AD AD9852_07

CMOS 300 MSPS Complete DDS
AD9852
FEATURES
Frequency ramped FSK
<25 ps rms total jitter in clock generator mode
Automatic bidirectional frequency sweeping
Sin(x)/x correction
Simplified control interface
10 MHz serial 2-wire or 3-wire SPI-compatible
100 MHz parallel 8-bit programming
3.3 V single supply
Multiple power-down functions
Single-ended or differential input reference clock
Small, 80-lead LQFP or TQFP with exposed pad
300 MHz internal clock rate
FSK, BPSK, PSK, chirp, AM operation
Dual integrated 12-bit D/A converters
Ultrahigh speed comparator, 3 ps rms jitter
Excellent dynamic performance
80 dB SFDR at 100 MHz (±1 MHz) AOUT
4× to 20× programmable reference clock multiplier
Dual 48-bit programmable frequency registers
Dual 14-bit programmable phase offset registers
12-bit programmable amplitude modulation and on/off
output shaped keying function
Single-pin FSK and BPSK data interfaces
PSK capability via I/O interface
Linear or nonlinear FM chirp functions with single pin
frequency hold function
APPLICATIONS
Agile LO frequency synthesis
Programmable clock generator
FM chirp source for radar and scanning systems
Test and measurement equipment
Commercial and amateur RF exciter
FUNCTIONAL BLOCK DIAGRAM
48
I
17
17
PHASE-TOAMPLITUDE
CONVERTER
SYSTEM
CLOCK
48
PHASE
ACCUMULATOR
ACC 2
MUX
48
INV
SINC
FILTER
12
DIGITAL MULTIPLIERS
12
MUX
SYSTEM
CLOCK
DEMUX
ANALOG
OUT
12
3
MUX
MUX
MUX
DELTA
FREQUENCY
RATE TIMER
2
48 SYSTEM
CLOCK
DELTA
FREQUENCY
WORD
BIDIRECTIONAL
INTERNAL/EXTERNAL
I/O UPDATE CLOCK
ANALOG
OUT
DAC RSET
12-BIT
CONTROL
DAC
14
Q
FSK/BPSK/HOLD
DATA IN
12-BIT
COSINE
DAC
MODE SELECT
SYSTEM
CLK
CLOCK
Q
D
INT
EXT
SYSTEM
CLOCK
48
48
FREQUENCY FREQUENCY
TUNING
TUNING
WORD 2
WORD 1
14
COMPARATOR
12
14
FIRST 14-BIT
PHASE/OFFSET
WORD
ANALOG
IN
PROGRAMMABLE
AMPLITUDE AND
RATE CONTROL
SECOND 14-BIT
PHASE/OFFSET
WORD
CLOCK
OUT
AM
12-BIT DC
MODULATION CONTROL
PROGRAMMING REGISTERS
÷2
SYSTEM
CLOCK
AD9852
OSK
BUS
INTERNAL
PROGRAMMABLE
UPDATE CLOCK
GND
I/O PORT BUFFERS
READ
WRITE
SERIAL/
PARALLEL
SELECT
6-BIT ADDRESS
OR SERIAL
PROGRAMMING
LINES
+VS
8-BIT
PARALLEL
LOAD
MASTER
RESET
00634-001
DIFF/SINGLE
SELECT
REFCLK
BUFFER
DDS CORE
MUX
REFERENCE
CLOCK IN
FREQUENCY
ACCUMULATOR
ACC 1
SYSTEM CLOCK
4× TO 20×
REFCLK
MULTIPLIER
Figure 1.
Rev. E
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. Specifications subject to change without notice. No
license is granted by implication or otherwise under any patent or patent rights of Analog Devices.
Trademarks and registered trademarks are the property of their respective owners.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700
www.analog.com
Fax: 781.461.3113 ©2002–2007 Analog Devices, Inc. All rights reserved.
AD9852
TABLE OF CONTENTS
Features .............................................................................................. 1
Inverse Sinc Function ................................................................ 29
Applications....................................................................................... 1
REFCLK Multiplier .................................................................... 29
Functional Block Diagram .............................................................. 1
High Speed Comparator............................................................ 30
Revision History ............................................................................... 3
Power-Down ............................................................................... 30
General Description ......................................................................... 4
Programming the AD9852............................................................ 31
Overview........................................................................................ 4
MASTER RESET ........................................................................ 31
Specifications..................................................................................... 5
Parallel I/O Operation ............................................................... 31
Absolute Maximum Ratings............................................................ 8
Serial Port I/O Operation.......................................................... 31
Thermal Resistance ...................................................................... 8
General Operation of the Serial Interface ................................... 34
Explanation of Test Levels ........................................................... 8
Instruction Byte .......................................................................... 34
ESD Caution.................................................................................. 8
Serial Interface Port Pin Descriptions ..................................... 35
Pin Configuration and Function Descriptions............................. 9
MSB/LSB Transfers .................................................................... 35
Typical Performance Characteristics ........................................... 12
Control Register Descriptions .................................................. 36
Typical Applications ....................................................................... 16
Power Dissipation and Thermal Considerations ....................... 38
Modes of Operation ....................................................................... 18
Thermal Impedance................................................................... 38
Single Tone (Mode 000)............................................................. 18
Junction Temperature Considerations .................................... 38
Unramped FSK (Mode 001)...................................................... 19
Evaluation of Operating Conditions............................................ 40
Ramped FSK (Mode 010) .......................................................... 19
Thermally Enhanced Package Mounting Guidelines............ 40
Chirp (Mode 011)....................................................................... 22
Evaluation Board ............................................................................ 41
BPSK (Mode 100) ....................................................................... 26
Evaluation Board Instructions.................................................. 41
Using the AD9852 .......................................................................... 27
General Operating Instructions ............................................... 41
Internal and External Update Clock ........................................ 27
Using the Provided Software .................................................... 43
On/Off Output Shaped Keying (OSK) .................................... 27
Support ........................................................................................ 43
Cosine DAC ................................................................................ 29
Outline Dimensions ....................................................................... 51
Control DAC ............................................................................... 29
Ordering Guide .......................................................................... 52
Rev. E | Page 2 of 52
AD9852
REVISION HISTORY
5/07—Rev. D to Rev. E
Changed AD9852ASQ to AD9852ASVZ ....................... Universal
Changed AD9852AST to AD9852ASTZ......................... Universal
Change to Features............................................................................1
Changes to Endnote 10 of Table 1...................................................7
Changes to Absolute Maximum Ratings........................................8
Added Thermal Resistance Section ................................................8
Change to Ramped FSK (Mode 010) Section..............................19
Change to Internal and External Update Clock Section............27
Change to Thermal Impedance Section.......................................38
Changes to Junction Temperature Considerations Section.......38
Changes to Thermally Enhanced Package Mounting
Guidelines Section......................................................................40
Deleted Figure 61 to Figure 64 ......................................................41
Changes to Table 14 ........................................................................44
Updated Outline Dimensions........................................................51
Changes to Ordering Guide...........................................................52
3/02—Rev. A to Rev. B
Changes to General Description .....................................................1
Changes to Functional Block Diagram ..........................................1
Changes to Specifications ................................................................3
Changes to Absolute Maximum Ratings........................................5
Changes to Pin Function Descriptions ..........................................6
Changes to Figure 3 ..........................................................................8
Deleted Two TPCs ..........................................................................11
Changes to Figure 18 and Figure 19 .............................................11
Changes to BPDK Mode Section ..................................................21
Changes to Differential Refclk Enable Section ...........................24
Changes to Master Reset Section ..................................................24
Changes to Parallel I/O Operation Section .................................24
Changes to General Operation of the Serial
Interface Section..............................................................................27
Changes to Figure 50 ......................................................................27
Changes to Figure 65 ......................................................................36
12/05—Rev. C to Rev. D
Updated Format.................................................................. Universal
Changes to General Description .....................................................4
Changes to Explanation of Test Levels Section .............................9
Change to Pin Configuration ........................................................10
Changes to Figure 65 ......................................................................47
Changes to Outline Dimensions ...................................................52
Changes to Ordering Guide...........................................................52
4/04—Rev. B to Rev. C
Updated Format.................................................................. Universal
Changes to Figure 1...........................................................................1
Changes to General Description .....................................................3
Changes to Table 1 ............................................................................4
Changes to Footnote 2 ......................................................................6
Changes to Figure 2...........................................................................8
Changes to Table 5 ..........................................................................17
Changes to Equation in Ramped FSK (Mode 010).....................19
Changes to Evaluation Board Instructions ..................................39
Changes to General Operating Instructions Section..................39
Changes to Using the Provided Software Section.......................42
Changes to Figure 65 ......................................................................43
Changes to Figure 66 ......................................................................44
Changes to Figure 72 and Figure 73 .............................................48
Changes to Ordering Guide...........................................................48
Rev. E | Page 3 of 52
AD9852
GENERAL DESCRIPTION
The AD9852 digital synthesizer is a highly integrated device
that uses advanced DDS technology, coupled with an internal
high speed, high performance D/A converter to form a digitally
programmable, agile synthesizer function. When referenced to
an accurate clock source, the AD9852 generates a highly stable
frequency-, phase-, and amplitude-programmable cosine output
that can be used as an agile LO in communications, radar, and
many other applications. The innovative high speed DDS core
of the AD9852 provides 48-bit frequency resolution (1 μHz
tuning resolution with 300 MHz SYSCLK). Maintaining 17 bits
ensures excellent SFDR.
The circuit architecture of the AD9852 allows the generation of
output signals at frequencies up to 150 MHz, which can be
digitally tuned at a rate of up to 100 million new frequencies
per second. The (externally filtered) cosine wave output can be
converted to a square wave by the internal comparator for agile
clock generator applications. The device provides two 14-bit
phase registers and a single pin for BPSK operation.
For higher-order PSK operation, the I/O interface can be used
for phase changes. The 12-bit cosine DAC, coupled with the
innovative DDS architecture, provides excellent wideband and
narrow-band output SFDR. When configured with the
comparator, the 12-bit control DAC facilitates static duty cycle
control in the high speed clock generator applications.
The 12-bit digital multiplier permits programmable amplitude
modulation, on/off output shaped keying, and precise amplitude
control of the cosine DAC output. Chirp functionality is also
included for wide bandwidth frequency sweeping applications.
The AD9852 programmable 4× to 20× REFCLK multiplier circuit internally generates the 300 MHz system clock from a lower
frequency external reference clock. This saves the user the expense
and difficulty of implementing a 300 MHz system clock source.
Direct 300 MHz clocking is also accommodated with either singleended or differential inputs. Single-pin, conventional FSK and the
enhanced spectral qualities of ramped FSK are supported. The
AD9852 uses advanced 0.35 μ CMOS technology to provide this
high level of functionality on a single 3.3 V supply.
The AD9852 is pin-for-pin compatible with the AD9854 singletone synthesizer. The AD9852 is specified to operate over the
extended industrial temperature range of −40°C to +85°C.
OVERVIEW
The AD9852 digital synthesizer is a highly flexible device that
addresses a wide range of applications. The device consists of
an NCO with a 48-bit phase accumulator, a programmable
reference clock multiplier, an inverse sinc filter, a digital
multiplier, two 12-bit/300 MHz DACs, a high speed analog
comparator, and an interface logic. This highly integrated
device can be configured to serve as a synthesized LO agile
clock generator and FSK/BPSK modulator. The theory of
operation for the functional blocks of the device and a technical
description of the signal flow through a DDS device is provided
by Analog Devices, Inc., in the tutorial A Technical Tutorial on
Digital Signal Synthesis. The tutorial also provides basic
applications information for a variety of digital synthesis
implementations.
Rev. E | Page 4 of 52
AD9852
SPECIFICATIONS
VS = 3.3 V ± 5%, RSET = 3.9 kΩ, external reference clock frequency = 30 MHz with REFCLK multiplier enabled at 10× for AD9852ASVZ,
external reference clock frequency = 20 MHz with REFCLK multiplier enabled at 10× for AD9852ASTZ, unless otherwise noted.
Table 1.
Parameter
REFERENCE CLOCK INPUT CHARACTERISTICS 1
Internal System Clock Frequency Range
REFCLK Multiplier Enabled
REFCLK Multiplier Disabled
External Reference Clock Frequency Range
REFCLK Multiplier Enabled
REFCLK Multiplier Disabled
Duty Cycle
Input Capacitance
Input Impedance
Differential Common-Mode Voltage Range
Minimum Signal Amplitude 2
Common-Mode Range
VIH (Single-Ended Mode)
VIL (Single-Ended Mode)
DAC STATIC OUTPUT CHARACTERISTICS
Output Update Speed
Resolution
Cosine and Control DAC Full-Scale Output Current
Gain Error
Temp
Test
Level
AD9852ASVZ
Min
Typ
Max
AD9852ASTZ
Min
Typ
Max
Unit
Full
Full
VI
VI
20
DC
300
300
20
DC
200
200
MHz
MHz
Full
Full
25°C
25°C
25°C
VI
VI
IV
IV
IV
5
DC
45
75
300
55
5
DC
45
50
200
55
MHz
MHz
%
pF
kΩ
25°C
25°C
25°C
25°C
IV
IV
IV
IV
400
1.6
2.3
1.9
400
1.6
2.3
Full
25°C
25°C
25°C
I
IV
IV
I
Output Offset
Differential Nonlinearity
Integral Nonlinearity
Output Impedance
Voltage Compliance Range
DAC DYNAMIC OUTPUT CHARACTERISTICS
DAC Wideband SFDR
1 MHz to 20 MHz AOUT
20 MHz to 40 MHz AOUT
40 MHz to 60 MHz AOUT
60 MHz to 80 MHz AOUT
80 MHz to 100 MHz AOUT
100 MHz to 120 MHz AOUT
DAC Narrow-Band SFDR
10 MHz AOUT (±1 MHz)
10 MHz AOUT (±250 kHz)
10 MHz AOUT (±50 kHz)
41 MHz AOUT (±1 MHz)
41 MHz AOUT (±250 kHz)
41 MHz AOUT (±50 kHz)
119 MHz AOUT (±1 MHz)
119 MHz AOUT (±250 kHz)
119 MHz AOUT (±50 kHz)
25°C
25°C
25°C
25°C
25°C
I
I
I
IV
I
25°C
25°C
25°C
25°C
25°C
25°C
V
V
V
V
V
V
58
56
52
48
48
48
58
56
52
48
48
dBc
dBc
dBc
dBc
dBc
dBc
25°C
25°C
25°C
25°C
25°C
25°C
25°C
25°C
25°C
V
V
V
V
V
V
V
V
V
83
83
91
82
84
89
71
77
83
83
83
91
82
84
89
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
50
3
100
1.75
50
3
100
1.75
1
1
300
5
−6
12
10
0.3
0.6
100
−0.5
Rev. E | Page 5 of 52
1.9
200
20
+2.2
5
2
1.25
1.66
5
−6
+1.0
−0.5
12
10
0.3
0.6
100
20
+2.2
5
2
1.25
1.66
+1.0
mV p-p
V
V
V
MSPS
Bits
mA
% FS
μA
LSB
LSB
kΩ
V
AD9852
Parameter
Residual Phase Noise
(AOUT = 5 MHz, External Clock = 30 MHz,
REFCLK Multiplier Engaged at 10×)
1 kHz Offset
10 kHz Offset
100 kHz Offset
(AOUT = 5 MHz, External Clock = 300 MHz,
REFCLK Multiplier Bypassed)
1 kHz Offset
0 kHz Offset
100 kHz Offset
PIPELINE DELAYS 3, 4, 5
DDS Core (Phase Accumulator and
Phase-to-Amp Converter)
Frequency Accumulator
Inverse Sinc Filter
Digital Multiplier
DAC
I/O Update Clock (Internal Mode)
I/O Update Clock (External Mode)
MASTER RESET DURATION
COMPARATOR INPUT CHARACTERISTICS
Input Capacitance
Input Resistance
Input Current
Hysteresis
COMPARATOR OUTPUT CHARACTERISTICS
Logic 1 Voltage, High-Z Load
Logic 0 Voltage, High-Z Load
Output Power, 50 Ω Load, 120 MHz Toggle Rate
Propagation Delay
Output Duty Cycle Error 6
Rise/Fall Time, 5 pF Load
Toggle Rate, High-Z Load
Toggle Rate, 50 Ω Load
Output Cycle-to-Cycle Jitter 7
COMPARATOR NARROW-BAND SFDR 8
10 MHz (±1 MHz)
10 MHz (±250 MHz)
10 MHz (±50 kHz)
41 MHz (±1 MHz)
41 MHz (±250 kHz)
41 MHz (±50 kHz)
119 MHz (±1 MHz)
119 MHz (±250 kHz)
119 MHz (±50 kHz)
CLOCK GENERATOR OUTPUT JITTER8
5 MHz AOUT
40 MHz AOUT
100 MHz AOUT
Temp
Test
Level
AD9852ASVZ
Min
Typ
Max
AD9852ASTZ
Min
Typ
Max
25°C
25°C
25°C
V
V
V
140
138
142
140
138
142
dBc/Hz
dBc/Hz
dBc/Hz
25°C
25°C
25°C
V
V
V
142
148
152
142
148
152
dBc/Hz
dBc/Hz
dBc/Hz
25°C
IV
33
33
SYSCLK cycles
25°C
25°C
25°C
25°C
25°C
25°C
25°C
IV
IV
IV
IV
IV
IV
IV
26
16
9
1
2
3
26
16
9
1
2
3
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
25°C
25°C
25°C
25°C
V
IV
I
IV
3
500
±1
10
pF
kΩ
μA
mV p-p
Full
Full
25°C
25°C
25°C
25°C
25°C
25°C
25°C
VI
VI
I
IV
I
V
IV
IV
IV
25°C
25°C
25°C
25°C
25°C
25°C
25°C
25°C
25°C
V
V
V
V
V
V
V
V
V
84
84
92
76
82
89
73
73
83
84
84
92
76
82
89
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
25°C
25°C
25°C
V
V
V
23
12
7
23
12
7
ps rms
ps rms
ps rms
10
10
3
500
±1
10
±5
20
3.1
3.1
0.16
9
−10
300
375
Rev. E | Page 6 of 52
±5
20
11
3
±1
2
350
400
0.16
9
+10
−10
300
375
11
3
±1
2
350
400
4.0
+10
4.0
Unit
V
V
dBm
ns
%
ns
MHz
MHz
ps rms
AD9852
Parameter
PARALLEL I/O TIMING CHARACTERISTICS
tASU (Address Setup Time to WR Signal Active)
tADHW (Address Hold Time to WR Signal Inactive)
tDSU (Data Setup Time to WR Signal Inactive)
tDHD (Data Hold Time to WR Signal Inactive)
tWRLOW (WR Signal Minimum Low Time)
tWRHIGH (WR Signal Minimum High Time)
tWR (Minimum WR Time)
tADV (Address to Data Valid Time)
tADHR (Address Hold Time to RD Signal Inactive)
tRDLOV (RD Low to Output Valid)
tRDHOZ (RD High to Data Three-State)
SERIAL I/O TIMING CHARACTERISTICS
tPRE (CS Setup Time)
tSCLK (Period of Serial Data Clock)
tDSU (Serial Data Setup Time)
tSCLKPWH (Serial Data Clock Pulse Width High)
tSCLKPWL (Serial Data Clock Pulse Width Low)
tDHLD (Serial Data Hold Time)
tDV (Data Valid Time)
CMOS LOGIC INPUTS 9
Logic 1 Voltage
Logic 0 Voltage
Logic 1 Current
Logic 0 Current
Input Capacitance
POWER SUPPLY 10
VS Current 11
VS Current 12
VS Current 13
PDISS 11
PDISS 12
PDISS 13
PDISS Power-Down Mode
Temp
Test
Level
AD9852ASVZ
Min
Typ
Max
AD9852ASTZ
Min
Typ
Max
Full
Full
Full
Full
Full
Full
Full
Full
Full
Full
Full
IV
IV
IV
IV
IV
IV
IV
V
IV
IV
IV
8.0
0
3.0
0
2.5
7
10.5
15
5
8.0
0
3.0
0
2.5
7
10.5
15
5
Full
Full
Full
Full
Full
Full
Full
IV
IV
IV
IV
IV
IV
V
30
100
30
40
40
0
25°C
25°C
25°C
25°C
25°C
I
I
IV
IV
V
2.2
25°C
25°C
25°C
25°C
25°C
25°C
25°C
I
I
I
I
I
I
I
7.5
1.6
1.8
15
7.5
1.6
1.8
15
15
10
15
10
30
100
30
40
40
0
30
1
2.2
3
815
640
585
2.70
2.12
1.93
1
0.8
± 12
± 12
V
V
μA
μA
pF
660
520
475
2.39
1.81
1.65
50
mA
mA
mA
W
W
W
mW
3
922
725
660
3.20
2.52
2.29
50
585
465
425
1.93
1.53
1.40
1
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
30
0.8
±5
±5
Unit
The reference clock inputs are configured to accept a 1 V p-p (typical) dc offset square or sine waves centered at one-half the applied VDD or a 3 V TTL-level pulse input.
