ADS1610
www.ti.com
SBAS344C–AUGUST 2005–REVISED OCTOBER 2006
Figure 32 shows the settling error as a function of
time for a full-scale signal step applied at t = 0, with
MODE = 00 (See Table 4). This figure uses DRDY
cycles for the ADS1610 for the time scale (X-axis).
After 55 DRDY cycles, the settling error drops below
0.001%. For fCLK = 60MHz, this corresponds to a
settling time of 5.5µs.
ADS1610
1
DRDY
DRDY
1
SYNC
Clock
SYNC
CLK
DOUT[15:0]
DOUT[15:0]
1
101
100
ADS1610
2
DRDY
DRDY
2
SYNC
CLK
DOUT[15:0]
DOUT[15:0]
2
10−
1
10−
2
CLK
10−3
10−4
10−5
SYNC
t11
DRDY
1
30
35
40
45
50
55
60
Settling Time (DRDY cycles)
Settled
Data
DOUT[15:0]
1
Figure 32. Settling Time
DRDY
2
IMPULSE RESPONSE
Settled
Data
DOUT[15:0]
2
Figure 33 plots the normalized response for an input
applied at t = 0, with MODE = 00. The X-axis units of
time are DRDY cycles for the ADS1610. As shown in
Figure 33, the peak of the impulse takes 30 DRDY
cycles to propagate to the output. For fCLK = 60 MHz,
Synchronized
a
DRDY cycle is 0.1µs in duration and the
propagation time (or group delay) is 30 × 0.1µs =
3.0 µs.
Figure 31. Synchronizing Multiple Converters
SETTLING TIME
1.0
0.8
0.6
0.4
0.2
0
The settling time is an important consideration when
measuring signals with large steps or when using a
multiplexer in front of the analog inputs. The
ADS1610 digital filter requires time for an
instantaneous change in signal level to propagate to
the output.
Be sure to allow the filter time to settle after applying
a large step in the input signal, switching the channel
on a multiplexer placed in front of the inputs,
resetting the ADS1610, or exiting the power-down
mode.
−
−
0.2
0.4
0
10
20
30
40
50
60
Time (DRDY cycles)
Figure 33. Impulse Response
16
Submit Documentation Feedback