AD9851BRS Analog Devices Inc, AD9851BRS Datasheet - Page 12

Direct Digital Synthesizer 180MHz 1-DAC 10-Bit Parallel/Serial 28-Pin SSOP

AD9851BRS

Manufacturer Part Number

AD9851BRS

Description

Direct Digital Synthesizer 180MHz 1-DAC 10-Bit Parallel/Serial 28-Pin SSOP

Manufacturer

Analog Devices Inc

Datasheet

1.AD9851BRSZ.pdf (24 pages)

Specifications of AD9851BRS

Resolution

10 Bit

Maximum Input Frequency

180 MHz

Tuning Word Width

32 Bit

Minimum Operating Supply Voltage

2.7 V

Typical Operating Supply Voltage

5 V

Maximum Operating Supply Voltage

5.25 V

Minimum Operating Temperature

-40 Â°C

Maximum Operating Temperature

85 Â°C

Rohs Status

RoHS non-compliant

Resolution (bits)

10 b

Master Fclk

180MHz

Tuning Word Width (bits)

32 b

Voltage - Supply

2.7 V ~ 5.25 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

28-SSOP

For Use With

AD9951/PCBZ - BOARD EVALUATION FOR AD9851

Lead Free Status / RoHS Status

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THEORY OF OPERATION AND APPLICATION

The AD9851 uses direct digital synthesis (DDS) technology,

in the form of a numerically controlled oscillator (NCO), to

generate a frequency/phase-agile sine wave. The digital sine

wave is converted to analog form via an internal 10-bit high

speed D/A converter. An on-board high speed comparator

is provided to translate the analog sine wave into a low-jitter

TTL/CMOS-compatible output square wave. DDS technol-

ogy is an innovative circuit architecture that allows fast and

precise manipulation of its output word, under full digital con-

trol. DDS also enables very high resolution in the incremental

selection of output frequency. The AD9851 allows an output

frequency resolution of approximately 0.04 Hz at an 180 MSPS

clock rate with the option of directly using the reference clock or

by engaging the 6 REFCLK multiplier. The AD9851’s out-

put waveform is phase-continuous from one output frequency

change to another.

The basic functional block diagram and signal flow of the

AD9851 configured as a clock generator is shown in Figure 11.

The DDS circuitry is basically a digital frequency divider function

whose incremental resolution is determined by the frequency of

the system clock, and N (number of bits in the tuning word). The

phase accumulator is a variable-modulus counter that increments

the number stored in it each time it receives a clock pulse. When

the counter reaches full-scale it wraps around, making the phase

accumulator’s output phase-continuous. The frequency tuning

word sets the modulus of the counter, which effectively determines

the size of the increment ( Phase) that will be added to the value

in the phase accumulator on the next clock pulse. The larger

the added increment, the faster the accumulator wraps around,

which results in a higher output frequency.

The AD9851 uses an innovative and proprietary angle rotation

algorithm that mathematically converts the 14-bit truncated

AD9851

TUNING WORD SPECIFIES

OUTPUT FREQUENCY AS A

FRACTION OF REF CLOCK

FREQUENCY

(DC)

0Hz

ACCUMULATOR

Figure 11. Basic DDS Block Diagram and Signal Flow of AD9851

REFERENCE

20MHz

OUT

CLOCK

PHASE

Figure 12. Output Spectrum of a Sampled Sin(x)/x Signal

SYSTEM CLOCK FREQUENCY

1ST IMAGE

DDS CIRCUITRY

80MHz

SIN (X)/ ENVELOPE

 = ()F/F

–F

CONV ALGORITHM

AMPLITUDE/SINE

100MHz

IN DIGITAL

DOMAIN

2ND IMAGE

120MHz

–12–

3RD IMAGE

180MHz

CONVERTER

value of the 32-bit phase accumulator to the 10-bit quantized

amplitude that is passed to the DAC. This unique algorithm uses a

much-reduced ROM look-up table and DSP to perform this func-

tion.This contributes to the small size and low power dissipation of

the AD9851.

The relationship between the output frequency, system clock, and

tuning word of the AD9851 is determined by the expression:

where

Phase = decimal value of 32-bit frequency tuning word.

System Clock = direct input reference clock (in MHz) or 6 the

input clock (in MHz) if the 6 REFCLK multiplier is engaged.

The digital sine wave output of the DDS core drives the internal

high speed 10-bit D/A converter that will construct the sine wave

in analog form. This DAC has been optimized for dynamic per-

formance and low glitch energy, which results in the low spurious

and jitter performance of the AD9851. The DAC can be operated

in either the single-ended (Figures 2 and 8) or differential output

configuration (Figures 9 and 10). DAC output current and R

values are determined using the following expressions:

Since the output of the AD9851 is a sampled signal, its output

spectrum follows the Nyquist sampling theorem. Specifically,

its output spectrum contains the fundamental plus aliased sig-

nals (images) that occur at integer multiples of the system clock

frequency ± the selected output frequency. A graphical repre-

sentation of the sampled spectrum, with aliased images, is shown

in Figure 12. Normal usable bandwidth is considered to extend

from dc to 1/2 the system clock.

OUT

–F

D/A

= frequency of the output signal in MHz.

4TH IMAGE

220MHz

OUT

= (

= (

= ( Phase  System Clock)/2

COMPARATOR

5TH IMAGE



280MHz

OUT

SET

–F

= 39.93/

CLOCK

OUT

SET

REV. D

SET

AD9851BRS Analog Devices Inc, AD9851BRS Datasheet - Page 12

AD9851BRS

Specifications of AD9851BRS

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