AD9838ACPZ-RL7_技术文档

11 mW Power, 2.3 V to 5.5 V,

Complete DDS

AD9838

Capability for phase modulation and frequency modulation is

provided. The frequency registers are 28 bits wide: with a 16 MHz

clock rate, resolution of 0.06 Hz can be achieved; with a 5 MHz

clock rate, the AD9838 can be tuned to 0.02 Hz resolution.

Frequency and phase modulation are configured by loading

registers through the serial interface and by toggling the registers

using software or the FSELECT and PSELECT pins, respectively.

FEATURES

2.3 V to 5.5 V power supply

MCLK speed: 16 MHz (B grade), 5 MHz (A grade)

Output frequency up to 8 MHz

Sinusoidal and triangular outputs

On-board comparator

3-wire SPI interface

Extended temperature range: −40°C to +125°C

Power-down option

11 mW power consumption at 2.3 V

20-lead LFCSP

The AD9838 is written to via a 3-wire serial interface. This serial

interface operates at clock rates up to 40 MHz and is compatible

with DSP and microcontroller standards.

The device operates with a power supply from 2.3 V to 5.5 V. The

analog and digital sections are independent and can be run from

different power supplies; for example, AVDD can equal 5 V with

DVDD equal to 3 V.

APPLICATIONS

Frequency stimulus/waveform generation

Frequency phase tuning and modulation

Low power RF/communications systems

Liquid and gas flow measurement

Sensory applications: proximity, motion, and defect detection

Test and medical equipment

The AD9838 has a power-down pin (SLEEP) that allows external

control of the power-down mode. Sections of the device that are

not being used can be powered down to minimize current con-

sumption. For example, the DAC can be powered down when

a clock output is being generated.

GENERAL DESCRIPTION

The AD9838 is available in a 20-lead LFCSP_WQ package.

The AD9838 is a low power DDS device capable of producing high

performance sine and triangular outputs. It also has an on-board

comparator that allows a square wave to be produced for clock

generation. Consuming only 11 mW of power at 2.3 V, the

AD9838 is an ideal candidate for power-sensitive applications.

FUNCTIONAL BLOCK DIAGRAM

DVDD CAP/2.5V

AVDD

AGND

DGND

REFOUT FSADJUST

REGULATOR

ON-BOARD

REFERENCE

MCLK

VCC

2.5V

FULL-SCALE

CONTROL

COMP

FSELECT

28-BIT FREQ0

REG

12

PHASE

ACCUMULATOR

(28-BIT)

IOUT

SIN

ROM

10-BIT

DAC

MUX

Σ

IOUTB

28-BIT FREQ1

REG

MSB

12-BIT PHASE0 REG

12-BIT PHASE1 REG

MUX

DIVIDE

BY 2

16-BIT CONTROL

REGISTER

SIGN BIT OUT

VIN

SERIAL INTERFACE

COMPARATOR

AND

CONTROL LOGIC

AD9838

FSYNC

SCLK

SDATA

PSELECT

SLEEP RESET

Figure 1.

Rev. A

Information furnished by Analog Devices is believed to be accurate and reliable. However, no

responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other

rights of third parties that may result from its use. Specifications subject to change without notice. No

license is granted by implication or otherwise under any patent or patent rights of Analog Devices.

Trademarks and registeredtrademarks arethe property of their respective owners.

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.

Tel: 781.329.4700

Fax: 781.461.3113

www.analog.com

AD9838

TABLE OF CONTENTS

Features .............................................................................................. 1

Functional Description.................................................................. 17

Serial Interface............................................................................ 17

Latency Period............................................................................ 17

Control Register ......................................................................... 17

Frequency and Phase Registers ................................................ 19

Reset Function............................................................................ 20

Sleep Function ............................................................................ 20

SIGN BIT OUT Pin.................................................................... 21

IOUT and IOUTB Pins ............................................................. 21

Powering Up the AD9838 ......................................................... 21

Applications Information.............................................................. 24

Grounding and Layout .............................................................. 24

Interfacing to Microprocessors................................................. 24

Evaluation Board ............................................................................ 26

System Demonstration Platform.............................................. 26

AD9838 to SPORT Interface..................................................... 26

Evaluation Kit ............................................................................. 26

Crystal Oscillator vs. External Clock....................................... 26

Power Supply............................................................................... 26

Evaluation Board Schematics ................................................... 27

Evaluation Board Layout........................................................... 29

Outline Dimensions....................................................................... 30

Ordering Guide .......................................................................... 30

Applications....................................................................................... 1

General Description......................................................................... 1

Functional Block Diagram .............................................................. 1

Revision History ............................................................................... 2

Specifications..................................................................................... 3

Timing Characteristics ................................................................ 5

Absolute Maximum Ratings............................................................ 6

Thermal Resistance ...................................................................... 6

ESD Caution.................................................................................. 6

Pin Configuration and Function Descriptions............................. 7

Typical Performance Characteristics ............................................. 9

Test Circuit ...................................................................................... 12

Terminology .................................................................................... 13

Theory of Operation ...................................................................... 14

Circuit Description......................................................................... 15

Numerically Controlled Oscillator Plus Phase Modulator... 15

SIN ROM..................................................................................... 15

Digital-to-Analog Converter (DAC) ....................................... 15

Comparator ................................................................................. 15

Regulator...................................................................................... 16

REVISION HISTORY

4/11—Rev. 0 to Rev. A

Change to Title.................................................................................. 1

Change to Figure 3 ........................................................................... 5

Change to Figure 8 ........................................................................... 9

4/11—Revision 0: Initial Version

Rev. A | Page 2 of 32

AD9838

SPECIFICATIONS

AVDD = DVDD = 2.3 V to 5.5 V, AGND = DGND = 0 V, T_A= T_MINto T_MAX, R_SET= 6.8 kΩ, R_LOAD= 200 Ω for IOUT and IOUTB, unless

otherwise noted.

Table 1.

Parameter¹

Min

Typ

Max

Unit

Test Conditions/Comments

SIGNAL DAC SPECIFICATIONS

Resolution

10

Bits

Update Rate

A Grade

B Grade

I_OUTFull Scale²

V_OUTMaximum

V_OUTMinimum

Output Compliance³

5

16

MSPS

mA

V

mV

V

3.0

0.6

30

0.8

DC Accuracy

Integral Nonlinearity (INL)

Differential Nonlinearity (DNL)

DDS SPECIFICATIONS

Dynamic Specifications

Signal-to-Noise Ratio (SNR)

A Grade

1

0.5

LSB

−63

−64

dB

f_MCLK= 5 MHz, f_OUT= f_MCLK/4096

f_MCLK= 16 MHz, f_OUT= f_MCLK/4096

B Grade

Total Harmonic Distortion (THD)

A Grade

B Grade

−64

dBc

f_MCLK= 5 MHz, f_OUT= f_MCLK/4096

f_MCLK= 16 MHz, f_OUT= f_MCLK/4096

Spurious-Free Dynamic Range (SFDR)

Wideband (0 to Nyquist)

A Grade

−68

−66

dBc

f_MCLK= 5 MHz, f_OUT= f_MCLK/50

f_MCLK= 16 MHz, f_OUT= f_MCLK/50

B Grade

Narrow-Band ( 200 ꢀHz)

A Grade

B Grade

−97

−92

dBc

f_MCLK= 5 MHz, f_OUT= f_MCLK/50

f_MCLK= 16 MHz, f_OUT= f_MCLK/50

Clocꢀ Feedthrough

A Grade

B Grade

−68

−65

1

dBc

ms

f_MCLK= 5 MHz, f_OUT= reset

f_MCLK= 16 MHz, f_OUT= reset

Waꢀe-Up Time

COMPARATOR

Input Voltage Range

Input Capacitance

Input High-Pass Cutoff Frequency

Input DC Resistance

Input Leaꢀage Current

OUTPUT BUFFER

Output Rise/Fall Time

Output Jitter

1

V p-p

pF

MHz

MΩ

μA

AC-coupled internally

10

3

5

10

12

120

ns

ps rms

Using a 15 pF load

3 MHz sine wave 0.6 V p-p

VOLTAGE REFERENCE

Internal Reference

REFOUT Output Impedance⁴

Reference TC

1.11

1.18

1

100

1.14

1.24

V

ꢀΩ

ppm/°C

V

FSADJUST Voltage

Rev. A | Page 3 of 32

AD9838

Parameter¹

Min

Typ

Max

Unit

Test Conditions/Comments

LOGIC INPUTS

Input High Voltage, V_INH

1.7

2.0

2.8

V

μA

pF

2.3 V to 2.7 V power supply

2.7 V to 3.6 V power supply

4.5 V to 5.5 V power supply

2.3 V to 2.7 V power supply

2.7 V to 3.6 V power supply

4.5 V to 5.5 V power supply

Input Low Voltage, V_INL

0.6

0.7

0.8

10

Input Current, I_INH/I_INL

Input Capacitance, C_IN

POWER SUPPLIES

AVDD

3

2.3

5.5

5

V

mA

f_MCLK= 16 MHz, f_OUT= f_MCLK/4096

I_DDcode dependent; see Figure 7

See Figure 6

DVDD

5

I_AA

3.7

5

I_DD

A Grade

B Grade

0.9

1.2

2

2.4

mA

5

I_AA+ I_DD

A Grade

B Grade

4.6

4.9

7

7.4

mA

Low Power Sleep Mode

A Grade

B Grade

DAC powered down; see Table 17

0.4

mA

¹Operating temperature range is −40°C to +125°C; typical specifications are at 25°C.

