AD AD9953YSV

400 MSPS, 14-Bit, 1.8 V CMOS
Direct Digital Synthesizer
AD9953
FEATURES
PLL REFCLK multiplier (4× to 20×)
Internal oscillator, can be driven by a single crystal
Phase modulation capability
Multichip synchronization
400 MSPS internal clock speed
Integrated 14-bit DAC
32-bit tuning word
Phase noise ≤ –120 dBc/Hz @ 1 kHz offset (DAC output)
Excellent dynamic performance
>80 dB SFDR @ 160 MHz (±100 kHz offset) AOUT
Serial I/O control
1.8 V power supply
Software and hardware controlled power-down
48-lead TQFP/EP package
Support for 5 V input levels on most digital inputs
APPLICATIONS
Agile VHF/UHF LO frequency synthesis
FM chirp source for radar and scanning systems
Nonlinear-shaped PSK/FSK modulator
Test and measurement equipment
FUNCTIONAL BLOCK DIAGRAM
DDS CORE
19
PHASE
ACCUMULATOR
RESET
FREQUENCY
TUNING WORD
32
10
14
COS(X)
14
Z–1
DAC
IOUT
IOUT
SYSTEM
CLOCK
MUX
14
14
RAM DATA <31:18>
SYNC_IN
PHASE
OFFSET
WORD
OSK
TIMING AND CONTROL LOGIC
I/O UPDATE
SYNC_CLK
DAC_RSET
PHASE
OFFSET
Z–1
DDS CLOCK
3
32
M
U
X
32
DDS CLOCK
RAM CONTROL
RAM ADDRESS
RAM DATA
1024 × 32
STATIC RAM
AD9953
PHASE
ACCUMULATOR
RAM
DATA
PWRDWNCTL
0
M
U
X
SYNC
CONTROL REGISTERS
÷4
OSCILLATOR/BUFFER
4×–20×
CLOCK
MULTIPLIER
REFCLK
REFCLK
M
U
X
SYSTEM
CLOCK
CRYSTAL OUT
03357-0-001
ENABLE
PS<1:0>
I/O PORT
RESET
Figure 1.
Rev. A
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.
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Tel: 781.329.4700
www.analog.com
Fax: 781.461.3113 ©2004–2009 Analog Devices, Inc. All rights reserved.
AD9953
TABLE OF CONTENTS
Features .............................................................................................. 1 Component Blocks ..................................................................... 12 Applications ....................................................................................... 1 Modes of Operation ................................................................... 19 Revision History ............................................................................... 2 Programming AD9953 Features .............................................. 22 General Description ......................................................................... 3 Serial Port Operation ................................................................. 25 Electrical Specifications ................................................................... 4 Instruction Byte .......................................................................... 27 Absolute Maximum Ratings............................................................ 6 Serial Interface Port Pin Description ....................................... 27 ESD Caution .................................................................................. 6 MSB/LSB Transfers .................................................................... 27 Pin Configuration ............................................................................. 7 Suggested Application Circuits ..................................................... 29 Pin Function Descriptions .............................................................. 8 Outline Dimensions ....................................................................... 30 Typical Performance Characteristics ............................................. 9 Ordering Guide .......................................................................... 30 Theory of Operation ...................................................................... 12 REVISION HISTORY
5/09—Rev. 0 to Rev. A
Changes to Absolute Maximum Ratings Section ......................... 6
Changes to Table 3 ............................................................................ 8
Changes to Table 5 .......................................................................... 14
Changes to Figure 22 ...................................................................... 25
Changes to Serial Port Operation Section................................... 25
Changes to Serial Interface Port Pin Description Section ........ 27
Changes to Figure 29 ...................................................................... 29
Updated Outline Dimensions ....................................................... 30
Changes to Ordering Guide .......................................................... 30
1/04—Revision 0: Initial Version
Rev. A | Page 2 of 32
AD9953
GENERAL DESCRIPTION
The AD9953 is a direct digital synthesizer (DDS) featuring a
14-bit DAC operating up to 400 MSPS. The AD9953 uses
advanced DDS technology, coupled with an internal high speed,
high performance DAC to form a digitally programmable,
complete high frequency synthesizer capable of generating a
frequency-agile analog output sinusoidal waveform at up to
200 MHz. The AD9953 includes an integrated 1024 × 32 static
RAM to support flexible frequency sweep capability in several
modes. The AD9953 is designed to provide fast frequency
hopping and fine tuning resolution (32-bit frequency tuning
word). The frequency tuning and control words are loaded into
the AD9953 via a serial I/O port.
The AD9953 is specified to operate over the extended industrial
temperature range of –40°C to +105°C.
Rev. A | Page 3 of 32
AD9953
ELECTRICAL SPECIFICATIONS
Table 1. Unless otherwise noted, AVDD, DVDD = 1.8 V ± 5%, DVDD_I/O = 3.3 V ± 5%, RSET = 3.92 kΩ, External Reference Clock
Frequency = 20 MHz with REFCLK Multiplier Enabled at 20×. DAC Output Must Be Referenced to AVDD, Not AGND.
Parameter
REF CLOCK INPUT CHARACTERISTICS
Frequency Range
REFCLK Multiplier Disabled
REFCLK Multiplier Enabled at 4×
REFCLK Multiplier Enabled at 20×
Input Capacitance
Input Impedance
Duty Cycle
Duty Cycle with REFCLK Multiplier Enabled
REFCLK Input Power 1
DAC OUTPUT CHARACTERISTICS
Resolution
Full-Scale Output Current
Gain Error
Output Offset
Differential Nonlinearity
Integral Nonlinearity
Output Capacitance
Residual Phase Noise @ 1 kHz Offset, 40 MHz AOUT
REFCLK Multiplier Enabled @ 20×
REFCLK Multiplier Enabled @ 4×
REFCLK Multiplier Disabled
Voltage Compliance Range
Wideband SFDR
1 MHz to 10 MHz Analog Out
10 MHz to 40 MHz Analog Out
40 MHz to 80 MHz Analog Out
80 MHz to 120 MHz Analog Out
120 MHz to 160 MHz Analog Out
Narrow-Band SFDR
40 MHz Analog Out (±1 MHz)
40 MHz Analog Out (±250 kHz)
40 MHz Analog Out (±50 kHz)
40 MHz Analog Out (±10 kHz)
80 MHz Analog Out (±1 MHz)
80 MHz Analog Out (±250 kHz)
80 MHz Analog Out (±50 kHz)
80 MHz Analog Out (±10 kHz)
120 MHz Analog Out (±1 MHz)
120 MHz Analog Out (±250 kHz)
120 MHz Analog Out (±50 kHz)
120 MHz Analog Out (±10 kHz)
160 MHz Analog Out (±1 MHz)
160 MHz Analog Out (±250 kHz)
160 MHz Analog Out (±50 kHz)
160 MHz Analog Out (±10 kHz)
Temp
Min
FULL
FULL
FULL
25°C
25°C
25°C
25°C
FULL
1
20
4
25°C
25°C
25°C
25°C
25°C
25°C
25°C
25°C
25°C
25°C
Typ
Max
Unit
400
100
20
MHz
MHz
MHz
pF
kΩ
%
%
dBm
3
1.5
50
35
–15
5
–10
0
14
10
65
+3
15
+10
0.6
1
2
5
–105
–115
–132
AVDD – 0.5
AVDD + 0.5
Bits
mA
%FS
μA
LSB
LSB
pF
dBc/Hz
dBc/Hz
dBc/Hz
V
25°C
25°C
25°C
25°C
25°C
73
67
62
58
52
dBc
dBc
dBc
dBc
dBc
25°C
25°C
25°C
25°C
25°C
25°C
25°C
25°C
25°C
25°C
25°C
25°C
25°C
25°C
25°C
25°C
87
89
91
93
85
87
89
91
83
85
87
89
81
83
85
87
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
Rev. A | Page 4 of 32
AD9953
Parameter
TIMING CHARACTERISTICS
Serial Control Bus
Maximum Frequency
Minimum Clock Pulse Width Low
Minimum Clock Pulse Width High
Maximum Clock Rise/Fall Time
Minimum Data Setup Time DVDD_I/O = 3.3 V
Minimum Data Setup Time DVDD_I/O = 1.8 V
Minimum Data Hold Time
Maximum Data Valid Time
Wake-Up Time 2
Minimum Reset Pulse Width High
I/O UPDATE (PS0/PS1) to SYNC_CLK Setup Time DVDD_I/O = 3.3 V
I/O UPDATE (PS0/PS1) to SYNC_CLK Setup Time DVDD_I/O = 1.8 V
I/O UPDATE (PS0/PS1), SYNC_CLK Hold Time
Latency
I/O UPDATE (PS0/PS1) to Frequency Change Prop Delay
I/O UPDATE (PS0/PS1) to Phase Offset Change Prop Delay
I/O UPDATE (PS0/PS1) to Amplitude Change Prop Delay
CMOS LOGIC INPUTS
Logic 1 Voltage @ DVDD_I/O (Pin 43) = 1.8 V
Logic 0 Voltage @ DVDD_I/O (Pin 43) = 1.8 V
Logic 1 Voltage @ DVDD_I/O (Pin 43) = 3.3 V
Logic 0 Voltage @ DVDD_I/O (Pin 43) = 3.3 V
Logic 1 Current
Logic 0 Current
Input Capacitance
CMOS LOGIC OUTPUTS (1 mA Load) DVDD_I/O = 1.8 V
Logic 1 Voltage
Logic 0 Voltage
CMOS LOGIC OUTPUTS (1 mA Load) DVDD_I/O = 3.3 V
Logic 1 Voltage
Logic 0 Voltage
POWER CONSUMPTION (AVDD = DVDD = 1.8 V)
Single-Tone Mode
Rapid Power-Down Mode
Full-Sleep Mode
SYNCHRONIZATION FUNCTION 4
Maximum SYNC Clock Rate (DVDD_I/O = 1.8 V)
Maximum SYNC Clock Rate (DVDD_I/O = 3.3 V)
SYNC_CLK Alignment Resolution 5
Temp
Min
Typ
Max
25
Unit
FULL
FULL
FULL
FULL
FULL
FULL
FULL
FULL
FULL
FULL
FULL
FULL
FULL
5
4
6
0
Mbps
ns
ns
ns
ns
ns
ns
ns
ms
SYSCLK Cycles 3
ns
ns
ns
25°C
25°C
25°C
24
24
16
SYSCLK Cycles
SYSCLK Cycles
SYSCLK Cycles
25°C
25°C
25°C
25°C
25°C
25°C
25°C
1.25
25°C
25°C
1.35
25°C
25°C
2.8
7
7
2
3
5
0
25
1
0.6
2.2
3
2
25°C
25°C
25°C
25°C
25°C
25°C
1
0.8
12
12
162
150
20
62.5
100
±1
V
V
V
V
μA
μA
pF
0.4
V
V
0.4
V
V
171
160
27
mW
mW
mW
MHz
MHz
SYSCLK Cycles
To achieve the best possible phase noise, the largest amplitude clock possible should be used. Reducing the clock input amplitude will reduce the phase noise
performance of the device.
2
Wake-up time refers to the recovery from analog power-down modes (see the Power-Down Functions of the AD9953 section). The longest time required is for the
reference clock multiplier PLL to relock to the reference. The wake-up time assumes there is no capacitor on DACBP and that the recommended PLL loop filter values
are used.
