserved
[7:0]
SEL_SYNC_
LOST
SEL_SYNC_
LOCKED
SEL_SYNC_
DONE
SEL_PLL_LOST
SEL_PLL_
LOCKED
SEL_OVER_
THRESHOLD
SEL_DACOUT 0x00 RW
_MUTED
0x08 IRQ_SEL1
Reserved
SEL_FIFO_
UNDERFLOW OVERFLOW
SEL_FIFO_
SEL_FIFO_
WARNING
0x00 RW
0x10 DACCLK_
RECEIVER_
CTRL
[7:0] DACCLK_
Reserved
DACCLK_
CROSSPOINT_
CTRL_ENABLE
DACCLK_CROSSPOINT_LEVEL
0xFF RW
DUTYCYCLE_
CORRECTION
0x11 REFCLK_
RECEIVER_CTRL
[7:0] DUTYCYCLE_ Reserved
CORRECTION
REFCLK_
CROSSPOINT_
CTRL_ENABLE
REFCLK_CROSSPOINT_LEVEL
PLL_MANUAL_BAND
0xBF RW
0x00 RW
0x12 PLL_CTRL0
[7:0] PLL_ENABLE
AUTO_
MANUAL_SEL
0x14 PLL_CTRL2
0x15 PLL_CTRL3
[7:0]
PLL_LOOP_BW
PLL_CP_CURRENT
VCO_DIVIDER
0xE7 RW
0xC9 RW
[7:0]
DIGLOGIC_DIVIDER
Reserved
Reserved
CROSSPOINT_
CTRL_EN
LOOP_DIVIDER
0x16 PLL_STATUS0
0x17 PLL_STATUS1
[7:0] PLL_LOCK
[7:0]
VCO_CTRL_VOLTAGE_READBACK
PLL_BAND_READBACK
IDAC_FULLSCALE_ADJUST_LSB
Reserved
0x00
0x00
R
R
Reserved
0x18 IDAC_FS_ADJ0 [7:0]
0x19 IDAC_FS_ADJ1 [7:0]
0xF9 RW
IDAC_FULLSCALE_ADJUST_ 0xE1 RW
MSB
0x1A QDAC_FS_ADJ0 [7:0]
0x1B QDAC_FS_ADJ1 [7:0]
QDAC_FULLSCALE_ADJUST_LSB
0xF9 RW
Reserved
QDAC_FULLSCALE_ADJUST_ 0x01 RW
MSB
0x1C DIE_TEMP_
SENSOR_CTRL
[7:0] Reserved
FS_CURRENT
REF_CURRENT
DIE_TEMP_
SENSOR_EN
0x02 RW
0x1D DIE_TEMP_LSB [7:0]
0x1E DIE_TEMP_MSB [7:0]
DIE_TEMP_LSB
DIE_TEMP_MSB
0x00
0x00
0x0A
R
R
R
0x1F CHIP_ID
[7:0]
[7:0]
CHIP_ID
0x20 INTERRUPT_
CONFIG
INTERRUPT_CONFIGURATION
0x00 RW
0x00 RW
0x12 RW
0x40 RW
0x21 SYNC_CTRL
[7:0]
Reserved
SYNC_CLK_
EDGE_SEL
SYNC_
ENABLE
0x22 FRAME_RST_
CTRL
[7:0]
Reserved
FRAME_
RESET_ACK
EN_CON_
FRAME_RESET
FRAME_RESET_MODE
0x23 FIFO_LEVEL_
CONFIG
[7:0] Reserved
[7:0] Reserved
[7:0]
INTEGRAL_FIFO_LEVEL_REQUEST
INTEGRAL_FIFO_LEVEL_READBACK
Reserved
Reserved
Reserved
FRACTIONAL_FIFO_LEVEL_REQUEST
FRACTIONAL_FIFO_LEVEL_READBACK
0x24 FIFO_LEVEL_
READBACK
0x00
R
0x25 FIFO_CTRL
FIFO_SPI_
RESET_ACK
FIFO_SPI_
RESET_
REQUEST
0x00 RW
0x00 RW
0x26 DATA_
FORMAT_SEL
[7:0] DATA_
FORMAT
DATA_PAIRIN DATA_BUS_
INVERT
NCO_ENABLE IQ_GAIN_ADJ_ IQ_PHASE_
Reserved
FS4_
DATA_BUS_
WIDTH
G
0x27 DATAPATH_
CTRL
[7:0] INVSINC_
ENABLE
Reserved
NCO_SIDE-
MODULATION_ BAND_SEL
ENABLE
SEND_IDATA_ 0x00 RW
TO_QDAC
DCOFFSET_
ENABLE
ADJ_ENABLE
Rev. 0 | Page 42 of 64
Data Sheet
AD9142
0x28 INTERPOLATION_ [7:0]
CTRL
Reserved
THRESHOLD_LEVEL_REQUEST_LSB
INTERPOLATION_MODE
0x00 RW
0x29 OVER_
THRESHOLD_
[7:0]
0x00 RW
CTRL0
0x2A OVER_
[7:0]
Reserved
THRESHOLD_LEVEL_REQUEST_MSB
0x00 RW
0x00 RW
THRESHOLD_
CTRL1
0x2B OVER_
[7:0] ENABLE_
IQ_DATA_
SWAP
Reserved
SAMPLE_WINDOW_LENGTH
THRESHOLD_
CTRL2
PROTECTION
0x2C INPUT_POWER_ [7:0]
READBACK_LSB
INPUT_POWER_READBACK_LSB
INPUT_POWER_READBACK_MSB
Reserved NCO_SPI_
0x00
0x00
R
R
0x2D INPUT_POWER_ [7:0]
READBACK_MSB
Reserved
0x30 NCO_CTRL
[7:0] Reserved
NCO_FRAME_ SPI_NCO_
UPDATE_ACK PHASE_RST_
ACK
SPI_NCO_
PHASE_
NCO_SPI_
0x00 RW
0x00 RW
0x00 RW
0x00 RW
0x10 RW
UPDATE_ACK UPDATE_REQ
RST_REQ
0x31 NCO_FREQ_
TUNING_
[7:0]
[7:0]
[7:0]
[7:0]
NCO_FTW0
NCO_FTW1
NCO_FTW2
NCO_FTW3
WORD0
0x32 NCO_FREQ_
TUNING_
WORD1
0x33 NCO_FREQ_
TUNING_
WORD2
0x34 NCO_FREQ_
TUNING_
WORD3
0x35 NCO_PHASE_
OFFSET0
[7:0]
[7:0]
[7:0]
[7:0]
[7:0]
[7:0]
[7:0]
[7:0]
NCO_PHASE_OFFSET_LSB
0x00 RW
0x00 RW
0x00 RW
0x36 NCO_PHASE_
OFFSET1
NCO_PHASE_OFFSET_MSB
IQ_PHASE_ADJ_LSB
0x37 IQ_PHASE_
ADJ0
0x38 IQ_PHASE_
ADJ1
Reserved
IQ_PHASE_ADJ_MSB
0x00 RW
0
0x3B IDAC_DC_
OFFSET0
IDAC_DC_OFFSET_LSB
IDAC_DC_OFFSET_MSB
QDAC_DC_OFFSET_LSB
QDAC_DC_OFFSET_MSB
0x00 RW
0x00 RW
0x00 RW
0x00 RW
0x3C IDAC_DC_
OFFSET1
0x3D QDAC_DC_
OFFSET0
0x3E QDAC_DC_
OFFSET1
0x3F IDAC_GAIN_ADJ [7:0]
Reserved
IDAC_GAIN_ADJ
0x20 RW
0x20 RW
0x40 QDAC_GAIN_
ADJ
[7:0]
Reserved
QDAC_GAIN_ADJ
0x41 GAIN_STEP_
CTRL0
[7:0]
Reserved
RAMP_UP_STEP
0x01 RW
0x01 RW
0x07 RW
0x42 GAIN_STEP_
CTRL1
[7:0] DAC_OUTPUT_ DAC_OUTPUT_
STATUS ON
RAMP_DOWN_STEP
0x43 TX_ENABLE_
CTRL
[7:0]
Reserved
Reserved
TXENABLE_
GAINSTEP_EN SLEEP_EN
TXENABLE_
TXENABLE_
POWER_
DOWN_EN
0x44 DAC_OUTPUT_ [7:0] DAC_OUTPUT_
FIFO_WARNING_ OVER-
Reserved
FIFO_ERROR_ 0x8F RW
CTRL
CTRL_EN
SHUTDOWN_EN THRESHOLD_
SHUTDOWN_