²For compliance with the specified load of 200 Ω, I_OUTfull scale should not exceed 4 mA.

³Guaranteed by design.

⁴Applies when REFOUT is sourcing current. The impedance is higher when REFOUT is sinꢀing current.

⁵Measured with the digital inputs static and equal to 0 V or DVDD.

Rev. A | Page 4 of 32

AD9838

TIMING CHARACTERISTICS

DVDD = 2.3 V to 5.5 V, AGND = DGND = 0 V, unless otherwise noted.

Table 2.

Parameter¹

Limit at T_MINto T_MAX

Unit

Description

t₁

t₂

t₃

t₄

t₅

t₆

t₇

t₈

200/62.5

80/26

ns min

ns max

ns min

MCLK period (5 MHz/16 MHz)

MCLK high duration (5 MHz/16 MHz)

MCLK low duration (5 MHz/16 MHz)

SCLK period

SCLK high duration

SCLK low duration

80/26

25

10

5

10

t₄− 5

5

3

8

5

FSYNC to SCLK falling edge setup time

SCLK falling edge to FSYNC rising edge time

t₉

Data setup time

Data hold time

FSELECT, PSELECT setup time before MCLK rising edge

FSELECT, PSELECT setup time after MCLK rising edge

SCLK high to FSYNC falling edge setup time

t₁₀

t₁₁

t_11A

t₁₂

¹Guaranteed by design; not production tested.

Timing Diagrams

t₁

MCLK

t₂

t₃

Figure 2. Master Clock

MCLK

t_11A

t₁₁

FSELECT,

PSELECT

VALID DATA

Figure 3. Control Timing

t₅

t₄

t₁₂

SCLK

t₇

t₆

t₈

FSYNC

t₁₀

t₉

SDATA

D15

D14

D2

D1

D0

D15

D14

Figure 4. Serial Timing

Rev. A | Page 5 of 32

AD9838

ABSOLUTE MAXIMUM RATINGS

T_A= 25°C, unless otherwise noted.

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 3.

Parameter

Rating

AVDD to AGND

DVDD to DGND

AVDD to DVDD

AGND to DGND

−0.3 V to +6 V

−0.3 V to +0.3 V

2.75 V

THERMAL RESISTANCE

CAP/2.5V

θ_JAis specified for the worst-case conditions, that is, a device

soldered in a circuit board for surface-mount packages.

Digital I/O Voltage to DGND

Analog I/O Voltage to AGND

Operating Temperature Range

Industrial (B Version)

Storage Temperature Range

Maximum Junction Temperature

Lead Temperature, Soldering (10 sec)

IR Reflow, Peaꢀ Temperature

Reflow Soldering (Pb Free)

Peaꢀ Temperature

−0.3 V to DVDD + 0.3 V

−0.3 V to AVDD + 0.3 V

Table 4. Thermal Resistance

−40°C to +125°C

−65°C to +150°C

150°C

300°C

220°C

Package Type

θ_JA

θ_JC

Unit

20-Lead LFCSP_WQ (CP-20-10)

49.5

5.3

°C/W

ESD CAUTION

260°C (+0/−5)

Time at Peaꢀ Temperature

10 sec to 40 sec

Rev. A | Page 6 of 32

AD9838

PIN CONFIGURATION AND FUNCTION DESCRIPTIONS

15 AGND

AVDD

DVDD

CAP/2.5V

DGND

1

2

3

4

5

14 VIN

AD9838

13 SIGN BIT OUT

12 FSYNC

11 SCLK

TOP

VIEW

MCLK

(Not to Scale)

NOTES

1. CONNECT EXPOSED PAD TO GROUND.

Figure 5. Pin Configuration

Table 5. Pin Function Descriptions

Pin No.

Mnemonic

Description

1

AVDD

Positive Power Supply for the Analog Section. AVDD can have a value from 2.3 V to 5.5 V. A 0.1 μF decoupling

capacitor should be connected between AVDD and AGND.

2

3

DVDD

Positive Power Supply for the Digital Section. DVDD can have a value from 2.3 V to 5.5 V. A 0.1 μF decoupling

capacitor should be connected between DVDD and DGND.

The digital circuitry operates from a 2.5 V power supply. This 2.5 V is generated from DVDD using an on-board

regulator when DVDD exceeds 2.7 V. The regulator requires a decoupling capacitor of 100 nF typical, which is

connected from CAP/2.5V to DGND. If DVDD is less than or equal to 2.7 V, CAP/2.5V should be shorted to DVDD.

CAP/2.5V

4

5

DGND

MCLK

Digital Ground.

Digital Clocꢀ Input. DDS output frequencies are expressed as a binary fraction of the frequency of MCLK. The

output frequency accuracy and phase noise are determined by this clocꢀ.

6

7

FSELECT

PSELECT

Frequency Select Input. FSELECT controls which frequency register, FREQ0 or FREQ1, is used in the phase

accumulator. The frequency register to be used can be selected using the FSELECT pin or the FSEL bit. When

the FSEL bit is used to select the frequency register, the FSELECT pin should be tied to CMOS high or low.

Phase Select Input. PSELECT controls which phase register, PHASE0 or PHASE1, is added to the phase accumulator

output. The phase register to be used can be selected using the PSELECT pin or the PSEL bit. When the PSEL bit

is used to select the phase register, the PSELECT pin should be tied to CMOS high or low.

8

9

RESET

SLEEP

Active High Digital Input. This pin resets the appropriate internal registers to 0 (this corresponds to an analog

output of midscale). RESET does not affect any of the addressable registers.

Active High Digital Input. When this pin is high, the DAC is powered down. This pin has the same function as

the SLEEP12 control bit.

10

11

12

SDATA

SCLK

FSYNC

Serial Data Input. The 16-bit serial data-word is applied to this input.

Serial Clocꢀ Input. Data is clocꢀed into the AD9838 on each falling edge of SCLK.

Active Low Control Input. FSYNC is the frame synchronization signal for the input data. When FSYNC is taꢀen

low, the internal logic is informed that a new word is being loaded into the device.

13

14

SIGN BIT OUT Logic Output. The comparator output is available on this pin or, alternatively, the MSB from the NCO can be

output on this pin. Setting the OPBITEN bit in the control register to 1 enables this output pin. The SIGN/PIB bit

determines whether the comparator output or the MSB from the NCO is output on this pin.

VIN

Input to Comparator. The comparator can be used to generate a square wave from the sinusoidal DAC output.

The DAC output should be filtered appropriately before it is applied to the comparator to reduce jitter. When

the OPBITEN and SIGN/PIB bits in the control register are set to 1, the comparator input is connected to VIN.

15

AGND

Analog Ground.

16, 17

IOUT,

IOUTB

Current Output. This is a high impedance current source. A load resistor of nominally 200 Ω should be connected

between IOUT and AGND. IOUTB should be tied to AGND through an external load resistor of 200 Ω, but it can

be tied directly to AGND. A 20 pF capacitor to AGND is also recommended to prevent clocꢀ feedthrough.

Rev. A | Page 7 of 32

AD9838

Pin No.

Mnemonic

Description

18

FSADJUST

Full-Scale Adjust Control. A resistor (R_SET) is connected between this pin and AGND to determine the magnitude

of the full-scale DAC current. The relationship between R_SETand the full-scale current is as follows:

IOUT _{FULL SCALE}= 18 × FSADJUST/R_SET

FSADJUST = 1.14 V nominal, R_SET= 6.8 ꢀΩ typical

19

20

REFOUT

COMP

EP

Voltage Reference Output. The AD9838 has an internal 1.20 V reference that is available at this pin.

DAC Bias Pin. This pin is used for decoupling the DAC bias voltage.

Exposed Pad. Connect the exposed pad to ground.