An internal 400 mV p-p differential voltage swing equates to 200 mV p-p applied to both REFCLK input pins.
3
Pipeline delays of each individual block are fixed; however, if the first eight MSBs of a tuning word are all 0s, the delay appears longer. This is due to insufficient phase
accumulation per a system clock period to produce enough LSB amplitude to the D/A converter.
4
If a feature such as inverse sinc, which has 16 pipeline delays, can be bypassed, the total delay is reduced by that amount.
5
The I/O UD CLK transfers data from the I/O port buffers to the programming registers. This transfer is measured in system clocks.
6
A change in duty cycle from 1 MHz to 100 MHz with 1 V p-p sine wave input and 0.5 V threshold.
7
Represents the comparator’s inherent cycle-to-cycle jitter contribution. The input signal is a 1 V, 40 MHz square wave, and the measurement device is a Wavecrest DTS-2075.
8
Comparator input originates from analog output section via external 7-pole elliptic low-pass filter. Single-ended input, 0.5 V p-p. Comparator output terminated in 50 Ω.
9
Avoid overdriving digital inputs. (Refer to equivalent circuits in Figure 3.)
10
If all device functions are enabled, it is not recommended to simultaneously operate the device at the maximum ambient temperature of 85°C and at the maximum
internal clock frequency. This configuration may result in violating the maximum die junction temperature of 150°C. Refer to the Power Dissipation and Thermal
Considerations section for derating and thermal management information.
11
All functions engaged.
12
All functions except inverse sinc engaged.
13
All functions except inverse sinc and digital multipliers engaged.
2
Rev. E | Page 7 of 52
AD9852
ABSOLUTE MAXIMUM RATINGS
Table 2.
Parameter
Maximum Junction Temperature
VS
Digital Inputs
Digital Output Current
Storage Temperature
Operating Temperature
Lead Temperature (Soldering, 10 sec)
Maximum Clock Frequency (ASVZ)
Maximum Clock Frequency (ASTZ)
Rating
150°C
4V
−0.7 V to +VS
5 mA
−65°C to +150°C
−40°C to +85°C
300°C
300 MHz
200 MHz
To determine the junction temperature on the application PCB
use the following equation:
TJ = Tcase + (ΨJT × PD)
where:
TJ is the junction temperature expressed in degrees Celsius.
Tcase is the case temperature expressed in degrees Celsius, as
measured by the user at the top center of the package.
ΨJT = 0.3°C/W.
PD is the power dissipation (PD); see the Power Dissipation and
Thermal Considerations section for the method to calculate PD.
EXPLANATION OF TEST LEVELS
Stresses above those listed under Absolute Maximum Ratings
may cause permanent damage to the device. This is a stress
rating only; functional operation of the device at these or any
other conditions above those indicated in the operational
section of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect
device reliability.
THERMAL RESISTANCE
Table 4.
Test Level
I
III
IV
V
VI
The heat sink of the AD9852ASVZ 80-lead TQFP package must
be soldered to the PCB.
ESD CAUTION
Table 3.
Thermal Characteristic
θJA (0 m/sec airflow)1, 2, 3
θJMA (1.0 m/sec airflow)2, 3, 4, 5
θJMA (2.5 m/sec airflow)2, 3, 4, 5
ΨJT1, 2
θJC6, 7
Description
100% production tested.
Sample tested only.
Parameter is guaranteed by design and
characterization testing.
Parameter is a typical value only.
Devices are 100% production tested at 25°C and
guaranteed by design and characterization testing
for industrial operating temperature range.
TQFP
16.2°C/W
13.7°C/W
12.8°C/W
0.3°C/W
2.0°C/W
LQFP
38°C/W
1
Per JEDEC JESD51-2 (heat sink soldered to PCB).
2S2P JEDEC test board.
3
Values of θJA are provided for package comparison and PCB design
considerations.
4
Per JEDEC JESD51-6 (heat sink soldered to PCB).
5
Airflow increases heat dissipation, effectively reducing θJA. Furthermore, the
more metal that is directly in contact with the package leads from metal
traces through holes, ground, and power planes, the more θJA is reduced.
6
Per MIL-Std 883, Method 1012.1.
7
Values of θJC are provided for package comparison and PCB design
considerations when an external heat sink is required.
2
Rev. E | Page 8 of 52
AD9852
PLL FILTER
AGND
NC
DIFF CLK ENABLE
AVDD
AGND
AGND
REFCLK
REFCLK
S/P SELECT
MASTER RESET
DGND
DVDD
DVDD
DGND
DGND
DGND
DGND
DVDD
DVDD
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61
D7 1
60
AVDD
59
AGND
D5 3
58
NC
D4 4
57
NC
D3 5
56
DAC RSET
D2 6
55
DACBP
D1 7
54
AVDD
53
AGND
52
IOUT2
DVDD 10
51
IOUT2
DGND 11
50
AVDD
DGND 12
49
IOUT1
NC 13
48
IOUT1
A5 14
47
AGND
A4 15
46
AGND
A3 16
45
AGND
A2/IO RESET 17
44
AVDD
A1/SDO 18
43
VINN
A0/SDIO 19
42
VINP
I/O UD CLK 20
41
AGND
PIN 1
D6 2
AD9852
D0 8
TOP VIEW
(Not to Scale)
DVDD 9
00634-002
AGND
AGND
AVDD
AVDD
VOUT
NC
AGND
AGND
AVDD
AVDD
OSK
FSK/BPSK/HOLD
DGND
DGND
DGND
DVDD
DVDD
DVDD
RD/CS
WR/SCLK
21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40
NC = NO CONNECT
Figure 2. Pin Configuration
Table 5. Pin Function Descriptions
Pin Number
1 to 8
9, 10, 23, 24, 25,
73, 74, 79, 80
11, 12, 26, 27, 28,
72, 75 to 78
13, 35, 57, 58, 63
14 to 16
Mnemonic
D7 to D0
DVDD
NC
A5 to A3
17
A2/IO RESET
18
A1/SDO
DGND
Description
8-Bit Bidirectional Parallel Programming Data Inputs. Used only in parallel programming mode.
Connections for the Digital Circuitry Supply Voltage. Nominally 3.3 V more positive than AGND
and DGND.
Connections for Digital Circuitry Ground Return. Same potential as AGND.
No Internal Connection.
Parallel Address Inputs for Program Registers (Part of 6-Bit Parallel Address Inputs for Program
Register, A5:A0). Used only in parallel programming mode.
Parallel Address Input for Program Registers (Part of 6-Bit Parallel Address Inputs for Program
Register, A5:A0)/IO Reset. A2 is used only in parallel programming mode. IO RESET is used when
the serial programming mode is selected, allowing an IO RESET of the serial communication bus
that is unresponsive due to improper programming protocol. Resetting the serial bus in this
manner does not affect previous programming, nor does it invoke the default programming
values seen in Table 9. Active high.
Parallel Address Input for Program Registers (Part of 6-Bit Parallel Address Inputs for Program
Register, A5:A0)/Unidirectional Serial Data Output. A1 is used only in parallel programming
mode. SDO is used in 3-wire serial communication mode when the serial programming mode is
selected.
Rev. E | Page 9 of 52
AD9852
Pin Number
19
Mnemonic
A0/SDIO
20
I/O UD CLK
21
WR/SCLK
22
RD/CS
29
FSK/BPSK/HOLD
30
OSK
31, 32, 37, 38, 44, 50, 54,
60, 65
33, 34, 39, 40, 41, 45, 46,
47, 53, 59, 62, 66, 67
36
AVDD
42
43
48
49
51
52
55
VINP
VINN
IOUT1
IOUT1
IOUT2
IOUT2
DACBP
56
DAC RSET
61
PLL FILTER
64
DIFF CLK ENABLE
68
REFCLK
69
REFCLK
70
S/P SELECT
71
MASTER RESET
AGND
VOUT
Description
Parallel Address Input for Program Registers (Part of 6-Bit Parallel Address Inputs for Program
Register, A5:A0)/Bidirectional Serial Data Input/Output. A0 is used only in parallel programming
mode. SDIO is used in 2-wire serial communication mode.
Bidirectional I/O Update Clock. Direction is selected in control register. If selected as an input, a
rising edge transfers the contents of the I/O port buffers to the programming registers. If I/O UD
CLK is selected as an output (default), an output pulse (low to high) with a duration of eight
system clock cycles indicates that an internal frequency update has occurred.
Write Parallel Data to I/O Port Buffers. Shared function with SCLK. Serial clock signal associated
with the serial programming bus. Data is registered on the rising edge. This pin is shared with
WR when the parallel mode is selected. The mode is dependent on Pin 70 (S/P SELECT).
Read Parallel Data from Programming Registers. Shared function with CS. Chip select signal
associated with the serial programming bus. Active low. This pin is shared with RD when the
parallel mode is selected.
Multifunction Pin. Functions according to the mode of operation selected in the programming
control register. If in the FSK mode, logic low selects F1 and logic high selects F2. If in the BPSK
mode, logic low selects Phase 1 and logic high selects Phase 2. In chirp mode, logic high
engages the hold function, causing the frequency accumulator to halt at its current location. To
resume or commence chirp, logic low is asserted.
Output Shaped Keying. Must first be selected in the programming control register to function.
A logic high causes the cosine DAC outputs to ramp up from zero-scale to full-scale amplitude
at a preprogrammed rate. Logic low causes the full-scale output to ramp down to zero scale at
the preprogrammed rate.
Connections for the Analog Circuitry Supply Voltage. Nominally 3.3 V more positive than AGND
and DGND.
Connections for Analog Circuitry Ground Return. Same potential as DGND.
Noninverted Output of the Internal High Speed Comparator. Designed to drive 10 dBm to 50 Ω
loads as well as standard CMOS logic levels.
Voltage Input Positive. The noninverting input of the internal high speed comparator.
Voltage Input Negative. The inverting input of the internal high speed comparator.
Unipolar Current Output of the Cosine DAC (refer to Figure 3).
Complementary Unipolar Current Output of the Cosine DAC.
Complementary Unipolar Current Output of the Control DAC.
Unipolar Current Output of the Control DAC.
Common Bypass Capacitor Connection for Both DACs. A 0.01 μF chip capacitor from this pin to
AVDD improves harmonic distortion and SFDR slightly. No connect is permissible, but results in
a slight degradation in SFDR.
Common Connection for Both DACs. Used to set the full-scale output current. RSET = 39.9/ IOUT.
Normal RSET range is from 8 kΩ (5 mA) to 2 kΩ (20 mA).
Connection for the External Zero-Compensation Network of the REFCLK Multiplier’s PLL Loop
Filter. The zero-compensation network consists of a 1.3 kΩ resistor in series with a 0.01 μF
capacitor. The other side of the network should be connected to AVDD as close as possible to
Pin 60. For optimum phase noise performance, the REFCLK multiplier can be bypassed by
setting the bypass PLL bit in Control Register 1E hex.
Differential REFCLK Enable. A high level of this pin enables the differential clock inputs, REFCLK
and REFCLK (Pin 69 and Pin 68, respectively).
Complementary (180° Out of Phase) Differential Clock Signal. User should tie this pin high or
low when single-ended clock mode is selected. Same signal levels as REFCLK.
Single-Ended (CMOS Logic Levels Required) Reference Clock Input or One of Two Differential
Clock Signals. In differential reference clock mode, both inputs can be CMOS logic levels or have
greater than 400 mV p-p square or sine waves centered about 1.6 V dc.
Selects between serial programming mode (logic low) and parallel programming mode
(logic high).
Initializes the serial/parallel programming bus to prepare for user programming, and sets
programming registers to a do-nothing state defined by the default values listed in Table 9.
Active on logic high. Asserting this pin is essential for proper operation upon power-up.
Rev. E | Page 10 of 52
AD9852
DVDD
AVDD
AVDD
IOUT IOUTB
MUST TERMINATE OUTPUTS
FOR CURRENT FLOW. DO
NOT EXCEED THE OUTPUT
VOLTAGE COMPLIANCE RATING.
A. DAC Outputs
COMPARATOR
OUT
VINP/
VINN
B. Comparator Output
AVOID OVERDRIVING
DIGITAL INPUTS. FORWARD
BIASING ESD DIODES MAY
COUPLE DIGITAL NOISE
ONTO POWER PINS.
C. Comparator Input
Figure 3. Equivalent Input and Output Circuits
Rev. E | Page 11 of 52
DIGITAL
IN
D. Digital Inputs
00634-003
AVDD
AD9852
TYPICAL PERFORMANCE CHARACTERISTICS
0
–10
–10
–20
–20
–30
–30
–40
–40
–50
–50
–60
–60
–70
–70
–80
–80
–90
–90
15MHz/
STOP 150MHz
–100
START 0Hz
Figure 4. Wideband SFDR, 19.1 MHz
–10
–10
–20
–20
–30
–30
–40
–40
–50
–50
–60
–60
–70
–70
–80
–80
–90
–90
15MHz/
STOP 150MHz
00634-005
0
START 0Hz
–100
START 0Hz
Figure 5. Wideband SFDR, 39.1 MHz
0
–10
–20
–20
–30
–30
–40
–40
–50
–50
–60
–60
–70
–70
–80
–80
–90
–90
15MHz/
STOP 150MHz
00634-006
0
START 0Hz
15MHz/
STOP 150MHz
Figure 8. Wideband SFDR, 99.1 MHz
–10
–100
STOP 150MHz
Figure 7. Wideband SFDR, 79.1 MHz
0
–100
15MHz/
00634-008
START 0Hz
–100
START 0Hz
Figure 6. Wideband SFDR, 59.1 MHz
15MHz/
STOP 150MHz
Figure 9. Wideband SFDR, 119.1 MHz
Rev. E | Page 12 of 52
00634-009
–100
00634-004
0
00634-007
Figure 4 to Figure 9 indicate the wideband harmonic distortion performance of the AD9852 from 19.1 MHz to 119.1 MHz fundamental
output, reference clock = 30 MHz, REFCLK multiplier = 10×. Each graph is plotted from 0 MHz to 150 MHz (Nyquist).
