AD9915 (Rev. D) - Analog Devices

2.5 GSPS Direct Digital Synthesizer
with 12-Bit DAC
AD9915
Data Sheet
FEATURES
Software and hardware controlled power-down
88-lead LFCSP package
PLL REF CLK multiplier
Phase modulation capability
Amplitude modulation capability
Multichip synchronization
2.5 GSPS internal clock speed
Integrated 12-bit DAC
Frequency tuning resolution to 135 pHz
16-bit phase tuning resolution
12-bit amplitude scaling
Programmable modulus
Automatic linear and nonlinear frequency sweeping
capability
32-bit parallel datapath interface
8 frequency/phase offset profiles
Phase noise: −128 dBc/Hz (1 kHz offset at 978 MHz)
Wideband SFDR < −57 dBc
Serial or parallel I/O control
1.8 V/3.3 V power supplies
APPLICATIONS
Agile LO frequency synthesis
Programmable clock generator
FM chirp source for radar and scanning systems
Test and measurement equipment
Acousto-optic device drivers
Polar modulator
Fast frequency hopping
FUNCTIONAL BLOCK DIAGRAM
AD9915
HIGH SPEED PARALLEL
MODULATION
PORT
2.5GSPS DDS CORE
REF CLK
MULTIPLIER
TIMING AND CONTROL
SERIAL OR PARALLEL
DATA PORT
12-BIT DAC
10837-001
LINEAR
SWEEP
BLOCK
Figure 1.
Rev. D
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AD9915
Data Sheet
TABLE OF CONTENTS
Features .............................................................................................. 1
12-Bit DAC Output .................................................................... 20
Applications ....................................................................................... 1
DAC Calibration Output ........................................................... 20
Functional Block Diagram .............................................................. 1
Reconstruction Filter ................................................................. 20
Revision History ............................................................................... 2
Clock Input (REF_CLK/REF_CLK) ........................................ 21
General Description ......................................................................... 3
PLL Lock Indication .................................................................. 22
Specifications..................................................................................... 4
Output Shift Keying (OSK) ....................................................... 22
DC Specifications ......................................................................... 4
Digital Ramp Generator (DRG) ............................................... 23
AC Specifications.......................................................................... 5
Power-Down Control ................................................................ 27
Absolute Maximum Ratings............................................................ 8
Programming and Function Pins ................................................. 28
Thermal Performance .................................................................. 8
Serial Programming ....................................................................... 31
ESD Caution .................................................................................. 8
Control Interface—Serial I/O ................................................... 31
Pin Configuration and Function Descriptions ............................. 9
General Serial I/O Operation ................................................... 31
Typical Performance Characteristics ........................................... 12
Instruction Byte .......................................................................... 31
Equivalent Circuits ......................................................................... 16
Serial I/O Port Pin Descriptions .............................................. 31
Theory of Operation ...................................................................... 17
Serial I/O Timing Diagrams ..................................................... 32
Single Tone Mode ....................................................................... 17
MSB/LSB Transfers .................................................................... 32
Profile Modulation Mode .......................................................... 17
Parallel Programming (8-/16-Bit) ................................................ 33
Digital Ramp Modulation Mode .............................................. 17
Multiple Chip Synchronization .................................................... 34
Parallel Data Port Modulation Mode....................................... 17
Register Map and Bit Descriptions .............................................. 36
Programmable Modulus Mode................................................. 17
Register Bit Descriptions ........................................................... 41
Mode Priority .............................................................................. 18
Outline Dimensions ....................................................................... 47
Functional Block Detail ................................................................. 19
Ordering Guide .......................................................................... 47
DDS Core..................................................................................... 19
REVISION HISTORY
1/14—Rev. C to Rev. D
Change to Maximum DAC Calibration Time Parameter ............ 5
Change to Figure 23 ........................................................................15
Changes to DAC Calibration Output Section..............................20
Change to Address 0x02, Table 16.................................................36
Changes to Table 19 .........................................................................43
11/13—Rev. B to Rev. C
Changes to Table 2 ............................................................................. 5
Changes to Programming and Function Pins Section ...............30
Changed PLL Charge Pump Section to PLL Charge Pump/
Total Feedback Divider Section; Changes to Table 8, PLL
Loop Filter Components Section, and Figure 34 ........................ 22
Change to Table 16 .......................................................................... 36
Changes to Bits [15:8], Table 19 .................................................... 43
8/12—Rev. 0 to Rev. A
Changed External Clock Frequency from 3.5 GHz to 2.5 GHz
and Differential Input Voltage Unit from mV p-p to V p-p ........4
Updated Outline Dimensions ....................................................... 47
7/12—Revision 0: Initial Version
7/13—Rev. A to Rev. B
Change to CMOS Logic Outputs Parameter, Table 1 ................... 4
Changes to Table 2 ............................................................................. 7
Changes to DDS Core Section .......................................................19
Changes to Phase-Locked Loop (PLL) Multiplier Section ........21
Rev. D | Page 2 of 48
Data Sheet
AD9915
GENERAL DESCRIPTION
AD9915 via a serial or parallel I/O port. The AD9915 also
supports a user defined linear sweep mode of operation for
generating linear swept waveforms of frequency, phase or
amplitude. A high speed, 32-bit parallel data input port is
included, enabling high data rates for polar modulation
schemes and fast reprogramming of the phase, frequency,
and amplitude tuning words.
The AD9915 is a direct digital synthesizer (DDS) featuring a
12-bit DAC. The AD9915 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 1.0 GHz. The AD9915
enables fast frequency hopping and fine tuning resolution
(64-bit capable using programmable modulus mode). The
AD9915 also offers fast phase and amplitude hopping capability.
The frequency tuning and control words are loaded into the
The AD9915 is specified to operate over the extended industrial
temperature range (see the Absolute Maximum Ratings section).
AD9915
OUTPUT
SHIFT
KEYING
OSK
DRCTL
DRHOLD
2
DIGITAL
RAMP
GENERATOR
DROVER
3
PS[2:0]
I/O_UPDATE
32
INTERNAL
PROGRAMMING
REGISTERS
DDS
DAC_RSET
AMPLITUDE (A)
A
Acos (ωt + θ)
PHASE (θ)
DATA
θ
ROUTE
FREQUENCY (ω)
Asin (ωt + θ)
AND
ω
PARTITION
CONTROL
CLOCK
DAC
12-BIT
SYSCLK
AOUT
AOUT
REF_CLK
REF_CLK
INTERNAL CLOCK TIMING
AND CONTROL
PLL
D0 TO D31
4
F0 TO F3
POWERDOWN
CONTROL
MULTICHIP
SYNCHRONIZATION
Figure 2. Detailed Block Diagram
Rev. D | Page 3 of 48
10837-002
MASTER_RESET
LOOP_FILTER
SYNC_IN
SYNC_OUT
EXT_PWR_DWN
SYNC_CLK
AD9915
Data Sheet
SPECIFICATIONS
DC SPECIFICATIONS
AVDD (1.8V) and DVDD (1.8V) = 1.8 V ± 5%, AVDD (3.3V) and DVDD_I/O (3.3V) = 3.3 V ± 5%, TA = 25°C, RSET = 3.3 kΩ,
IOUT = 20 mA, external reference clock frequency = 2.5 GHz with reference clock (REF CLK) multiplier bypassed, unless otherwise noted.
Table 1.
Parameter
Min
Typ
Max
Unit
Test Conditions/Comments
SUPPLY VOLTAGE
DVDD_I/O
DVDD
AVDD (3.3V)
3.135
1.71
3.135
3.30
1.80
3.30
3.465
1.89
3.465
V
V
V
1.71
1.80
1.89
V
20
270
640
mA
mA
mA
148
mA
Pin 16, Pin 83
Pin 6, Pin 23, Pin 73
Pin 34, Pin 36, Pin 39, Pin 40, Pin 43, Pin 47, Pin 50, Pin 52,
Pin 53, Pin 60
Pin 32, Pin 56, Pin 57
See also the total power dissipation specifications
Pin 16, Pin 83
Pin 6, Pin 23, Pin 73
Pin 34, Pin 36, Pin 39, Pin 40, Pin 43, Pin 47, Pin 50, Pin 52,
Pin 53, Pin 60
Pin 32, Pin 56, Pin 57
AVDD (1.8V)
SUPPLY CURRENT
IDVDD_I/O
IDVDD
IAVDD(3.3V)
IAVDD(1.8V)
TOTAL POWER DISSIPATION
Base DDS Power, PLL Disabled
2138
2797
mW
Base DDS Power, PLL Enabled
2237
2890
mW
Linear Sweep Additional Power
Modulus Additional Power
Amplitude Scaler Additional
Power
Full Power-Down Mode
28
20
138
CMOS LOGIC INPUTS
Input High Voltage (VIH)
Input Low Voltage (VIL)
Input Current (IINH, IINL)
Maximum Input Capacitance (CIN)
CMOS LOGIC OUTPUTS
Output High Voltage (VOH)
Output Low Voltage (VOL)
REF CLK INPUT CHARACTERISTICS
REF CLK Multiplier Bypassed
Input Capacitance
Input Resistance
Internally Generated DC Bias
Voltage
Differential Input Voltage
REF CLK Multiplier Enabled
Input Capacitance
Input Resistance
Internally Generated DC Bias
Voltage
Differential Input Voltage
400
2.0
±60
3
2.7
mW
mW
mW
mW
DVDD_I/O
0.8
±200
V
V
µA
pF
DVDD_I/O
0.4
V
V
IOH = 1 mA
IOL = 1 mA
REF CLK inputs should always be ac-coupled (both singleended and differential)
pF
kΩ
V
Single-ended, each pin
Differential
1.5
1
1.4
2
0.8
Manual or automatic
616
1
1.4
2
0.8
2.5 GHz, single-tone mode, modules disabled, linear
sweep disabled, amplitude scaler disabled
2.5 GHz, single-tone mode, modules disabled, linear
sweep disabled, amplitude scaler disabled
At VIN = 0 V and VIN = DVDD_I/O
V p-p
pF
kΩ
V
1.5
Using either the power-down and enable register or the
EXT_PWR_DWN pin
V p-p
Rev. D | Page 4 of 48
Single-ended, each pin
Differential
Data Sheet
AD9915
AC SPECIFICATIONS
AVDD (1.8V) and DVDD (1.8V) = 1.8 V ± 5%, AVDD3 (3.3V) and DVDD_I/O (3.3V) = 3.3 V ± 5%, TA = 25°C, RSET = 3.3 kΩ, IOUT =
20 mA, external reference clock frequency = 2.5 GHz with reference clock (REF CLK) multiplier bypassed, unless otherwise noted.
Table 2.
Parameter
REF CLK INPUT
REF CLK Multiplier Bypassed
Input Frequency Range
Duty Cycle
Minimum Differential Input Level
System Clock (SYSCLK) PLL Enabled
VCO Frequency Range
VCO Gain (KV)
Maximum PFD Rate
CLOCK DRIVERS
SYNC_CLK Output Driver
Frequency Range
Duty Cycle
Rise Time/Fall Time (20% to 80%)
SYNC_OUT Output Driver
Frequency Range
Duty Cycle
Rise Time (20% to 80%)
Fall Time (20% to 80%)
DAC OUTPUT CHARACTERISTICS
Output Frequency Range (1st Nyquist
Zone)
Output Resistance
Output Capacitance
Full-Scale Output Current
Gain Error
Output Offset
Voltage Compliance Range
Min
Typ
500
45
632
2400
Max
Unit
Test Conditions/Comments
Input frequency range
2500
55
MHz
%
mV p-p
Maximum fOUT is 0.4 × fSYSCLK
2500
60
125
45
50
650
MHz
MHz/V
MHz
156
55
MHz
%
ps
6.5
66
MHz
%
ps
ps
1250
MHz
10 pF load
33
1350
1670
0
50
Ω
1
20.48
+10
0.6
AVDD +
0.50
−10
AVDD −
0.50
pF
mA
% FS
μA
V
Wideband SFDR
122.5 MHz Output
305.3 MHz Output
497.5 MHz Output
978.2 MHz Output
Narrow-Band SFDR
122.5 MHz Output
305.3 MHz Output
497.5 MHz Output
978.2 MHz Output
DIGITAL TIMING SPECIFICATIONS
Time Required to Enter Power-Down
Time Required to Leave Power-Down
Minimum Master Reset time
Maximum DAC Calibration Time (tCAL)
Maximum PLL Calibration Time (tREF_CLK)
Maximum Profile Toggle Rate
Equivalent to 316 mV swing on each leg
−67
−66
−59
−60
dBc
dBc
dBc
dBc
−95
−95
−95
−92
dBc
dBc
dBc
dBc
45
ns
250
188
ns
SYSCLK cycles
μs
16
8
2
ms
ms
SYNC_CLK period
24
Rev. D | Page 5 of 48
CFR2 register, Bit 9 = 1
10 pF load
10 pF load
Single-ended (each pin internally terminated to
AVDD (3.3V))
Range depends on DAC RSET resistor
See the Typical Performance Characteristics
section
0 MHz to 1250 MHz
0 MHz to 1250 MHz
0 MHz to 1250 MHz
0 MHz to 1250 MHz
See the Typical Performance Characteristics
section
±500 kHz
±500 kHz
±500 kHz
±500 kHz
Power-down mode loses DAC/PLL calibration
settings
Must recalibrate DAC/PLL
See the DAC Calibration Output section for
formula; Bit 6 in Register 0x1B = 0
PFD rate = 25 MHz
PFD rate = 50 MHz
AD9915
Parameter
PARALLEL PORT TIMING
Write Timing
Address Setup Time to WR Active
Data Sheet
Min
Max
1
Address Hold Time to WR Inactive
Data Setup Time to WR Inactive
Typ
Unit
ns
0
3.8
ns
ns
Data Hold Time to WR Inactive
0
WR Minimum Low Time
WR Minimum High Time
Minimum WR Time
2.1
ns
3.8
ns
10.5
ns
92
0
ns
ns
Read Timing
Address to Data Valid
Address Hold to RD Inactive
RD Active to Data Valid
RD Inactive to Data Tristate
RD Minimum Low Time
RD Minimum High Time
SERIAL PORT TIMING
SCLK Clock Rate (1/tCLK )
SCLK Pulse Width High, tHIGH
SCLK Pulse Width Low, tLOW
SDIO to SCLK Setup Time, tDS
SDIO to SCLK Hold Time, tDH
SCLK Falling Edge to Valid Data on
SDIO/SDO, tDV
CS to SCLK Setup Time, tS
CS to SCLK Hold Time, tH
CS Minimum Pulse Width High, tPWH
DATA PORT TIMING
D[31:0] Setup Time to SYNC_CLK
D[31:0] Hold Time to SYNC_CLK
F[3:0] Setup Time to SYNC_CLK
F[3:0] Hold Time to SYNC_CLK
IO_UPDATE Pin Setup Time to
SYNC_CLK
IO_UPDATE Pin Hold Time to
SYNC_CLK
Profile Pin Setup Time to SYNC_CLK
Profile Pin Hold Time to SYNC_CLK
DR_CTL/DR_HOLD Setup Time to
SYNC_CLK
DR_CTL/DR_HOLD Hold Time to
SYNC_CLK
Test Conditions/Comments
ns
69
ns
50
ns
69
ns
50
ns
80
MHz
ns
ns
ns
ns
ns
1.5
5.1
4.9
0
78
4
ns
0
4
ns
ns
2
0
2
0
2
ns
ns
ns
ns
ns
0
ns
0
ns
ns
ns
0
ns
2
2
Rev. D | Page 6 of 48
SCLK duty cycle = 50%
Data Sheet
Parameter
DATA LATENCY (PIPELINE DELAY)
Single Tone Mode or Profile Mode
(Matched Latency Disabled)
Frequency
Phase
Amplitude
Single Tone Mode or Profile Mode
(Matched Latency Enabled)
Frequency
Phase
Amplitude
Modulation Mode with 32-Bit Parallel
Port (Match Latency Disabled)
Frequency
Phase
Amplitude
Modulation Mode with 32-Bit Parallel
Port (Match Latency Enabled)
Frequency
Phase
Amplitude
Sweep Mode (Match Latency Disabled)
Frequency
Phase
Amplitude
Sweep Mode (Match Latency Enabled)
Frequency
Phase
Amplitude
AD9915
Min
Typ
Max
Unit
Test Conditions/Comments
SYSCLK cycles = fS = system clock frequency
in GHz
222
238
206
222
78
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
OSK disabled
OSK enabled
OSK disabled
OSK enabled
OSK enabled
222
238
222
238
238
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
OSK disabled
OSK enabled
OSK disabled
OSK enabled
OSK enabled
222
238
206
222
78
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
OSK disabled
OSK enabled
OSK disabled
OSK enabled
OSK enabled
222
238
222
238
238
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
OSK disabled
OSK enabled
OSK disabled
OSK enabled
OSK enabled
238
254
222
238
94
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
OSK disabled
OSK enabled
OSK disabled
OSK enabled
OSK enabled
238
254
238
254
254
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
SYSCLK cycles
OSK disabled
OSK enabled
OSK disabled
OSK enabled
OSK enabled
Rev. D | Page 7 of 48
AD9915
Data Sheet
ABSOLUTE MAXIMUM RATINGS
THERMAL PERFORMANCE
Table 3.