Rev. A | Page 8 of 32

AD9838

TYPICAL PERFORMANCE CHARACTERISTICS

–40

6.0

AVDD = DVDD = 3V

= 25°C

0Hz TO NYQUIST

T

–45

–50

–55

–60

A

5.5

VDD = 5V

5.0

VDD = 3V

4.5

4.0

MCLK/7

–65

–70

–75

–80

MCLK/50

3.5

3.0

1

6

11

16

0

2

4

6

8

10

12

14

16

18

MCLK FREQUENCY (MHz)

Figure 6. Typical Current Consumption (I_DD+ I_AA) vs. MCLK Frequency

for f_OUT= MCLK/10

Figure 9. Wideband SFDR vs. MCLK Frequency

–40

–45

2.5

2.0

VDD = 5V

–50

–55

1.5

VDD = 3V

1.0

–60

0.5

0

–65

–70

0

2

4

6

8

10

12

14

16

18

0

2

4

6

8

10

12

14

16

18

MCLK FREQUENCY (MHz)

Figure 7. Typical Current Consumption (I_DD) vs. MCLK Frequency

for f_OUT= MCLK/10

Figure 10. SNR vs. MCLK Frequency

–91

1000

900

AVDD = DVDD = 3V

T

= 25°C

A

–92

–93

–94

–95

±200kHz

VDD = 2.3V

800

700

MCLK/50

VDD = 5.5V

MCLK/7

–96

–97

–98

–99

600

500

400

–40

–20

0

20

40

60

80

100

120

140

0

2

4

6

8

10

12

14

16

TEMPERATURE (°C)

MCLK FREQUENCY (MHz)

Figure 11. Wake-Up Time vs. Temperature

Figure 8. Narrow-Band SFDR vs. MCLK Frequency

Rev. A | Page 9 of 32

AD9838

1.180

0

–10

–20

–30

–40

–50

–60

–70

–80

–90

–100

1.178

VDD = 2.7V

1.176

1.174

1.172

1.170

1.168

1.166

VDD = 5.0V

1.164

–40

–20

0

20

40

60

80

100

120

140

0

10

20

30

40

50

60

70

80

90

100

TEMPERATURE (°C)

FREQUENCY (kHz)

Figure 12. V_REFvs. Temperature

Figure 15. Power vs. Frequency, f_MCLK= 16 MHz, f_OUT= 3.8 kHz,

Frequency Word = 0x000FBA9

0.20

0.18

0.16

0.14

0.12

0.10

0.08

0.06

0.04

0.02

0

–10

–20

–30

–40

–50

–60

–70

–80

–90

–100

DVDD = 3.3V

DVDD = 2.3V

DVDD = 5.5V

0

–40

–20

0

20

40

60

80

100

0

10

20

30

40

50

60

70

80

90

100

TEMPERATURE (°C)

FREQUENCY (kHz)

Figure 13. SIGN BIT OUT Pin, Low Level, I_SINK= 1 mA

Figure 16. Power vs. Frequency, f_MCLK= 5 MHz, f_OUT= 1.2 kHz,

Frequency Word = 0x000FBA9

5.5

5.0

4.5

4.0

3.5

3.0

2.5

2.0

1.5

0

–10

–20

–30

–40

–50

–60

–70

–80

–90

DVDD = 5.5V

DVDD = 4.5V

DVDD = 3.3V

DVDD = 2.7V

DVDD = 2.3V

–100

–40

–20

0

20

40

60

80

100

0

0.5

1.0

1.5

2.0

2.5

TEMPERATURE (°C)

FREQUENCY (MHz)

Figure 14. SIGN BIT OUT Pin, High Level, I_SINK= 1 mA

Figure 17. Power vs. Frequency, f_MCLK= 5 MHz, f_OUT= 0.714 MHz = f_MCLK/7,

Frequency Word = 0x2492492

Rev. A | Page 10 of 32

AD9838

0

–10

–20

–30

–40

–50

–60

–70

–80

–90

0

1

2

3

4

5

6

7

8

FREQUENCY (MHz)

Figure 18. Power vs. Frequency, f_MCLK= 16 MHz, f_OUT= 2.28 MHz,

Frequency Word = 0x2492492

Rev. A | Page 11 of 32

AD9838

TEST CIRCUIT

R

SET

6.8kΩ

100nF

10nF

AVDD

10nF

CAP/2.5V

REFOUT

FSADJUST

COMP

ON-BOARD

REFERENCE

FULL-SCALE

REGULATOR

CONTROL

12

IOUT

SIN

ROM

10-BIT DAC

AD9838

R

LOAD

200Ω

20pF

Figure 19. Test Circuit Used to Test Specifications

Rev. A | Page 12 of 32

AD9838

TERMINOLOGY

Integral Nonlinearity (INL)

Total Harmonic Distortion (THD)

INL is the maximum deviation of any code from a straight line

passing through the endpoints of the transfer function. The

endpoints of the transfer function are zero scale, a point 0.5 LSB

below the first code transition (000 … 00 to 000 … 01), and full

scale, a point 0.5 LSB above the last code transition (111 … 10

to 111 … 11). The error is expressed in LSBs.

Total harmonic distortion (THD) is the ratio of the rms sum of

harmonics to the rms value of the fundamental. For the AD9838,

THD is defined as

2

V₂²+V₃²+V₄²+V₅²+V₆

THD = 20 log

V₁

Differential Nonlinearity (DNL)

where:

DNL is the difference between the measured and ideal 1 LSB

change between two adjacent codes in the DAC. A specified

DNL of 1 LSB maximum ensures monotonicity.

V₁is the rms amplitude of the fundamental.

V₂, V₃, V₄, V₅, and V₆are the rms amplitudes of the second

through sixth harmonics.

Output Compliance

Signal-to-Noise Ratio (SNR)

Output compliance refers to the maximum voltage that can be

generated at the output of the DAC to meet the specifications.

When voltages greater than that specified for the output compli-

ance are generated, the AD9838 may not meet the specifications

listed in the data sheet.

SNR is the ratio of the rms value of the measured output signal

to the rms sum of all other spectral components below the

Nyquist frequency. The value for SNR is expressed in decibels.

Clock Feedthrough

There is feedthrough from the MCLK input to the analog

output. Clock feedthrough refers to the magnitude of the

MCLK signal relative to the fundamental frequency in the

output spectrum of the AD9838.

Spurious-Free Dynamic Range (SFDR)

Along with the frequency of interest, harmonics of the funda-

mental frequency and images of these frequencies are present at

the output of a DDS device. The spurious-free dynamic range

(SFDR) refers to the largest spur or harmonic present in the

band of interest. The wideband SFDR gives the magnitude of

the largest spur or harmonic relative to the magnitude of the

fundamental frequency in the 0 to Nyquist bandwidth. The

narrow-band SFDR gives the attenuation of the largest spur or

harmonic in a bandwidth of 200 kHz about the fundamental

frequency.

Rev. A | Page 13 of 32

AD9838

THEORY OF OPERATION

Sine waves are typically thought of in terms of their magnitude

form: a(t) = sin(ωt). However, sine waves are nonlinear and not

easy to generate except through piecewise construction. On the

other hand, the angular information is linear in nature; that is,

the phase angle rotates through a fixed angle for each unit of

time. The angular rate depends on the frequency of the signal

by the traditional rate of ω = 2πf.

Knowing that the phase of a sine wave is linear and given a

reference interval (clock period), the phase rotation for that

period can be determined as follows:

ΔPhase = ωΔt

Solving for ω,

(1)

(2)

ω = ΔPhase/Δt = 2πf

MAGNITUDE

Solving for f and substituting the reference clock frequency for

the reference period (1/f_MCLK= Δt),

+1

6π

0

f = ΔPhase × f_MCLK∕2π

(3)

4π

2π

The AD9838 builds the output based on this simple equation. A

simple DDS chip can implement this equation with three major

subcircuits: numerically controlled oscillator (NCO) plus phase

modulator, SIN ROM, and digital-to-analog converter (DAC).

Each subcircuit is described in the Circuit Description section.

–1

28

6π

4π

2π

PHASE

2

0

Figure 20. Sine Wave

Rev. A | Page 14 of 32

AD9838

CIRCUIT DESCRIPTION

The AD9838 is a fully integrated direct digital synthesis (DDS)

chip. The chip requires one reference clock, one low precision

resistor, and eight decoupling capacitors to provide digitally

created sine waves up to 8 MHz. In addition to the generation

of this RF signal, the chip is fully capable of a broad range of

simple and complex modulation schemes. These modulation

schemes are fully implemented in the digital domain, allowing

accurate and simple realization of complex modulation algo-

rithms using DSP techniques.