AD9852
0
–10
–20
–20
–30
–30
–40
–40
–50
–50
–60
–60
–70
–70
–80
–80
–90
–90
CENTER 39.1MHz
100kHz/
SPAN 1MHz
–100
CENTER 39.1MHz
Figure 10. Narrow-Band SFDR, 39.1 MHz, 1 MHz BW,
300 MHz REFCLK with REFCLK Multiplier Bypassed
0
–10
–20
–20
–30
–30
–40
–40
–50
–50
–60
–60
–70
–70
–80
–80
–90
–90
5kHz/
SPAN 50kHz
00634-011
0
CENTER 39.1MHz
SPAN 1MHz
Figure 13. Narrow-Band SFDR, 39.1 MHz, 1 MHz BW,
30 MHz REFCLK with REFCLK Multiplier = 10×
–10
–100
100kHz/
–100
CENTER 39.1MHz
Figure 11. Narrow-Band SFDR, 39.1 MHz, 50 kHz BW,
300 MHz REFCLK with REFCLK Multiplier Bypassed
5kHz/
SPAN 50kHz
00634-014
–100
00634-010
0
–10
00634-013
Figure 10 to Figure 15 show the trade-off in elevated noise floor, increased phase noise (PN), and discrete spurious energy when the
internal REFCLK multiplier circuit is engaged. Plots with wide (1 MHz) and narrow (50 kHz) spans are shown. Compare the noise floor of
Figure 11 and Figure 12 with that of Figure 14 and Figure 15. The improvement seen in Figure 11 and Figure 12 is a direct result of sampling
the fundamental at a higher rate. Sampling at a higher rate spreads the quantization noise of the DAC over a wider bandwidth, which
effectively lowers the noise floor.
Figure 14. Narrow-Band SFDR, 39.1 MHz, 50 kHz BW,
30 MHz REFCLK with REFCLK Multiplier = 10×
0
0
–10
–10
–20
–20
–30
–30
–40
–40
–50
–50
–60
–60
–70
–70
–80
–80
–90
5kHz/
SPAN 50kHz
–100
CENTER 39.1MHz
Figure 12. Narrow-Band SFDR, 39.1 MHz, 50 kHz BW,
100 MHz REFCLK with REFCLK Multiplier Bypassed
5kHz/
SPAN 50kHz
Figure 15. Narrow-Band SFDR, 39.1 MHz, 50 kHz BW,
10 MHz REFCLK with REFCLK Multiplier = 10×
Rev. E | Page 13 of 52
00634-015
CENTER 39.1MHz
00634-012
–90
–100
AD9852
Figure 18 and Figure 19 show the residual phase noise performance of the AD9852 when operating with a 300 MHz reference clock with
the REFCLK multiplier bypassed vs. a 30 MHz reference clock with the REFCLK multiplier enabled at 10×.
0
–90
–10
–100
–30
–40
–50
–60
–70
–80
AOUT = 80MHz
–110
–120
–130
–140
–150
AOUT = 5MHz
–100
50kHz/
CENTER 112.469MHz
SPAN 500kHz
00634-016
–90
–160
10
Figure 16. A Slight Change in Tuning Word Yields Dramatically Better Results;
112.469 MHz with All Spurs Shifted Out-of-Band, 300 MHz REFCLK
100
1k
10k
FREQUENCY (Hz)
100k
1M
00634-019
PHASE NOISE (dBc/Hz)
–20
Figure 19. Residual Phase Noise,
30 MHz REFCLK with REFCLK Multiplier = 10×
55
0
–10
54
–20
53
SFDR (dBc)
–30
–40
–50
–60
52
51
50
–70
–80
49
5kHz/
CENTER 39.1MHz
SPAN 50kHz
48
0
Figure 17. Narrow-Band SFDR, 39.1 MHz, 50 kHz BW,
200 MHz REFCLK with REFCLK Multiplier Bypassed
25
SUPPLY CURRENT (mA)
615
–120
–130
AOUT = 80MHz
–140
–150
610
605
600
595
100
1k
10k
FREQUENCY (Hz)
100k
Figure 18. Residual Phase Noise,
300 MHz REFCLK with REFCLK Multiplier Bypassed
1M
590
0
20
40
60
80
100
FREQUENCY (MHz)
120
140
00634-021
AOUT = 5MHz
00634-018
PHASE NOISE (dBc/Hz)
20
620
–110
–170
10
10
15
DAC CURRENT (mA)
Figure 20. SFDR vs. DAC Current, 59.1 AOUT,
300 MHz REFCLK with REFCLK Multiplier Bypassed
–100
–160
5
00634-020
–100
00634-017
–90
Figure 21. Supply Current vs. Output Frequency (Variation Is Minimal,
Expressed as a Percentage, and Heavily Dependent on Tuning Word)
Rev. E | Page 14 of 52
AD9852
1200
AMPLITUDE (mV p-p)
1000
RISE TIME
1.04ns
JITTER
[10.6ps RMS]
800
600
400
MINIMUM COMPARATOR
INPUT DRIVE
VCM = 0.5V
200
232mV/DIV
+33ps
50Ω INPUT
0
0
Figure 22. Typical Comparator Output Jitter, 40 MHz AOUT,
300 MHz REFCLK with REFCLK Multiplier Bypassed
M 500ps CH1
980mV
00634-023
C1 FALL
1.286ns
500mVΩ
200
300
FREQUENCY (MHz)
400
Figure 24. Comparator Toggle Voltage Requirement
REF1 RISE
1.174ns
CH1
100
Figure 23. Comparator Rise/Fall Times
Rev. E | Page 15 of 52
500
00634-024
500ps/DIV
0ps
00634-022
–33ps
AD9852
TYPICAL APPLICATIONS
RF/IF
INPUT
LOW-PASS
FILTER
AD9852
COS
00634-025
REFCLK
BASEBAND
Figure 25. Synthesized LO Application for the AD9852
8
I
I/Q MIXER
AND
LOW-PASS
FILTER
DUAL
8-/10-BIT
ADC
Q
Rx BASEBAND
DIGITAL
DATA OUT
DIGITAL
DEMODULATOR
8
VCA
AGC
ADC CLOCK FREQUENCY
LOCKED TO Tx CHIP/
SYMBOL/PN RATE
ADC ENCODE
REFERENCE
CLOCK
48
CHIP/SYMBOL/PN
RATE DATA
00634-026
AD9852
CLOCK
GENERATOR
Figure 26. Chip Rate Generator in Spread Spectrum Application
BAND-PASS
FILTER
AD9852
AMPLIFIER
IOUT
50Ω
50Ω
AD9852
SPECTRUM
FINAL OUTPUT
SPECTRUM
FUNDAMENTAL
FC + FO
IMAGE
FC + FO
IMAGE
FCLK
BAND-PASS
FILTER
00634-027
FC – FO
IMAGE
Figure 27. Using an Aliased Image to Generate a High Frequency
REFERENCE
CLOCK
PHASE
COMPARATOR
LOOP
FILTER
RF FREQUENCY
OUT
VCO
FILTER
AD9852
DAC OUT
REFCLK IN
DDS
TUNING
WORD
PROGRAMMABLE
DIVIDE-BY-N FUNCTION
(WHERE N = 248/TUNING WORD)
Figure 28. Programmable Fractional Divide-by-N Synthesizer
Rev. E | Page 16 of 52
00634-028
Rx
RF IN
AD9852
REFERENCE
CLOCK
DDS
FILTER
PHASE
LOOP
COMPARATOR FILTER
TUNING
WORD
RF FREQUENCY
OUT
VCO
00634-029
AD9852
DIVIDE-BY-N
Figure 29. Agile High Frequency Synthesizer
DIFFERENTIAL
TRANSFORMER-COUPLED
OUTPUT
IOUT
FILTER
50Ω
AD9852
DDS
IOUT
50Ω
1:1 TRANSFORMER
THAT IS, Mini-Circuits® T1-1T
00634-030
REFERENCE
CLOCK
Figure 30. Differential Output Connection for Reduction of Common-Mode Signals
AD9852
8-BIT PARALLEL OR
SERIAL PROGRAMMING
DATA AND CONTROL
SIGNALS
CONTROL
DAC
LOW-PASS
FILTER
1
2
LOW-PASS
FILTER
300MHz MAX DIRECT
MODE OR 15MHz TO 75MHz
MAX IN THE 4× TO 20× CLOCK
MULTIPLIER MODE
REFERENCE
CLOCK
2kΩ
NOTES
1. IOUT = APPROXIMATELY 20mA MAX WHEN RSET = 2kΩ.
2. SWITCH POSITION 1 PROVIDES COMPLEMENTARY
SINUSOIDAL SIGNALS TO THE COMPARATOR TO
PRODUCE A FIXED 50% DUTY CYCLE FROM THE
COMPARATOR.
3. SWITCH POSITION 2 PROVIDES A USER-PROGRAMMABLE
DC THRESHOLD VOLTAGE TO ALLOW SETTING OF THE
COMPARATOR DUTY CYCLE.
RSET
CMOS LOGIC CLOCK OUT
Figure 31. Frequency Agile Clock Generator Applications for the AD9852
Rev. E | Page 17 of 52
00634-031
μPROCESSOR/
CONTROLLER
FPGA, ETC.
COSINE
DAC
AD9852
MODES OF OPERATION
There are five programmable modes of operation of the AD9852.
Selecting a mode requires that three bits in the control register
(Parallel Address 1F hex) be programmed as shown in Table 6.
As with all Analog Devices DDS devices, the value of the frequency
tuning word is determined using the following equation:
Table 6. Mode Selection Table
where:
N is the phase accumulator resolution (48 bits in this instance).
Desired Output Frequency is expressed in hertz.
FTW (frequency tuning word) is a decimal number.
Mode 2
0
0
0
0
1
Mode 1
0
0
1
1
0
Mode 0
0
1
0
1
0
Result
Single tone
FSK
Ramped FSK
Chirp
BPSK
FTW = (Desired Output Frequency × 2N)/SYSCLK
After a decimal number has been calculated, it must be rounded
to an integer and then converted to binary format—a series of
48 binary-weighted 1s and 0s. The fundamental sine wave DAC
output frequency range is from dc to one-half SYSCLK.
In each mode, engaging certain functions may be prohibited.
Table 7 lists some important functions and their availability for
each mode.
SINGLE TONE (MODE 000)
When the MASTER RESET pin is asserted, single-tone mode
becomes the default. The user can also access this mode by
programming it into the control register. The phase accumulator,
responsible for generating an output frequency, is presented with
a 48-bit value from the Frequency Tuning Word 1 registers with
default values of 0. Default values from the remaining applicable
registers further define the single-tone output signal qualities.
The default values after a master reset configures the device
with an output signal of 0 Hz and zero phase. Upon power-up
and reset, the output from both DACs is a dc value equal to the
midscale output current. This is the default mode amplitude setting
of 0. Refer to the On/Off Output Shaped Keying (OSK) section
for further explanation of the output amplitude control. It is
necessary to program all or some of the 28 program registers to
produce a user-defined output signal. Figure 32 shows the
transition from the default condition (0 Hz) to a user-defined
output frequency (F1).
Changes in frequency are phase continuous; therefore, the first
sampled phase value of the new frequency is referenced from the
time of the last sampled phase value of the previous frequency.
The 14-bit phase register adjusts the cosine DAC’s output phase.
The single-tone mode allows the user to control the following
signal qualities:
•
•
Output frequency to 48-bit accuracy
Output amplitude to 12-bit accuracy
•
Fixed, user-defined amplitude control
•
Variable, programmable amplitude control
•
Automatic, programmable, single-pin-controlled
on/off output shaped keying
Output phase to 14-bit accuracy
•
Furthermore, all of these qualities can be changed or modulated
via the 8-bit parallel programming port at a 100 MHz parallel
byte rate or at a 10 MHz serial rate. Incorporating this attribute
permits FM, AM, PM, FSK, PSK, and ASK operation in the
single-tone mode.
FREQUENCY
F1
0
MODE
TW1
000 (DEFAULT)
000 (SINGLE TONE)
0
F1
00634-032
MASTER RESET
I/O UD CLK
Figure 32. Default State to User-Defined Output Transition
Rev. E | Page 18 of 52
AD9852
Table 7. Function Availability vs. Mode of Operation
Function
Phase Adjust 1
Phase Adjust 2
Single-Pin FSK/BPSK or HOLD
Single-Pin Output Shaped Keying
Phase Offset or Modulation
Amplitude Control or Modulation
Inverse Sinc Filter
Frequency Tuning Word 1
Frequency Tuning Word 2
Automatic Frequency Sweep
Single-Tone Mode
●
FSK Mode
●
Ramped FSK Mode
●
Chirp Mode
●
●
●
●
●
●
●
●
●
●
●
●
●
●
●
●
●
●
●
●
●
●
●
●
●
●
●
BPSK Mode
●
●
●
●
●
●
●
●
UNRAMPED FSK (MODE 001)
RAMPED FSK (MODE 010)
When this mode is selected, the output frequency of the DDS is
a function of the values loaded into Frequency Tuning Word
Register 1 and Frequency Tuning Word Register 2 and the logic
level of Pin 29 (FSK/BPSK/HOLD). A logic low on Pin 29
chooses F1 (Frequency Tuning Word 1, Parallel Address 4 hex
to Parallel Address 9 hex), and a logic high chooses F2
(Frequency Tuning Word 2, Parallel Register Address A hex to
Parallel Register Address F hex). Changes in frequency are
phase continuous and are internally coincident with the FSK
data pin (Pin 29); however, there is deterministic pipeline delay
between the FSK data signal and the DAC output (see Table 1).
In this method of FSK, changes from F1 to F2 are not
instantaneous, but are accomplished in a frequency sweep or
ramped fashion. The ramped notation implies the sweep is
linear. Although linear sweeping, or frequency ramping, is
easily and automatically accomplished, it is only one of many
possibilities. Other frequency transition schemes can be
implemented by changing the ramp rate and ramp step size at
any time during operation.
The unramped FSK mode (see Figure 33) is representative
of traditional FSK, radio teletype (RTTY), or teletype (TTY)
transmission of digital data. FSK is a very reliable means of
digital communication; however, it makes inefficient use of
the bandwidth in the RF spectrum. Ramped FSK, shown in
Figure 34, is a method of conserving the bandwidth.
Frequency ramping, whether linear or nonlinear, necessitates
that many intermediate frequencies between F1 and F2 are
output in addition to the primary F1 and F2 frequencies.
Figure 34 and Figure 35 graphically depict the frequency vs.
time characteristics of a linear ramped FSK signal.
In ramped FSK mode, the delta frequency word (DFW) is
required to be programmed as a positive twos complement
value. Another requirement is that the lowest frequency (F1) be
programmed in the Frequency Tuning Word 1 registers.
F2
FREQUENCY
F1
0
000 (DEFAULT)
001 (FSK NO RAMP)
TW1
0
F1
TW2
0
F2
MODE
00634-033
I/O UD CLK
FSK DATA (PIN 29)
Figure 33. Unramped (Traditional) FSK Mode
Rev. E | Page 19 of 52
AD9852
F2
FREQUENCY
F1
0
000 (DEFAULT)
010 (RAMPED FSK)
TW1
0
F1
TW2
0
F2
MODE
REQUIRES A POSITIVE TWOS COMPLEMENT VALUE
DFW
RAMP RATE
00634-034
I/O UD CLK
FSK DATA (PIN 29)
Figure 34. Ramped FSK Mode (Start at F1)
F2
FREQUENCY
F1
0
MODE
000 (DEFAULT)
010 (RAMPED FSK)
TW1
0
F1
TW2
0
F2
00634-035
I/O UD CLK
FSK DATA (PIN 29)
Figure 35. Ramped FSK Mode (Start at F2)
The purpose of ramped FSK is to provide better bandwidth
containment than can be achieved using traditional FSK. In
ramped FSK, the instantaneous frequency changes of traditional
FSK are replaced with more gradual, user-defined frequency
changes. The dwell time at F1 and F2 can be equal to or much
greater than the time spent at each intermediate frequency. The
user controls the dwell time at F1 and F2, the number of
intermediate frequencies, and the time spent at each frequency.
Unlike unramped FSK, ramped FSK requires the lowest
frequency to be loaded into the F1 registers and the highest
frequency to be loaded into the F2 registers.
Several registers must be programmed to instruct the DDS
regarding the resolution of intermediate frequency steps (48 bits)
and the time spent at each step (20 bits). Furthermore, the CLR
ACC1 bit in the control register should be toggled (low-high-low)
prior to operation to ensure that the frequency accumulator is
starting from an all 0s output condition.