3
SYSCLK cycle refers to the actual clock frequency used on-chip by the DDS. If the reference clock multiplier is used to multiply the external reference clock frequency,
the SYSCLK frequency is the external frequency multiplied by the reference clock multiplication factor. If the reference clock multiplier is not used, the SYSCLK
frequency is the same as the external reference clock frequency.
4
SYNC_CLK = ¼ SYSCLK rate. For SYNC_CLK rates ≥ 50 MHz, the high speed sync enable bit, CFR2<11>, should be set.
5
This parameter indicates that the digital synchronization feature cannot overcome phase delays (timing skew) between system clock rising edges. If the system clock
edges are aligned, the synchronization function should not increase the skew between the two edges.
Rev. A | Page 5 of 32
AD9953
ABSOLUTE MAXIMUM RATINGS
Table 2.
Rating
150°C
4V
2V
–0.7 V to +5.25 V
–0.7 V to +2.2 V
5 mA
–65°C to +150°C
–40°C to +105°C
300°C
38°C/W
15°C/W
DIGITAL
INPUTS
ESD CAUTION
DAC OUTPUTS
DVDD_I/O
IOUT
IOUT
INPUT
AVOID OVERDRIVING
DIGITAL INPUTS.
FORWARD BIASING
ESD DIODES MAY
COUPLE DIGITAL NOISE
ONTO POWER PINS.
MUST TERMINATE
OUTPUTS TO AVDD. DO
NOT EXCEED THE
OUTPUT VOLTAGE
COMPLIANCE RATING.
Figure 2. Equivalent Input and Output Circuits
Rev. A | Page 6 of 32
03374-0-032
Parameter
Maximum Junction Temperature
DVDD_I/O (Pin 43)
AVDD, DVDD
Digital Input Voltage (DVDD_I/O = 3.3 V)
Digital Input Voltage (DVDD_I/O = 1.8 V)
Digital Output Current
Storage Temperature
Operating Temperature
Lead Temperature (10 sec Soldering)
θJA
θJC
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.
AD9953
PS0
OSK
SYNC_CLK
SYNC_IN
DVDD_I/O
DGND
SDIO
SCLK
CS
SDO
IOSYNC
48
47
46
45
44
43
42
41
40
39
38
37
I/O UPDATE
1
36
RESET
DVDD
2
35
PWRDWNCTL
DGND
3
34
DVDD
AVDD
4
33
DGND
AGND
5
32
AGND
AVDD
6
31
AGND
AGND
7
30
AGND
OSC/REFCLK
8
29
AVDD
OSC/REFCLK
9
28
AGND
CRYSTAL OUT 10
27
AVDD
CLKMODESELECT 11
26
AGND
LOOP_FILTER 12
25
AVDD
AD9953
13
14
15
16
17
18
19
20
21
22
23
24
AVDD
AGND
AGND
AVDD
AGND
AVDD
AVDD
IOUT
IOUT
AGND
DACBP
DAC_RSET
TOP VIEW
(Not to Scale)
03357-0-002
PS1
PIN CONFIGURATION
Figure 3. 48-Lead TQFP/EP
Note that the exposed paddle on the bottom of the package forms an electrical connection for the DAC and must be attached to
analog ground. Note that Pin 43, DVDD_I/O, can be powered to 1.8 V or 3.3 V; however, the DVDD pins (Pin 2 and Pin 34) can
only be powered to 1.8 V.
Rev. A | Page 7 of 32
AD9953
PIN FUNCTION DESCRIPTIONS
Table 3. 48-Lead TQFP/EP
Pin No.
1
Mnemonic
I/O UPDATE
I/O
I
2, 34
3, 33, 42
4, 6, 13,
16, 18, 19,
25, 27, 29
5, 7, 14,
15, 17, 22,
26, 32
8
DVDD
DGND
AVDD
I
I
I
Description
The rising edge transfers the contents of the internal buffer memory to the I/O registers. This pin
must be set up and held around the SYNC_CLK output signal.
Digital Power Supply Pins (1.8 V).
Digital Power Ground Pins.
Analog Power Supply Pins (1.8 V).
AGND
I
Analog Power Ground Pins.
OSC/REFCLK
I
9
OSC/REFCLK
I
10
11
CRYSTAL OUT
CLKMODESELECT
O
I
12
LOOP_FILTER
I
20
21
23
24
IOUT
IOUT
DACBP
DAC_RSET
O
O
I
I
35
36
PWRDWNCTL
RESET
I
I
37
IOSYNC
I
38
SDO
O
39
40
41
CS
SCLK
SDIO
I
I
I/O
43
44
DVDD_I/O
SYNC_IN
I
I
45
46
SYNC_CLK
OSK
O
I
47, 48
PS0, PS1
I
<49>
AGND
I
Complementary Reference Clock/Oscillator Input. When the REFCLK port is operated in singleended mode, REFCLK should be decoupled to AVDD with a 0.1 μF capacitor.
Reference Clock/Oscillator Input. See Clock Input section for details on the OSCILLATOR/REFCLK
operation.
Output of the Oscillator Section.
Control Pin for the Oscillator Section. When high, the oscillator section is enabled. When low, the
oscillator section is bypassed.
This pin provides the connection for the external zero compensation network of the REFCLK
multiplier’s PLL loop filter. The network consists of a 1 kΩ resistor in series with a 0.1 μF capacitor
tied to AVDD.
Complementary DAC Output. Should be biased through a resistor to AVDD, not AGND.
DAC Output. Should be biased through a resistor to AVDD, not AGND.
DAC Biasline Decoupling Pin. A 0.1 μF capacitor to AGND is recommended.
A resistor (3.92 kΩ nominal) connected from AGND to DAC_RSET establishes the reference current
for the DAC.
Input Pin Used as an External Power-Down Control (see Table 10 for details).
Active High Hardware Reset Pin. Assertion of the RESET pin forces the AD9953 to the initial state,
as described in the I/O port register map.
Asynchronous Active High Reset of the Serial Port Controller. When high, the current I/O
operation is immediately terminated, enabling a new I/O operation to commence once IOSYNC is
returned low. If unused, ground this pin; do not allow this pin to float.
When operating the I/O port as a 3-wire serial port, this pin serves as the serial data output. When
operated as a 2-wire serial port, this pin is unused and can be left unconnected.
This pin functions as an active low chip select that allows multiple devices to share the I/O bus.
This pin functions as the serial data clock for I/O operations.
When operating the I/O port as a 3-wire serial port, this pin serves as the serial data input only.
When operated as a 2-wire serial port, this pin is the bidirectional serial data pin.
Digital Power Supply (for I/O Cells Only, 3.3 V).
Input Signal Used to Synchronize Multiple AD9953s. This input is connected to the SYNC_CLK
output of a master AD9953.
Clock Output Pin that Serves as a Synchronizer for External Hardware.
Input Pin Used to Control the Direction of the Shaped On-Off Keying Function when Programmed
for Operation. OSK is synchronous to the SYNC_CLK pin. When OSK is not programmed, this pin
should be tied to DGND.
Input pin used to select one of the four internal profiles. Profile <1:0> are synchronous to the
SYNC_CLK pin. Any change in these inputs transfers the contents of the internal buffer memory
to the I/O registers (sends an internal I/O UPDATE).
The exposed paddle on the bottom of the package is a ground connection for the DAC and must
be attached to AGND in any board layout.
Rev. A | Page 8 of 32
AD9953
TYPICAL PERFORMANCE CHARACTERISTICS
REF 0dBm
0
PEAK
1R
LOG
–10
10dB/
MKR1 98.0MHz
–70.68dB
ATTEN 10dB
REF 0dBm
0
PEAK
LOG
–10
10dB/
–20
–30
MARKER
100.000000MHz
–70.68dB
–50
–60
W1 S2
S3 FC –70
AA
–80
–60
W1 S2
S3 FC –70
AA
–80
03374-0-016
1
–90
–100
CENTER 100MHz
#RES BW 3kHz
VBW 3kHz
–90
–100
SPAN 200MHz
SWEEP 55.56 s (401 PTS)
CENTER 100MHz
#RES BW 3kHz
Figure 4. FOUT = 1 MHz FCLK = 400 MSPS, WBSFDR
REF 0dBm
0
PEAK
1R
LOG
–10
10dB/
REF 0dBm
0
PEAK
LOG
–10
10dB/
–20
–20
–30
–30
MARKER
80.000000MHz
–69.12dB
–40
–50
–50
–60
03374-0-017
1
–90
CENTER 100MHz
#RES BW 3kHz
VBW 3kHz
ATTEN 10dB
1R
1
–90
–100
SPAN 200MHz
SWEEP 55.56 s (401 PTS)
CENTER 100MHz
#RES BW 3kHz
Figure 5. FOUT = 10 MHz, FCLK = 400 MSPS, WBSFDR
REF 0dBm
0
PEAK
LOG
10dB/ –10
MKR1 40.0MHz
–56.2dB
ATTEN 10dB
–60
W1 S2
S3 FC –70
AA
–80
–100
SPAN 200MHz
SWEEP 55.56 s (401 PTS)
MARKER
40.000000MHz
–56.2dB
–40
W1 S2
S3 FC –70
AA
–80
VBW 3kHz
Figure 7. FOUT = 80 MHz FCLK = 400 MSPS, WBSFDR
MKR1 80.0MHz
–69.12dB
ATTEN 10dB
1
03374-0-019
–50
MARKER
80.000000MHz
–61.55dB
–40
03374-0-020
–40
VBW 3kHz
SPAN 200MHz
SWEEP 55.56 s (401 PTS)
Figure 8. FOUT = 120 MHz, FCLK = 400 MSPS, WBSFDR
MKR1 0Hz
–68.44dB
REF 0dBm
0
PEAK
LOG
10dB/ –10
1R
–20
ATTEN 10dB
MKR1 0Hz
–53.17dB
1R
–20
–30
–50
1R
–20
–30
–40
MKR1 80.0MHz
–61.55dB
ATTEN 10dB
–30
MARKER
40.000000MHz
–68.44dB
–40
–50
MARKER
80.000000MHz
–53.17dB
1
–60
–60
W1 S2
S3 FC –70
AA
–80
03374-0-018
1
–90
–100
CENTER 100MHz
#RES BW 3kHz
VBW 3kHz
SPAN 200MHz
SWEEP 55.56 s (401 PTS)
03374-0-021
W1 S2
S3 FC –70
AA
–80
–90
–100
CENTER 100MHz
#RES BW 3kHz
Figure 6. FOUT = 40 MHz, FCLK = 400 MSPS, WBSFDR
VBW 3kHz
SPAN 200MHz
SWEEP 55.56 s (401 PTS)
Figure 9. FOUT = 160 MHz, FCLK = 400 MSPS, WBSFDR
Rev. A | Page 9 of 32
AD9953
REF –4dBm
0
PEAK
LOG
–10
10dB/
ATTEN 10dB
1
MKR1 1.105MHz
–5.679dBm
REF –4dBm
0
PEAK
LOG
–10
10dB/
–20
–20
–30
–30
MARKER
1.105000MHz
–5.679dBm
–40
–50
–40
–50
03374-0-022
–90
ST
–100
CENTER 1.105MHz
#RES BW 30Hz
VBW 30Hz
SPAN 2MHz
SWEEP 199.2 s (401 PTS)
–90
ST
–100
SPAN 2MHz
SWEEP 199.2 s (401 PTS)
CENTER 80.25MHz
#RES BW 30Hz
Figure 10. FOUT = 1.1 MHz, FCLK = 400 MSPS, NBSFDR, ±1 MHz
REF 0dBm
0
PEAK
LOG
10dB/ –10
Figure 13. FOUT = 80.3 MHz, FCLK = 400 MSPS, NBSFDR, ±1 MHz
MKR1 85kHz
–93.01dB
ATTEN 10dB
REF –4dBm
0
PEAK
LOG
10dB/ –10
1R
–20
–20
–30
–30
MARKER
40.000000MHz
–56.2dB
–40
–50
–40
–50
ATTEN 10dB
1
MKR1 120.205MHz
–6.825dBm
MARKER
120.205000MHz
–6.825dBm
–90
1
–100
CENTER 10MHz
#RES BW 30Hz
VBW 30Hz
–90
ST
–100
SPAN 2MHz
SWEEP 199.2 s (401 PTS)
