Datasheet
AD7192
Rev. A | Page 21 of 40
Table 18. Operating Modes
MD2 MD1 MD0 Mode
0 0 0
Continuous conversion mode (default). In continuous conversion mode, the ADC continuously performs
conversions and places the result in the data register. The DOUT/RDY
pin and the RDY bit in the status register go
low when a conversion is complete. The user can read these conversions by setting the CREAD bit in the commun-
ications register to 1, which enables continuous read. When continuous read is enabled, the conversions are
automatically placed on the DOUT line when SCLK pulses are applied. Alternatively, the user can instruct the ADC to
output each conversion by writing to the communications register. After power-on, a reset, or a reconfiguration of
the ADC, the complete settling time of the filter is required to generate the first valid conversion. Subsequent
conversions are available at the selected output data rate, which is dependent on filter choice.
0 0 1
Single conversion mode. When single conversion mode is selected, the ADC powers up and performs a single
conversion on the selected channel. The internal clock requires up to 1 ms to power up and settle. The ADC then
performs the conversion, which requires the complete settling time of the filter. The conversion result is placed in
the data register. RDY
goes low, and the ADC returns to power-down mode. The conversion remains in the data
register until another conversion is performed. RDY
remains active (low) until the data is read or another conversion
is performed.
0 1 0
Idle mode. In idle mode, the ADC filter and modulator are held in a reset state even though the modulator clocks are
still provided.
0 1 1
Power-down mode. In power-down mode, all AD7192 circuitry, except the bridge power-down switch, is powered
down. The bridge power-down switch remains active because the user may need to power up the sensor prior to
powering up the AD7192 for settling reasons. The external crystal, if selected, remains active.
1 0 0
Internal zero-scale calibration. An internal short is automatically connected to the input. RDY
goes high when the
calibration is initiated and returns low when the calibration is complete. The ADC is placed in idle mode following a
calibration. The measured offset coefficient is placed in the offset register of the selected channel.
1 0 1 Internal full-scale calibration. A full-scale input voltage is automatically connected to the input for this calibration.
RDY
goes high when the calibration is initiated and returns low when the calibration is complete. The ADC is placed
in idle mode following a calibration. The measured full-scale coefficient is placed in the full-scale register of the
selected channel. A full-scale calibration is required each time the gain of a channel is changed to minimize the full-
scale error. When AV
DD
is less than 4.75 V, the CLK_DIV bit must be set when performing the internal full-scale
calibration.
1 1 0
System zero-scale calibration. The user should connect the system zero-scale input to the channel input pins as
selected by the CH7 to CH0 bits in the configuration register. RDY goes high when the calibration is initiated and
returns low when the calibration is complete. The ADC is placed in idle mode following a calibration. The measured
offset coefficient is placed in the offset register of the selected channel. A system zero-scale calibration is required
each time the gain of a channel is changed.
1 1 1
System full-scale calibration. The user should connect the system full-scale input to the channel input pins as
selected by the CH7 to CH0 bits in the configuration register. RDY
goes high when the calibration is initiated and
returns low when the calibration is complete. The ADC is placed in idle mode following a calibration. The measured
full-scale coefficient is placed in the full-scale register of the selected channel. A full-scale calibration is required
each time the gain of a channel is changed.
CONFIGURATION REGISTER
(RS2, RS1, RS0 = 0, 1, 0; Power-On/Reset = 0x000117)
The configuration register is a 24-bit register from which data can be read or to which data can be written. This register is used to
configure the ADC for unipolar or bipolar mode, to enable or disable the buffer, to enable or disable the burnout currents, to select the
gain, and to select the analog input channel.
Tabl e 1 9 outlines the bit designations for the filter register. CON0 through CON23 indicate the bit locations. CON denotes that the bits
are in the configuration register. CON23 denotes the first bit of the data stream. The number in parentheses indicates the power-on/reset
default status of that bit.
CON23 CON22 CON21 CON20 CON19 CON18 CON17 CON16
CHOP(0) 0(0) 0(0) REFSEL(0) 0(0) 0(0) 0(0) (0)
CON15 CON14 CON13 CON12 CON11 CON10 CON9 CON8
CH7(0) CH6(0) CH5(0) CH4(0) CH3(0) CH2(0) CH1(0) CH0(1)
CON7 CON6 CON5 CON4 CON3 CON2 CON1 CON0
BURN(0) REFDET(0) 0(0) BUF(1)
U/B
(0)
G2(1) G1(1) G0(1)