For piecewise, nonlinear frequency transitions, it is necessary
to reprogram the registers while the frequency transition is in
progress to affect the desired response.
Parallel Register Address 1A hex to Parallel Register Address 1C
hex comprise the 20-bit ramp rate clock registers. This is a
countdown counter that outputs a single pulse whenever the
count reaches 0. The counter is activated any time a logic level
change occurs on the FSK input (Pin 29). This counter is run at
the system clock rate, 300 MHz maximum. The time period
between each output pulse is
(N + 1) × System Clock Period
where N is the 20-bit ramp rate clock value programmed by
the user.
The allowable range of N is from 1 to (220 − 1). The output of
this counter clocks the 48-bit frequency accumulator shown in
Rev. E | Page 20 of 52
AD9852
Figure 36. The ramp rate clock determines the amount of time
spent at each intermediate frequency between F1 and F2.
Parallel Register Address 10 hex to Parallel Register Address 15 hex
comprise the 48-bit, twos complement delta frequency word
registers. This 48-bit word is accumulated (added to the
accumulator’s output) every time it receives a clock pulse from
the ramp rate counter. The output of this accumulator is added
to or subtracted from the F1 or F2 frequency word, which is
then fed into the input of the 48-bit phase accumulator that
forms the numerical phase steps for the sine and cosine wave
outputs. In this fashion, the output frequency is ramped up and
down in frequency according to the logic state of Pin 29. This
ramping rate is a function of the 20-bit ramp rate clock. When
the destination frequency is achieved, the ramp rate clock is
stopped, halting the frequency accumulation process.
PHASE
ACCUMULATOR
ADDER
FREQUENCY
ACCUMULATOR
FSK (PIN 29)
FREQUENCY
TUNING
WORD 1
FREQUENCY
TUNING
WORD 2
20-BIT
RAMP RATE
CLOCK
SYSTEM
CLOCK
Figure 36. Block Diagram of Ramped FSK Function
F2
FREQUENCY
F1
Generally speaking, the delta frequency word is a much smaller
value compared with the value of the F1 or F2 tuning word. For
example, if F1 and F2 are 1 kHz apart at 13 MHz, the delta
frequency word might be only 25 Hz.
Figure 39 shows that premature toggling causes the ramp to
immediately reverse itself and proceed at the same rate and
resolution until the original frequency is reached.
INSTANTANEOUS
PHASE OUT
48-BIT DELTA
FREQUENCY
WORD (TWOS
COMPLEMENT)
00634-036
The counter stops automatically when the destination
frequency is achieved. The dwell time spent at F1 and F2 is
determined by the duration that the FSK input (Pin 29) is held
high or low after the destination frequency has been reached.
0
MODE
010 (RAMPED FSK)
TW1
F1
TW2
F2
FSK DATA
The control register contains a triangle bit at Parallel Register
Address 1F hex. Setting this bit high in Mode 010 causes an
automatic ramp-up and ramp-down between F1 and F2 to
occur without toggling Pin 29 (shown in Figure 37). In fact, the
logic state of Pin 29 has no effect once the triangle bit is set
high. This function uses the ramp rate clock time period and
the step size of the delta frequency word to form a continuously
sweeping linear ramp from F1 to F2 and back to F1 with equal
dwell times at every frequency. Use this function to automatically
sweep between any two frequencies from dc to Nyquist.
00634-037
TRIANGLE BIT
I/O UD CLK
Figure 37. Effect of Triangle Bit in Ramped FSK Mode
F2
FREQUENCY
F1
0
MODE 000 (DEFAULT)
010 (RAMPED FSK)
TW1
0
F1
TW2
0
F2
FSK DATA
TRIANGLE BIT
Figure 38. Automatic Linear Ramping Using the Triangle Bit
Rev. E | Page 21 of 52
00634-038
In the ramped FSK mode with the triangle bit set high, an
automatic frequency sweep begins at either F1 or F2, according
to the logic level on Pin 29 (FSK input pin) when the triangle
bit’s rising edge occurs, as shown in Figure 38. If the FSK data
bit is high instead of low, F2, rather than F1, is chosen as the
start frequency.
AD9852
Additional flexibility in the ramped FSK mode is provided by
the AD9852’s ability to respond to changes in the 48-bit delta
frequency word and/or the 20-bit ramp rate counter at any time
during the ramping from F1 to F2 or vice versa. To create these
nonlinear frequency changes, it is necessary to combine several
linear ramps with different slopes in a piecewise fashion. This is
done by programming and executing a linear ramp at a rate or
slope and then altering the slope (by changing the ramp rate
clock or delta frequency word, or both). Changes in slope can
be made as often as needed before the destination frequency has
been reached to form the desired nonlinear frequency sweep
response. These piecewise changes can be precisely timed using
the 32-bit internal update clock (see the Internal and External
Update Clock section).
Nonlinear ramped FSK has the appearance of the chirp function
shown in Figure 41. The major difference between a ramped
FSK function and a chirp function is that FSK is limited to
operation between F1 and F2, whereas chirp operation has no
F2 limit frequency.
Two additional control bits (CLR ACC1 and CLR ACC2) are
available in the ramped FSK mode that allow more options. Setting
CLR ACC1 (Register Address 1F hex) high clears the 48-bit
frequency accumulator (ACC1) output with a retriggerable
one-shot pulse of one system clock duration. If the CLR ACC1
bit is left high, a one-shot pulse is delivered on the rising edge of
every update clock. The effect is to interrupt the current ramp,
reset the frequency to the start point (F1 or F2), and then
continue to ramp up (or down) at the previous rate. This occurs
even when a static F1 or F2 destination frequency has been
achieved.
Alternatively, the CLR ACC2 control bit (Register Address 1F hex)
can be used to clear both the frequency accumulator (ACC1)
and the phase accumulator (ACC2). When this bit is set high,
the output of the phase accumulator results in 0 Hz output from
the DDS. As long as this bit is set high, the frequency and phase
accumulators are cleared, resulting in 0 Hz output. To return to
previous DDS operation, CLR ACC2 must be set to logic low.
CHIRP (MODE 011)
Chirp mode is also known as pulsed FM. Most chirp systems
use a linear FM sweep pattern, but the AD9852 can also support
nonlinear patterns. In radar applications, use of chirp or pulsed
FM allows operators to significantly reduce the output power
needed to achieve the same result a single frequency radar
system produces. Figure 41 represents a very low resolution
nonlinear chirp that demonstrates the different slopes created
by varying the time steps (ramp rate) and frequency steps (delta
frequency word).
The AD9852 permits precise, internally generated linear,
or externally programmed nonlinear, pulsed or continuous
FM over the complete frequency range, duration, frequency
resolution, and sweep direction(s). All of these options are user
programmable. A block diagram of the FM chirp components
is shown in Figure 40.
F2
FREQUENCY
F1
0
000 (DEFAULT)
010 (RAMPED FSK)
TW1
0
F1
TW2
0
F2
MODE
00634-039
I/O UD CLK
FSK DATA
Figure 39. Effect of Premature Ramped FSK Data
Rev. E | Page 22 of 52
AD9852
OUT
PHASE
ACCUMULATOR
ADDER
FREQUENCY
ACCUMULATOR
48-BIT DELTA
FREQUENCY
WORD (TWOS
COMPLEMENT)
CLR ACC1
FREQUENCY
TUNING
WORD 1
20-BIT
RAMP RATE
CLOCK
SYSTEM
CLOCK
00634-040
HOLD
CLR ACC2
Figure 40. FM Chirp Components
FREQUENCY
F1
0
MODE
TW1
000 (DEFAULT)
010 (RAMPED FSK)
0
F1
DFW
00634-041
RAMP RATE
I/O UD CLK
Figure 41. Example of a Nonlinear Chirp
Basic FM Chirp Programming Steps
1.
Program a start frequency into Frequency Tuning Word 1
(Parallel Register Address 4 hex to Parallel Register
Address 9 hex), hereafter called FTW1.
2.
Program the frequency step resolution into the 48-bit, twos
complement delta frequency word (Parallel Register
Address 10 hex to Parallel Register Address 15 hex).
3.
Program the rate of change (time at each frequency) into
the 20-bit ramp rate clock (Parallel Register Address 1A hex
to Parallel Register Address 1C hex).
When programming is complete, an I/O update pulse at Pin 20
engages the program commands.
The necessity for a twos complement delta frequency word is to
define the direction in which the FM chirp moves. If the 48-bit
delta frequency word is negative (MSB is high), the incremental
frequency changes are in a negative direction from FTW1. If the
48-bit word is positive (MSB is low), the incremental frequency
changes are in a positive direction from FTW1.
It is important to note that FTW1 is only a starting point for
FM chirp. There is no built-in restraint requiring a return to
FTW1. Once the FM chirp begins, it is free to move (under
program control) within the Nyquist bandwidth (dc to one-half
the system clock). However, instant return to FTW1 can be
easily achieved.
Two control bits (CLR ACC1 and CLR ACC2) are available in the
FM chirp mode that allow the device to return to the beginning
frequency, FTW1, or to 0 Hz. When the CLR ACC1 bit (Register
Address 1F hex) is set high, the 48-bit frequency accumulator
(ACC1) output is cleared with a retriggerable one-shot pulse of
one system clock duration. The 48-bit delta frequency word input
to the accumulator is unaffected by the CLR ACC1 bit. If the
CLR ACC1 bit is held high, a one-shot pulse is delivered to the
frequency accumulator (ACC1) on every rising edge of the I/O
update clock. The effect is to interrupt the current chirp, reset the
frequency to that programmed into FTW1, and continue the chirp
at the previously programmed rate and direction. Figure 42 shows
clearing of the frequency accumulator output in chirp mode.
Shown in the diagram is the I/O update clock, which is either user
Rev. E | Page 23 of 52
AD9852
supplied or internally generated. See the Internal and External
Update Clock section for a discussion of the I/O update.
Alternatively, the CLR ACC2 control bit (Register Address 1F hex)
is available to clear both the frequency accumulator (ACC1)
and the phase accumulator (ACC2). When this bit is set high,
the output of the phase accumulator results in 0 Hz output from
the DDS. As long as this bit is set high, the frequency and phase
accumulators are cleared, resulting in 0 Hz output. To return to
the previous DDS operation, CLR ACC2 must be set to logic
low. This bit is useful for generating pulsed FM.
Figure 43 graphically illustrates the effect of the CLR ACC2 bit on
the DDS output frequency. Reprogramming the registers while
the CLR ACC2 bit is high allows a new FTW1 frequency and
slope to be loaded.
Another function only available in the chirp mode is the
HOLD pin (Pin 29). This function stops the clock signal to the
ramp rate counter, thereby halting any further clocking pulses
to the frequency accumulator, ACC1.
The effect is to halt the chirp at the frequency existing just
before the HOLD pin is pulled high. When the HOLD pin is
returned low, the clock resumes and chirp continues. During a
hold condition, the user can change the programming registers;
however, the ramp rate counter must resume operation at its
previous rate until a count of 0 is obtained before a new ramp
rate count can be loaded. Figure 44 illustrates the effect of the
hold function on the DDS output frequency.
FREQUENCY
F1
0
MODE
000 (DEFAULT)
011 (CHIRP)
FTW1
0
F1
DFW
RAMP RATE
DELTA FREQUENCY WORD
RAMP RATE
00634-042
I/O UD CLK
CLR ACC1
Figure 42. Effect of CLR ACC1 in FM Chirp Mode
Rev. E | Page 24 of 52
AD9852
FREQUENCY
F1
0
MODE
000 (DEFAULT)
011 (CHIRP)
0
TW1
DPW
RAMP RATE
00634-043
CLR ACC2
I/O UD CLK
Figure 43. Effect of CLR ACC2 in FM Chirp Mode
FREQUENCY
F1
0
MODE
TW1
000 (DEFAULT)
011 (CHIRP)
0
F1
DELTA FREQUENCY WORD
DFW
RAMP RATE
RAMP RATE
00634-044
HOLD
I/O UD CLK
Figure 44. Example of Hold Function
The 32-bit automatic I/O update counter can be used to
construct complex chirp or ramped FSK sequences. Because
this internal counter is synchronized with the AD9852 system
clock, it allows precisely timed program changes to be invoked.
For such changes, the user need only reprogram the desired
registers before the automatic I/O update clock is generated.
In chirp mode, the destination frequency is not directly specified. If the user fails to control the chirp, the DDS automatically
confines itself to the frequency range between dc and Nyquist.
Unless terminated by the user, the chirp continues until power
is removed.
When the chirp destination frequency is reached, the user can
choose any of the following actions:
•
•
•
Rev. E | Page 25 of 52
Stop at the destination frequency either by using the
HOLD pin or by loading all 0s into the delta frequency
word registers of the frequency accumulator (ACC1).
Use the HOLD pin function to stop the chirp, and then ramp
down the output amplitude either by using the digital multiplier stages and the output shaped keying pin (Pin 30) or by
using the program register control (Address 21 hex to
Address 24 hex).
Abruptly end the transmission with the CLR ACC2 bit.
AD9852
•
Continue chirp by reversing the direction and returning to
the previous or another destination frequency in a linear or
user-directed manner. If this involves reducing the
frequency, a negative 48-bit delta frequency word (the
MSB is set to 1) must be loaded into Register 10 hex to
Register 15 hex. Any decreasing frequency step of the delta
frequency word requires the MSB to be set to logic high.
Continue chirp by immediately returning to the beginning
frequency (F1) in a sawtooth fashion, and then repeating the
previous chirp process. In this case, an automatic repeating
chirp can be set up by using the 32-bit update clock to issue
the CLR ACC1 command at precise time intervals. Adjusting
the timing intervals or changing the delta frequency word
changes the chirp range. It is incumbent upon the user to
balance the chirp duration and frequency resolution to
achieve the proper frequency range.
BPSK (MODE 100)
Binary, biphase, or bipolar phase shift keying is a means to
rapidly select between two preprogrammed 14-bit output phase
offsets. The logic state of BPSK (Pin 29) controls the selection of
Phase Adjust Register 1 or Phase Adjust Register 2. When low,
BPSK selects Phase Adjust Register 1; when high, it selects
Phase Adjust Register 2. Figure 45 illustrates phase changes
made to four cycles of an output carrier.
Basic BPSK Programming Steps
1.
2.
Program a carrier frequency into Frequency Tuning Word 1.
Program the appropriate 14-bit phase words into Phase Adjust
Register 1 and Phase Adjust Register 2.
Attach the BPSK data source to Pin 29.
Activate the I/O update clock when ready.
3.
4.
If higher-order PSK modulation is desired, the user can select
single-tone mode and program Phase Adjust Register 1 using
the serial or high speed parallel programming bus.
360
PHASE
0
MODE
000 (DEFAULT)
100 (BPSK)
FTW1
0
F1
PHASE ADJUST 1
270°
PHASE ADJUST 2
90°
BPSK DATA
00634-045
•
I/O UD CLK
Figure 45. BPSK Mode
Rev. E | Page 26 of 52
AD9852
USING THE AD9852
INTERNAL AND EXTERNAL UPDATE CLOCK
ON/OFF OUTPUT SHAPED KEYING (OSK)
The update clock function is composed of a bidirectional
I/O pin (Pin 20) and a programmable 32-bit down-counter. In
order for programming changes to be transferred from the I/O
buffer registers to the active core of the DDS, a clock signal
(low-to-high edge) must be externally supplied to Pin 20 or
internally generated by the 32-bit update clock.
The on/off OSK feature allows the user to control the amplitude
vs. time slope of the cosine DAC output signal. This function is
used in burst transmissions of digital data to reduce the adverse
spectral impact of short, abrupt bursts of data. Users must first
enable the digital multiplier by setting the OSK EN bit (Control
Register Address 20 hex) to logic high in the control register.
Otherwise, if the OSK EN bit is set low, the digital multiplier
responsible for amplitude control is bypassed, and the cosine
DAC output is set to full-scale amplitude.
An internally generated update clock can be established by
programming the 32-bit update clock registers (Address 16 hex
to Address 19 hex) and setting the internal/external update clock
control register bit (Address 1F hex) to logic high. The update
clock countdown counter function operates at half the rate of
the system clock (150 MHz maximum) and counts down from a
32-bit binary value (programmed by the user). When the count
reaches 0, an automatic I/O update of the DDS output or the DDS
functions is generated. The update clock is internally and externally
routed to Pin 20 to allow users to synchronize the programming of
update information with the update clock rate. The time between
update pulses is given as
(N + 1)(System Clock Period × 2)
where N is the 32-bit value programmed by the user, and the
allowable range of N is from 1 to (232 − 1).
The internally generated update pulse output on Pin 20 has a
fixed high time of eight system clock cycles.
Programming the update clock register for values less than 5 causes
the I/O UD CLK pin to remain high. Although the update clock
can still function in this state, it cannot be used to indicate when
data is transferring. This is an effect of the minimum high pulse
time when I/O UD CLK functions as an output.