CENTER 120.2MHz
#RES BW 30Hz
Figure 11. FOUT = 10 MHz, FCLK = 400 MSPS, NBSFDR, ±1 MHz
REF 0dBm
0
PEAK
LOG
10dB/ –10
VBW 30Hz
SPAN 2MHz
SWEEP 199.2 s (401 PTS)
Figure 14. FOUT = 120.2 MHz, FCLK = 400 MSPS, NBSFDR, ±1 MHz
MKR1 39.905MHz
–5.347dBm
ATTEN 10dB
03374-0-026
–60
W1 S2
S3 FC –70
AA
–80
03374-0-023
–60
W1 S2
S3 FC –70
AA
–80
REF –4dBm
0
PEAK
LOG
10dB/ –10
1
–20
ATTEN 10dB
1
MKR1 600kHz
–0.911dB
–20
–30
–30
MARKER
39.905000MHz
–5.347dBm
–40
CENTER
160.5000000MHz
–50
–60
W1 S2
S3 FC –70
AA
–80
03374-0-024
–60
W1 S2
S3 FC –70
AA
–80
–90
–100
CENTER 39.9MHz
#RES BW 30Hz
VBW 30Hz
SPAN 2MHz
SWEEP 199.2 s (401 PTS)
03374-0-027
–50
VBW 30Hz
MARKER
80.301000MHz
–6.318dBm
–60
W1 S2
S3 FC –70
AA
–80
W1 S2
S3 FC –70
AA
–80
–40
MKR1 80.301MHz
–6.318dBm
03374-0-025
–60
1
ATTEN 10dB
–90
ST
–100
CENTER 160.5MHz
#RES BW 30Hz
Figure 12. FOUT = 39.9 MHz, FCLK = 400 MSPS, NBSFDR, ±1 MHz
VBW 30Hz
SPAN 2MHz
SWEEP 199.2 s (401 PTS)
Figure 15. FOUT = 160 MHz, FCLK = 400 MSPS, NBSFDR, ±1 MHz
Rev. A | Page 10 of 32
AD9953
Figure 16. Residual Phase Noise with FOUT = 159.5 MHz, FCLK = 400 MSPS
(Green), 4 × 100 MSPS (Red), and 20 × 20 MSPS (Blue)
Figure 18. Residual Phase Noise with FOUT = 9.5 MHz, FCLK = 400 MSPS (Green),
4 ×100 MSPS (Red), and 20 × 20 MSPS (Blue)
t1 = 3.156ns
t2 = 3.04ns
Δt = –116.0PS
1/Δt = –8.621GHz
FALL (R1) = 396.4PS
RISE(R2) = 464.3PS
R1
R2
CH1 200mVΩ
M 200PS 20.0GS/S
A CH1
708mV
03374-0-030
03374-0-031
1
IT 4.0PS/PT 3.1ns
REF2 200mV 500ns
Figure 17. Residual Peak-to-Peak Jitter of DDS
and Comparator Operating Together at 160 MHz
M 500PS 20.0GS/S IT 10.0PS/PT –100PS
A CH1
708mV
Figure 19. Comparator Rise and Fall Time at 160 MHz
Rev. A | Page 11 of 32
AD9953
THEORY OF OPERATION
COMPONENT BLOCKS
DDS Core
Clock Input
The output frequency (fO) of the DDS is a function of the
frequency of the system clock (SYSCLK), the value of the
frequency tuning word (FTW), and the capacity of the
accumulator (232, in this case). The exact relationship is given
below with fS defined as the frequency of SYSCLK.
The AD9953 supports various clock methodologies. Support for
differential or single-ended input clocks and enabling of an onchip oscillator and/or a phase-locked loop (PLL) multiplier is all
controlled via user programmable bits. The AD9953 may be
configured in one of six operating modes to generate the system
clock. The modes are configured using the CLKMODESELECT
pin, CFR1<4>, and CFR2<7:3>. Connecting the external pin
CLKMODESELECT to Logic High enables the on-chip crystal
oscillator circuit. With the on-chip oscillator enabled, users of
the AD9953 connect an external crystal to the REFCLK and
REFCLKB inputs to produce a low frequency reference clock in
the range of 20 MHz to 30 MHz. The signal generated by the
oscillator is buffered before it is delivered to the rest of the chip.
This buffered signal is available via the CRYSTAL OUT pin. Bit
CFR1<4> can be used to enable or disable the buffer, turning on
or off the system clock. The oscillator itself is not powered
down in order to avoid long start-up times associated with
turning on a crystal oscillator. Writing CFR2<9> to Logic High
enables the crystal oscillator output buffer. Logic Low at
CFR2<9> disables the oscillator output buffer.
f O  FTW  f S / 2 32 with 0  FTW  2 31
f O  f S  1 – FTW / 2 32  with 2 31  FTW  2 32 – 1
The value at the output of the phase accumulator is translated to
an amplitude value via the COS(x) functional block and routed
to the DAC.
In certain applications, it is desirable to force the output signal
to zero phase. Simply setting the FTW to 0 does not accomplish
this; it only results in the DDS core holding its current phase
value. Thus, a control bit is required to force the phase
accumulator output to zero.
At power-up, the clear phase accumulator bit is set to Logic 1,
but the buffer memory for this bit is cleared (Logic 0).
Therefore, upon power-up, the phase accumulator will remain
clear until the first I/O UPDATE is issued.
Phase-Locked Loop (PLL)
The PLL allows multiplication of the REFCLK frequency.
Control of the PLL is accomplished by programming the 5-bit
REFCLK multiplier portion of Control Function Register No. 2,
Bits <7:3>.
When programmed for values ranging from 0x04 to 0x14
(4 decimal to 20 decimal), the PLL multiplies the REFCLK
input frequency by the corresponding decimal value. However,
the maximum output frequency of the PLL is restricted to
400 MHz. Whenever the PLL value is changed, the user should
be aware that time must be allocated to allow the PLL to lock
(approximately 1 ms).
Connecting CLKMODESELECT to Logic Low disables the
on-chip oscillator and the oscillator output buffer. With the
oscillator disabled, an external oscillator must provide the
REFCLK and/or REFCLKB signals. For differential operation,
these pins are driven with complementary signals. For singleended operation, a 0.1 μF capacitor should be connected
between the unused pin and the analog power supply. With the
capacitor in place, the clock input pin bias voltage is 1.35 V. In
addition, the PLL may be used to multiply the reference
frequency by an integer value in the range of 4 to 20. Table 4
summarizes the clock modes of operation. Note that the PLL
multiplier is controlled via the CFR2<7:3> bits, independent of
the CFR1<4> bit.
The PLL is bypassed by programming a value outside the range
of 4 to 20 (decimal). When bypassed, the PLL is shut down to
conserve power.
Table 4. Clock Input Modes of Operation
CFR1<4>
Low
Low
Low
Low
High
CLKMODESELECT
High
High
Low
Low
X
CFR2<7:3>
3 < M < 21
M < 4 or M > 20
3 < M < 21
M < 4 or M > 20
X
Oscillator Enabled?
Yes
Yes
No
No
No
Rev. A | Page 12 of 32
System Clock
FCLK = FOSC × M
FCLK = FOSC
FCLK = FOSC × M
FCLK = FOSC
FCLK = 0
Frequency Range (MHz)
80 < FCLK < 400
20 < FCLK < 30
80 < FCLK < 400
10 < FCLK < 400
N/A
AD9953
DAC Output
Serial IO Port
The AD9953 incorporates an integrated 14-bit current output
DAC. Unlike most DACs, this output is referenced to AVDD,
not AGND.
The AD9953 serial port is a flexible, synchronous serial
communications port that allows easy interface to many industrystandard microcontrollers and microprocessors. The serial I/O port
is compatible with most synchronous transfer formats, including
both the Motorola 6905/11 SPI® and Intel® 8051 SSR protocols.
Two complementary outputs provide a combined full-scale
output current (IOUT). Differential outputs reduce the amount of
common-mode noise that might be present at the DAC output,
offering the advantage of an increased signal-to-noise ratio. The
full-scale current is controlled by an external resistor (RSET)
connected between the DAC_RSET pin and the DAC ground
(AGND_DAC). The full-scale current is proportional to the
resistor value as follows:
RSET = 39.19 / IOUT
The maximum full-scale output current of the combined DAC
outputs is 15 mA, but limiting the output to 10 mA provides the
best spurious-free dynamic range (SFDR) performance. The DAC
output compliance range is AVDD + 0.5 V to AVDD – 0.5 V.
Voltages developed beyond this range will cause excessive DAC
distortion and could potentially damage the DAC output circuitry.
Proper attention should be paid to the load termination to keep the
output voltage within this compliance range.
The interface allows read/write access to all registers that configure
the AD9953. MSB first or LSB first transfer formats are supported.
The AD9953’s serial interface port can be configured as a single pin
I/O (SDIO), which allows a 2-wire interface or two unidirectional
pins for in/out (SDIO/SDO), which in turn enables a 3-wire
interface. Two optional pins, IOSYNC and CS, enable greater
flexibility for system design in the AD9953.
Register Map and Descriptions
The register map is listed in Table 5.
Rev. A | Page 13 of 32
AD9953
Table 5. Register Map
Register
Name
(Serial
Address)
Bit
Range
<7:0>
Control
Function
Register
No.1
(CFR1)
(0x00)
<15:8>
<23:16>
<31:24>
Control
Function
Register
No. 2 (CFR2)
(0x01)
Amplitude
Scale Factor
(ASF)
(0x02)
Amplitude
Ramp Rate
(ARR)
(0x03)
Frequency
Tuning
Word
(FTW0)
(0x04)
Phase
Offset Word
(POW0)
(0x05)
Frequency
Tuning
Word
(FTW1)
(0x06)
<7:0>
<15:8>
<23:16>
<7:0>
<15:8>
(MSB)
Bit 7
Digital
PowerDown
Bit 6
Comp
PowerDown
Bit 5
Bit 4
DAC
PowerDown
Clock Input
PowerDown
Bit 3
External
PowerDown
Mode
Clear
Freq.
Accum.
Bit 1
Linear
Sweep No
Dwell
SYNC_CLK
Out
Disable
Not
Used
SDIO
Input
Only
LSB First
Not Used
Not
Used
OSK
Enable
Auto
OSK
Keying
AutoClr
AutoClr
Enable
Clear
Freq.
Phase
SINE
Phase
Accum.
Accum.
Output
Accum.
