AD9726 Analog Devices, AD9726 Datasheet - Page 17

AD9726

Manufacturer Part Number

AD9726

Description

Manufacturer

Analog Devices

Datasheet

1.AD9726.pdf (24 pages)

Specifications of AD9726

Resolution (bits)

16bit

Dac Update Rate

400MSPS

Dac Settling Time

n/a

Max Pos Supply (v)

+3.47V

Single-supply

Dac Type

Current Out

Dac Input Format

LVDS,Par

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

AD9726BSVZ

Manufacturer:

Epson

Quantity:

1 271

Company:

BOSTOCK HK LIMITED

Part Number:

AD9726BSVZ

Manufacturer:

Analog Devices Inc

Quantity:

10 000

Company:

BOSTOCK HK LIMITED

Part Number:

AD9726BSVZRL

Manufacturer:

Analog Devices Inc

Quantity:

10 000

Current page: 17 of 24
Download datasheet (406Kb)

THEORY OF OPERATION

The AD9726 uses LVDS for input data to enable high sample

rates and high performance. LVDS technology uses differential

signals for noise rejection and small signal amplitude for fast

speed with lower power. Each LVDS input on the AD9726 has

an internal 100 Ω active load for proper termination.

DAC CLOCK AND DATA CLOCK OUTPUT

The AD9726 uses two clock inputs and offers one clock output.

All are differential signals.

The AD9726 is driven by a master input clock that initiates con-

version and controls all on-chip activity. This signal is referred

to as the DAC clock. It is not LVDS, and the CLK+ and CLK–

pins are high impedance inputs.

The DAC clock is then used to generate the data clock output.

The DCLK_OUT+ and DCLK_OUT– pins form an LVDS

signal that can be used to drive an external FPGA or another

data pump. In SDR mode, the data clock output always runs at

the same frequency as the DAC clock. In DDR mode, the data

clock output always runs at ½ the DAC clock frequency.

Use of the data clock output is optional. It is meant to serve as

a convenient means of regulating the incoming data stream.

The driver can be loaded by a 100 Ω differential termination.

An external 1 kΩ resistor from the REXT pin to DBGND is also

required to set the drive strength. If unused, the data clock

output pins can be left unconnected, and the 1 kΩ resistor at

REXT can be omitted.

The data clock output can also be inverted by asserting the

INVDCLKO bit in SPI Register 0x02, or the driver can be

disabled by asserting the DISDCLKO bit in the same register.

DATA CLOCK INPUT

The remaining clock signal associated with the AD9726 is the

data clock input. This LVDS signal is not optional and must

accompany the 16-bit data bus. The data clock input is used to

latch incoming data into the synchronization (sync) logic.

The data clock input always runs at the same frequency as the

data clock output in both SDR and DDR modes. A logical

inversion can be accomplished by asserting the INVDCLKI bit.

Driving the DAC Clock Inputs

The DAC clock must be precise and spectrally pure to ensure

the highest ac performance. A symmetrical 50% duty cycle

should be maintained at all times.

The CLK+ and CLK– input pins should be driven by a signal

with a common-mode voltage near ½ of CLKVDD. From this

point, peak-to-peak signal amplitude should swing over a range

of at least several hundred millivolts.

Rev. B | Page 17 of 24

The circuit option shown in Figure 19 uses a receiver/driver IC

from the 2.5 V LVPECL logic family to provide complementary

outputs that fall within these guidelines. A transformer helps

ensure a 50% duty cycle and provides a single-ended to differ-

ential conversion at the input.

The LVPECL device can be conveniently powered from the

same power supply as CLKVDD. The center tap of the trans-

former secondary must be held at 1 V, the switching threshold

of the receiver/driver inputs (use a resistive divider to generate

this voltage or use the internal VBB source with a buffer

amplifier). Based on a 1:1 impedance ratio, 25 Ω resistors across

the secondary provide a matched load to a 50 Ω source.

The driver outputs are terminated as close as possible to the

AD9726 with 50 Ω to VCC − 2 V (or use a Thevenin equivalent

circuit). Controlled impedance PCB traces should be used to

minimize reflections. Signal levels at the CLK+ and CLK– pins

transition between a high near 1500 mV to a low near 750 mV.

An alternative circuit option for driving the DAC clock inputs

employs a transmission line transformer (balun) to accomplish

the single-ended to differential conversion. This all-passive

circuit is considerably simpler and less costly, and it provides

acceptable performance over a limited range of frequencies.

In this implementation, a sine wave (or other single-ended

source) is coupled directly to the differential DAC clock inputs

through a 50 Ω transformer. Capacitors are used for isolation,

and each DAC clock pin must be dc-biased to a level of 1.25 V

(a pair of simple resistive dividers can be used).

1:1

VBB = 1.0V

1:1

Figure 20. Passive DAC Clock Drive Circuit

Figure 19. Active DAC Clock Drive Circuit

25Ω

0.1μF

MC100LVEP16

VDC BIAS = 1.25V

VCC = CLKVDD = 2.5V

50Ω

VCC – 2V

50Ω

AD9726

CLK+

CLK–

CLK+

CLK–

AD9726

AD9726 Analog Devices, AD9726 Datasheet - Page 17

AD9726

Specifications of AD9726

Available stocks

Related parts for AD9726