AD AD9775EB

a
14-Bit, 160 MSPS 2ⴛ/4ⴛ/8ⴛ
Interpolating Dual TxDAC+ D/A Converter
AD9775*
®
FEATURES
14-Bit Resolution, 160/400 MSPS Input/Output Data Rate
Selectable 2ⴛ/4ⴛ/8ⴛ Interpolating Filter
Programmable Channel Gain and Offset Adjustment
f S/4, fS/8 Digital Quadrature Modulation
Capability
Direct IF Transmission Mode for 70 MHz + IFs
Enables Image Rejection Architecture
Fully Compatible SPI Port
Excellent AC Performance
SFDR –71 dBc @ 2 MHz–35 MHz
WCDMA ACPR –71 dB @ IF = 71 MHz
Internal PLL Clock Multiplier
Selectable Internal Clock Divider
Versatile Clock Input
Differential/Single-Ended Sine Wave or
TTL/CMOS/LVPECL Compatible
Versatile Input Data Interface
Two’s Complement/Straight Binary Data Coding
Dual-Port or Single-Port Interleaved Input Data
Single 3.3 V Supply Operation
Power Dissipation: Typical 1.2 W @ 3.3 V
On-Chip 1.2 V Reference
80-Lead Thermally Enhanced TQFP Package
APPLICATIONS
Communications
Analog Quadrature Modulation Architectures
3G, Multicarrier GSM, TDMA, CDMA Systems
Broadband Wireless, Point-to-Point Microwave Radios
Instrumentation/ATE
GENERAL DESCRIPTION
The AD9775 is the 14-bit member of the AD977x pin-compatible,
high performance, programmable 2×/4×/8× interpolating TxDAC+
family. The AD977x family features a serial port interface (SPI)
providing a high level of programmability, thus allowing for
enhanced system-level options. These options include: selectable 2×/4×/8× interpolation filters; fS/2, fS/4, or fS/8 digital
quadrature modulation with image rejection; a direct IF mode;
programmable channel gain and offset control; programmable
internal clock divider; straight binary or two’s complement data
interface; and a single-port or dual-port data interface.
The selectable 2×/4×/8× interpolation filters simplify the requirements of the reconstruction filters while simultaneously enhancing
the TxDAC+ family’s pass-band noise/distortion performance.
The independent channel gain and offset adjust registers allow
the user to calibrate LO feedthrough and sideband suppression
(continued on page 2)
FUNCTIONAL BLOCK DIAGRAM
IDAC
COS
AD9775
I AND Q
NONINTERLEAVED
OR
INTERLEAVED
DATA
SELECT
GAIN
DAC
OFFSET
DAC
SIN
I
LATCH
16
Q
LATCH
16
16
16
16
fDAC/2, 4, 8
IMAGE
REJECTION/
DUAL DAC
MODE
BYPASS
MUX
I/Q DAC
GAIN/OFFSET
REGISTERS
SIN
16
WRITE
HALFHALFBAND
BAND
FILTER 2* FILTER 3*
IOFFSET
16
HALFBAND
FILTER 1*
VREF
DATA
ASSEMBLER
MUX
CONTROL
16
16
16
FILTER
BYPASS
MUX
COS
IDAC
IOUT
/2
(fDAC)
CLOCK OUT
/2
/2
/2
PRESCALER
SPI INTERFACE AND
CONTROL REGISTERS
* HALF-BAND FILTERS ALSO CAN BE
CONFIGURED FOR "ZERO STUFFING ONLY"
DIFFERENTIAL
CLK
PHASE DETECTOR
AND VCO
PLL CLOCK MULTIPLIER AND CLOCK DIVIDER
TxDAC+ is a registered trademark of Analog Devices, Inc.
*Protected bu U.S. Patent Numbers 5568145, 5689257, and 5703519. Other Patents pending.
REV. 0
Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
use, nor for any infringements of patents or other rights of third parties that
may result from its use. No license is granted by implication or otherwise
under any patent or patent rights of Analog Devices.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781/329-4700
www.analog.com
Fax: 781/326-8703
© Analog Devices, Inc., 2002
AD9775
(continued from page 1)
PRODUCT HIGHLIGHTS
errors associated with analog quadrature modulators. The 6 dB
of gain adjustment range can also be used to control the output
power level of each DAC.
1.
The AD9775 is the 14-bit member of the AD977x pincompatible, high performance, programmable 2×/4×/8×
interpolating TxDAC+ family.
The AD9775 features the ability to perform fS/2, fS/4, and fS/8
digital modulation and image rejection when combined with an
analog quadrature modulator. In this mode, the AD9775 accepts I and Q complex data (representing a single or multicarrier
waveform), generates a quadrature modulated IF signal along with
its orthogonal representation via its dual DACs, and presents
these two reconstructed orthogonal IF carriers to an analog
quadrature modulator to complete the image rejection
upconversion process. Another digital modulation mode (i.e.,
the Direct IF Mode) allows the original baseband signal representation to be frequency translated such that pairs of images fall
at multiples of one-half the DAC update rate.
2.
Direct IF transmission capability for 70 MHz + IFs through
a novel digital mixing process.
3.
fS/2, fS/4, and fS/8 digital quadrature modulation and userselectable image rejection to simplify/remove cascaded
SAW filter stages.
4.
A 2×/4×/8× user-selectable interpolating filter eases data
rate and output signal reconstruction filter requirements.
5.
User-selectable two’s complement/straight binary data
coding.
6.
User-programmable channel gain control over 1 dB
range in 0.01 dB increments.
7.
User-programmable channel offset control ± 10% over
the FSR.
8.
Ultra high speed 400 MSPS DAC conversion rate.
9.
Internal clock divider provides data rate clock for easy
interfacing.
The AD977x family includes a flexible clock interface accepting
differential or single-ended sine wave or digital logic inputs. An
internal PLL clock multiplier is included and generates the
necessary on-chip high frequency clocks. It can also be disabled
to allow the use of a higher performance external clock source.
An internal programmable divider simplifies clock generation in
the converter when using an external clock source. A flexible data
input interface allows for straight binary or two’s complement
formats and supports single-port interleaved or dual-port data.
10. Flexible clock input with single-ended or differential input,
CMOS, or 1 V p-p LO sine wave input capability.
Dual high performance DAC outputs provide a differential
current output programmable over a 2 mA to 20 mA range. The
AD9775 is manufactured on an advanced 0.35 micron CMOS
process, operates from a single supply of 3.1 V to 3.5 V, and
consumes 1.2 W of power.
11. Low power: Complete CMOS DAC operates on 1.2 W
from a 3.1 V to 3.5 V single supply. The 20 mA full-scale
current can be reduced for lower power operation and
several sleep functions are provided to reduce power during idle periods.
Targeted at wide dynamic range, multicarrier and multistandard
systems, the superb baseband performance of the AD9775 is ideal
for wideband CDMA, multicarrier CDMA, multicarrier TDMA,
multicarrier GSM, and high performance systems employing
high order QAM modulation schemes. The image rejection
feature simplifies and can help to reduce the number of signal
band filters needed in a transmit signal chain. The direct IF
mode helps to eliminate a costly mixer stage for a variety of
communications systems.
12. On-chip voltage reference: The AD9775 includes a 1.20 V
temperature compensated band gap voltage reference.
13. 80-lead thermally enhanced TQFP.
–2–
REV. 0
AD9775
AD9775–SPECIFICATIONS
DC SPECIFICATIONS
(TMIN to TMAX, AVDD = 3.3 V, CLKVDD = 3.3 V, DVDD = 3.3 V, PLLVDD = 3.3 V, IOUTFS = 20 mA, unless
otherwise noted.)
Parameter
Min
RESOLUTION
DC Accuracy1
Integral Nonlinearity
Differential Nonlinearity
14
ANALOG OUTPUT (for IR and 2R Gain Setting Modes)
Offset Error
Gain Error (With Internal Reference)
Gain Matching
Full-Scale Output Current2
Output Compliance Range
Output Resistance
Output Capacitance
Gain, Offset Cal DACs, Monotonicity Guaranteed
Max
–5
–3
± 1.5
± 1.0
+5
+3
LSB
LSB
–0.02
–1.0
–1.0
2
–1.0
± 0.01
+0.02
+1.0
+1.0
20
+1.25
% of FSR
% of FSR
% of FSR
mA
V
kΩ
pF
1.26
V
nA
1.25
V
MΩ
MHz
1.14
REFERENCE INPUT
Input Compliance Range
Reference Input Resistance (REFLO = 3 V)
Small Signal Bandwidth
± 0.1
1.20
100
0.1
10
0.5
TEMPERATURE COEFFICIENTS
Offset Drift
Gain Drift (With Internal Reference)
Reference Voltage Drift
0
50
POWER SUPPLY
AVDD
Voltage Range
Analog Supply Current (IAVDD)4
IAVDD in SLEEP Mode
CLKVDD
Voltage Range
Clock Supply Current (ICLKVDD)4
CLKVDD (PLL ON)
Clock Supply Current (ICLKVDD)
DVDD
Voltage Range
Digital Supply Current (IDVDD)4
Nominal Power Dissipation
PDIS5
PDIS IN PWDN
Power Supply Rejection Ratio—AVDD
ppm of FSR/°C
ppm of FSR/°C
ppm/°C
3.1
3.3
72.5
23.3
3.5
76
26
V
mA
mA
3.1
3.3
8.5
3.5
V
mA
23.5
3.1
OPERATING RANGE
–40
NOTES
1
Measured at I OUTA driving a virtual ground.
2
Nominal full-scale current, I OUTFS, is 32× the IREF current.
3
Use an external amplifier to drive any external load.
4
100 MSPS fDAC with fOUT = 1 MHz, all supplies = 3.3 V, no interpolation, no modulation.
5
400 MSPS f DAC = 50 MSPS, f S/2 modulation, PLL enabled.
Specifications subject to change without notice.
–3–
Unit
Bits
200
3
REFERENCE OUTPUT
Reference Voltage
Reference Output Current3
REV. 0
Typ
3.3
34
380
1.75
6.0
± 0.4
mA
3.5
41
410
V
mA
mW
W
mW
% of FSR/V
+85
°C
AD9775
DYNAMIC SPECIFICATIONS
(TMIN to TMAX, AVDD = 3.3 V, CLKVDD = 3.3 V, DVDD = 3.3 V, PLLVDD = 0 V, IOUTFS = 20 mA,
Interpolation = 2ⴛ, Differential Transformer Coupled Output, 50 ⍀ Doubly Terminated,
unless otherwise noted.)
Parameter
Min
DYNAMIC PERFORMANCE
Maximum DAC Output Update Rate (fDAC)
Output Settling Time (tST) (to 0.025%)
Output Rise Time (10% to 90%)*
Output Fall Time (10% to 90%)*
Output Noise (IOUTFS = 20 mA)
Typ
400
AC LINEARITY—–BASEBAND MODE
Spurious-Free Dynamic Range (SFDR) to Nyquist (fOUT = 0 dBFS)
fDATA = 100 MSPS, fOUT = 1 MHz
fDATA = 65 MSPS, fOUT = 1 MHz
fDATA = 65 MSPS, fOUT = 15 MHz
fDATA = 78 MSPS, fOUT = 1 MHz
fDATA = 78 MSPS, fOUT = 15 MHz
fDATA = 160 MSPS, fOUT = 1 MHz
fDATA = 160 MSPS, fOUT = 15 MHz
Spurious-Free Dynamic Range within a 1 MHz Window
(fOUT = 0 dBFS, fDATA = 100 MSPS, fOUT = 1 MHz)
Two-Tone Intermodulation (IMD) to Nyquist (fOUT1 = fOUT2 = –6 dBFS)
fDATA = 65 MSPS, fOUT1 = 10 MHz; fOUT2 = 11 MHz
fDATA = 65 MSPS, fOUT1 = 20 MHz; fOUT2 = 21 MHz
fDATA = 78 MSPS, fOUT1 = 10 MHz; fOUT2 = 11 MHz
fDATA = 78 MSPS, fOUT1 = 20 MHz; fOUT2 = 21 MHz
fDATA = 160 MSPS, fOUT1 = 10 MHz; fOUT2 = 11 MHz
fDATA = 160 MSPS, fOUT1 = 20 MHz; fOUT2 = 21 MHz
Total Harmonic Distortion (THD)
fDATA = 100 MSPS, fOUT = 1 MHz; 0 dBFS
Signal-to-Noise Ratio (SNR)
fDATA = 78 MSPS, fOUT = 5 MHz; 0 dBFS
fDATA = 160 MSPS, fOUT = 5 MHz; 0 dBFS
Adjacent Channel Power Ratio (ACLR)
WCDMA with 3.84 MHz BW, 5 MHz Channel Spacing
IF = Baseband, fDATA = 76.8 MSPS
IF = 19.2 MHz, fDATA = 76.8 MSPS
Four-Tone Intermodulation
21 MHz, 22 MHz, 23 MHz, and 24 MHz at –12 dBFS
(fDATA = MSPS, Missing Center)
AC LINEARITY—IF MODE
Four-Tone Intermodulation at IF = 200 MHz
MHz, MHz, MHz, and MHz at dBFS
(fDATA = MSPS, fDAC = MHz)
Max
Unit
11
0.8
0.8
50
MSPS
ns
ns
ns
pA√Hz
71
84.5
84
80
84
80
82
80
dBc
dBc
dBc
dBc
dBc
dBc
dBc
73
91.3
dBc
81
76
81
76
81
76
dBc
dBc
dBc
dBc
dBc
dBc
–82.5
dB
76
74
dB
dB
75
73
dBc
dBc
75
dBFS
72
dBFS
–71
*Measured single-ended into 50 Ω load.
Specifications subject to change without notice.
–4–
REV. 0
AD9775
DIGITAL SPECIFICATIONS
(TMIN to TMAX, AVDD = 3.3 V, CLKVDD = 3.3 V, PLLVDD = 0 V, DVDD = 3.3 V, IOUTFS = 20 mA, unless
otherwise noted.)
Parameter
DIGITAL INPUTS
Logic “1” Voltage
Logic “0” Voltage
Logic “1” Current
Logic “0” Current
Input Capacitance
Min
Typ
2.1
3
0
–10
–10
Max
Unit
0.9
+10
+10
V
V
µA
µA
pF
5
CLOCK INPUTS
Input Voltage Range
Common-Mode Voltage
Differential Voltage
0
0.75
0.5
3
2.25
1.5
1.5
V
V
V
Specifications subject to change without notice.
ABSOLUTE MAXIMUM RATINGS*
Parameter
With Respect to
Min
Max
Unit
AVDD, DVDD, CLKVDD
AVDD, DVDD, CLKVDD
AGND, DGND, CLKGND
REFIO, REFLO, FSADJ1/2
IOUTA, IOUTB
P1B13–P1B0, P2B13–P2B0
DATACLK, PLL_LOCK
CLK+, CLK–, RESET
LPF
SPI_CSB, SPI_CLK,
SPI_SDIO, SPI_SDO
Junction Temperature
Storage Temperature
Lead Temperature (10 sec)
AGND, DGND, CLKGND
AVDD, DVDD, CLKVDD
AGND, DGND, CLKGND
AGND
AGND
DGND
DGND
CLKGND
CLKGND
DGND
–0.3
–4.0
–0.3
–0.3
–1.0
–0.3
–0.3
–0.3
–0.3
–0.3
+4.0
+4.0
+0.3
AVDD + 0.3
AVDD + 0.3
DVDD + 0.3
DVDD + 0.3
CLKVDD + 0.3
CLKVDD + 0.3
DVDD + 0.3
V
V
V
V
V
V
V
V
V
V
–65
+125
+150
+300
°C
°C
°C
*Stresses above those listed under the 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 sections of this specification is not implied. Exposure to absolute
maximum ratings for extended periods may affect device reliability.
ORDERING GUIDE
Model
Temperature
Range
AD9775BSV –40°C to +85°C
AD9775EB
THERMAL CHARACTERISTICS
Package
Description
Package
Option*
Thermal Resistance
80-Lead TQFP
Evaluation Board
SV-80
*With thermal pad soldered to PCB.
80-Lead Thermally Enhanced
TQFP Package ␪JA = 23.5 °C/W*
*SV = Thin Plastic Quad Flatpack
CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily
accumulate on the human body and test equipment and can discharge without detection. Although
the AD9775 features proprietary ESD protection circuitry, permanent damage may occur on
devices subjected to high energy electrostatic discharges. Therefore, proper ESD precautions are
recommended to avoid performance degradation or loss of functionality.
REV. 0
–5–
WARNING!
