ad73311 Analog Devices, Inc., ad73311 Datasheet - Page 30

ad73311

Manufacturer Part Number

ad73311

Description

Low Cost, Low Power Cmos General Purpose Analog Front End

Manufacturer

Analog Devices, Inc.

Datasheet

1.AD73311.pdf (36 pages)

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AD73311

APPENDIX C

Configuring a Cascade of Two AD73311s to Operate in

Data Mode

This section describes a typical sequence of control words that

would be sent to a cascade of two AD73311s to set them up for

operation. It is not intended to be a definitive initialization

sequence, but will show users the typical input/output events

that occur in the programming and operation phases

description panel refers to Figure 35.

In Step 1, we have the first output sample event following device

reset. The SDOFS signal is raised on both devices simulta-

neously, which prepares the DSP Rx register to accept the ADC

word from Device 2, while SDOFS from Device 1 becomes an

SDIFS to Device 2. As the SDOFS of Device 2 is coupled to

the DSP’s TFS and RFS, and to the SDIFS of Device 1, this

event also forces a new control word to be output from the DSP

Tx register to Device 1.

In Step 2, we observe the status of the devices following the

transmission of the first control word. The DSP has received the

ADC word from Device 2, while Device 2 has received the

ADC word from Device 1 and Device 1 has received the Con-

trol word destined for Device 2. At this stage, the SDOFS of

both devices are again raised because Device 2 has received

Device 1’s ADC word, and as it is not a valid control word

addressed to Device 2, it is passed on to the DSP. Likewise,

Device 1 has received a control word destined for Device 2—

address field is not zero—and it decrements the address field of

the control word and passes it on.

Step 3 shows completion of the first series of control word

writes. The DSP has now received both invalid ADC words and

each device has received a control word that addresses control

rate to DMCLK/8. Note that both devices are updated simulta-

neously as both receive the addressed control word at the same

time. This is an important factor in cascaded operation as any

latency between updating the SCLK or DMCLK of devices can

result in corrupted operation. This will not happen in the case

of a FSLB configuration as shown here, but must be taken into

account in a non-FSLB configuration. One other important

observation of this sequence is that the data words are received

and transmitted in reverse order, i.e., the ADC words are

received by the DSP, Device 2 first, then Device 1, and similarly

the transmit words from the DSP are sent Device 2 first, then

Device 1. This ensures that all devices are updated at the same

time.

In Step 4, the next ADC sample event that happens raises the

SDOFS lines of each of the devices. The DSP Tx register con-

tains the first of the two control words to be written to the cas-

cade—the word for Device 2.

. This

In Step 5, following transmission of the first of the two control

words, the DSP Rx register contains Device 2’s ADC word,

Device 2’s serial register contains the Device 1 ADC word,

Device 1’s serial register contains the control word addressed to

Device 2 and the DSP Tx register contains the next control

word—that addressed to Device 1. Again, both devices raise

their SDOFS lines as both have received control words not

addressed to them.

Step 6 shows the completion of the second set of control word

writes. In this case, both devices have received a control word

addressed to control register A, which sets the device count field

equal to two devices in cascade and sets the PGM/DATA bit to

one to put the device in data mode.

In Step 7, the programming phase is complete and we now

begin actual device data read and write. The words loaded into

the serial registers of the two devices at the ADC sampling event

now contain valid ADC data and the words written to the de-

vices from the DSP’s Tx register will now be interpreted as

DAC words. Note, therefore, that the DSP Tx register contains

the DAC word for Device 2.

In Step 8, the first DAC word has been transmitted into the

cascade and the ADC word from Device 2 has been read from

the cascade. The DSP Tx register now contains the DAC word

for Device 1. As the words being sent to the cascade are now

being interpreted as 16-bit DAC words, the addressing scheme

now changes from one where the address was embedded in the

transmitted word to one where the serial port now counts the

SDIFS pulses. When the number of SDIFS pulses received

equals the value in the device count field of control register A—

the length of the cascade—each device updates its DAC register

with the present word in its serial register. In Step 8 each device

has received only one SDIFS pulse; Device 2 received one

SDIFS from the SDOFS of Device 1 when it sent its ADC word

and Device 1 received one SDIFS pulse when it received the

DAC word for Device 2 from the DSP’s Tx register. Therefore,

each device raises its SDOFS line to pass on the current word in

its serial register, and each device now receives another SDIFS

pulse.

Step 9 shows the completion of an ADC read and DAC write

cycle. Following Step 8, each device has received two SDIFS

pulses that equal the setting of the device count field in Control

with the contents of the word that accompanied the SDIFS

pulse which satisfied the device count requirement. The internal

frame sync counter is now reset to zero and will begin counting

for the next DAC update cycle.

NOTE

This sequence assumes that the DSP SPORT’s Rx and Tx interrupts are enabled.

It is important to ensure that there is no latency (separation) between control

words in a cascade configuration. This is especially the case when programming

Control Register B as it contains settings for SCLK and DMCLK rates.

ad73311 Analog Devices, Inc., ad73311 Datasheet - Page 30

ad73311

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