Parameter
AVDD (1.8V), DVDD (1.8V) Supplies
AVDD (3.3V), DVDD_I/O (3.3V) Supplies
Digital Input Voltage
Digital Output Current
Storage Temperature Range
Operating Temperature Range
Maximum Junction Temperature
Lead Temperature (10 sec Soldering)
Rating
2V
4V
−0.7 V to +4 V
5 mA
−65°C to +150°C
−40°C to +85°C
150°C
300°C
Stresses above those listed under Absolute Maximum Ratings
may cause permanent damage to the device. This is a stress
rating only; functional operation of the device at these or any
other conditions above those indicated in the operational
section of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect
device reliability.
Table 4.
Symbol
θJA
θJMA
θJMA
θJB
ΨJB
θJC
ΨJT
1
Description
Junction-to-ambient thermal
resistance (still air) per JEDEC
JESD51-2
Junction-to-ambient thermal
resistance (1.0 m/sec airflow)
per JEDEC JESD51-6
Junction-to-ambient thermal
resistance (2.0 m/sec air flow)
per JEDEC JESD51-6
Junction-to-board thermal
resistance (still air) per JEDEC
JESD51-8
Junction-to-board characterization
parameter (still air) per JEDEC
JESD51-6
Junction-to-case thermal resistance
Junction-to-top-of-package
characterization parameter (still air)
per JEDEC JESD51-2
Value1
24.1
Unit
°C/W
21.3
°C/W
20.0
°C/W
13.3
°C/W
12.8
°C/W
2.21
0.23
°C/W
°C/W
Results are from simulations. PCB is JEDEC multilayer. Thermal performance
for actual applications requires careful inspection of the conditions in the
application to determine if they are similar to those assumed in these
calculations.
ESD CAUTION
Rev. D | Page 8 of 48
Data Sheet
AD9915
88
87
86
85
84
83
82
81
80
79
78
77
76
75
74
73
72
71
70
69
68
67
D18
D19
I/O_UPDATE
MASTER_RESET
DGND
DVDD_I/O (3.3V)
SYNC_CLK
D20
D21
D22
D23
D24
D25
D26
DGND
DVDD (1.8V)
D27
D28
D29
D30
D31
EXT_PWR_DWN
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
AD9915
TOP VIEW
(Not to Scale)
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
OSK
DROVER
DRHOLD
DRCTL
SYNC_IN
SYNC_OUT
AVDD (3.3V)
REF
LOOP_FILTER
AVDD (1.8V)
AVDD (1.8V)
REF CLK
REF CLK
AVDD (3.3V)
AVDD (3.3V)
AGND
AVDD (3.3V)
AGND
DAC_RSET
AVDD (3.3V)
AGND
DAC_BP
NOTES
1. THE EPAD MUST BE SOLDERED TO GROUND.
10837-003
DVDD (1.8V)
DGND
PS0
PS1
PS2
F0
F1
F2
F3
AVDD (1.8V)
AGND
AVDD (3.3V)
AGND
AVDD (3.3V)
AGND
AGND
AVDD (3.3V)
AVDD (3.3V)
AOUT
AOUT
AVDD (3.3V)
AGND
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
D17
D16
D15/A7
D14/A6
D13/A5
DVDD (1.8V)
DGND
D12/A4
D11/A3
D10/A2
D9/A1
D8/A0
D7
D6
D5
DVDD_I/O (3.3V)
DGND
D4/SYNCIO
D3/SDO
D2/SDIO/WR
D1/SCLK/RD
D0/CS/PWD
Figure 3. Pin Configuration
Table 5. Pin Function Descriptions
Pin No.
1, 2, 13 to 15, 68
to 72, 75 to 81,
87, 88
Mnemonic
D5 to D7, D16 to
D31, D27 to D31
I/O 1
I/O
3
D15/A7
I/O
4
D14/A6
I/O
5
D13/A5
I/O
8
D12/A4
I/O
9
D11/A3
I/O
10
D10/A2
I/O
11
D9/A1
I/O
Description
Parallel Port Pins. The 32-bit parallel port offers the option for serial or parallel programming
of the internal registers. In addition, the parallel port can be configured to provide direct FSK,
PSK, or ASK (or combinations thereof ) modulation data. The 32-bit parallel port configuration
is set by the state of the four function pins (F0 to F3).
Parallel Port Pin/Address Line. The state of the F0 to F3 function pins determines if this pin
acts as a line for direct FSK, PSK, or ASK data or as an address line for programming the
internal registers.
Parallel Port Pin/Address Line. The state of the F0 to F3 function pins determines if this pin
acts as a line for direct FSK, PSK, or ASK data or as an address line for programming the
internal registers.
Parallel Port Pin/Address Line. The state of the F0 to F3 function pins determines if this pin
acts as a line for direct FSK, PSK, or ASK data or as an address line for programming the
internal registers.
Parallel Port Pin/Address Line. The state of the F0 to F3 function pins determines if this pin
acts as a line for direct FSK, PSK, or ASK data or as an address line for programming the
internal registers.
Parallel Port Pin/Address Line. The state of the F0 to F3 function pins determines if this pin
acts as a line for direct FSK, PSK, or ASK data or as an address line for programming the
internal registers.
Parallel Port Pin/Address Line. Multipurpose pin depending on the state of the function pins
(F0 to F3). The state of the F0 to F3 function pins determines if this pin acts as a line for direct
FSK, PSK, or ASK data or as an address line for programming the internal registers.
Parallel Port Pin/Address Line. Multipurpose pin depending on the state of the function pins
(F0 to F3). The state of the F0 to F3 function pins determines if this pin acts as a line for direct
FSK, PSK, or ASK data or as an address line for programming the internal registers.
Rev. D | Page 9 of 48
AD9915
Data Sheet
Pin No.
12
Mnemonic
D8/A0
I/O 1
I/O
18
D4/SYNCIO
I
19
D3/SDO
I/O
20
D2/SDIO/WR
I/O
21
D1/SCLK/RD
I
22
D0/CS/PWD
I
6, 23, 73
7, 17, 24, 74, 84
16, 83
32, 56, 57
33, 35, 37, 38,
44, 46, 49, 51
34, 36, 39, 40,
43, 47, 50, 52,
53, 60
25, 26, 27
DVDD (1.8V)
DGND
DVDD_I/O (3.3V)
AVDD (1.8V)
AGND
I
I
I
I
I
Description
Parallel Port Pin/Address Line. The state of the F0 to F3 function pins determines if this pin
acts as a line for direct FSK, PSK, or ASK data or as an address line for programming the
internal registers.
Parallel Port Pin/Serial Port Synchronization Pin. This pin is D4 for direct FSK, PSK, or ASK data.
If serial mode is invoked via F0 to F3, this pin is used to reset the serial port.
Parallel Port Pin/Serial Data Output This pin is D3 for direct FSK, PSK, or ASK data. If serial
mode is invoked via F0 to F3, this pin is used for readback mode for serial operation.
Parallel Port Pin/Serial Data Input and Output/Write Input. This pin is D2 for direct FSK, PSK,
or ASK data. If serial mode is invoked via F0 to F3, this pin is used for the SDIO for serial
operation. If parallel mode is enabled, this pin is used to write to change the values of the
internal registers.
Parallel Port Pin/Serial Clock/Read Input. This pin is D1 for direct FSK, PSK, or ASK data. If
serial mode is invoked via F0 to F3, this pin is used for SCLK for serial operation. If parallel
mode is enabled, this pin is used to read back the value of the internal registers.
Parallel Port Pin/Chip Select/Parallel Width. This pin is D0 for direct FSK, PSK, or ASK data. If
serial mode is invoked via F0 to F3, this pin is used for the chip select for serial operation. If
parallel mode is enabled, this pin is used to set either 8-bit data or 16-bit data.
Digital Core Supplies (1.8 V).
Digital Ground.
Digital Input/Output Supplies (3.3 V).
Analog Core Supplies (1.8 V).
Analog Ground.
AVDD (3.3V)
I
Analog DAC Supplies (3.3 V).
PS0 to PS2
I
28, 29, 30, 31
F0 to F3
I
41
AOUT
O
42
AOUT
O
45
DAC_BP
I
48
DAC_RSET
O
54
55
58
59
61
62
63
64
65
REF_CLK
REF_CLK
LOOP_FILTER
REF
SYNC_OUT
SYNC_IN
DRCTL
DRHOLD
DROVER
I
I
O
O
O
I
I
I
O
66
OSK
I
Profile Select Pins. Digital inputs (active high). Use these pins to select one of eight
phase/frequency profiles for the DDS. Changing the state of one of these pins transfers the
current contents of all I/O buffers to the corresponding registers. State changes should be set
up on the SYNC_CLK pin (Pin 82).
Function Pins. Digital inputs. The state of these pins determines if a serial or parallel interface
is used. In addition, the function pins determine how the 32-bit parallel data-word is
partitioned for FSK, PSK, or ASK modulation mode.
DAC Complementary Output Source. Analog output (voltage mode). Internally connected
through a 50 Ω resistor to AVDD (3.3V).
DAC Output Source. Analog output (voltage mode). Internally connected through a 50 Ω
resistor to AVDD (3.3V).
DAC Bypass Pin. Provides access to the common control node of the DAC current sources.
Connecting a capacitor between this pin and ground can improve noise performance at the
DAC output.
Analog Reference. This pin programs the DAC output full-scale reference current. Connect a
3.3 kΩ resistor to AGND.
Complementary Reference Clock Input. Analog input.
Reference Clock Input. Analog input.
External PLL Loop Filter Node.
Local PLL Reference Supply. Typically at 2.05 V.
Digital Synchronization Output. Used to synchronize multiple chips.
Digital Synchronization Input. Used to synchronize multiple chips.
Ramp Control. Digital input (active high). This pin controls the sweep direction (up/down).
Ramp Hold. Digital input (active high). Pauses the sweep when active.
Ramp Over. Digital output (active high). This pin switches to Logic 1 when the digital ramp
generator reaches its programmed upper or lower limit.
Output Shift Keying. Digital input (active high). When the OSK features are placed in either
manual or automatic mode, this pin controls the OSK function. In manual mode, it toggles
the multiplier between 0 (low) and the programmed amplitude scale factor (high). In
automatic mode, a low sweeps the amplitude down to zero and a high sweeps the
amplitude up to the amplitude scale factor.
Rev. D | Page 10 of 48
Data Sheet
AD9915
Pin No.
67
Mnemonic
EXT_PWR_DWN
I/O 1
I
82
SYNC_CLK
O
85
MASTER_RESET
I
86
I/O_UPDATE
I
EPAD
1
Description
External Power-Down. Digital input (active high). A high level on this pin initiates the
currently programmed power-down mode.
Clock Output. Digital output. Many of the digital inputs on the chip, such as I/O_UPDATE,
PS[2:0], and the parallel data port (D0 to D31), must be set up on the rising edge of
this signal.
Master Reset. Digital input (active high). Clears all memory elements and sets registers to
default values.
Input/Output Update. Digital input (active high). A high on this pin transfers the contents of
the I/O buffers to the corresponding internal registers.
Exposed Pad. The EPAD must be soldered to ground.
I = input, O = output.
Rev. D | Page 11 of 48
AD9915
Data Sheet
TYPICAL PERFORMANCE CHARACTERISTICS
0
0
–10
–10
–20
–20
–30
–30
–40
–40
SFDR (dBc)
–50
–60
–50
–60
–70
–70
–80
–80
–90
START 0Hz
125MHz/DIV
STOP 1.25GHz
–100
0
0
–10
–10
–20
–20
–30
–30
–40
–40
–50
–60
–60
–70
–80
–80
START 0Hz
125MHz/DIV
STOP 1.25GHz
–100
0
–10
–10
–20
–20
–30
–30
–40
–40
SFDR (dBc)
0
–50
–60
–80
–80
–90
–90
STOP 1.25GHz
SPAN 500kHz
–60
–70
125MHz/DIV
50kHz/DIV
–50
–70
START 0Hz
CENTER 305.357MHz
Figure 8. Narrow-Band SFDR at 305.3 MHz,
SYSCLK = 2.5 GHz (SYSCLK PLL Bypassed)
10837-006
SFDR (dBc)
Figure 5. Wideband SFDR at 305.3 MHz
SYSCLK = 2.5 GHz (SYSCLK PLL Bypassed)
10837-008
–90
10837-005
–90
–100
SPAN 500kHz
–50
–70
–100
50kHz/DIV
Figure 7. Narrow-Band SFDR at 122.5 MHz,
SYSCLK = 2.5 GHz (SYSCLK PLL Bypassed)
SFDR (dBc)
SFDR (dBc)
Figure 4. Wideband SFDR at 122.5 MHz
SYSCLK = 2.5 GHz (SYSCLK PLL Bypassed)
CENTER 122.499MHz
10837-007
–90
10837-004
–100
–100
Figure 6. Wideband SFDR at 497.5 MHz,
SYSCLK = 3.5 GHz (SYSCLK PLL Bypassed)
CENTER 497.499MHz
50kHz/DIV
SPAN 500kHz
Figure 9. Narrow-Band SFDR at 497.5 MHz,
SYSCLK = 2.5 GHz (SYSCLK PLL Bypassed)
Rev. D | Page 12 of 48
10837-009
SFDR (dBc)
Nominal supply voltage; DAC RSET = 3.3 kΩ, TA = 25°C, unless otherwise noted.
AD9915
0
0
–10
–10
–20
–20
–30
–30
–40
–40
SFDR (dBc)
–50
–60
–50
–60
–70
–70
–80
–80
–90
–90
START 0Hz
125MHz/DIV
STOP 1.25GHz
10837-010
–100
–100
CENTER 978.214MHz
Figure 10. Wideband SFDR at 978.2 MHz,
SYSCLK = 2.5 GHz (SYSCLK PLL Bypassed)
50kHz/DIV
SPAN 500kHz
10837-013
SFDR (dBc)
Data Sheet
Figure 13. Narrow-Band SFDR at 978.2 MHz,
SYSCLK = 2.5 GHz (SYSCLK PLL Bypassed)
–70
0
–80
–10
–90
PHASE NOISE (dBc/Hz)
SFDR (dBc)
–20
–30
–40
–50
–100
–110
–120
–130
–140
SMA AND
ADCLK925
–60
–150
0
0.05
0.10
0.15
0.20
0.25
0.30
0.35
0.40
fC/fS
Figure 11. Wideband SFDR vs. Normalized fOUT
SYSCLK = 2.5 GHz
0
–30
–40
1k
10k
100k
1M
FREQUENCY OFFSET (Hz)
10M
100M
–70
–80
–90
PHASE NOISE (dBc/Hz)
–20
100
Figure 14. Absolute Phase Noise of REF CLK Source Driving AD9915
Rohde & Schwarz SMA100 Signal Generator at 2.5 GHz Buffered by Series
ADCLK925
SYSCLK = 1.5GHz
SYSCLK = 1.6GHz
SYSCLK = 1.7GHz
SYSCLK = 1.8GHz
SYSCLK = 1.9GHz
SYSCLK = 2.0GHz
SYSCLK = 2.1GHz
SYSCLK = 2.2GHz
SYSCLK = 2.3GHz
SYSCLK = 2.4GHz
SYSCLK = 2.5GHz
–10
–170
10
10837-011
–80
–50
–60
–100
–110
978MHz
–120
497MHz
–130
–140
–150
305MHz
–70
–160
0
0.05
0.10
0.15
0.20
0.25
0.30
0.35
fC/fS
Figure 12. Wideband SFDR vs. Normalized fOUT,
SYSCLK = 2.5 GHz to 2.5 GHz
0.40
–170
10
100
1k
10k
100k
1M
FREQUENCY OFFSET (Hz)
10M
100M
10837-015
123MHz
–80
10837-012
SFDR (dBc)
SMA
–160
10837-014
–70
Figure 15. Absolute Phase Noise Curves of DDS Output at 2.5 GHz Operation
Rev. D | Page 13 of 48
Data Sheet
–70
–70
–80
–80
–90
–90
PHASE NOISE (dBc/Hz)
–100
–110
978MHz
–130
–140
NORMALIZED
REF CLK SOURCE
–150
497MHz
–130
305MHz
–140
123MHz
–160
1k
10k
100k
1M
FREQUENCY OFFSET (Hz)
10M
100M
–170
10
10837-016
100
Figure 16. Absolute Phase Noise Curves of Normalized REF CLK Source to
DDS Output at 978.5 MHz (SYSCLK = 2.5 GHz)
100
1k
10k
100k
1M
FREQUENCY OFFSET (Hz)
10M
100M
Figure 19. Absolute Phase Noise Curves of DDS Output Using Internal PLL at
2.5 GHz Operation
–60
–60
–70
–70
–80
–80
PHASE NOISE (dBc/Hz)
–90
–100
–110
–120
978MHz
–130
497MHz
–140
–150
–100
–110
978MHz ABSOLUTE
–120
–130
305MHz
–150
–170
–180
10
–90
–140
–160
978MHz RESIDUAL
123MHz
100
1k
10k
100k
1M
FREQUENCY OFFSET (Hz)
10M
100M
–160
10
10837-017
PHASE NOISE (dBc/Hz)
–120
–150
–160
–170
10
978MHz
–110
10837-019
–120
–100
Figure 17. Residual Phase Noise Curves
100
1k
10k
100k
1M
FREQUENCY OFFSET (Hz)
10M
100M
10837-020
PHASE NOISE (dBc/Hz)
AD9915
Figure 20. Residual PN vs. Absolute PN Measurement Curves at 978.5 MHz
–60
0.5
3.3V ANALOG
–70
–80
PHASE NOISE (dBc/Hz)
0.3
1.8V DIGITAL
0.2
1.8V ANALOG
–90
–100
–110
978MHz ABSOLUTE
–120
–130
–140
–150
978MHz RESIDUAL
0.1
–160
1000
1500
2000
SYSTEM CLOCK (MHz)
Figure 18. Power Supply Current vs. SYSCLK
2500
–180
10
100
1k
10k
100k
1M
FREQUENCY OFFSET (Hz)
10M
100M
10837-021
–170
3.3V DIGITAL
0
500
10837-018
SUPPLY CURRENT (A)
0.4
Figure 21. Residual Phase Noise vs. Normalized Absolute REF CLK Source
Phase Noise at 978.5 MHz
Rev. D | Page 14 of 48
Data Sheet
AD9915
930
FREQUENCY (MHz)
920
2
910
900
890
M20.00ms 5.0GS/s IT 40.0ps/pt
A CH2
1.64V
870
–6
–4
–2
0
2
4
6
TIME (ms)
10837-024
CH2 1.0V Ω
10837-022
880
Figure 24. Measured Rising Linear Frequency Sweep
Figure 22. SYNC_OUT (fSYSCLK/384)
930
1.0
0.9
920
0.8
FREQUENCY (MHz)
TIME (ms)
0.7
0.6
0.5
0.4
0.3
0.2
910
900
890
880
1000
1500
2000
SYSTEM CLOCK RATE (MHz)
2500
Figure 23. DAC Calibration Time vs. SYSCLK Rate. See the DAC Calibration
Output section for formula.