ESD SENSITIVE DEVICE
AD9775
AGND
AVDD
AVDD
AGND
AVDD
AGND
AGND
IOUTA2
IOUTB2
AGND
AGND
IOUTA1
IOUTB1
AGND
AVDD
AGND
AGND
AVDD
AGND
AVDD
PIN CONFIGURATION
80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61
CLKVDD 1
60
FSADJ1
59
FSADJ2
CLKVDD 3
58
REFIO
CLKGND 4
57
RESET
CLK+ 5
56
SPI_CSB
CLK– 6
CLKGND 7
DATACLK/PLL_LOCK 8
55
SPI_CLK
54
SPI_SDIO
53
SPI_SDO
52
DGND
51
DVDD
50
NC
P1B12 12
49
NC
P1B11 13
48
P2B0 (LSB)
P1B10 14
47
P2B1
P1B9 15
46
P2B2
P1B8 16
45
P2B3
DGND 17
44
DGND
DVDD 18
43
DVDD
P1B7 19
42
P2B4
P1B6 20
41
P2B5
LPF 2
PIN 1
IDENTIFIER
AD9775
TxDAC+
DGND 9
DVDD 10
TOP VIEW
(Not to Scale)
P1B13 (MSB) 11
–6–
P2B6
P2B7
P2B8
P2B9
DGND
DVDD
P2B11
P2B10
ONEPORTCLK/P2B12
NC
IQSEL/P2B13 (MSB)
NC
P1B1
P1B0 (LSB)
DVDD
P1B2
DGND
P1B3
NC = NO CONNECT
P1B5
P1B4
21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40
REV. 0
AD9775
PIN FUNCTION DESCRIPTIONS
Pin Number
Mnemonic
1, 3
2
4, 7
5
6
8
CLKVDD
LPF
CLKGND
CLK+
CLK–
DATACLK/PLL_LOCK
Description
Clock Supply Voltage
PLL Loop Filter
Clock Supply Common
Differential Clock Input
Differential Clock Input
With the PLL enabled, this pin indicates the state of the PLL. A read of a
Logic “1” indicates the PLL is in the locked state. Logic “0” indicates the
PLL has not achieved lock. This pin may also be programmed to act as
either an input or output (Address 02h, Bit 3) DATACLK signal running at
the input data rate.
9, 17, 25, 35, 44, 52
DGND
Digital Common
10, 18, 26, 36, 43, 51 DVDD
Digital Supply Voltage
11–16, 19–24, 27, 28 P1B13 (MSB) to P1B0 (LSB) Port “1” Data Inputs
29, 30, 49, 50
NC
No Connect
31
IQSEL/P2B13 (MSB)
In “1” port mode, IQSEL = 1 followed by a rising edge of the differential
input clock will latch the data into the I channel input register. IQSEL = 0
will latch the data into the Q channel input register. In “2” port mode, this
pin becomes the port “2” MSB.
32
ONEPORTCLK/P2B12
With the PLL disabled and the AD9775 in “1” port mode, this pin becomes
a clock output that runs at twice the input data rate of the I and Q channels.
This allows the AD9775 to accept and demux interleaved I and Q data to
the I and Q input registers.
33, 34, 37–42, 45–48 P2B11 to P2B0 (LSB)
Port “2” Data Inputs
53
SPI_SDO
In the case where SDIO is an input, SDO acts as an output. When SDIO
becomes an output, SDO enters a High-Z state.
54
SPI_SDIO
Bidirectional Data Pin. Data direction is controlled by Bit 7 of Register
Address 00h. The default setting for this bit is “0,” which sets SDIO as an input.
55
SPI_CLK
Data input to the SPI port is registered on the rising edge of SPI_CLK.
Data output on the SPI port is registered on the falling edge.
56
SPI_CSB
Chip Select/SPI Data Synchronization. On momentary logic high, resets
SPI port logic and initializes instruction cycle.
57
RESET
Logic “1” resets all of the SPI port registers, including Address 00h, to their
default values. A software reset can also be done by writing a Logic “1” to
SPI Register 00h, Bit 5. However, the software reset has no effect on the bits
in Address 00h.
58
REFIO
Reference Output, 1.2 V Nominal
59
FSADJ2
Full-Scale Current Adjust, Q Channel
60
FSADJ1
Full-Scale Current Adjust, I Channel
61, 63, 65, 76, 78, 80 AVDD
Analog Supply Voltage
62, 64, 66, 67, 70, 71, AGND
Analog Common
74, 75, 77, 79
68, 69
IOUTA2, IOUTB2
Differential DAC Current Outputs, Q Channel
72, 73
IOUTA1, IOUTB1
Differential DAC Current Outputs, I Channel
REV. 0
–7–
AD9775
20
DIGITAL FILTER SPECIFICATIONS
0
Coefficient
1, 43
2, 42
3, 41
4, 40
5, 39
6, 38
7, 37
8, 36
9, 35
10, 34
11, 33
12, 32
13, 31
14, 30
15, 29
16, 28
17, 27
18, 26
19, 25
20, 24
21, 23
22
8
0
–29
0
67
0
–134
0
244
0
–414
0
673
0
–1079
0
1772
0
–3280
0
10364
16384
1, 19
2, 18
3, 17
4, 16
5, 15
6, 14
7, 13
8, 12
9, 11
10
19
0
–120
0
438
0
–1288
0
5047
8192
Coefficient
1, 11
2, 10
3, 9
4, 8
5, 7
6
7
0
–53
0
302
512
–80
0
1.0
1.5
0.5
fOUT – Normalized to Input Data Rate
2.0
20
0
–20
–40
–60
–80
–100
–120
0
1.0
1.5
0.5
fOUT – Normalized to Input Data Rate
2.0
Figure 1b. 4ⴛ Interpolating Filter Response
20
0
Half-Band Filter No. 3 (11 Coefficients)
Tap
–60
Figure 1a. 2ⴛ Interpolating Filter Response
ATTENUATION – dBFS
Coefficient
–40
–120
Half-Band Filter No. 2 (19 Coefficients)
Tap
–20
–100
ATTENUATION – dBFS
Tap
ATTENUATION – dBFS
Half-Band Filter No. 1 (43 Coefficients)
–20
–40
–60
–80
–100
–120
0
4
6
2
fOUT – Normalized to Input Data Rate
8
Figure 1c. 8ⴛ Interpolating Filter Response
–8–
REV. 0
AD9775
DEFINITIONS OF SPECIFICATIONS
Monotonicity
Adjacent Channel Power Ratio (ACPR)
A D/A converter is monotonic if the output either increases
or remains constant as the digital input increases.
A ratio in dBc between the measured power within a channel
relative to its adjacent channel.
Complex Image Rejection
In a traditional two-part upconversion, two images are created
around the second IF frequency. These images are redundant
and 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.
Complex Modulation
The process of passing the real and imaginary components of a
signal through a complex modulator (transfer function = ej␻t =
cos␻t + jsin␻t) and realizing real and imaginary components on
the modulator output.
Offset Error
The deviation of the output current from the ideal of “0” is
called offset error. For IOUTA, 0 mA output is expected when the
inputs are all “0.” For IOUTB, 0 mA output is expected when all
inputs are set to “1.”
Output Compliance Range
The range of allowable voltage at the output of a current output
DAC. Operation beyond the maximum compliance limits may
cause either output stage saturation or breakdown, resulting in
nonlinear performance.
Pass Band
Frequency band in which any input applied therein passes
unattenuated to the DAC output.
Differential Nonlinearity (DNL)
Power Supply Rejection
DNL is the measure of the variation in analog value, normalized
to full scale, associated with a 1 LSB change in digital input code.
The maximum change in the full-scale output as the supplies
are varied from minimum to maximum specified voltages.
Gain Error
Settling Time
The difference between the actual and ideal output span. The
actual span is determined by the output when all inputs are set
to “1,” minus the output when all inputs are set to “0.”
The time required for the output to reach and remain within a
specified error band about its final value, measured from the
start of the output transition.
Glitch Impulse
Signal-to-Noise Ratio (SNR)
Asymmetrical switching times in a DAC give rise to undesired
output transients that are quantified by a glitch impulse. It is
specified as the net area of the glitch in pV–S.
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.
Group Delay
Number of input clocks between an impulse applied at the
device input and peak DAC output current. A half-band FIR
filter has constant group delay over its entire frequency range.
Spurious-Free Dynamic Range
Impulse Response
Stop-Band Rejection
Response of the device to an impulse applied to the input.
The amount of attenuation of a frequency outside the pass band
applied to the DAC, relative to a full-scale signal applied at the
DAC input within the pass band.
Interpolation Filter
If the digital inputs to the DAC are sampled at a multiple rate of
fDATA (interpolation rate), a digital filter can be constructed
with a sharp transition band near fDATA/2. Images that would
typically appear around fDAC (output data rate) can be greatly
suppressed.
Linearity Error (Also Called Integral Nonlinearity or INL)
Linearity error is defined as the maximum deviation of the actual
analog output from the ideal output, determined by a straight
line drawn from zero to full scale.
REV. 0
The difference, in dB, between the rms amplitude of the output
signal and the peak spurious signal over the specified bandwidth.
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 °C. For reference drift, the drift is reported in
ppm per °C.
Total Harmonic Distortion (THD)
THD is the ratio of the rms sum of the first six harmonic components to the rms value of the measured fundamental. It is
expressed as a percentage or in decibels (dB).
–9–
AD9775–Typical Performance Characteristics
(T = 25ⴗC, AVDD = 3.3 V, CLKVDD = 3.3 V, DVDD = 3.3 V, IOUTFS = 20 mA, Interpolation = 2ⴛ, Differential Coupled Transformer Output, 50 ⍀
Doubly Terminated, unless otherwise noted.)
10
90
0
85
90
0dBFS
85
–6dBFS
0dBFS
80
–6dBFS
80
–20
–30
–40
–50
–60
75
SFDR – dBc
SFDR – dBc
AMPLITUDE – dBm
–10
–12dBFS
70
65
75
70
–12dBFS
65
60
60
55
55
–70
–80
50
–90
0
65
FREQUENCY – MHz
0
130
TPC 1. Single-Tone Spectrum @ fDATA = 65 MSPS with
fOUT = fDATA/3
5
10
15
20
FREQUENCY – MHz
25
50
30
0
TPC 2. In-Band SFDR vs. fOUT
@ fDATA = 65 MSPS
10
25
30
90
0dBFS
85
85
80
80
–6dBFS
–10
–30
–40
–50
75
SFDR – dBc
–20
SFDR – dBc
–12dBFS
70
–6dBFS
65
0dBFS
75
70
–12dBFS
65
–60
–70
–80
–90
0
100
50
FREQUENCY – MHz
60
60
55
55
50
150
TPC 4. Single-Tone Spectrum @ fDATA = 78 MSPS with
fOUT = fDATA/3
0
5
10
15
20
FREQUENCY – MHz
25
50
30
0
TPC 5. In-Band SFDR vs. fOUT
@ fDATA = 78 MSPS
10
90
0
85
5
15
20
10
FREQUENCY – MHz
25
30
TPC 6. Out-of-Band SFDR vs.
fOUT @ fDATA = 78 MSPS
90
0dBFS
85
–6dBFS
–10
80
80
75
75
SFDR – dBc
–20
–30
–40
–50
SFDR – dBc
AMPLITUDE – dBm
10
15
20
FREQUENCY – MHz
TPC 3. Out-of-Band SFDR vs.
fOUT @ fDATA = 65 MSPS
90
0
AMPLITUDE – dBm
5
70
–12dBFS
65
0dBFS
–6dBFS
70
65
–60
60
60
55
55
–70
–12dBFS
–80
–90
0
200
100
FREQUENCY – MHz
TPC 7. Single-Tone Spectrum @ fDATA = 160 MSPS
with fOUT = fDATA/3
300
50
50
0
10
20
30
40
FREQUENCY – MHz
TPC 8. In-Band SFDR vs. fOUT
@ fDATA = 160 MSPS
–10–
50
0
10
20
30
40
FREQUENCY – MHz
50
TPC 9. Out-of-Band SFDR vs.
fOUT @ fDATA = 160 MSPS
REV. 0
AD9775
(T = 25ⴗC, AVDD = 3.3 V, CLKVDD = 3.3 V, DVDD = 3.3 V, IOUTFS = 20 mA, Interpolation = 2ⴛ, Differential Coupled Transformer Output, 50 ⍀
Doubly Terminated, unless otherwise noted.)
90
90
–6dBFS
85
85
–3dBFS
0dBFS
70
65
80
75
IMD – dBc
75
–3dBFS
70
65
75
60
55
55
55
50
5
15
20
10
FREQUENCY – MHz
25
0
30
TPC 10. Third Order IMD
Products vs. fOUT @ fDATA =
65 MSPS
5
10
15
20
FREQUENCY – MHz
25
50
30
0
80
80
IMD – dBc
4ⴛ
1ⴛ
2ⴛ
65
85
8ⴛ
75
2ⴛ
1ⴛ
70
65
70
–12dBFS
60
55
55
55
20
30
40
FREQUENCY – MHz
55
50
–15
60
90
3.3
AVDD – V
3.4
3.5
TPC 15. SFDR vs. AVDD @
fOUT = 10 MHz, fDAC = 320 MSPS,
fDATA = 160 MSPS
90
90
85
85
75
SNR – dB
0dBFS
80
80
–6dBFS
70
65
75
PLL OFF
70
65
60
60
55
55
50
3.1
50
3.3
AVDD – V
3.4
TPC 16. Third Order IMD
Products vs. AVDD @ fOUT =
10 MHz, fDAC = 320 MSPS,
fDATA = 160 MSPS
3.5
SFDR – dBc
80
REV. 0
3.2
78MSPS
–3dBFS
3.2
50
3.1
0
TPC 14. Third Order IMD
Products vs. AOUT and Interpolation Rate fDATA = 50
MSPS for All Cases,
1ⴛ fDAC = 50 MSPS,
2ⴛ fDAC = 100 MSPS,
4ⴛ fDAC = 200 MSPS,
8ⴛ fDAC = 400 MSPS
TPC 13. Third Order IMD
Products vs. fOUT and
Interpolation Rate,
1ⴛ fDATA = 160 MSPS,
2ⴛ fDATA = 160 MSPS,
4ⴛ fDATA = 80 MSPS,
8ⴛ fDATA = 50 MSPS
85
–5
–10
AOUT – dBFS
–6dBFS
65
60
50
0dBFS
75
60
10
60
80
SFDR – dBc
85
0
50
4ⴛ
85
70
20
30
40
FREQUENCY – MHz
90
90
8ⴛ
75
10
TPC 12. Third Order IMD
Products vs. fOUT @ fDATA =
160 MSPS
TPC 11. Third Order IMD
Products vs. fOUT @ fDATA =
78 MSPS
90
0dBFS
65
60
0
–3dBFS
70
60
50
IMD – dBc
–6dBFS
80
IMD – dBc
IMD – dBc
85
0dBFS
80
SFDR – dBc
90
–6dBFS
PLL ON
75
FDATA = 65MSPS
160MSPS
70
65
60
55
0
50
100
INPUT DATA RATE – MSPS
TPC 17. SNR vs. Data Rate
for fOUT = 5 MHz
–11–
150
50
–50
50
0
TEMPERATURE – ⴗC
100
TPC 18. SFDR vs. Temperature
@ fOUT = fDATA/11
AD9775
(T = 25ⴗC, AVDD = 3.3 V, CLKVDD = 3.3 V, DVDD = 3.3 V, IOUTFS = 20 mA, Interpolation = 2ⴛ, Differential Coupled Transformer Output, 50 ⍀
Doubly Terminated, unless otherwise noted.)
0
0
0
–10
–10
–30
–40
–50
–60
–70
AMPLIFIER – dBm
AMPLITUDE – dBm
AMPLITUDE – dBm
–20
–20
–20
–40
–60
–40
–50
–60
–70
–80
–80
–100
–100
–80
–90
–90
–100
100
50
FREQUENCY – MHz
0
150
0
10
20
30
40
FREQUENCY – MHz
50
TPC 20. Two-Tone IMD Performance, fDATA = 150 MSPS,
No Interpolation
TPC 19. Single-Tone Spurious Performance, fOUT =
10 MHz, fDATA = 150 MSPS,
No Interpolation
0
0
–10
–10
–20
–20
–20
–30
–30
–50
–60
–40
AMPLITUDE – dBm
0
–40
–40
–50
–60
–70
–60
–80
–90
–100
15 20 25 30 35 40 45
FREQUENCY – MHz
50
0
50
100
150
200
FREQUENCY – MHz
250
300
–100
0
5
10
15
FREQUENCY – MHz
20
25
TPC 24. Two-Tone IMD Performance, fOUT = 10 MHz,
fDATA = 50 MSPS, Interpolation = 8ⴛ
TPC 23. Single-Tone Spurious Performance, fOUT =
10 MHz, fDATA = 80 MSPS,
Interpolation = 4ⴛ
TPC 22. Two-Tone IMD Performance, fDATA = 150 MSPS,
Interpolation = 4ⴛ
300
–70
–90
10
250
–40
–80
5
100
150
200
FREQUENCY – MHz
–50
–90
0
50
–30
–80
–100
0
TPC 21. Single-Tone Spurious Performance, fOUT =
10 MHz, fDATA = 150 MSPS,
Interpolation = 2ⴛ
–10
AMPLITUDE – dBm
AMPLITUDE – dBm
–30
0
0
–10
–20
AMPLITUDE – dBm
AMPLITUDE – dBm
–20
–30
–40
–50
–60
–70
–80
–40
–60
–80
–100
–90
–100
–120
0
100
200
300
FREQUENCY – MHz
TPC 25. Single-Tone Spurious Performance, fOUT =
10 MHz, fDATA = 50 MSPS,
Interpolation = 8ⴛ
400
0
20
40
60
FREQUENCY – MHz
80
TPC 26. Eight-Tone IMD
Performance, fDATA =
160 MSPS, Interpolation = 8ⴛ
–12–
REV. 0
AD9775
MODE CONTROL (VIA SPI PORT)
Table I. Mode Control via SPI Port
(Default Values Are Highlighted)
Address
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
00h
SDIO
Bidirectional
0 = Input
1 = I/O
LSB, MSB First
0 = MSB
1 = LSB
Software Reset on
Logic “1”
Sleep Mode
Logic “1” shuts down
the DAC output
currents.