EN
SHUTDOWN_
EN
0x5E DATA_RX_CTRL0 [7:0]
0x5F DATA_RX_CTRL1 [7:0]
DLY_TAP_LSB
0xFF RW
0x07 RW
0x00 RW
Reserved
DLYLINE_EN
DLY_TAP_MSB
0x79 DEVICE_
CONFIG0
[7:0]
DEVICE_CONFIGURATION0
0x7F Version
[7:0]
[7:0]
Version
0x05
R
0x80 DEVICE_
CONFIG1
DEVICE_CONFIGURATION1
0x00 RW
0xE1 DEVICE_
CONFIG2
[7:0]
DEVICE_CONFIGURATION2
0x00 RW
Rev. 0 | Page 43 of 64
AD9142
Data Sheet
SPI CONFIGURE REGISTER
Address: 0x00, Reset: 0x00, Name: Common
Table 23. Bit Descriptions for Common
Bits
Bit Name
Settings Description
Serial port communication, MSB-first or LSB-first selection.
MSB first.
Reset
Access
6
SPI_LSB_FIRST
0x0
RW
0
1
LSB first.
5
DEVICE_RESET
The device resets when 1 is written to this bit. DEVICE_RESET is a self clear bit.
After the reset, the bit returns to 0 automatically. The readback is always 0.
0x0
RW
POWER-DOWN CONTROL REGISTER
Address: 0x01, Reset: 0xC0, Name: PD_CONTROL
Table 24. Bit Descriptions for PD_CONTROL
Bits
Bit Name
Settings Description
The IDAC is powered down when PD_IDAC is set to 1. This bit powers down
only the analog portion of the IDAC. The IDAC digital data path is not affected.
Reset
Access
7
PD_IDAC
0x1
RW
6
5
2
1
0
PD_QDAC
The QDAC is powered down when PD_QDAC is set to 1. This bit powers down only 0x1
the analog portion of the QDAC. The QDAC digital data path is not affected.
RW
RW
RW
RW
RW
PD_DATARCV
PD_DEVICE
PD_DACCLK
PD_FRAME
The data interface circuitry is powered down when PD_DATARCV is set to 1.
This bit powers down the data interface and the write side of the FIFO.
0x0
0x0
0x0
0x0
The bandgap circuitry is powered down when set to 1. This bit powers down
the entire chip.
The DAC clocking powers down when PD_DEVICE is set to 1. This bit powers down
the DAC clocking path and, thus, the majority of the digital functions.
The frame receiver powers down when PD_FRAME is set to 1. The frame signal
is internally pulled low. Set to 1 when frame is not used.
INTERRUPT ENABLE0 REGISTER
Address: 0x03, Reset: 0x00, Name: INTERRUPT_ENABLE0
Table 25. Bit Descriptions for INTERRUPT_ENABLE0
Bits
6
Bit Name
Settings
Description
Reset
0x0
0x0
0x0
0x0
0x0
0x0
0x0
Access
RW
ENABLE_SYNC_LOST
ENABLE_SYNC_LOCKED
ENABLE_SYNC_DONE
ENABLE_PLL_LOST
Enable interrupt for sync lost.
Enable interrupt for sync lock.
Enable interrupt for sync done.
Enable interrupt for PLL lost.
Enable interrupt for PLL locked.
Enable interrupt for overthreshold.
Enable interrupt for DACOUT muted.
5
RW
4
RW
3
RW
2
ENABLE_PLL_LOCKED
ENABLE_OVER_THRESHOLD
ENABLE_DACOUT_MUTED
RW
1
RW
0
RW
INTERRUPT ENABLE1 REGISTER
Address: 0x04, Reset: 0x00, Name: INTERRUPT_ENABLE1
Table 26. Bit Descriptions for INTERRUPT_ENABLE1
Bits
2
Bit Name
Settings
Description
Reset
0x0
Access
RW
ENABLE_FIFO_UNDERFLOW
ENABLE_FIFO_OVERFLOW
ENABLE_FIFO_WARNING
Enable interrupt for FIFO underflow.
Enable interrupt for FIFO overflow.
Enable interrupt for FIFO warning.
1
0x0
RW
0
0x0
RW
Rev. 0 | Page 44 of 64
Data Sheet
AD9142
INTERRUPT FLAG0 REGISTER
Address: 0x05, Reset: 0x00, Name: INTERRUPT_FLAG0
Table 27. Bit Descriptions for INTERRUPT_FLAG0
Bits
Bit Name
Settings
Description
Reset
Access
6
SYNC_LOST
SYNC_LOST is set to 1 when sync is lost.
SYNC_LOCKED is set to 1 when sync is locked.
SYNC_DONE is set to 1 when sync is done.
PLL_LOST is set to 1 when PLL loses lock.
PLL_LOCKED is set to 1 when PLL is locked.
0x0
0x0
0x0
0x0
0x0
0x0
R
R
R
R
R
R
5
SYNC_LOCKED
SYNC_DONE
PLL_LOST
4
3
2
PLL_LOCKED
OVER_THRESHOLD
1
OVER_THRESHOLD is set to 1 when input power is
overthreshold.
0
DACOUT_MUTED
DACOUT_MUTED is set to 1 when the DAC output is muted
(midscale dc).
0x0
R
INTERRUPT FLAG1 REGISTER
Address: 0x06, Reset: 0x00, Name: INTERRUPT_FLAG1
Table 28. Bit Descriptions for INTERRUPT_FLAG1
Bits
Bit Name
Settings
Description
Reset
Access
2
FIFO_UNDERFLOW
FIFO_UNDERFLOW is set to 1 when the FIFO read pointer
catches the FIFO write pointer.
0x0
R
1
0
FIFO_OVERFLOW
FIFO_WARNING
FIFO_OVERFLOW is set to 1 when the FIFO write pointer
catches the FIFO read pointer.