Software
Automatic
Linear
Not Used
Not Used
Not Used
Sync
Manual
Sweep
Enable
Sync
Enable
RAM
RAM
Dest. Is
Load ARR
Internal Profile Control <2:0>
Phase
Enable
@ I/O UD
Word
REFCLK Multiplier
VCO Range
0x00 or 0x01, or 0x02 or 0x03: Bypass Multiplier
0x04 to 0x14: 4× to 20× Multiplication
High
Hardware
Speed
Manual
Not Used
Sync
Sync
Enable
Enable
Not Used
Amplitude Scale Factor Register <7:0>
Load SRR
@ I/O UD
Auto Ramp Rate Speed
Control <1:0>
(LSB)
Bit 0
Bit 2
0x00
Charge Pump Current
<1:0>
CRYSTAL
OUT Pin
Active
Default
Value
OR
Profile
0x00
0x00
0x00
0x00
0x00
Not
Used
0x18
0x00
0x00
Amplitude Scale Factor Register <13:8>
0x00
<7:0>
Amplitude Ramp Rate Register <7:0>
<7:0>
<15:8>
<23:16>
Frequency Tuning Word No. 0 <7:0>
Frequency Tuning Word No. 0 <15:8>
Frequency Tuning Word No. 0 <23:16>
<31:24>
Frequency Tuning Word No. 0 <31:24>
<7:0>
Phase Offset Word No. 0 <7:0>
<15:8>
<7:0>
<15:8>
<23:16>
<31:24>
Not Used<1:0>
0x00
0x00
0x00
0x00
0x00
0x00
Phase Offset Word No. 0 <13:8>
Frequency Tuning Word No. 1 <7:0>
Frequency Tuning Word No. 1 <15:8>
Frequency Tuning Word No. 1 <23:16>
Frequency Tuning Word No. 1 <31:24>
Rev. A | Page 14 of 32
0x00
0x00
0x00
0x00
AD9953
Register
Name
(Serial
Address)
Bit
Range
<7:0>
RAM
Segment
Control
Word No. 0
(RSCW0)
(0x07)
<15:8>
<23:16>
<31:24>
<39:32>
<7:0>
RAM
Segment
Control
Word No. 1
(RSCW1)
(0x08)
<15:8>
<23:16>
<31:24>
<39:32>
<7:0>
RAM
Segment
Control
Word No. 2
(RSCW2)
(0x09)
<15:8>
<23:16>
<31:24>
<39:32>
<7:0>
RAM
Segment
Control
Word No. 3
(RSCW3)
(0x0A)
<15:8>
<23:16>
<31:24>
<39:32>
RAM (0x0B)
(MSB)
Bit 7
Bit 6
Bit 5
Bit 4
RAM Segment 0 Mode Control <2:0> No Dwell
Active
RAM Segment 0 Beginning Address <5:0>
(LSB)
Bit 3
Bit 2
Bit 1
Bit 0
RAM Segment 0 Beginning Address <9:6>
RAM Segment 0 Final Address <9:8>
RAM Segment 0 Final Address <7:0>
RAM Segment 0 Address Ramp Rate <15:8>
RAM Segment 0 Address Ramp Rate <7:0>
RAM Segment 1 Mode Control
No Dwell
<2:0>
Active
RAM Segment 1 Beginning Address <5:0>
RAM Segment 1 Beginning Address <9:6>
RAM Segment 1 Final Address <9:8>
RAM Segment 1 Final Address <7:0>
RAM Segment 1 Address Ramp Rate <15:8>
RAM Segment 1 Address Ramp Rate <7:0>
No Dwell Active
RAM Segment 2 Mode Control
RAM Segment 2 Beginning
Address <9:6>
<2:0>
RAM Segment 2 Beginning Address <5:0>
RAM Segment 2 Final Address <9:8>
RAM Segment 2 Final Address <7:0>
RAM Segment 2 Address Ramp Rate <15:8>
RAM Segment 2 Address Ramp Rate <7:0>
No Dwell Active
RAM Segment 3 Mode Control
RAM Segment 3 Beginning
<2:0>
Address <9:6>
RAM Segment 3 Beginning Address <5:0>
RAM Segment 3 Final Address <9:8>
RAM Segment 3 Final Address <7:0>
RAM Segment 3 Address Ramp Rate <15:8>
RAM Segment 3 Address Ramp Rate <7:0>
RAM [1023:0] <31:0> (Read Instructions: Write Out RAM Register Data)
Rev. A | Page 15 of 32
Default
Value
OR
Profile
PS0 = 0
PS1 = 0
PS0 = 0
PS1 = 0
PS0 = 0
PS1 = 0
PS0 = 0
PS1 = 0
PS0 = 0
PS1 = 0
PS0 = 1
PS1 = 0
PS0 = 1
PS1 = 0
PS0 = 1
PS1 = 0
PS0 = 1
PS1 = 0
PS0 = 1
PS1 = 0
PS0 = 0
PS1 = 1
PS0 = 0
PS1 = 1
PS0 = 0
PS1 = 1
PS0 = 0
PS1 = 1
PS0 = 0
PS1 = 1
PS0 = 1
PS1 = 1
PS0 = 1
PS1 = 1
PS0 = 1
PS1 = 1
PS0 = 1
PS1 = 1
PS0 = 1
PS1 = 1
Control Register Bit Descriptions
Control Function Register. No. 1 (CFR1)
The CFR1 is used to control the various functions, features, and
modes of the AD9953. The functionality of each bit is below.
CFR1<31>: RAM Enable Bit
CFR1<31> = 0 (default). The RAM is powered down to
conserve power. Single-tone mode of operation is active.
CFR1<31> = 1. If CFR1<31> is active, the RAM is enabled for
operation. Access control for normal operation is controlled via
the mode control bits of the RSCW for the current profile.
CFR1<30>: RAM Destination Bit
CFR1<30> = 0 (default). If CFR1<31> is active, a Logic 0 on the
RAM destination bit (CFR1<30> = 0) configures the AD9953
such that the RAM output drives the phase accumulator (i.e.,
the frequency tuning word). If CFR1<31> is inactive,
CFR1<30> is a Don’t Care.
will cause the output to ramp down from the amplitude scale
factor to zero scale at the amplitude ramp rate. See the Shaped
On-Off Keying section for details.
CFR1<23>: Automatic Synchronization Enable Bit
CFR1<23> = 0 (default). The automatic synchronization feature
of multiple AD9953s is inactive.
CFR1<23> = 1. The automatic synchronization feature of
multiple AD9953s is active. The device will synchronize its
internal synchronization clock (SYNC_CLK) to align to the
signal present on the SYNC_IN input. See the Synchronizing
Multiple AD9953s section for details.
CFR1<22>: Software Manual Synchronization of Multiple
AD9953s
CFR1<22> = 0 (default). The manual synchronization feature is
inactive.
CFR1<29:27>: Not Used
CFR1<22> = 1. The software controlled manual synchronization feature is executed. The SYNC_CLK rising edge is
advanced by one SYNC_CLK cycle and this bit is cleared. To
advance the rising edge multiple times, this bit needs to be set
for each advance. See the Synchronizing Multiple AD9953s
section for details.
CFR1<26>: Amplitude Ramp Rate Load Control Bit
CFR1<21:14>: Not Used
CFR1<26> = 0 (default). The amplitude ramp rate timer is
loaded only upon timeout (timer == 1) and is not loaded due to
an I/O UPDATE input signal.
CFR1<13>: Auto-Clear Phase Accumulator Bit
CFR1<26> = 1. The amplitude ramp rate timer is loaded upon
timeout (timer == 1) or at the time of an I/O UPDATE input signal.
CFR1<25>: Shaped On-Off Keying Enable Bit
CFR1<13> = 1. This bit automatically synchronously clears
(loads 0s into) the phase accumulator for one cycle upon
reception of an I/O UPDATE signal.
CFR1<25> = 0 (default). Shaped on-off keying is bypassed.
CFR1<12>: Sine/Cosine Select Bit
CFR1<25> = 1. Shaped on-off keying is enabled. When enabled,
CFR1<24> controls the mode of operation for this function.
CFR1<12> = 0 (default). The angle-to-amplitude conversion
logic employs a COSINE function.
CFR1<24>: Auto Shaped On-Off Keying Enable Bit (Only Valid
when CFR1<25> Is Active High)
CFR1<12> = 1. The angle-to-amplitude conversion logic
employs a SINE function.
CFR1<24> = 0 (default). When CFR1<25> is active, a Logic 0
on CFR1<24> enables the manual shaped on-off keying
operation. Each amplitude sample sent to the DAC is multiplied
by the amplitude scale factor. See the Shaped On-Off Keying
section for details.
CFR1<11>: Not Used
CFR1<24> = 1. When CFR1<25> is active, a Logic 1 on
CFR1<24> enables the auto shaped on-off keying operation.
Toggling the OSK pin high will cause the output scalar to ramp
up from zero scale to the amplitude scale factor at a rate determined by the amplitude ramp rate. Toggling the OSK pin low
CFR1<10> = 1. The phase accumulator memory elements are
cleared and held clear until this bit is cleared.
CFR1<30> = 1. If CFR1<31> is active, a Logic 1 on the RAM
destination bit (CFR1<30> = 1) configures the AD9953 such
that the RAM output drives the phase-offset adder (i.e., sets the
phase offset of the DDS core).
CFR1<13> = 0 (default). The current state of the phase accumulator remains unchanged when the frequency tuning word is applied.
CFR1<10>: Clear Phase Accumulator
CFR1<10> = 0 (default). The phase accumulator functions as
normal.
AD9953
minimum. However, the synchronization circuitry remains
active (internally) to maintain normal device timing.
CFR1<9>: SDIO Input Only
CFR1<9> = 0 (default). The SDIO pin has bidirectional
operation (2-wire serial programming mode).
CFR1<0>: Not Used, Leave at 0
CFR1<9> = 1. The serial data I/O pin (SDIO) is configured as
an input only pin (3-wire serial programming mode).
CFR1<8>: LSB First
CFR1<8> = 0 (default). MSB first format is active.
Control Function Register No. 2 (CFR2)
The CFR2 is used to control the various functions, features, and
modes of the AD9953, primarily related to the analog sections
of the chip.
CFR1<8> = 1. The serial interface accepts serial data in LSB
first format.
CFR2<23:12>: Not Used
CFR1<7>: Digital Power-Down Bit
CFR2<11> = 0 (default). The high speed sync enhancement is off.
CFR1<7> = 0 (default). All digital functions and clocks are active.
CFR2<11> = 1. The high speed sync enhancement is on. This
bit should be set when attempting to use the autosynchronization feature for SYNC_CLK inputs beyond 50 MHz,
(200 MSPS SYSCLK). See the Synchronizing Multiple AD9953s
section for details.
CFR2<11>: High Speed Sync Enable Bit
CFR1<7> = 1. All non-IO digital functionality is suspended,
lowering the power significantly.
CFR1<6>: Not Used
CFR1<5>: DAC Power-Down Bit
CFR2<10>: Hardware Manual Sync Enable Bit
CFR1<5> = 0 (default). The DAC is enabled for operation.
CFR2<10> = 0 (default). The hardware manual sync function is off.
CFR1<5> = 1. The DAC is disabled and is in its lowest power
dissipation state.
CFR1<4>: Clock Input Power-Down Bit
CFR1<4> = 0 (default). The clock input circuitry is enabled for
operation.
CFR1<4> = 1. The clock input circuitry is disabled and the
device is in its lowest power dissipation state.
CFR2<10> = 1. The hardware manual sync function is enabled.
While this bit is set, a rising edge on the SYNC_IN pin will
cause the device to advance the SYNC_CLK rising edge by one
REFCLK cycle. Unlike the software manual sync enable bit, this
bit does not self clear. Once the hardware manual sync mode is
enabled, it will stay enabled until this bit is cleared. See the
Synchronizing Multiple AD9953s section for details.