Power-Down Mode
Logic “1” shuts down
all digital and analog
functions.
1R/2R Mode
DAC output current set
by one or two external
resistors.
0 = 2R, 1 = 1R
PLL_LOCK
Indicator
01h
Filter
Interpolation
Rate
(1×, 2×, 4×, 8×)
Filter
Interpolation
Rate
(1×, 2×, 4×, 8×)
Modulation
Mode
(None, fS/2,
fS/4, fS/8)
Modulation Mode
(None, fS/2, fS/4, fS/8)
0 = No Zero Stuffing
on Interpolation
Filters, Logic “1”
enables zero stuffing.
1 = Real Mix Mode
0 = Complex
Mix Mode
0 = e–j␻
1 = e+j␻
DATACLK/
PLL_LOCK
Select
0 = PLLLOCK
1 = DATACLK
02h
0 = Signed Input
Data
1 = Unsigned
0 = Two Port Mode
1 = One Port Mode
DATACLK Driver DATACLK Invert
Strength
0 = No Invert
1 = Invert
ONEPORTCLK Invert
0 = No Invert
1 = Invert
IQSEL Invert
0 = No Invert
1 = Invert
Q First
0 = I First
1 = Q First
PLL Divide
(Prescaler) Ratio
PLL Divide
(Prescaler) Ratio
PLL Charge Pump
Control
PLL Charge Pump
Control
PLL Charge Pump
Control
IDAC Fine Gain
Adjustment
IDAC Fine Gain
Adjustment
IDAC Fine Gain
Adjustment
IDAC Fine Gain
Adjustment
IDAC Coarse Gain
Adjustment
IDAC Coarse Gain
Adjustment
IDAC Coarse Gain
Adjustment
IDAC Coarse Gain
Adjustment
IDAC Offset
Adjustment Bit 5
IDAC Offset
Adjustment Bit 4
IDAC Offset
Adjustment Bit 3
IDAC Offset
Adjustment Bit 2
IDAC Offset
Adjustment Bit 1
IDAC Offset
Adjustment Bit 0
03h
04h
0 = PLL OFF
1 = PLL ON
0 = Automatic
Charge Pump Control
1 = Programmable
05h
IDAC Fine Gain
Adjustment
IDAC Fine Gain
Adjustment
IDAC Fine Gain
Adjustment
IDAC Fine Gain
Adjustment
06h
07h
IDAC Offset
Adjustment Bit 9
08h
IDAC IOFFSET
Direction
0 = IOFFSET
on IOUTA
1 = IOFFSET on
IOUTB
09h
QDAC Fine Gain
Adjustment
IDAC Offset
Adjustment Bit 8
QDAC Fine Gain
Adjustment
IDAC Offset
Adjustment Bit 7
QDAC Fine Gain
Adjustment
IDAC Offset
Adjustment Bit 6
QDAC Fine Gain
Adjustment
0Ah
0Bh
QDAC Offset
Adjustment Bit 9
0Ch
QDAC IOFFSET
Direction
0 = IOFFSET
on IOUTA
1 = IOFFSET
on IOUTB
0Dh
REV. 0
QDAC Offset
Adjustment Bit 8
QDAC Offset
Adjustment Bit 7
QDAC Offset
Adjustment Bit 6
Bit 0
QDAC Fine Gain
Adjustment
QDAC Fine Gain
Adjustment
QDAC Fine Gain
Adjustment
QDAC Fine Gain
Adjustment
QDAC Coarse
Gain Adjustment
QDAC Coarse
Gain Adjustment
QDAC Coarse
Gain Adjustment
QDAC Coarse
Gain Adjustment
QDAC Offset
Adjustment Bit 5
QDAC Offset
Adjustment Bit 4
QDAC Offset
Adjustment Bit 3
QDAC Offset
Adjustment Bit 2
QDAC Offset
Adjustment Bit 1
QDAC Offset
Adjustment Bit 0
Version Register
Version Register
Version Register
–13–
Version Register
AD9775
REGISTER DESCRIPTION
Address 00h
Bit 3
Logic “1” enables zero stuffing mode for interpolation filters.
Bit 7
Logic “0” (default). Causes the SDIO pin to act as
an input during the data transfer (Phase 2) of the
communications cycle. When set to “1,” SDIO
can act as an input or output, depending on Bit 7 of
the instruction byte.
Bit 2
Bit 6
Logic “0” (default). Determines the direction
(LSB/MSB first) of the communications and data
transfer communications cycles. Refer to the section
MSB/LSB Transfers for a detailed description.
Bit 5
Writing a “1” to this bit resets the registers to their
default values and restarts the chip. The RESET bit
always reads back “0.” Register Address 00h bits are
not cleared by this software reset. However, a high
level at the RESET pin forces all registers, including
those in Address 00h, to their default state.
Default (“1”) enables the real mix mode. The I and
Q data channels are individually modulated by fS/2,
fS/4, or fS/8 after the interpolation filters. However, no
complex modulation is done. In the complex mix
mode (Logic “0”), the digital modulators on the I
and Q data channels are coupled to create a digital complex modulator. When the AD9775 is
applied in conjunction with an external quadrature
modulator, rejection can be achieved of either the
higher or lower frequency image around the second
IF frequency (i.e., the second IF frequency is the
LO of the analog quadrature modulator external to
the AD9775) according to the bit value of Register
01h, Bit 1.
Bit 1
Bit 4
Sleep Mode. A Logic “1” to this bit shuts down the
DAC output currents.
Bit 3
Power-Down. Logic “1” shuts down all analog and
digital functions except for the SPI port.
Logic “0” (default) causes the complex modulation
to be of the form e–j␻t, resulting in the rejection of
the higher frequency image when the AD9775 is used
with an external quadrature modulator. A Logic “1”
causes the modulation to be of the form e+j␻t, which
causes rejection of the lower frequency image.
Bit 2
1R/2R Mode. The default (“0”) places the AD9775
in two resistor mode. In this mode, the IREF currents
for the I and Q DAC references are set separately by
the RSET resistors on FSADJ1 and FSADJ2 (Pins
59 and 60). In the 2R mode, assuming the coarse
gain setting is full scale and the fine gain setting is
zero, I FULLSCALE1 = 32 × V REF /FSADJ1 and
IFULLSCALE2 = 32 × VREF/FSADJ2. With this bit set
to “1,” the reference currents for both I and Q
DACs are controlled by a single resistor on Pin 60.
IFULLSCALE in one resistor mode for both of the I
and Q DACs is half of what it would be in the 2R
mode, assuming all other conditions (RSET, register
settings) remain unchanged. The full-scale current
of each DAC can still be set to 20 mA by choosing
a resistor of half the value of the RSET value used in
the 2R mode.
Bit 0
In two port mode, a Logic “0” (default) causes Pin 8
to act as a lock indicator for the internal PLL. A
Logic “1” in this register causes Pin 8 to act as a
DATACLK, either generating or acting as an input
clock (see Register 02h, Bit 3) at the input data rate
of the AD9775.
Bit 1
Address 02h
Bit 7
Logic “0” (default) causes data to be accepted on
the inputs as two’s complement binary. Logic “1”
causes data to be accepted as straight binary.
Bit 6
Logic “0” (default) places the AD9775 in two port
mode. I and Q data enters the AD9775 via Ports 1
and 2, respectively. A Logic “1” places the AD9775
in one port mode in which interleaved I and Q data
is applied to Port 1. See the Pin Function Descriptions for DATACLK/PLL_LOCK, IQSEL, and
ONEPORTCLK for detailed information on how
to use these modes.
Bit 5
DATACLK Driver Strength. With the internal PLL
disabled, and this bit set to Logic “0,” it is recommended that DATACLK be buffered. When this bit
is set to Logic “1,” DATACLK acts as a stronger
driver capable of driving small capacitive loads.
Bit 4
Default Logic “0.” A value of “1” inverts DATACLK
at Pin 8.
Bit 2
Default Logic “0.” A value of 1 inverts
ONEPORTCLK at Pin 32.
Modulation mode according to the following table:
Bit 1
00
01
10
11
The default of Logic “0” causes IQSEL = 1 to
direct input data to the I channel, while IQSEL = 0
directs input data to the Q channel. A Logic “1” in
this register inverts the sense of IQSEL.
Bit 0
The default of Logic “0” defines IQ pairing as IQ,
IQ...while programming a Logic “1” causes the pair
ordering to be QI, QI...
PLL_LOCK Indicator. When the PLL is enabled,
reading this bit will give the status of the PLL. A
Logic “1” indicates the PLL is locked. A Logic “0”
indicates an unlocked state.
Address 01h
Bits 7, 6
Filter interpolation rate according to the following table:
00
01
10
11
Bits 5, 4
1×
2×
4×
8×
none
fS/2
fS/4
fS/8
–14–
REV. 0
AD9775
Address 03h
Address 05h, 09h
Bits 1, 0
Bits 7–0
Setting this divide ratio to a higher number allows
the VCO in the PLL to run at a high rate (for best
performance) while the DAC input and output clocks
run substantially slower. The divider ratio is set
according to the following table:
00
01
10
11
⫼1
⫼2
⫼4
⫼8
These bits represent an 8-bit binary number (Bit 7
MSB) that defines the fine gain adjustment of the I
(05h) and Q (09h) DAC, according to the equation
given below.
Address 06h, 0Ah
Bits 3–0
These bits represent a 4-bit binary number (Bit 3 MSB)
that defines the coarse gain adjustment of the I (06h)
and Q (0Ah) DACs according to the equation below.
Address 07h, 0Bh
Address 04h
Bits 7–0
Bit 7
Logic “0” (default) disables the internal PLL. Logic
“1” enables the PLL.
Address 08h, 0Ch
Bit 6
Logic “0” (default) sets the charge pump control to
automatic. In this mode, the charge pump bias
current is controlled by the divider ratio defined in
Address 03h, Bits 1 and 0. Logic “1” allows the
user to manually define the charge pump bias current using Address 04h, Bits 2, 1, and 0. Adjusting
the charge pump bias current allows the user to
optimize the noise/settling performance of the PLL.
Bit 1, 0
Address 08h, 0Ch
Bit 7
Bits 0, 1, 2 With the charge pump control set to manual, these
bits define the charge pump bias current according
to the following table:
000
001
010
011
100
50 µA
100 µA
200 µA
400 µA
800 µA
 6 × IREF
IOUTA = 
8

 6 × IREF
IOUTB = 
8

The 10 bits from these two address pairs (07h, 08h
and 0Bh, 0Ch) represent a 10-bit binary number
that defines the offset adjustment of the I and Q
DACs according to the equation below (07h, 0Bh–Bit
7 MSB/08h, 0Ch–Bit 0 LSB)
This bit determines the direction of the offset of the
I (08h) and Q (0Ch) DACs. A Logic “0” will apply
a positive offset current to IOUTA, while a Logic “1”
will apply a positive offset current to IOUTB. The
magnitude of the offset current is defined by the
bits in Addresses 07h, 0Bh, 08h, and 0Ch according to the formulas given below.
  COARSE + 1  3 × IREF
 –
 
  32
16

  FINE    1024   DATA  
 × 


 
 256    24   214  
  COARSE + 1  3 × IREF
 –
 
  32
16

  FINE    1024   214 – DATA – 1 
  × 

 

 256    24  
 
214
(1)
 OFFSET 
IOFFSET = 4 × IREF 

 1024 
Equation 1 shows IOUTA and IOUTB as a function of fine gain, coarse gain, and offset adjustment when using the 2R mode. In the 1R
mode, the current IREF is created by a single FSADJ resistor (Pin 60). This current is divided equally into each channel so that a
scaling factor of one-half must be added to these equations for full-scale currents for both DACs and the offset.
REV. 0
–15–
AD9775
FUNCTIONAL DESCRIPTION
SERIAL INTERFACE FOR REGISTER CONTROL
The AD9775 dual interpolating DAC consists of two data channels that can be operated completely independently or coupled to
form a complex modulator in an image reject transmit architecture. Each channel includes three FIR filters, making the
AD9775 capable of 2×, 4×, or 8× interpolation. High speed input
and output data rates can be achieved within the following
limitations.
The AD9775 serial port is a flexible, synchronous serial communications port allowing easy interface to many industry
standard microcontrollers 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 AD9775.
Single- or multiple-byte transfers are supported as well as MSB
first or LSB first transfer formats. The AD9775’s serial interface
port can be configured as a single pin I/O (SDIO) or two unidirectional pins for in/out (SDIO/SDO).
Interpolation
Rate (MSPS)
1×
2×
4×
8×
Input Data
Rate (MSPS)
160
160
100
50
DAC Sample
Rate (MSPS)
160
320
400
400
GENERAL OPERATION OF THE SERIAL INTERFACE
Both data channels contain a digital modulator capable of mixing the data stream with an LO of fDAC/2, fDAC/4, or fDAC/8,
where fDAC is the output data rate of DAC. A zero stuffing feature is also included and can be used to improve pass-band
flatness for signals being attenuated by the SIN(x)/x characteristic
of the DAC output. The speed of the AD9775, combined with
the digital modulation capability, enables direct IF conversion
architectures at 70 MHz and higher.
The digital modulators on the AD9775 can be coupled to form
a complex modulator. By using this feature with an external analog
quadrature modulator, such as Analog Devices’ AD8345, an
image rejection architecture can be enabled. To optimize the
image rejection capability, as well as LO feedthrough in this
architecture, the AD9775 offers programmable (via the SPI port)
gain and offset adjust for each DAC.
Also included on the AD9775 are a phase-locked loop (PLL)
clock multiplier and a 1.20 V band gap voltage reference. With
the PLL enabled, a clock applied to the CLK+/CLK– inputs is
frequency multiplied internally and generates all necessary
internal synchronization clocks. Each 14-bit DAC provides two
complementary current outputs whose full-scale currents can
be determined either from a single external resistor or independently from two separate resistors (see 1R/2R mode). The
AD9775 features a low jitter, differential clock input that
provides excellent noise rejection while accepting a sine or
square wave input. Separate voltage supply inputs are provided
for each functional block to ensure optimum noise and distortion performance.
There are two phases to a communication cycle with the AD9775.
Phase 1 is the instruction cycle, which is the writing of an instruction byte into the AD9775 coincident with the first eight SCLK
rising edges. The instruction byte provides the AD9775 serial
port controller with information regarding the data transfer
cycle, which is Phase 2 of the communication cycle. The Phase 1
instruction byte defines whether the upcoming data transfer is
read or write, the number of bytes in the data transfer, and the
starting register address for the first byte of the data transfer.
The first eight SCLK rising edges of each communication cycle
are used to write the instruction byte into the AD9775.
A logic high on the CSB pin, followed by a logic low, will reset
the SPI port timing to the initial state of the instruction cycle.
This is true regardless of the present state of the internal registers or the other signal levels present at the inputs to the SPI
port. If the SPI port is in the midst of an instruction cycle or a
data transfer cycle, none of the present data will be written.
The remaining SCLK edges are for Phase 2 of the communication cycle. Phase 2 is the actual data transfer between the AD9775
and the system controller. Phase 2 of the communication cycle
is a transfer of 1, 2, 3, or 4 data bytes as determined by the
instruction byte. Normally, using one multibyte transfer is the
preferred method. However, single byte data transfers are useful
to reduce CPU overhead when register access requires one byte
only. Registers change immediately upon writing to the last bit of
each transfer byte.
INSTRUCTION BYTE
The instruction byte contains the information shown below.
SLEEP and power-down modes can be used to turn off the DAC
output current (SLEEP) or the entire digital and analog sections
(power-down) of the chip. An SPI-compliant serial port is used
to program the many features of the AD9775. Note that in
power-down mode, the SPI port is the only section of the chip
still active.