0x0
0x0
R
R
FIFO_WARNING is set to 1 when the FIFO is one slot from
empty (≤1) or full (≥6).
INTERRUPT SELECT0 REGISTER
Address: 0x07, Reset: 0x00, Name: IRQ_SEL0
Table 29. Bit Descriptions for IRQ_SEL0
Bits
Bit Name
Settings
Description
Reset
Access
6
SEL_SYNC_LOST
0
1
0
1
0
1
0
1
0
1
0
1
0
1
Selects the IRQ1 pin.
Selects the IRQ2 pin.
Selects the IRQ1 pin.
Selects the IRQ2 pin.
Selects the IRQ1 pin.
Selects the IRQ2 pin.
Selects the IRQ1 pin.
Selects the IRQ2 pin.
Selects the IRQ1 pin.
Selects the IRQ2 pin.
Selects the IRQ1 pin.
Selects the IRQ2 pin.
Selects the IRQ1 pin.
Selects the IRQ2 pin.
0x0
RW
5
4
3
2
1
0
SEL_SYNC_LOCKED
SEL_SYNC_DONE
0x0
0x0
0x0
0x0
0x0
0x0
RW
RW
RW
RW
RW
RW
SEL_PLL_LOST
SEL_PLL_LOCKED
SEL_OVER_THRESHOLD
SEL_DACOUT_MUTED
Rev. 0 | Page 45 of 64
AD9142
Data Sheet
INTERRUPT SELECT1 REGISTER
Address: 0x08, Reset: 0x00, Name: IRQ_SEL1
Table 30. Bit Descriptions for IRQ_SEL1
Bits
Bit Name
Settings
Description
Reset
Access
2
SEL_FIFO_UNDERFLOW
0
1
0
1
0
1
Selects the IRQ1 pin.
Selects the IRQ2 pin.
Selects the IRQ1 pin.
Selects the IRQ2 pin.
Selects the IRQ1 pin.
Selects the IRQ2 pin.
0x0
RW
1
0
SEL_FIFO_OVERFLOW
SEL_FIFO_WARNING
0x0
0x0
RW
RW
DAC CLOCK RECEIVER CONTROL REGISTER
Address: 0x10, Reset: 0xFF, Name: DACCLK_RECEIVER_CTRL
Table 31. Bit Descriptions for DACCLK_RECEIVER_CTRL
Bits
Bit Name
Settings
Description
Reset
Access
7
DACCLK_DUTYCYCLE_CORRECTION
Enables duty cycle correction at the DACCLK input. For
best performance, the default and recommended status
is turned on.
0x1
RW
5
DACCLK_CROSSPOINT_CTRL_ENABLE
DACCLK_CROSSPOINT_LEVEL
Enables crosspoint control at the DACCLK input. For best 0x1
performance, the default and recommended status is
turned on.
RW
RW
[4:0]
A twos complement value. For best performance, it is
recommended to set DACCLK_CROSSPOINT_LEVEL to
the default value.
0x1F
01111 Highest crosspoint.
11111 Lowest crosspoint.
REF CLOCK RECEIVER CONTROL REGISTER
Address: 0x11, Reset: 0xBF, Name: REFCLK_RECEIVER_CTRL
Table 32. Bit Descriptions for REFCLK_RECEIVER_CTRL
Bits
Bit Name
Settings
Description
Reset
Access
7
DUTYCYCLE_CORRECTION
Enables duty cycle correction at the REFCLK input. For
best performance, the default and recommended status
is turned off.
0x0
RW
5
REFCLK_CROSSPOINT_CTRL_ENABLE
REFCLK_CROSSPOINT_LEVEL
Enables crosspoint control at the REFCLK input. For best 0x0
performance, the default and recommended status is
turned off.
RW
RW
[4:0]
A twos complement value. For best performance, it is
recommended to set REFCLK_CROSSPOINT_LEVEL to
the default value.
0x1F
01111 Highest crosspoint.
11111 Lowest crosspoint.
Rev. 0 | Page 46 of 64
Data Sheet
AD9142
PLL CONTROL REGISTER
Address: 0x12, Reset: 0x00, Name: PLL_CTRL0
Table 33. Bit Descriptions for PLL_CTRL0
Bits
Bit Name
Settings
Description
Reset
Access
RW
7
PLL_ENABLE
Enables PLL clock multiplier.
PLL band selection mode.
Automatic mode.
0x0
0x0
6
AUTO_MANUAL_SEL
RW
0
1
Manual mode.
[5:0]
PLL_MANUAL_BAND
PLL band setting in manual mode. 64 bands in total, covering a 1 GHz to 0x00
2.1 GHz VCO range.
RW
000000 Lowest band (1 GHz).
111111 Highest band (2.1 GHz).
PLL CONTROL REGISTER
Address: 0x14, Reset: 0xE7, Name: PLL_CTRL2
Table 34. Bit Descriptions for PLL_CTRL2
Bits
Bit Name
Settings
Description
Reset
Access
[7:5]
PLL_LOOP_BW
Selects the PLL loop filter bandwidth. The default and recommended
setting is 111 for optimal PLL performance.
0x7
RW
0x00 Lowest setting.
0x1F Highest setting.
Sets nominal PLL charge pump current. The default and recommended
setting is 00111 for optimal PLL performance.
0x00 Lowest setting.
0x1F Highest setting.
[4:0]
PLL_CP_CURRENT
0x07
RW
PLL CONTROL REGISTER
Address: 0x15, Reset: 0xC9, Name: PLL_CTRL3
Table 35. Bit Descriptions for PLL_CTRL3
Bits
Bit Name
Settings
Description
Reset
Access
[7:6]
DIGLOGIC_DIVIDER
REFCLK to PLL digital clock divide ratio. The PLL digital clock drives the
internal PLL logics. The divide ratio must be set to ensure that the PLL
digital clock is below 75 MHz.
0x3
RW
00 fREFCLK/fDIG = 2.
01 fREFCLK/fDIG = 4.
10 fREFCLK/fDIG = 8.
11 fREFCLK/fDIG = 16.
4
CROSSPOINT_CTRL_EN
VCO_DIVIDER
Enable loop divider crosspoint control. The default and recommended
setting is turned off (0) for optimal PLL performance.
0x0
0x2
RW
RW
[3:2]
PLL VCO divider. This divider determines the ratio of the VCO frequency
to the DACCLK frequency.
00 fVCO/fDACCLK = 1.
01 fVCO/fDACCLK = 2.
10 fVCO/fDACCLK = 4.
11 fVCO/fDACCLK = 4.
[1:0]
LOOP_DIVIDER
PLL loop divider. This divider determines the ratio of the DACCLK
frequency to the REFCLK frequency.
00 fDACCLK/fREFCLK = 2.
0x1
RW
01 fDACCLK/fREFCLK = 4.
10 fDACCLK/fREFCLK = 8.
11 fDACCLK/fREFCLK = 16.