CFR2<9>: CRYSTAL OUT Enable Bit
CFR1<3>: External Power-Down Mode
CFR1<3> = 0 (default). The external power-down mode
selected is the rapid recovery power-down mode. In this mode,
when the PWRDWNCTL input pin is high, the digital logic
and the DAC digital logic are powered down. The DAC bias
circuitry, PLL, oscillator, and clock input circuitry are not
powered down.
CFR1<3> = 1. The external power-down mode selected is the
full power-down mode. In this mode, when the PWRDWNCTL
input pin is high, all functions are powered down. This includes
the DAC and PLL, which take a significant amount of time to
power up.
CFR2<9> = 0 (default). The CRYSTAL OUT pin is inactive.
CFR2<9> = 1. The CRYSTAL OUT pin is active. When active,
the crystal oscillator circuitry output drives the CRYSTAL OUT
pin, which can be connected to other devices to produce a
reference frequency. The oscillator will respond to crystals in
the range of 20 MHz to 30 MHz.
CFR2<8>: Not Used
CFR2<7:3>: Reference Clock Multiplier Control Bits
CFR1<2>: Not Used
This 5-bit word controls the multiplier value out of the clockmultiplier (PLL) block. Valid values are decimal 4 to 20 (0x04 to
0x14). Values entered outside this range will bypass the clock
multiplier. See the Phase-Locked Loop (PLL) section for details.
CFR1<1>: SYNC_CLK Disable Bit
CFR2<2>: VCO Range Control Bit
CFR1<1> = 0 (default). The SYNC_CLK pin is active.
This bit is used to control the range setting on the VCO.
When CFR2<2> == 0 (default), the VCO operates in a range of
100 MHz to 250 MHz. When CFR2<2> == 1, the VCO operates
in a range of 250 MHz to 400 MHz.
CFR1<1> = 1. The SYNC_CLK pin assumes a static Logic 0
state to keep noise generated by the digital circuitry at a
Rev. A | Page 17 of 32
AD9953
CFR2<1:0>: Charge Pump Current Control Bits
These bits are used to control the current setting on the charge
pump. The default setting, CFR2<1:0>, sets the charge pump
current to the default value of 75 μA. For each bit added (01, 10,
11), 25 μA of current is added to the charge pump current:
100 μA, 125 μA, and 150 μA.
Other Register Descriptions
Amplitude Scale Factor (ASF)
The ASF register stores the 2-bit auto ramp rate speed value
and the 14-bit amplitude scale factor used in the output shaped
keying (OSK) operation. In auto OSK operation, ASF <15:14>
tells the OSK block how many amplitude steps to take for each
increment or decrement. For ASF<15:14> = {00, 01, 10, 11}, the
increment/decrement is set to {1, 2, 4, 8}, respectively. ASF
<13:0> sets the maximum value achievable by the OSK internal
multiplier. In manual OSK mode, ASF<15:14> has no effect.
ASF <13:0> provides the output scale factor directly. If the OSK
enable bit is cleared, CFR1<25> = 0, this register has no effect
on device operation.
ramping, this 16-bit word defines the number of SYNC_CLK
cycles the RAM controller dwells at each address. A value of 0 is
invalid. Any other value from 1 to 65535 may be used.
RAM Segment Final Address RSCW<9:8>, RSCW<23:16>
This discontinuous 10-bit sequence defines the final address
value for the given RAM segment. The order in which the bits
are listed is the order in which the bits must be written.
RSCW<23>, even though during the write operation is more
significant than RSCW<9>, is only the third MSB of the final
address value. RSCW<9>, even though it comes later in the
RSCW than RSCW<23>, is the MSB of the final address value.
RAM Segment Beginning Address RSCW<3:0>, <15:10>
This discontinuous 10-bit sequence defines the final address
value for the given RAM segment. The order in which the bits
are listed is the order in which the bits must be written.
RSCW<15>, even though during the write operation is more
significant than RSCW<3>, is only the fifth MSB of the final
address value. RSCW<3>, even though it comes later in the
RSCW than RSCW<15>, is the MSB of the final address value.
Amplitude Ramp Rate (ARR)
RAM Segment Mode Control RSCW<7:5>
The ARR register stores the 8-bit amplitude ramp rate used in
the auto OSK mode. This register programs the rate at which
the amplitude scale factor counter increments or decrements. If
the OSK is set to manual mode, or if OSK enable is cleared, this
register has no effect on device operation.
This 3-bit sequence determines the RAM segment’s mode of
operation. There are only five possible RAM modes, so only
values of 0 to 5 are valid. See Table 6 to determine the bit
combination for various RAM modes.
Frequency Tuning Word 0 (FTW0)
This bit sets the no-dwell feature of sweeping profiles. In
profiles that sweep from a defined beginning to a defined end,
the RAM controller can either dwell at the final address until
the next profile is selected or, when this bit is set, the RAM
controller will return to the beginning address and dwell there
until the next profile is selected.
The frequency tuning word is a 32-bit register that controls the
rate of accumulation in the phase accumulator of the DDS core.
Its specific role is dependent on the device mode of operation.
Phase Offset Word (POW)
The phase offset word is a 14-bit register that stores a phase
offset value. This offset value is added to the output of the phase
accumulator to offset the current phase of the output signal. The
exact value of phase offset is given by the following formula:
POW
Φ = ⎛⎜ 14 ⎞⎟ × 360°
⎝ 2 ⎠
RAM Segment Control Words (RSCW0, RSCW1, RSCW2,
and RSCW3)
When the linear sweep enable bit CFR1<21> is clear,
Registers 0x07, 0x08, 0x09, and 0x0A act as the RAM segment
control words for each of the RAM segments. Each of the RAM
segment control words is comprised of a RAM segment address
ramp rate, a final address value, a beginning address value, a
RAM segment mode control, and a no-dwell bit.
RAM Segment Address Ramp Rate, RSCW<39:24>
For RAM modes that step through address values, such as
RAM Segment No-Dwell Bit RSCW<4>
RAM
The AD9953 incorporates a 1024 × 32 block of SRAM. The
RAM is a bidirectional single port. Both read and write
operations from and to the RAM are valid, but they cannot
occur simultaneously. Write operations from the serial I/O port
have precedence, and if an attempt to write to RAM is made
during a read operation, the read operation will be halted. The
RAM is controlled in multiple ways, dictated by the modes of
operation described in the RAM Segment Control Word <7:5>
as well as data in the control function register. Read/write
control for the RAM will be described for each mode
supported.
When the RAM enable bit (CFR1<31>) is set, the RAM output
optionally drives the input to the phase accumulator or the
phase offset adder, depending on the state of the RAM destination bit (CFR1<30>). If CFR1<30> is a Logic 1, the RAM output
is connected to the phase offset adder and supplies the phase
offset control word(s) for the device. When CFR1<30> is
Logic 0 (default condition), the RAM output is connected to the
Rev. A | Page 18 of 32
AD9953
input of the phase accumulator and supplies the frequency
tuning word(s) for the device. When the RAM output drives the
phase accumulator, the phase offset word (POW, Address 0x05)
drives the phase-offset adder. Similarly, when the RAM output
drives the phase offset adder, the frequency tuning word (FTW,
Address 0x04) drives the phase accumulator. When CFR1<31>
is Logic 0, the RAM is inactive unless being written to via the
serial port. The power-up state of the AD9953 is the single-tone
mode, in which the RAM enable bit is inactive. The RAM is
segmented into four unique slices controlled by the Profile<1:0>
input pins.
All RAM writes/reads, unless otherwise specified, are controlled
by the Profile<1:0> input pins and the respective RAM segment
control word. The RAM can be written to during normal
operation, but any I/O operation that commands the RAM to be
written immediately suspends read operation from the RAM,
causing the current mode of operation to be nonfunctional. This
excludes single-tone mode, as the RAM is not read in this mode.
Writing the RAM is accomplished as follows. After configuring
the desired RAM segment control words, the desired RAM
segment must be selected via the profile select pins PS<1:0>.
During the instruction byte, write the address for the RAM,
0x0B. The serial port and RAM controller will work in
conjunction to determine the width of the profile and the serial
port will accept the defined number of 32-bit words
sequentially from the beginning address to the ending address.
Consider the following example:
RAM Controlled Modes of Operation
Direct Switch Mode
Direct switch mode enables FSK or PSK modulation. The
AD9953 is programmed for direct switch mode by writing the
RAM enable bit true and programming the RAM segment
mode control bits of each desired profile to Logic 000(b). This
mode simply reads the RAM contents at the RAM segment
beginning address for the current profile. No address ramping is
enabled in direct switch mode.
To perform 4-tone FSK, the user programs each RAM segment
control word for direct switch mode and a unique beginning
address value. In addition, the RAM enable bit is written true,
which enables the RAM, and the RAM destination bit is written
false, setting the RAM output to be the frequency tuning word.
The Profile<1:0> inputs are the 4-tone FSK data inputs. When
the profile is changed, the frequency tuning word stored in the
new profile is loaded into the phase accumulator and is used to
increment the currently stored value in a phase continuous
fashion. The phase offset word drives the phase-offset adder.
Two-tone FSK is accomplished by using only one profile pin for
data.
•
The RAM Segment Control Word 1 lists the beginning
RAM address at 256 and the ending address at 511.
•
PS0 = 1 and PS1 = 0.
Programming the AD9953 for PSK modulation is similar to
FSK except the RAM destination bit is set to a Logic 1, enabling
the RAM output to drive the phase offset adder. The FTW0
drives the input to the phase accumulator. Toggling the profile
pins changes (modulates) the current phase value. The upper
14 bits of the RAM drive the phase adder (<31:18>).
Bits <17:0> of the RAM output are unused when the RAM
destination bit is set. The no-dwell bit is a Don’t Care in direct
switch mode.
•
The instruction byte is 10001001.
Ramp-Up Mode
The RAM controller would configure the serial port to expect
256 32-bit words. The first 32 bits would be parsed as a word
and sent to RAM Address 256. The next 32 bits would be parsed
and sent to 257, and so forth, all the way through until the 256
word was sent (grand total of 8,192 data bits in this operation).
MODES OF OPERATION
Single-Tone Mode
In single-tone mode, the DDS core uses a single tuning word.
Whatever value is stored in FTW0 is supplied to the phase
accumulator. This value can only be changed manually, which is
done by writing a new value to FTW0 and by issuing an I/O
UPDATE. Phase adjustment is possible through the phase
offset register.
Ramp-up mode, in conjunction with the segmented RAM
capability, allows up to four different sweep profiles to be
programmed into the AD9953. The AD9953 is programmed for
ramp-up mode by writing the RAM enable bit true and
programming the RAM mode control bits of each profile to be
used to Logic 001(b). As in all modes that enable the memory,
the RAM destination bit controls whether the RAM output
drives the phase accumulator or the phase offset adder.
Upon starting a sweep (via an I/O UPDATE or change in
profile bits), the RAM address generator loads the RAM
segment beginning address bits of the current RSCW, driving
the RAM output from this address, and the ramp rate timer
loads the RAM segment address ramp rate bits. When the
ramp rate timer finishes a cycle, the RAM address generator
increments to the next address and the timer reloads the ramp
rate bits and begins a new countdown cycle. This sequence
continues until the RAM address generator has incremented to
an address equal to the RAM segment final address bits of the
current RSCW.