N1
N0
Description
0
0
1
1
0
1
0
1
Transfer 1 Byte
Transfer 2 Bytes
Transfer 3 Bytes
Transfer 4 Bytes
SDO (PIN 53)
SDIO (PIN 54)
SCLK (PIN 55)
AD9775 SPI PORT
INTERFACE
CSB (PIN 56)
Figure 2. SPI Port Interface
–16–
REV. 0
AD9775
R/W
SDIO (Pin 54)—Serial Data I/O
Bit 7 of the instruction byte determines whether a read or a
write data transfer will occur after the instruction byte write.
Logic high indicates read operation. Logic “0” indicates a write
operation.
Data is always written into the AD9775 on this pin. However,
this pin can be used as a bidirectional data line. The configuration of this pin is controlled by Bit 7 of Register Address 00h.
The default is Logic “0,” which configures the SDIO Pin as
unidirectional.
N1, N0
Bits 6 and 5 of the instruction byte determine the number of
bytes to be transferred during the data transfer cycle. The bit
decodes are shown in the following table:
MSB
I7
R/W
SDO (Pin 53)—Serial Data Out
Data is read from this pin for protocols that use separate lines
for transmitting and receiving data. In the case where the AD9775
operates in a single bidirectional I/O mode, this pin does not
output data and is set to a high impedance state.
LSB
I6
N1
I5
N0
I4
A4
I3
A3
I2
A2
I1
A1
I0
A0
MSB/LSB TRANSFERS
The AD9775 serial port can support both most significant bit
(MSB) first or least significant bit (LSB) first data formats. This
functionality is controlled by Register Address 00h, Bit 6. The
default is MSB first. When this bit is set active high, the AD9775
serial port is in LSB first format. That is, if the AD9775 is in
LSB first mode, the instruction byte must be written from leastsignificant bit to most significant bit. Multibyte data transfers in
MSB format can be completed by writing an instruction byte
that includes the register address of the most significant byte. In
MSB first mode, the serial port internal byte address generator
decrements for each byte required of the multibyte communication cycle. Multibyte data transfers in LSB first format can be
completed by writing an instruction byte that includes the register address of the least significant byte. In LSB first mode, the
serial port internal byte address generator increments for each
byte required of the multibyte communication cycle.
A4, A3, A2, A1, A0
Bits 4, 3, 2, 1, and 0 of the instruction byte determine which
register is accessed during the data transfer portion of the communications cycle. For multibyte transfers, this address is the
starting byte address. The remaining register addresses are
generated by the AD9775.
SERIAL INTERFACE PORT PIN DESCRIPTIONS
SCLK (Pin 55)—Serial Clock
The serial clock pin is used to synchronize data to and from the
AD9775 and to run the internal state machines. SCLK maximum frequency is 15 MHz. All data input to the AD9775 is
registered on the rising edge of SCLK. All data is driven out of
the AD9775 on the falling edge of SCLK.
The AD9775 serial port controller address will increment from
1Fh to 00h for multibyte I/O operations if the MSB first mode is
active. The serial port controller address will decrement from 00h
to 1Fh for multibyte I/O operations if the LSB first mode is active.
CSB (Pin 56)—Chip Select
Active low input starts and gates a communication cycle. It
allows more than one device to be used on the same serial communications lines. The SDO and SDIO pins will go to a high
impedance state when this input is high. Chip select should stay
low during the entire communication cycle.
DATA TRANSFER CYCLE
INSTRUCTION CYCLE
CS
SCLK
SDIO
R/W
I6 (N)
I5 (N)
I4
I3
I2
I1
I0
SDO
D7N
D6N
D20
D10
D00
D7N
D6N
D20
D10
D00
Figure 3a. Serial Register Interface Timing MSB First
INSTRUCTION CYCLE
DATA TRANSFER CYCLE
CS
SCLK
SDIO
I0
I1
I2
I3
I4
I5 (N)
I6 (N)
R/W
SDO
D00
D10
D20
D6N
D7N
D00
D10
D20
D6N
D7N
Figure 3b. Serial Register Interface Timing LSB First
REV. 0
–17–
AD9775
tDS
tSCLK
CS
tPWH
tPWL
SCLK
tDS
SDIO
tDH
INSTRUCTION BIT 7
INSTRUCTION BIT 6
Figure 4. Timing Diagram for Register Write to AD9775
CS
SCLK
tDV
SDIO
DATA BIT N
DATA BIT N–1
SDO
Figure 5. Timing Diagram for Register Read from AD9775
NOTES ON SERIAL PORT OPERATION
DAC OPERATION
The AD9775 serial port configuration bits reside in Bits 6 and 7
of Register Address 00h. It is important to note that the configuration changes immediately upon writing to the last bit of the register.
For multibyte transfers, writing to this register may occur during the middle of the communication cycle. Care must be taken
to compensate for this new configuration for the remaining
bytes of the current communication cycle.
The dual 14-bit DAC output of the AD9775, along with the
reference circuitry, gain, and offset registers, is shown in Figure 6.
Referring to the transfer functions in Equation 1, a reference
current is set by the internal 1.2 V reference, the external RSET
resistor, and the values in the coarse gain register. The fine gain
DAC subtracts a small amount from this and the result is input
to IDAC and QDAC, where it is scaled by an amount equal
to 1024/24. Figures 7a and 7b show the scaling effect of the
coarse and fine adjust DACs. IDAC and QDAC are PMOS
current source arrays, segmented in a 5-4-5 configuration. The
five most significant bits control an array of 31 current sources.
The next four bits consist of 15 current sources whose values
are all equal to 1/16 of an MSB current source. The five LSBs
are binary weighted fractions of the middle bit’s current sources.
All current sources are switched to either IOUTA or IOUTB, depending on the input code.
The same considerations apply to setting the reset bit in Register
Address 00h. All other registers are set to their default values, but
the software reset doesn’t affect the bits in Register Address 00h.
It is recommended to use only single-byte transfers when changing serial port configurations or initiating a software reset.
A write to Bits 1, 2, and 3 of Address 00h with the same logic
levels as for Bits 7, 6, and 5 (bit pattern: XY1001YX binary)
allows the user to reprogram a lost serial port configuration and
to reset the registers to their default values. A second write to
Address 00h with reset bit low and serial port configuration as
specified above (XY) reprograms the OSC IN multiplier setting. A changed fSYSCLK frequency is stable after a maximum of
200 fMCLK cycles (equals wake-up time).
The fine adjustment of the gain of each channel allows for
improved balance of QAM modulated signals, resulting in
improved modulation accuracy and image rejection. In the
Applications section of this data sheet, performance data is
included that shows to what degree image rejection can be improved when the AD9775 is used with an AD8345 quadrature
modulator from ADI.
–18–
REV. 0
AD9775
The offset control defines a small current that can be added to
IOUTA or IOUTB (not both) on the IDAC and QDAC. The selection of which IOUT this offset current is directed toward is
programmable via Register 08h, Bit 7 (IDAC) and Register 0Ch,
Bit 7 (QDAC). Figure 8 shows the scale of the offset current
that can be added to one of the complementary outputs on the
IDAC and QDAC. Offset control can be used for suppression of
LO leakage resulting from modulation of dc signal components.
If the AD9775 is dc-coupled to an external modulator, this
feature can be used to cancel the output offset on the AD9775
as well as the input offset on the modulator. Figure 9 shows a
typical example of the effect that the offset control has on LO
suppression.
FINE REFERENCE CURRENT – mA
0
–0.5
1R MODE
–1.0
–1.5
2R MODE
–2.0
–2.5
–3.0
FINE
GAIN
DAC
GAIN
CONTROL
REGISTERS
1.2VREF
IOUTA1
IDAC
IOUTB1
REFIO
COARSE
GAIN
DAC
COARSE
GAIN
DAC
IOUTA2
QDAC
IOUTB2
FSADJ1
FSADJ2
RSET1
RSET2
OFFSET
CONTROL OFFSET
DAC
REGISTERS
GAIN
CONTROL
REGISTERS
20
In Figure 9, the negative scale represents an offset added to
IOUTB, while the positive scale represents an offset added to
IOUTA of the respective DAC. Offset Register 1 corresponds to
IDAC, while Offset Register 2 corresponds to QDAC. Figure 9
represents the AD9775 synthesizing a complex signal that is then
dc-coupled to an AD8345 quadrature modulator with an LO of
800 MHz. The dc-coupling allows the input offset of the
AD8345 to be calibrated out as well. The LO suppression at
the AD8345 output was optimized first by adjusting Offset
Register 1 in the AD9775. When an optimal point was found
(roughly Code 54), this code was held in Offset Register 1, and
Offset Register 2 was adjusted. The resulting LO suppression
is 70 dBFS. These are typical numbers and the specific code for
optimization will vary from part to part.
25
5
20
4
OFFSET CURRENT – mA
COARSE REFERENCE CURRENT – mA
Figure 6. DAC Outputs, Reference Current Scaling, and
Gain/Offset Adjust
2R MODE
15
10
1R MODE
3
2R MODE
2
1R MODE
1
5
0
0
0
5
10
15
COARSE GAIN REGISTER CODE – Assuming
RSET1, 2 = 1.9k⍀
0
20
200
400
600
800
COARSE GAIN REGISTER CODE – Assuming
RSET1, 2 = 1.9k⍀
Figure 8. DAC Output Offset Current
Figure 7a. Coarse Gain Effect on IFULLSCALE
REV. 0
5
10
15
FINE GAIN REGISTER CODE – Assuming
RSET1, 2 = 1.9k⍀
Figure 7b. Fine Gain Effect on IFULLSCALE
FINE
GAIN
DAC
0.1␮F
0
OFFSET
CONTROL OFFSET
DAC
REGISTERS
–19–
1000
AD9775
0
AD9775
–10
0.1␮F
LO SUPPRESSION – dBFS
OFFSET REGISTER 1 ADJUSTED
1k⍀
CLK+
1k⍀
–20
ECL/PECL
–30
0.1␮F
0.1␮F
–40
1k⍀
1k⍀
CLKVDD
CLK–
CLKGND
–50
–60
OFFSET REGISTER 2
ADJUSTED, WITH OFFSET
REGISTER 1 SET
TO OPTIMIZED VALUE
–70
–80
–1024
–768
–512
–256
0
256
512
DAC1, DAC2 – Offset Register Codes
768
Figure 11. Differential Clock Driving Clock Inputs
A transformer, such as the T1-1T from Mini-Circuits, can also
be used to convert a single-ended clock to differential. This
method is used on the AD9775 evaluation board so that an external sine wave with no dc offset can be used as a differential clock.
1024
Figure 9. Offset Adjust Control, Effect on LO
Suppression
1R/2R MODE
In the 2R mode, the reference current for each channel is set
independently by the FSADJ resistor on that channel. The AD9775
can be programmed to derive its reference current from a single
resistor on Pin 60 by placing the part in the 1R mode. The transfer functions in Equation 1 are valid for the 2R mode. In the
1R mode, the current developed in the single FSADJ resistor is
split equally between the two channels. The result is that in the
1R mode, a scale factor of one-half must be applied to the formulas in Equation 1. The full-scale DAC current in the 1R mode
can still be set to as high as 20 mA by using the internal 1.2 V
reference and a 950 Ω resistor, instead of the 1.9 kΩ resistor
typically used in the 2R mode.
CLOCK INPUT CONFIGURATIONS
The clock inputs to the AD9775 can be driven differentially or
single-ended. The internal clock circuitry has supply and ground
(CLKVDD, CLKGND) separate from the other supplies on the
chip to minimize jitter from internal noise sources.
Figure 10 shows the AD9775 driven from a single-ended clock
source. The CLK+/CLK– Pins form a differential input (CLKIN),
so that the statically terminated input must be dc-biased to the
midswing voltage level of the clock driven input.
AD9775
R SERIES
CLK+
CLKVDD
CLK–
VTHRESHOLD
0.1µF
CLKGND
Figure 10. Single-Ended Clock Driving Clock Inputs
A configuration for differentially driving the clock inputs is given
in Figure 11. DC-blocking capacitors can be used to couple a
clock driver output whose voltage swings exceed CLKVDD or
CLKGND. If the driver voltage swings are within the supply
range of the AD9775, the dc-blocking capacitors and bias resistors
are not necessary.
PECL/ECL drivers require varying termination networks, the
details of which are left out of Figures 10 and 11 but can be found
in application notes such as AND8020/D from On Semiconductor.
These networks depend on the assumed transmission line impedance and power supply voltage of the clock driver. Optimum
performance of the AD9775 is achieved when the driver is placed
very close to the AD9775 clock inputs, thereby negating any
transmission line effects such as reflections due to mismatch.
The quality of the clock and data input signals is important in
achieving optimum performance. The external clock driver circuitry should provide the AD9775 with a low jitter clock input
that meets the min/max logic levels while providing fast edges.
Although fast clock edges help minimize any jitter that will manifest
itself as phase noise on a reconstructed waveform, the high gain
bandwidth product of the AD9775’s differential comparator can
tolerate sine wave inputs as low as 0.5 V p-p, with minimal
degradation of the output noise floor.
PROGRAMMABLE PLL
CLKIN can function either as an input data rate clock (PLL
enabled) or as a DAC data rate clock (PLL disabled) according
to the state of Address 02h, Bit 7 in the SPI port register. The
internal operation of the AD9775 clock circuitry in these two
modes is illustrated in Figures 12 and 13.
The PLL clock multiplier and distribution circuitry produce the
necessary internal synchronized 1×, 2×, 4×, and 8× clocks for
the rising edge triggered latches, interpolation filters, modulators, and DACs. This circuitry consists of a phase detector,
charge pump, voltage controlled oscillator (VCO), prescaler,
clock distribution, and SPI port control. The charge pump and
VCO are powered from PLLVDD while the differential clock
input buffer, phase detector, prescaler, and clock distribution
are powered from CLKVDD. PLL lock status is indicated by
the logic signal at the PLL_LOCK Pin, as well as by the status of
Bit 1, Register 00h. To ensure optimum phase noise performance
from the PLL clock multiplier and distribution, PLLVDD and
CLKVDD should originate from the same clean analog supply.
The speed of the VCO with the PLL enabled also has an effect
on phase noise. Optimal phase noise with respect to VCO speed
is achieved by running the VCO in the range of 450 MHz to
550 MHz. The VCO speed is a function of the input data rate,
the interpolation rate, and the VCO prescaler, according to the
following function:
VCO Speed ( MHz ) =
Input Data Rate ( MHz ) × InterpolationRate × Prescaler
–20–
REV. 0
AD9775
0
CLK+ CLK–
PLLVDD
PLL_LOCK
1 = LOCK
0 = NO LOCK
–20
4
PHASE
DETECTOR
CHARGE
PUMP
PHASE NOISE – dBFS
AD9775
INTERPOLATION
FILTERS,
MODULATORS,
AND DACS
2
–10
LPF
8
1
–40
–50
–60
–70
–80
–90
CLOCK
DISTRIBUTION
CIRCUITRY
INPUT
DATA
LATCHES
–30
PRESCALER
VCO
–100
–110
INTERPOLATION
RATE
CONTROL
PLL
CONTROL
(PLL ON)
MODULATION
RATE
CONTROL
SPI PORT
Figure 12. PLL and Clock Circuitry with PLL Enabled
PLL_LOCK
1 = LOCK
0 = NO LOCK
AD9775
INTERPOLATION
FILTERS,
MODULATORS,
AND DACS
4
PHASE
DETECTOR
CHARGE
PUMP
PRESCALER
VCO
8
1
INPUT
DATA
LATCHES
INTERPOLATION
RATE
CONTROL
CLOCK
DISTRIBUTION
CIRCUITRY
PLL DIVIDER
(PRESCALER)
CONTROL
INTERNAL SPI
CONTROL
REGISTERS
SPI PORT
1
2
3
FREQUENCY OFFSET – MHz
4
5
Figure 14. Phase Noise Performance
It is important to note that the resistor/capacitor needed for the
PLL loop filter is internal on the AD9775. This will suffice unless
the input data rate is below 10 MHz, in which case an external
series RC is required between the LPF and PLLVDD pins.
POWER DISSIPATION
CLK+ CLK–
2
0
PLL DIVIDER
(PRESCALER)
CONTROL
INTERNAL SPI
CONTROL
REGISTERS
The AD9775 has three voltage supplies: AVDD, DVDD, and
CLKVDD. Figures 15, 16, and 17 show the current required
from each of these supplies when each is set to the 3.3 V nominal
specified for the AD9775. Power dissipation (PD) can easily be
extracted by multiplying the given curves by 3.3. As Figure 15
shows, IDVDD is very dependent on the input data rate, the interpolation rate, and the activation of the internal digital modulator.
IDVDD, however, is relatively insensitive to the modulation rate
by itself. In Figure 16, IAVDD shows the same type of sensitivity
to the data, the interpolation rate, and the modulator function
but to a much lesser degree (<10%). In Figure 17, ICLKVDD
varies over a wide range yet is responsible for only a small percentage of the overall AD9775 supply current requirements.
