20.8kHz with a –3dB frequency of 4.24kHz. The –3dB
frequency scales with the system clock frequency.
THEORY OF OPERATION
The ADS1254 is a precision, high-dynamic range, 24-bit,
delta-sigma, A/D converter capable of achieving very
high-resolution digital results at high data rates.
The analog-input signal is sampled at a rate determined by the
frequency of the system clock (CLK). The sampled analog
input is modulated by the delta-sigma A/D modulator, which
is followed by a digital filter. A sinc5 digital low-pass filter
processes the output of the delta-sigma modulator and writes
the result into the data-output register. The DOUT/DRDY pin
is pulled LOW, indicating that new data is available to be read
by the external microcontroller/microprocessor. As shown in
the block diagram, the main functional blocks of the ADS1254
are the fourth-order delta-sigma modulator, a digital filter,
control logic, and a serial interface. Each of these functional
blocks is described below.
To ensure the best linearity of the ADS1254, a fully differen-
tial signal is recommended.
INPUT MULTIPLEXER
The CHSEL1 and CHSEL0 pins are used to select the analog
input channel, as shown in Table I. The recommended
method for changing channels is to change them after the
conversion from the previous channel has been completed
and read. When a channel is changed, internal logic senses
the change on the falling edge of CLK and resets the
conversion process. The conversion data from the new
channel is valid on the first DRDY after the channel change.
When multiplexing inputs, it is possible to achieve sample
rates close to 4kHz. This is due to the fact that it requires five
internal conversion cycles for the data to fully settle. The
data also must be read before the channel is changed. The
DRDY signal indicates a valid result after the five cycles
have occurred.
ANALOG INPUT
The ADS1254 contains a fully differential analog input. In order
to provide low system noise, common-mode rejection of 102dB,
and excellent power-supply rejection, the design topology is
based on a fully differential switched-capacitor architecture. The
bipolar input voltage range is from –4.096V to +4.096V, when
the reference input voltage equals +4.096V. The bipolar range is
with respect to –VIN, and not with respect to GND.
BIPOLAR INPUT
CHSEL1
CHSEL0
CHANNEL
0
0
1
1
0
1
0
1
CH1
CH2
CH3
CH4
Figure 1 shows the basic input structure of the ADS1254.
The impedance is directly related to the sampling frequency
of the input capacitor that is set by the CLK rate. Higher
CLK rates result in lower impedance, and lower CLK rates
result in higher impedance.
TABLE I. Channel Selection.
Each of the differential inputs of the ADS1254 must stay
between AGND and AVDD. With a reference voltage at less
than half of AVDD, one input can be tied to the reference
voltage, and the other input can range from AGND to
2 • VREF. By using a three op-amp circuit featuring a single
amplifier and four external resistors, the ADS1254 can be
configured to accept bipolar inputs referenced to ground.
The conventional ±2.5V, ±5V, and ±10V input ranges can
be interfaced to the ADS1254 using the resistor values
shown in Figure 2.
RSW
(1300Ω typical)
Internal
AIN
Circuitry
CINT
(6pF typical)
Modulator Frequency
= fMOD
VCM
FIGURE 1. Analog-Input Structure.
R1
The input impedance of the analog input changes with the
ADS1254 system clock frequency (CLK). The relationship is:
10kΩ
AIN Impedance (Ω) = (8MHz/CLK) • 125,000
+IN
OPA4350
20kΩ
ADS1254
VREF
With regard to the analog-input signal, the overall analog
performance of the device is affected by three items: first, the
input impedance can affect accuracy. If the source impedance
of the input signal is significant, or if there is passive filtering
prior to the ADS1254, a significant portion of the signal can be
lost across this external impedance. The magnitude of the
effect is dependent on the desired system performance.
Bipolar
Input
–IN
R
2
OPA4350
OPA4350
Second, the current into or out of the analog inputs must be
limited. Under no conditions should the current into or out
of the analog inputs exceed 10mA.
REF
2.5V
BIPOLAR INPUT
R1
R2
±10V
±5V
2.5kΩ
5kΩ
5kΩ
10kΩ
20kΩ
Third, to prevent aliasing of the input signal, the analog-input
signal must be band limited. The bandwidth of the A/D
converter is a function of the system clock frequency. With a
system clock frequency of 8MHz, the data-output rate is
±2.5V
10kΩ
FIGURE 2. Level Shift Circuit for Bipolar Input Ranges.
ADS1254
7
SBAS213
BB [ BURR-BROWN CORPORATION ]