Although the NCO contains a 28-bit phase accumulator, the

output of the NCO is truncated to 12 bits. Using the full reso-

lution of the phase accumulator is impractical and unnecessary

because a lookup table of 2²⁸entries would be required. It is only

necessary to have sufficient phase resolution such that the errors

due to truncation are smaller than the resolution of the 10-bit

DAC. Therefore, the SIN ROM must have two bits of phase

resolution more than the 10-bit DAC.

The SIN ROM is enabled using the OPBITEN and MODE bits

(Bit D5 and Bit D1) in the control register (see Table 19).

The internal circuitry of the AD9838 consists of the following

main sections: a numerically controlled oscillator (NCO),

frequency and phase modulators, SIN ROM, a digital-to-analog

converter, a comparator, and a regulator.

DIGITAL-TO-ANALOG CONVERTER (DAC)

The AD9838 includes a high impedance, current source, 10-bit

DAC capable of driving a wide range of loads. The full-scale

output current can be adjusted for optimum power and external

load requirements using a single external resistor (R_SET).

NUMERICALLY CONTROLLED OSCILLATOR PLUS

PHASE MODULATOR

The AD9838 consists of two frequency select registers, a phase

accumulator, two phase offset registers, and a phase offset adder.

The main component of the NCO is a 28-bit phase accumulator.

Continuous time signals have a phase range of 0 to 2π. Outside

this range of numbers, the sinusoid functions repeat themselves

in a periodic manner. The digital implementation is no different.

The accumulator simply scales the range of phase numbers into

a multibit digital word. The phase accumulator in the AD9838

is implemented with 28 bits. Therefore, in the AD9838, 2π = 2²⁸.

Likewise, the ΔPhase term is scaled into this range of numbers:

The DAC can be configured for single-ended or differential

operation. The IOUT and IOUTB pins can be connected through

equal external resistors to AGND to develop complementary

output voltages. The load resistors can be of any value required,

as long as the full-scale voltage developed across them does not

exceed the output compliance range. Because full-scale current

is controlled by R_SET, adjustments to R_SETcan balance changes

made to the load resistors.

COMPARATOR

The AD9838 can be used to generate synthesized digital clock

signals. This is accomplished by using the on-board self-biasing

comparator that converts the sinusoidal signal of the DAC to a

square wave. The output from the DAC can be filtered externally

before being applied to the comparator input. The comparator

reference voltage is the time average of the signal applied to VIN.

The comparator can accept signals in the range of approximately

100 mV p-p to 1 V p-p. The comparator input is ac-coupled;

therefore, to operate correctly as a zero-crossing detector, the

comparator requires a minimum input frequency of 3 MHz typ-

ical. The comparator output is a square wave with an amplitude

from 0 V to DVDD.

0 < ΔPhase < 2²⁸− 1

With these substitutions, Equation 3 becomes

f = ΔPhase × f_MCLK∕2²⁸

(4)

where 0 < ΔPhase < 2²⁸− 1.

The input to the phase accumulator can be selected from either

the FREQ0 register or the FREQ1 register and is controlled by

the FSELECT pin or the FSEL bit in the control register. NCOs

inherently generate continuous phase signals, thus avoiding any

output discontinuity when switching between frequencies.

Following the NCO, a phase offset can be added to perform

phase modulation using the 12-bit phase registers. The contents

of one of these phase registers is added to the MSBs of the NCO.

The AD9838 has two phase registers; their resolution is 2π/4096.

The AD9838 provides a sampled signal with its output follow-

ing Nyquist sampling theorem. Specifically, its output spectrum

contains the fundamental plus aliased signals (images) that occur

at multiples of the reference clock frequency and the selected

output frequency. A graphical representation of the sampled

spectrum, with aliased images, is shown in Figure 21.

SIN ROM

To make the output from the NCO useful, it must be converted

from phase information into a sinusoidal value. Because phase

information maps directly to amplitude, the SIN ROM uses the

digital phase information as an address to a lookup table and

converts the phase information into amplitude.

Rev. A | Page 15 of 32

AD9838

The prominence of the aliased images depends on the ratio of

f_OUTto MCLK. If the ratio is small, the aliased images are very

prominent and of a relatively high energy level as determined by

the sin(x)/x roll-off of the quantized DAC output. In fact, depend-

ing on the f_OUT/reference clock ratio, the first aliased image can

be on the order of −3 dB below the fundamental.

REGULATOR

The AD9838 has separate power supplies for the analog and

digital sections. AVDD provides the power supply required for

the analog section, and DVDD provides the power supply for

the digital section. Both supplies can have a value of 2.3 V to

5.5 V and are independent of each other. For example, the

analog section can be operated at 5 V, and the digital section

can be operated at 3 V, or vice versa.

A low-pass filter is generally placed between the output of the

DAC and the input of the comparator to further suppress the

effects of aliased images. To avoid unwanted (and unexpected)

output anomalies, it is necessary to consider the relationship of

the selected output frequency and the reference clock frequency.

The internal digital section of the AD9838 is operated at 2.5 V.

An on-board regulator steps down the voltage applied at DVDD

to 2.5 V. The digital interface (serial port) of the AD9838 also

operates from DVDD. These digital signals are level shifted

within the AD9838 to make them 2.5 V compatible.

To apply the AD9838 as a clock generator, limit the selected

output frequency to <33% of the reference clock frequency. In

this way, the user can prevent the generation of aliased signals

that fall within, or close to, the output band of interest (generally

the dc selected output frequency). This practice reduces the

complexity (and cost) of the external filter requirement for the

clock generator application. For more information, see the

AN-837 Application Note.

If the voltage applied at the DVDD pin of the AD9838 is less than

or equal to 2.7 V, the CAP/2.5V and DVDD pins should be tied

together to bypass the on-board regulator.

To enable the comparator, the SIGN/PIB and OPBITEN bits in

the control resister must be set to 1 (see Table 18).

f_OUT

sin(x)/x ENVELOPE

x = π (f/f_C)

f_C– f_OUT

f_C

+

f_OUT

2f_C– f_OUT

2

f_C

+

f_OUT

3f_C– f_OUT

f_C

2f_C

3f_C+ f_OUT

3

f_C

0Hz

FIRST

IMAGE

SECOND

IMAGE

THIRD

IMAGE

FOURTH

IMAGE

FIFTH

IMAGE

SIXTH

IMAGE

SYSTEM CLOCK

FREQUENCY (Hz)

Figure 21. DAC Output Spectrum

Rev. A | Page 16 of 32

AD9838

FUNCTIONAL DESCRIPTION

When the t₁₁and t_11Atiming specifications are met (see Figure 3),

FSELECT and PSELECT have latencies of eight MCLK cycles.

When the t₁₁and t_11Atiming specifications are not met, the latency

is increased by one MCLK cycle.

SERIAL INTERFACE

The AD9838 has a standard 3-wire serial interface that is

compatible with the SPI, QSPI™, MICROWIRE®, and DSP

interface standards.

Similarly, a latency period is associated with each asynchronous

write operation. If a selected frequency or phase register is

loaded with a new word, there is a delay of eight or nine MCLK

cycles before the analog output changes. The delay can be eight

or nine MCLK cycles, depending on the position of the MCLK

rising edge when the data is loaded into the destination register.

Data is loaded into the device as a 16-bit word under the control

of a serial clock input, SCLK. The timing diagram for this oper-

ation is given in Figure 4.

FSYNC is a level triggered input that acts as a frame synchroni-

zation and chip enable input. Data can be transferred into the

device only when FSYNC is low. To start the serial data transfer,

FSYNC should be taken low, observing the minimum FSYNC

to SCLK falling edge setup time, t₇(see Table 2). After FSYNC

goes low, serial data is shifted into the input shift register of the

device on the falling edges of SCLK for 16 clock pulses. FSYNC

can be taken high after the 16th falling edge of SCLK, observing

the minimum SCLK falling edge to FSYNC rising edge time, t₈.

Alternatively, FSYNC can be kept low for a multiple of 16 SCLK

pulses and then brought high at the end of the data transfer. In

this way, a continuous stream of 16-bit words can be loaded

while FSYNC is held low; FSYNC goes high only after the 16th

SCLK falling edge of the last word loaded.

The negative transitions of the RESET and SLEEP pins are

sampled on the internal falling edge of MCLK. Therefore, they

also have a latency period associated with them.

CONTROL REGISTER

The AD9838 contains a 16-bit control register that allows the

user to configure the operation of the AD9838. All control bits

other than the MODE bit are sampled on the internal falling

edge of MCLK.

Figure 22 illustrates the functions of the control bits. Table 7

describes the individual bits of the control register. The different

functions and the various output options of the AD9838 are

described in more detail in the following sections.

The SCLK can be continuous, or it can idle high or low between

write operations. In either case, it must be high when FSYNC

goes low (t₁₂).