Rev. 0 | Page 47 of 64
AD9142
Data Sheet
PLL STATUS REGISTER
Address: 0x16, Reset: 0x00, Name: PLL_STATUS0
Table 36. Bit Descriptions for PLL_STATUS0
Bits
Bit Name
Settings Description
Reset
0x0
Access
7
PLL_LOCK
PLL clock multiplier output is stable.
R
R
[3:0]
VCO_CTRL_VOLTAGE_READBACK
VCO control voltage readback. A binary value.
1111 The highest VCO control voltage.
0x0
0111 The mid value when a proper VCO band is selected. When
the PLL is locked, selecting a higher VCO band decreases this
value and selecting a lower VCO band increases this value.
0000 The lowest VCO control voltage.
PLL STATUS REGISTER
Address: 0x17, Reset: 0x00, Name: PLL_STATUS1
Table 37. Bit Descriptions for PLL_STATUS1
Bits
Bit Name
Settings
Description
Reset
Access
[5:0]
PLL_BAND_READBACK
Indicates the VCO band currently selected.
0x00
R
IDAC FS ADJUST LSB REGISTER
Address: 0x18, Reset: 0xF9, Name: IDAC_FS_ADJ0
Table 38. Bit Descriptions for IDAC_FS_ADJ0
Bits
Bit Name
Settings Description
Reset
Access
[7:0]
IDAC_FULLSCALE_ADJUST_LSB
See Register 0x19.
0xF9
RW
IDAC FS ADJUST MSB REGISTER
Address: 0x19, Reset: 0xE1, Name: IDAC_FS_ADJ1
Table 39. Bit Descriptions for IDAC_FS_ADJ1
Bits
Bit Name
Settings Description
Reset
Access
[1:0]
IDAC_FULLSCALE_ADJUST_MSB
IDAC full-scale adjust, Bits[9:0] sets the full-scale current of
the IDAC. The full-scale current can be adjusted from 8.64 mA
to 31.68 mA. The default value (0x1F9) sets the full-scale
current to 20 mA.
0x1
RW
QDAC FS ADJUST LSB REGISTER
Address: 0x1A, Reset: 0xF9, Name: QDAC_FS_ADJ0
Table 40. Bit Descriptions for QDAC_FS_ADJ0
Bits
Bit Name
Settings Description
Reset
Access
[7:0]
QDAC_FULLSCALE_ADJUST_LSB
See Register 0x1B.
0xF9
RW
Rev. 0 | Page 48 of 64
Data Sheet
AD9142
QDAC FS ADJUST MSB REGISTER
Address: 0x1B, Reset: 0x01, Name: QDAC_FS_ADJ1
Table 41. Bit Descriptions for QDAC_FS_ADJ1
Bits Bit Name
Settings Description
Reset Access
[1:0] QDAC_FULLSCALE_ADJUST_MSB
QDAC full-scale adjust, Bits[9:0] sets the full-scale current of the QDAC.
The full-scale current can be adjusted from 8.64 mA to 31.68 mA. The
default value (0x1F9) sets the full-scale current to 20 mA.
0x1
RW
DIE TEMPERATURE SENSOR CONTROL REGISTER
Address: 0x1C, Reset: 0x02, Name: DIE_TEMP_SENSOR_CTRL
Table 42. Bit Descriptions for DIE_TEMP_SENSOR_CTRL
Bits Bit Name
Settings Description
Temperature sensor ADC full-scale current. Using the default
setting is recommended.
000 50 μA.
Reset Access
[6:4] FS_CURRENT
0x0
0x1
0x0
RW
RW
RW
001 62.5 μA.
…
110 125 μA.
111 137.5 μA.
[3:1] REF_CURRENT
Temperature sensor ADC reference current. Using the default
setting is recommended.
000 12.5 μA.
001 19 μA.
…
110 50 μA.
111 56.5 μA.
0
DIE_TEMP_SENSOR_EN
Enable the on-chip temperature sensor.
DIE TEMPERATURE LSB REGISTER
Address: 0x1D, Reset: 0x00, Name: DIE_TEMP_LSB
Table 43. Bit Descriptions for DIE_TEMP_LSB
Bits Bit Name
Settings Description
See Register 0x1E.
Reset Access
[7:0] DIE_TEMP_LSB
0x00
R
DIE TEMPERATURE MSB REGISTER
Address: 0x1E, Reset: 0x00, Name: DIE_TEMP_MSB
Table 44. Bit Descriptions for DIE_TEMP_MSB
Bits Bit Name
Settings Description
Reset
Access
[7:0] DIE_TEMP_MSB
Die temperature, Bits[15:0] indicate the approximate die temperature. 0x00
For more information, see the Temperature Sensor section.
R
CHIP ID REGISTER
Address: 0x1F, Reset: 0x0A, Name: CHIP_ID
Table 45. Bit Descriptions for CHIP_ID
Bits Bit Name
Settings Description
Reset Access
0x0A
[7:0] CHIP_ID
The AD9142 chip ID is 0x0A.
R
Rev. 0 | Page 49 of 64
AD9142
Data Sheet
INTERRUPT CONFIGUATION REGISTER
Address: 0x20, Reset: 0x00, Name: INTERRUPT_CONFIG
Table 46. Bit Descriptions for INTERRUPT_CONFIG
Bits Bit Name
Settings Description
Reset Access
[7:0] INTERRUPT_CONFIGURATION
0x00 Test mode.
0x00
RW
0x01 Recommended mode (described in Interrupt Request
Operation section).
SYNC CTRL REGISTER
Address: 0x21, Reset: 0x00, Name: SYNC_CTRL
Table 47. Bit Descriptions for SYNC_CTRL
Bits
Bit Name
Settings
Description
Reset
Access
1
SYNC_CLK_EDGE_SEL
Selects the sampling edge of the DACCLK on the SYNC CLK.
SYNC CLK is sampled by rising edges of DACCLK.
SYNC CLK is sampled by falling edges of DACCLK.
Enables multichip synchronization.
0x0
RW
0
1
0
SYNC_ENABLE
0x0
RW
FRAME RESET CTRL REGISTER
Address: 0x22, Reset: 0x12, Name: FRAME_RST_CTRL
Table 48. Bit Descriptions for FRAME_RST_CTRL
Bits
Bit Name
Settings
Description
Reset
Access
3
FRAME_RESET_ACK
Frame reset acknowledge. This bit is set to 1 when a valid frame pulse 0x0
is received.
R
2
EN_CON_FRAME_RESET
Reset mode selection.
0x0
RW
0
1
Responds to only the first valid frame pulse and resets the FIFO and/or
NCO one time only. This is the default and recommended mode.
Responds to every valid frame pulse and resets the FIFO and/or NCO
accordingly.
[1:0]
FRAME_RESET_MODE
These bits determine what is to be reset when the device receives a
valid frame signal.
0x2
RW
00 FIFO only.
01 NCO only.
10 FIFO and NCO.
11 None.
Rev. 0 | Page 50 of 64
Data Sheet
AD9142
FIFO LEVEL CONFIGURATION REGISTER
Address: 0x23, Reset: 0x40, Name: FIFO_LEVEL_CONFIG
Table 49. Bit Descriptions for FIFO_LEVEL_CONFIG
Bits
Bit Name
Settings Description
Reset
Access
[6:4]
INTEGRAL_FIFO_LEVEL_REQUEST
Sets the integral FIFO level. This is the difference between the 0x4
RW
read pointer and the write pointer values in the unit of
input data rate (fDATA). The default and recommended FIFO
level is integral level = 4 and fractional level = 0. See the
FIFO Operation section for details.