Rev. D | Page 15 of 48
870
–6
–4
–2
0
2
4
TIME (ms)
Figure 25. Measured Falling Linear Frequency Sweep
6
10837-025
0
500
10837-023
0.1
AD9915
Data Sheet
EQUIVALENT CIRCUITS
AGND
IFS
CURRENT
SWITCH
ARRAY
SWITCH
CONTROL
CURRENT
SWITCH
ARRAY
IFS/2 + ICODE
DVDD (3.3V)
IFS/2 – ICODE
CODE
41
INTERNAL
50Ω
10837-044
INTERNAL
50Ω
AOUT
AVDD (3.3V)
10837-045
AOUT 42
Figure 28. CMOS Input
Figure 26. DAC Output
AVDD (3.3V)
DVDD (3.3V)
REF_CLK
10837-043
10837-048
REF_CLK
Figure 29. CMOS Output
Figure 27. REF CLK input
Rev. D | Page 16 of 48
Data Sheet
AD9915
THEORY OF OPERATION
the profile change must meet the setup and hold times to the
SYNC_CLK rising edge. Note that amplitude control must also
be enabled using the OSK enable bit in the CFR1 register (0x00[8]).
The AD9915 has five modes of operation.
• Single tone
• Profile modulation
• Digital ramp modulation (linear sweep)
• Parallel data port modulation
• Programmable modulus mode
DIGITAL RAMP MODULATION MODE
The modes define the data source used to supply the DDS with
its signal control parameters: frequency, phase, or amplitude.
The partitioning of the data into different combinations of
frequency, phase, and amplitude is established based on the
mode and/or specific control bits and function pins.
Although the various modes are described independently, they
can be enabled simultaneously. This provides an unprecedented
level of flexibility for generating complex modulation schemes.
However, to avoid multiple data sources from driving the same
DDS signal control parameter, the device has a built-in priority
protocol.
In single tone mode, the DDS signal control parameters come
directly from the profile programming registers. In digital ramp
modulation mode, the DDS signal control parameters are delivered
by a digital ramp generator. In parallel data port modulation mode,
the DDS signal control parameters are driven directly into the
parallel port.
The various modulation modes generally operate on only one of
the DDS signal control parameters (two in the case of the polar
modulation format via the parallel data port). The unmodulated
DDS signal control parameters are stored in programming
registers and automatically routed to the DDS based on the
selected mode.
A separate output shift keying (OSK) function is also available.
This function employs a separate digital linear ramp generator
that affects only the amplitude parameter of the DDS. The OSK
function has priority over the other data sources that can drive
the DDS amplitude parameter. As such, no other data source
can drive the DDS amplitude when the OSK function is enabled.
SINGLE TONE MODE
In single tone mode, the DDS signal control parameters are
supplied directly from the profile programming registers. A
profile is an independent register that contains the DDS signal
control parameters. Eight profile registers are available. Note
that the profile pins must be used to select the desired register.
PROFILE MODULATION MODE
Each profile is independently accessible. For FSK, PSK, or ASK
modulation, use the three external profile pins (PS[2:0]) to select
the desired profile. A change in the state of the profile pins with
the next rising edge on SYNC_CLK updates the DDS with the
parameters specified by the selected profile. Therefore,
In digital ramp modulation mode, the modulated DDS signal
control parameter is supplied directly from the digital ramp
generator (DRG). The ramp generation parameters are
controlled through the serial or parallel I/O port.
The ramp generation parameters allow the user to control both
the rising and falling slopes of the ramp. The upper and lower
boundaries of the ramp, the step size and step rate of the rising
portion of the ramp, and the step size and step rate of the falling
portion of the ramp are all programmable.
The ramp is digitally generated with 32-bit output resolution.
The 32-bit output of the DRG can be programmed to affect
frequency, phase, or amplitude. When programmed for frequency,
all 32 bits are used. However, when programmed for phase or
amplitude, only the 16 MSBs or 12 MSBs, respectively, are used.
The ramp direction (rising or falling) is externally controlled by
the DRCTL pin. An additional pin (DRHOLD) allows the user
to suspend the ramp generator in its present state. Note that
amplitude control must also be enabled using the OSK enable
bit in Register CFR1.
PARALLEL DATA PORT MODULATION MODE
In parallel data port modulation mode, the modulated DDS
signal control parameter(s) are supplied directly from the 32-bit
parallel data port. The function pins define how the 32-bit dataword is applied to the DDS signal control parameters. Formatting of the 32-bit data-word is unsigned binary, regardless of the
destination.
Parallel Data Clock (SYNC_CLK)
The AD9915 generates a clock signal on the SYNC_CLK pin
that runs at 1/16 of the DAC sample rate (the sample rate of the
parallel data port). SYNC_CLK serves as a data clock for the
parallel port.
PROGRAMMABLE MODULUS MODE
In programmable modulus mode, the DRG is used as an
auxiliary accumulator to alter the frequency equation of the
DDS core, making it possible to implement fractions that are
not restricted to a power of 2 in the denominator. A standard
DDS is restricted to powers of 2 as a denominator because the
phase accumulator is a set of bits as wide as the frequency
tuning word (FTW).
When in programmable modulus mode, however, the
frequency equation is:
f0 = (fS)(FTW + A/B)/232
where f0/fS < ½, 0 ≤ FTW < 231, 2 ≤ B ≤ 232 – 1, and A < B.
Rev. D | Page 17 of 48
AD9915
Data Sheet
This equation implies a modulus of B × 232 (rather than 232, in
the case of a standard DDS). Furthermore, because B is programmable, the result is a DDS with a programmable modulus.
When in programmable modulus mode, the 32-bit auxiliary
accumulator operates in a way that allows it to roll over at a
value other than its full capacity of 232. That is, it operates with a
modified modulus based on the programmable value of B. With
each roll over of the auxiliary accumulator, a value of 1 LSB adds to
the current accumulated value of the 32-bit phase accumulator.
This behavior changes the modulus of the phase accumulator to
B × 232 (instead of 232), allowing it to synthesize the desired f0.
To determine the programmable modulus mode register values
for FTW, A, and B, the user must first define f0/fS as a ratio of
relatively prime integers, M/N. That is, having converted f0 and
fS to integers, M and N, reduce the fraction, M/N, to its lowest
terms. Then, divide M × 232 by N. The integer part of this
division operation is the value of FTW (Register 0x04[31:0]).
The remainder, Y, of this division operation is
Y = (232 × M) – (FTW × N)
The value of Y facilitates the determination of A and B by
taking the fraction, Y/N, and reducing it to its lowest terms.
Then, the numerator of the reduced fraction is A (Register
0x06[31:0]) and the denominator is the B (Register 0x05[31:0]).
For example, synthesizing precisely 300 MHz with a 1 GHz
system clock is not possible with a standard DDS. It is possible,
however, using programmable modulus as follows.
First, express f0/fS as a ratio of integers:
300,000,000/1,000,000,000
Reducing this fraction to lowest terms yields 3/10; therefore,
M = 3 and N = 10. FTW is the integer part of (M × 232)/N, or
(3 × 232)/10, which is 1,288,490,188 (0x4CCCCCCC in 32-bit
hexadecimal notation). The remainder, Y, of (3 × 232)/10, is (232
× 3) − (1,288,490,188 × 10), which is 8. Therefore, Y/N is 8/10,
which reduces to 4/5. Therefore, A = 4 and B = 5 (0x00000004
and 0x00000005 in 32-bit hexadecimal notation, respectively).
Programming the AD9915 with these values of FTW, A, and B
results in an output frequency that is exactly 3/10 of the system
clock frequency.
MODE PRIORITY
The ability to activate each mode independently makes it possible
to have multiple data sources attempting to drive the same DDS
signal control parameter (frequency, phase, and amplitude). To
avoid contention, the AD9915 has a built-in priority system.
Table 6 summarizes the priority for each of the DDS modes.
The data source column in Table 6 lists data sources for a
particular DDS signal control parameter in descending order of
precedence. For example, if the profile mode enable bit and the
parallel data port enable bit (0x01[23:22]) are set to Logic 1 and
both are programmed to source the frequency tuning word to
DDS output, the profile modulation mode has priority over the
parallel data port modulation mode.
Table 6. Data Source Priority
Priority
Highest
Priority
Data Source
Programmable
modulus
DRG
Profiles
Lowest
Priority
Parallel port
DDS Signal Control Parameters
Conditions
If programmable modulus mode is used to output frequency only, no other data source can be used to
control the output frequency in this mode. Note that the DRG is used in conjunction with programmable
modulus mode; therefore, the DRG cannot be used to sweep phase or amplitude in programmable
modulus mode.
If output phase offset control is desired, enable profile mode and use the profile registers and profile
pins accordingly to control output phase adjustment.
If output amplitude control is desired, enable profile mode and use the profile registers and profile pins
accordingly to control output amplitude adjustment. Note that the OSK enable bit must be set to control
the output amplitude.
The digital ramp modulation mode is the next highest priority mode. If the DRG is enabled to sweep
output frequency, phase, or amplitude, the two parameters not being swept can be controlled
independently via the profile mode.
The profile modulation mode is the next highest priority mode. Profile mode can be used to control all
three parameters independently, if desired.
Parallel data port modulation has the lowest priority but the most flexibility as far as changing any
parameter at the high rate. See the Programming and Function Pins section.
Rev. D | Page 18 of 48
Data Sheet
AD9915
FUNCTIONAL BLOCK DETAIL
DDS CORE
POW
2π  14 
 2 
∆θ =
POW
360 14 
 2 
The direct digital synthesizer (DDS) block generates a reference
signal (sine or cosine based on 0x00[16], the enable sine output
bit). The parameters of the reference signal (frequency, phase,
and amplitude) are applied to the DDS at its frequency, phase
offset, and amplitude control inputs, as shown in Figure 30.
where the upper quantity is for the phase offset expressed as
radian units and the lower quantity as degrees.
The output frequency (fOUT) of the AD9915 is controlled by the
frequency tuning word (FTW) at the frequency control input to
the DDS. The relationship among fOUT, FTW, and fSYSCLK is given by
FTW
f OUT =  32  f SYSCLK
 2 
To find the POW value necessary to develop an arbitrary Δθ,
solve the preceding equation for POW and round the result (in
a manner similar to that described previously for finding an
arbitrary FTW).
(1)
The relative amplitude of the DDS signal can be digitally scaled
(relative to full scale) by means of a 12-bit amplitude scale factor
(ASF). The amplitude scale value is applied at the output of the
angle-to-amplitude conversion block internal to the DDS core.
The amplitude scale is given by
where FTW is a 32-bit integer ranging in value from 0 to
2,147,483,647 (231 − 1), which represents the lower half of the
full 32-bit range. This range constitutes frequencies from dc to
Nyquist (that is, ½ fSYSCLK).
The FTW required to generate a desired value of fOUT is found
by solving Equation 1 for FTW, as given in Equation 2.




Amplitude Scale =
(2)
To find the ASF value necessary for a particular scale factor, solve
Equation 3 for ASF and round the result (in a manner similar
to that described previously for finding an arbitrary FTW).
Programming an FTW greater than 231 produces an aliased
image that appears at a frequency given by
When the AD9915 is programmed to modulate any of the DDS
signal control parameters, the maximum modulation sample
rate is 1/16 fSYSCLK. This means that the modulation signal
exhibits images at multiples of 1/16 fSYSCLK. The impact of these
images must be considered when using the device as a
modulator.
(for FTW ≥ 231)
The relative phase of the DDS signal can be digitally controlled
by means of a 16-bit phase offset word (POW). The phase offset
is applied prior to the angle-to-amplitude conversion block
internal to the DDS core. The relative phase offset (Δθ) is given by
DDS SIGNAL CONTROL PARAMETERS
AMPLITUDE
CONTROL
12
PHASE
OFFSET
CONTROL
16
MSB ALIGNED
32-BIT
ACCUMULATOR
32
FREQUENCY 32
CONTROL
32
DQ
R
DDS_CLK
(3)
where the upper quantity is amplitude expressed as a fraction of
full scale and the lower quantity is expressed in decibels relative
to full scale.
where the round(x) function rounds the argument (the value of
x) to the nearest integer. This is required because the FTW is
constrained to be an integer value. For example, for fOUT =
41 MHz and fSYSCLK = 122.88 MHz, FTW = 1,433,053,867
(0x556AAAAB).
FTW
f OUT = 1 − 32  f SYSCLK
2 

ASF
20 log  12 
 2 
12
14
17
32 17
(MSBs)
ANGLE-TOAMPLITUDE 12
12
CONVERSION
(SINE OR
COSINE)
TO DAC
ACCUMULATOR
RESET
Figure 30. DDS Block Diagram
Rev. D | Page 19 of 48
10837-026
  f
FTW = round  2 32  OUT

  f SYSCLK
ASF
212
AD9915
Data Sheet
12-BIT DAC OUTPUT
RECONSTRUCTION FILTER
The AD9915 incorporates an integrated 12-bit, current output
DAC. The output current is delivered as a balanced signal using
two outputs. The use of balanced outputs reduces the potential
amount of common-mode noise present at the DAC output,
offering the advantage of an increased signal-to-noise ratio. An
external resistor (RSET) connected between the DAC_RSET pin
and AGND establishes the reference current. The recommended
value of RSET is 3.3 kΩ.
The DAC output signal appears as a sinusoid sampled at fS. The
frequency of the sinusoid is determined by the frequency tuning
word (FTW) that appears at the input to the DDS. The DAC
output is typically passed through an external reconstruction
filter that serves to remove the artifacts of the sampling process
and other spurs outside the filter bandwidth.
Because the DAC constitutes a sampled system, its output must
be filtered so that the analog waveform accurately represents the
digital samples supplied to the DAC input. The unfiltered DAC
output contains the desired baseband signal, which extends from
dc to the Nyquist frequency (fS/2). It also contains images of the
baseband signal that theoretically extend to infinity. Notice that
the odd numbered images (shown in Figure 31) are mirror
images of the baseband signal. Furthermore, the entire DAC
output spectrum is affected by a sin(x)/x response, which is
caused by the sample-and-hold nature of the DAC output signal.
Attention should be paid to the load termination to keep the
output voltage within the specified compliance range; voltages
developed beyond this range cause excessive distortion and can
damage the DAC output circuitry.
DAC CALIBRATION OUTPUT
The DAC CAL enable bit in the CFR4 control register (0x03[24])
must be manually set and then cleared after each power-up and
every time the REF CLK or internal system clock is changed.
This initiates an internal calibration routine to optimize the
setup and hold times for internal DAC timing. Failure to
calibrate may degrade performance and even result in loss of
functionality. The length of time to calibrate the DAC clock is
calculated from the following equation:
469,632
fS
Note that the time to calibrate is increased by the following
equation if multiple device synchronization is required. Refer to
Application Note AN-1254, Synchronizing Multiple AD9915
DDS-Based Synthesizers for multiple device synchronization.
t CAL =
Some applications operate from an image above the Nyquist
frequency, and those applications use a band-pass filter instead
of a low-pass filter. The design of the reconstruction filter has a
significant impact on the overall signal performance. Therefore,
good filter design and implementation techniques are important
for obtaining the best possible jitter results.
469,632
16
+
fS
f SYNCIN
MAGNITUDE
(dB)
IMAGE 0
IMAGE 1
IMAGE 2
IMAGE 3
IMAGE 4
0
–20
–40
PRIMARY
SIGNAL
FILTER
RESPONSE
SIN(x)/x
ENVELOPE
–60
–80
SPURS
f
–100
fs/2
fs
3fs/2
2 fs
BASE BAND
Figure 31. DAC Spectrum vs. Reconstruction Filter Response
Rev. D | Page 20 of 48
5fs/2
10837-027
t CAL =
For applications using the fundamental frequency of the DAC
output, the response of the reconstruction filter should preserve
the baseband signal (Image 0), while completely rejecting all other
images. However, a practical filter implementation typically exhibits
a relatively flat pass band that covers the desired output frequency
plus 20%, rolls off as steeply as possible, and then maintains
significant (though not complete) rejection of the remaining
images. Depending on how close unwanted spurs are to the
desired signal, a third-, fifth-, or seventh-order elliptic low-pass
filter is common.