To inform the AD9838 that the contents of the control register

will be altered, Bit D15 and Bit D14 must be set to 0, as shown

in Table 6.

For an example of how to program the AD9838, see the AN-1070

Application Note on the Analog Devices, Inc., website. The

AD9838 has the same register settings as the AD9833/AD9834.

Table 6. Control Register Bits

D15

D14

D13 to D0

LATENCY PERIOD

0

Control bits

A latency period is associated with each operation. When the

FSELECT and PSELECT pins change value, there is a pipeline

delay before control is transferred to the selected register.

SLEEP12

SLEEP1

IOUT

SIN

ROM

0

(LOW POWER)

10-BIT DAC

PHASE

ACCUMULATOR

(28-BIT)

RESET

MUX

IOUTB

1

MSB

MODE + OPBITEN

COMPARATOR

VIN

DIVIDE

BY 2

0

MUX

1

DIGITAL

OUTPUT

(ENABLE)

MUX

SIGN BIT OUT

0

SIGN/PIB

OPBITEN

D15 D14

D13 D12

D11

D10

D9

D8

D7

D6

D5

D4

D3

D2

0

D1

MODE

D0

0

B28 HLB FSEL PSEL PIN/SW RESET SLEEP1 SLEEP12 OPBITEN SIGN/PIB DIV2

Figure 22. Function of Control Bits

Rev. A | Page 17 of 32

AD9838

Table 7. Control Register Bit Descriptions

Bit

Bit Name

Description

D13

B28

Two write operations are required to load a complete word into either of the frequency registers.

B28 = 1 allows a complete word to be loaded into a frequency register in two consecutive writes. The first write

contains the 14 LSBs of the frequency word, and the second write contains the 14 MSBs. The first two bits of each

16-bit word define the frequency register to which the word is loaded and should, therefore, be the same for both

consecutive writes. See Table 11 for the appropriate addresses. The write to the frequency register occurs after both

words have been loaded, so the register never holds an intermediate value. An example of a complete 28-bit write

is shown in Table 12. Note, however, that consecutive 28-bit writes to the same frequency register are not allowed;

to execute consecutive 28-bit writes, you must alternate between the frequency registers.

B28 = 0 configures the 28-bit frequency register to operate as two 14-bit registers, one containing the 14 MSBs and

the other containing the 14 LSBs. In this way, the 14 MSBs of the frequency word can be altered independently of

the 14 LSBs, and vice versa. To alter the 14 MSBs or the 14 LSBs, a single write is made to the appropriate frequency

address. Bit D12 (HLB) informs the AD9838 whether the bits to be altered are the 14 MSBs or the 14 LSBs.

D12

HLB

This control bit allows the user to continuously load the MSBs or LSBs of a frequency register while ignoring the

remaining 14 bits. This is useful if the complete 28-bit resolution is not required. The HLB bit is used in conjunction

with the B28 bit (Bit D13). The HLB bit indicates whether the 14 bits to be loaded are transferred to the 14 MSBs or

the 14 LSBs of the addressed frequency register. Bit D13 (B28) must be set to 0 to change the MSBs or LSBs of a

frequency word separately. When Bit D13 (B28) is set to 1, the HLB bit is ignored.

HLB = 1 allows a write to the 14 MSBs of the addressed frequency register.

HLB = 0 allows a write to the 14 LSBs of the addressed frequency register.

D11

D10

FSEL

PSEL

The FSEL bit defines whether the FREQ0 register or the FREQ1 register is used in the phase accumulator (see Table 9).

The PSEL bit defines whether the PHASE0 register data or the PHASE1 register data is added to the output of the

phase accumulator (see Table 10).

D9

PIN/SW

The following functions can be implemented using either software or hardware: frequency register selection, phase

register selection, reset of internal registers, and DAC power-down. The PIN/SW bit selects the source of control for

these functions.

PIN/SW = 1 selects the control pins to implement the register selection, reset, and DAC power-down functions.

PIN/SW = 0 selects the control bits to implement the register selection, reset, and DAC power-down functions.

D8

D7

RESET

When the PIN/SW bit is set to 0, this bit controls the reset function.

RESET = 1 resets internal registers to 0, which corresponds to an analog output of midscale.

RESET = 0 disables the reset function (see the Reset Function section).

SLEEP1

This bit enables or disables the internal MCLK.

SLEEP1 = 1 disables the internal MCLK. The DAC output remains at its present value because the NCO is no longer

accumulating.

SLEEP1 = 0 enables the internal MCLK (see the Sleep Function section).

D6

D5

SLEEP12

OPBITEN

When the PIN/SW bit is set to 0, this bit powers down the on-chip DAC.

SLEEP12 = 1 powers down the on-chip DAC. This is useful when the AD9838 is used to output the MSB of the DAC data.

SLEEP12 = 0 implies that the DAC is active (see the Sleep Function section).

This bit controls whether an output is available at the SIGN BIT OUT pin. If the user is not using the SIGN BIT OUT

pin, this bit should be set to 0.

OPBITEN = 1 enables the SIGN BIT OUT pin.

OPBITEN = 0 places the SIGN BIT OUT output buffer into a high impedance state (no output is available at the SIGN

BIT OUT pin).

D4

D3

SIGN/PIB

DIV2

This bit controls the output at the SIGN BIT OUT pin when the OPBITEN bit (Bit D5) is set to 1.

SIGN/PIB = 1 connects the on-board comparator to the SIGN BIT OUT pin. After filtering the sinusoidal output from

the DAC, the waveform can be applied to the comparator to generate a square waveform (see Table 18).

SIGN/PIB = 0 connects the MSB (or MSB/2) of the DAC data to the SIGN BIT OUT pin. Bit D3 (DIV2) controls whether

the output is the MSB or MSB/2.

DIV2 is used when the OPBITEN bit (Bit D5) is set to 1 and the SIGN/PIB bit (Bit D4) is set to 0 (see Table 18).

DIV2 = 1 causes the MSB of the DAC data to be output at the SIGN BIT OUT pin.

DIV2 = 0 causes the MSB/2 of the DAC data to be output at the SIGN BIT OUT pin.

This bit must be set to 0.

D2

D1

Reserved

MODE

This bit, in association with the OPBITEN bit (Bit D5), controls the output at the IOUT and IOUTB pins. This bit should

be set to 0 if the OPBITEN bit is set to 1 (see Table 19).

MODE = 1 bypasses the SIN ROM, resulting in a triangle output from the DAC.

MODE = 0 uses the SIN ROM to convert the phase information into amplitude information, resulting in a sinusoidal

signal at the output.

D0

Reserved

This bit must be set to 0.

Rev. A | Page 18 of 32

AD9838

Table 10. Selecting a Phase Register

FREQUENCY AND PHASE REGISTERS

PSELECT Pin

PSEL Bit

PIN/SW Bit Selected Register

The AD9838 contains two frequency registers and two phase

registers, which are described in Table 8.

0

1

X

0

1

0

PHASE0

PHASE1

PHASE0

PHASE1

Table 8. Frequency and Phase Registers

Register Size

Description

28 bits Frequency Register 0.

When the FSEL bit or FSELECT pin = 0, the

FREQ0

The FSELECT and PSELECT pins are sampled on the internal

falling edge of MCLK. It is recommended that the data on these

pins not change within the time window of the falling edge of

MCLK (see Figure 3 for timing). If the FSELECT or PSELECT

pin changes value when a falling edge occurs, there is an uncer-

tainty of one MCLK cycle as it pertains to when control is

transferred to the other frequency/phase register.

FREQ0 register defines the output frequency

as a fraction of the MCLK frequency.

FREQ1

28 bits Frequency Register 1.

When the FSEL bit or FSELECT pin = 1, the

FREQ1 register defines the output frequency

as a fraction of the MCLK frequency.

PHASE0

PHASE1

12 bits Phase Offset Register 0.

The flowcharts in Figure 26 and Figure 27 show the routine for

selecting and writing to the frequency and phase registers of the

AD9838.

When the PSEL bit or PSELECT pin = 0, the

contents of the PHASE0 register are added

to the output of the phase accumulator.

12 bits Phase Offset Register 1.

Writing to a Frequency Register

When the PSEL bit or PSELECT pin = 1, the

contents of the PHASE1 register are added

to the output of the phase accumulator.

When writing to a frequency register, Bit D15 and Bit D14 of

the control register give the address of the frequency register

(see Table 11).

The analog output from the AD9838 is

f_MCLK/2²⁸× FREQREG

Table 11. Frequency Register Bits

D15

D14

D13 to D0

where FREQREG is the value loaded into the selected frequency

register.