In addition to setting the OSK EN bit, a second control bit, OSK
INT (also at Address 20 hex), must be set to logic high. Logic high
selects the linear internal control of the output ramp-up or rampdown function. A logic low in the OSK INT bit switches control
of the digital multiplier to a user-programmable 12-bit register,
allowing users to dynamically shape the amplitude transition in
practically any fashion. The 12-bit register, labeled output shape
key, is located at Address 21 hex to Address 22 hex, as indicated
in Table 9. The maximum output amplitude is a function of the
RSET resistor and is not programmable when OSK INT is enabled.
ABRUPT ON/OFF KEYING
ZERO
SCALE
FULL
SCALE
ZERO
SCALE
FULL
SCALE
SHAPED ON/OFF KEYING
00634-046
When the user provides an external update clock, it is internally
synchronized with the system clock to prevent partial transfer
of program register information due to violation of data setup
or hold times. This mode provides the user with complete control
of when updated program information becomes effective. The
default mode for the update clock is internal (internal/external
update clock control register bit is logic high). To switch to
external update clock mode, the internal/external update clock
control register bit must be set to logic low. The internal update
mode generates automatic, periodic update pulses at intervals
set by the user.
Figure 46. On/Off Output Shaped Keying
The transition time from zero scale to full scale must also be
programmed. The transition time is a function of two fixed
elements and one variable. The variable element is the programmable 8-bit ramp rate counter. This is a countdown counter
that is clocked at the system clock rate (300 MHz maximum)
and generates one pulse whenever the counter reaches 0. This
pulse is routed to a 12-bit counter that increments with each
pulse received. The outputs of the 12-bit counter are connected
to the 12-bit digital multiplier. When the digital multiplier has
a value of all 0s at its inputs, the input signal is multiplied by 0,
producing zero scale. When the multiplier has a value of all 1s,
the input signal is multiplied by a value of 4095 or 4096, producing
nearly full scale. There are 4094 remaining fractional multiplier
values that produce output amplitudes scaled according to their
binary values.
Rev. E | Page 27 of 52
AD9852
A total of 4096 output pulses is required to advance the 12-bit
up-counter from zero scale to full scale. Therefore, the minimum
output shaped keying ramp time for a 100 MHz system clock is
The two fixed elements of the transition time are the period of
the system clock (which drives the ramp rate counter) and the
number of amplitude steps (4096). For example, if the system
clock of the AD9852 is 100 MHz (10 ns period) and the ramp
rate counter is programmed for a minimum count of 3, two system
clock periods are required: one rising edge loads the countdown
value, and the next edge decrements the counter from 3 to 2. If the
countdown value is less than 3, the ramp rate counter stalls and
therefore produces a constant scaling value to the digital multiplier.
This stall condition may have an application for the user.
4096 × 4 × 10 ns ≈ 164 μs
The maximum ramp time is
4096 × 256 × 10 ns ≈ 10.5 ms
Finally, by changing the logic state of Pin 30, output shaped
keying automatically performs the programmed output envelope
functions when OSK INT is high. A logic high on Pin 30 causes
the outputs to linearly ramp up to full-scale amplitude and hold
until the logic level is changed to low, causing the outputs to
ramp down to zero scale.
The relationship of the 8-bit countdown value to the time between
output pulses is given as
(N + 1) × System Clock Period
where N is the 8-bit countdown value.
(BYPASS MULTIPLIER)
OSK EN = 0
12
OSK EN = 1
USER-PROGRAMMABLE
12-BIT MULTIPLIER
OUTPUT SHAPED
KEYING MULTIPLIER
REGISTER
OSK EN = 0
12
12-BIT DIGITAL
MULTIPLIER
COSINE
DAC
OSK EN = 1
12
OSK INT = 1
12
OSK INT = 0
12
12-BIT
UP/DOWN
COUNTER
1
8-BIT RAMP
RATE
COUNTER
SYSTEM
CLOCK
ON/OFF OUTPUT SHAPED
KEYING PIN
00634-047
DIGITAL
DDS DIGITAL SIGNAL IN
OUTPUT
Figure 47. Block Diagram of the Digital Multiplier Section Responsible for the Output Shaped Keying Function
Rev. E | Page 28 of 52
AD9852
4.0
COSINE DAC
3.5
3.0
The cosine output of the DDS drives the cosine DAC (300 MSPS
maximum). Its maximum output amplitude is set by the DAC RSET
resistor at Pin 56. This is a current-output DAC with a full-scale
maximum output of 20 mA; however, a nominal 10 mA output
current provides best spurious-free dynamic range (SFDR) performance. The value of RSET is 39.93/IOUT, where IOUT is expressed in
amps. DAC output compliance specifications limit the maximum
voltage developed at the outputs to −0.5 V to +1 V. Voltages
developed beyond this limitation cause excessive DAC distortion
and possibly permanent damage. The user must choose a proper
load impedance to limit the output voltage swing to the compliance
limits. Both DAC outputs should be terminated equally for best
SFDR, especially at higher output frequencies, where harmonic
distortion errors are more prominent.
The cosine DAC is preceded by an inverse sin(x)/x filter
(also called an inverse sinc filter) that precompensates for
DAC output amplitude variations over frequency to achieve
flat amplitude response from dc to Nyquist. This DAC can be
powered down when not needed by setting the DAC PD bit
high (Address 1D hex of the control register). Cosine DAC
outputs are designated as IOUT1 (Pin 48) and IOUT1 (Pin 49).
CONTROL DAC
The control DAC output can provide dc control levels to
external circuitry, generate ac signals, or enable duty cycle
control of the on-board comparator. The input to the control
DAC is configured to accept twos complement data supplied by
the user. Data is channeled through the serial or parallel interface to the 12-bit control DAC register (Address 26 hex and
Address 27 hex) at a maximum data rate of 100 MHz. This DAC
is clocked at the system clock, 300 MSPS (maximum), and has
the same maximum output current capability as that of the
cosine DAC. The single RSET resistor on the AD9852 sets the
full-scale output current for both DACs. When not needed, the
control DAC can be powered down separately to conserve power
by setting the control DAC power-down bit high (Address 1D hex).
Control DAC outputs are designated as IOUT2 (Pin 52) and
IOUT2 (Pin 51).
2.5
ISF
MAGNITUDE (dB)
2.0
1.5
1.0
0.5
SYSTEM
0
–0.5
–1.0
–1.5
–2.0
SINC
–2.5
–3.5
–4.0
0
0.1
0.2
0.3
0.4
FREQUENCY NORMALIZED TO SAMPLE RATE
0.5
00634-048
–3.0
Figure 48. Inverse Sinc Filter Response
INVERSE SINC FUNCTION
This filter precompensates input data to the cosine DAC for
the sin(x)/x roll-off characteristic inherent in the DAC’s
output spectrum. This allows wide bandwidth signals, such
as QPSK, to be output from the DAC without appreciable
amplitude variations as a function of frequency. The inverse
sinc function can be bypassed to significantly reduce power
consumption, especially at higher clock speeds.
Inverse sinc is engaged by default and is bypassed by bringing
the bypass inverse sinc bit high in Control Register 20 hex, as
noted in Table 9.
REFCLK MULTIPLIER
The REFCLK multiplier is a programmable PLL-based
reference clock multiplier that allows the user to select an
integer clock multiplying value over the range of 4× to 20×. Use
of this function allows users to input as little as 15 MHz at the
REFCLK input to produce a 300 MHz internal system clock.
Five bits in Control Register 1E hex set the multiplier value, as
described in Table 8.
The REFCLK multiplier function can be bypassed to allow
direct clocking of the AD9852 from an external clock source.
The system clock for the AD9852 is either the output of the
REFCLK multiplier (if it is engaged) or the REFCLK inputs.
REFCLK can be either a single-ended or differential input by
setting Pin 64 (DIFF CLK ENABLE) low or high, respectively.
PLL Range Bit
The PLL range bit selects the frequency range of the REFCLK
multiplier PLL. For operation from 200 MHz to 300 MHz
(internal system clock rate), the PLL range bit should be set to
Logic 1. For operation below 200 MHz, set the PLL range bit to
Logic 0. The PLL range bit adjusts the PLL loop parameters for
optimized phase noise performance within each range.
Rev. E | Page 29 of 52
AD9852
PLL Filter
The PLL FILTER pin (Pin 61) provides the connection for the
external zero-compensation network of the PLL loop filter. The
zero-compensation network consists of a 1.3 kΩ resistor in
series with a 0.01 μF capacitor. The other side of the network
should be connected as close as possible to Pin 60 (AVDD). For
optimum phase noise performance, the clock multiplier can be
bypassed by setting the bypass PLL bit in Control Register
Address 1E hex.
Differential REFCLK Enable
A high level on the DIFF CLK ENABLE pin enables the differential
clock inputs, REFCLK (Pin 69) and REFCLK (Pin 68). The minimum differential signal amplitude required is 400 mV p-p at
the REFCLK input pins. The center point or common-mode
range of the differential signal can range from 1.6 V to 1.9 V.
When Pin 64 (DIFF CLK ENABLE) is tied low, REFCLK (Pin 69)
is the only active clock input. This is referred to as single-ended
mode. In this mode, Pin 68 (REFCLK) should be tied low or high.
HIGH SPEED COMPARATOR
50 Ω or CMOS logic levels into high impedance loads. The comparator can be powered down separately to conserve power. This
comparator is used in clock-generator applications to square up
the filtered sine wave generated by the DDS.
POWER-DOWN
The programming registers allow several individual stages to be
powered down to reduce power consumption while maintaining
the functionality of the desired stages. These stages are identified in
the Register Layout table (Table 9) in the Address 1D hex section.
Power-down is achieved by setting the specified bits to logic high.
A logic low indicates that the stages are powered up.
Furthermore, and perhaps most importantly, the inverse sinc
filters and the digital multiplier stages can be bypassed to achieve
significant power reduction by programming the control registers in Address 20 hex. Again, logic high causes the stage to be
bypassed. Of particular importance is the inverse sinc filter
because this stage consumes a significant amount of power.
A full power-down occurs when all four PD bits in Control
Register 1D hex are set to logic high. This reduces power
consumption to approximately 10 mW (3 mA).
The comparator is optimized for high speed and has a toggle
rate greater than 300 MHz, low jitter, sensitive input, and builtin hysteresis. It also has an output level of 1 V p-p minimum into
Rev. E | Page 30 of 52
AD9852
PROGRAMMING THE AD9852
The AD9852 Register Layout table (Table 9) contains information
for programming a chip for a desired functionality. Although
many applications require very little programming to configure
the AD9852, some use all 12 accessible register banks. The
AD9852 supports an 8-bit parallel I/O operation or an SPIcompatible serial I/O operation. All accessible registers can be
written and read back in either I/O operating mode.
S/P SELECT (Pin 70) is used to configure the I/O mode.
Systems that use a parallel I/O mode must connect the S/P
SELECT pin to VDD. Systems that operate in the serial I/O mode
must tie the S/P SELECT pin to GND.
Regardless of the mode, the I/O port data is written to a buffer
memory that only affects operation of the part after the contents
of the buffer memory are transferred to the register banks. This
transfer of information occurs synchronous to the system clock
in one of two ways:
•
•
The transfer is internally controlled at a rate programmed
by the user.
The transfer is externally controlled by the user. I/O operations can occur in the absence of REFCLK, but data cannot be
moved from the buffer memory to the register bank without
REFCLK. (See the Internal and External Update Clock
section for details.)
MASTER RESET
The MASTER RESET pin must be held at logic high active for
a minimum of 10 system clock cycles. This initializes the communication bus and loads the default values listed in Table 9.
PARALLEL I/O OPERATION
With the S/P SELECT pin tied high, the parallel I/O mode is
active. The I/O port is compatible with industry-standard DSPs
and microcontrollers. Six address bits, eight bidirectional data
bits, and separate write/read control inputs comprise the I/O
port pins.
Parallel I/O operation allows write access to each byte of any
register in a single I/O operation of up to one per 10.5 ns.
Readback capability for each register is included to ease
designing with the AD9852.
Reads are not guaranteed at 100 MHz, because they are
intended for software debugging only.
Parallel I/O operation timing diagrams are shown in Figure 49
and Figure 50.
Table 8. REFCLK Multiplier Control Register Values
Multiplier Value
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
Bit 4
0
0
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
Reference Multiplier
Bit 3
Bit 2
Bit 1
0
1
0
0
1
0
0
1
1
0
1
1
1
0
0
1
0
0
1
0
1
1
0
1
1
1
0
1
1
0
1
1
1
1
1
1
0
0
0
0
0
0
0
0
1
0
0
1
0
1
0
Bit 0
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
SERIAL PORT I/O OPERATION
With the S/P SELECT pin tied low, the serial I/O mode is
active. The AD9852 serial port is a flexible, synchronous, serial
communication port, allowing easy interface to many industrystandard microcontrollers and microprocessors. The serial I/O
is compatible with most synchronous transfer formats, including
both the Motorola 6905/11 SPI and Intel 8051 SSR protocols.
The interface allows read/write access to all 12 registers that
configure the AD9852 and can be configured as a single-pin
I/O (SDIO) or two unidirectional pins for input and output
(SDIO/SDO). Data transfers are supported in MSB- or LSBfirst format at up to 10 MHz.
When configured for serial I/O operation, most pins from the
AD9852 parallel port are inactive; only some pins are used for
serial I/O operation. Table 10 describes pin requirements for
serial I/O operation.
When operating the device in the serial I/O mode, it is best to
use the external I/O update clock mode to avoid an I/O update
clock occurring during a serial communication cycle. Such an
occurrence may cause incorrect programming due to a partial
data transfer. Therefore, users should write to the device between
I/O update clocks. To exit the default internal update mode,
program the device for external update operation at power-up
before starting the REFCLK signal but after a master reset.
Starting the REFCLK causes this information to transfer to the
register bank, forcing the device to switch to external update mode.
Rev. E | Page 31 of 52
AD9852
Table 9. Register Layout 1
Parallel
Address
(Hex)
00
01
02
03
04
05
06
07
08
09
0A
0B
0C
0D
0E
0F
10
11
12
13
14
15
16
17
18
19
1A
1B
1C
1D
Serial
Address
(Hex)
0
1
2
3
5
6
7
1E
1F
20
21
22
23
24
25
26
27
1
8
9
A
B
AD9852 Register Layout
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Phase Adjust Register 1 <13:8> (Bits 15, 14 don’t care)
Phase 1
Phase Adjust Register 1 <7:0>
Phase Adjust Register 2 <13:8> (Bits 15, 14 don’t care)
Phase 2
Phase Adjust Register 2 <7:0>
Frequency 1
Frequency Tuning Word 1 <47:40>
Frequency Tuning Word 1 <39:32>
Frequency Tuning Word 1 <31:24>
Frequency Tuning Word 1 <23:16>
Frequency Tuning Word 1 <15:8>
Frequency Tuning Word 1 <7:0>
Frequency 2
Frequency Tuning Word 2 <47:40>
Frequency Tuning Word 2 <39:32>
Frequency Tuning Word 2 <31:24>
Frequency Tuning Word 2 <23:16>
Frequency Tuning Word 2 <15:8>
Frequency Tuning Word 2 <7:0>
Delta frequency word <47:40>
Delta frequency word <39:32>
Delta frequency word <31:24>
Delta frequency word <23:16>
Delta frequency word <15:8>
Delta frequency word <7:0>
Update clock <31:24>
Update clock <23:16>
Update clock <15:8>
Update clock <7:0>
Ramp rate clock <19:16> (Bits 23, 22, 21, 20, don’t care)
Ramp rate clock <15:8>
Ramp rate clock <7:0>
Don’t care
Don’t care
Don’t
Comp
Reserved, Control
CR [31]
care
PD
always
DAC PD
low
Don’t care
PLL range
Ref Mult 2
Bypass
Ref
Ref
PLL
Mult 4
Mult 3
CLR ACC1
CLR ACC2
Triangle Don’t
Mode 2
Mode 1
care
Don’t care
OSK EN
OSK INT Don’t care Don’t care
Bypass inv
sinc
Output shaped keying multiplier <11:8> (Bits 15, 14, 13, 12 don’t care)
Output shaped keying multiplier <7:0>
Don’t care
Don’t care
Output shaped keying ramp rate <7:0>
Control DAC <11:8> (Bits 15, 14, 13, 12 don’t care)
Control DAC <7:0> (Data is required to be in twos complement format)
The shaded sections comprise the control register.
