During autozero, a ground reference is applied as an
input to the A/D converter. Under ideal conditions the
output of the comparator would also go to zero.
However, input-offset-voltage errors accumulate in the
amplifier loop, and appear at the comparator output as
an error voltage. This error is impressed across the AZ
capacitor where it is stored for the remainder of the
measurement cycle. The stored level is used to provide
offset voltage correction during the integrate and read
periods.
The integrate period begins at the end of the autozero
period. As the period begins, the AZ switch opens and
the INTEG switch closes. This applies the unknown
input voltage to the input of the A/D converter. The
voltage is buffered and passed on to the unknown input
voltage to the input of the A/D converter. The voltage is
buffered and passed on to the integrator to determine
the charge rate (slope) on the INTEG capacitor. At the
end of the fixed integrate period, the capacitor is
charged to a level proportional to the unknown input
voltage. This voltage is translated to a digital indication
by discharging the capacitor at a fixed rate during the
read period, and counting the number of clock pulses
that occur before it returns to the original autozero
level.
As the read period begins, the INTEG switch opens and
the read switch closes. This applies a known reference
voltage to the input of the A/D converter. The polarity
of this voltage is automatically selected to be opposite
that of unknown input voltage, thus causing the INTEG
capacitor to discharge as fixed rate (slope). When the
charge is equal to the initial starting point (autozero
level), the read period is ended. Since the discharge
slope is fixed during the read period, the time required
is proportional to the unknown input voltage.
The autozero period and thus a new measurement
cycle begins at the end of the read period. At the same
time, the counter is released for operation by
transferring its contents (previous measurement value)
to a series of latches. This stored stat is then decoded
and buffered before being used for driving the LCD
display.
-2-
AZ
READ
+REF
(FLYING
CAPACITOR)
UNKNOWN
INPUT
INTEG
INTEG
AZ
AZ
READ
AZ
INTEG.
TO
DIGITAL
CONTROL
LOGIC
COUNTER OUTPUT
+.20
.15
.10
.05
0
0
10,000
1000
500
0
166.7mS
1500
2000
Figure 2 Dual Slope A/D Converter
AZ
COMPARATOR
INTEGRATOR
BUFFER
AMP
EXTERNAL
INPUTS
A/D CONVERTER
A simplified circuit diagram of the analog portion of
the A/D converter is shown in Figure 2. Each of the
switches shown represent analog gates which are
operated by the digital section of the A/D converter.
Basic timing for switch operation is keyed by an
external oscillator.
The conversion process is
continuously repeated. A complete cycle is shown
in Figure 2.
Any given measurement cycle performed by the A/D
converter can be divided into three consecutive time
periods: autozero (AZ), integrate (INTEG) and read.
Both autozero and integrate are fixed time periods.
A counter determines the length of both time
periods by providing an overflow at the end of every
1,000 clock pulses. The read period is a variable
time, which is proportional to the unknown input
voltage. The value of the voltage is determined by
counting the number of clock pulses that occur
during the read period.
SCHEMATIC DIAGRAM
-33-