0

1

0

14 FREQ0 register bits

14 FREQ1 register bits

This signal is phase shifted by

To change the entire contents of a frequency register, two consec-

utive writes to the same address must be performed because the

frequency registers are 28 bits wide. The first write contains the

14 LSBs, and the second write contains the 14 MSBs. For this

mode of operation, the B28 control bit (Bit D13) must be set

to 1. An example of a 28-bit write is shown in Table 12.

2π/4096 × PHASEREG

where PHASEREG is the value contained in the selected phase

register.

The relationship of the selected output frequency and the refer-

ence clock frequency must be considered to avoid unwanted

output anomalies.

Table 12. Writing 0xFFFC000 to the FREQ0 Register

Selecting a Frequency or Phase Register

SDATA Input

Result of Input Word

Access to the frequency and phase registers is controlled by

the FSELECT and PSELECT pins or by the FSEL and PSEL

control bits. If the PIN/SW control bit (Bit D9) = 1, the pins

control the function; if the PIN/SW control bit = 0, the bits

control the function (see Table 9 and Table 10). If the FSEL

and PSEL bits are used, the pins should be held at CMOS logic

high or low. Control of the frequency and phase registers is

interchangeable from the pins to the bits.

0010 0000 0000 0000

Control word write

(D15, D14 = 00), B28 (D13) = 1,

HLB (D12) = X

FREQ0 register write

(D15, D14 = 01), 14 LSBs = 0x0000

0100 0000 0000 0000

0111 1111 1111 1111

FREQ0 register write

(D15, D14 = 01), 14 MSBs = 0x3FFF

Note, however, that continuous writes to the same frequency

register may result in intermediate updates during the writes. If

a frequency sweep, or something similar, is required, it is recom-

mended that users alternate between the two frequency registers.

Table 9. Selecting a Frequency Register

FSELECT Pin

FSEL Bit

PIN/SW Bit Selected Register

0

1

X

0

1

0

FREQ0

FREQ1

FREQ0

FREQ1

Rev. A | Page 19 of 32

AD9838

In some applications, the user does not need to alter all 28 bits

of the frequency register. With coarse tuning, only the 14 MSBs

are altered; with fine tuning, only the 14 LSBs are altered. By

setting the B28 control bit (Bit D13) to 0, the 28-bit frequency

register operates as two 14-bit registers, one containing the

14 MSBs and the other containing the 14 LSBs. In this way, the

14 MSBs of the frequency word can be altered independently

of the 14 LSBs, and vice versa. The HLB bit (Bit D12) in the

control register identifies which 14 bits are being altered (see

Table 13 and Table 14).

Table 16. Applying the Reset Function

RESET Pin RESET Bit PIN/SW Bit Result

0

1

X

0

1

0

No reset applied

Internal registers reset

No reset applied

Internal registers reset

The effect of asserting the RESET pin is immediately evident

at the output—that is, the 0-to-1 transition of this pin is not

sampled. However, the negative (1-to-0) transition of the

RESET pin is sampled on the internal falling edge of MCLK.

Table 13. Writing 0x3FFF to the 14 LSBs of the FREQ1 Register

SLEEP FUNCTION

SDATA Input

Result of Input Word

Sections of the AD9838 that are not in use can be powered

down to minimize power consumption by using the sleep

function. The parts of the chip that can be powered down are

the internal clock and the DAC. The DAC can be powered

down using hardware or software (see Table 17).

0000 0000 0000 0000

Control word write

(D15, D14 = 00), B28 (D13) = 0,

HLB (D12) = 0, that is, LSBs

FREQ1 register write

(D15, D14 = 10), 14 LSBs = 0x3FFF

1011 1111 1111 1111

Table 17. Applying the Sleep Function

SLEEP SLEEP1 SLEEP12 PIN/SW

Table 14. Writing 0x00FF to the 14 MSBs of the FREQ0 Register

SDATA Input

Result of Input Word

Bit

Result

0001 0000 0000 0000

Control word write

0

X

1

No power-down

DAC powered down

No power-down

DAC powered down

Internal clocꢀ disabled

(D15, D14 = 00), B28 (D13) = 0,

HLB (D12) = 1, that is, MSBs

1

X

1

0100 0000 1111 1111

FREQ0 register write

(D15, D14 = 01), 14 MSBs = 0x00FF

X

0

1

0

1

0

1

0

Writing to a Phase Register

DAC powered down and

internal clocꢀ disabled

When writing to a phase register, Bit D15 and Bit D14 are set

to 11. Bit D13 identifies the phase register that is being loaded.

DAC Powered Down

Table 15. Phase Register Bits

When the AD9838 is used to output the MSB of the DAC data

only, the DAC is not required. The DAC can be powered down

to reduce power consumption.

D15

D14

D13

D12

D11 to D0

1

0

X

12 PHASE0 register bits

12 PHASE1 register bits

1

Internal Clock Disabled

RESET FUNCTION

When the internal clock of the AD9838 is disabled, the DAC

output remains at its present value because the NCO is no longer

accumulating. New frequency, phase, and control words can be

written to the part when the SLEEP1 control bit is active. Because

the synchronizing clock (FSYNC) remains active, the selected

frequency and phase registers can also be changed either at the

pins or by using the control bits. Setting the SLEEP1 bit to 0

enables the MCLK. Any changes made to the registers while

SLEEP1 was active are observed at the output after a latency

period (see the Latency Period section).

The reset function resets the appropriate internal registers to 0

to provide an analog output of midscale. A reset does not reset

the phase, frequency, or control registers. When the AD9838 is

powered up, the part should be reset (see the Powering Up the

AD9838 section). To reset the AD9838, set the RESET pin or bit

to 1. To take the part out of reset, set the RESET pin or bit to 0.

A signal appears at the DAC output eight or nine MCLK cycles

after the RESET pin or bit is set to 0.

The reset function is controlled by either the RESET pin or the

RESET control bit. If the PIN/SW control bit = 0, the RESET bit

controls the function; if the PIN/SW control bit = 1, the RESET

pin controls the function (see Table 16).

The effect of asserting the SLEEP pin is immediately evident

at the output—that is, the 0-to-1 transition of this pin is not

sampled. However, the negative (1-to-0) transition of the SLEEP

pin is sampled on the internal falling edge of MCLK.

Rev. A | Page 20 of 32

AD9838

SIGN BIT OUT PIN

IOUT AND IOUTB PINS

The AD9838 offers a variety of outputs from the chip. The

digital outputs are available from the SIGN BIT OUT pin. The

available outputs are the comparator output or the MSB of the

DAC data. The bits controlling the SIGN BIT OUT pin are

listed in Table 18.

The analog outputs from the AD9838 are available from the

IOUT and IOUTB pins. The available outputs are a sinusoidal

output or a triangular output (see Table 19).

Note that the SLEEP pin and the SLEEP12 bit must be set to 0

(the DAC is enabled) when using the IOUT and IOUTB pins.

Table 18. Outputs from the SIGN BIT OUT Pin

Table 19. Outputs from the IOUT and IOUTB Pins

OPBITEN MODE SIGN/PIB DIV2

OPBITEN Bit

MODE Bit

IOUT and IOUTB Pin Output

Bit

X

0

Bit

SIGN BIT OUT Pin

High impedance

DAC data MSB/2

DAC data MSB

Reserved

0

1

0

1

0

1

Sinusoid

Triangle

Sinusoid

Reserved

0

1

X

0

X

0

1

0

1

0

1

0

1

0

1

X

1

X

Comparator output

Reserved

Sinusoidal Output

The SIN ROM converts the phase information from the

frequency and phase registers into amplitude information,

resulting in a sinusoidal signal at the output. To obtain a

sinusoidal output from the IOUT and IOUTB pins, set the

MODE bit (Bit D1) to 0.

The SIGN BIT OUT pin must be enabled before use. The

OPBITEN bit (Bit D5) in the control register enables and dis-

ables this pin. When OPBITEN = 1, the SIGN BIT OUT pin is

enabled. Note that if OPBITEN = 1, the MODE bit (Bit D1) in

the control register should be set to 0.

Triangle Output

Comparator Output

The SIN ROM can be bypassed so that the truncated digital output

from the NCO is sent to the DAC. In this case, the output is no

longer sinusoidal. The DAC produces a 10-bit linear triangular

function (see Figure 23). To obtain a triangle output from the

IOUT and IOUTB pins, set the MODE bit (Bit D1) to 1 and the

OPBITEN bit (Bit D5) to 0.

The AD9838 has an on-board comparator. To connect this com-

parator to the SIGN BIT OUT pin, the OPBITEN bit (Bit D5)

and the SIGN/PIB bit (Bit D4) must be set to 1. After filtering

the sinusoidal output from the DAC, the waveform can be

applied to the comparator to generate a square waveform.