400
MODULATION
RATE
CONTROL
8ⴛ, (MOD. ON)
PLL
CONTROL
(PLL ON)
350
4 ⴛ, (MOD. ON)
2 ⴛ , (MOD. ON)
300
IDVDD – mA
Figure 13. PLL and Clock Circuitry with PLL Disabled
In addition, if the zero stuffing option is enabled, the VCO will
double its speed again. Phase noise may be slightly higher with
the PLL enabled. Figure 14 illustrates typical phase noise performance of the AD9775 with 2× interpolation and various
input data rates. The signal synthesized for the phase noise
measurement was a single carrier at a frequency of fDATA/4. The
repetitive nature of this signal eliminated quantization noise and
distortion spurs as a factor in the measurement. Although the
curves blend together in Figure 14, the different conditions are
called out here for clarity.
fDATA
PLL
Prescaler Ratio
125 MSPS
125 MSPS
100 MSPS
75 MSPS
50 MSPS
Disabled
Enabled
Enabled
Enabled
Enabled
div1
div2
div2
div4
REV. 0
8ⴛ
250
4ⴛ
2ⴛ
200
150
100
1ⴛ
50
0
0
50
100
fDATA – MHz
150
200
Figure 15. IDVDD vs. fDATA vs. Interpolation Rate,
PLL Disabled
–21–
AD9775
76.0
8 ⴛ, (MOD. ON)
ONE/TWO PORT INPUT MODES
2ⴛ, (MOD. ON)
The digital data input ports can be configured as two independent
ports or as a single (one port mode) port. In two port mode, the
AD9775 can be programmed to generate an externally available data rate clock (DATACLK) for the purpose of data
synchronization. Data at the two input ports can be latched into
the AD9775 on every rising clock edge of DATACLK. In one
port mode, P2B12 and P2B13 from input data Port 2 are
redefined as IQSEL and ONEPORTCLK, respectively. The
input data in one port mode is steered to one of the two internal
data channels based on the logic level of IQSEL. A clock signal,
ONEPORTCLK, is generated by the AD9775 in this mode for
the purpose of external data synchronization. ONEPORTCLK
runs at the input interleaved data rate which is 2× the data rate
at the internal input to either channel.
75.5
4 ⴛ, (MOD. ON)
IAVDD – mA
75.0
74.5
8ⴛ
74.0
4ⴛ
2ⴛ
73.5
73.0
1ⴛ
72.5
72.0
0
50
100
fDATA – MHz
150
200
Test configurations showing the various clocks that are required and
produced by the AD9775 in the PLL and one/two port modes
are given in Figures 55 through 58. Jumper positions needed to
operate the AD9775 evaluation board in these modes are given
as well.
Figure 16. IAVDD vs. fDATA vs. Interpolation Rate,
PLL Disabled
35
8ⴛ
30
ICLKVDD – mA
2ⴛ
4ⴛ
25
PLL ENABLED, TWO PORT MODE
(Control Register 02h, Bits 6–0 and 04h, Bits 7–1)
20
15
1ⴛ
10
5
0
0
50
100
fDATA – MHz
150
200
Figure 17. ICLKVDD vs. fDATA vs. Interpolation Rate,
PLL Disabled
SLEEP/POWER-DOWN MODES
(Control Register 00h, Bits 3 and 4)
The AD9775 provides two methods for programmable reduction
in power savings. The sleep mode, when activated, turns off the
DAC output currents but the rest of the chip remains functioning.
When coming out of sleep mode, the AD9775 will immediately
return to full operation. Power-down mode, on the other hand,
turns off all analog and digital circuitry in the AD9775 except
for the SPI port. When returning from power-down mode, enough
clock cycles must be allowed to flush the digital filters of random
data acquired during the power-down cycle.
With the phase-locked loop (PLL) enabled and the AD9775 in
two port mode, the speed of CLKIN is inherently that of the input
data rate. In two port mode, Pin 8 (DATACLK/PLL_ LOCK)
can be programmed (Control Register 01h, Bit 0) to function as
either a lock indicator for the internal PLL or as a clock running
at the input data rate. When Pin 8 is used as a clock output
(DATACLK), its frequency is equal to that of CLKIN. Data at
the input ports is latched into the AD9775 on the rising edge of the
CLKIN. Figure 18 shows the delay, tOD, inherent between the
rising edge of CLKIN and the rising edge of DATACLK, as well
as the setup and hold requirements for the data at Ports 1 and 2.
Note that the setup and hold times given in Figure 18 are the
input data transitions with respect to CLKIN. tOD can vary with
CLKIN speed, PLL divider setting, and interpolation rate. It is
therefore highly recommended that the input data be synchronized to CLKIN rather than DATACLK when the PLL is enabled.
Note that in two port mode (PLL enabled or disabled), the data
rate at the interpolation filter inputs is the same as the input data
rate at Ports 1 and 2.
The DAC output sample rate in two port mode is equal to the
clock input rate multiplied by the interpolation rate. If zero
stuffing is used, another factor of two must be included to calculate the DAC sample rate.
DATACLK Inversion
(Control Register 02h, Bit 4)
By programming this bit, the DATACLK signal shown in
Figure 18 can be inverted. With inversion enabled, tOD will
refer to the time between the rising edge of CLKIN and the
falling edge of DATACLK. No other effect on timing will occur.
–22–
REV. 0
AD9775
to the internal input data rate of the I and Q channels. The
selection of the data for the I or the Q channel is determined by the
state of the logic level at Pin 31 (IQSEL when the AD9775 is in
one port mode) on the rising edge of ONEPORTCLK. IQSEL
= 1 under these conditions will latch the data into the I channel
on the clock rising edge, while IQSEL = 0 will latch the data into
the Q channel. It is possible to invert the I and Q selection by setting control Register 02h, Bit 1 to the invert state (Logic “1”).
Figure 20 illustrates the timing requirements for the data inputs as
well as the IQSEL input. Note that the 1× interpolation rate is
not available in the one port mode.
tOD
CLKIN
DATACLK
The DAC output sample rate in one port mode is equal to CLKIN
multiplied by the interpolation rate. If zero stuffing is used, another
factor of two must be included to calculate the DAC sample rate.
DATA AT PORTS
1 AND 2
tS
t S = 0.0ns
t H = 2.5ns
(TYP SPECS)
tH
ONEPORTCLK INVERSION
(Control Register 02h, Bit 2)
Figure 18. Timing Requirements in Two Port
Input Mode, with PLL Enabled
DATACLK DRIVER STRENGTH
(Control Register 02h, Bit 5)
The DATACLK output driver strength is capable of driving
>10 mA into a 330 Ω load while providing a rise time of 3 ns.
Figure 19 shows DATACLK driving a 330 Ω resistive load at a
frequency of 50 MHz. By enabling the drive strength option
(Control Register 02h, Bit 5), the amplitude of DATACLK
under these conditions will be increased by approximately 200 mV.
By programming this bit, the ONEPORTCLK signal shown in
Figure 20 can be inverted. With inversion enabled, tOD refers to
the delay between the rising edge of the external clock and the
falling edge of ONEPORTCLK. The setup and hold times, tS
and tH, will be with respect to the falling edge of ONEPORTCLK.
There will be no other effect on timing.
ONEPORTCLK DRIVER STRENGTH
The drive capability of ONEPORTCLK is identical to that of
DATACLK in the two port mode. Refer to Figure 19 for performance under load conditions.
tOD
3.0
2.5
tOD = 4.7ns
t S = 3.0ns
t H = –0.5ns
tIQS = 3.5ns
tIQH = –1.5ns
CLKIN
FREQUENCY – V
2.0
1.5
ONEPORTCLK
1.0
0.5
0
DELTA APPROX. 2.8ns
I AND Q INTERLEAVED
INPUT DATA AT PORT 1
–0.5
0
10
20
30
40
50
TIME – ns
Figure 19. DATACLK Driver Capability into 330 Ω
at 50 MHz
tS tH
IQSEL
PLL ENABLED, ONE PORT MODE
(Control Register 02h, Bits 6–1 and 04h, Bits 7–1)
In one port mode, the I and Q channels receive their data from an
interleaved stream at digital input Port 1. The function of Pin 32
is defined as an output (ONEPORTCLK) that generates a clock at
the interleaved data rate which is 2× the internal input data
rate of the I and Q channels. The frequency of CLKIN is equal
REV. 0
tIQS
tIQH
Figure 20. Timing Requirements in One Port
Input Mode with the PLL Enabled
–23–
AD9775
IQ PAIRING
(Control Register 02h, Bit 0)
tOD
In one port mode, the interleaved data is latched into the
AD9775 internal I and Q channels in pairs. The order of how
the pairs are latched internally is defined by this control register.
The following is an example of the effect this has on incoming
interleaved data.
CLKIN
Given the following interleaved data stream, where the data
indicates the value with respect to full scale:
I
Q
I
Q
I
Q
I
Q
I
Q
0.5
0.5
1
1
0.5
0.5
0
0
0.5
0.5
DATACLK
With the control register set to “0” (I first), the data will appear
at the internal channel inputs in the following order in time:
I Channel
Q Channel
0.5
0.5
1
1
0.5
0.5
0
0
DATA AT PORTS
1 AND 2
0.5
0.5
tS
With the control register set to “1” (Q first), the data will appear at
the internal channel inputs in the following order in time:
I Channel
Q Channel
0.5
y
1
0.5
0.5
1
0
0.5
0.5
0
x
0.5
tH
t S = 5.0ns
t H = –3.2ns
(TYP SPECS)
Figure 21. Timing Requirements in Two Port
Input Mode with PLL Disabled
PLL DISABLED, ONE PORT MODE
The values x and y represent the next I value and the previous
Q value in the series.
PLL DISABLED, TWO PORT MODE
With the PLL disabled, a clock at the DAC output rate must be
applied to CLKIN. Internal clock dividers in the AD9775 synthesize the DATACLK signal at Pin 8, which runs at the input
data rate and can be used to synchronize the input data. Data is
latched into input Ports 1 and 2 of the AD9775 on the rising edge
of DATACLK. DATACLK speed is defined as the speed of
CLKIN divided by the interpolation rate. With zero stuffing
enabled, this division increases by a factor of 2. Figure 21
illustrates the delay between the rising edge of CLKIN and the
rising edge of DATACLK, as well as tS and tH in this mode.
The programmable modes DATACLK inversion and DATACLK
driver strength described in the previous section (PLL
Enabled, Two Port Mode) have identical functionality with
the PLL disabled.
As described earlier in the PLL-Enabled Mode section, tOD can
vary depending on CLKIN frequency and interpolation rate.
However, with the PLL disabled, the input data latches are
closely synchronized to DATACLK so that it is recommended
in this mode that the input data be timed from DATACLK, not CLKIN.
In one port mode, data is received into the AD9775 as an interleaved stream on Port 1. A clock signal (ONEPORT CLK),
running at the interleaved data rate which is 2× the input data
rate of the internal I and Q channels is available for data synchronization at Pin 32.
With PLL disabled, a clock at the DAC output rate must be applied
to CLKIN. Internal dividers synthesize the ONEPORTCLK
signal at Pin 32. The selection of the data for the I or Q channel
is determined by the state of the logic level applied to Pin 31
(IQSEL when the AD9775 is in one port mode) on the rising
edge of ONEPORTCLK. IQSEL = 1 under these conditions
will latch the data into the I channel on the clock rising edge,
while IQSEL = 0 will latch the data into the Q channel. It is
possible to invert the I and Q selection by setting control
Register 02h, Bit 1 to the invert state (Logic “1”). Figure 22
illustrates the timing requirements for the data inputs as well as
the IQSEL input. Note that the 1⫻ interpolation rate is not
available in the one port mode.
One port mode is very useful when interfacing with devices
such as Analog Devices’ AD6622 or AD6623 transmit signal
processors, in which two digital data channels have been interleaved (multiplexed).
–24–
REV. 0
AD9775
The programmable modes’ ONEPORTCLK inversion,
ONEPORTCLK driver strength, and IQ pairing described in
the previous section (PLL Enabled, One Port Mode) have
identical functionality with the PLL disabled.
tOD
CLKIN
AMPLITUDE MODULATION
Given two sine waves at the same frequency, but with a 90 phase
difference, a point of view in time can be taken such that the
waveform that leads in phase is cosinusoidal and the waveform
that lags is sinusoidal. Analysis of complex variables states that
the cosine waveform can be defined as having real positive and
negative frequency components, while the sine waveform consists
of imaginary positive and negative frequency images. This is
shown graphically in the frequency domain in Figure 23.
e–j␻t/2j
SINE
ONEPORTCLK
DC
e–j␻t/2j
e–j␻t /2
e–j␻t /2
COSINE
I AND Q INTERLEAVED
INPUT DATA AT PORT 1
DC
Figure 23. Real and Imaginary Components of
Sinusoidal and Cosinusoidal Waveforms
tS tH
tOD = 4.7ns
t S = 3.0ns
t H = –1.0ns
tIQS = 3.5ns
tIQH = –1.5ns
IQSEL
tIQS
tIQH
(TYP SPECS)
Figure 22. Timing Requirements in One Port
Input Mode with PLL Disabled
Amplitude modulating a baseband signal with a sine or a cosine
convolves the baseband signal with the modulating carrier in the
frequency domain. Amplitude scaling of the modulated signal
reduces the positive and negative frequency images by a factor of
two. This scaling will be very important in the discussion of the
various modulation modes. The phase relationship of the modulated signals is dependent on whether the modulating carrier is
sinusoidal or cosinusoidal, again with respect to the reference
point of the viewer. Examples of sine and cosine modulation are
given in Figure 24.
DIGITAL FILTER MODES
The I and Q data paths of the AD9775 have their own independent half-band FIR filters. Each data path consists of three FIR
filters, providing up to 8× interpolation for each channel. The
rate of interpolation is determined by the state of Control Register
01h, Bits 7 and 6. Figures 1a–1c show the response of the digital filters when the AD9775 is set to 2×, 4×, and 8× modes. The
frequency axes of these graphs have been normalized to the input
data rate of the DAC. As the graphs show, the digital filters can
provide greater than 75 dB of out-of-band rejection.
Ae–j␻t/2j
SINUSOIDAL
MODULATION
DC
Ae–j␻t/2j
Ae–j␻t /2
COSINUSOIDAL
MODULATION
An online tool is available for quick and easy analysis of the
AD9775 interpolation filters in the various modes. The link
can be accessed at: www.analog.com/techSupport/designTools/
interactiveTools/dac/ad9777image.html.
REV. 0
Ae–j␻t /2
DC
Figure 24. Baseband Signal, Amplitude
Modulated with Sine and Cosine Carriers
–25–
AD9775
MODULATION, NO INTERPOLATION
characteristics required for the DAC reconstruction filter. Note
also, per the previous discussion on amplitude modulation, that
the spectral components (where modulation is set to fS/4 or fS/8)
are scaled by a factor of 2. In the situation where the modulation is fS/2, the modulated spectral components add constructively
and there is no scaling effect.
0
0
–20
–20
AMPLITUDE – dBFS
AMPLITUDE – dBFS
With Control Register 01h, Bits 7 and 6 set to “00,” the interpolation function on the AD9775 is disabled. Figures 25a–25d
show the DAC output spectral characteristics of the AD9775 in
the various modulation modes, all with the interpolation filters
disabled. The modulation frequency is determined by the state
of Control Register 01h, Bits 5 and 4. The tall rectangles
represent the digital domain spectrum of a baseband signal of
narrow bandwidth. By comparing the digital domain spectrum
to the DAC SIN(x)/x roll-off, an estimate can be made for the
–40
–60
–40
–60
–80
–80
–100
–100
0
0.2
0.4
0.6
0.8
1.0
0
0.2
fOUT (ⴛfDATA)
0.6
0.8
1.0
fOUT (ⴛfDATA)
Figure 25a. No Interpolation, Modulation Disabled
Figure 25c. No Interpolation, Modulation = fDAC/4
0
0
–20
–20
AMPLITUDE – dBFS
AMPLITUDE – dBFS
0.4
–40
–60
–40
–60
–80
–80
–100
–100
0
0.2
0.4
0.6
0.8
1.0
0
fOUT (ⴛfDATA)
0.2
0.4
0.6
0.8
1.0
fOUT (ⴛfDATA)
Figure 25b. No Interpolation, Modulation = fDAC/2
Figure 25d. No Interpolation, Modulation = fDAC/8
Figure 25. Effects of Digital Modulation on DAC Output Spectrum, Interpolation Disabled
–26–
REV. 0
AD9775
MODULATION, INTERPOLATION = 2×
>70 dB. Another significant point is that the interpolation filtering is done previous to the digital modulator. For this reason, as
Figures 26a–26d show, the pass band of the interpolation
filters can be frequency shifted, giving the equivalent of a
high pass digital filter.
