TC811 查看數據表(PDF) - Microchip Technology
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TC811
Microchip Technology
TC811 Datasheet PDF : 14 Pages
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3-1/2 Digit Analog-To-Digital Converter with
Hold and Differential Reference Inputs
TC811
Accuracy in a dual slope converter is unrelated to the
integrating resistor and capacitor values as long as they are
stable during a measurement cycle. An inherent benefit of
the dual slope technique is noise immunity. Noise spikes are
1000
INT
integrated or averaged to zero during the integration peri-
ods, making integration ADCs immune to the large conver-
DE-INT
1–2000
sion errors that plague successive approximation convert-
ers in high noise environments. Interfering signals, with
ZI
11–140
frequency components at multiples of the averaging (inte-
AZ
grating) period, will be attenuated. (see Figure 3). Integrat-
910–2900
ing ADCs commonly operate with the signal integration
4000
period set to a multiple of the 50/60Hz power line period.
THEORY OF OPERATION
Figure 4a. Conversion Timing During Normal Operation
Analog Section
In addition to the basic integrate and deintegrate dual-
slope cycles discussed above, the TC811 design incorpo-
rates an “Integrator Output Zero” cycle and an “Auto Zero”
cycle. These additional cycles ensure the integrator starts at
0V (even after a severe overrange conversion) and that all
offset voltage errors (buffer amplifier, integrator and com-
parator) are removed from the conversion. A true digital zero
reading is assured without any external adjustments.
A complete conversion consists of four distinct phases:
(1) Integrator Output Zero Cycle
(2) Auto Zero Cycle
(3) Signal Integrate Cycle
(4) Reference Deintegrate Cycle
Integrator Output Zero Cycle
This phase guarantees that the integrator output is at
zero volts before the system zero phase is entered, ensuring
that the true system offset voltages will be compensated for
even after an overrange conversion. The duration of this
phase is variable, being a function of the number of counts
(clock cycles) required for deintegration.
The Integrator Output Zero cycle will last from 11 to 140
counts for non-over-range conversions and from 31 to 640
counts for overrange conversions.
Auto Zero Cycle
During the Auto Zero cycle, the differential input signal
is disconnected from the measurement circuit by opening
internal analog switches and the internal nodes are shorted
to Analog Common (0V ref.) to establish a zero input
condition. Additional analog switches close a feedback loop
around the integrator and comparator to permit comparator
offset voltage error compensation. A voltage established on
CAZ then compensates for internal device offset voltages
during the measurement cycle. The Auto Zero cycle residual
INT
DE-INT
ZI
AZ
1000
2001–2090
31–640
4000
300–910
Figure 4b. Conversion Timing During Overrange Operation
is typically 10 to 15µV.
The Auto Zero duration is from 910 to 2,900 counts for
non-over-range conversions and from 300 to 910 counts for
overrange conversions.
Signal Integration Cycle
Upon completion of the Auto Zero cycle, the Auto Zero
loop is opened and the internal differential inputs connect to
VIN+ and VIN–. The differential input signal is then integrated
for a fixed time period which, in the TC811 is 1000 counts
(4000 clock periods). The externally set clock frequency is
divided by four before clocking the internal counters. The
integration time period is:
TINT =
4000
fOSC
The differential input voltage must be within the device
common-mode range when the converter and measured
system share the same power supply common (ground).
If the converter and measured system do not share the same
power supply common, as in battery powered applications,
VIN– should be tied to Analog Common.
TC811-7 11/5/96
6
© 2001 Microchip Technology Inc. DS21472A
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