Data Sheet
AD9915
CLOCK INPUT (REF_CLK/REF_CLK)
REF_CLK/REF_CLK Overview
The AD9915 supports a number of options for producing the
internal SYSCLK signal (that is, the DAC sample clock) via the
REF_CLK/REF_CLK input pins. The REF_CLK input can be
driven directly from a differential or single-ended source. There
is also an internal phase-locked loop (PLL) multiplier that can
be independently enabled. However, the PLL limits the SYSCLK
signal between 2.4 GHz and 2.5 GHz operation. A differential
signal is recommended when the PLL is bypassed. A block
diagram of the REF_CLK functionality is shown in Figure 32.
Figure 32 also shows how the CFR3 control bits are associated
with specific functional blocks.
is relatively high; therefore, its effect on the termination impedance
is negligible and can usually be chosen to be the same as the
output impedance of the signal source. The bottom two examples
in Figure 33 assume a signal source with a 50 Ω output impedance.
0.1µF
DIFFERENTIAL SOURCE,
DIFFERENTIAL INPUT
PECL,
LVPECL,
OR
LVDS
DRIVER
÷ 1, 2, 4, 8
BALUN
(1:1)
SINGLE-ENDED SOURCE,
DIFFERENTIAL INPUT
PLL
OUT
1
SYSCLK
54
55
REF_CLK
54
REF_CLK
10837-029
Figure 33. Direct Connection Diagram
0
Phase-Locked Loop (PLL) Multiplier
INPUT DIVIDER
2
7
RESET CFR3[22]
N
INPUT DIVIDER RATIO
ICP CFR3[15:8]
CFR3[21:20]
CFR3[5:3]
10837-028
55
REF_CLK
0.1µF
2
REF_CLK
54
50Ω
LOOP
FILTER
CHARGE
PUMP DIVIDE
REF_CLK
0.1µF
1
IN
55
0.1µF
50Ω
PLL ENABLE
CFR3[18]
SINGLE-ENDED SOURCE,
SINGLE-ENDED INPUT
0
REF_CLK
0.1µF
DOUBLER
CLOCK EDGE
CFR3[16]
ENABLE
54
0.1µF
58
×2
REF_CLK
TERMINATION
LOOP_FILTER
DOUBLER ENABLE
CFR3[19]
55
REF_CLK
Figure 32. REF_CLK Block Diagram
The PLL enable bit is used to choose between the PLL path or
the direct input path. When the direct input path is selected,
the REF_CLK/REF_CLK pins must be driven by an external
signal source (single-ended or differential). Input frequencies
up to 3.5 GHz are supported.
Direct Driven REF_CLK/REF_CLK
With a differential signal source, the REF_CLK/REF_CLK pins
are driven with complementary signals and ac-coupled with 0.1 µF
capacitors. With a single-ended signal source, either a singleended-to-differential conversion can be employed or the REF_CLK
input can be driven single-ended directly. In either case, 0.1 µF
capacitors are used to ac couple both REF_CLK/ REF_CLK pins
to avoid disturbing the internal dc bias voltage of ~1.35 V. See
Figure 33 for more details.
The REF_CLK/REF_CLK input resistance is ~2.5 kΩ differential
(~1.2 kΩ single-ended). Most signal sources have relatively low
output impedances. The REF_CLK/REF_CLK input resistance
An internal phase-locked loop (PLL) provides the option to use
a reference clock frequency that is significantly lower than the
system clock frequency. The PLL supports a wide range of even
programmable frequency multiplication factors (20× to 510×)
as well as a programmable charge pump current and external
loop filter components (connected via the PLL LOOP_FILTER
pin). These features add an extra layer of flexibility to the PLL,
allowing optimization of phase noise performance and flexibility
in frequency plan development. The PLL is also equipped with
a PLL lock bit indicator (0x1B[24]).
The PLL output frequency range (fSYSCLK) is constrained to the
range of 2.4 GHz ≤ fSYSCLK ≤ 2.5 GHz by the internal VCO.
VCO Calibration
When using the PLL to generate the system clock, VCO calibration
is required to tune the VCO appropriately and achieve good
performance. When the reference input signal is stable, the
VCO cal enable bit in the CFR1 register, 0x00[24], must be
asserted. Subsequent VCO calibrations require that the VCO
calibration bit be cleared prior to initiating another VCO
calibration. VCO calibration must occur before DAC calibration
to ensure optimal performance and functionality.
Rev. D | Page 21 of 48
AD9915
Data Sheet
PLL Charge Pump/ Total Feedback Divider
CZ = 560pF (RECOMMENDED)
The charge pump current (ICP) value is automatically chosen via
the VCO calibration process and N value (N = 10 to 255) stored
in Feedback Divider N[7:0] in the CFR3 Register (0x02[15:8]).
N values below 10 should be avoided.
0.47µF
REF
CP
50pF
Note that the total PLL multiplication value for the PLL is always
2N due to the fixed divide by 2 element in the feedback path.
This is shown in Figure 34. The fixed divide by 2 element forces
only even PLL multiplication.
Table 7. PLL Charge Pump Current
Charge Pump Current, ICP (μA)
125
250
375
500 (default)
625
750
875
1000
VCO
CP
PFD
÷N
PLL OUT
÷2
Figure 34. REF CLK PLL External Loop Filter
PLL LOCK INDICATION
When the PLL is in use, the PLL lock bit (0x1B[24])provides an
active high indication that the PLL has locked to the REF CLK
input signal.
OUTPUT SHIFT KEYING (OSK)
The OSK function (see Figure 35) allows the user to control the
output signal amplitude of the DDS. The amplitude data generated
by the OSK block has priority over any other functional block
that is programmed to deliver amplitude data to the DDS.
Therefore, the OSK data source, when enabled, overrides all
other amplitude data sources.
The operation of the OSK function is governed by two CFR1
register bits, OSK enable (0x00[8]) and external OSK enable
(0x00[9]), the external OSK pin, the profile pins, and the 12 bits
of amplitude scale factor found in one of eight profile registers.
The profile pins are used to select the profile register containing
the desired amplitude scale factor.
Table 8. N divider vs. Charge Pump Current
N Divider Range
10 to 15
16 to 23
24 to 35
36 to 43
44 to 55
56 to 63
64 to 79
80 to 100
REFCLK PLL
PLL IN
Recommended Charge Pump
Current, ICP (μA)
125
250
375
500
625
750
875
1000
The primary control for the OSK block is the OSK enable bit
(0x00[8]). When the OSK function is disabled, the OSK input
controls and OSK pin are ignored.
PLL Loop Filter Components
The loop filter is mostly internal to the device, as shown in
Figure 34. The recommended external capacitor value is 560 pF.
Because CP and RPZ are integrated, it is not recommended to
adjust the loop bandwidth via the external capacitor value. The
better option is to adjust the charge pump current even though
it is a coarse adjustment.
The OSK pin functionality depends on the state of the external
OSK enable bit and the OSK enable bit. When both bits are set
to Logic 1 and the OSK pin is Logic 0, the output amplitude is
forced to 0; otherwise, if the OSK pin is Logic 1, the output
amplitude is set by the amplitude scale factor value in one of
eight profile registers depending on the profile pin selection.
OSK
PS0 PS1 PS2
25
For example, suppose the PLL is manually programmed such
that ICP = 375 μA, KV = 60 MHz/V, and N = 25. This produces a
loop bandwidth of approximately 250 kHz.
26
27
66
OSK ENABLE
EXTERNAL
OSK ENABLE
AMPLITUDE SCALE 12
FACTOR (1 OF 8
SELECTED PROFILE
REGISTERS [27:16])
12
OSK
CONTROLLER
DDS CLOCK
Figure 35. OSK Block Diagram
Rev. D | Page 22 of 48
TO DDS
AMPLITUDE
CONTROL
PARAMETER
10837-031
ICP Bits (CFR3[5:3])
000
001
010
011
100
101
110
111
RPZ (3.5kΩ)
10837-030
To manually override the charge pump current value, the manual
ICP selection bit in CFR3 (0x02[6]) must be set to Logic 1.This
provides the user with additional flexibility to optimize the PLL
performance. Table 7 lists the bit settings vs. the nominal charge
pump current.
LOOP_FILTER
58
59
Data Sheet
AD9915
DIGITAL RAMP GENERATOR (DRG)
The output of the DRG is a 32-bit unsigned data bus that can be
routed to any one of the three DDS signal control parameters, as
controlled by the two digital ramp destination bits in Control
Function Register 2 according to Table 9. The 32-bit output bus
is MSB-aligned with the 32-bit frequency parameter, the 16-bit
phase parameter, or the 12-bit amplitude parameter, as defined
by the destination bits. When the destination is phase or
amplitude, the unused LSBs are ignored.
DRG Overview
DRCTL
DRHOLD
DROVER
To sweep phase, frequency, or amplitude from a defined start
point to a defined endpoint, a completely digital ramp generator
is included in the AD9915. The DRG makes use of eight control
register bits, three external pins, and five 32-bit registers (see
Figure 36).
63
64
65
Table 9. Digital Ramp Destination
DIGITAL RAMP NO-DWELL
Digital Ramp
Destination Bits
(CFR2[21:20])
00
01
1x1
LOAD LRR AT I/O_UPDATE
1
DIGITAL RAMP ENABLE
2
DIGITAL RAMP DESTINATION
2
CLEAR DIGITAL
RAMP ACCUMULATOR
AUTOCLEAR DIGITAL
RAMP ACCUMULATOR
RISING DIGITAL RAMP STEP
SIZE REGISTER
FALLING DIGITAL RAMP STEP
SIZE REGISTER
32
x = don’t care.
32
TO DDS
SIGNAL
CONTROL
PARAMETER
The direction of the ramping function is controlled by the
DRCTL pin. Logic 0 on this pin causes the DRG to ramp with
a negative slope, whereas Logic 1 causes the DRG to ramp with
a positive slope.
32
32
32
DIGITAL RAMP RATE REGISTER
10837-032
The DRG also supports a hold feature controlled via the DRHOLD
pin. When this pin is set to Logic 1, the DRG is stalled at its last
state; otherwise, the DRG operates normally. The DDS signal
control parameters that are not the destination of the DRG are
taken from the active profile.
DDS CLOCK
Figure 36. Digital Ramp Block Diagram
The primary control for the DRG is the digital ramp enable bit
(0x01[19]). When disabled, the other DRG input controls are
ignored and the internal clocks are shut down to conserve power.
32
DECREMENT STEP SIZE
32
INCREMENT STEP SIZE
DIGITAL RAMP ACCUMULATOR
0
32
32
1
32
32
D
Q
DRCTL 62
R
16
NEGATIVE SLOPE RATE
16
POSITIVE SLOPE RATE
LOAD LRR AT I/O_UPDATE
32
32
UPPER
LIMIT
LOWER
LIMIT
TO DDS
SIGNAL
CONTROL
PARAMETER
16
1
LOAD
CONTROL
LOGIC
DRHOLD 63
DDS CLOCK
0
LIMIT CONTROL
PRESET
LOAD
ACCUMULATOR
RESET
CONTROL
LOGIC
Q
DIGITAL
RAMP
TIMER
Figure 37. Digital Ramp Generator Detail
Rev. D | Page 23 of 48
NO-DWELL
CONTROL
2
NO DWELL
CLEAR DIGITAL RAMP ACCUMULATOR
. ACC
AUTOCLEAR DIGITAL RAMP
10837-033
DIGITAL RAMP UPPER LIMIT REGISTER
DIGITAL
RAMP
GENERATOR
Bits Assigned to
DDS Parameter
31:0
31:18
31:20
The ramp characteristics of the DRG are fully programmable. This
includes the upper and lower ramp limits, and independent control
of the step size and step rate for both the positive and negative slope
characteristics of the ramp. A detailed block diagram of the DRG is
shown in Figure 37.
32
DIGITAL RAMP LOWER LIMIT REGISTER
DDS Signal
Control
Parameter
Frequency
Phase
Amplitude
AD9915
Data Sheet
DRG Slope Control
The core of the DRG is a 32-bit accumulator clocked by a
programmable timer. The time base for the timer is the DDS
clock, which operates at 1/24 fSYSCLK. The timer establishes the
interval between successive updates of the accumulator. The
positive (+Δt) and negative (−Δt) slope step intervals are
independently programmable as given by
+ ∆t =
− ∆t =
24 P
f SYSCLK
24 N
f SYSCLK
where P and N are the two 16-bit values stored in the 32-bit digital
ramp rate register and control the step interval. N defines the step
interval of the negative slope portion of the ramp. P defines the step
interval of the positive slope portion of the ramp.
The step size of the positive (STEPP) and negative (STEPN) slope
portions of the ramp are 32-bit values programmed into the 32-bit
rising and falling digital ramp step size registers (0x06 and 0x07).
Program each of the step sizes as an unsigned integer (the
hardware automatically interprets STEPN as a negative value).
The relationship between the 32-bit step size values and actual
units of frequency, phase, or amplitude depend on the digital
ramp destination bits. Calculate the actual frequency, phase, or
amplitude step size by substituting STEPN or STEPP for M in the
following equations as required:
M
Frequency Step =  32  f SYSCLK
2


Phase Step =
Phase Step =
πM
231
45M
229
(radians)
(degrees)
Note that the frequency units are the same as those used to
represent fSYSCLK (MHz, for example). The amplitude units are
the same as those used to represent IFS, the full-scale output
current of the DAC (mA, for example).
The phase and amplitude step size equations yield the average
step size. Although the step size accumulates with 32-bit precision,
the phase or amplitude destination exhibits only 16 bits or 12 bits,
respectively. Therefore, at the destination, the actual phase or
amplitude step is the accumulated 32-bit value truncated to
16 bits or 12 bits, respectively.
As described previously, the step interval is controlled by a 16-bit
programmable timer. There are three events that can cause this
timer to be reloaded prior to its expiration. One event occurs
when the digital ramp enable bit transitions from cleared to set,
followed by an I/O update. A second event is a change of state
in the DRCTL pin. The third event is enabled using the load
LRR at I/O update bit (0x00[15]).
DRG Limit Control
The ramp accumulator is followed by limit control logic that
enforces an upper and lower boundary on the output of the
ramp generator. Under no circumstances does the output of the
DRG exceed the programmed limit values while the DRG is
enabled. The limits are set through the 64-bit digital ramp limit
register. Note that the upper limit value must be greater than the
lower limit value to ensure normal operation.
DRG Accumulator Clear
The ramp accumulator can be cleared (that is, reset to 0) under
program control. When the ramp accumulator is cleared, it forces
the DRG output to the lower limit programmed into the digital
ramp limit register.
With the limit control block embedded in the feedback path of the
accumulator, resetting the accumulator is equivalent to presetting it
to the lower limit value.
M
Amplitude Step =  32  I FS
2 
Rev. D | Page 24 of 48
Data Sheet
AD9915
P DDS CLOCK CYCLES
N DDS CLOCK CYCLES
1 DDS CLOCK CYCLE
NEGATIVE
STEP SIZE
+Δt
POSITIVE
STEP SIZE
–Δt
UPPER LIMIT
DRG OUTPUT
LOWER LIMIT
DROVER
DRHOLD
AUTO
CLEAR
CLEAR
DRCTL
RELEASE
DIGITAL RAMP ENABLE
CLEAR DIGITAL
RAMP ACCUMULATOR
AUTOCLEAR DIGITAL
RAMP ACCUMULATOR
1
2
3
4
5
6
7
8
9
13
11
10
12
10837-034
I/O_UPDATE
Figure 38. Normal Ramp Generation
Normal Ramp Generation
Normal ramp generation implies that both no-dwell bits are
cleared (see the No-Dwell Ramp Generation section for details). In
Figure 38, a sample ramp waveform is depicted with the required
control signals. The top trace is the DRG output. The next trace
down is the status of the DROVER output pin (assuming that the
DRG over output enable bit is set). The remaining traces are
control bits and control pins. The pertinent ramp parameters
are also identified (upper and lower limits plus step size and Δt
for the positive and negative slopes). Along the bottom, circled
numbers identify specific events. These events are referred to by
number (Event 1 and so on) in the following paragraphs.
In this example, the positive and negative slopes of the ramp are
different to demonstrate the flexibility of the DRG. The parameters
of both slopes can be programmed to make the positive and
negative slopes the same.
Event 1—The digital ramp enable bit is set, which has no effect
on the DRG output because the bit is not effective until an I/O
update occurs.
Event 2—An I/O update registers the digital ramp enable bit. If
DRCTL = 1 is in effect (the gray portion of the DRCTL trace),
the DRG output immediately begins a positive slope (the gray
portion of the DRG output trace). Otherwise, if DRCTL = 0, the
DRG output is initialized to the lower limit.
Event 3—DRCTL transitions to Logic 1 to initiate a positive slope
at the DRG output. In this example, the DRCTL pin is held long
enough to cause the DRG to reach its programmed upper limit.
The DRG remains at the upper limit until the ramp accumulator
is cleared (DRCTL = 0) or the upper limit is reprogrammed to a
higher value. In the latter case, the DRG immediately resumes
its previous positive slope profile.
Event 4—DRCTL transitions to Logic 0 to initiate a negative
slope at the DRG output. In this example, the DRCTL pin is
held long enough to cause the DRG to reach its programmed
lower limit. The DRG remains at the lower limit until DRCTL = 1,
or until the lower limit is reprogrammed to a lower value. In the
latter case, the DRG immediately resumes its previous negative
slope profile.
Event 5—DRCTL transitions to Logic 1 for the second time,
initiating a second positive slope.
