AD9125-M5372-EBZ Analog Devices Inc, AD9125-M5372-EBZ Datasheet - Page 47

AD9125-M5372-EBZ

Manufacturer Part Number

AD9125-M5372-EBZ

Description

16-BIT DAC Evaluation Board

Manufacturer

Analog Devices Inc

Datasheets

1.ADL5372ACPZ-R7.pdf (24 pages)

2.AD9125-M5372-EBZ.pdf (56 pages)

Specifications of AD9125-M5372-EBZ

Silicon Manufacturer

Analog Devices

Application Sub Type

DAC

Kit Application Type

Data Converter

Silicon Core Number

AD9125

Features

Come With Clocking And Analog Quadrature Modulator Circuits

Kit Contents

Quick Start Guide, Board, Software Updates

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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MULTICHIP SYNCHRONIZATION

System demands may require that the outputs of multiple DACs

be synchronized with each other or with a system clock. Systems

that support transmit diversity or beam forming, where multiple

antennas are used to transmit a correlated signal, require multiple

DAC outputs to be phase aligned with each other. Systems with

a time division multiplexing transmit chain may require one or

more DACs to be synchronized with a system-level reference clock.

Multiple devices are considered synchronized to each other when

the state of the clock generation state machine is identical for all

parts and when time aligned data is being read from the FIFOs

of all parts simultaneously. Devices are considered synchronized

to a system clock when there is a constant, known relationship

among the clock generation state machine, the data being read

from the FIFO, and a particular clock edge of the system clock.

The AD9125 has provisions for enabling multiple devices to be

synchronized to each other or to a system clock.

The AD9125 supports synchronization in two modes: data rate

mode and FIFO rate mode. Each of these modes has a different

lowest rate clock that the synchronization logic attempts to syn-

chronize to. In data rate mode, the input data rate represents the

lowest synchronized clock. In FIFO rate mode, the FIFO rate,

which is the data rate divided by the FIFO depth of 8, represents

the lowest rate clock. The advantage of FIFO rate synchronization

is increased time between keep-out windows for DCI changes

relative to the DACCLK or REFCLK input.

When in data rate mode, the elasticity of the FIFO is not used to

absorb timing variations between the data source and the DAC,

resulting in keep-out widows repeating at the input data rate.

The method chosen for providing the DAC sampling clock directly

impacts the synchronization methods available. When the device

clock multiplier is used, only data rate mode is available. When

the DAC sampling clock is sourced directly, both data rate mode

and FIFO rate mode synchronization are available. This section

details the synchronization methods for enabling both clocking

modes and for querying the status of the synchronization logic.

SYNCHRONIZATION WITH CLOCK MULTIPLICATION

When using the clock multiplier to generate the DAC sample

rate clock, the REFCLK input signal acts both as the reference

clock for the PLL-based clock multiplier and as the synchronization

signal. To synchronize devices, distribute the REFCLK signal

with low skew to all of the devices that need to be synchronized.

Skew between the REFCLK signals of the devices shows up

directly as a timing mismatch at the DAC outputs.

The frequency of the REFCLK signal is typically equal to the

input data rate. The FRAME and DCI signals, along with the

data, can be created in the FPGA. A circuit diagram of a typical

configuration is shown in Figure 81.

Rev. 0 | Page 47 of 56

The Procedure for Synchronization when Using the PLL section

outlines the steps required to synchronize multiple devices. The

procedure assumes that the REFCLK signal is applied to all devices

and that the PLL of each device is phase locked to this signal. This

procedure must be carried out on each individual device.

Procedure for Synchronization when Using the PLL

To synchronize all devices,

To maintain synchronization, the skew between the REFCLK

signals of the devices must be less than t

and hold times to be observed among the DCI, the data of each

device, and the REFCLK signal. When resetting the FIFO, the

FRAME signal must be held high for the time interval required

to write two complete input data-words. A timing diagram of

the input signals is shown in Figure 82.

This example shows a REFCLK frequency equal to the data rate.

Although this is the most common situation, it is not strictly

required for proper synchronization. Any REFCLK frequency

that satisfies the following equation is acceptable:

where N = 0, 1, 2, or 3.

As an example, a configuration with 4× interpolation and clock

frequencies of f

200 MHz, and f

SYSTEM

CLOCK

FPGA

Configure the device for data rate mode and periodic

synchronization by writing 0xC0 to the Sync Control 1

options are available.

Read the Sync Status 1 register (Register 0x12) and verify that

the sync locked bit (Bit 6) is set high, indicating that the

device achieved back-end synchronization and that the

sync lost bit (Bit 7) is low. These levels indicate that the clocks

are running with a constant, known phase relative to the

sync signal.

Reset the FIFO by strobing the FRAME signal high for the

time required to write two complete input data-words.

Resetting the FIFO ensures that the correct data is being

read from the FIFO.

SYNC_I

Figure 81. Typical Circuit Diagram for Synchronizing Devices

CLOCK DRIVER

= f

LOW SKEW

DACCLK

VCO

SYNC_I

= 1600 MHz, f

= 100 MHz is a viable solution.

MATCHED

LENGTH TRACES

and f

SYNC_I

≤ f

DACCLK

DATA

REFCLKP/

REFCLKN

FRAME

DCI

REFCLKP/

REFCLKN

FRAME

DCI

SKEW

= 800 MHz, f

. There are also setup

AD9125

DATA

IOUT1P/

IOUT1N

IOUT2P/

IOUT2N

AD9125-M5372-EBZ Analog Devices Inc, AD9125-M5372-EBZ Datasheet - Page 47

AD9125-M5372-EBZ

Specifications of AD9125-M5372-EBZ

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