Note that when using the fS/4 modulation mode, there is no true
stop band as the band edges coincide with each other. In the fS/8
modulation mode, amplitude scaling occurs over only a portion of
the digital filter pass band due to constructive addition over just
that section of the band.
0
0
–20
–20
AMPLITUDE – dBFS
AMPLITUDE – dBFS
With Control Register 01h, Bits 7 and 6 set to “01,” the interpolation rate of the AD9775 is 2×. Modulation is achieved by
multiplying successive samples at the interpolation filter output
by the sequence (1, –1). Figures 26a–26d represent the spectral
response of the AD9775 DAC output with 2× interpolation in
the various modulation modes to a narrow band baseband signal
(again, the tall rectangles in the graphic). The advantage of
interpolation becomes clear in Figures 26a–26d, where it can
be seen that the images that would normally appear in the spectrum around the input data rate frequency are suppressed by
–40
–60
–80
–40
–60
–80
–100
–100
0
0.5
1.0
1.5
2.0
0
0.5
fOUT (ⴛfDATA)
1.5
0
–20
–20
AMPLITUDE – dBFS
0
–40
–60
–40
–60
–80
–80
–100
–100
0
0.5
1.0
1.5
0
2.0
0.5
1.0
1.5
2.0
fOUT (ⴛfDATA)
fOUT (ⴛfDATA)
Figure 26d. 2 × Interpolation, Modulation = fDAC/8
Figure 26b. 2 × Interpolation, Modulation = fDAC/2
Figure 26. Effects of Digital Modulation on DAC Output Spectrum, Interpolation = 2 ×
REV. 0
2.0
Figure 26c. 2 × Interpolation, Modulation = fDAC/4
Figure 26a. 2 × Interpolation, Modulation = Disabled
AMPLITUDE – dBFS
1.0
fOUT (ⴛfDATA)
–27–
AD9775
MODULATION, INTERPOLATION = 4×
by the sequence (0, 1, 0, –1). Figures 27a–27d represent the
spectral response of the AD9775 DAC output with 4× interpolation in the various modulation modes to a narrow band
baseband signal.
0
0
–20
–20
AMPLITUDE – dBFS
AMPLITUDE – dBFS
With Control Register 01h, Bits 7 and 6 set to “10,” the interpolation rate of the AD9775 is 4×. Modulation is achieved by
multiplying successive samples at the interpolation filter output
–40
–60
–80
–40
–60
–80
–100
–100
0
1
2
3
4
0
1
fOUT (ⴛfDATA)
Figure 27a. 4 × Interpolation, Modulation Disabled
3
4
Figure 27c. 4 × Interpolation, Modulation = fDAC/4
0
0
–20
–20
AMPLITUDE – dBFS
AMPLITUDE – dBFS
2
fOUT (ⴛfDATA)
–40
–60
–80
–40
–60
–80
–100
–100
0
1
2
3
4
0
fOUT (ⴛfDATA)
1
2
3
4
fOUT (ⴛfDATA)
Figure 27b. 4 × Interpolation, Modulation = fDAC/2
Figure 27d. 4 × Interpolation, Modulation = fDAC/8
Figure 27. Effect of Digital Modulation on DAC Output Spectrum, Interpolation = 4 ×
–28–
REV. 0
AD9775
MODULATION, INTERPOLATION = 8×
Looking at Figures 26–29, the user can see how higher interpolation rates reduce the complexity of the reconstruction filter needed
at the DAC output. It also becomes apparent that the ability to
modulate by fS/2, fS/4, or fS/8 adds a degree of flexibility in
frequency planning.
0
0
–20
–20
AMPLITUDE – dBFS
AMPLITUDE – dBFS
With Control Register 01h, Bits 7 and 6 set to “11,” the
interpolation rate of the AD9775 is 8×. Modulation is achieved
by multiplying successive samples at the interpolation filter
output by the sequence (0, 0.707, 1, 0.707, 0, –0.707, –1, 0.707).
Figures 28a–28d represent the spectral response of the AD9775
DAC output with 8× interpolation in the various modulation
modes to a narrow band baseband signal.
–40
–60
–80
–40
–60
–80
–100
0
1
2
3
–100
4
0
1
2
3
fOUT (ⴛfDATA)
Figure 28a. 8 × Interpolation, Modulation Disabled
5
6
7
8
Figure 28c. 8 × Interpolation, Modulation = fDAC/4
0
0
–20
–20
AMPLITUDE – dBFS
AMPLITUDE – dBFS
4
fOUT (ⴛf DATA)
–40
–60
–80
–40
–60
–80
–100
–100
0
1
2
3
4
0
fOUT (ⴛfDATA)
1
2
3
4
5
6
7
8
fOUT (ⴛfDATA)
Figure 28b. 8 × Interpolation, Modulation = fDAC/2
Figure 28d. 8 × Interpolation, Modulation = fDAC/8
Figure 28. Effect of Digital Modulation on DAC Output Spectrum, Interpolation = 8 ×
ZERO STUFFING
(Control Register 01h, Bit 3)
As shown in Figure 29, a “0” or null in the output frequency
response of the DAC (after interpolation, modulation, and DAC
reconstruction) occurs at the final DAC sample rate (fDAC).
This is due to the inherent SIN(x)/x roll-off response in the digitalto-analog conversion. In applications where the desired frequency
content is below fDAC/2, this may not be a problem. Note that at
fDAC/2 the loss due to SIN(x)/x is 4 dB. In direct RF applications, this roll-off may be problematic due to the increased
pass band amplitude variation as well as the reduced amplitude
of the desired signal.
REV. 0
Consider an application where the digital data into the AD9775
represents a baseband signal around fDAC/4 with a pass band of
fDAC/10. The reconstructed signal out of the AD9775 would
experience only a 0.75 dB amplitude variation over its pass band.
However, the image of the same signal occurring at 3 × fDAC/4
will suffer from a pass-band flatness variation of 3.93 dB. This
image may be the desired signal in an IF application using one
of the various modulation modes in the AD9775. This roll-off
of image frequencies can be seen in Figures 25 through 28,
where the effect of the interpolation and modulation rate is
apparent as well.
–29–
AD9775
If a complex modulation function (e+j␻t) is desired, the real and
imaginary components of the system correspond to the real and
imaginary components of e+j␻t, or cos␻t and sin␻t. As Figure
31 shows, the complex modulation function can be realized
by applying these components to the structure of the complex system defined in Figure 30.
10
ZERO STUFFING
ENABLED
SIN (X)/X ROLL-OFF – dBFS
0
–10
–20
COMPLEX MODULATION AND IMAGE REJECTION OF
BASEBAND SIGNALS
ZERO STUFFING
DISABLED
–30
In traditional transmit applications, a two-step upconversion is
done in which a baseband signal is modulated by one carrier to
an IF (intermediate frequency) and then modulated a second
time to the transmit frequency. Although this approach has
several benefits, a major drawback is that two images are created near the transmit frequency. Only one image is needed, the
other being an exact duplicate. Unless the unwanted image is
filtered, typically with analog components, transmit power is
wasted and the usable bandwidth available in the system is
reduced.
–40
–50
0
0.5
1.0
1.5
fOUT, NORMALIZED TO fDATA WITH ZERO STUFFING
2.0
DISABLED – Hz
Figure 29. Effect of Zero Stuffing on DAC’s SIN(x)/
x Response
To improve upon the pass-band flatness of the desired image,
the zero stuffing mode can be enabled by setting the control
register bit to a Logic “1.” This option increases the ratio of
fDAC/fDATA by a factor of 2 by doubling the DAC sample rate and
inserting a midscale sample (i.e., 1000 0000 0000 0000) after
every data sample originating from the interpolation filter. This
is important as it will affect the PLL divider ratio needed to keep
the VCO within its optimum speed range. Note that the zero
stuffing takes place in the digital signal chain at the output of the
digital modulator before the DAC.
A more efficient method of suppressing the unwanted image
can be achieved by using a complex modulator followed by a
quadrature modulator. Figure 32 is a block diagram of a
quadrature modulator. Note that it is in fact the real output half
of a complex modulator. The complete upconversion can actually be referred to as two complex upconversion stages, the real
output of which becomes the transmitted signal.
The net effect is to increase the DAC output sample rate by a
factor of 2× with the “0” in the SIN(x)/x DAC transfer function
occurring at twice the original frequency. A 6 dB loss in amplitude at low frequencies is also evident, as can be seen in Figure 29.
It is important to realize that the zero stuffing option by itself
does not change the location of the images but rather their amplitude, pass-band flatness, and relative weighting. For instance, in
the previous example, the pass-band amplitude flatness of the
image at 3 × fDATA/4 is now improved to 0.59 dB while the signal
level has increased slightly from –10.5 dBFS to –8.1 dBFS.
a(t)
INPUT
OUTPUT
c(t) ⴛ b(t) + d ⴛ b(t)
COMPLEX FILTER
= (c + jd)
b(t)
IMAGINARY
OUTPUT
INPUT
b(t) ⴛ a(t) + c ⴛ b(t)
Figure 30. Realization of a Complex System
INPUT
(REAL)
ⴛ
INPUT
(IMAGINARY)
ⴛ
INTERPOLATING (COMPLEX MIX MODE)
(Control Register 01h, Bit 2)
OUTPUT
(REAL)
90ⴗ
In the complex mix mode, the two digital modulators on the
AD9775 are coupled to provide a complex modulation function.
In conjunction with an external quadrature modulator, this
complex modulation can be used to realize a transmit image
rejection architecture. The complex modulation function can be
programmed for e+j␻t or e–j␻t to give upper or lower image rejection. As in the real modulation mode, the modulation frequency
␻ can be programmed via the SPI port for fDAC/2, fDAC/4, and
fDAC/8, where fDAC represents the DAC output rate.
OPERATIONS ON COMPLEX SIGNALS
Truly complex signals cannot be realized outside of a computer
simulation. However, two data channels, both consisting of real
data, can be defined as the real and imaginary components of a
complex signal. I (real) and Q (imaginary) data paths are often
defined this way. By using the architecture defined in Figure 30,
a system can be realized that operates on complex signals,
giving a complex (real and imaginary) output.
–30–
OUTPUT
(IMAGINARY)
e–j␻t = COS␻t + jSIN␻t
Figure 31. Implementation of a Complex Modulator
INPUT
(REAL)
ⴛ
INPUT
(IMAGINARY)
ⴛ
SIN␻t
OUTPUT
90ⴗ
COS␻t
Figure 32. Quadrature Modulator
REV. 0
AD9775
The entire upconversion, from baseband to transmit frequency,
is represented graphically in Figure 33. The resulting spectrum
shown in Figure 33 represents the complex data consisting of
the baseband real and imaginary channels, now modulated onto
orthogonal (cosine and negative sine) carriers at the transmit
frequency. It is important to remember that in this application
(two baseband data channels) the image rejection is not
dependent on the data at either of the AD9775 input channels.
In fact, image rejection will still occur with either one or both of
the AD9775 input channels active. Note that by changing the sign
of the sinusoidal multiplying term in the complex modulator, the
upper sideband image could have been suppressed while passing
the lower one. This is easily done in the AD9775 by selecting
the e+j␻t bit (Register 01h, Bit 1). In purely complex terms,
Figure 31 represents the two-stage upconversion from complex
baseband to carrier.
REAL CHANNEL (OUT)
A/2
A/2
–FC*
FC
–B/2J
B/2J
–FC
FC
REAL CHANNEL (IN)
A
DC
COMPLEX
MODULATOR
TO QUADRATURE
MODULATOR
IMAGINARY CHANNEL (OUT)
–A/2J
A/2J
–FC
–FC
B/2
B/2
–FC
FC
IMAGINARY CHANNEL (IN)
B
DC
*FC = COMPLEX MODULATION FREQUENCY
*FQ = QUADRATURE MODULATION FREQUENCY
A/4 + B/4J A/4 – B/4J
A/4 + B/4J A/4 – B/4J
–FQ*
–FQ – FC
FQ
–FQ + FC
FQ – FC
FQ + FC
OUT
REAL
–A/4 – B/4J A/4 – B/4J
A/4 + B/4J –A/4 + B/4J
QUADRATURE
MODULATOR
–FQ
IMAGINARY
FQ
REJECTED IMAGES
A/2 + B/2J
–FQ
A/2 – B/2J
FQ
Figure 33. Two-Stage Upconversion and Resulting Image Rejection
REV. 0
–31–
AD9775
imaginary inputs of the AD9775. A system in which multiple
baseband signals are complex modulated and then applied to
the AD9775 real and imaginary inputs followed by a quadrature
modulator is shown in Figure 36, which also describes the transfer
function of this system and the spectral output. Note the similarity of the transfer functions given in Figure 36 and Figure 34.
Figure 36 adds an additional complex modulator stage for the
purpose of summing multiple carriers at the AD9775 inputs. Also,
as in Figure 33, the image rejection is not dependent on the real
or imaginary baseband data on any channel. Image rejection on
a channel will occur if either the real or imaginary data, or both,
is present on the baseband channel.
COMPLEX BASEBAND
SIGNAL
1
OUTPUT = REAL
ⴛ
ej(␻1 + ␻2)t
1/2
= REAL
–␻1 – ␻2
1/2
␻1 + ␻2
FREQUENCY
DC
Figure 34. Two-Stage Complex Upconversion
IMAGE REJECTION AND SIDEBAND SUPPRESSION OF
MODULATED CARRIERS
It is important to remember that the magnitude of a complex signal
can be 1.414× the magnitude of its real or imaginary components.
Due to this 3 dB increase in signal amplitude, the real and imaginary inputs to the AD9775 must be kept at least 3 dB below full
scale when operating with the complex modulator. Overranging
in the complex modulator will result in severe distortion at the
DAC output.
As shown in Figure 33, image rejection can be achieved by applying
baseband data to the AD9775 and following the AD9775 with a
quadrature modulator. To process multiple carriers while still
maintaining image reject capability, each carrier must be complex
modulated. As Figure 34 shows, single- or multiple-complex
modulators can be used to synthesize complex carriers. These
complex carriers are then summed and applied to the real and
BASEBAND CHANNEL 1
REAL INPUT
R(1)
COMPLEX
MODULATOR 1
IMAGINARY INPUT
BASEBAND CHANNEL 2
REAL INPUT
MULTICARRIER
REAL OUTPUT =
R(1) + R(2) + ...R(N)
(TO REAL INPUT OF AD9775)
R(1)
R(2)
COMPLEX
MODULATOR 2
IMAGINARY INPUT
MULTICARRIER
IMAGINARY OUTPUT =
I(1) + I(2) + ...I(N)
(TO IMAGINARY INPUT OF AD9775)
R(2)
BASEBAND CHANNEL N
REAL INPUT
R(N) = REAL OUTPUT OF N
I(N) = IMAGINARY OUTPUT OF N
R(N)
COMPLEX
MODULATOR N
R(N)
IMAGINARY INPUT
Figure 35. Synthesis of Multicarrier Complex Signal
MULTIPLE
BASEBAND
CHANNELS
REAL
IMAGINARY
MULTIPLE
COMPLEX
MODULATORS
FREQUENCY = ␻1, ␻2...␻N
REAL
AD9775
COMPLEX
MODULATOR
FREQUENCY = ␻C
IMAGINARY
REAL
IMAGINARY
REAL
QUADRATURE
MODULATOR
FREQUENCY = ␻Q
COMPLEX BASEBAND
SIGNAL
ej(␻N + ␻C + ␻Q)t
OUTPUT = REAL
–␻1 – ␻C – ␻Q
␻ 1 + ␻ C + ␻Q
DC
REJECTED IMAGES
Figure 36. Image Rejection with Multicarrier Signals
–32–
REV. 0
AD9775
The complex carrier synthesized in the AD9775 digital modulator
is accomplished by creating two real digital carriers in quadrature.
Carriers in quadrature cannot be created with the modulator
running at fDAC/2. As a result, complex modulation only functions
with modulation rates of fDAC/4 and fDAC/8.
Region C
Region C is most accurately described as a down conversion, as the
modulating carrier is –ej␻t. If viewed as a complex signal, only the
images in Region C will remain. This image will appear on the
real and imaginary outputs of the AD9775, as well as on the
output of the quadrature modulator, where the center of the spectral plot will now represent the quadrature modulator LO and the
horizontal scale will represent the frequency offset from this LO.
Regions A and B of Figures 37 through 42 are the result of the
complex signal described above, when complex modulated in the
AD9775 by +ej␻t. Regions C and D are the result of the complex
signal described above, again with positive frequency components
only, modulated in the AD9775 by –ej␻t. The analog quadrature modulator after the AD9775 inherently modulates by +ej␻t.