Event 6—The positive slope profile is interrupted by DRHOLD
transitioning to Logic 1. This stalls the ramp accumulator and
freezes the DRG output at its last value.
Event 7—DRHOLD transitions to Logic 0, releasing the ramp
accumulator and reinstating the previous positive slope profile.
Event 8—The clear digital ramp accumulator bit is set, which
has no effect on the DRG because the bit is not effective until an
I/O update is issued.
Event 9—An I/O update registers that the clear digital ramp
accumulator bit is set, resetting the ramp accumulator and forcing
the DRG output to the programmed lower limit. The DRG output
remains at the lower limit until the clear condition is removed.
Event 10—The clear digital ramp accumulator bit is cleared,
which has no effect on the DRG output because the bit is not
effective until an I/O update is issued.
Event 11—An I/O update registers that the clear digital ramp
accumulator bit is cleared, releasing the ramp accumulator; and
the previous positive slope profile restarts.
Event 12—The autoclear digital ramp accumulator bit is set,
which has no effect on the DRG output because the bit is not
effective until an I/O update is issued.
Rev. D | Page 25 of 48
AD9915
Data Sheet
tion between the limits. Likewise, if the DRG output is in the
midst of a negative slope and the DRCTL pin transitions from
Logic 0 to Logic 1, the DRG immediately switches to the positive
slope parameters and resumes oscillation between the limits.
Event 13—An I/O update registers that the autoclear digital
ramp accumulator bit is set, resetting the ramp accumulator.
However, with an automatic clear, the ramp accumulator is held
in reset for only a single DDS clock cycle. This forces the DRG
output to the lower limit, but the ramp accumulator is immediately made available for normal operation. In this example, the
DRCTL pin remains Logic 1; therefore, the DRG output restarts
the previous positive ramp profile.
When both no-dwell bits are set, the DROVER signal produces
a positive pulse (two cycles of the DDS clock) each time the DRG
output reaches either of the programmed limits (assuming that
the DRG over output enable bit (0x01[13]) is set).
No-Dwell Ramp Generation
A no-dwell high DRG output waveform is shown in Figure 39.
The waveform diagram assumes that the digital ramp no-dwell
high bit is set and has been registered by an I/O update. The
status of the DROVER pin is also shown with the assumption
that the DRG over output enable bit has been set.
The two no-dwell high and no-dwell low bits (0x01[18:17]) in
CFR2 add to the flexibility of the DRG capabilities. During normal
ramp generation, when the DRG output reaches the programmed
upper or lower limit, it simply remains at the limit until the
operating parameters dictate otherwise. However, during no-dwell
operation, the DRG output does not necessarily remain at the limit.
For example, if the digital ramp no-dwell high bit is set when the
DRG reaches the upper limit, it automatically (and immediately)
snaps to the lower limit (that is, it does not ramp back to the lower
limit; it jumps to the lower limit). Likewise, when the digital ramp
no-dwell low bit is set, and the DRG reaches the lower limit, it
automatically (and immediately) snaps to the upper limit.
The circled numbers in Figure 39 indicate specific events, which
are explained as follows:
Event 1—Indicates the instant that an I/O update registers that
the digital ramp enable bit is set.
Event 2—DRCTL transitions to Logic 1, initiating a positive
slope at the DRG output.
Event 3—DRCTL transitions to Logic 0, which has no effect on
the DRG output.
During no-dwell operation, the DRCTL pin is monitored for state
transitions only; that is, the static logic level is immaterial.
Event 4—Because the digital ramp no-dwell high bit is set, the
moment that the DRG output reaches the upper limit, it immediately switches to the lower limit, where it remains until the
next Logic 0 to Logic 1 transition of DRCTL.
During no-dwell high operation, a positive transition of the
DRCTL pin initiates a positive slope ramp, which continues
uninterrupted (regardless of any further activity on the DRCTL
pin) until the upper limit is reached.
Event 5—DRCTL transitions from Logic 0 to Logic 1, which
restarts a positive slope ramp.
During no-dwell low operation, a negative transition of the DRCTL
pin initiates a negative slope ramp, which continues uninterrupted
(regardless of any further activity on the DRCTL pin) until the
lower limit is reached.
Event 6 and Event 7—DRCTL transitions are ignored until the
DRG output reaches the programmed upper limit.
Event 8—Because the digital ramp no-dwell high bit is set, the
moment that the DRG output reaches the upper limit, it immediately switches to the lower limit, where it remains until the next
Logic 0 to Logic 1 transition of DRCTL.
Setting both no-dwell bits invokes a continuous ramping mode
of operation; that is, the DRG output automatically oscillates
between the two limits using the programmed slope parameters.
Furthermore, the function of the DRCTL pin is slightly different.
Instead of controlling the initiation of the ramp sequence, it
only serves to change the direction of the ramp; that is, if the
DRG output is in the midst of a positive slope and the DRCTL
pin transitions from Logic 1 to Logic 0, the DRG immediately
switches to the negative slope parameters and resumes oscilla-
Operation with the digital ramp no-dwell low bit set (instead of
the digital ramp no-dwell high bit) is similar, except that the
DRG output ramps in the negative direction on a Logic 1 to
Logic 0 transition of DRCTL and jumps to the upper limit upon
reaching the lower limit.
P DDS CLOCK CYCLES
POSITIVE
STEP SIZE
+Δt
UPPER LIMIT
DRG OUTPUT
LOWER LIMIT
DROVER
1
2
3
4
5
6
Figure 39. No-Dwell High Ramp Generation
Rev. D | Page 26 of 48
7
8
10837-035
DRCTL
Data Sheet
AD9915
DROVER Pin
POWER-DOWN CONTROL
The DROVER pin provides an external signal to indicate the status
of the DRG. Specifically, when the DRG output is at either of
the programmed limits, the DROVER pin is Logic 1; otherwise,
it is Logic 0. In the special case of both no-dwell bits set, the
DROVER pin pulses positive for two DDS clock cycles each
time the DRG output reaches either of the programmed limits.
The AD9915 offers the ability to independently power down
three specific sections of the device. Power-down functionality
applies to the following:
Frequency Jumping Capability in DRG Mode
Another feature of the AD9915 allows the user to skip a
predefined range of frequencies during a normal sweep. The
frequency jump enable bit in CFR2 (0x01[14]) enables this
functionality. When this bit is set, the sweeping logic monitors
the instantaneous frequency. When it reaches the frequency
point defined in the lower frequency jump register (0x09) on
the next accumulation cycle, instead of accumulating a delta
tuning word as in normal sweeping, it skips directly to the
frequency value set in the upper frequency jump register
(0x0A), and vice versa. Figure 40 shows how this feature works.
The following rules apply when this feature is enabled.
•
The frequency jump values must lie between the lower
limit and upper limit of the frequency sweep range.
The lower frequency jump register value must be lower
than that of the upper frequency jump register value.
UPPER LIMIT
0x09
Software power-down is controlled via three independent
power-down bits in CFR1. Software control requires that the
EXT_PWR_DWN pin be forced to a Logic 0 state. In this case,
setting the desired power-down bits (0x00[7:5]) via the serial
I/O port powers down the associated functional block, whereas
clearing the bits restores the function.
10837-036
0x0A
t
A power-down of the digital core disables the ability to update
the serial/parallel I/O port. However, the digital power-down
bit (0x00[7]) can still be cleared to prevent the possibility of a
nonrecoverable state.
Based on the state of the external power-down control bit, the
EXT_PWR_DWN pin produces either a full power-down or a
fast recovery power-down. The fast recovery power-down
mode maintains power to the DAC bias circuitry and the PLL,
VCO, and input clock circuitry. Although the fast recovery
power-down does not conserve as much power as the full
power-down, it allows the device to awaken very quickly
from the power-down state.
FREQUENCY
LOWER LIMIT
Digital core
DAC
Input REF CLK clock circuitry
Alternatively, all three functions can be simultaneously powered
down via external hardware control through the EXT_PWR_DWN
pin. When this pin is forced to Logic 1, all four circuit blocks are
powered down regardless of the state of the power-down bits;
that is, the independent power-down bits in CFR1 are ignored
and overridden when EXT_PWR_DWN is Logic 1.
A second frequency jump can also be allowed if the frequency
jump registers are reprogrammed before the sweeping is
complete.
•
•
•
•
Figure 40. Frequency vs. Time
Rev. D | Page 27 of 48
AD9915
Data Sheet
PROGRAMMING AND FUNCTION PINS
The AD9915 is equipped with a 32-bit parallel port. The 32-bit
port is for programming the internal registers of the device in
either serial mode or parallel mode as well as allowing for direct
modulation control of frequency (FTW), phase (POW), and
amplitude (AMP).The state of the external function pins (F0
to F3) determines how the 32-bit parallel port is configured.
Pin 28 to Pin 31 are the function pins. Refer to Table 10 for
possible configurations.
Note that the OSK enable bit, CFR1[8], must be set to enable
amplitude control, as shown in Table 10.
Table 10. Parallel Port Configurations
Function Pins,
F[3:0] 1
0000
Mode Description
Parallel programming mode
Bits[31:24] 2
Data[15:8]
(optional)
0001
Serial programming mode
Not used
0010
Full 32 bits of direct frequency
tuning word control. MSB and LSB
aligned to parallel port pins
Full 32 bits of direct frequency
tuning word control with different
parallel port pin assignments
Full 16 bits of direct phase offset
control and full 12 bits of direct
amplitude control
Full 12 bits of direct amplitude
control and full 16 bits of direct
phase offset control
24 bits of partial FTW control and
8 bits of partial amplitude control
24 bits of partial FTW control and
8 bits of partial phase offset control
24 bits of partial FTW control and
8 bits of partial amplitude control
24 bits of partial FTW control and
8 bits of partial phase offset control
24 bits of partial FTW control and
8 bits of partial amplitude control
24 bits of partial FTW control and
8 bits of partial phase offset control
24 bits of partial FTW control and
8 bits of partial amplitude control
24 bits of partial FTW control and
8 bits of partial phase offset control
FTW[31:24]
32-Bit Parallel Port Pin Assignment
Bits[23:16] 3 Bits[15:8] 4
Bits[7:0] 5
Data[7:0]
Address[7:0] Used to control writes, reads, and
8-bit or 16-bit data-word. See the
Parallel Programming section for
details.
Not used
Not used
Used to control SCLK, SDIO,
SDO, CS, and SYNCIO. See the
Serial Programming section for
details.
FTW[23:16]
FTW[15:8]
FTW[7:0]
FTW[15:8]
FTW[7:0]
FTW[31:24]
FTW[23:16]
POW[15:8]
POW[7:0]
AMP[11:8]
AMP[7:0]
AMP[11:8]
AMP[7:0]
POW[15:8]
POW[7:0]
FTW[31:24]
FTW[23:16]
FTW[15:8]
AMP[15:8]
FTW[31:24]
FTW[23:16]
FTW[15:8]
POW[15:8]
FTW[31:24]
FTW[23:16]
FTW[15:8]
AMP[7:0]
FTW[31:24]
FTW[23:16]
FTW[15:8]
POW[7:0]
FTW[23:16]
FTW[15:8]
FTW[7:0]
AMP[15:8]
FTW[23:16]
FTW[15:8]
FTW[7:0]
POW[15:8]
FTW[23:16]
FTW[15:8]
FTW[7:0]
AMP[7:0]
FTW[23:16]
FTW[15:8]
FTW[7:0]
POW[7:0]
Not used
Not used
Not used
Not used
Not used
Not used
Not used
Not used
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
Pin 31 to Pin 28.
Pin 68 to Pin 72, Pin 75 to 77.
3
Pin 78 to Pin 81, Pin 87, Pin 88, Pin 1, Pin 2.
4
Pin 3 to Pin 5, Pin 8 to Pin 12.
5
Pin 13 to Pin 15, Pin 18 to Pin 22.
1
2
Rev. D | Page 28 of 48
Data Sheet
FUNCTION
PINS
AD9915
4
F[3:0]
DECODE
DDS
DIRECT MODES
PARALLEL
PORT PINS
32
32
BITS[31:0]
32
32
ROUTING
LOGIC
DQ
CK
SYNC_CLK
FTW
FREQUENCY
POW
PHASE
AMP
AMPLITUDE
16
12
32
FUNCTION PINS AND DIRECT MODE
BITS[31:0] VS. FTW, POW, AMP
F[3:0] BITS[31:24] BITS[23:16] BITS[15:8]
0000
PARALLEL MODE
0001
SERIAL MODE
PARALLEL
CONTROL
BITS[7:0]
27
FTW[31:24] FTW[23:16] FTW[15:8]
8 BITS[31:24]
8 BITS[23:16]
8
DIRECT MODE
0010
BITS[15:8]
FTW[7:0]
BIT 2
0011
FTW[15:8]
FTW[7:0]
FTW[31:24] FTW[23:16]
BIT 1
0100
POW[15:8]
POW[7:0]
AMP[11:8]
BIT 0
0101
AMP[11:8]
AMP[7:0]
POW[15:8]
OSK ENABLE
PARALLEL MODE
AMP[7:0]
D[15:8]
SYSTEM
CLOCK
PROGRAMMING
REGISTERS
D[7:0]
A[7:0]
WR
IO_UPDATE
RD
16 BITS/8 BITS
POW[7:0]
0110
FTW[31:24] FTW[23:16] FTW[15:8]
AMP[15:8]
0111
FTW[31:24] FTW[23:16] FTW[15:8]
POW[15:8]
1000
FTW[31:24] FTW[23:16] FTW[15:8]
AMP[7:0]
1001
FTW[31:24] FTW[23:16] FTW[15:8]
POW[7:0]
1010
FTW[23:16] FTW[15:8]
FTW[7:0]
AMP[15:8]
BIT 3
1011
FTW[23:16] FTW[15:8]
FTW[7:0]
POW[15:8]
BIT 2
1100
FTW[23:16] FTW[15:8]
FTW[7:0]
AMP[7:0]
BIT 1
1101
FTW[23:16] FTW[15:8]
FTW[7:0]
POW[7:0]
BIT 0
SERIAL MODE
SERIAL
CONTROL
5
SYNCIO
SDO
SDIO
SCLK
CS
10837-046
BIT 4
NOTES
1. AMP[11:0] CONTROLS AMPLITUDE. AMP[15:12] UNUSED.
Figure 41. Parallel Port Block Diagram
The 32-pin parallel port of the AD9915 works in conjunction
with an independent set of four function pins that control the
functionality of the parallel port. The 32 pins of the parallel port
constitute a 32-bit word designated by Bits[31:0] (31 indicating
the most significant bit (MSB) and 0 indicating the least significant
bit (LSB)), with the four function pins designated as F[3:0]. The
relationship between the function pins, the 32-pin parallel port,
the internal programming registers, and the DDS control
parameters (frequency, phase, and amplitude) is illustrated in
Figure 41. Note that the parallel port operates in three different
modes as defined by the function pins.
The parallel mode is in effect when the logic levels applied to
the function pins are F[3:0] = 0000. This allows the parallel port
to function as a parallel interface providing access to all of the
device programming registers. In parallel mode, the 32-pin port
(Bits[31:0]) is subdivided into three groups with Bits[31:16]
constituting 16 data bits, Bits[15:8] constituting eight address
bits, and Bits[2:0] constituting three control bits. The address bits
target a specific device register, whereas the data bits constitute
the register content. The control bits establish read or write
functionality as well as set the width of the data bus. That is, the
user can select whether the data bus spans 16 bits (Bits[31:16])
or eight bits (Bits[23:16]). The parallel mode allows the user to
write to the device registers at rates of up to 200 MBps using
16-bit data (or 100 MBps using 8-bit data).
The serial mode is in effect when the logic levels applied to the
function pins are F[3:0] = 0001. This allows the parallel port to
function as a serial interface providing access to all of the device
programming registers. In this mode, only five pins of the 32-pin
parallel port are functional (Bits[4:0]). These pins provide chip
select (CS), serial clock (SCLK), and I/O synchronization
(SYNCIO) functionality for the serial interface, as well as two
serial data lines (SDO and SDIO). The serial mode supports
data rates of up to 80 Mbps.
When the logic levels applied to the function pins are F[3:0] =
0010 to 1101 (note that 1110 and 1111 are unused), the parallel
port functions as a high speed interface with direct access to the
32-bit frequency, 16-bit phase, and 12-bit amplitude parameters
of the DDS core. The table in Figure 41 shows the segmentation
of the 32-pin parallel port by identifying Bits[31:0] with the
frequency (FTW[31:0]), phase (POW[15:0]), and amplitude
(AMP[15:0]) parameters of the DDS. Note, however, that
although AMP[15:0] indicate 16-bit resolution, the actual
amplitude resolution is 12 bits. Therefore, only AMP[11:0]
provide amplitude control (that is, AMP[15:12] are not used).
Rev. D | Page 29 of 48
AD9915
Data Sheet
Furthermore, to make use of amplitude control, the user must
be sure to program the OSK enable bit in the CFR1 register
(0x00[8]) to Logic 1.
The combination of the F[3:0] pins and Bits[31:0] provides the
AD9915 with unprecedented modulation capability by allowing
the user direct control of the DDS parameters (frequency, phase,
amplitude, or various combinations thereof). Furthermore, the
parallel port operates at a sample rate equal to 1/16 of the system
sample clock. This allows for updates of the DDS parameters at
rates of up to 156 MSPS (assuming a 2.5 GHz system clock)
allowing the AD9915 to accommodate applications with
wideband modulation requirements.