000 0.
001 1.
…
111 7.
[2:0]
FRACTIONAL_FIFO_LEVEL_REQUEST
Sets the fractional FIFO level. This is the difference between
0x0
RW
the read pointer and the write pointer values in the unit of
DACCLK rate (FDAC). The maximum allowed setting value =
interpolation rate − 1. See the FIFO Operation section for
details.
000 0.
001 1.
…
Max 001 in 2×.
allowed
setting.
003 in 4×.
007 in 8×.
FIFO LEVEL READBACK REGISTER
Address: 0x24, Reset: 0x00, Name: FIFO_LEVEL_READBACK
Table 50. Bit Descriptions for FIFO_LEVEL_READBACK
Bits
Bit Name
Settings Description
Reset
Access
[6:4]
INTEGRAL_FIFO_LEVEL_READBACK
The integral FIFO level read back. The difference between the 0x0
R
overall FIFO level request and readback should be within
two DACCLK cycles. See the FIFO Operation section for
details.
[2:0]
FRACTIONAL_FIFO_LEVEL_READBACK
The fractional FIFO level read back. This value should be
used in combination with the readback in Bit[6:4].
0x0
R
FIFO CTRL REGISTER
Address: 0x25, Reset: 0x00, Name: FIFO_CTRL
Table 51. Bit Descriptions for FIFO_CTRL
Bits
Bit Name
Settings Description
Reset
0x0
Access
R
1
FIFO_SPI_RESET_ACK
FIFO_SPI_RESET_REQUEST
Acknowledge a serial port initialized FIFO reset.
Initialize a FIFO reset via the serial port.
0
0x0
RW
Rev. 0 | Page 51 of 64
AD9142
Data Sheet
DATA FORMAT SELECT REGISTER
Address: 0x26, Reset: 0x00, Name: DATA_FORMAT_SEL
Table 52. Bit Descriptions for DATA_FORMAT_SEL
Bits
Bit Name
Settings
Description
Reset
Access
7
DATA_FORMAT
Select binary or twos complement data format.
Input data in twos complement format.
Input data in binary format.
0x0
RW
0
1
6
5
DATA_PAIRING
Indicate I/Q data pairing on data input.
I samples are paired with the next Q samples.
I samples are paired with the prior Q samples.
0x0
0x0
RW
RW
0
1
DATA_BUS_INVERT
Swap the bit order of the data input port. MSBs become the LSBs:
D[15:0] changes to D[0:15].
0
1
The order of the data bits corresponds to the pin descriptions in Table 9.
The order of the data bits is inverted.
0
DATA_BUS_WIDTH
Data interface mode. See the LVDS Input Data Ports section for
information about the operation of the different interface modes.
0x0
RW
0
1
Word mode; 16-bit interface bus width.
Byte mode; 8-bit interface bus width.
DATAPATH CONTROL REGISTER
Address: 0x27, Reset: 0x00, Name: DATAPATH_CTRL
Table 53. Bit Descriptions for DATAPATH_CTRL
Bits
7
Bit Name
Settings
Description
Reset
0x0
0x0
0x0
0x0
0x0
0x0
Access
RW
INVSINC_ENABLE
Enable the inverse sinc filter.
6
NCO_ENABLE
Enable the NCO.
RW
5
IQ_GAIN_ADJ_DCOFFSET_ENABLE
IQ_PHASE_ADJ_ENABLE
FS4_MODULATION_ENABLE
NCO_SIDEBAND_SEL
Enable digital IQ gain adjustment and dc offset.
Enable digital IQ phase adjustment.
Enable fS/4 modulation function.
Selects the single-side NCO modulation image.
The NCO outputs the high-side image.
The NCO outputs the low-side image.
RW
4
RW
2
RW
1
RW
0
1
0
SEND_IDATA_TO_QDAC
Send the IDATA to the QDAC. When enabled, I data is sent
to both the IDAC and the QDAC. The Q data path still runs,
and the Q data is ignored.
0x0
RW
INTERPOLATION CONTROL REGISTER
Address: 0x28, Reset: 0x00, Name: INTERPOLATION_CTRL
Table 54. Bit Descriptions for INTERPOLATION_CTRL
Bits
Bit Name
Settings
Description
Reset
Access
[1:0]
INTERPOLATION_MODE
Interpolation rate and mode selection.
00 2× Mode 1; use HB1 filter.
0x0
RW
10 4× mode; use HB1 and HB2 filters.
11 8× mode; use all three filters (HB1, HB2, and HB3).
Rev. 0 | Page 52 of 64
Data Sheet
AD9142
OVER THRESHOLD CTRL0 REGISTER
Address: 0x29, Reset: 0x00, Name: OVER_THRESHOLD_CTRL0
Table 55. Bit Descriptions for OVER_THRESHOLD_CTRL0
Bits
Bit Name
Settings
Description
Reset
0x0
Access
RW
[7:0]
THRESHOLD_LEVEL_REQUEST_LSB
See Register 0x2A.
OVER THRESHOLD CTRL1 REGISTER
Address: 0x2A, Reset: 0x00, Name: OVER_THRESHOLD_CTRL1
Table 56. Bit Descriptions for OVER_THRESHOLD_CTRL1
Bits
Bit Name
Settings
Description
Reset
0x00
Access
RW
[4:0]
THRESHOLD_LEVEL_REQUEST_MSB
Minimum average input power (I2 + Q2) to trigger the
input power protection function.
OVER THRESHOLD CTRL2 REGISTER
Address: 0x2B, Reset: 0x00, Name: OVER_THRESHOLD_CTRL2
Table 57. Bit Descriptions for OVER_THRESHOLD_CTRL2
Bits Bit Name
Settings
Description
Reset
0x0
Access
RW
7
6
ENABLE_PROTECTION
IQ_DATA_SWAP
Enable input power protection.
Swap I and Q data in average power calculation.
Number of data input samples for power averaging.
0x0
RW
[3:0] SAMPLE_WINDOW_LENGTH
0x0
RW
0000 512 IQ data sample pairs.
0001 1024 IQ data sample pairs.
…
1010 219 IQ data sample pairs.
1011 to invalid.
1111
INPUT POWER READBACK LSB REGISTER
Address: 0x2C, Reset: 0x00, Name: INPUT_POWER_READBACK_LSB
Table 58. Bit Descriptions for INPUT_POWER_READBACK_LSB
Bits Bit Name
Settings
Description
Reset
Access
[7:0] INPUT_POWER_READBACK_LSB
See Register 0x2D.
0x0
R
INPUT POWER READBACK MSB REGISTER
Address: 0x2D, Reset: 0x00, Name: INPUT_POWER_READBACK_MSB
Table 59. Bit Descriptions for INPUT_POWER_READBACK_MSB
Bits Bit Name
Settings
Description
Reset
Access
[4:0] INPUT_POWER_READBACK_MSB
Input signal average power readback.