Rev. A | Page 19 of 32
AD9953
If the no-dwell bit is clear when the RAM address generator
equals the final address, the generator stops incrementing as the
terminal frequency has been reached. The sweep is complete
and does not restart until an I/O UPDATE or change in profile
is detected to enable another sweep from the beginning to the
final RAM address as described above.
If the no-dwell bit is set when the RAM address generator
equals the final address, after the next ramp rate timer cycle the
phase accumulator is cleared. The phase accumulator remains
cleared until another sweep is initiated via an I/O UPDATE
input or change in profile.
Another application for ramp-up mode is nonsymmetrical FSK
modulation. With the RAM configured for two segments, using
the Profile<0> bit as the data input allows nonsymmetrical
ramped FSK.
Bidirectional Ramp Mode
Bidirectional ramp mode allows the AD9953 to offer a symmetrical sweep between two frequencies using the Profile<0> signal as
the control input. The AD9953 is programmed for bidirectional
ramp mode by writing the RAM enable bit true and the RAM
mode control bits of RSCW0 to Logic 010(b). In bidirectional
ramp mode, the Profile<1> input is ignored and the Profile<0>
input is the ramp direction indicator. In this mode, the memory
is not segmented and uses only a single beginning and final
address. The address registers that affect the control of the RAM
are located in the RSCW associated with Profile 0.
Upon entering this mode (via an I/O UPDATE or changing
Profile<0>), the RAM address generator loads the RAM segment beginning address bits of RSCW0 and the ramp rate timer
loads the RAM segment address ramp rate bits. The RAM
drives data from the beginning address, and the ramp rate timer
begins to count down to 1. While operating in this mode, toggling the Profile<0> pin does not cause the device to generate
an internal I/O UPDATE. When the Profile<0> pin is acting as
the ramp direction indicator, any transfer of data from the I/O
buffers to the internal registers can only be initiated by a rising
edge on the I/O UPDATE pin.
RAM address control now is a function of the Profile<0> input.
When the Profile<0> bit is a Logic 1, the RAM address generator increments to the next address when the ramp rate timer
completes a cycle (and reloads to start the timer again). As in
the ramp-up mode, this sequence continues until the RAM
address generator has incremented to an address equal to the
final address as long as the Profile<0> input remains high. If the
Profile<0> input goes low, the RAM address generator immediately decrements and the ramp rate timer is reloaded. The
RAM address generator will continue to decrement at the ramp
rate period until the RAM address is equal to the beginning
address as long as the Profile<0> input remains low.
The sequence of ramping up and down is controlled via the
Profile<0> input signal for as long as the part is programmed
into this mode. The no-dwell bit is a Don’t Care in this mode as
is all data in the RAM segment control words associated with
Profiles 1, 2, and 3. Only the information in the RAM segment
control word for Profile 0 is used to control the RAM in the
bidirectional ramp mode.
Continuous Bidirectional Ramp Mode
Continuous bidirectional ramp mode allows the AD9953 to
offer an automatic symmetrical sweep between two frequencies.
The AD9953 is programmed for continuous bidirectional ramp
mode by writing the RAM enable bit true and the RAM mode
control bits of each profile to be used to Logic 011(b).
Upon entering this mode (via an I/O UPDATE or changing
Profile<1:0>), the RAM address generator loads the RAM
segment beginning address bits of the current RSCW and the
ramp rate timer loads the RAM segment address ramp rate bits.
The RAM drives data from the beginning address, and the ramp
rate timer begins to count down to 1. When the ramp rate timer
completes a cycle, the RAM address generator increments to the
next address, and the timer reloads the ramp rate bits and
continues counting down. This sequence continues until the
RAM address generator has incremented to an address equal to
the RAM segment final address bits of the current RSCW. Upon
reaching this terminal address, the RAM address generator will
decrement in value at the ramp rate until it reaches the RAM
segment beginning address. Upon reaching the beginning
address, the entire sequence repeats.
The entire sequence repeats for as long as the part is
programmed for this mode. The no-dwell bit is a Don’t Care in
this mode. In general, this mode is identical in control to the
bidirectional ramp mode except the ramp up and down is
automatic (no external control via the Profile<0> input) and
switching profiles is valid. Once in this mode, the address
generator ramps from the beginning address to the final
address, then back to the beginning address at the rate
programmed into the ramp rate register. This mode enables
generation of an automatic saw tooth sweep characteristic.
Continuous Recirculate Mode
Continuous recirculate mode allows the AD9953 to offer
an automatic, continuous unidirectional sweep between two
frequencies. The AD9953 is programmed for continuous
recirculate mode by writing the RAM enable bit true and the RAM
mode control bits of each profile to be used to Logic 100(b).
Upon entering this mode (via an I/O UPDATE or changing
Profile<1:0>), the RAM address generator loads the RAM
segment beginning address bits of the current RSCW and the
ramp rate timer loads the RAM segment address ramp rate bits.
The RAM drives data from the beginning address, and the ramp
rate timer begins to count down to 1. When the ramp rate timer
completes a cycle, the RAM address generator increments to the
Rev. A | Page 20 of 32
AD9953
next address, and the timer reloads the ramp rate bits and
continues counting down. This sequence continues until the
RAM address generator has incremented to an address equal to
the RAM segment final address bits of the current RSCW. Upon
reaching this terminal address, the RAM address generator
reloads the RAM segment beginning address bits and the
sequence repeats.
The sequence of circulating through the specified RAM
addresses repeats for as long as the part is programmed for this
mode. The no-dwell bit is a Don’t Care in this mode.
is only valid when the device is operating in RAM mode. There
is no internal profile control for linear sweeping operations.
When the internal profile control mode is engaged, the RAM
segment mode control bits are Don’t Care and the device
operates all profiles as if these mode control bits were
programmed for ramp-up mode. Switching between profiles
occurs when the RAM address generator has exhausted the
memory contents for the current profile.
Table 7. Internal Profile Control
RAM Controlled Modes of Operation Notes and
Summary
Notes:
1.
The user must ensure that the beginning address is lower
than the final address.
2.
Changing profiles or issuing an I/O UPDATE automatically
terminates the current sweep and starts the next sweep.
3.
Setting the RAM destination bit true such that the RAM
output drives the phase offset adder is valid. While the
above discussion describes a frequency sweep, a phase
sweep operation is also available.
CFR1<29:27>
(Binary)
000
001
010
011
100
101
The AD9953 offers five modes of RAM controlled operation
(see Table 6).
110
Table 6. RAM Modes of Operation
111
RSCW<7:5>
(Binary)
000
Mode
Direct Switch
001
Ramp Up
010
Bidirectional
Ramp
011
Continuous
Bidirectional
Ramp
Continuous
Recirculate
Open
100
101, 110, 111
Notes
No Sweeping, Profiles
Valid, No Dwell Invalid
Sweeping, Profiles Valid,
No Dwell Valid
Sweeping, Profile <0> Is a
Direction Control Bit, No
Dwell Invalid
Sweeping, Profiles Valid,
No Dwell Invalid
Sweeping, Profiles Valid,
No Dwell Invalid
Invalid Mode—Default To
Direct Switch
Internal Profile Control
The AD9953 offers a mode in which a composite frequency
sweep can be built, for which the timing control is software
programmable. The internal profile control capability disengages the Profile<1:0> pins and enables the AD9953 to take
control of switching between profiles. Modes are defined that
allow continuous or single burst profile switches for three
combinations of profile selection bits. These are listed in
Table 7. When any of the CFR1<29:27> bits are active, the
internal profile control mode is engaged. Internal profile control
Mode Description
Internal Control Inactive
Internal Control Active, Single Burst, Activate
Profile 0, Then 1, Then Stop
Internal Control Active, Single Burst, Activate
Profile 0, Then 1, Then 2, Then Stop
Internal Control Active, Single Burst, Activate
Profile 0, Then 1, Then 2, Then 3, Then Stop
Internal Control Active, Continuous, Activate
Profile 0, Then 1, Then Loop Starting 0
Internal Control Active, Continuous, Activate
Profile 0, Then 1, Then 2, Then Loop Starting 0
Internal Control Active, Continuous, Activate
Profile 0, Then 1, Then 2, Then 3, Then Loop
Starting 0
Invalid
A single burst mode is one in which the composite sweep is
executed once. For example, assume the device is programmed
for ramp-up mode and the CFR1<29:27> bits are written to
Logic 010(b). Upon receiving an I/O UPDATE, the internal
control logic signals the device to begin executing the ramp-up
mode sequence for Profile 0. Upon reaching the RAM segment
final address value for Profile 0, the device automatically
switches to Profile 1 and begins executing that ramp-up
sequence. Upon reaching the RAM segment final address value
for Profile 1, the device automatically switches to Profile 2 and
begins executing that ramp-up sequence. When the RAM
segment final address value for Profile 2 is reached, the
sequence is over and the composite sweep has completed.
Issuing another I/O UPDATE restarts the burst process.
A continuous internal profile control mode is one in which the
composite sweep is continuously executed for as long as the
device is programmed into that mode. Using the example
above, except programming the CFR1<29:27> bits to Logic
101(b), the operation would be identical until the RAM
segment final address value for Profile 2 is reached. At this
point, instead of stopping the sequence, it repeats, starting with
Profile 0.
Rev. A | Page 21 of 32
AD9953
PROGRAMMING AD9953 FEATURES
Phase Offset Control
A 14-bit phase offset (θ) may be added to the output of the phase
accumulator by means of the control registers. This feature
provides the user with two different methods of phase control.
The first method is a static phase adjustment where a fixed
phase offset is loaded into the appropriate phase offset register
and left unchanged. The result is that the output signal is offset
by a constant angle relative to the nominal signal. This allows
the user to phase align the DDS output with some external
signal, if necessary.
The second method of phase control is where the user regularly
updates the phase offset register via the I/O port. By properly
modifying the phase offset as a function of time, the user can
implement a phase modulated output signal. However, both the
speed of the I/O port and the frequency of SYSCLK limit the
rate at which phase modulation can be performed.
The AD9953 allows for a programmable continuous zeroing of
the phase accumulator as well as a clear and release or
automatic zeroing function. Each feature is individually
controlled via the CFR1 bits. CFR1<13> is the automatic clear
phase
accumulator bit. CFR1<10> clears the phase accumulator and
holds the value to zero.
Continuous Clear Bit
The continuous clear bit is simply a static control signal that,
when active high, holds the phase accumulator at zero for the
entire time the bit is active. When the bit goes low, inactive, the
phase accumulator is allowed to operate.
Clear and Release Function
When set, the auto-clear phase accumulator clears and releases
the phase accumulator upon receiving an I/O UPDATE. The
automatic clearing function is repeated for every subsequent
I/O UPDATE until the appropriate auto-clear control bit is
cleared.
Shaped On-Off Keying
The shaped on-off keying function of the AD9953 allows the
user to control the ramp-up and ramp-down time of an on-off
emission from the DAC. This function is used in burst
transmissions of digital data to reduce the adverse spectral
impact of short, abrupt bursts of data.
The modes are controlled by two bits located in the most significant byte of the control function register (CFR). CFR1<25> is
the shaped on-off keying enable bit. When CFR1<25> is set, the
output scaling function is enabled and CFR1<25> bypasses the
function. CFR1<24> is the internal shaped on-off keying active
bit. When CFR1<24> is set, internal shaped on-off keying mode
is active; CFR1<24> is cleared, external shaped on-off keying
mode is active. CFR1<24> is a Don’t Care if the shaped on-off
keying enable bit (CFR1<25>) is cleared. The power-up
condition is shaped on-off keying disabled (CFR1<25> = 0).