Rev. E | Page 32 of 52
DAC PD
DIG PD
Default
Value
(Hex)
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
10
Ref
Mult 1
Mode 0
Ref Mult 0
64
Int/Ext
update clock
SDO active
CR [0]
01
Bit 1
LSB first
Bit 0
20
00
00
00
00
80
00
00
AD9852
A<5:0>
A1
A2
A3
D<7:0>
D1
D2
D3
RD
tRDLOV
tAHD
tADV
SPECIFICATION
VALUE
DESCRIPTION
tADV
tAHD
tRDLOV
tRDHOZ
15ns
5ns
15ns
10ns
ADDRESS TO DATA VALID TIME (MAXIMUM)
ADDRESS HOLD TIME TO RD SIGNAL INACTIVE (MINIMUM)
RD LOW TO OUTPUT VALID (MAXIMUM)
RD HIGH TO DATA THREE-STATE (MAXIMUM)
00634-049
tRDHOZ
Figure 49. Parallel Port Read Timing Diagram
tWR
A<5:0>
D<7:0>
A1
A2
D1
A3
D2
D3
WR
tDSU
tWRHIGH
tWRLOW
SPECIFICATION
tASU
tDSU
tADH
tDHD
tWRLOW
tWRHIGH
tWR
tAHD
VALUE
8.0ns
3.0ns
0ns
0ns
2.5ns
7ns
10.5ns
tDHD
DESCRIPTION
ADDRESS SETUP TIME TO WR SIGNAL ACTIVE
DATA SETUP TIME TO WR SIGNAL ACTIVE
ADDRESS HOLD TIME TO WR SIGNAL INACTIVE
DATA HOLD TIME TO WR SIGNAL INACTIVE
WR SIGNAL MINIMUM LOW TIME
WR SIGNAL MINIMUM HIGH TIME
MINIMUM WRITE TIME
00634-050
tASU
Figure 50. Parallel Port Write Timing Diagram
Table 10. Serial I/O Pin Requirements
Pin Number
1 to 8
14 to 16
17
18
19
20
21
22
Mnemonic
D [7:0]
A [5:3]
A2/IO RESET
A1/SDO
A0/SDIO
I/O UD CLK
WR/SCLK
RD/CS
Serial I/O Description
The parallel data pins are not active; tie these pins to VDD or GND.
The A5, A4, and A3 parallel address pins are not active; tie these pins to VDD or GND.
IO RESET.
SDO.
SDIO.
Update Clock. Same functionality for serial mode as parallel mode.
SCLK.
CS—Chip Select.
Rev. E | Page 33 of 52
AD9852
GENERAL OPERATION OF THE SERIAL INTERFACE
B
Register Name
Phase Offset Tuning Word Register 1
Phase Offset Tuning Word Register 2
Frequency Tuning Word 1
Frequency Tuning Word 2
Delta frequency register
Update clock rate register
Ramp rate clock register
Control register
Digital multiplier register
On/off output shaped keying ramp
rate register
Control DAC register
CS
INSTRUCTION
BYTE
DATA BYTE 1
DATA BYTE 2
DATA BYTE 3
SDIO
INSTRUCTION
CYCLE
DATA TRANSFER
Figure 51. Using SDIO as a Read/Write Transfer
CS
INSTRUCTION
BYTE
SDIO
INSTRUCTION
CYCLE
DATA TRANSFER
DATA BYTE 1
DATA BYTE 2
DATA BYTE 3
SDO
Table 11. Register Address vs. Data Bytes Transferred
Serial
Register
Address
0
1
2
3
4
5
6
7
8
A
Figure 51 and Figure 52 are useful in understanding the general
operation of the AD9852 serial port.
00634-051
The first eight SCLK rising edges of each communication cycle
are used to write the instruction byte into the AD9852. The
remaining SCLK edges are for Phase 2 of the communication
cycle. Phase 2 is the actual data transfer between the AD9852
and the system controller. The number of data bytes transferred
during Phase 2 of the communication cycle is a function of the
register address. The AD9852 internal serial I/O controller
expects every byte of the register being accessed to be
transferred. Table 11 describes how many bytes must be
transferred.
All data input to the AD9852 is registered on the rising edge of
SCLK, and all data is driven out of the AD9852 on the falling
edge of SCLK.
00634-052
There are two phases of a serial communication cycle with the
AD9852. Phase 1 is the instruction cycle, which is the writing of
an instruction byte into the AD9852 coincident with the first
eight SCLK rising edges. The instruction byte provides the
AD9852 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 next
data transfer is a read or write and the register address to be
acted upon.
Number
of Bytes
Transferred
2
2
6
6
6
4
3
4
2
1
DATA TRANSFER
Figure 52. Using SDIO as an Input and SDO as an Output
INSTRUCTION BYTE
The instruction byte contains the following information:
MSB
D7
R/W
D6
X
D5
X
D4
X
D3
A3
D2
A2
D1
A1
LSB
D0
A0
R/W—Bit 7 of the instruction byte determines whether a read
or write data transfer occurs following the instruction byte.
Logic high indicates that a read operation will occur. Logic 0
indicates that a write operation will occur.
2
At the completion of a communication cycle, the AD9852 serial
port controller expects the subsequent eight rising SCLK edges
to be the instruction byte of the next communication cycle. In
addition, an active high input on the IO RESET pin immediately
terminates the current communication cycle. After IO RESET
returns low, the AD9852 serial port controller requires the subsequent eight rising SCLK edges to be the instruction byte of
the next communication cycle.
Bit 6, Bit 5, and Bit 4 of the instruction byte are dummy bits
(don’t care).
A3, A2, A1, A0—Bit 3, Bit 2, Bit 1, and Bit 0 of the instruction
byte determine which register is accessed during the data transfer
portion of the communication cycle (see Table 9 for register
address details).
Rev. E | Page 34 of 52
AD9852
SERIAL INTERFACE PORT PIN DESCRIPTIONS
Table 12.
Pin
SCLK
CS
SDIO
SDO
IO RESET
Description
Serial Clock (Pin 21). The serial clock pin is used to synchronize data to and from the AD9852 and to run the internal state
machines. The SCLK maximum frequency is 10 MHz.
Chip Select (Pin 22). Active low input that allows more than one device on the same serial communication line. The SDO and
SDIO pins go to a high impedance state when this input is high. If this pin is driven high during a communication cycle, the
cycle is suspended until CS is reactivated low. The chip select pin can be tied low in systems that maintain control of SCLK.
Serial Data I/O (Pin 19). Data is always written to the AD9852 on this pin. However, this pin can be used as a bidirectional data
line. The configuration of this pin is controlled by Bit 0 of Register Address 20 hex. The default is Logic 0, which configures the
SDIO pin as bidirectional.
Serial Data Out (Pin 18). Data is read from this pin for protocols that use separate lines for transmitting and receiving data.
In the case where the AD9852 operates in a single bidirectional I/O mode, this pin does not output data and is set to a high
impedance state.
Synchronize I/O Port (Pin 17). Synchronizes the I/O port state machines without affecting the contents of the addressable
registers. An active high input on the IO RESET pin causes the current communication cycle to terminate. After the IO RESET pin
returns low (Logic 0), another communication cycle can begin, starting with the instruction byte.
Notes on Serial Port Operation
MSB/LSB TRANSFERS
The AD9852 serial port configuration bits reside in Bit 1 and Bit 0
of Register Address 20 hex. The configuration changes immediately
upon a valid I/O update. For multibyte transfers, writing to this
register can occur during the middle of a communication cycle.
Care must be taken to compensate for this new configuration
during the remainder of the current communication cycle.
The AD9852 serial port can support both MSB- and LSB-first
data formats. This functionality is controlled by Bit 1 of Serial
Bank 20 hex. When this bit is set active high, the AD9852 serial
port is in LSB-first format. This bit defaults low, to the MSB-first
format. The instruction byte must be written in the format
indicated by Bit 1 of Serial Register Bank 20 hex. Therefore, if
the AD9852 is in LSB-first mode, the instruction byte must be
written from LSB to MSB.
tPRE
tDSU
tSCLKPWH tSCLKPWL
SCLK
tDHLD
SDIO
FIRST BIT
SYMBOL
In cases where synchronization is lost between the system and
the AD9852, the IO RESET pin provides a means to re-establish
synchronization without reinitializing the entire chip. Asserting
the IO RESET pin (active high) resets the AD9852 serial port
state machine, terminating the current I/O operation and forcing
the device into a state in which the next eight SCLK rising edges
are understood to be an instruction byte. The IO RESET pin
must be deasserted (low) before the next instruction byte write
can begin. Any information written to the AD9852 registers
during a valid communication cycle prior to loss of synchronization remains intact.
tSCLK
CS
tPRE
tSCLK
tDSU
tSCLKPWH
tSCLKPWL
tDHLD
MIN
30ns
100ns
30ns
40ns
40ns
0ns
SECOND BIT
DEFINITION
CS SETUP TIME
PERIOD OF SERIAL DATA CLOCK
SERIAL DATA SETUP TIME
SERIAL DATA CLOCK PULSE WIDTH HIGH
SERIAL DATA CLOCK PULSE WIDTH LOW
SERIAL DATA HOLD TIME
00634-053
The system must maintain synchronization with the AD9852;
otherwise, the internal control logic is not able to recognize further
instructions. For example, if the system sends the instruction to
write a 2-byte register and then pulses the SCLK pin for a 3-byte
register (24 additional SCLK rising edges), communication
synchronization is lost. In this case, the first 16 SCLK rising
edges after the instruction cycle properly write the first two data
bytes into the AD9852, but the subsequent eight rising SCLK
edges are interpreted as the next instruction byte, not the final
byte of the previous communication cycle.
Figure 53. Timing Diagram for Data Write to AD9852
CS
SCLK
SDIO
SDO
FIRST BIT
SECOND BIT
MAX
tDV
30ns DATA VALID TIME
DEFINITION
Figure 54. Timing Diagram for Read from AD9852
Rev. E | Page 35 of 52
00634-054
tDV
SYMBOL
AD9852
CONTROL REGISTER DESCRIPTIONS
The control register is located at Address 1D hex to Address 20 hex (shown in the shaded portion of Table 9). It is composed of 32 bits.
Bit 31 is located at the top left position, and Bit 0 is located in the lower right position of the shaded area of Table 9. The register has been
subdivided into bits to make it easier to locate the information associated with specific control categories.
Table 13. Control Register Bit Descriptions
Bit
CR [31:29]
CR [28]
CR [27]
CR [26]
CR [25]
CR [24]
CR [23]
CR [22]
CR [21]
CR [20:16]
CR [15]
CR [14]
CR [13]
CR [12]
CR [11:9]
CR [8]
CR [7]
CR [6]
CR [5]
CR [4]
CR [3:2]
CR [1]
CR [0]
Description
Open.
The comparator power-down bit. When this bit is set to Logic 1, it indicates to the comparator that a power-down mode is
active. This bit is an output of the digital section and is an input to the analog section.
Must always be written to Logic 0. Writing this bit to Logic 1 causes the AD9852 to stop functioning until a master reset is applied.
The control DAC power-down bit. When this bit is set to Logic 1, it indicates to the control DAC that power-down mode is active.
The full DAC power-down bit. When this bit is set to Logic 1, it indicates to both the cosine and control DACs, as well as the
reference, that a power-down mode is active.
The digital power-down bit. When this bit is set to Logic 1, it indicates to the digital section that a power-down mode is
active. Within the digital section, the clocks are forced to dc, effectively powering down the digital section. The PLL still
accepts the REFCLK signal and continues to output the higher frequency.
Reserved. Write to 0.
The PLL range bit. The PLL range bit controls the VCO gain. The power-up state of the PLL range bit is Logic 1; a higher gain is
required for frequencies greater than 200 MHz.
The bypass PLL bit, active high. When this bit is active, the PLL is powered down and the REFCLK input is used to drive the
system clock signal. The power-up state of the bypass PLL bit is Logic 1 with PLL bypassed.
The PLL multiplier factor. These bits are the REFCLK multiplication factor unless the bypass PLL bit is set. The PLL multiplier
valid range is from 4 to 20, inclusive.
The Clear Accumulator 1 bit. This bit has a one-shot type of function. When this bit is written active (Logic 1), a Clear
Accumulator 1 signal is sent to the DDS logic, resetting the accumulator value to 0. The bit is then automatically reset, but
the buffer memory is not reset. This bit allows the user to easily create a sawtooth frequency sweep pattern with minimal
user intervention. This bit is intended for chirp mode only, but its function is still retained in other modes.
The clear accumulator bit. When this bit is active high, it holds both the Accumulator 1 and Accumulator 2 values at 0 for as
long as the bit is active. This allows the DDS phase to be initialized via the I/O port.
The triangle bit. When this bit is set, the AD9852 automatically performs a continuous frequency sweep from F1 to F2
frequencies and back. The effect is a triangular frequency sweep. When this bit is set, the operating mode must be set to
ramped FSK.
Don’t care.
The three bits that describe the five operating modes of the AD9852:
0x0 = single-tone mode
0x1 = FSK mode
0x2 = ramped FSK mode
0x3 = chirp mode
0x4 = BPSK mode
The internal update active bit. When this bit is set to Logic 1, the I/O UD CLK pin is an output and the AD9852 generates the
I/O UD CLK signal. When this bit is set to Logic 0, external I/O update function is performed, and the I/O UD CLK pin is
configured as an input.
Reserved. Write to 0.
This is the inverse sinc filter bypass bit. When this bit is set, the data from the DDS block goes directly to the output shaped
keying logic, and the clock for the inverse sinc filter is stopped. Default is clear with the filter enabled.
The output shaped keying enable bit. When this bit is set, the output ramping function is enabled and is performed in
accordance with the CR [4] bit requirements.
The internal/external output shaped keying control bit. When this bit is set to Logic 1, the output shaped keying factor is
internally generated and applied to the cosine DAC path. When this bit is cleared (default), the output shaped keying function is
externally controlled by the user, and the output shaped keying factor is the value of the output shaped keying multiplier
register. The two output shaped keying multiplier registers also default low so that the output is off at power-up until the device
is programmed by the user.
Reserved. Write to 0.
The serial port MSB-/LSB-first bit. Defaults low, MSB first.
The serial port SDO active bit. Defaults low, inactive.
Rev. E | Page 36 of 52
AD9852
INSTRUCTION CYCLE
DATA TRANSFER CYCLE
CS
SDIO
I7
I6
I5
I4
I3
I2
I1
D7
I0
D6
D5
D4
D3
D2
D1
00634-055
SCLK
D0
Figure 55. Serial Port Write Timing Clock Stall Low
DATA TRANSFER CYCLE
INSTRUCTION CYCLE
CS
SCLK
I7
I6
I5
I4
I3
I2
I1
I0
DON’T CARE
DO6
DO7
SDO
DO5
DO4
DO3
DO2
DO1
00634-056
SDIO
DO0
Figure 56. 3-Wire Serial Port Read Timing Clock Stall Low
INSTRUCTION CYCLE
DATA TRANSFER CYCLE
CS
SDIO
I7
I6
I5
I4
I3
I2
I1
I0
D7
D6
D5
D4
D3
D2
D1
00634-057
SCLK
D0
Figure 57. Serial Port Write Timing Clock Stall High
INSTRUCTION CYCLE
DATA TRANSFER CYCLE
CS
SDIO
I7
I6
I5
I4
I3
I2
I1
I0
DO7
DO6
DO5
DO4
Figure 58. 2-Wire Serial Port Read Timing Clock Stall High
Rev. E | Page 37 of 52
DO3
DO2
DO1
DO0
00634-058
SCLK
AD9852
POWER DISSIPATION AND THERMAL CONSIDERATIONS
The AD9852 is a multifunctional, high speed device that targets
a wide variety of synthesizer and agile clock applications. The
numerous innovative features contained in the device each
consume incremental power. If enabled in combination, the safe
thermal operating conditions of the device may be exceeded.
Careful analysis and consideration of power dissipation and
thermal management is a critical element in the successful
application of the AD9852 device.
The AD9852 device is specified to operate within the industrial
temperature range of –40°C to +85°C. This specification is conditional, however, such that the absolute maximum junction
temperature of 150°C is not exceeded. At high operating temperatures, extreme care must be taken when operating the device
to avoid exceeding the junction temperature and potentially
damaging the device.
Many variables contribute to the operating junction temperature
within the device, including
•
•
•
•
•
Package style
Selected mode of operation
Internal system clock speed
Supply voltage
Ambient temperature
JUNCTION TEMPERATURE CONSIDERATIONS
The power dissipation (PDISS) of the AD9852 device in a given
application is determined by many operating conditions. Some
of the conditions have a direct relationship with PDISS, such as
supply voltage and clock speed, but others are less deterministic.
The total power dissipation within the device and its effect on
the junction temperature must be considered when using the
device. The junction temperature of the device is given by
Junction Temperature = (Thermal Impedance ×
Power Consumption) + Ambient Temperature
The maximum ambient temperature combined with the
maximum junction temperature establish the following power
consumption limits for each package: 4.06 W for ASVZ models
and 1.71 W for ASTZ models.
Supply Voltage
Because PDISS = V × I, the supply voltage affects power dissipation
and junction temperature. Users should design for 3.3 V nominally;
however, the device is guaranteed to meet specifications over the
full temperature range and over the supply voltage range of
3.135 V to 3.465 V.
Clock Speed
The combination of these variables determines the junction
temperature within the AD9852 device for a given set of
operating conditions.
The AD9852 device is available in two package styles: a
thermally enhanced surface-mount package with an exposed
heat sink and a standard (nonthermally enhanced) surfacemount package. The thermal impedance of these packages is
16°C/W and 38°C/W, respectively, measured under still air
conditions.
THERMAL IMPEDANCE
The thermal impedance of a package can be thought of as a
thermal resistor that exists between the semiconductor surface
and the ambient air. The thermal impedance is determined by
the package material and the physical dimensions of the package.
The dissipation of the heat from the package is directly dependent on the ambient air conditions and the physical connection
made between the IC package and the PCB.
Adequate dissipation of power from the AD9852 relies on all
power and ground pins of the device being soldered directly to a
copper plane on a PCB. In addition, the thermally enhanced
package of the AD9852ASVZ has an exposed paddle on the
bottom that must be soldered to a large copper plane, which,
for convenience, can be the ground plane. Sockets for either
package style of the AD9852 device are not recommended.