Region D
Region A
Region A is a direct result of the upconversion of the complex
signal near baseband. If viewed as a complex signal, only the
images in Region A will remain. The complex Signal A, consisting
of positive frequency components only in the digital domain, has
images in the positive odd Nyquist zones (1, 3, 5...) as well as
images in the negative even Nyquist zones. The appearance and
rejection of images in every other Nyquist zone will become
more apparent at the output of the quadrature modulator. The
A images will appear on the real and the imaginary outputs of
the AD9775, as well as on the output of the quadrature modulator, where the center of the spectral plot will now represent the
quadrature modulator LO, and the horizontal scale now represents the frequency offset from this LO.
Region B
Region B is the image (complex conjugate) of Region A. If a spectrum analyzer is used to view the real or imaginary DAC outputs
of the AD9775, Region B will appear in the spectrum. However, on
the output of the quadrature modulator, Region B will be rejected.
REV. 0
Region D is the image (complex conjugate) of Region C. If a
spectrum analyzer is used to view the real or imaginary DAC
outputs of the AD9775, Region D will appear in the spectrum.
However, on the output of the quadrature modulator, Region D
will be rejected.
Figures 43 through 50 show the measured response of the AD9775
and AD8345 given the complex input signal to the AD9775 in
Figure 43. The data in these graphs was taken with a data rate of
12.5 MSPS at the AD9775 inputs. The interpolation rate of 4× or
8× gives a DAC output data rate of 50 MSPS or 100 MSPS. As a
result, the high end of the DAC output spectrum in these graphs
is the first null point for the SIN(x)/x roll-off, and the asymmetry
of the DAC output images is representative of the SIN(x)/x roll-off
over the spectrum. The internal PLL was enabled for these
results. In addition, a 35 MHz third order low-pass filter was
used at the AD9775/AD8345 interface to suppress DAC images.
An important point can be made by looking at Figures 45 and 47.
Figure 45 represents a group of positive frequencies modulated by
complex +fDAC/4, while Figure 47 represents a group of negative
frequencies modulated by complex –fDAC/4. When looking at the
real or imaginary outputs of the AD9775, as shown in Figures 45
and 47, the results look identical. However, the spectrum analyzer
cannot show the phase relationship of these signals. The difference in phase between the two signals becomes apparent when
they are applied to the AD8345 quadrature modulator, with the
results shown in Figures 46 and 48.
–33–
AD9775
0
0
–20
–20
D
A
B
C
D
A
B
C
–40
–40
–60
–60
–80
–80
D
–100
–2.0
–1.5
–1.0
–0.5
0
0.5
(LO)
fOUT (ⴛfDATA)
1.0
1.5
–100
–2.0
2.0
0
–20
–20
B
C
D
–1.0
A
B
–40
–60
–60
–80
–80
D A
–3.0
–2.0
–1.0
0
(LO)
–0.5
0
(LO)
0.5
1.0
2.0
3.0
–100
–4.0
4.0
–3.0
B
–2.0
B
1.0
C
1.5
2.0
–1.0
C D
A
0
(LO)
1.0
B
2.0
C
3.0
4.0
fOUT (ⴛfDATA)
fOUT (ⴛfDATA)
Figure 41. 4× Interpolation, Complex fDAC/8 Modulation
Figure 38. 4× Interpolation, Complex fDAC/4 Modulation
0
0
–20
–20
D
A
B
C
D
A
B
D A
C
–40
–40
–60
–60
–80
–80
–100
–8.0
A
C
–40
–100
–4.0
CD
Figure 40. 2× Interpolation, Complex fDAC/8 Modulation
0
A
–1.5
B
fOUT (ⴛfDATA)
Figure 37. 2× Interpolation, Complex fDAC/4 Modulation
D
A
–6.0
–4.0
–2.0
0
(LO)
2.0
4.0
6.0
–100
–8.0
8.0
fOUT (ⴛfDATA)
–6.0
B C
–4.0
–2.0
D A
0
2.0
(LO)
fOUT (ⴛfDATA)
B C
4.0
6.0
8.0
Figure 42. 8× Interpolation, Complex fDAC/8 Modulation
Figure 39. 8× Interpolation, Complex fDAC/4 Modulation
–34–
REV. 0
0
0
–10
–10
–20
–20
–30
–30
AMPLITUDE – dBm
AMPLITUDE – dBm
AD9775
–40
–50
–60
–70
–60
–70
–80
–90
–90
0
30
20
FREQUENCY – MHz
10
40
–100
50
Figure 43. AD9775, Real DAC Output of Complex
Input Signal Near Baseband (Positive Frequencies
Only), Interpolation = 4ⴛ , No Modulation in
AD9775
0
0
–10
–10
–20
–20
–30
–30
–40
–50
–60
–70
–70
–90
780
790 800 810 820
FREQUENCY – MHz
830
840
50
–60
–80
770
40
–50
–90
760
20
30
FREQUENCY – MHz
10
–40
–80
–100
750
0
Figure 45. AD9775, Real DAC Output of Complex
Input Signal Near Baseband (Positive Frequencies
Only), Interpolation = 4ⴛ, Complex Modulation in
AD9775 = +fDAC/4
AMPLITUDE – dBm
AMPLITUDE – dBm
–50
–80
–100
–100
750
850
760
770
780
790 800 810 820
FREQUENCY – MHz
830
Figure 46. AD9775 Complex Output from
Figure 45, Now Quadrature Modulated
by AD8345 (LO = 800 MHz)
Figure 44. AD9775 Complex Output from
Figure 43, Now Quadrature Modulated by AD8345
(LO = 800 MHz)
*Windows is a registered trademark of Microsoft Corporation
REV. 0
–40
–35–
840
850
0
0
–10
–10
–20
–20
–30
–30
AMPLITUDE – dBm
AMPLITUDE – dBm
AD9775
–40
–50
–60
–70
–80
–40
–50
–60
–70
–80
–90
–90
–100
–100
0
20
30
FREQUENCY – MHz
10
40
50
0
0
0
–10
–10
–20
–20
–30
–30
–40
–50
–60
–70
–80
–40
–50
–60
–70
–80
–90
–100
750
100
80
Figure 49. AD9775, Real DAC Output of Complex
Input Signal Near Baseband (Positive Frequencies
Only), Interpolation = 8ⴛ, Complex Modulation in
AD9775 = +fDAC/8
AMPLITUDE – dBm
AMPLITUDE – dBm
Figure 47. AD9775, Real DAC Output of Complex
Input Signal Near Baseband (Negative Frequencies
Only), Interpolation = 4ⴛ, Complex Modulation in
AD9775 = –fDAC/4
60
40
FREQUENCY – MHz
20
–90
760
770
780
790 800 810 820
FREQUENCY – MHz
830
840
–100
700
850
720
740
760
780 800 820 840
FREQUENCY – MHz
860
880
900
Figure 50. AD9775 Complex Output from
Figure 49, Now Quadrature Modulated by
AD8345 (LO = 800 MHz)
Figure 48. AD9775 Complex Output from
Figure 47, Now Quadrature Modulated by
AD8345 (LO = 800 MHz)
–36–
REV. 0
AD9775
APPLYING THE AD9775 OUTPUT CONFIGURATIONS
DIFFERENTIAL COUPLING USING A TRANSFORMER
The following sections illustrate typical output configurations for
the AD9775. Unless otherwise noted, it is assumed that IOUTFS
is set to a nominal 20 mA. For applications requiring optimum
dynamic performance, a differential output configuration is
suggested. A simple differential output may be achieved by converting IOUTA and IOUTB to a voltage output by terminating
them to AGND via equal value resistors. This type of configuration may be useful when driving a differential voltage input
device such as a modulator. If a conversion to a single-ended
signal is desired and the application allows for ac-coupling, an RF
transformer may be useful, or if power gain is required, an op amp
may be used. The transformer configuration provides optimum
high frequency noise and distortion performance. The differential op amp configuration is suitable for applications requiring
dc-coupling, signal gain, and/or level shifting within the bandwidth of the chosen op amp.
An RF transformer can be used to perform a differentialto-single-ended signal conversion as shown in Figure 52. A
differentially coupled transformer output provides the optimum
distortion performance for output signals whose spectral content
lies within the transformer’s pass band. An RF transformer such
as the Mini-Circuits T1-1T provides excellent rejection of
common-mode distortion (i.e., even-order harmonics) and noise
over a wide frequency range. It also provides electrical isolation
and the ability to deliver twice the power to the load. Transformers with different impedance ratios may also be used for
impedance matching purposes.
A single-ended output is suitable for applications requiring a
unipolar voltage output. A positive unipolar output voltage will
result if IOUTA and/or I OUTB is connected to a load resistor,
RLOAD, referred to AGND. This configuration is most suitable
for a single-supply system requiring a dc-coupled, ground referred
output voltage. Alternatively, an amplifier could be configured
as an I-V converter, thus converting IOUTA or IOUTB into a negative unipolar voltage. This configuration provides the best DAC
dc linearity as IOUTA or IOUTB are maintained at ground or virtual ground.
UNBUFFERED DIFFERENTIAL OUTPUT, EQUIVALENT
CIRCUIT
In many applications, it may be necessary to understand the
equivalent DAC output circuit. This is especially useful when
designing output filters or when driving inputs with finite input
impedances. Figure 51 illustrates the output of the AD9775 and
the equivalent circuit. A typical application where this information
may be useful is when designing an interface filter between the
AD9775 and Analog Devices’ AD8345 quadrature modulator.
IOUTA
VOUT+
IOUTB
VOUT–
RA + RB
VSOURCE =
IOUTFS ⴛ (RA + RB)
p-p
IOUTA
RLOAD
DAC
IOUTB
Figure 52. Transformer-Coupled Output Circuit
The center tap on the primary side of the transformer must be
connected to AGND to provide the necessary dc current path
for both IOUTA and IOUTB. The complementary voltages appearing
at IOUTA and IOUTB (i.e., VOUTA and VOUTB) swing symmetrically
around AGND and should be maintained within the specified
output compliance range of the AD9775. A differential resistor,
RDIFF, may be inserted in applications where the output of the
transformer is connected to the load, RLOAD, via a passive reconstruction filter or cable. RDIFF is determined by the transformer’s
impedance ratio and provides the proper source termination
that results in a low VSWR. Note that approximately half the
signal power will be dissipated across RDIFF.
DIFFERENTIAL COUPLING USING AN OP AMP
An op amp can also be used to perform a differential-to-singleended conversion as shown in Figure 53. This has the added
benefit of providing signal gain as well. In Figure 53, the AD9775
is configured with two equal load resistors, RLOAD, of 25 Ω. The
differential voltage developed across IOUTA and IOUTB is converted
to a single-ended signal via the differential op amp configuration. An optional capacitor can be installed across IOUTA and
IOUTB, forming a real pole in a low pass filter. The addition of
this capacitor also enhances the op amp’s distortion performance
by preventing the DAC’s fast slewing output from overloading
the input of the op amp.
500⍀
VOUT
(DIFFERENTIAL)
IOUTA
AD8021
COPT
225⍀
AVDD
For the typical situation, where IOUTFS = 20 mA and RA and RB
both equal 50 Ω, the equivalent circuit values become:
25⍀
VSOURCE = 2 V p-p
ROUT = 100 Ω
Note that the output impedance of the AD9775 DAC itself is
greater than 100 kΩ and typically has no effect on the impedance
of the equivalent output circuit.
225⍀
DAC
IOUTB
Figure 51. DAC Output Equivalent Circuit
REV. 0
MINI-CIRCUITS
T1-T2
25⍀
500⍀
ROPT
225⍀
Figure 53. Op Amp-Coupled Output Circuit
The common-mode (and second order distortion) rejection of this
configuration is typically determined by the resistor matching.
The op amp used must operate from a dual supply since its
output is approximately ± 1.0 V. A high speed amplifier, such as
the AD8021, capable of preserving the differential performance
–37–
AD9775
of the AD9775 while meeting other system level objectives (i.e.,
cost, power) is recommended. The op amp’s differential gain,
its gain setting resistor values, and full-scale output swing capabilities should all be considered when optimizing this circuit. ROPT
is only necessary if level shifting is required on the op amp output. In Figure 53, AVDD, which is the positive analog supply for
both the AD9775 and the op amp, is also used to level shift the
differential output of the AD9775 to midsupply (i.e., AVDD/2).
0
–10
AMPLITUDE – dBm
–20
INTERFACING THE AD9775 WITH THE AD8345
QUADRATURE MODULATOR
–30
–40
–50
–60
–70
–80
The AD9775 architecture was defined to operate in a transmit
signal chain using an image reject architecture. A quadrature
modulator is also required in this application and should be
designed to meet the output characteristics of the DAC as much
as possible. The AD8345 from Analog Devices meets many of
the requirements for interfacing with the AD9775. As with any
DAC output interface, there are a number of issues that have to
be resolved. Among the major issues are the following.
–90
–100
762.5
782.5
802.5
FREQUENCY – MHz
822.5
842.5
Figure 54. AD9775/AD8345 Synthesizing a ThreeCarrier WCDMA Signal at an LO of 800 MHz
EVALUATION BOARD
DAC Compliance Voltage/Input Common-Mode Range
The dynamic range of the AD9775 is optimal when the DAC
outputs swing between ± 1.0 V. The input common-mode range
of the AD8345, at 0.7 V, allows optimum dynamic range to be
achieved in both components.
Gain/Offset Adjust
The matching of the DAC output to the common-mode input
of the AD8345 allows the two components to be dc-coupled,
with no level shifting necessary. The combined voltage offset of
the two parts can therefore be compensated for via the AD9775
programmable offset adjust. This allows excellent LO cancellation at the AD8345 output. The programmable gain adjust
allows for optimal image rejection as well.
The AD9775 evaluation board includes an AD8345 and recommended interface (Figures 59 and 60). On the output of the
AD9775, R9 and R10 convert the DAC output current to a
voltage. R16 may be used to do a slight common-mode shift if
necessary. The (now voltage) signal is applied to a low pass
reconstruction filter to reject DAC images. The components
installed on the AD9775 provide a 35 MHz cutoff, but may be
changed to fit the application. A balun (Mini-Circuits ADTL1-12)
is used to cross the ground plane boundary to the AD8345.
Another balun (Mini-Circuits ETC1-1-13) is used to couple
the LO input of the AD8345. The interface requires a low ac
impedance return path from the AD8345, so a single connection between the AD9775 and AD8345 ground planes is
recommended.
The performance of the AD9775 and AD8345 in an image reject
transmitter, reconstructing three WCDMA carriers, can be seen
in Figure 54. The LO of the AD8345 in this application is 800 MHz.
Image rejection (50 dB) and LO feedthrough (–78 dBFS) have
been optimized with the programmable features of the AD9775.
The average output power of the digital waveform for this test
was set to –15 dBFS to account for the peak-to-average ratio of
the WCDMA signal.
The AD9775 evaluation board allows easy configuration of the
various modes, programmable via the SPI port. Software is
available for programming the SPI port from either Win95® or
Win98®. The evaluation board also contains an AD8345 quadrature modulator and support circuitry that allows the user to
optimally configure the AD9775 in an image reject transmit
signal chain.
Figures 55 through 58 describe how to configure the evaluation
board in the one and two port input modes with the PLL
enabled and disabled. Refer to Figures 59 through 68, the
schematics, and the layout for the AD9775 evaluation board for
the jumper locations described below. The AD9775 outputs can
be configured for various applications by referring to the following instructions.
DAC Single-Ended Outputs
Remove transformers T2 and T3. Solder jumper links JP4 or
JP28 to look at the DAC1 outputs. Solder jumper links JP29 or
JP30 to look at the DAC2 outputs. Jumpers 8 and 13–17 should
remain unsoldered. The jumpers JP35–JP38 may be used to
ground one of the DAC outputs while the other is measured
single-ended. Optimum single-ended distortion performance is
typically achieved in this manner. The outputs are taken from
S3 and S4.
DAC Differential Outputs
Transformers T2 and T3 should be in place. Note that the lower
band of operation for these transformers is 300 kHz to 500 kHz.
Jumpers 4, 8, 13–17, and 28–30 should remain unsoldered. The
outputs are taken from S3 and S4.
Using the AD8345
Remove transformers T2 and T3. Jumpers JP4 and 28–30 should
remain unsoldered. Jumpers 13–16 should be soldered. The
desired components for the low pass interface filter L6, L7, C55,
and C81 should be in place. The LO drive is connected to the
AD8345 via J10 and the balun T4; and the AD8345 output is
taken from J9.
Win95 and Win98 are a registered trademarks of Microsoft Corporation.
