AD9854ASTZ Analog Devices Inc, AD9854ASTZ Datasheet - Page 30

AD9854ASTZ

Manufacturer Part Number

AD9854ASTZ

Description

IC DDS QUADRATURE CMOS 80-LQFP

Manufacturer

Analog Devices Inc

Datasheet

1.AD9854ASTZ.pdf (52 pages)

Specifications of AD9854ASTZ

Package / Case

80-LQFP

Resolution (bits)

12 b

Master Fclk

300MHz

Tuning Word Width (bits)

48 b

Voltage - Supply

3.14 V ~ 3.47 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Supply Voltage Range

3.135V To 3.465V

Operating Temperature Range

-40Â°C To +85Â°C

Digital Ic Case Style

LQFP

No. Of Pins

Svhc

No SVHC (18-Jun-2010)

Base Number

9854

Ic Function

Direct Digital Synthesizer

Rohs Compliant

Yes

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

For Use With

AD9854/PCBZ - BOARD EVAL FOR AD9854

Lead Free Status / RoHS Status

Lead free / RoHS Compliant, Lead free / RoHS Compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

AD9854ASTZ

Manufacturer:

Renesas

Quantity:

103

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

AD9854ASTZ

Manufacturer:

ADI

Quantity:

271

Company:

BOSTOCK HK LIMITED

Part Number:

AD9854ASTZ

Manufacturer:

Analog Devices Inc

Quantity:

10 000

Company:

Meier Automation Equipment Co., Limited

Part Number:

AD9854ASTZ

Manufacturer:

ADI/亚德诺

Quantity:

20 000

Current page: 30 of 52
Download datasheet (2Mb)

AD9854

The two fixed elements of the transition time are the period of

the system clock (which drives the ramp rate counter) and the

number of amplitude steps (4096). For example, if the system

clock of the AD9854 is 100 MHz (10 ns period) and the ramp

rate counter is programmed for a minimum count of 3, the

transition takes two system clock periods (one rising edge loads

the countdown value, and the next edge decrements the counter

from 3 to 2). If the countdown value is less than 3, the ramp rate

counter stalls and therefore produces a constant scaling value to

the digital multipliers. This stall condition may have an application

for the user.

The relationship of the 8-bit countdown value to the time

between output pulses is given as

where N is the 8-bit countdown value.

It takes 4096 of these pulses to advance the 12-bit up-counter

from zero scale to full scale. Therefore, the minimum output

shaped keying ramp time for a 100 MHz system clock is

The maximum ramp time is

Finally, changing the logic state of Pin 30, output shaped keying

automatically performs the programmed output envelope functions

when OSK INT is high. A logic high on Pin 30 causes the outputs

to linearly ramp up to full-scale amplitude and to hold until the

logic level is changed to low, causing the outputs to ramp down

to zero scale.

I AND Q DACS

The sine and cosine outputs of the DDS drive the Q and I DACs,

respectively (300 MSPS maximum). The maximum amplitudes

of these output are set by the DAC R

are current-output DACs with a full-scale maximum output of

20 mA; however, a nominal 10 mA output current provides the

best spurious-free dynamic range (SFDR) performance. The value

(N + 1) × System Clock Period

4096 × 4 × 10 ns ≈ 164 μs

4096 × 256 × 10 ns ≈ 10.5 ms

Figure 50. Block Diagram of Q DAC Pathway of the Digital Multiplier Section Responsible for the Output Shaped Keying Function

DDS DIGITAL

OUTPUT

SET

SIGNAL IN

USER-PROGRAMMABLE

DIGITAL

KEYING Q MULTIPLIER

resistor at Pin 56. These

12-BIT Q CHANNEL

OUTPUT SHAPED

MULTIPLIER

OSK EN = 1

OSK EN = 0

Rev. E | Page 30 of 52

OSK INT = 0

(BYPASS MULTIPLIER)

12-BIT DIGITAL

MULTIPLIER

UP/DOWN

COUNTER

12-BIT

OSK INT = 0

of R

compliance specifications limit the maximum voltage developed

at the outputs to −0.5 V to +1 V. Voltages developed beyond this

limitation cause excessive DAC distortion and possibly permanent

damage. The user must choose a proper load impedance to limit

the output voltage swing to the compliance limits. Both DAC

outputs should be terminated equally for best SFDR, especially

at higher output frequencies, where harmonic distortion errors

are more prominent.

Both DACs are preceded by inverse sin(x)/x filters (also called

inverse sinc filters) that precompensate for DAC output amplitude

variations over frequency to achieve flat amplitude response from

dc to Nyquist. Both DACs can be powered down when not needed

by setting the DAC PD bit high (Address 1D hex of the control

Pin 48 and Pin 49, respectively. Q DAC outputs are designated

as IOUT2 and IOUT2 , Pin 52 and Pin 51, respectively.

CONTROL DAC

The 12-bit Q DAC can be reconfigured to perform as a control

or auxiliary DAC. The control DAC output can provide dc

control levels to external circuitry, generate ac signals, or enable

duty cycle control of the on-board comparator. When the SRC

Q DAC bit in the control register (Parallel Address 1F hex) is

set high, the Q DAC inputs are switched from internal 12-bit

Q data source (default setting) to external 12-bit, twos complement

data supplied by the user. Data is channeled through the serial

or parallel interface to the 12-bit Q DAC register (Address 26 hex

and Address 27 hex) at a maximum data rate of 100 MHz. This

DAC is clocked at the system clock, 300 MSPS (maximum), and

has the same maximum output current capability as that of the I

DAC. The single R

output current for both DACs. When not needed, the control

DAC can be separately powered down to conserve power by

setting the Q DAC power-down bit high (Address 1D hex).

Control DAC outputs are designated as IOUT2 and IOUT2 ,

Pin 52 and Pin 51, respectively.

SET

ON/OFF OUTPUT SHAPED

KEYING PIN

is 39.93/I

OSK EN = 0

OSK EN = 1

8-BIT RAMP

COUNTER

RATE

OUT

SET

, where I

resistor on the AD9854 sets the full-scale

SINE DAC

OUT

SYSTEM

CLOCK

is expressed in amps. DAC output

AD9854ASTZ Analog Devices Inc, AD9854ASTZ Datasheet - Page 30

AD9854ASTZ

Specifications of AD9854ASTZ

Available stocks

Related parts for AD9854ASTZ