Be aware that the frequency, phase, and amplitude changes applied
at the parallel port travel to the DDS core over different paths,
experiencing different propagation times (latency). Therefore,
modulating more than one DDS parameter necessitates setting
the device’s matched latency enable bit in the CFR2 register
(0x01[15]), which equalizes the latency of each DDS parameter
as it propagates from the parallel port to the DDS core. Note
that high speed modulation requires a DAC reconstruction
filter with sufficient bandwidth to accommodate the
instantaneous time domain transitions.
Because direct access to the DDS parameters occurs via the
FTW, POW, and AMP registers, the IO_UPDATE pin (see
Figure 41) adds another layer of flexibility. To accommodate
this functionality, the AD9915 provides a register control bit,
parallel port streaming enable (0x00[17]). When this bit is set
to Logic 1, the parallel port operates without the need for an
I/O update. When this bit is Logic 0, however, the device
delivers the parallel port data to the appropriate registers (FTW,
POW, AMP), but not to the DDS core. Data does not transfer to
the DDS core until the user asserts the IO_UPDATE pin.
For example, suppose that an application requires frequency and
amplitude modulation with full 32-bit frequency resolution and
full 12-bit amplitude resolution. Note that none of the F[3:0] pin
combinations supports such modulation capability directly. To
circumvent this problem, set the parallel port streaming enable
bit (0x00[17]) to Logic 0. This allows for the use of two direct
mode cycles of the 32-pin parallel port, each with a different
function pin setting, without affecting the DDS core until assertion
of the IO_UPDATE pin. That is, during the first direct mode
cycle, set the function pins to F[3:0] = 0010, which routes all 32
bits to the FTW register (frequency). On the next direct mode
cycle, set the function pins to F[3:0] = 0100, which provides full
12-bit access to the AMP register (amplitude). Be aware, however,
this also provides access to the POW register (phase); therefore,
be sure keep the phase bits static. Next, toggle the IO_UPDATE
pin, which synchronously transfers the new frequency and phase
values from the FTW and POW registers to the DDS core. This
mode of operation reduces the overall modulation rate by a factor
of three because it requires two separate operations on the parallel
port followed by an IO_UPDATE. However, this still allows for
modulation sample rates as high as ~52 MSPS.
Rev. D | Page 30 of 48
Data Sheet
AD9915
SERIAL PROGRAMMING
To enable SPI operations, set Pin 28 (F0) to logic high and Pin 29
to Pin 31 (F1 to F3) to logic low. To program the AD9915 with a
parallel interface, see the Parallel Programming section.
CONTROL INTERFACE—SERIAL I/O
The AD9915 serial port is a flexible, synchronous serial communications port allowing easy interface to many industry-standard
microcontrollers and microprocessors. The serial I/O is compatible
with most synchronous transfer formats.
The interface allows read/write access to all registers that configure
the AD9915. MSB-first or LSB-first transfer formats are supported. In addition, the serial interface port can be configured
as a single pin input/output (SDIO) allowing a 2-wire interface,
or it can be configured as two unidirectional pins for input/
output (SDIO and SDO), enabling a 3-wire interface. Two
optional pins (I/O_SYNC and CS) enable greater flexibility
for designing systems with the AD9915.
the serial port buffer to active registers. The I/O update can be
sent either after each communication cycle or when all serial
operations are complete. In addition, a change in profile pins
can initiate an I/O update.
For a read cycle, Phase 2 is the same as the write cycle with the
following differences: data is read from the active registers, not
the serial port buffer, and data is driven out on the falling edge
of SCLK.
Note that, to read back any profile register (0x0B to 0x1A), the
three external profile pins must be used. For example, if the profile
register is Profile 5 (0x15), the PS[0:2] pins must equal 101.This
is not required to write to the profile registers.
INSTRUCTION BYTE
The instruction byte contains the following information as
shown in the instruction byte information bit map.
Instruction Byte Information Bit Map
Table 11. Serial I/O Pin Description
MSB
Pin No.
18
19
20
21
22
I7
I6
I5
I4
I3
I2
I1
I0
R/W
X
A5
A4
A3
A2
A1
A0
Mnemonic
D4/SYNCIO
D3/SDO
D2/SDIO/WR
D1/SCLK/RD
D0/CS/PWD
Serial I/O Description
SYNCIO
SDO
SDIO
SCLK
CS—chip select
LSB
R/W—Bit 7 of the instruction byte determines whether a read
or write data transfer occurs after the instruction byte write.
Logic 1 indicates a read operation. Logic 0 indicates a write
operation.
GENERAL SERIAL I/O OPERATION
There are two phases to a serial communications cycle. The first
is the instruction phase to write the instruction byte into the
AD9915. The instruction byte contains the address of the register
to be accessed and defines whether the upcoming data transfer
is a write or read operation.
For a write cycle, Phase 2 represents the data transfer between
the serial port controller to the serial port buffer. The number
of bytes transferred is a function of the register being accessed.
For example, when accessing Control Function Register 2
(Address 0x01), Phase 2 requires that four bytes be transferred.
Each bit of data is registered on each corresponding rising edge
of SCLK. The serial port controller expects that all bytes of the
register be accessed; otherwise, the serial port controller is put
out of sequence for the next communication cycle. However,
one way to write fewer bytes than required is to use the SYNCIO
pin feature. The SYNCIO pin function can be used to abort an
I/O operation and reset the pointer of the serial port controller.
After a SYNCIO, the next byte is the instruction byte. Note that
every completed byte written prior to a SYNCIO is preserved in
the serial port buffer. Partial bytes written are not preserved. At
the completion of any communication cycle, the AD9915 serial
port controller expects the next eight rising SCLK edges to be
the instruction byte for the next communication cycle.
X—Bit 6 of the instruction byte is don’t care.
A5, A4, A3, A2, A1, A0—Bit 5, Bit 4, 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 communications cycle.
SERIAL I/O PORT PIN DESCRIPTIONS
SCLK—Serial Clock
The serial clock pin is used to synchronize data to and from the
AD9915 and to run the internal state machines.
CS—Chip Select Bar
CS is an active low input that allows more than one device on
the same serial communications line. The SDO and SDIO pins
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 (CS) can be tied low in
systems that maintain control of SCLK.
SDIO—Serial Data Input/Output
Data is always written into the AD9915 on this pin. However,
this pin can be used as a bidirectional data line. Bit 1 of CFR1
(0x00) controls the configuration of this pin. The default is
Logic 0, which configures the SDIO pin as bidirectional.
After a write cycle, the programmed data resides in the serial
port buffer and is inactive. I/O_UPDATE transfers data from
Rev. D | Page 31 of 48
AD9915
Data Sheet
SDO—Serial Data Out
SERIAL I/O TIMING DIAGRAMS
Data is read from this pin for protocols that use separate lines
for transmitting and receiving data. When the AD9915 operates
in single bidirectional I/O mode, this pin does not output data
and is set to a high impedance state.
Figure 42 through Figure 45 provide basic examples of the timing
relationships between the various control signals of the serial
I/O port. Most of the bits in the register map are not transferred
to their internal destinations until assertion of an I/O update,
which is not included in the timing diagrams that follow.
SYNCIO—Input/Output Reset
Note that the SCLK stall condition between the instruction byte
cycle and data transfer cycle in Figure 42 to Figure 45 is not
required.
SYNCIO synchronizes the I/O port state machines without
affecting the contents of the addressable registers. An active
high input on the SYNCIO pin causes the current communication cycle to abort. After SYNCIO returns low (Logic 0),
another communication cycle can begin, starting with the
instruction byte write.
MSB/LSB TRANSFERS
The AD9915 serial port can support both most significant bit
(MSB) first or least significant bit (LSB) first data formats. This
functionality is controlled by Bit 0 in CFR1 (0x00). The default
format is MSB first. If LSB first is active, all data, including the
instruction byte, must follow LSB-first convention. Note that the
highest number found in the bit range column for each register is
the MSB, and the lowest number is the LSB for that register.
I/O_UPDATE—Input/Output Update
The I/O update initiates the transfer of written data from the
serial or parallel I/O port buffer to active registers. I/O_UPDATE
is active on the rising edge, and its pulse width must be greater
than one SYNC_CLK period.
INSTRUCTION CYCLE
DATA TRANSFER CYCLE
CS
SDIO
I7
I6
I5
I4
I3
I2
I1
I0
D7
D6
D5
D4
D3
D2
D1
10837-037
SCLK
D0
Figure 42. Serial Port Write Timing, Clock Stall Low
INSTRUCTION CYCLE
DATA TRANSFER CYCLE
CS
SCLK
I6
I7
I5
I4
I3
I2
I1
I0
DON'T CARE
DO7
SDO
DO5
DO6
DO4
DO3
DO2
DO1
DO0
10837-038
SDIO
Figure 43. 3-Wire Serial Port Read Timing, Clock Stall Low
INSTRUCTION CYCLE
DATA TRANSFER CYCLE
CS
I7
I6
I5
I4
I3
I2
I1
I0
D7
D6
D5
D4
D3
D2
D1
D0
10837-039
SDIO
DO0
10837-040
SCLK
Figure 44. Serial Port Write Timing, Clock Stall High
INSTRUCTION CYCLE
DATA TRANSFER CYCLE
CS
SCLK
SDIO
I7
I6
I5
I4
I3
I2
I1
I0
DO7
DO6
DO5
DO4
Figure 45. 2-Wire Serial Port Read Timing, Clock Stall High
Rev. D | Page 32 of 48
DO3
DO2
DO1
Data Sheet
AD9915
PARALLEL PROGRAMMING (8-/16-BIT)
The state of the external function pins (F0 to F3) determine the
type of interface used by the AD9915. Pin 28 to Pin 31 are
dedicated function pins. To enable the parallel mode interface
set Pin 28 to Pin 31 to logic low.
Parallel programming consists of eight address lines and either
eight or 16 bidirectional data lines for read/write operations.
The logic state on Pin 22 determines the width of the data lines
used. A logic low on Pin 22 sets the data width to eight bits, and
logic high sets the data width to 16 bits. In addition, parallel
mode has dedicated write/read control inputs. If 16-bit mode is
used, the upper byte, Bits[15:8], goes to the addressed register
and the lower byte, Bits[7:0], goes to the adjacent lower address.
Parallel I/O operation allows write access to each byte of any
register in a single I/O operation. Readback capability for each
register is included to ease designing with the AD9915.
A[7:0]
D[7:0] OR
D[15:0]
A1
D1
tRDHIGH
Table 12. Parallel Port Read Timing (See Figure 46)
Parameter
tADV
tAHD
Value
92
0
Unit
ns max
ns min
tRDLOV
tRDHOZ
tRDLOW
tRDHIGH
69
50
69
50
ns max
ns max
ns max
ns max
Test Conditions/Comments
Address to data valid time
Address hold time to RD signal
inactive
RD low to output valid
RD high to data three-state
RD signal minimum low time
RD signal minimum high time
Table 13. Parallel Port Write Timing (See Figure 47)
Parameter
tASU
Value
1
Unit
ns
tDSU
3.8
ns
tAHD
0
ns
tDHD
0
ns
tWRLOW
tWRHIGH
tWR
2.1
3.8
10.5
ns
ns
ns
Test Conditions / Comments
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
A2
A3
D2
D3
tRDLOW
RD
tRDLOV
10837-041
tRDHOZ
tADV
tAHD
Figure 46. Parallel Port Read Timing Diagram
tWR
D[7:0] OR
D[15:0]
A1
A2
D1
A3
D2
WR
tASU
tWRHIGH
tDSU
tWRLOW
D3
tAHD
tDHD
Figure 47. Parallel Port Write Timing Diagram
Rev. D | Page 33 of 48
10837-042
A[7:0]
AD9915
Data Sheet
MULTIPLE CHIP SYNCHRONIZATION
To use the multichip synchronization feature, two requirements
must be met. First, a synchronization signal must be provided
to the device. Second, 0x1B[6] must be set. The actual synchronization process occurs as part of the DAC calibration, as follows.
When the DAC CAL enable bit is set in 0x03, the device undergoes
the first step of the calibration phase and then pauses to allow
the synchronization process to complete. It is important to note
that, if the synchronization signal is not present and 0x1B[6] is
set, the calibration does not successfully complete. After the
synchronization is finished, the DAC clock calibration proceeds
to completion. When employing the multichip synchronization,
the amount of time to complete the DAC clock calibration
increases by an amount of time equal to 16 cycles of the
synchronization signal.
Figure 48 is a block diagram of the synchronization function.
The synchronization logic is divided into two independent
blocks: a SYNC_OUT generator and a SYNC_IN receiver. The
SYNC_OUT generator consists of a free running divider
clocked by the internal system clock, the same clock from which
all other internal clock signals are derived. The SYNC_OUT
generator block is activated via the SYNC_OUT enable bit in
the CFR2 register (0x01[9]). The SYNC out/in mux enable bit
(0x01[8]) is an output enable bit. Both bits must be in a logic
high state for the internal generator to be active at Pin 61. Either
bit turns off the output signal. However, if the SYNC_OUT
enable bit (0x01[9]) is cleared, the device takes the signal that is
present at Pin 62 and buffers it before driving it out on Pin 61.
For one AD9915 in a group to function as a master timing
source with the remaining devices slaved to the master, set
the SYNC_OUT enable and SYNC out/in mux enable bits
(0x01[9:8]) = 0x03. Set the SYNC_OUT enable bit (0x01[9]) =
0x0 for the devices slaved to the master, whereas SYNC out/in
mux enable bit (0x01[8]) can be either set or cleared. The sync
generator produces a clock signal that appears at the SYNC_
OUT pin. This clock is delivered by a CMOS output driver and
exhibits a 67% duty cycle and has a fixed frequency given by
fSYS/384, where fSYS refers to the system clock frequency. The
clock at the SYNC_OUT pins synchronizes with the rising edge
of the internal SYSCLK signal. Because the SYNC_OUT signal
is synchronized with the internal SYSCLK of the master device,
the master device SYSCLK serves as the reference timing source
for all slave devices. The user can adjust the output delay of the
SYNC_OUT signal by programming the 3-bit SYNC_OUT delay
ADJ word in the USR0 register (0x1B[5:3]) via the serial I/O port.
SYNC_CLK 82
REF_CLK 54
REF CLK
INPUT
CIRCUITRY
REF_CLK 55
SYSCLK
CFR2 [9]
SYNC_OUT 61
SYNC OUT
GENERATOR
SYNC_IN 62
SYNC IN
RECEIVER
INTERNAL
CLOCKS
GENERATOR
INTERNAL
CLOCKS
10837-047
Multiple devices are synchronized when their clock states match
and they transition between states simultaneously. Clock
synchronization allows the user to asynchronously program
multiple devices but synchronously activate the programming
by applying a coincident I/O update to all devices. The function
of the synchronization logic in the AD9915 is to force the internal
clock generator to a predefined state coincident with an external
synchronization signal applied to the SYNC_IN pin. If all devices
are forced to the same clock state in synchronization with the same
external signal, the devices are, by definition, synchronized.
Figure 48. Synchronization Block Diagram
The sync receiver block is a CMOS input that accepts a periodic
clock signal, known as the SYNC_IN signal, at Pin 62 and delivers
it to the appropriate clock generation circuitry requiring
synchronization. If the AD9915 is not enabled as a master
timing device for multiple devices, the sync receiver block can
be used to buffer a signal from Pin 62 to Pin 61. The user can
delay the SYNC_IN signal by programming the 3-bit input
SYNC_IN delay ADJ word in the USR0 register (0x1B[2:0]).
Edge detection logic generates a sync pulse having a duration of
one SYSCLK cycle with a repetition rate equal to the frequency
of the signal applied to the SYNC_IN pin. The sync pulse is
generated as a result of sampling the rising edge of the SYNC_IN
signal with the rising edge of the local SYSCLK. The sync pulse
is routed to the internal clock generator, which behaves as a
presettable counter clocked at the SYSCLK rate. The sync pulse
presets the counter to a predefined state. The predefined state is
active for only a single SYSCLK cycle, after which the clock
generator resumes cycling through its state sequence at the
SYSCLK rate.
Multiple device synchronization is accomplished by providing
each AD9915 with a SYNC_IN signal that is edge aligned across
all the devices. This concept is shown in Figure 49, in which three
AD9915 devices are synchronized, with one device operating as
a master timing unit and the others as slave units. The master
device must have its SYNC_IN pin included as part of the
synchronization distribution and delay equalization mechanism
in order for it to be synchronized with the slave units. The
synchronization mechanism relies on the premise that the
REF_CLK signal appearing at each device is edge aligned with
all others as a result of the external REF_CLK distribution
system (see Figure 49).
Rev. D | Page 34 of 48
Data Sheet
AD9915
The synchronization mechanism begins with the clock
distribution and delay equalization block, which is used to
ensure that all devices receive an edge-aligned REF_CLK signal.
However, even though the REF_CLK signal is edge aligned
among all devices, this alone does not guarantee that the clock
state of each internal clock generator is coordinated with the
others. This is the role of the synchronization redistribution
circuit, which accepts the SYNC_OUT signal generated by the
master device and redistributes it to the SYNC_IN input of the
slave units (as well as feeding it back to the master). The goal of
the redistributed SYNC_OUT signal from the master device is
to deliver an edge-aligned SYNC_IN signal to all of the sync
receivers. Assuming that all devices share the same REF_CLK
edge (due to the clock distribution and delay equalization
block) and all devices share the same SYNC_IN edge (due to
the synchronization distribution and delay equalization block),
all devices should generate an internal sync pulse in unison and
the synchronized sync pulses cause all of the devices to assume
the same predefined clock state simultaneously; that is, the
internal clocks of all devices become fully synchronized. The
synchronization mechanism depends on the reliable generation
of a sync pulse by the edge detection block in the sync receiver.