Clock speed directly and linearly influences the total power
dissipation of the device and therefore the junction temperature.
As a rule, the user should select the lowest internal clock speed
possible to support a given application to minimize power
dissipation. Typically, the usable frequency output bandwidth
from a DDS is limited to 40% of the clock rate to ensure that the
requirements on the output low-pass filter are reasonable. For a
typical DDS application, the system clock frequency should be
2.5 times the highest desired output frequency.
Mode of Operation
The selected mode of operation for the AD9852 significantly
influences the total power consumption. The AD9852 offers
many features and modes, each of which imposes an additional
power requirement. The available features make the AD9852
suitable for a variety of applications, but the device is designed
to operate with only a few features enabled in a given application.
Enabling multiple features at high clock speeds may result in
exceeding the maximum junction temperature of the die and
therefore severely limit the long-term reliability of the device.
Figure 59 and Figure 60 show the power requirements associated
with each feature of the AD9852. These charts should be used
as a guide when determining how to optimize the AD9852 for
reliable operation in a specific application.
Figure 59 shows the supply current consumed by the AD9852
over a range of frequencies for two possible configurations. All
circuits enabled means that the output scaling multipliers, the
Rev. E | Page 38 of 52
AD9852
inverse sinc filter, both DACs, and the on-board comparator
are enabled. Basic configuration means the output scaling
multipliers, the inverse sinc filter, the control DAC, and the
on-board comparator are disabled.
500
INVERSE SINC FILTER
450
Figure 60 shows the approximate current consumed by each of
the four functions.
1400
1200
SUPPLY CURRENT (mA)
400
350
300
250
OUTPUT SCALING
MULTIPLIERS
200
150
CONTROL DAC
COMPARATOR
1000
0
800
600
60
100
140
180
220
FREQUENCY (MHz)
260
300
NOTES
THIS GRAPH ASSUMES THAT THE AD9852 DEVICE IS SOLDERED
TO A MULTILAYER PCB PER THE RECOMMENDED BEST
MANUFACTURING PRACTICES AND PROCEDURES FOR THE
GIVEN PACKAGE TYPE.
400
BASIC CONFIGURATION
200
0
20
00634-060
50
ALL CIRCUITS ENABLED
Figure 60. Current Consumption by Function vs. Clock Frequency
20
60
100
140
180
220
FREQUENCY (MHz)
260
300
00634-059
SUPPLY CURRENT (mA)
100
NOTES
THIS GRAPH ASSUMES THAT THE AD9852 DEVICE IS SOLDERED
TO A MULTILAYER PCB PER THE RECOMMENDED BEST
MANUFACTURING PRACTICES AND PROCEDURES FOR THE
GIVEN PACKAGE TYPE.
Figure 59. Current Consumption vs. Clock Frequency
Rev. E | Page 39 of 52
AD9852
EVALUATION OF OPERATING CONDITIONS
The first step in applying the AD9852 is to select the internal
clock frequency. Clock frequency selections greater than 200 MHz
require use of the thermally enhanced package (AD9852ASVZ);
clock frequency selections equal to or less than 200 MHz may
allow use of the standard (nonthermally enhanced) plastic
surface-mount package, but more information is needed to
make this determination.
power dissipation limit of 4.1 W and 1.7 W for the thermally and
nonthermally enhanced packages, respectively. Therefore, for a
3.3 V nominal power supply voltage, the current consumed by the
device under full operating conditions must not exceed 515 mA
for the standard plastic package or 1242 mA for the thermally
enhanced package. The total set of enabled functions and
operating conditions for a given application must support these
current consumption limits.
The second step is to determine the maximum required
operating temperature for the AD9852 in a given application.
Subtract this value from 150°C, which is the maximum junction
temperature allowed for the AD9852. For the extended industrial temperature range, the maximum operating temperature is
85°C, which results in a difference of 65°C. This is the maximum temperature gradient the device can experience due to
power dissipation.
Figure 59 and Figure 60 can be used to determine the suitability
of a given AD9852 application in terms of the power dissipation
requirements. These graphs assume that the AD9852 device is
soldered to a multilayer PCB according to the recommended best
manufacturing practices and procedures for a given package type.
This ensures that the specified thermal impedance specifications
are achieved.
The third step is to divide this maximum temperature gradient
by the thermal impedance to determine the maximum power
dissipation allowed for the application. For this example, 65°C
divided by the thermal impedance of the package yields a total
THERMALLY ENHANCED PACKAGE
MOUNTING GUIDELINES
Refer to the AN-772 Application Note for details on mounting
devices with an exposed paddle.
Rev. E | Page 40 of 52
AD9852
EVALUATION BOARD
An evaluation board is available that supports the AD9852 DDS
device. This evaluation board consists of a PCB, software, and
documentation to facilitate bench analysis of the performance of
the AD9852 device. It is recommended that users of the AD9852
familiarize themselves with the operation and performance
capabilities of the device by using the evaluation board. The
evaluation board should also be used as a PCB reference design
to ensure optimum dynamic performance from the device.
EVALUATION BOARD INSTRUCTIONS
The AD9852/AD9854 Rev. E evaluation board includes either
an AD9852ASVZ or AD9854ASVZ IC.
The ASVZ package permits 300 MHz operation by virtue of its
thermally enhanced design. This package has a bottom-side
heat slug that must be soldered to the ground plane of the
PCB directly beneath the IC. In this manner, the evaluation
board PCB ground plane layer extracts heat from the AD9852
or AD9854 IC package. If device operation is limited to 200 MHz
or less, the ASTZ package can be used without a heat slug in
customer installations over the full temperature range.
Evaluation boards for both the AD9852 and AD9854 are
identical except for the installed IC.
•
•
•
•
Load the CD software onto the PC’s hard disk. Connect a
printer cable from the PC to the AD9852 evaluation board
printer port connector labeled J11. The current software
(Version 1.72) supports Windows® 95 or better operating
systems.
Hardware Preparation
Using the schematic in conjunction with these instructions
helps acquaint the user with the electrical functioning of the
evaluation board.
Attach power wires to the connector labeled TB1 using the
screw-down terminals. This is a plastic connector that press-fits
over a 4-pin header soldered to the board. Table 14 lists the
connections to each pin.
Table 14. Power Requirements for DUT Pins1
AVDD 3.3 V
All DUT
analog pins
1
To assist in proper placement of the pin header shorting
jumpers, the instructions refer to direction (left, right, top,
bottom) as well as header pins to be shorted. Pin 1 for each
3-pin header is marked on the PCB corresponding with the
schematic diagram. When following these instructions, position
the PCB so that the PCB text can be read from left to right. The
board is shipped with the pin headers configuring the board as
follows:
•
GENERAL OPERATING INSTRUCTIONS
REFCLK for the AD9852 or AD9854 is configured as
differential. The differential clock signals are provided by
the MC100LVEL16D differential receiver.
Input clock for the MC100LVEL16D is single ended via
J25. This signal may be 3.3 V CMOS or a 2 V p-p sine wave
capable of driving 50 Ω (R13).
Both DAC outputs from the AD9852 or AD9854 are
routed through the two 120 MHz elliptical LP filters, and
their outputs are connected to J7 (Q, or control DAC) and
J6 (I , or cosine DAC).
The board is set up for software control via the printer port
connector.
The output currents of the DAC are configured for 10 mA.
DVDD 3.3 V
All DUT
digital pins
VCC 3.3 V
All other
devices
Ground
All devices
DUT = device under test.
Clock Input, J25
Attach REFCLK to the clock input, J25. This is a single-ended
input that is routed to the MC100LVEL16D for conversion to
differential PECL output. This is accomplished by attaching a 2
V p-p clock or sine wave source to J25. This is a 50 Ω impedance
point set by R13. The input signal is ac-coupled and then biased
to the center-switching threshold of the MC100LVEL16D. To
engage the differential clocking mode of the AD9852, Pin 2 and
Pin 3 (the bottom two pins) of W3 must be connected with a
shorting jumper.
The signal arriving at the AD9852 is called the reference clock.
If the user chooses to engage the on-chip PLL clock multiplier,
this signal is the reference clock for the PLL and the multiplied
PLL output becomes the system clock. If the user chooses to bypass
the PLL clock multiplier, the reference clock that has been supplied
is directly operating the AD9852 and is therefore the system clock.
Three-State Control
Three of the following control or switch headers must be
shorted to allow the provided software to control the evaluation
board via Printer Port Connector J11: W9, W11, W12, W13,
W14, and W15.
Rev. E | Page 41 of 52
AD9852
Programming
If a PC and Analog Devices software are not used to program
the AD9852, the W9, W11, W12, W13, W14, and W15 headers
should be opened (shorting jumpers removed). This effectively
detaches the PC interface and allows J10 (the 40-pin header) and J1
to assume control without bus contention. Input signals on J10
and J1 going to the AD9852 should be 3.3 V CMOS logic levels.
the I and Q signals to remove images, aliased harmonics, and
other spurious signals that are greater than approximately
120 MHz:
1.
2.
3.
4.
Low-Pass Filter Testing
The purpose of the 2-pin W7 and W10 headers (associated with
J4 and J5) is to allow the two 50 Ω, 120 MHz filters to be tested
during PCB assembly without interference from other circuitry
attached to the filter inputs. Normally, a shorting jumper is attached
to each header to allow the DAC signals to be routed to the filters.
If the user wishes to test the filters, the shorting jumpers at W7 and
W10 should be removed and 50 Ω test signals should be applied at
the J4 and J5 inputs to the 50 Ω elliptic filters. The user can refer to
the provided schematic (Figure 61 and Figure 62) and the
following sections to properly position the remaining shorting
jumpers.
5.
Install shorting jumpers at W7 and W10.
Install a shorting jumper at W16.
Install a shorting jumper on Pin 1 and Pin 2 (bottom two pins)
of the 3-pin W1 header.
Install a shorting jumper on Pin 1 and Pin 2 (bottom two pins)
of the 3-pin W4 header.
Install a shorting jumper on Pin 2 and Pin 3 (bottom two pins)
of the 3-pin W2 and W8 headers.
The resulting signals appear as nearly pure sine waves and are
90° out of phase with each other. These filters are designed with
the assumption that the system clock speed is at or near its
maximum speed (300 MHz). If the system clock speed is much
less than 300 MHz, for example 200 MHz, it is possible, or
inevitable, that unwanted DAC products other than the
fundamental signal will be passed by the low-pass filters.
If an AD9852 evaluation board is used, any reference to the Q
signal should be interpreted to mean the control DAC.
Observing the Unfiltered IOUT1 and the Unfiltered
IOUT2 DAC Signals
Observing the Filtered IOUT1 and the Filtered IOUT1
The unfiltered DAC outputs can be observed at J5 (the I, or
cosine DAC, signal) and J4 (the Q, or control DAC, signal). Use
the following procedure to route the two 50 Ω terminated analog
DAC outputs to the SMB connectors and to disconnect any other
circuitry.
The filtered I DAC outputs can be observed at J6 (the true signal)
and J7 (the complementary signal). Use the following procedure to
route the 120 MHz low-pass filters in the true and complementary
output paths of the I DAC to remove images, aliased harmonics,
and other spurious signals above approximately 120 MHz:
1.
2.
3.
4.
1.
2.
3.
Install shorting jumpers at W7 and W10.
Remove the shorting jumper at W16.
Remove the shorting jumper from the 3-pin W1 header.
Install a shorting jumper on Pin 1 and Pin 2 (bottom two
pins) of the 3-pin W4 header.
The raw DAC outputs may appear as a series of quantized
(stepped) output levels that do not resemble a sine wave until
they are filtered. The default 10 mA output current develops a
0.5 V p-p signal across the on-board 50 Ω termination. If the
observation equipment uses 50 Ω inputs, the DAC develops
only 0.25 V p-p due to the double termination.
If using the AD9852 evaluation board, the user can control
IOUT2 (the control DAC output) by using the serial or parallel
ports. The 12-bit, twos complement value(s) is/are written to
the control DAC register that sets the IOUT2 output to a static
dc level. Allowable hexadecimal values are 7FF (maximum) to
800 (minimum), with all 0s being midscale. Rapidly changing
the contents of the control DAC register (up to 100 MSPS)
allows IOUT2 to assume any programmable waveform.
Observing the Filtered IOUT1 and the Filtered IOUT2
The filtered I (cosine DAC) and Q (control DAC) outputs can
be observed at J6 (the I, or cosine DAC, signal) and J7 (the Q, or
control DAC, signal). Use the following procedure to route the
50 Ω (input and output Z) low-pass filters into the pathways of
4.
5.
Install shorting jumpers at W7 and W10.
Install a shorting jumper at W16.
Install a shorting jumper on Pin 2 and Pin 3 (top two pins)
of the 3-pin W1 header.
Install a shorting jumper on Pin 2 and Pin 3 (top two pins)
of the 3-pin W4 header.
Install a shorting jumper on Pin 2 and Pin 3 (bottom two pins)
of the 3-pin W2 and W8 headers.
The resulting signals appear as nearly pure sine waves and are
180° out of phase with each other. If the system clock speed is
much less than 300 MHz, for example 200 MHz, it is possible,
or inevitable, that unwanted DAC products other than the
fundamental signal will be passed by the low-pass filters.
Connecting the High Speed Comparator
To connect the high speed comparator to the DAC output
signals use either the quadrature filtered output configuration
(AD9854 only) or the complementary filtered output configuration
(both AD9854 and AD9852). Follow Step 1 through Step 4 of
either the Observing the Filtered IOUT1 and the Filtered
IOUT2 section or the Observing the Filtered IOUT1 and the
Filtered IOUT1 section. Then install a shorting jumper on Pin 1
and Pin 2 (the top two pins) of the 3-pin W2 and W8 headers.
Rev. E | Page 42 of 52
AD9852
This step reroutes the filtered signals from the output connectors
(J6 and J7) to the 100 Ω configured comparator inputs. This sets
up the comparator for differential input without affecting the
comparator output duty cycle, which should be approximately
50% for the complementary filtered output configuration.
Several numerical entries, such as frequency and phase information, require pressing ENTER to register this information.
For example, if a new frequency is input but does not take effect
when Load is clicked, the user probably neglected to press
ENTER after inputting the new frequency information.
The user can change the value of RSET Resistor R2 from 3.9 kΩ
to 1.95 kΩ to receive more robust signals at the comparator
inputs. This decreases jitter and extends the operating range of
the comparator. To implement this change install a shorting
jumper at W6, which provides a second 3.9 kΩ chip resistor
(R20) in parallel with that provided by R2. This boosts the DAC
output current from 10 mA to 20 mA and doubles the peak-topeak output voltage developed across the loads, thus resulting
in more robust signals at the comparator inputs.
Typical operation of the AD9852/AD9854 evaluation board
begins with a master reset. After this reset, many of the default
register values are depicted in the software control panel. The
reset command sets the DDS output amplitude to minimum
and 0 Hz, zero phase offset, as well as other states that are listed
in the Register Layout table (Table 9).
Single-Ended Configuration
To connect the high speed comparator in a single-ended
configuration so that the duty cycle or pulse width can be
controlled, a dc threshold voltage must be present at one of the
comparator inputs. This voltage can be supplied using the
control DAC. A 12-bit, twos complement value is written to the
control DAC register that sets the IOUT2 output to a static dc
level. Allowable hexadecimal values are 7FF (maximum) to 800
(minimum), with all 0s being midscale. The IOUT1 channel
continues to output a user-programmable, filtered sine wave.
These two signals are routed to the comparator by using the
3-pin W2 and W8 header switches. Use of the configuration
described in the Observing the Filtered IOUT1 and the Filtered
IOUT2 section is required. Follow Step 1 through Step 4 in this
section, and then install a shorting jumper on Pin 1 and Pin 2
(top two pins) of the 3-pin W2 and W8 header switches.
The user can change the value of RSET Resistor R2 from 3.9 kΩ
to 1.95 kΩ to receive more robust signals at the comparator
inputs. This decreases jitter and extends the operating range of the
comparator. To implement this change install a shorting jumper
at W6, which provides a second 3.9 kΩ chip resistor (R20) in
parallel with that provided by R2.
USING THE PROVIDED SOFTWARE
The evaluation software is provided on a CD, along with a brief
set of instructions. Use the instructions in conjunction with the
AD9852 or AD9854 data sheet and the AD9852 or AD9854
evaluation board schematic.
The next programming block should be the reference clock and
multiplier because this information is used to determine the
proper 48-bit frequency tuning words that are entered and later
calculated.
The output amplitude defaults to the 12-bit, straight binary
multiplier values of the I (cosine DAC) multiplier register of
000 hex; no output (dc) should be seen from the DAC. Set the
multiplier amplitude in the Output Amplitude dialog box to a
substantial value, such as FFF hex. The digital multiplier can be
bypassed by selecting the Output Amplitude is always Full Scale
box, but this usually does not result in the best spurious-free
dynamic range (SFDR). The best SFDR, achieving improvements
of up to 11 dB, is obtained by routing the signal through the digital
multiplier and reducing the multiplier amplitude. For instance,
FC0 hex produces less spurious signal amplitude than FFF hex.