Figure 20 shows the block diagram of the OSK circuitry.
AUTO Shaped On-Off Keying Mode Operation
The auto shaped on-off keying mode is active when CFR1<25>
and CFR1<24> are set. When auto shaped on-off keying mode
is enabled, a single scale factor is internally generated and
applied to the multiplier input for scaling the output of the DDS
core block (see Figure 20). The scale factor is the output of a
14-bit counter that increments/decrements at a rate determined
by the contents of the 8-bit output ramp rate register. The scale
factor increases if the OSK pin is high and decreases if the OSK
pin is low. The scale factor is an unsigned value such that all 0s
multiply the DDS core output by 0 (decimal) and 0x3FFF
multiplies the DDS core output by 16383 (decimal).
For those users who use the full amplitude (14 bits) but need
fast ramp rates, the internally generated scale factor step size
is controlled via the ASF<15:14> bits. Table 8 describes the
increment/decrement step size of the internally generated scale
factor per the ASF<15:14> bits.
A special feature of this mode is that the maximum output
amplitude allowed is limited by the contents of the amplitude
scale factor register. This allows the user to ramp to a value less
than full scale.
Table 8. Auto-Scale Factor Internal Step Size
ASF<15:14> (Binary)
00
01
10
11
Auto and manual shaped on-off keying modes are supported.
The auto mode generates a linear scale factor at a rate
determined by the amplitude ramp rate (ARR) register
controlled by an external pin (OSK). Manual mode allows the
user to directly control the output amplitude by writing the
scale factor value into the amplitude scale factor (ASF) register.
The shaped on-off keying function may be bypassed (disabled)
by clearing the OSK enable bit (CFR1<25> = 0).
Rev. A | Page 22 of 32
Increment/Decrement Size
1
2
4
8
AD9953
OSK Ramp Rate Timer
The OSK ramp rate timer is a loadable down counter, which
generates the clock signal to the 14-bit counter that generates
the internal scale factor. The ramp rate timer is loaded with the
value of the ASFR every time the counter reaches 1 (decimal).
This load and countdown operation continues for as long as the
timer is enabled, unless the timer is forced to load before
reaching a count of 1.
If the load OSK timer bit (CFR1<26>) is set, the ramp rate
timer is loaded upon an I/O UPDATE or upon reaching a value
of 1. The ramp timer can be loaded before reaching a count of 1
by three methods.
The first method of loading is by changing the OSK input pin.
When the OSK input pin changes state, the ASFR value is
loaded into the ramp rate timer, which then proceeds to count
down as normal.
The second method in which the sweep ramp rate timer can be
loaded before reaching a count of 1 is if the load OSK timer bit
(CFR1<26>) is set and an I/O UPDATE is issued.
The third method in which the sweep ramp rate timer can be
loaded before reaching a count of 1 is when going from the
inactive auto shaped on-off keying mode to the active auto
shaped on-off keying mode; that is, when the sweep enable bit is
being set.
DDS CORE
0
TO DAC
1
COS(X)
AUTO DESK
ENABLE
CFR1<24>
OSK ENABLE
SYNC_CLK
1
OSK PIN
AMPLITUDE RAMP
RATE REGISTER
(ASF)
0
0
1
AMPLITUDE SCALE
FACTOR REGISTER
(ASF)
OUT
LOAD OSK TIMER
CFR1<26>
HOLD
UP/DN
LOAD
INC/DEC ENABLE
DATA
EN
CLOCK
AUTO SCALE
FACTOR GENERATOR
RAMP RATE TIMER
Figure 20. On-Off Shaped Keying Block Diagram
Rev. A | Page 23 of 32
03374-0-005
CFR<25>
0
AD9953
External Shaped On-Off Keying Mode Operation
coupled with SYNC_CLK is used to transfer internal buffer
contents into the control registers of the device. The combination of the SYNC_CLK and I/O UPDATE pins provides the
user with constant latency relative to SYSCLK, and also ensures
phase continuity of the analog output signal when a new tuning
word or phase offset value is asserted. Figure 21 demonstrates
an I/O UPDATE timing cycle and synchronization.
The external shaped on-off keying mode is enabled by writing
CFR1<25> to a Logic 1 and writing CFR1<24> to a Logic 0.
When configured for external shaped on-off keying, the
content of the ASFR becomes the scale factor for the data path.
The scale factors are synchronized to SYNC_CLK via the
I/O UPDATE functionality.
Notes for synchronization logic:
Synchronization; Register Updates (I/O UPDATE)
Functionality of the SYNC_CLK and I/O UPDATE
1.
The I/O UPDATE signal is edge detected to generate a
single rising edge clock signal that drives the register bank
flops. The I/O UPDATE signal has no constraints on duty
cycle. The minimum low time on I/O UPDATE is one
SYNC_CLK clock cycle.
2.
The I/O UPDATE pin is set up and held around the rising
edge of SYNC_CLK and has zero hold time and 4 ns setup
time.
Data into the AD9953 is synchronous to the SYNC_CLK signal
(supplied externally to the user on the SYNC_CLK pin). The
I/O UPDATE pin is sampled on the rising edge of the
SYNC_CLK.
Internally, SYSCLK is fed to a divide-by-4 frequency divider to
produce the SYNC_CLK signal. The SYNC_CLK signal is
provided to the user on the SYNC_CLK pin. This enables
synchronization of external hardware with the device’s internal
clocks. This is accomplished by forcing any external hardware
to obtain its timing from SYNC_CLK. The I/O UPDATE signal
SYNC_CLK
DISABLE
1
0
SYSCLK
0
÷4
OSK
PROFILE<1:0>
D
I/O UPDATE
D
Q
Q
D
Q
EDGE
DETECTION
LOGIC
TO CORE LOGIC
REGISTER
MEMORY
I/O BUFFER
LATCHES
Figure 21. I/O Synchronization Block Diagram
Rev. A | Page 24 of 32
SCLK
SDI
CS
03374-0-006
SYNC_CLK
GATING
AD9953
SYSCLK
A
B
A
B
SYNC_CLK
I/O UPDATE
DATA IN
REGISTERS
DATA 1
DATA 2
DATA 3
DATA 0
DATA 1
THE DEVICE REGISTERS AN I/O UPDATE AT POINT A. THE DATA IS TRANSFERRED FROM THE I/O BUFFERS AT POINT B.
DATA 2
03357-007
DATA IN
I/O BUFFERS
Figure 22. I/O Synchronization Timing Diagram
Synchronizing Multiple AD9953s
The AD9953 allows easy synchronization of multiple AD9953s.
There are three modes of synchronization available to the user:
an automatic synchronization mode, a software controlled
manual synchronization mode, and a hardware controlled
manual synchronization mode. In all cases, when a user wants
to synchronize two or more devices, the following considerations must be observed. First, all units must share a common
clock source. Trace lengths and path impedance of the clock
tree must be designed to keep the phase delay of the different
clock branches as closely matched as possible. Second, the I/O
UPDATE signal’s rising edge must be provided synchronously
to all devices in the system. Finally, regardless of the internal
synchronization method used, the DVDD_I/O supply should
be set to 3.3 V for all devices that are to be synchronized.
AVDD and DVDD should be left at 1.8 V.
In automatic synchronization mode, one device is chosen as a
master; the other device(s) will be slaved to this master. When
configured in this mode, the slaves will automatically synchronize their internal clocks to the SYNC_CLK output signal of the
master device. To enter automatic synchronization mode, set
the slave device’s automatic synchronization bit (CFR1<23> =
1). Connect the SYNC_IN input(s) to the master SYNC_CLK
output. The slave device will continuously update the phase
relationship of its SYNC_CLK until it is in phase with the
SYNC_IN input, which is the SYNC_CLK of the master device.
When attempting to synchronize devices running at SYSCLK
speeds beyond 250 MSPS, the high speed sync enhancement
enable bit should be set (CFR2<11> = 1).
In software manual synchronization mode, the user forces the
device to advance the SYNC_CLK rising edge one SYSCLK
cycle (1/4 SYNC_CLK period). To activate the manual
synchronization mode, set the slave device’s software manual
synchronization bit (CFR1<22> = 1). The bit (CFR1<22>) will be
cleared immediately. To advance the rising edge of the SYNC_CLK
multiple times, this bit will need to be set multiple times.
In hardware manual synchronization mode, the SYNC_IN
input pin is configured such that it will now advance the rising
edge of the SYNC_CLK signal each time the device detects a
rising edge on the SYNC_IN pin. To put the device into hardware manual synchronization mode, set the hardware manual
synchronization bit (CFR2<10> = 1). Unlike the software
manual synchronization bit, this bit does not self clear. Once the
hardware manual synchronization mode is enabled, all rising
edges detected on the SYNC_IN input will cause the device to
advance the rising edge of the SYNC_CLK by one SYSCLK
cycle until this enable bit is cleared (CFR2<10> = 0).
Using a Single Crystal to Drive Multiple AD9953 Clock
Inputs
The AD9953 crystal oscillator output signal is available on the
CRYSTAL OUT pin, enabling one crystal to drive multiple
AD9953s. In order to drive multiple AD9953s with one crystal,
the CRYSTAL OUT pin of the AD9953 using the external crystal
should be connected to the REFCLK input of the other AD9953.
The CRYSTAL OUT pin is static until the CFR2<9> bit is set,
enabling the output. The drive strength of the CRYSTAL OUT
pin is typically very low, so this signal should be buffered prior
to using it to drive any loads.
SERIAL PORT OPERATION
With the AD9953, the instruction byte specifies read/write
operation and the register address. Serial operations on the
AD9953 occur only at the register level, not the byte level. For
the AD9953, the serial port controller recognizes the instruction byte register address and automatically generates the
proper register byte address. In addition, the controller expects
that all bytes of that register will be accessed. It is required that
all bytes of a register be accessed during serial I/O operations,
with one exception. The IOSYNC function can be used to abort
an I/O operation, thereby allowing some, but not all bytes to be
accessed.
Rev. A | Page 25 of 32
AD9953
There are two phases to a communication cycle with the
AD9953. Phase 1 is the instruction cycle, which is the writing of
an instruction byte into the AD9953, coincident with the first
eight SCLK rising edges. The instruction byte provides the
AD9953 serial port controller with information regarding the
data transfer cycle, which is Phase 2 of the communication cycle.
The Phase 1 instruction byte defines whether the upcoming data
transfer is read or write and the serial address of the register
being accessed.
during Phase 2 of the communication cycle is a function of the
register being accessed. For example, when accessing the Control
Function Register No. 2, which is three bytes wide, Phase 2 requires
that three bytes be transferred. If accessing the frequency tuning
word, which is four bytes wide, Phase 2 requires that four bytes
be transferred. After transferring all data bytes per the
instruction, the communication cycle is completed.
At the completion of any communication cycle, the AD9953
serial port controller expects the next eight rising SCLK edges
to be the instruction byte of the next communication cycle. All
data input to the AD9953 is registered on the rising edge of
SCLK. All data is driven out of the AD9953 on the falling edge
of SCLK. Figure 23 through Figure 26 are useful in VOEFSTUBOE
ing the general operation of the AD9953 serial port.
