POWER SUPPLY DECOUPLING
+VCC
On the ADS574, +5V (to Pin 1) is the only power supply
required for correct operation. Pin 7 is not connected inter-
nally, so there is no problem in existing ADC574 sockets
where this is connected to +15V. Pin 11 (VEE) is only used
as a logic input to select modes of control over the sampling
function as described above. When used in an existing
ADC574 socket, the –15V on pin 11 selects the ADC574
Emulation Mode. Since pin 11 is used as a logic input, it is
immune to typical supply variations.
Unipolar
Offset
Adjust
Full-Scale
Adjust
R1
100kΩ
R2
100Ω
10 Ref In
ADS574
100kΩ
–VCC
2.5V
8
Ref Out
100Ω
R3
12 Bipolar Offset
The +5V supply should be bypassed with a 10µF tantalum
capacitor located close to the converter to promote noise-
free operations, as shown in Figure 2. Noise on the power
supply lines can degrade the converter’s performance. Noise
and spikes from a switching power supply are especially
troublesome.
10V
Range
13
14
9
Analog
Input
20V
Range
RANGE CONNECTIONS
Analog
Common
The ADS574 offers four standard input ranges: 0V to +10V,
0V to +20V, ±5V, or ±10V. Figures 10 and 11 show the
necessary connections for each of these ranges, along with
the optional gain and offset trim circuits. If a 10V input
range is required, the analog input signal should be con-
nected to pin 13 of the converter. A signal requiring a 20V
range is connected to pin 14. In either case the other pin of
the two is left unconnected. Pin 12 (Bipolar Offset) is
connected either to Pin 9 (Analog Common) for unipolar
operation, or to Pin 8 (2.5V Ref Out), or the external
reference, for bipolar operation. Full-scale and offset adjust-
ments are described below.
FIGURE 10. Unipolar Configuration.
Full-Scale Adjust
R2
10 Ref In
100Ω
ADS574
2.5V
8
Ref Out
100Ω
R1
Bipolar
Offset
Adjust
12 Bipolar Offset
The input impedance of the ADS574 is typically 84kΩ in the
20V ranges and 21kΩ in the 10V ranges. This is signifi-
cantly higher than that of traditional ADC574 architectures,
reducing the load on the input source in most applications.
13
14
9
Analog
Input
10V
Range
20V
Range
INPUT STRUCTURE
Analog
Common
Figure 12 shows the resistor divider input structure of the
ADS574. Since the input is driving a capacitor in the CDAC
during acquisition, the input is looking into a high imped-
FIGURE 11. Bipolar Configuration.
If the 10V analog input range is used (either bipolar or
unipolar), the 20V range input (pin 14) should be shielded
with ground plane to reduce noise pickup.
68kΩ
Pin 14
20V Range
Coupling between analog input and digital lines should be
minimized by careful layout. For instance, if the lines must
cross, they should do so at right angles. Parallel analog and
digital lines should be separated from each other by a pattern
connected to common.
34kΩ
Pin 13
Capacitor
Array
10V Range
34kΩ
If external full scale and offset potentiometers are used, the
potentiometers and associated resistors should be as close as
possible to the ADS574.
17kΩ
Pin 12
Bipolar
Offset
10kΩ
FIGURE 12. ADS574 Input Structure.
®
12
ADS574