Generation of a valid sync pulse, however, requires proper
sampling of the rising edge of the SYNC_IN signal with the
rising edge of the local SYSCLK. If the edge timing of these
signals fails to meet the setup or hold time requirements of the
internal latches in the edge detection circuitry, the proper
generation of the sync pulse is in jeopardy.
devices. In general, the propagation delay from the SYNC_IN
pin to the internal clock generators is fixed for a given operating
temperature. However, large temperature differences between
devices or rapid increases in device temperature at power-up
increase the complexity of synchronization.
Table 14 and Table 15 display the delay time increment for both
SYNC_IN and SYNC_OUT vs. their corresponding register values,
from 0 to 7.
Table 14. SYNC_IN Delay (Total Delay = 1.2 ns)
Delay Step
0 to 1
1 to 2
2 to 3
3 to 4
4 to 5
5 to 6
6 to 7
Increment, Typ (ns)
0.26
0.15
0.15
0.15
0.15
0.17
0.17
Table 15. SYNC_OUT Delay (Total Delay = 1.97 ns)
Delay Step
0 to 1
1 to 2
2 to 3
3 to 4
4 to 5
5 to 6
6 to 7
Increment, Typ (ns)
0.17
0.3
0.3
0.3
0.3
0.3
0.3
Ambient operating temperature and self-heating of the AD9915
must also be considered when attempting to synchronize multiple
CLOCK DISTRIBUTION
AND
DELAY EQUALIZATION
EDGE
ALIGNED
AT REF_CLK
INPUTS
CLOCK
SOURCE
(FOR EXAMPLE AD951x)
REF_CLK
PDCLK
DATA
FPGA
NUMBER 1
SYNC SYNC
IN
OUT
REF_CLK
PDCLK
DATA
FPGA
AD9915
AD9915
MASTER DEVICE
EDGE
ALIGNED
AT SYNC_IN
INPUTS
NUMBER 2
SYNC SYNC
IN
OUT
SYNCHRONIZATION
DISTRIBUTION AND
DELAY EQUALIZATION
(FOR EXAMPLE AD951x)
REF_CLK
AD9915
NUMBER 3
SYNC SYNC
IN
OUT
Figure 49. Configuration of Multiple Devices to Be Synchronized
Rev. D | Page 35 of 48
10837-053
FPGA
PDCLK
DATA
AD9915
Data Sheet
REGISTER MAP AND BIT DESCRIPTIONS
Table 16. Register Map
Register
Name (Serial
Address)
CFR1—
Control
Function
Register 1
(0x00)
Bit Range
(Parallel
Address)
[7:0]
(0x00)
[15:8]
(0x01)
Bit 7
(MSB)
Digital
powerdown
Load LRR
at I/O
update
Bit 6
DAC
powerdown
Autoclear
digital
ramp
accumulator
Bit 5
REF CLK
input
powerdown
Autoclear
phase
accumulator
[23:16]
(0x02)
CFR2—
Control
Function
Register 2
(0x01)
[31:24]
(0x03)
[7:0]
(0x04)
[15:8]
(0x05)
[23:16]
(0x06)
CFR3—
Control
Function
Register 3
(0x02)
CFR4—
Control
Function
Register 4
(0x03)
Digital Ramp
Lower Limit
Register
(0x04)
[31:24]
(0x07)
[7:0]
(0x08)
[15:8]
(0x09)
[23:16]
(0x0A)
[31:24]
(0x0B)
[7:0]
(0x0C)
[15:8]
(0x0D)
[23:16]
(0x0E)
[31:24]
(0x0F)
[7:0]
(0x10)
[15:8]
(0x11)
[23:16]
(0x12)
[31:24]
(0x13)
Bit 4
Open
Bit 3
External
power-down
control
Bit 2
Open
Bit 1
SDIO input
only
Clear digital
ramp
accumulator
Clear phase
accumulator
Open
External
OSK enable
OSK
enable
0x00
Parallel port
streaming
enable
Enable
sine
output
VCO cal
enable
0x01
Open
Open
Open
Matched
latency
enable
Profile
mode
enable
Frequency
jump
enable
Parallel
data port
enable
DRG over Open
output
enable
Digital ramp destination
Manual ICP
selection
SYNC_CLK
enable
SYNC_CLK
invert
SYNC_OUT
enable
Digital ramp
enable
Digital
ramp nodwell high
Digital
ramp nodwell low
ICP[2:0]
SYNC out/
in mux
enable
Program
modulus
enable
Input
divider
reset
Input divider[1:0]
Lock
detect
enable
Doubler
enable
0x09
0x00
0x00
Minimum LDW[1:0]
Feedback Divider N[7:0]
Open
0x00
0x00
Open
Open
Default
Value
(Hex) 1
0x08
Bit 0
(LSB)
LSB first
mode
0x1C
0x19
PLL enable
PLL input
divider
enable
Doubler
clock edge
0x00
Open
0x00
Requires register default value settings (0x20)
0x20
Requires register default value settings (0x21)
0x21
Requires register default value settings (0x05)
0x05
Open
Auxiliary
divider
powerdown
DAC CAL
clock
powerdown
DAC CAL
enable 2
0x00
Digital ramp lower limit[7:0]
0x00
Digital ramp lower limit[15:8]
0x00
Digital ramp lower limit[23:16]
0x00
Digital ramp lower limit[31:24]
0x00
Rev. D | Page 36 of 48
Data Sheet
Register
Name (Serial
Address)
Digital Ramp
Upper
Limit
Register
(0x05)
Rising Digital
Ramp Step
Size
Register
(0x06)
Falling Digital
Ramp Step
Size
Register
(0x07)
Digital Ramp
Rate
Register
(0x08)
Lower
Frequency
Jump
Register
(0x09)
Upper
Frequency
Jump
Register
(0x0A)
Profile 0 (P0)
Frequency
Tuning
Word 0
Register
(0x0B)
Bit Range
(Parallel
Address)
[7:0]
(0x14)
[15:8]
(0x15)
[23:16]
(0x16)
[31:24]
(0x17)
[7:0]
(0x18)
[15:8]
(0x19)
[23:16]
(0x1A)
[31:24]
(0x1B)
[7:0]
(0x1C)
[15:8]
(0x1D)
[23:16]
(0x1E)
[31:24]
(0x1F)
[7:0]
(0x20)
[15:8]
(0x21)
[23:16]
(0x22)
[31:24]
(0x23)
[7:0]
(0x24)
[15:8]
(0x25)
[23:16]
(0x26)
[31:24]
(0x27)
[7:0]
(0x28)
[15:8]
(0x29)
[23:16]
(0x2A)
[31:24]
(0x2B)
[7:0]
(0x2C)
[15:8]
(0x2D)
[23:16]
(0x2E)
[31:24]
(0x2F)
AD9915
Bit 7
(MSB)
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Digital ramp upper limit[7:0]
Bit 1
Bit 0
(LSB)
Default
Value
(Hex) 1
0x00
Digital ramp upper limit[15:8]
0x00
Digital ramp upper limit[23:16]
0x00
Digital ramp upper limit[31:24]
0x00
Rising digital ramp increment step size[7:0]
N/A
Rising digital ramp increment step size[15:8]
N/A
Rising digital ramp increment step size[23:16]
N/A
Rising digital ramp increment step size[31:24]
N/A
Falling digital ramp decrement step size[7:0]
N/A
Falling digital ramp decrement step size[15:8]
N/A
Falling digital ramp decrement step size[23:16]
N/A
Falling digital ramp decrement step size[31:24]
N/A
Digital ramp positive slope rate[7:0]
N/A
Digital ramp positive slope rate[15:8]
N/A
Digital ramp negative slope rate[7:0]
N/A
Digital ramp negative slope rate[15:8]
N/A
Lower frequency jump point[7:0]
0x00
Lower frequency jump point[15:8]
0x00
Lower frequency jump point[23:16]
0x00
Lower frequency jump point[31:24]
0x00
Upper frequency jump point[7:0]
0x00
Upper frequency jump point[15:8]
0x00
Upper frequency jump point[23:16]
0x00
Upper frequency jump point[31:24]
0x00
Frequency Tuning Word 0[7:0]
0x00
Frequency Tuning Word 0[15:8]
0x00
Frequency Tuning Word 0[23:16]
0x00
Frequency Tuning Word 0[31:24]
0x00
Rev. D | Page 37 of 48
AD9915
Register
Name (Serial
Address)
Profile 0 (P0)
Phase/
Amplitude
Register
(0x0C)
Profile 1 (P1)
Frequency
Tuning
Word 1
Register
(0x0D)
Profile 1 (P1)
Phase/
Amplitude
Register
(0x0E)
Profile 2 (P2)
Frequency
Tuning
Word 2
Register
(0x0F)
Profile 2 (P2)
Phase/
Amplitude
Register
(0x10)
Profile 3 (P3)
Frequency
Tuning
Word 3
Register
(0x11)
Profile 3 (P3)
Phase/
Amplitude
Register
(0x12)
Data Sheet
Bit Range
(Parallel
Address)
[7:0]
(0x30)
[15:8]
(0x31)
[23:16]
(0x32)
[31:24]
(0x33)
[7:0]
(0x34)
[15:8]
(0x35)
[23:16]
(0x36)
[31:24]
(0x37)
[7:0]
(0x38)
[15:8]
(0x39)
[23:16]
(0x3A)
[31:24]
(0x3B)
[7:0]
(0x3C)
[15:8]
(0x3D)
[23:16]
(0x3E)
[31:24]
(0x3F)
[7:0]
(0x40)
[15:8]
(0x41)
[23:16]
(0x42)
[31:24]
(0x43)
[7:0]
(0x44)
[15:8]
(0x45)
[23:16]
(0x46)
[31:24]
(0x47)
[7:0]
(0x48)
[15:8]
(0x49)
[23:16]
(0x4A)
[31:24]
(0x4B)
Bit 7
(MSB)
Bit 6
Bit 5
Bit 4
Bit 3
Phase Offset Word 0[7:0]
Bit 2
Bit 1
Bit 0
(LSB)
Default
Value
(Hex) 1
0x00
Phase Offset Word 0[15:8]
0x00
Amplitude Scale Factor 0[7:0]
0x00
Open
Amplitude Scale Factor 0[11:8]
0x00
Frequency Tuning Word 1[7:0]
N/A
Frequency Tuning Word 1[15:8]
N/A
Frequency Tuning Word 1[23:16]
N/A
Frequency Tuning Word 1[31:24]
N/A
Phase Offset Word 1[7:0]
N/A
Phase Offset Word 1[15:8]
N/A
Amplitude Scale Factor 1[7:0]
N/A
Open
Amplitude Scale Factor 1[11:8]
N/A
Frequency Tuning Word 2[7:0]
N/A
Frequency Tuning Word 2[15:8]
N/A
Frequency Tuning Word 2[23:16]
N/A
Frequency Tuning Word 2[31:24]
N/A
Phase Offset Word 2[7:0]
N/A
Phase Offset Word 2[15:8]
N/A
Amplitude Scale Factor 2[7:0]
N/A
Open
Amplitude Scale Factor 2[11:8]
N/A
Frequency Tuning Word 3[7:0]
N/A
Frequency Tuning Word 3[15:8]
N/A
Frequency Tuning Word 3[23:16]
N/A
Frequency Tuning Word 3[31:24]
N/A
Phase Offset Word 3[7:0]
N/A
Phase Offset Word 3[15:8]
N/A
Amplitude Scale Factor 3[7:0]
N/A
Open
Amplitude Scale Factor 3[11:8]
Rev. D | Page 38 of 48
N/A
Data Sheet
Register
Name (Serial
Address)
Profile 4 (P4)
Frequency
Tuning
Word 4
Register
(0x13)
Profile 4 (P4)
Phase/
Amplitude
Register
(0x14)
Profile 5 (P5)
Frequency
Tuning
Word 5
Register
(0x15)
Profile 5 (P5)
Phase/
Amplitude
Register
(0x16)
Profile 6 (P6)
Frequency
Tuning
Word 6
Register
(0x17)
Profile 6 (P6)
Phase/
Amplitude
Register
(0x18)
Profile 7 (P7)
Frequency
Tuning
Word 7
Register
(0x19)
Bit Range
(Parallel
Address)
[7:0]
(0x4C)
[15:8]
(0x4D)
[23:16]
(0x4E)
[31:24]
(0x4F)
[7:0]
(0x50)
[15:8]
(0x51)
[23:16]
(0x52)
[31:24]
(0x53)
[7:0]
(0x54)
[15:8]
(0x55)
[23:16]
(0x56)
[31:24]
(0x57)
[7:0]
(0x58)
[15:8]
(0x59)
[23:16]
(0x5A)
[31:24]
(0x5B)
[7:0]
(0x5C)
[15:8]
(0x5D)
[23:16]
(0x5E)
[31:24]
(0x5F)
[7:0]
(0x60)
[15:8]
(0x61)
[23:16]
(0x62)
[31:24]
(0x63)
[7:0]
(0x64)
[15:8]
(0x65)
[23:16]
(0x66)
[31:24]
(0x67)
AD9915
Bit 7
(MSB)
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Frequency Tuning Word 4[7:0]
Bit 1
Bit 0
(LSB)
Default
Value
(Hex) 1
N/A
Frequency Tuning Word 4[15:8]
N/A
Frequency Tuning Word 4[23:16]
N/A
Frequency Tuning Word 4[31:24]
N/A
Phase Offset Word 4[7:0]
N/A
Phase Offset Word 4[15:8]
N/A
Amplitude Scale Factor 4[7:0]
N/A
Open
Amplitude Scale Factor 4[11:8]
N/A
Frequency Tuning Word 5[7:0]
N/A
Frequency Tuning Word 5[15:8]
N/A
Frequency Tuning Word 5[23:16]
N/A
Frequency Tuning Word 5[31:24]
N/A
Phase Offset Word 5[7:0]
N/A
Phase Offset Word 5[15:8]
N/A
Amplitude Scale Factor 5[7:0]
N/A
Open
Amplitude Scale Factor 5[11:8]
N/A
Frequency Tuning Word 6[7:0]
N/A
Frequency Tuning Word 6[15:8]
N/A
Frequency Tuning Word 6[23:16]
N/A
Frequency Tuning Word 6[31:24]
N/A
Phase Offset Word 6[7:0]
N/A
Phase Offset Word 6[15:8]
N/A
Amplitude Scale Factor 6[7:0]
N/A
Open
Amplitude Scale Factor 6[11:8]
N/A
Frequency Tuning Word 7[7:0]
N/A
Frequency Tuning Word 7[15:8]
N/A
Frequency Tuning Word 7[23:16]
N/A
Frequency Tuning Word 7[31:24]
N/A
Rev. D | Page 39 of 48
AD9915
Register
Name (Serial
Address)
Profile 7 (P7)
Phase/
Amplitude
Register
(0x1A)
USR0 (0x1B)
1
2
Data Sheet
Bit Range
(Parallel
Address)
[7:0]
(0x68)
[15:8]
(0x69)
[23:16]
(0x6A)
[31:24]
(0x6B)
[7:0]
(0x6C)
[15:8]
(0x6D)
[23:16]
(0x6E)
[31:24]
(0x6F)
Bit 7
(MSB)
Bit 6
Bit 5
Bit 4
Bit 3
Phase Offset Word 7[7:0]
CAL with
SYNC
Bit 1
Default
Value
(Hex) 1
N/A
Phase Offset Word 7[15:8]
N/A
Amplitude Scale Factor 7[7:0]
N/A
Open
Reserved
Bit 2
Bit 0
(LSB)
Amplitude Scale Factor 7[11:8]
SYNC_OUT delay ADJ[2:0]
N/A
SYNC_IN delay ADJ[2:0]
0x00
Requires register default value settings (0x08)
0x08
Requires register default value settings (0x00)
0x00
Open
PLL lock
Read
only
A master reset is required after power up. The master reset returns the internal registers to their default values.
The DAC CAL enable bit must be manually set and then cleared after each power-up and every time REF CLK or the internal system clock is changed. This initiates an
internal calibration routine to optimize the setup and hold times for internal DAC timing. Failure to calibrate degrades ac performance or makes the part nonfunctional.
Rev. D | Page 40 of 48
Data Sheet
AD9915
REGISTER BIT DESCRIPTIONS
The serial I/O port registers span an address range of 0 to 27
(0x00 to 0x1B in hexadecimal notation). This represents a total
of 28 individual serial registers. If programming in parallel mode,
the number of parallel registers increases to 112 individual parallel
registers. Additionally, the registers are assigned names according
to their functionality. In some cases, a register is given a mnemonic
descriptor. For example, the register at Serial Address 0x00 is
named Control Function Register 1 and is assigned the
mnemonic CFR1.
This section provides a detailed description of each bit in the
AD9915 register map. For cases in which a group of bits serves
a specific function, the entire group is considered a binary word
and is described in aggregate.
This section is organized in sequential order of the serial addresses
of the registers. Each subheading includes the register name and
optional register mnemonic (in parentheses). Also given is the
serial address in hexadecimal format and the number of bytes
assigned to the register.
Following each subheading is a table containing the individual
bit descriptions for that particular register. The location of the
bit(s) in the register is indicated by a single number or a pair of
numbers separated by a colon; that is, a pair of numbers (A:B)
indicates a range of bits from the most significant (A) to the
least significant (B). For example, [5:2] implies Bit Position 5 to
Bit Position 2, inclusive, with Bit 0 identifying the LSB of the
register.