0x00
R
Rev. 0 | Page 53 of 64
AD9142
Data Sheet
NCO CONTROL REGISTER
Address: 0x30, Reset: 0x00, Name: NCO_CTRL
Table 60. Bit Descriptions for NCO_CTRL
Bits Bit Name
Settings
Description
Reset
0x0
Access
6
5
4
1
0
NCO_FRAME_UPDATE_ACK
Frequency tuning word update request from frame.
NCO phase SPI reset acknowledge.
NCO phase SPI reset request.
R
SPI_NCO_PHASE_RST_ACK
SPI_NCO_PHASE_RST_REQ
NCO_SPI_UPDATE_ACK
NCO_SPI_UPDATE_REQ
0x0
R
0x0
RW
R
Frequency tuning word update acknowledge.
Frequency tuning word update request from SPI.
0x0
0x0
RW
NCO_FREQ_TUNING_WORD0 REGISTER
Address: 0x31, Reset: 0x00, Name: NCO_FREQ_TUNING_WORD0
Table 61. Bit Descriptions for NCO_FREQ_TUNING_WORD0
Bits Bit Name
Settings
Description
Reset
Access
[7:0] NCO_FTW0
See Register 0x34.
0x00
RW
NCO_FREQ_TUNING_WORD1 REGISTER
Address: 0x32, Reset: 0x00, Name: NCO_FREQ_TUNING_WORD1
Table 62. Bit Descriptions for NCO_FREQ_TUNING_WORD1
Bits Bit Name
Settings
Description
Reset
Access
[7:0] NCO_FTW1
See Register 0x34.
0x00
RW
NCO_FREQ_TUNING_WORD2 REGISTER
Address: 0x33, Reset: 0x00, Name: NCO_FREQ_TUNING_WORD2
Table 63. Bit Descriptions for NCO_FREQ_TUNING_WORD2
Bits Bit Name
Settings
Description
Reset
Access
[7:0] NCO_FTW2
See Register 0x34.
0x00
RW
NCO_FREQ_TUNING_WORD3 REGISTER
Address: 0x34, Reset: 0x10, Name: NCO_FREQ_TUNING_WORD3
Table 64. Bit Descriptions for NCO_FREQ_TUNING_WORD3
Bits Bit Name
Settings Description
FTW[31:0] is the 32-bit frequency tuning word that determines the
Reset
Access
[7:0] NCO_FTW3
0x10
RW
frequency of the complex carrier generated by the on-chip NCO.
The frequency is not updated when the FTW registers are written. The
values are only updated when a serial port update or frame update is
initialized in Register 0x30. It is in twos complement format.
NCO_PHASE_OFFSET0 REGISTER
Address: 0x35, Reset: 0x00, Name: NCO_PHASE_OFFSET0
Table 65. Bit Descriptions for NCO_PHASE_OFFSET0
Bits Bit Name
Settings Description
See Register 0x36.
Reset
Access
[7:0] NCO_PHASE_OFFSET_LSB
0x00
RW
Rev. 0 | Page 54 of 64
Data Sheet
AD9142
NCO_PHASE_OFFSET1 REGISTER
Address: 0x36, Reset: 0x00, Name: NCO_PHASE_OFFSET1
Table 66. Bit Descriptions for NCO_PHASE_OFFSET1
Bits Bit Name
Settings
Description
Reset
Access
[7:0] NCO_PHASE_OFFSET_MSB
This register sets the initial phase of the complex carrier signal upon reset.
The phase offset spans from 0 degrees to 360 degrees. Each bit represents
an offset of 0.0055 degrees. This value is in twos complement format.
0x00
RW
IQ_PHASE_ADJ0 REGISTER
Address: 0x37, Reset: 0x00, Name: IQ_PHASE_ADJ0
Table 67. Bit Descriptions for IQ_PHASE_ADJ0
Bits Bit Name
Settings
Description
Reset
Access
[7:0] IQ_PHASE_ADJ_LSB
See Register 0x38.
0x00
RW
IQ_PHASE_ADJ1 REGISTER
Address: 0x38, Reset: 0x000, Name: IQ_PHASE_ADJ1
Table 68. Bit Descriptions for IQ_PHASE_ADJ1
Bits Bit Name
Settings
Description
Reset
Access
[4:0] IQ_PHASE_ADJ_MSB
IQ phase adjust, Bits[12:0], is used to insert a phase offset between the 0x0
I and Q datapaths. It provides an adjustment range of 14 degrees with
a step of 0.0035 degrees. This value is in twos complement. See the
Quadrature Phase Adjustment section for more information.
RW
IDAC_DC_OFFSET0 REGISTER
Address: 0x3B, Reset: 0x00, Name: IDAC_DC_OFFSET0
Table 69. Bit Descriptions for IDAC_DC_OFFSET0
Bits Bit Name
Settings
Description
Reset
Access
[7:0] IDAC_DC_OFFSET_LSB
See Register 0x3C.
0x00
RW
IDAC_DC_OFFSET1 REGISTER
Address: 0x3C, Reset: 0x00, Name: IDAC_DC_OFFSET1
Table 70. Bit Descriptions for IDAC_DC_OFFSET1
Bits Bit Name
Settings
Description
Reset
Access
[7:0] IDAC_DC_OFFSET_MSB
IDAC DC offset, Bits[15:0], is a dc value that is added directly to the
sample values written to the IDAC.
0x00
RW
QDAC_DC_OFFSET0 REGISTER
Address: 0x3D, Reset: 0x00, Name: QDAC_DC_OFFSET0
Table 71. Bit Descriptions for QDAC_DC_OFFSET0
Bits Bit Name
Settings
Description
Reset
Access
[7:0] QDAC_DC_OFFSET_LSB
See Register 0x3E.
0x00
RW
Rev. 0 | Page 55 of 64
AD9142
Data Sheet
QDAC_DC_OFFSET1 REGISTER
Address: 0x3E, Reset: 0x00, Name: QDAC_DC_OFFSET1
Table 72. Bit Descriptions for QDAC_DC_OFFSET1
Bits
Bit Name
Settings
Description
Reset
Access
[7:0]
QDAC_DC_OFFSET_MSB
QDAC DC offset, Bits[15:0], is a dc value that is added directly to the
sample values written to the QDAC.
0x00
RW
IDAC_GAIN_ADJ REGISTER
Address: 0x3F, Reset: 0x20, Name: IDAC_GAIN_ADJ
Table 73. Bit Descriptions for IDAC_GAIN_ADJ
Bits
Bit Name
Settings
Description
Reset
Access
[5:0]
IDAC_GAIN_ADJ
This register is the 6-bit digital gain adjust on the I channel. The bit
weighting is MSB = 20, LSB = 2−5, which yields a multiplier range of 0 to 2 or
−∞ to 6 dB. The default gain setting is 0x20, which maps to unity gain (0 dB).
0x20
RW
QDAC_GAIN_ADJ REGISTER
Address: 0x40, Reset: 0x20, Name: QDAC_GAIN_ADJ
Table 74. Bit Descriptions for QDAC_GAIN_ADJ
Bits
Bit Name
Settings
Description
Reset
Access
[5:0]
QDAC_GAIN_ADJ
This register is the 6-bit digital gain adjust on the Q channel. The bit
weighting is MSB = 20, LSB = 2−5, which yields a multiplier range of 0 to 2 or
−∞ to 6 dB. The default gain setting is 0x20, which maps to unity gain (0 dB).