The first eight SCLK rising edges of each communication cycle
are used to write the instruction byte into the AD9953. The
remaining SCLK edges are for Phase 2 of the communication
cycle. Phase 2 is the actual data transfer between the AD9953
and the system controller. The number of bytes transferred
DATA TRANSFER CYCLE
INSTRUCTION CYCLE
CS
SDIO
I7
I6
I5
I4
I3
I2
I1
I0
D7
D6
D5
D4
D3
D2
D1
03374-0-008
SCLK
D0
Figure 23. Serial Port Write Timing—Clock Stall Low
INSTRUCTION CYCLE
DATA TRANSFER CYCLE
CS
SDIO
I7
I6
I5
I4
I3
I2
I1
I0
DON'T CARE
DO 7
SDO
DO 6 DO 5 DO 4 DO 3 DO 2 DO 1
DO 0
03374-0-009
SCLK
Figure 24. 3-Wire Serial Port Read Timing—Clock Stall Low
DATA TRANSFER CYCLE
INSTRUCTION CYCLE
CS
I7
I6
I5
I4
I3
I2
I1
I0
D0
03374-0-010
SDIO
DO 7 DO 6 DO 5 DO 4 DO 3 DO 2 DO 1 DO 0
03374-0-011
SCLK
D7
D6
D5
D4
D3
D2
D1
Figure 25. Serial Port Write Timing—Clock Stall High
INSTRUCTION CYCLE
DATA TRANSFER CYCLE
CS
SCLK
SDIO
I7
I6
I5
I4
I3
I2
I1
I0
Figure 26. 2-Wire Serial Port Read Timing—Clock Stall High
Rev. A | Page 26 of 32
AD9953
INSTRUCTION BYTE
The instruction byte contains the following information:
Table 9.
MSB
R/W
D6
X
D5
X
D4
A4
D3
A3
R/W—Bit 7 of the instruction byte determines whether a read
or write data transfer will occur after the instruction byte write.
Logic High indicates read operation. Logic 0 indicates a write
operation.
X, X—Bits 6 and 5 of the instruction byte are Don’t Care.
A4, A3, A2, A1, A0—Bits 4, 3, 2, 1, 0 of the instruction byte
determine which register is accessed during the data transfer
portion of the communications cycle.
SERIAL INTERFACE PORT PIN DESCRIPTION
SCLK—Serial Clock. The serial clock pin is used to synchronize
data to and from the AD9953 and to run the internal state
machines. SCLK maximum frequency is 25 MHz.
CSB—Chip Select Bar. CSB is active low input that allows more
than one device on the same serial communications line. The
SDO and SDIO pins will go to a high impedance state when this
input is high. If driven high during any communications cycle,
that cycle is suspended until CS is reactivated low. Chip select
can be tied low in systems that maintain control of SCLK.
SDIO—Serial Data I/O. Data is always written into the AD9953
on this pin. However, this pin can be used as a bidirectional
data line. Bit 9 of Register Address 0x00 controls the
configuration of this pin. The default is Logic 0, which
configures the SDIO pin as bidirectional.
SDO—Serial Data Out. Data is read from this pin for protocols
that use separate lines for transmitting and receiving data. In the
case where the AD9953 operates in a single bidirectional I/O mode,
this pin does not output data and is set to a high impedance state.
IOSYNC—It synchronizes the I/O port state machines without
affecting the addressable register’s contents. An active high
input on the IOSYNC pin causes the current communication
cycle to abort. After IOSYNC returns low (Logic 0), another
communication cycle may begin, starting with the instruction
byte write.
MSB/LSB TRANSFERS
The AD9953 serial port can support both most significant bit
(MSB) first or least significant bit (LSB) first data formats. This
functionality is controlled by the Control Register 0x00 <8> bit.
The default value of Control Register 0x00 <8> is low (MSB
first). When Control Register 0x00 <8> is set high, the AD9953
serial port is in LSB first format. The instruction byte must be
D2
A2
D1
A1
LSB
A0
written in the format indicated by Control Register 0x00 <8>. If
the AD9953 is in LSB first mode, the instruction byte must be
written from least significant bit to most significant bit.
For MSB first operation, the serial port controller will generate
the most significant byte (of the specified register) address first
followed by the next lesser significant byte addresses until the
I/O operation is complete. All data written to (read from) the
AD9953 must be (will be) in MSB first order. If the LSB mode is
active, the serial port controller will generate the least significant byte address first followed by the next greater significant byte
addresses until the I/O operation is complete. All data written to
(read from) the AD9953 must be (will be) in LSB first order.
Example Operation
To write the amplitude scale factor register in MSB first format,
apply an instruction byte of 0x02 [serial address is 00010(b)].
From this instruction, the internal controller will know to use
the first byte as the most significant byte. The first two bits will
be recorded as the auto ramp rate speed control bits, and the
next six bits will be the most significant bits of the amplitude
scale factor. The second byte will be applied as the eight less
significant bits of the amplitude scale factor ASF<7:0>.
To write the amplitude scale factor register in LSB first format,
assuming the control register has already been set for LSB first
format, apply an instruction byte of 0x40. From this instruction,
the internal controller will know to use the first byte as the least
significant byte of the amplitude scale factor ASF<0:7>. The
second byte will be split into the first six bits ASF<8:13> and the
last two will provide the auto ramp rate speed control bits
ARRSC<0:1>.
Power-Down Functions of the AD9953
The AD9953 supports an externally controlled or hardware
power-down feature as well as the more common software
programmable power-down bits found in previous ADI DDS
products.
The software control power-down allows the DAC, PLL, input
clock circuitry, and digital logic to be individually powered
down via unique control bits (CFR1<7:4>). With the exception
of CFR1<6>, these bits are not active when the externally
controlled power-down pin (PWRDWNCTL) is high. External
power-down control is supported on the AD9953 via the
PWRDWNCTL input pin. When the PWRDWNCTL input pin
is high, the AD9953 will enter a power-down mode based on
the CFR1<3> bit. When the PWRDWNCTL input pin is low,
the external power-down control is inactive.
Rev. A | Page 27 of 32
AD9953
When the CFR1<3> bit is 0 and the PWRDWNCTL input pin is
high, the AD9953 is put into a fast recovery power-down mode.
In this mode, the digital logic and the DAC digital logic are
powered down. The DAC bias circuitry, PLL, oscillator, and
clock input circuitry is not powered down.
When the CFR1<3> bit is high, and the PWRDWNCTL input
pin is high, the AD9953 is put into the full power-down mode.
In this mode, all functions are powered down. This includes the
DAC and PLL, which take a significant amount of time to
power up.
When the PWRDWNCTL input pin is high, the individual
power-down bits (CFR1<7>, <5:4>) are invalid (Don’t Care)
and unused. When the PWRDWNCTL input pin is low, the
individual power-down bits control the power-down modes of
operation.
Note that the power-down signals are all designed such that a
Logic 1 indicates the low power mode and a Logic 0 indicates
the active or power-up mode.
the digital clock generation section of the chip for the external
power-down operation.
Layout Considerations
For the best performance, the following layout guidelines
should be observed. Always provide the analog power supply
(AVDD) and the digital power supply (DVDD) on separate
supplies, even if just from two different voltage regulators
driven by a common supply. Likewise, the ground connections
(AGND, DGND) should be kept separate as far back to the
source as possible (i.e., separate the ground planes on a
localized board even if the grounds connect to a common point
in the system). Bypass capacitors should be placed as close to
the device pin as possible. Usually a multitiered bypassing
scheme consisting of a small high frequency capacitor (100 pF)
placed close to the supply pin and progressively larger capacitors (0.1 μF, 10 μF) placed further away from the actual supply
source works best.
Table 10 indicates the logic level for each power-down bit that
drives out of the AD9953 core logic to the analog section and
Table 10. Power-Down Control Functions
Control
PWRDWNCTL = 0 CFR1<3> Don’t Care
Mode Active
Software Control
PWRDWNCTL = 1 CFR1<3> = 0
External Control,
Fast Recovery Power-Down Mode
PWRDWNCTL = 1 CFR1<3> = 1
External Control,
Full Power-Down Mode
Rev. A | Page 28 of 32
Description
Digital Power-Down = CFR1<7>
DAC Power-Down = CFR1<5>
Input Clock Power-Down = CFR1<4>
Digital Power-Down = 1’b1
DAC Power-Down = 1’b0
Input Clock Power-Down = 1’b0
Digital Power-Down = 1’b1
DAC Power-Down = 1’b1
Input Clock Power-Down = 1’b1
AD9953
SUGGESTED APPLICATION CIRCUITS
FREQUENCY
TUNING
WORD
MODULATED/
DEMODULATED
SIGNAL
RF/IF INPUT
PHASE
OFFSET
WORD 1
I/I-BAR
BASEBAND
03357-0-003
REFCLK
LPF
AD9953
REFCLK
CRYSTAL
AD9953 DDS
IOUT
IOUT
LPF
REFCLK
CRYSTAL OUT
SYNC OUT
RF OUT
Figure 27. Synchronized LO for Up Conversion/Down Conversion
SYNC IN
AD9953 DDS
LOOP
FILTER
VCO
FILTER
IOUT
LPF
REFCLK
AD9953
TUNING
WORLD
IOUT
FREQUENCY
TUNING
WORD
PHASE
OFFSET
WORD 2
Q/Q-BAR
BASEBAND
Figure 29. Two AD9953s Synchronized to Provide I and
Q Carriers with Independent Phase Offsets for Nulling
Figure 28. Digitally Programmable Divide-by-N Function in PLL
Rev. A | Page 29 of 32
03357-006
PHASE
COMPARATOR
03357-0-004
REF
SIGNAL
AD9953
OUTLINE DIMENSIONS
9.00
BSC SQ
1.20
MAX
BOTTOM VIEW
(PINS UP)
37
36
48
1
37
36
48
1
7.00
BSC SQ
PIN 1
3.50
SQ
TOP VIEW
(PINS DOWN)
0° MIN
1.05
1.00
0.95
0.15
0.05
SEATING
PLANE
0.20
0.09
7°
3.5°
0°
0.08 MAX
COPLANARITY
EXPOSED
PAD
12
13
VIEW A
25
24
25
24
0.50 BSC
LEAD PITCH
VIEW A
ROTATED 90° CCW
12
13
0.27
0.22
0.17 FOR PROPER CONNECTION OF
THE EXPOSED PAD, REFER TO
THE PIN CONFIGURATION AND
FUNCTION DESCRIPTIONS
SECTION OF THIS DATA SHEET.
COMPLIANT TO JEDEC STANDARDS MS-026-ABC
011708-A
0.75
0.60
0.45
Figure 30. 48-Lead Thin Quad Flat Package, Exposed Pad [TQFP_EP]
(SV-48-4)
Dimensions shown in millimeters
ORDERING GUIDE
Model
AD9953YSV
AD9953YSV-REEL7
AD9953YSVZ1
AD9953YSVZ-REEL71
AD9954/PCBZ1
1
Temperature
Range
−40°C to +105°C
−40°C to +105°C
−40°C to +105°C
−40°C to +105°C
Package Description
48-Lead Thin Quad Flat Package, Exposed Pad [TQFP_EP]
48-Lead Thin Quad Flat Package, Exposed Pad [TQFP_EP]
48-Lead Thin Quad Flat Package, Exposed Pad [TQFP_EP]
48-Lead Thin Quad Flat Package, Exposed Pad [TQFP_EP]
Evaluation Board Used for the AD9953
Z = RoHS Compliant Part.
Rev. A | Page 30 of 32
Ordering
Quantity
500
500
Package
Option
SV-48-4
SV-48-4
SV-48-4
SV-48-4
AD9953
NOTES
Rev. A | Page 31 of 32
AD9953
NOTES
©2004–2009 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D03374-0-5/09(A)
Rev. A | Page 32 of 32