Unless otherwise stated, programmed bits are not transferred to
their internal destinations until the assertion of the I/O_UPDATE
pin or a profile pin change.
Control Function Register 1 (CFR1)—Address 0x00
Table 17. Bit Description for CFR1
Bits
[31:25]
24
Mnemonic
Open
VCO cal enable
[23:18]
17
Open
Parallel port streaming
enable
16
Enable sine output
15
Load LRR at I/O update
14
Autoclear digital ramp
accumulator
13
Autoclear phase accumulator
12
Clear digital ramp
accumulator
11
Clear phase accumulator
10
Open
Description
1 = initializes the auto internal PLL calibration. The calibration is required if the PLL is to
provide the internal system clock. Must first be reset to Logic 0 before another calibration can
be issued.
Open.
0 = the 32 bit parallel port needs an I/O update to activate or register any FTW, POW, or AMP
data presented to the 32-bit parallel port.
1 = the parallel port continuously samples data on the 32 input pins using SYNC_CLK and
multiplexes the value of FTW/POW/AMP accordingly, per the configuration of the F0 to F3
pins, without the need of an I/O update. Data must meet the setup and hold times of the
SYNC_CLK rising edge. If the function pins are used dynamically to alter data between
parameters, they must also meet the timing of the SYNC_CLK edge.
0 = cosine output of the DDS is selected.
1 = sine output of the DDS is selected (default).
Ineffective unless CFR2[19] = 1.
0 = normal operation of the digital ramp timer (default).
1 = interrupts the digital ramp timer operation to load a new linear ramp rate (LRR) value any
time I/O_UPDATE is asserted or a PS[2:0] change occurs.
0 = normal operation of the DRG accumulator (default).
1 = the digital ramp accumulator is reset for one cycle of the DDS clock (SYNC_CLK), after
which the accumulator automatically resumes normal operation. As long as this bit remains
set, the ramp accumulator is momentarily reset each time an I/O update is asserted or a PS[2:0]
change occurs. This bit is synchronized with either an I/O update or a PS[2:0] change and the
next rising edge of SYNC_CLK.
0 = normal operation of the DDS phase accumulator (default).
1 = synchronously resets the DDS phase accumulator anytime I/O_UPDATE is asserted or a
profile change occurs.
0 = normal operation of the digital ramp generator (default).
1 = asynchronous, static reset of the DRG accumulator. The ramp accumulator remains reset as
long as this bit remains set. This bit is synchronized with either an I/O update or a PS[2:0]
change and the next rising edge of SYNC_CLK.
0 = normal operation of the DDS phase accumulator (default).
1 = asynchronous, static reset of the DDS phase accumulator as long as this bit is set. This bit is
synchronized with either an I/O update or a PS[2:0] change and the next rising edge of
SYNC_CLK.
Open.
Rev. D | Page 41 of 48
AD9915
Bits
9
Mnemonic
External OSK enable
8
OSK enable
7
Digital power-down
6
DAC power-down
5
REFCLK input power-down
4
3
Open
External power-down control
2
1
Open
SDIO input only
0
LSB first mode
Data Sheet
Description
0 = manual OSK enabled (default).
1 = automatic OSK enabled.
Ineffective unless CFR1[8] = 1.
0 = OSK disabled (default).
1 = OSK enabled. To engage any digital amplitude adjust using DRG, profile, or direct mode via
the 32-bit parallel port, or OSK pin, this bit must be set.
This bit is effective without the need for an I/O update.
0 = clock signals to the digital core are active (default).
1 = clock signals to the digital core are disabled.
0 = DAC clock signals and bias circuits are active (default).
1 = DAC clock signals and bias circuits are disabled.
This bit is effective without the need for an I/O update.
0 = REFCLK input circuits and PLL are active (default).
1 = REFCLK input circuits and PLL are disabled.
Open.
0 = assertion of the EXT_PWR_DWN pin affects power-down.
1 = assertion of the EXT_PWR_DWN pin affects fast recovery power-down (default).
Open.
0 = configures the SDIO pin for bidirectional operation; 2-wire serial programming
mode (default).
1 = configures the serial data I/O pin (SDIO) as an input only pin; 3-wire serial
programming mode.
0 = configures the serial I/O port for MSB-first format (default).
1 = configures the serial I/O port for LSB-first format.
Control Function Register 2 (CFR2)—Address 0x01
Table 18. Bit Descriptions for CFR2
Bit(s)
[31:24]
23
Mnemonic
Open
Profile mode enable
22
Parallel data port enable
[21:20]
Digital ramp destination
19
Digital ramp enable
18
Digital ramp no-dwell high
17
Digital ramp no-dwell low
16
15
Programmable modulus
enable
Matched latency enable
14
Frequency jump enable
13
DRG over output enable
Description
Open
0 = disables profile mode functionality (default).
1 = enables profile mode functionality. Profile pins are used to select the desired profile.
See the Parallel Data Port Modulation Mode section for more details.
0 = disables parallel data port modulation functionality (default).
1 = enables parallel data port modulation functionality.
See Table 9 for details. Default is 00. See the Digital Ramp Generator (DRG) section for more
details.
0 = disables digital ramp generator functionality (default).
1 = enables digital ramp generator functionality.
See the Digital Ramp Generator (DRG) section for details.
0 = disables no-dwell high functionality (default).
1 = enables no-dwell high functionality.
See the Digital Ramp Generator (DRG) section for details.
0 = disables no-dwell low functionality (default).
1 = enables no-dwell low functionality.
0 = disables programmable modulus.
1 = enables programmable modulus.
0 = simultaneous application of amplitude, phase, and frequency changes to the DDS arrive at
the output in the order listed in Table 2 under data latency (pipe line delay) (default).
1 = simultaneous application of amplitude, phase, and frequency changes to the DDS arrive at
the output simultaneously.
0 = disables frequency jump.
1 = enables frequency jump mode. Must have the digital generator DRG enabled for this
feature.
0 = disables the DROVER output.
1 = enables the DROVER output.
Rev. D | Page 42 of 48
Data Sheet
Bit(s)
12
11
Mnemonic
Open
SYNC_CLK enable
10
SYNC_CLK invert
9
SYNC_OUT enable
8
SYNC out/in mux enable
[7:0]
Open
AD9915
Description
Open.
0 = the SYNC_CLK pin is disabled and forced to a static Logic 0 state; the internal clock signal
continues to operate and provide timing to the data assembler.
1 = the internal SYNC_CLK signal appears at the SYNC_CLK pin (default).
0 = normal SYNC_CLK polarity; Q data associated with Logic 1, I data with Logic 0 (default).
1 = inverted SYNC_CLK polarity.
0 = the SYNC_OUT pin is disabled; static Logic 0 output.
1 = the SYNC_OUT pin is enabled.
0 = the SYNC_OUT signal is routed to the SYNC_OUT pin.
1 = the SYNC_IN signal is routed to the SYNC_OUT pin.
Open.
Control Function Register 3 (CFR3)—Address 0x02
Table 19. Bit Descriptions for CFR3
Bit(s)
[31:23]
22
Mnemonic
Open
Input divider reset
[21:20]
Input divider
19
Doubler enable
18
PLL enable
17
PLL input divider enable
16
Doubler clock edge
[15:8]
Feedback divider N
7
6
Open
Manual ICP selection
[5:3]
2
ICP
Lock detect enable
[1:0]
Minimum LDW
Description
Open.
0 = disables input divider reset function.
1 = initiates a input divider reset.
Divides the input REF CLK signal by one of four values (1, 2, 4, 8). Bit 17 must be set to Logic 1
to enable the PLL input divider.
00 = divide by 1
01 = divide by 2
10 = divide by 4
11 = divide by 8
0 = disables the doubler feature.
1 = enables the doubler feature. Must have the doubler clock edge bit set to Logic 1 to utilize
this feature.
0 = disables the internal PLL.
1 = the internal PLL is enabled and the output generates the system clock. The PLL must be
calibrated when enabled via VCO calibration in Register CFR1, Bit 24.
0 = disables the PLL input divider function.
1 = enables the PLL input divider function.
0 = disables the internal doubler circuit.
1 = enables the doubler circuit. Must have doubler enable bit set to Logic 1 to utilize this
feature.
The N divider value in Bits[15:8] is one part of the total PLL multiplication available. The second
part is the fixed divide by two element in the feedback path. Therefore, the total PLL
multiplication value is 2N. The valid N divider range is 10× to 255×. The default N value for
Bits[15:8] = 25. This sets the total default PLL multiplication to 50× or 2N.
Open.
0 = the internal charge pump current is chosen automatically during the VCO calibration
routine (default).
1 = the internal charge pump is set manually per Table 7.
Manual charge pump current selection. See Table 7.
0 = disables PLL lock detection.
1 = enables PLL lock detection.
Selects the number of REF CLK cycles that the phase error (at the PFD inputs) must remain
within before a PLL lock condition can be read back via Bit 24 in Register 0x00.
00 = 128 REF CLK cycles
01 = 256 REF CLK cycles
10 = 512 REF CLK cycles
11 = 1024 REF CLK cycles
Rev. D | Page 43 of 48
AD9915
Data Sheet
Control Function Register 4 (CFR4)—Address 0x03
Table 20. Bit Descriptions for DAC
Bit(s)
[31:27]
26
24
Mnemonic
Open
Auxiliary divider powerdown
DAC CAL clock powerdown
DAC CAL enable
[23:0]
(See description)
25
Description
Open.
0 = enables the SYNC OUT circuitry.
1 = disables the SYNC OUT circuitry
0 = enables the DAC CAL clock if Bit 26 in Register 0x03 is Logic 0.
1 = disables the DAC CAL clock.
1 = initiates an auto DAC calibration. The DAC CAL calibration is required at power-up and
any time the internal system clock is changed.
These bits must always be programmed with the default values listed in the default column
in Table 16.
Digital Ramp Lower Limit Register—Address 0x04
This register is effective only if the digital ramp enable bit in the CFR2 register (0x01[19]) = 1. See the Digital Ramp Generator (DRG)
section for details.
Table 21. Bit Descriptions for Digital Ramp Lower Limit Register
Bit(s)
[31:0]
Mnemonic
Digital ramp lower limit
Description
32-bit digital ramp lower limit value.
Digital Ramp Upper Limit Register—Address 0x05
This register is effective only if the digital ramp enable bit in the CFR2 register (0x01[19]) = 1. See the Digital Ramp Generator (DRG)
section for details.
Table 22. Bit Descriptions for Digital Ramp Limit Register
Bit(s)
[31:0]
Mnemonic
Digital ramp upper limit
Description
32-bit digital ramp upper limit value.
Rising Digital Ramp Step Size Register—Address 0x06
This register is effective only if the digital ramp enable bit in the CFR2 register (0x01[19]) = 1. See the Digital Ramp Generator (DRG)
section for details.
Table 23. Bit Descriptions for Rising Digital Ramp Step Size Register
Bit(s)
[31:0]
Mnemonic
Rising digital ramp
increment step size
Description
32-bit digital ramp increment step size value.
Falling Digital Ramp Step Size Register—Address 0x07
This register is effective only if the digital ramp enable bit in the CFR2 register (0x01[19]) = 1. See the Digital Ramp Generator (DRG)
section for details.
Table 24. Bit Descriptions for Falling Digital Ramp Step Size Register
Bit(s)
[31:0]
Mnemonic
Falling digital ramp
decrement step size
Description
32-bit digital ramp decrement step size value.
Rev. D | Page 44 of 48
Data Sheet
AD9915
Digital Ramp Rate Register—Address 0x08
This register is effective only if the digital ramp enable bit in the CFR2 register (0x01[19]) = 1. See the Digital Ramp Generator (DRG)
section for details.
Table 25. Bit Descriptions for Digital Ramp Rate Register
Bit(s)
[31:16]
[15:0]
Mnemonic
Digital ramp negative slope
rate
Digital ramp positive slope
rate
Description
16-bit digital ramp negative slope value that defines the time interval between decrement
values.
16-bit digital ramp positive slope value that defines the time interval between increment
values.
Lower Frequency Jump Register—Address 0x09
This register is effective only if the digital ramp enable bit (0x01[19]) = 1 and the frequency jump enable bit (0x01[14]) = 1 in the CFR2
register. See the Digital Ramp Generator (DRG) section for details.
Table 26. Bit Descriptions for Lower Frequency Jump Register
Bit(s)
[31:0]
Mnemonic
Lower frequency jump
point
Description
32-bit digital lower frequency jump value. Any time the lower frequency jump value is
reached during a frequency sweep, the output frequency jumps to the upper frequency
value instantaneously and continues frequency sweeping in a phase-continuous manner.
Upper Frequency Jump Register—Address 0x0A
This register is effective only if the digital ramp enable bit (0x01[19]) = 1 and the frequency jump enable bit (0x01[14]) = 1 in the CFR2
register. See the Digital Ramp Generator (DRG) section for details.
Table 27. Bit Descriptions for Upper Frequency Jump Register
Bit(s)
[31:0]
Mnemonic
Upper frequency jump
point
Description
32-bit digital upper frequency jump value. Any time the upper frequency jump value is
reached during a frequency sweep, the output frequency jumps to the lower frequency
value instantaneously and continues frequency sweeping in a phase-continuous manner.
Rev. D | Page 45 of 48
AD9915
Data Sheet
Profile Registers
There are 16 serial I/O addresses (Address 0x0B to Address 0x01A)
dedicated to device profiles. Eight of the 16 profiles house up to
eight single tone frequencies. The remaining eight profiles contain
the corresponding phase offset and amplitude parameters
relative to the profile pin setting. To enable profile mode, set the
profile mode enable bit in CFR2 (0x01[23]) = 1. The active profile
register is selected using the external PS[2:0] pins.
Profile 0 to Profile 7, Single Tone Registers—0x0B, 0x0D, 0x0F, 0x11, 0x13, 0x15, 0x17, 0x19
Four bytes are assigned to each register.
Table 28. Bit Descriptions for Profile 0 to Profile 7 Single Tone Registers
Bit(s)
[31:0]
Mnemonic
Frequency tuning word
Description
This 32-bit number controls the DDS frequency.
Profile 0 to Profile 7, Phase Offset and Amplitude Registers—0x0C, 0x0E, 0x10, 0x12, 0x14, 0x16, 0x18, 0x1A
Four bytes are assigned to each register.
Table 29. Bit Descriptions for Profile 0 to Profile 7 Phase Offset and Amplitude Registers
Bit(s)
[31:28]
[27:16]
Mnemonic
Open
Amplitude scale factor
[15:0]
Phase offset word
Description
Open.
This 12-bit word controls the DDS frequency. Note that the OSK enable bit (0x00[8]) must
be set to logic high to make amplitude adjustments.
This 16-bit word controls the DDS frequency.
USR0 Register—Address 0x1B
Table 30. Bit Descriptions for USR0 Register
Bit(s)
[31:25]
24
Mnemonic
Open
PLL lock
[23:8]
(See description)
7
6
Reserved
CAL with SYNC
[5:3]
[2:0]
SYNC_OUT delay ADJ
SYNC_IN delay ADJ
Description
This is a readback bit only. If Logic 1 is read back, the PLL is locked. Logic 0 represents a
nonlocked state.
These bits must always be programmed with the default values listed in the default column
in Table 16.
Must be kept at Logic 0 (default).
0 = a SYNC_IN signal is not required to calibrate the DAC clock.
1 = a SYNC_IN signal is required to calibrate the DAC clock.
Provides the ability to delay the SYNC_OUT signal for multichip synchronization purposes.
Provides the ability to delay the internal SYNC_IN signal for multichip synchronization
purposes.
Rev. D | Page 46 of 48
Data Sheet
AD9915
OUTLINE DIMENSIONS
12.10
12.00 SQ
11.90
0.30
0.23
0.18
0.60 MAX
0.60
MAX
88
67
66
1
PIN 1
INDICATOR
PIN 1
INDICATOR
0.50
BSC
11.85
11.75 SQ
11.65
0.50
0.40
0.30
22
23
45
44
BOTTOM VIEW
TOP VIEW
0.70
0.65
0.60
12° MAX
SEATING
PLANE
10.50
REF
0.045
0.025
0.005
COPLANARITY
0.08
0.138~0.194 REF
FOR PROPER CONNECTION OF
THE EXPOSED PAD, REFER TO
THE PIN CONFIGURATION AND
FUNCTION DESCRIPTIONS
SECTION OF THIS DATA SHEET.
*COMPLIANT TO JEDEC STANDARDS MO-220-VRRD
EXCEPT FOR MINIMUM THICKNESS AND LEAD COUNT.
07-02-2012-B
*0.90
0.85
0.75
6.70
REF SQ
EXPOSED PAD
Figure 50. 88-Lead Lead Frame Chip Scale Package [LFCSP_VQ]
12 mm × 12 mm Body, Very Thin Quad
(CP-88-5)
Dimensions shown in millimeters
ORDERING GUIDE
Parameter 1
AD9915BCPZ
AD9915BCPZ-REEL7
AD9915/PCBZ
1
Temperature Range
−40°C to +85°C
−40°C to +85°C
Package Description
88-Lead Lead Frame Chip Scale Package [LFCSP_VQ]
88-Lead Lead Frame Chip Scale Package [LFCSP_VQ]
Evaluation Board
Z = RoHS Compliant Part.
Rev. D | Page 47 of 48
Package Option
CP-88-5
CP-88-5
AD9915
Data Sheet
NOTES
©2012–2014 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D10837-0-1/14(D)
Rev. D | Page 48 of 48