0x20
RW
GAIN STEP CONTROL0 REGISTER
Address: 0x41, Reset: 0x01, Name: GAIN_STEP_CTRL0
Table 75. Bit Descriptions for GAIN_STEP_CTRL0
Bits
Bit Name
Settings
Description
Reset
Access
[5:0]
RAMP_UP_STEP
This register sets the step size of the increasing gain. The digital gain
increases by the configured amount in every four DAC cycles until the
gain reaches the setting in I/QDAC_GAIN_ADJ (Register 0x3F and
Register 0x40). The bit weighting is MSB = 21, LSB = 2−4. Note that the
value in this register should not be greater than the values in the
I/QDAC_GAIN_ADJ (Register 0x3F and Register 0x40).
0x01
RW
GAIN STEP CONTROL1 REGISTER
Address: 0x42, Reset: 0x01, Name: GAIN_STEP_CTRL1
Table 76. Bit Descriptions for GAIN_STEP_CTRL1
Bits
Bit Name
Settings
Description
Reset
Access
7
DAC_OUTPUT_STATUS
This bit indicates the DAC output on/off status. When the DAC output
is automatically turned off, this bit is 1.
0x0
RW
6
DAC_OUTPUT_ON
RAMP_DOWN_STEP
In the case where the DAC output is automatically turned off in the
input power protection mode or TX enable mode, this register allows
for turning on the DAC output manually. It is a self clear bit.
0x0
R
[5:0]
This register sets the step size of the decreasing gain. The digital gain
decreases by the configured amount in every four DAC cycles until the
gain reaches zero. The bit weighting is MSB = 21, LSB = 2−4. Note that the
value in this register should not be greater than the values in the
I/QDAC_GAIN_ADJ (Register 0x3F and Register 0x40).
0x01
RW
Rev. 0 | Page 56 of 64
Data Sheet
AD9142
TX ENABLE CONTROL REGISTER
Address: 0x43, Reset: 0x07, Name: TX_ENABLE_CTRL
Table 77. Bit Descriptions for TX_ENABLE_CTRL
Bits Bit Name
Settings
Description
Reset
Access
2
TXENABLE_GAINSTEP_EN
DAC output gradually turns on/off under the control of the
TXENABLE signal from the TXEN pin according to the settings
in Register 0x41 and Register 0x42.
0x1
RW
1
0
TXENABLE_SLEEP_EN
When set to 1, the device is put in sleep mode when the
TXENABLE signal from the TXEN pin is low.
0x1
0x1
RW
RW
TXENABLE_POWER_DOWN_EN
When set to 1, the device is put in power down mode when
TXENABLE signal from the TXEN pin is low.
DAC OUTPUT CONTROL REGISTER
Address: 0x44, Reset: 0x8F, Name: DAC_OUTPUT_CTRL
Table 78. Bit Descriptions for DAC_OUTPUT_CTRL
Bits Bit Name
Settings
Description
Reset
Access
7
DAC_OUTPUT_CTRL_EN
Enable the DAC output control. This bit needs to be set to 1 to 0x1
enable the rest of the bits in this register.
RW
3
FIFO_WARNING_SHUTDOWN_EN
When this bit and Bit 7 are both high, if a FIFO warning occurs, 0x1
the DAC output shuts down automatically. By default, this
function is on.
RW
2
0
OVERTHRESHOLD_SHUTDOWN_EN
FIFO_ERROR_SHUTDOWN_EN
The DAC output is turned off when the input average power is 0x1
greater than the predefined threshold.
RW
RW
The DAC output is turned off when the FIFO reports warnings. 0x1
DATA RECEIVER TEST CONTROL REGISTER
Address: 0x5E, Reset: 0xFF, Name: DATA_RX_CTRL0
Table 79. Bit Descriptions for DATA_RX_CTRL0
Bits Bit Name
Settings
Description
Reset
Access
[7:0] DLY_TAP_LSB
See Register 0x5F[2:0].
0xFF
RW
DATA RECEIVER TEST CONTROL REGISTER
Address: 0x5F, Reset: 0x07, Name: DATA_RX_CTRL1
Table 80. Bit Descriptions for DATA_RX_CTRL1
Bits Bit Name
DLYLINE_EN
[2:0] DLY_TAP_MSB
Settings
Description
Reset
0x0
Access
RW
3
1 = Enable the data interface.
Four available delay settings. See the Interface Delay Line section for more
information.
0x7
RW
00 0x000
01 0x007
10 0x07F
11 0x5FF
Rev. 0 | Page 57 of 64
AD9142
Data Sheet
DEVICE CONFIGURATION0 REGISTER
Address: 0x79, Reset: 0x00, Name: DEVICE_CONFIG0
Table 81. Bit Descriptions for DEVICE_CONFIG0
Bits
Bit Name
Settings Description
Reset
Access
[7:0]
DEVICE_
0x18 Recommended setting for device start-up configuration
0x00
RW
CONFIGURATION0
VERSION REGISTER
Address: 0x7F, Reset: 0x05, Name: Version
Table 82. Bit Descriptions for Version
Bits
Bit Name
Settings Description
Reset
Access
[7:0]
Version
Chip version
0x05
R
DEVICE CONFIGURATION1 REGISTER
Address: 0x80, Reset: 0x00, Name: DEVICE_CONFIG1
Table 83. Bit Descriptions for DEVICE_CONFIG1
Bits
Bit Name
Settings Description
Reset
Access
[7:0]
DEVICE_
0xAD Recommended setting for device start-up configuration
0x00
RW
CONFIGURATION1
DEVICE CONFIGURATION2 REGISTER
Address: 0xE1, Reset: 0x00, Name: DEVICE_CONFIG2
Table 84. Bit Descriptions for DEVICE_CONFIG2
Bits
Bit Name
Settings Description
Reset
Access
[7:0]
DEVICE_
0x1A Recommended setting for device start-up configuration
0x00
RW
CONFIGURATION2
Rev. 0 | Page 58 of 64
Data Sheet
AD9142
DAC LATENCY AND SYSTEM SKEWS
DACCLK/8
DACCLK
DIV 2
DIV 2
DIV 2
DACCLK/4
DACCLK/2
FIFO
RdPtr
I AND
Q DAC
DATA
INTERFACE
OTHER DIGITAL
FUNCTIONALITIES
FIFO
HB1
HB2
HB3
FIFO
WrPtr
DCI
FIXED
LATENCY
VARYING
LATENCY
VARYING
LATENCY
FIXED
LATENCY
Figure 60. Breakdown of Pipeline Latencies
FIFO
FIFO
DAC LATENCY VARIATIONS
DATA 0
DATA 1
DATA 0
DATA 1
FIFO
WrPtr
DACs, like any other devices with internal multiphase clocks,
have an inherent pipeline latency variation. Figure 60 shows the
breakdown of pipeline latencies in the AD9142. The highlighted
section, including the FIFO and the clock generation circuitry, is
where the pipeline latencies vary. Upon each power-on, the status
of both the FIFO and the clock generation state machine is
arbitrary. This leads to varying latency in these two blocks.