If SFDR must be maximized, this exploitable and repeatable
phenomenon should be investigated in the given application.
This phenomenon is more readily observed at higher output
frequencies, where good SFDR becomes more difficult to achieve.
Refer to this data sheet and the evaluation board schematic
(Figure 61 and Figure 62) for information about the available
functions of the AD9852 and how the software responds to
programming commands.
SUPPORT
Applications assistance is available for the AD9852, the AD9852
evaluation board, and all other products of Analog Devices. Call
1-800-ANALOGD or visit www.analog.com/dds.
The CD-ROM contains the following:
•
•
•
•
•
The AD9852/AD9854 evaluation software
AD9852 evaluation board instructions
AD9852 data sheet
AD9852 evaluation board schematics
AD9852 PCB layout
Rev. E | Page 43 of 52
AD9852
Table 15. AD9852 Customer Evaluation Board (AD9852 PCB > U1 = AD9852ASVZ)
Item
1
Qty
3
2
21
3
Reference
Designator
C1, C2, C45
Device
Capacitor 0805
Package
805
Capacitor 0603
603
2
C7, C8, C9, C10,
C11, C12, C13,
C14, C16, C17,
C18, C19, C20,
C22, C23, C24,
C26, C27, C28,
C29, C44
C4, C37
Capacitor 1206
1206
4
2
C5, C38
Capacitor 1206
1206
5
3
C6, C21, C25
Capacitor TAJC
TAJC
6
2
C30, C39
Capacitor 1206
1206
7
2
C31, C40
Capacitor 1206
1206
8
2
C32, C41
Capacitor 1206
1206
9
2
C33, C42
Capacitor 1206
1206
10
2
C34, C43
Capacitor 1206
1206
11
9
SMB
12
13
14
15
1
4
2
2
J1, J2, J3, J4, J5,
J6, J7, J25, J26
J10
L1, L2, L3, L5
L4, L6
R1, R5
40-pin header
Inductor coil
Inductor coil
RES_SM
STR-PC
MNT
Header 40
1008CS
1008CS
1206
16
2
R2, R20
RES_SM
1206
17
2
R3, R7
RES_SM
1206
18
1
R4
RES_SM
1206
19
4
RES_SM
1206
20
1
R6, R11,
R12, R13
R8
RES_SM
1206
21
2
R9, R10
RES_SM
1206
22
4
RES_SM
1206
23
1
R15, R16,
R17, R18
RP1
Resistor network
SIP-10P
Value
0.01 μF,
50 V, X7R
0.1 μF,
50 V, X7R
27 pF,
50 V,
NPO
47 pF,
50 V,
NPO
10 μF,
16 V, TAJ
39 pF,
50 V,
NPO
22 pF,
50 V,
NPO
2.2 pF,
50 V,
NPO
12 pF,
50 V,
NPO
8.2 pF,
50 V,
NPO
N/A
N/A
68 nH
82 nH
49.9 Ω,
¼W
3.92 kΩ,
¼W
24.9 Ω,
¼W
1.3 kΩ,
¼W
49.9 Ω,
¼W
2 kΩ,
¼W
100 Ω,
¼W
10 kΩ,
¼W
10 kΩ
Rev. E | Page 44 of 52
Min
Tol
10%
Manufacturer
Kemet Corp.
Manufacturer Part No.
C0805C103K5RACTU
10%
Murata
Manufacturing
Co., Ltd.
GRM188R71H104KA93D
5%
Yageo Corporation
CC1206JRNPO9BN270
5%
Yageo Corporation
CC1206JRNPO9BN470
10%
AVX
TAJC106K016R
5%
Yageo Corporation
CC1206JRNPO9BN390
5%
Yageo Corporation
CC1206JRNPO9BN220
0.25
pF
Yageo Corporation
CC1206CRNPO9BN2R2
5%
Yageo Corporation
1206CG120J9B200
0.5 pF
Yageo Corporation
CC1206DRNPO9BN8R2
N/A
Emerson/Johnson
131-3701-261
N/A
2%
2%
1%
Samtec, Inc.
Coilcraft, Inc.
Coilcraft, Inc.
Panasonic-ECG
TSW-120-23-L-D
1008CS-680XGLB
1008CS-820XGLB
ERJ-8ENF49R9V
1%
Panasonic-ECG
ERJ-8ENF3921V
1%
Panasonic-ECG
ERJ-8ENF24R9
1%
Panasonic-ECG
ERJ-8ENF1301V
1%
Panasonic-ECG
ERJ-8ENF49R9V
1%
Panasonic-ECG
ERJ-8ENF2001V
1%
Panasonic-ECG
ERJ-8ENF1000V
1%
Panasonic-ECG
ERJ-8ENF1002V
2%
Bourns
4610X-101-103LF
AD9852
Item
24
Qty
1
Reference
Designator
TB1
Device
TB4
Package
4-position
terminal
Value
N/A
Min
Tol
N/A
25
26
1
1
U1
U2
AD9852
74HC125D
SV-80
14 SOIC
N/A
N/A
N/A
N/A
27
1
U3
8 SOIC
N/A
N/A
Analog Devices, Inc.
Texas Instruments
Incorporated
ON Semiconductor
8 SOIC
N/A
N/A
ON Semiconductor
14 SOIC
N/A
N/A
TSW-103-07-S-S
Manufacturer
Wieland Electric, Inc.
Manufacturer Part No.
Plug: 25.602.2453.0;
terminal strip:
Z5.530.3425.0
AD9852ASVZ
SN74HC125DR
28
4
U4, U5, U6, U7
Primary:
MC10EP16DGOS
Secondary:
MC100LVEL16DGOS
74HC14
29
3
U8, U9, U10
74HC574
20 SOIC
N/A
N/A
30
1
J11
C36CRPX
36CRP
N/A
N/A
31
6
3-pin header
SIP-3P
N/A
N/A
32
10
2-pin header
SIP-2P
N/A
N/A
Samtec, Inc.
TSW-102-07-S-S
33
6
Jumpers
N/A
Black
N/A
Samtec, Inc.
SNT-100-BK-G
34
10
Jumpers
N/A
Black
N/A
Samtec, Inc.
SNT-100-BK-G
35
2
W1, W2, W3,
W4, W8, W17
W6, W7, W9,
W10, W11,
W12, W13,
W14, W15,
W16
W1, W2,
W3, W4,
W8, W17
W6, W7, W9,
W10, W11,
W12, W13,
W14, W15,
W16
N/A
Texas Instruments
Incorporated
Texas Instruments
Incorporated
Tyco Electronics
Corporation
Samtec, Inc.
Self-tapping screw
N/A
N/A
36
37
38
4
1
2
N/A
AD9852/54 PCB
R14, R19
Adhesive feet
N/A
RES_SM
4–40,
Phillips
pan head
N/A
N/A
1206
Black
N/A
0 Ω,
¼W
N/A
N/A
5%
Panasonic-ECG
39
4
N/A
40
1
Y1
Pin socket
(open end)
XTAL
N/A
Tyco Electronics
Corporation
Optional
COSC
N/A
Rev. E | Page 45 of 52
Primary:
MC10EP16DGOS
Secondary:
MC100LVEL16DGOS
SN74HC14DR
SN74HC574DWR
5552742-1
90410A107
3M
SJ-5518
GS02669 REV. E
ERJ-8GEY0R00V
5-5330808-6
Optional
DGND1
3
4
5
6
7
8
9
10
11
D5
D4
D3
D2
D1
D0
DVDD
DVDD
ADDR3
A2/IO RESET
A1/SDO
15
16
17
18
19
20
A4
A3
A2/IO RESET
A1/SDO
A0/SDIO
I/O UD CLK
GND
J10
ADDR5
14
A5
UPDCLK
A0/SDIO
ADDR4
NC
13
DGND7
AVDD
PMODE
TOP VIEW
(Not to Scale)
AD9852
U1
CLKVDD
VOUT
NC2
DGND8
DVDD4
DVDD
DVDD
RD/CS
WR/SCLK
1
FDATA
1
4
3
2
GND
VCC
DVDD
C20
0.1μF
C6
10μF
C19
0.1μF
C18
0.1μF
C17
0.1μF
W7
C16
0.1μF
J25
C12
0.1μF
1
GND
L6
82nH
Y1
3.3V
Q 7
6
Q
5
4
GND
GND
GND
R11
DVDD 49.9Ω
8
W8
R12
49.9Ω
CLK
R14
0Ω
R19
0Ω
GND
J2
GND
J3
GND
GND
J7
J6
CLKB
C40
22pF
1
GND
GND
MC100LVEL16DGOS
D
U3
NC
1
7
GND
C39
39pF
L1
68nH
C43
8.2pF
W2
C31
22pF
1
GND
L2
68nH
C30
39pF
GND
OUT GND
D
GND
C28
0.1μF
3
2
14
8
L3
68nH
C42
12pF
C38
47pF
GND
C41
2.2pF
GND
R8
2kΩ
GND
C5
47pF
L5
68nH
120MHz LOW-PASS FILTER
C37
27pF
GND
C4
27pF
L4
82nH
120MHz LOW-PASS FILTER
C32
C33
C34
2.2pF
12pF
8.2pF
GND
DVDD
C13
0.1μF
C26
0.1μF
C44
0.1μF
C2
0.01μF
W17
C14
0.1μF
GND
1
J8
J6
J11
J12
J13
J14
J21
J23
GND
R6
49.9Ω
GND
C8
0.1μF
C11
0.1μF
C27
0.1μF
R13
GND 49.9Ω
GND
W16
R7
GND 24.9Ω
W1
J4
W4
GND
1
J15
J16
J17
J18
J19
J20
J22
J24
GND
R1
49.9Ω
C10
0.1μF
C22
0.1μF
C9
0.1μF
C23
0.1μF
R5
49.9Ω
R9
100Ω
GND
R10
100Ω
J5
GND
W10
GND
AVDD
GND
C29
0.1μF
C24
0.1μF
C7
0.1μF
DVDD
C25
10μF
AVDD
VCC
C21
10μF
AVDD
GND
GND
TB1
J26
J1
GND
GND
GND
GND
R3
AVDD 24.9Ω
GND
AVDD
R2
3.92kΩ
R20
3.92kΩ
AVDD
AVDD C45
0.01μF
W6
GND
NC = NO CONNECT
GND 41
VINP 42
VINN 43
COMPVDD 44
COMPGND 45
GND2 46
AGND 47
IOUT1 48
IOUT1 49
AVDD 50
IOUT2 51
IOUT2 52
AGND2 53
AVDD2 54
DACBYPASS 55
RSET 56
NC3 57
NC4 58
AVDD
R4
C1
1.3kΩ 0.01μF
GND
DVDD
PLLVDD 60
W3
PLLGND 59
21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40
DVDD5
DVDD
GND
DGND2
DVDD1
DGND6
DGND3
GND
D0
DVDD
DVDD7
DGND4
GND
12
2
D6
DVDD6
DGND5
GND
D1
CLK
AVDD
D2
CLK8
REFCLK
DACDGND
GND
D3
DVDD
DVDD8
RD
GND4
DACDGND2
GND
GND
DVDD2
1
D7
AVDD
D4
GND
AVDD
D5
RESET
OSK
D7
D6
D5
D4
D3
D2
D1
D0
ADR5
ADR4
ADR3
ADR2
ADR1
ADR0
UDCLK
WR
RD
PMODE
OSK
RESET
GND
D6
GND
GND
D7
GND
CLKGND
80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61
DGND9
DVDD3
OPTGND
FSK/BPSK/HOLD
NC5
COUTVDD2
MRESET
OSK
DVDD9
WR
DIFFCLKEN
COUTVDD
PLLFLT
COUTGND2
REFCLK
DACDVDD2
GND3
COUTGND
SPSELECT
DACDVDD
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
VEE
AVDD
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
VCC
Rev. E | Page 46 of 52
VBB
Figure 61. Evaluation Board Schematic
00634-065
GND
GND
AD9852
Figure 62. Evaluation Board Schematic
Rev. E | Page 47 of 52
13
7
C3
B3
C2
C1
B4
B5
B7
B6
J11
36-PIN
CONNECTOR
GND:[19:30]
36
32
31
14
13
12
11
10
A6 9
A7
A5
A3
R17
10kΩ
VCC
R16
10kΩ
VCC
VCC
11
A4 6
R15
10kΩ
9
5
U5
5Y
4Y
3Y
2Y
1Y
7
VCC
VCC
13
11
9
5
3
1
13
11
9
5
3
1
U6
12
10
8
6
4
2
5Y
4Y
3Y
2Y
1Y
7
5Y
4Y
3Y
2Y
1Y
7
VCC GND
14
6Y
6A
74HC14
VCC GND
5A
4A
3A
2A
1A
U7
VCC GND
14
6Y
6A
74HC14
VCC GND
5A
4A
3A
2A
1A
VCC GND
14
VCC GND
6Y
6A
74HC14
5A
4A
3A
2A
1A
VCC
5
4
A2
A1
8
3
3
A0
1
1
1 2 3 4 5 6 7 8 9 10
RP1
10kΩ
2
C0
VCC
12
10
8
6
4
2
12
10
8
6
4
2
2
19
18
3
16
15
14
13
12
D7
D6
D5
D4
D3
D2
D1
D0
VCC: 20
GND: 10
17
1D
74HC574
8D
EN
C1
4
5
6
7
8
9
11
1
U8
VCC
13
11
9
5
3
1
U4
5Y
4Y
3Y
2Y
1Y
7
VCC GND
14
ADDR5
2
1
ADDR0
W14
GND
7
6
5
4
3
W11
1D
U2
4G
4A
4Y
3G
3A
3Y
VCC
19
74HC125D
GND
1A
1Y
2G
2A
2Y
1G
17
4
18
16
14
13
8
9
10
11
12
13
14
VCC
W9
W13
W12
RESET
RD
WR
GND: 10
12
5
3
GND
VCC: 20
15
10
12
U10
74HC574
8D
EN
C1
W15
6
7
8
9
11
1
2
ADDR1
ADDR2
ADDR3
ADDR4
8
6
4
2
18
3
6Y
6A
74HC14
VCC GND
5A
4A
3A
2A
1A
VCC
17
4
19
16
5
1D
15
6
2
14
7
12
VCC: 20
GND: 10
13
74HC574
8D
EN
C1
8
9
11
1
U9
R18
10kΩ
FDATA
ORAMP
PMODE
UDCLK
00634-066
VCC
AD9852
00634-067
AD9852
00634-068
Figure 63. Assembly Drawing
Figure 64. Top Routing Layer, Layer 1
Rev. E | Page 48 of 52
00634-070
AD9852
00634-069
Figure 65. Ground Plane Layer, Layer 2
Figure 66. Power Plane Layer, Layer 3
Rev. E | Page 49 of 52
00634-071
AD9852
Figure 67. Bottom Routing Layer, Layer 4
Rev. E | Page 50 of 52
AD9852
OUTLINE DIMENSIONS
16.20
16.00 SQ
15.80
0.75
0.60
0.45
14.20
14.00 SQ
13.80
1.20
MAX
80
61
1
61
60
80
1
60
PIN 1
EXPOSED
PAD
TOP VIEW
(PINS DOWN)
0° MIN
1.05
1.00
0.95
0.15
0.05
9.50 SQ
SEATING
PLANE
0.20
0.09
7°
3.5°
0°
0.08 MAX
COPLANARITY
20
41
21
40
BOTTOM VIEW
(PINS UP)
41
20
21
40
VIEW A
0.65 BSC
LEAD PITCH
0.27
0.22
0.17
VIEW A
091506-A
ROTATED 90° CCW
COMPLIANT TO JEDEC STANDARDS MS-026-AEC-HD
Figure 68. 80-Lead Thin Quad Flat Package, Exposed Pad [TQFP_EP]
(SV-80-4)
Dimensions shown in millimeters
0.75
0.60
0.45
16.20
16.00 SQ
15.80
1.60
MAX
61
80
60
1
PIN 1
14.20
14.00 SQ
13.80
TOP VIEW
(PINS DOWN)
0.15
0.05
SEATING
PLANE
VIEW A
0.20
0.09
7°
3.5°
0°
0.10
COPLANARITY
20
41
40
21
VIEW A
0.65
BSC
LEAD PITCH
ROTATED 90° CCW
0.38
0.32
0.22
COMPLIANT TO JEDEC STANDARDS MS-026-BEC
Figure 69. 80-Lead Low Profile Quad Flat Package [LQFP]
(ST-80-2)
Dimensions shown in millimeters
Rev. E | Page 51 of 52
051706-A
1.45
1.40
1.35
AD9852
ORDERING GUIDE
Model
AD9852ASVZ 1
AD9852AST
AD9852ASTZ1
AD9852/PCB
1
Temperature Range
–40°C to +85°C
–40°C to +85°C
–40°C to +85°C
Package Description
80-Lead Thin Quad Flat Package, Exposed Pad [TQFP_EP]
80-Lead Low Profile Quad Flat Package [LQFP]
80-Lead Low Profile Quad Flat Package [LQFP]
Evaluation Board
Z = RoHS Compliant Part.
©2002–2007 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
C00634-0-5/07(E)
Rev. E | Page 52 of 52
Package Option
SV-80-4
ST-80-2
ST-80-2