V

OUT MAX

MSB of the DAC Data

The MSB of the DAC data can be output from the AD9838.

By setting the OPBITEN bit (Bit D5) to 1 and the SIGN/PIB bit

(Bit D4) to 0, the MSB of the DAC data is available at the SIGN

BIT OUT pin. This output is useful as a coarse clock source.

The square wave can also be divided by 2 before being output.

The DIV2 bit (Bit D3) in the control register controls the

frequency of this output from the SIGN BIT OUT pin.

V

OUT MIN

3π/2

7π/2

11π/2

Figure 23. Triangle Output

POWERING UP THE AD9838

The flowchart in Figure 24 shows the operating routine for the

AD9838. When the AD9838 is powered up, the part should be

reset. This resets the appropriate internal registers to 0 to provide

an analog output of midscale. To avoid spurious DAC outputs

during AD9838 initialization, the RESET pin or the RESET bit

should be set to 1 until the part is ready to begin generating

an output.

A reset does not reset the phase, frequency, or control registers.

These registers will contain invalid data and, therefore, should

be set to known values by the user. The RESET pin or bit should

then be set to 0 to begin generating an output. The data appears

on the DAC output eight or nine MCLK cycles after the RESET

pin or bit is set to 0.

Rev. A | Page 21 of 32

AD9838

DATA WRITE

(SEE FIGURE 26)

SELECT DATA

SOURCES

(SEE FIGURE 27)

WAIT 8/9 MCLK

CYCLES

(SEE TIMING DIAGRAM

FIGURE 3)

INITIALIZATION

(SEE FIGURE 25)

DAC OUTPUT

× (1 + (SIN(2π(FREQREG × f_MCLK

28

12

V

= V

REFOUT

× 18 × R

/R

×

t

/2 + PHASEREG/2 ))))

OUT

LOAD SET

YES

CHANGE PSEL/

PSELECT?

CHANGE PHASE?

NO

YES

CHANGE PHASE

REGISTER?

CHANGE FSEL/

FSELECT?

CHANGE FREQUENCY?

NO

YES

NO

CHANGE DAC OUTPUT

FROM SIN TO TRIANGLE?

CHANGE FREQUENCY

REGISTER?

YES

NO

CHANGE OUTPUT AT

SIGN BIT OUT PIN?

CONTROL

REGISTER

WRITE

(SEE TABLE 7)

NO

Figure 24. Flowchart for AD9838 Initialization and Operation

INITIALIZATION

APPLY RESET

USING PIN

USING CONTROL

BIT

(CONTROL REGISTER WRITE)

PIN/SW = 1

SET RESET PIN = 1

RESET = 1

PIN/SW = 0

WRITE TO FREQUENCY AND PHASE REGISTERS

28

FREQ0 REG = f

/f

× 2

OUT0 MCLK

FREQ1 REG = f /f

OUT1 MCLK

12

PHASE0 AND PHASE1 REG = (PHASESHIFT × 2 )/2π

(SEE FIGURE 26)

SET RESET = 0

SELECT FREQUENCY REGISTERS

SELECT PHASE REGISTERS

USING CONTROL

USING PINS

BITS

(CONTROL REGISTER WRITE)

(APPLY SIGNALS AT PINS)

RESET PIN = 0

FSELECT = SELECTED FREQUENCY REGISTER

PSELECT = SELECTED PHASE REGISTER

PIN/SW = 1

RESET BIT = 0

FSEL = SELECTED FREQUENCY REGISTER

PSEL = SELECTED PHASE REGISTER

PIN/SW = 0

Figure 25. Flowchart for Initialization

Rev. A | Page 22 of 32

AD9838

DATA WRITE

NO

WRITE 14 MSBs OR LSBs

TO A FREQUENCY REGISTER?

WRITE A FULL 28-BIT WORD

TO A FREQUENCY REGISTER?

WRITE TO PHASE

REGISTER?

YES

(CONTROL REGISTER WRITE)

B28 (D13) = 0

(CONTROL REGISTER WRITE)

B28 (D13) = 1

HLB (D12) = 0/1

(16-BIT WRITE)

D15, D14 = 11

D13 = 0/1 (CHOOSE THE

WRITE A 16-BIT WORD

PHASE REGISTER)

WRITE TWO CONSECUTIVE

16-BIT WORDS

D12 = X

D11 ... D0 = PHASE DATA

(SEE TABLE 13 AND TABLE 14

FOR EXAMPLES)

(SEE TABLE 12 FOR EXAMPLE)

WRITE 14 MSBs OR LSBs

TO A

FREQUENCY REGISTER?

WRITE TO ANOTHER

PHASE REGISTER?

WRITE ANOTHER FULL

28-BIT WORD TO A

FREQUENCY REGISTER?

YES

NO

Figure 26. Flowchart for Data Writes

SELECT DATA SOURCES

YES

SET FSELECT AND

PSELECT PINS

FSELECT AND PSELECT

PINS BEING USED?

NO

(CONTROL REGISTER WRITE)

PIN/SW = 0

SET FSEL BIT

SET PSEL BIT

(CONTROL REGISTER WRITE)

PIN/SW = 1

Figure 27. Flowchart for Selecting Data Sources

Rev. A | Page 23 of 32

AD9838

APPLICATIONS INFORMATION

The various output options available from the AD9838 make

the part suitable for a wide variety of applications, including

modulation applications. The AD9838 can be used to perform

simple modulation, such as frequency shift keying (FSK). More

complex modulation schemes, such as Gaussian minimum shift

keying (GMSK) and quadrature phase shift keying (QPSK), can

also be implemented using the AD9838.

Avoid crossover of digital and analog signals. Traces on opposite

sides of the board should run at right angles to each other to

reduce the effects of feedthrough through the board. A micro-

strip technique is by far the best but is not always possible with

a double-sided board. In this technique, the component side of

the board is dedicated to ground planes and signals are placed

on the other side.

In an FSK application, the two frequency registers of the AD9838

are loaded with different values. One frequency represents the

space frequency, and the other represents the mark frequency. The

digital data stream is fed to the FSELECT pin, causing the AD9838

to modulate the carrier frequency between the two values.

Good decoupling is important. The analog and digital supplies

to the AD9838 are independent and separately pinned out to

minimize coupling between the analog and digital sections of the

device. All analog and digital supplies should be decoupled to

AGND and DGND, respectively, with 0.1 μF ceramic capacitors

in parallel with 10 μF tantalum capacitors. To achieve the best

performance from the decoupling capacitors, they should be

placed as close as possible to the device, ideally right up against

the device.

The AD9838 has two phase registers, enabling the part to per-

form phase shift keying (PSK). With PSK, the carrier frequency

is phase shifted, that is, the phase is altered by an amount that

is related to the bit stream input to the modulator.

In systems where a common supply is used to drive both the

AVDD and DVDD pins of the AD9838, it is recommended that

the system’s AVDD supply be used. This supply should have the

recommended analog supply decoupling between the AVDD

pin of the AD9838 and AGND, as well as the recommended

digital supply decoupling capacitors between the DVDD pin

and DGND.

The AD9838 is also suitable for signal generator applications.

Using the on-board comparator, the device can be used to gen-

erate a square wave.

With its low current consumption, the part is also suitable for

applications in which it can be used as a local oscillator.

GROUNDING AND LAYOUT

Proper operation of the comparator requires good layout strategy.

The layout must minimize the parasitic capacitance between V_IN

and the SIGN BIT OUT pin by using a ground plane to add

isolation. For example, in a multilayered board, the V_INsignal

can be connected to the top layer, and the SIGN BIT OUT pin

can be connected to the bottom layer. In this way, isolation is

provided by the power and ground planes between V_INand the

SIGN BIT OUT pin.

The printed circuit board that houses the AD9838 should be

designed so that the analog and digital sections are separated

and confined to certain areas of the board. This facilitates the use

of ground planes that can be separated easily. A minimum etch

technique is generally best for ground planes because it provides

the best shielding. Digital and analog ground planes should be

joined in one place only. If the AD9838 is the only device that

requires an AGND to DGND connection, the ground planes

should be connected at the AGND and DGND pins of the

AD9838. If the AD9838 is in a system where multiple devices

require AGND to DGND connections, the connection should

be made at one point only, a star ground point that should be

established as close as possible to the AD9838.

INTERFACING TO MICROPROCESSORS

The AD9838 has a standard serial interface that allows the part to

interface directly with several microprocessors. The device uses

an external serial clock to write the data or control information

into the device. The serial clock can have a frequency of 40 MHz

maximum. The serial clock can be continuous, or it can idle high

or low between write operations. When data or control informa-

tion is written to the AD9838, FSYNC is taken low and is held

low until the 16 bits of data are written into the AD9838. The

FSYNC signal frames the 16 bits of information that are loaded

into the AD9838.