FIFO
RdPtr
DATA 2
DATA 3
DATA 4
DATA 5
DATA 2
DATA 3
DATA 4
DATA 5
FIFO
RdPtr
FIFO
WrPtr
DATA 6
DATA 7
DATA 6
DATA 7
FIFO LATENCY VARIATION
CASE 1:
CASE 2:
There are eight data slots in the FIFO. The FIFO read and write
pointers circulate the FIFO from Slot 0 to Slot 7 and back to Slot 0.
The FIFO depth is defined as the number of FIFO slots that are
required for the read pointer to catch the write pointer. It is also
the time a particular piece of data stays in the FIFO from the
point that it is written into the FIFO to the point where it is read
out from the FIFO. Therefore, the latency of the FIFO is equivalent
to its depth.
LATENCY = 4 DCI CYCLES
LATENCY = 6 DCI CYCLES
Figure 61. Example of FIFO Latency Difference
Figure 62 shows two equivalent cases of FIFO latency of four data
cycles. Although neither the read nor the write pointer match
each other in these two cases, the FIFO depth is the same in both
cases. Also, note that the beginning slots of the data stream in the
two cases are not the same, but the read and write pointers point
to the same piece of data in both cases. This does not affect the
alignment accuracy of the DAC outputs as long as the data and
the DCIs are well aligned at multiple devices.
Figure 61 is an example of FIFO latency variation. The latency in
Case 2 is two data cycles longer than that in Case 1. If other
latencies are the same, the skew between the DAC outputs in
these two cases is, likewise, two data cycles. Therefore, to keep a
constant FIFO latency, the FIFO depth needs to be reset to a pre-
defined value. Theoretically, any value other than 0 is valid but
typically it is set to 4 to maximize the capacity of absorbing the
rate fluctuation between the read and write side.
FIFO
FIFO
DATA 0
DATA 1
DATA 5
DATA 6
FIFO
WrPtr
FIFO
RdPtr
DATA 2
DATA 3
DATA 4
DATA 5
DATA 7
DATA 0
DATA 1
DATA 2
LATENCY = 4 DCI CYCLES
FIFO
RdPtr
FIFO
WrPtr
DATA 6
DATA 7
DATA 3
DATA 4
Figure 62. Example of Equal FIFO Latencies
Rev. 0 | Page 59 of 64
AD9142
Data Sheet
CLOCK GENERATION LATENCY VARIATION
CORRECTING SYSTEM SKEWS
The state machine of the clock generation circuitry is another
source of latency variations; this type of latency variation results
from inherent phase uncertainty of the static frequency dividers.
The divided down clock can be high or low at the rising edge of
the input clock, unless specifically forced to a known state. This
means that whenever there is interpolation (when slower clocks
need to be internally generated by dividing down the DACCLK),
there is an inherent latency variation in the DAC. Figure 63 is an
example of this latency variation in 2× interpolation. There are
two phase possibilities in the DACCLK/2 clock. The DACCLK/2
clock is used to read data from the FIFO and to drive the interpo-
lation filter. Regardless of which clock edge is used to drive the
digital circuit, there is a latency of one DAC clock cycle between
Case 1 and Case 2 (see Figure 62). Because the power-on state
arbitrarily falls in one of the two cases, the phase uncertainty of
the divider appears as a varying skew between two DAC outputs.
Generally, it is assumed that the input data and the DCI among
multiple devices are well aligned to each other. Depending on the
system design, the data and DCI being input into each DAC can
originate from various FPGAs or ASICs. Without synchronizing
the data sources, the output of one data source can be skewed
from that of another. The alignment between multiple data
sources can also drift over temperature.
Figure 64 shows an example of a 2-channel transmitter with two
data sources and two dual DACs. A constant but unknown phase
offset appears between the outputs of the DAC devices, even if
the DAC does not introduce any latency variations. The
multidevice synchronization in the AD9142 can be used to
compensate the skew due to misalignment of the data sources by
resetting the two sides of the FIFO independently through two
external reference clocks: the frame and the sync clock. The offset
between the two data sources is then absorbed by the FIFO and
clock generation block in the DAC. For more information about
using the multidevice synchronization function, refer to the
Synchronization Implementation section.
HB1
HB2
HB3
DCI
FRAME
DAC
16-BIT DATA
DATA
DACCLK
GEN
DCI
FRAME
DAC
16-BIT DATA
DACCLK/2
(CASE 1)
DCI
FRAME
DAC
DACCLK/2
(CASE 2)
16-BIT DATA
DATA
GEN
DCI
LATENCY VARIATION = 1 DACCLK CYCLE
FRAME
DAC
Figure 63. Latency Variation in 2× Interpolation from Clock Generation
16-BIT DATA
2
4
MASTER
SYNC CLOCK
REF CLOCK
DATA SKEW
Figure 64. DAC Output Skew from Skewed Input Data and DCI
Rev. 0 | Page 60 of 64
Data Sheet
AD9142
PACKAGING AND ORDERING INFORMATION
OUTLINE DIMENSIONS
10.10
10.00 SQ
9.90
0.60
0.42
0.24
0.30
0.23
0.18
0.60
0.42
0.24
PIN 1
INDICATOR
55
54
72
1
PIN 1
INDICATOR
9.85
0.50
BSC
9.75 SQ
9.65
6.15
6.00 SQ
5.85
EXPOSED
PAD
0.50
0.40
0.30
18
19
37
36
0.25 MIN
TOP VIEW
BOTTOM VIEW
8.50 REF
0.80 MAX
0.65 TYP
12° MAX
1.00
0.85
0.80
0.05 MAX
0.02 NOM
FOR PROPER CONNECTION OF
THE EXPOSED PAD, REFER TO
THE PIN CONFIGURATION AND
FUNCTION DESCRIPTIONS
COPLANARITY
0.08
SEATING
PLANE
0.20 REF
SECTION OF THIS DATA SHEET.
COMPLIANT TO JEDEC STANDARDS MO-220-VNND-4
Figure 65. 72-Lead Lead Frame Chip Scale Package [LFCSP_VQ]
10 mm × 10 mm Body, Very Thin Quad
(CP-72-7)
Dimensions shown in millimeters
ORDERING GUIDE
Model1
Temperature Range
−40°C to +85°C
−40°C to +85°C
Package Description
Package Option
AD9142BCPZ
72-lead LFCSP_VQ
72-lead LFCSP_VQ
Evaluation Board Connected to ADL5372 Modulator
Evaluation Board Connected to ADL5375 Modulator
CP-72-7
CP-72-7
AD9142BCPZRL
AD9142-M5372-EBZ
AD9142-M5375-EBZ
1 Z = RoHS Compliant Part.
Rev. 0 | Page 61 of 64
AD9142
NOTES
Data Sheet
Rev. 0 | Page 62 of 64
Data Sheet
NOTES
AD9142
Rev. 0 | Page 63 of 64
AD9142
NOTES
Data Sheet
©2012 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D10930-0-11/12(0)
Rev. 0 | Page 64 of 64
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