–38–
REV. 0
AD9775
LECROY
TRIG
PULSE
INP
GENERATOR
SIGNAL GENERATOR
DATACLK
INPUT CLOCK
AWG2021
OR
DG2020
CLK+/CLK–
40-PIN RIBBON CABLE
DAC1, DB11–DB0
DAC2, DB11–DB0
AD9775
JUMPER CONFIGURATION FOR TWO PORT MODE PLL ON
JP1 –
JP2 –
JP3 –
JP5 –
JP6 –
JP12 –
JP24 –
JP25 –
JP26 –
JP27 –
JP31 –
JP32 –
JP33 –
SOLDERED/IN
ⴛ
UNSOLDERED/OUT
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
Figure 55. Test Configuration for AD9775 in Two Port Mode with PLL Enabled, Signal Generator
Frequency = Input Data Rate, DAC Output Data Rate = Signal Generator Frequency ⴛ Interpolation Rate
LECROY
TRIG
PULSE
INP
GENERATOR
SIGNAL GENERATOR
ONEPORTCLK
INPUT CLOCK
CLK+/CLK–
AD9775
AWG2021
OR
DG2020
DAC1, DB11–DB0
DAC2, DB11–DB0
JUMPER CONFIGURATION FOR TWO PORT MODE PLL ON
JP1 –
JP2 –
JP3 –
JP5 –
JP6 –
JP12 –
JP24 –
JP25 –
JP26 –
JP27 –
JP31 –
JP32 –
JP33 –
SOLDERED/IN
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
UNSOLDERED/OUT
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
Figure 56. Test Configuration for AD9775 in One Port Mode with PLL Enabled, Signal Generator
Frequency = One-Half Interleaved Input Data Rate, ONEPORTCLK = Interleaved Input Data Rate, DAC Output
Data Rate = Signal Generator Frequency ⴛ Interpolation Rate
REV. 0
–39–
AD9775
LECROY
TRIG
PULSE
INP
GENERATOR
SIGNAL GENERATOR
DATACLK
INPUT CLOCK
AWG2021
OR
DG2020
CLK+/CLK–
40-PIN RIBBON CABLE
DAC1, DB11–DB0
DAC2, DB11–DB0
AD9775
JUMPER CONFIGURATION FOR TWO PORT MODE PLL OFF
JP1 –
JP2 –
JP3 –
JP5 –
JP6 –
JP12 –
JP24 –
JP25 –
JP26 –
JP27 –
JP31 –
JP32 –
JP33 –
SOLDERED/IN
ⴛ
UNSOLDERED/OUT
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
Figure 57. Test Configuration for AD9775 in Two Port Mode with PLL Disabled, DAC Output Data Rate = Signal
Generator Frequency, DATACLK = Signal Generator Frequency/Interpolation Rate
LECROY
TRIG
PULSE
INP
GENERATOR
SIGNAL GENERATOR
ONEPORTCLK
INPUT CLOCK
CLK+/CLK–
AD9775
AWG2021
OR
DG2020
DAC1, DB11–DB0
DAC2, DB11–DB0
JUMPER CONFIGURATION FOR TWO PORT MODE PLL OFF
JP1 –
JP2 –
JP3 –
JP5 –
JP6 –
JP12 –
JP24 –
JP25 –
JP26 –
JP27 –
JP31 –
JP32 –
JP33 –
SOLDERED/IN
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
UNSOLDERED/OUT
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
ⴛ
Figure 58. Test Configuration for AD9775 in One Port Mode with PLL Disabled, DAC Output Data Rate =
Signal Generator Frequency, ONEPORTCLK = Interleaved Input Data Rate = 2× Signal Generator
Frequency/Interpolation Rate
–40–
REV. 0
AD9775
O1N
O1P
C54
DNP
L4
DNP
C73
DNP
3
4
2
1
R37
DNP
6
R35
51⍀
J20
C77
100pF
C80
DNP
1
C78
0.1␮F
3
S
4
14
4
13
5
12
6
11
7
10
8
9
3
S
15
3
T4
ETC1-1-13
P
6
1
R33
51⍀
J19
R34
DNP
VDDMIN
P
5
4
R30
DNP
J21
16
IBBP
J7
JP18
R26
1k⍀
C74
100pF
R28
LOCAL OSC INPUT
0⍀
J10
DGND; 3, 4, 5
R23
0⍀
MODULATED OUTPUT
J10
DGND; 3, 4, 5
POWER INPUT FILTERS
W11
VDDMIN
L8 FERRITE
VDDM
C28
22␮F
16V
C32
0.1␮F
W12
TP2
RED
J8
J5
DVDD_IN
L3 FERRITE
J9
DVDD
AGND
C65
22␮F
16V
C66
22␮F
16V
C67
0.1␮F
TP3
BLK
TP4
RED
J4
J6
AVDD_IN
J10
L2 FERRITE
AVDD
AGND
C64
22␮F
16V
C61
22␮F
16V
C68
0.1␮F
TP5
BLK
TP6
RED
J3
J7
CLKVDD_IN
J11
L1 FERRITE
CLKVDD
AGND
C63
22␮F
16V
C69
0.1␮F
C62
22␮F
16V
TP7
BLK
Figure 59. AD8345 Circuitry on AD9775 Evaluation Board
REV. 0
–41–
L6
DNP
C81
DNP
T5
ADTL1-12
1
S
P
L7
DNP
C75
0.1␮F
C78
0.1␮F
T6
ADTL1-12
O2N
C55
DNP
C35
10␮F
L5
DNP
R36
51⍀
O2P
C72
10␮F VDDM
10V
R32
51⍀
C79
DNP
–42–
CX2
CX1
12
13
J34
OPCLK
J40
J27
J5
C29
0.1␮F
J3
C45
IQ
0.01␮F
AGND;3,4,5
S5
OPCLK
IQ
S6
AGND;3,4,5
OPCLK_3
BD15
2
3
5
4
J24
11
12
13
BD14
J31
J26
R39
1k⍀ J32
R5
49.9⍀
DVDD; 14
AGND; 7
74VCX86
TP14
WHT
C1
10␮F
6.3V
DVDD
DVDD
DVDD
DVDD
R1
200⍀
R38, 10k⍀
J23
R3
1k⍀
74VCX86 CX3
J25
11
AGND;3,4,5
S1
J12
R40
DVDD
200⍀
AGND;3,4,5
DATACLK
S2
R4
49.9⍀
1
6
J22
T1
T1-1T
J33
ADCLK
C13
0.1␮F
CLKIN
J2
J1
TP15
WHT
R2
1k⍀
C7
10␮F
6.3V
C8
10␮F
6.3V
C9
10␮F
6.3V
C10
10␮F
6.3V
C12
0.1␮F
C42
0.1␮F
BD11
C23
0.001␮F BD10
BD09
BD08
BD13
BD12
AD03
C24
0.001␮F AD02
AD01
AD00
AD09
C25
0.001␮F AD08
AD07
AD06
AD05
AD04
AD10
AD15
C26
0.001␮F AD14
AD13
AD12
AD11
C11
0.1␮F
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
AD9775
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
C36
0.1␮F
VDDA6
VSSA10
VDDA5
VSSA9
VDDA4
VSSA8
VSSA7
IOUT1P
IOUT1N
VSSA6
VSSA5
IOUT2P
IOUT2N
VSSA4
VSSA3
VDDA3
VSSA2
VDDA2
VSSA1
VDDA1
FSADJ1
FSADJ2
REFOUT
RESET
SP-CSB
SP-CLK
SP-SDI
SP-SDO
VSSD6
VDDD6
P2D0
P2D1
P2D2
P2D3
P2D4
P2D5
VSSD5
VDDD5
P2D6
P2D7
DVDD
VDDC1
LF
VDDC2
VSSC1
CLKP
CLKN
VSSC2
DCLK-PLLL
VSSD1
VDDD1
P1D15
P1D14
P1D13
P1D12
P1D11
P1D10
VSSD2
VDDD2
U1
P1D9
P1D8
P1D7
P1D6
P1D5
P1D4
VSSD3
VDDD3
P1D3
P1D2
P1D1
P1D0
P2D15-IQSEL
P2D14-OPCLK
P2D13
P2D12
VSSD4
VDDD4
P2D11
P2D10
P2D9
P2D8
CLKVDD
C20
0.1␮F
C38
0.1␮F
BD06
BD07
BD00
BD01
BD02
BD03
BD04
BD05
SPCSP
SPCLK
SPSDI
SPSDO
TP11
WHT
C22
0.001␮F
C40
0.1␮F
C15
0.1␮F
DVDD
C4
10␮F
6.3V
TP8
WHT
C6
10␮F
6.3V
DVDD
C2
10␮F
6.3V
AVDD
C41
0.1␮F
R7
2k⍀
C3
10␮F
6.3V
AVDD
C14
0.1␮F
C5
10␮F
6.3V
C16
0.1␮F
TP9
WHT
C17
0.1␮F
C58, DNP
C58, DNP
C19
0.1␮F
C39
0.1␮F
C21
0.001␮F
R6
1k⍀
TP10
WHT
C18
0.1␮F
C59, DNP
C57, DNP
C37
0.1␮F
R8
2k⍀
J38
J36
J35
J37
R11, 51⍀
R12, 51⍀
4
5
6
4
5
6
J14
J15
T1-1T
T3
J30
J29
J16
3
2
1
T2
T1-1T
J13
3
2
1
J28
J4
R9, 51⍀
R10, 51⍀
O1N
O1P
O2N
O2P
R17, 10⍀
C70, 0.1␮F
R43
49.9⍀
J17
AGND;3,4,5
OUT2
S4
R42
49.9⍀
AGND;3,4,5
OUT1
S3
R16, 10⍀
C70, 0.1␮F
J8
AD9775
Figure 60. AD9775 Clock, Power Supplies, and Output Circuitry
REV. 0
REV. 0
–43–
37
39
38
40
R15
220⍀
35
36
RIBBON
J1
33
22
34
21
20
31
19
18
32
17
16
29
15
14
30
13
12
27
11
10
28
9
8
25
7
26
5
6
23
3
4
24
1
2
DATA-A
R1
2
R2
3
R3
4
R4
5
R5
6
R6
7
R7
8
R8
9
ADCLK
9
1
2
3
4
5
6
7
8
RCON R1 R2 R3 R4 R5 R6 R7 R8
RCON
1
RP6
50⍀
Figure 61. AD9775 Evaluation Board Input (A Channel) and Clock Buffer Circuitry
PRE
4
K
R1
3
Q
6
5
DVDD
Q_
15
CLR
CLK
J
R1
2
R1
4
R1
5
R1
6
R1
7
R1
8
R1
9
2
1
U4
3
10
R9
R1
10
OPCLK_3
DVDD; 14
AGND; 7
74VCX86
OPCLK_2
9
1
2
3
4
5
6
7
8
RCON R1 R2 R3 R4 R5 R6 R7 R8
RCON
1
74LCX112
U7
2
1
3
1
16
RP1, 22⍀
2
15
RP1, 22⍀
3
14
RP1, 22⍀
4
13
RP1, 22⍀
5
12
RP1, 22⍀
6
11
RP1, 22⍀
7
10
RP1, 22⍀
8
9
RP2, 22⍀
1
16
RP2, 22⍀
2
15
RP2, 22⍀
3
14
RP2, 22⍀
4
13
RP2, 22⍀
5
12
RP2, 22⍀
6
11
RP2, 22⍀
7
10
RP2, 22⍀
8
9
RP2, 22⍀
RP5
50⍀
OPCLK
10
R9
R9
10
RP8
DNP
AD00
AD01
AD02
AD03
AD04
AD05
AD06
AD07
AD08
AD09
AD10
AD11
AD12
AD13
AD14
AD15
RP7
DNP
CX1
CX1
J
6
Q
74LCX112
U7
DVDD
DVDD
CX3
DVDD
14 AGND; 8
DVDD; 16
7
9
DVDD; 14
AGND; 7
PRE
10
U4
8
DVDD; 14
AGND; 7
74VCX86
U4
8
DVDD; 14
AGND; 7
74VCX86
U4
6
DVDD; 14
AGND; 7
74VCX86
U4
3
DVDD; 14
AGND; 7
74VCX86
U4
74VCX86
12 CLK
13
Q_
K
CLR
11
4
5
10
9
10
9
5
4
2
1
C52
4.7␮F
6.3V
C31
4.7␮F
6.3V
C30
4.7␮F
6.3V
C53
0.1␮F
C34
0.1␮F
C33
0.1␮F
AD9775
AD9775
DATA-B
RCON
1
2
1
4
3
6
5
8
7
10
9
12
11
14
13
16
15
18
17
20
19
22
21
24
23
26
25
28
27
30
29
32
31
34
33
36
35
38
37
40
39
R1
2
R2
3
R3
4
R4 R5 R6
5
6
7
R7
8
R8
9
RP12
50⍀
R9
10
RCON
1
R1
2
R1
3
R1 R1
4
5
R1
6
R1
7
R1
8
R1 R1
9 10
1
16
RP3, 22⍀
2
15
RP3, 22⍀
3
14
RP3, 22⍀
4
13
RP3, 22⍀
5
12
RP3, 22⍀
6
11
RP3, 22⍀
7
10
RP3, 22⍀
8
9
RP4, 22⍀
1
16
RP4, 22⍀
2
15
RP4, 22⍀
3
14
RP4, 22⍀
4
13
RP4, 22⍀
5
12
RP4, 22⍀
6
11
RP4, 22⍀
7
10
RP4, 22⍀
8
9
RP4, 22⍀
1
2
3
4
RCON R1 R2 R3
9
5
6
7
8
R4 R5 R6 R7 R8
10
R9
BD15
BD14
BD13
BD12
BD11
BD10
BD09
BD08
BD07
BD06
BD05
BD04
BD03
BD02
BD01
BD00
DVDD
C43
4.7␮F
6.3V
1
U5
74AC14
4
U5
74AC14
SPCLK
10
R9 RP10
DNP
DVDD
RIBBON
J2
SPCSB
9
7
8
R6 R7 R8
1
2
3
4
5
6
RCON R1 R2 R3 R4 R5
RP11
50⍀
RP9
DNP
6
U5
74AC14
C44
4.7␮F
6.3V
C50
0.1␮F
2
AGND; 7
DVDD; 14
3
AGND; 7
DVDD; 14
5
AGND; 7
DVDD; 14
12
U5
74AC14
10
U5
74AC14
8
U5
74AC14
13
C51
0.1␮F
R50
9k⍀
AGND; 7
DVDD; 14
11
P1
1
AGND; 7
DVDD; 14
9
SPI PORT
R48
9k⍀
2
R45
9k⍀
AGND; 7
DVDD; 14
3
4
5
6
SPSDI
SPSDO
1
U6
2
AGND; 7
74AC14 DVDD; 14
3
U6
4
AGND; 7
74AC14 DVDD; 14
5
U6
74AC14
6
AGND; 7
DVDD; 14
13
U6
12
AGND; 7
74AC14 DVDD; 14
11
U6
10
AGND; 7
74AC14 DVDD; 14
9
U6
8
AGND; 7
74AC14 DVDD; 14
Figure 62. AD9775 Evaluation Board Input (B Channel) and SPI Port Circuitry
–44–
REV. 0
AD9775
Figure 63. AD9775 Evaluation Board Components, Top Side
Figure 64. AD9775 Evaluation Board Components, Bottom Side
REV. 0
–45–
AD9775
Figure 65. AD9775 Evaluation Board Layout, Layer One (Top)
Figure 66. AD9775 Evaluation Board Layout, Layer Two (Ground Plane)
–46–
REV. 0
AD9775
Figure 67. AD9775 Evaluation Board Layout, Layer Three (Power Plane)
Figure 68. AD9775 Evaluation Board Layout, Layer Four (Bottom)
REV. 0
–47–
AD9775
OUTLINE DIMENSIONS
80-Lead, Thermally Enhanced, Thin Plastic Quad Flatpack [TQFP]
(SV-80)
Dimensions shown in millimeters and (inches)
14.00 (0.5512) SQ
12.00 (0.4724) SQ
80
61
80
61
60
1
SEATING
PLANE
60
1
PIN 1
TOP VIEW
BOTTOM
VIEW
(PINS DOWN)
20
COPLANARITY
0.15 (0.0059)
0.05 (0.0020)
C02858–0–5/02(0)
1.20 (0.0472)
MAX
0.75 (0.0295)
0.60 (0.0236)
0.45 (0.0177)
41
21
6.00 (0.2362) SQ
20
41
40
40
21
1.05 (0.0413)
1.00 (0.0394)
0.95 (0.0374)
0.20 (0.0079)
0.09 (0.0035)
GAGE PLANE
0.25 (0.0098)
0.50 (0.0197)
BSC
0.27 (0.0106)
0.22 (0.0087)
0.17 (0.0067)
7ⴗ
3.5ⴗ
0ⴗ
CONTROLLING DIMENSIONS ARE IN MILLIMETERS; INCH DIMENSIONS
(IN PARENTHESES) ARE ROUNDED-OFF MILLIMETER EQUIVALENTS FOR
REFERENCE ONLY AND ARE NOT APPROPRIATE FOR USE IN DESIGN
COMPLIANT TO JEDEC STANDARDS MO-026-ADD
PRINTED IN U.S.A.
AN APPLICATION NOTE DETAILING THE THERMALLY ENHANCED TQFP
CAN BE FOUND AT;
www.amkor.com/products/notes_papers/MLF_Appnote_0301.pdf
–48–
REV. 0