Avoid running digital lines under the device; these lines couple

noise onto the die. The analog ground plane should be allowed

to run under the AD9838 to avoid noise coupling. The power

supply lines to the AD9838 should use as large a track as possible

to provide low impedance paths and reduce the effects of glitches

on the power supply line. Fast switching signals, such as clocks,

should be shielded with digital ground to avoid radiating noise

to other sections of the board.

Rev. A | Page 24 of 32

AD9838

AD9838 to 68HC11/68L11 Interface

The 80C51/80L51 outputs the serial data in a format that has the

LSB first. The AD9838 accepts the MSB first (the four MSBs are

the control information, the next four bits are the address, and

the eight LSBs contain the data when writing to a destination

register). Therefore, the transmit routine of the 80C51/80L51

must take this into account and rearrange the bits so that the

MSB is output first.

Figure 28 shows the serial interface between the AD9838 and

the 68HC11/68L11 microcontroller. The microcontroller is con-

figured as the master by setting the MSTR bit in the SPCR to 1.

This setting provides a serial clock on SCK; the MOSI output

drives the serial data line, SDATA. Because the microcontroller

does not have a dedicated frame sync pin, the FSYNC signal is

derived from a port line (PC7). The setup conditions for correct

operation of the interface are as follows:

80C51/80L51

AD9838

•

SCK idles high between write operations (CPOL = 0)

Data is valid on the SCK falling edge (CPHA = 1)

FSYNC

SDATA

P3.3

RXD

TXD

When data is to be transmitted to the AD9838, the FSYNC line

(PC7) is taken low. Serial data from the 68HC11/68L11 is trans-

mitted in 8-bit bytes with only eight falling clock edges occurring

in the transmit cycle. Data is transmitted MSB first. To load data

into the AD9838, PC7 is held low after the first eight bits are

transferred, and a second serial write operation is performed to

the AD9838. Only after the second eight bits are transferred

should FSYNC be taken high again.

SCLK

Figure 29. 80C51/80L51 to AD9838 Interface

AD9838 to DSP56002 Interface

Figure 30 shows the interface between the AD9838 and the

DSP56002. The DSP56002 is configured for normal mode asyn-

chronous operation with a gated internal clock (SYN = 0, GCK = 1,

SCKD = 1). The frame sync pin is generated internally (SC2 = 1),

the transfers are 16 bits wide (WL1 = 1, WL0 = 0), and the frame

sync signal frames the 16 bits (FSL = 0). The frame sync signal is

available on the SC2 pin, but it must be inverted before it is applied

to the AD9838. The interface to the DSP56000/DSP56001 is

similar to that of the DSP56002.

68HC11/68L11

AD9838

PC7

MOSI

SCK

FSYNC

SDATA

SCLK

DSP56002

AD9838

Figure 28. 68HC11/68L11 to AD9838 Interface

AD9838 to 80C51/80L51 Interface

FSYNC

SDATA

SC2

STD

SCK

Figure 29 shows the serial interface between the AD9838 and

the 80C51/80L51 microcontroller. The microcontroller is oper-

ated in Mode 0 so that TxD of the 80C51/80L51 drives SCLK of

the AD9838, and RxD drives the serial data line, SDATA. The

FSYNC signal is derived from a bit programmable pin on the

port (P3.3 is shown in Figure 29).

SCLK

Figure 30. DSP56002 to AD9838 Interface

When data is to be transmitted to the AD9838, P3.3 is taken low.

The 80C51/80L51 transmits data in 8-bit bytes with only eight

falling SCLK edges occurring in each cycle. To load the remain-

ing eight bits to the AD9838, P3.3 is held low after the first eight

bits are transmitted, and a second write operation is initiated to

transmit the second byte of data. P3.3 is taken high following

the completion of the second write operation. SCLK should idle

high between the two write operations.

Rev. A | Page 25 of 32

AD9838

EVALUATION BOARD

The AD9838 evaluation board allows designers to evaluate the

high performance AD9838 DDS modulator with a minimum

of effort.

SYSTEM DEMONSTRATION PLATFORM

The system demonstration platform (SDP) is a hardware and

software evaluation tool for use in conjunction with product

evaluation boards. The SDP board is based on the Blackfin®

ADSP-BF527 processor with USB connectivity to the PC

through a USB 2.0 high speed port. For more information,

see the SDP board product page.

Note that the SDP board is sold separately from the AD9838

evaluation board.

AD9838 TO SPORT INTERFACE

The Analog Devices SDP board has a SPORT serial port that is

used to control the serial inputs to the AD9838. The connections

are shown in Figure 31.

Figure 32. AD9838 Evaluation Software Interface

CRYSTAL OSCILLATOR VS. EXTERNAL CLOCK

ADSP-BF527

AD9838

The AD9838 can operate with master clocks up to 16 MHz.

A 16 MHz oscillator is included on the evaluation board. This

oscillator can be removed and, if required, an external CMOS

clock can be connected to the part. Options for the general

oscillator include the following:

FSYNC

SCLK

SPORT_TFS

SPORT_TSCLK

SPORT_DT0

SDATA

•

AEL 301-Series oscillators, AEL Crystals

SG-310SCN oscillators, Epson Electronics

Figure 31. SDP to AD9838 Interface

POWER SUPPLY

EVALUATION KIT

Power to the AD9838 evaluation board can be provided from

the USB connector or externally through pin connections. The

power leads should be twisted to reduce ground loops.

The DDS evaluation kit includes a populated, tested AD9838

printed circuit board (PCB). The schematics of the evaluation

board are shown in Figure 33 and Figure 34.

The software provided in the evaluation kit allows the user to

easily program the AD9838 (see Figure 32). The evaluation soft-

ware runs on any IBM-compatible PC with Microsoft® Windows®

software installed (including Windows 7). The software is com-

patible with both 32-bit and 64-bit operating systems.

More information about the evaluation software is available on

the software CD and on the AD9838 product page.

Rev. A | Page 26 of 32

AD9838

EVALUATION BOARD SCHEMATICS

2

0 4 7 - 0 7 0 9

Figure 33. Evaluation Board Schematic

Rev. A | Page 27 of 32

AD9838

3 4 0 7 - 0 7 0 9

Figure 34. SDP Connector Schematic

Rev. A | Page 28 of 32

AD9838

EVALUATION BOARD LAYOUT

Figure 35. Evaluation Board Layout

Rev. A | Page 29 of 32

AD9838

OUTLINE DIMENSIONS

4.10

4.00 SQ

3.90

0.30

0.25

0.20

PIN 1

INDICATOR

PIN 1

INDICATOR

16

15

20

0.50

BSC

1

EXPOSED

PAD

2.65

2.50 SQ

2.35

5

11

6

10

0.50

0.40

0.30

0.25 MIN

TOP VIEW

BOTTOM VIEW

FOR PROPER CONNECTION OF

THE EXPOSED PAD, REFER TO

THE PIN CONFIGURATION AND

FUNCTION DESCRIPTIONS

0.80

0.75

0.70

0.05 MAX

0.02 NOM

COPLANARITY

0.08

SECTION OF THIS DATA SHEET.

SEATING

PLANE

0.20 REF

COMPLIANT TO JEDEC STANDARDS MO-220-WGGD.

Figure 36. 20-Lead Lead Frame Chip Scale Package [LFCSP_WQ]

4 mm × 4 mm Body, Very Very Thin Quad

(CP-20-10)

Dimensions shown in millimeters

ORDERING GUIDE

Model^{1, 2}

Temperature Range

−40°C to +125°C

Max MCLK

16 MHz

5 MHz

Package Description

Package Option

CP-20-10

AD9838BCPZ-RL

AD9838BCPZ-RL7

AD9838ACPZ-RL

AD9838ACPZ-RL7

EVAL-AD9838SDZ

20-Lead Lead Frame Chip Scale Package [LFCSP_WQ]

Evaluation Board

5 MHz

¹Z = RoHS Compliant Part.

²The evaluation board for the AD9838 requires the system demonstration platform (SDP) board, which is sold separately.

Rev. A | Page 30 of 32

AD9838

NOTES

Rev. A | Page 31 of 32

AD9838

NOTES

registered trademarks are the property of their respective owners.

D09077-0-4/11(A)

Rev. A | Page 32 of 32


型号：	AD9838ACPZ-RL7
厂家：	ADI
描述：	11 mW Power, 2.3 V to 5.5 V, Complete DDS Power-down option 11毫瓦功率， 2.3 V至5.5 V ，完整DDS省电选项模拟IC 信号电路数据分配系统 PC
文件：	总32页 (文件大小：604K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

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