ADS7812 Datasheet, PDF(16/17 Page) Burr-Brown (TI) – Low-Power, Serial 12-Bit Sampling ANALOG-TO-DIGITAL CONVERTER

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ADS7812 Datasheet, PDF (16/17 Pages) Burr-Brown (TI) – Low-Power, Serial 12-Bit Sampling ANALOG-TO-DIGITAL CONVERTER

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Keep in mind that the time period when the comparator is

most sensitive to noise is fairly small. Also, the peak portion

of the noise âeventâ produced by a digital transition is fairly

brief as most digital signals transition in a few nanoseconds.

The subsequent noise may last for a period of time longer

than this and may induce further effects which require a

longer settling time; however, in general, the event is over

within a few tens of nanoseconds.

For the ADS7812, error correction is done when the tenth bit

is decided. During this bit decision, it is possible to correct

limited errors that may have occurred during previous bit

decisions. However, after the tenth bit, no such correction is

possible. Note that for the timing diagrams shown in Figures

2, 5, 6, 7, and 8, all external digital signals should remain

static from 8Âµs after the start of a conversion until BUSY

rises. The tenth bit is decided approximately 10Âµs to 11Âµs

into the conversion.

APPLICATIONS INFORMATION

QSPI INTERFACING

Figure 14 shows a simple interface between the ADS7812

and any queued serial peripheral interface (QSPI) equipped

microcontroller (available on several Motorola devices).

This interface assumes that the convert pulse does not

originate from the microcontroller and that the ADS7812 is

the only serial peripheral.

Before enabling the QSPI interface, the microcontroller must

be configured to monitor the slave select (SS) line. When a

LOW to HIGH transition occurs (indicating the end of a

conversion), the port can be enabled. If this is not done, the

microcontroller and A/D converter may not be properly syn-

chronized. (The slave select line simply enables communica-

tionâit does not indicate the start or end of a serial transfer.)

three converters. After the conversions are finished, each

result is transferred, in turn. The QSPI port is completely

programmable to handle the timing and transfers without

processor intervention. If the CONV signal is generated in

this way, it should be possible to make both AC and DC

measurements with the ADS7812, as the CONV signal will

have low jitter. Note that if the CONV signal is generated via

software commands, it will have a good deal of jitter and

only low frequency (DC) measurements can be made.

QSPI

PCS0

PCS1

PCS2

PCS3

SCK

MIS0

ADS7812

+5V

CONV

EXT/INT

DATACLK

DATA

ADS7812

+5V

CONV EXT/INT

DATACLK

DATA

ADS7812

+5V

CONV EXT/INT

DATACLK

DATA

FIGURE 15. QSPI Interface to the Three ADS7812s.

QSPI

Convert Pulse

ADS7812

DSP56002 INTERFACING

The DSP56002 serial interface has an serial peripheral

interface (SPI) compatibility mode with some enhance-

ments. Figure 16 shows an interface between the ADS7812

and the DSP56002. As with the QSPI interface of Figure 14,

PCS0/SS

CONV

BUSY

Convert Pulse

MOSI

DATA

DSP56002

ADS7812

SCK

DATACLK

CONV

EXT/INT

SC1

BUSY

CPOL = 0 (Inactive State is LOW)

CPHA = 1 (Data valid on falling edge)

QSPI port is in slave mode.

FIGURE 14. QSPI Interface to the ADS7812.

Figure 15 shows a QSPI-equipped microcontroller interfac-

ing to three ADS7812s. There are many possible variations

to this interface scheme. As shown, the QSPI port produces

a common CONV signal which initiates a conversion on all

SRD

DATA

SCO

DATACLK

SYN = 0 (Asychronous)

GCK = 1 (Gated clock)

SCD1 = 0 (SC1 is an input)

SHFD = 0 (Shift MSB first)

WL1 = 0 WL0 = 1 (Word length = 12 bits)

EXT/INT

FIGURE 16. DSP56002 Interface to the ADS7812.

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ADS7812

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