TELCOM TC7129

1
TC7129
4-1/2 DIGIT ANALOG-TO-DIGITAL CONVERTER
WITH ON-CHIP LCD DRIVERS
FEATURES
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GENERAL DESCRIPTION
Count Resolution ......................................... ±19,999
Resolution on 200 mV Scale .......................... 10 µV
True Differential Input and Reference
Low Power Consumption ................... 500 µA at 9V
Direct LCD Driver for 4-1/2 Digits, Decimal Points,
Low-Battery Indicator, and Continuity Indicator
Overrange and Underrange Outputs
Range Select Input ............................................ 10:1
High Common-Mode Rejection Ratio ......... 110 dB
External Phase Compensation Not Required
The TC7129 is a 4-1/2 digit analog-to-digital converter
(ADC) that directly drives a multiplexed liquid crystal display (LCD). Fabricated in high-performance, low-power
CMOS, the TC7129 ADC is designed specifically for highresolution, battery-powered digital multimeter applications.
The traditional dual-slope method of A/D conversion has
been enhanced with a successive integration technique to
produce readings accurate to better than 0.005% of full
scale, and resolution down to 10 µV per count.
The TC7129 includes features important to multimeter
applications. It detects and indicates low-battery condition.
A continuity output drives an annunciator on the display, and
can be used with an external driver to sound an audible
alarm. Overrange and underrange outputs and a rangechange input provide the ability to create auto-ranging
instruments. For snapshot readings, the TC7129 includes a
latch-and-hold input to freeze the present reading. This
combination of features makes the TC7129 the ideal
choice for full-featured multimeter and digital measurement
applications.
ORDERING INFORMATION
Part No.
TC7129CKW
TC7129CLW
TC7129CPL
2
Pin
Layout
Formed
—
Normal
Package
Temperature
Range
44-Pin PQFP
44-Pin PLCC
40-Pin PDIP
0°C to +70°C
0°C to +70°C
0°C to +70°C
3
4
5
TYPICAL OPERATING CIRCUIT
LOW BATTERY
CONTINUITY
V+
5 pF
20 19 18 17 16 15 14 13 12 11 10
9
8
7
6
5
4
3
2
1
6
120 kHz
TC7129
21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40
330 kΩ
*
0.1 µF
1 µF
+
7
10 pF
0.1
µF
20
kΩ
TC04
150 kΩ
0.1 µF
V+
10 kΩ
+
100 kΩ
9V
–
+
VIN
8
* NOTE: RC network between pins 26 and 28 is not required.
TC7129-5 10/18/96
TELCOM SEMICONDUCTOR, INC.
3-231
4-1/2 DIGIT ANALOG-TO-DIGITAL
CONVERTER WITH ON-CHIP LCD DRIVERS
TC7129
ABSOLUTE MAXIMUM RATINGS*
(V+
V–) ............................................ 15V
Supply Voltage
to
Reference Voltage (REF HI or REF LO) .............. V+ to V–
Input Voltage (IN HI or IN LO) (Note 1) ................ V+ to V–
VDISP ................................................V+ to (DGND – 0.3V)
Digital Input, Pins
1, 2, 19, 20, 21, 22, 27, 37, 39, 40 .......... DGND to V+
Analog Input, Pins 25, 29, 30 ............................... V+ to V–
Package Power Dissipation (TA ≤ 70°C)
Plastic DIP ........................................................1.23W
PLCC ................................................................1.23W
Plastic QFP .......................................................1.00W
Operating Temperature Range .................... 0°C to +70°C
Storage Temperature Range ................ – 65°C to +150°C
Lead Temperature (Soldering, 10 sec) ................. +300°C
Notes: Input voltages may exceed supply voltages, provided input current
is limited to ±400 µA. Currents above this value may result in invalid display
readings but will not destroy the device if limited to ±1 mA.
Dissipation ratings assume device is mounted with all leads soldered to
printed circuit board.
*Static-sensitive device. Unused devices must be stored in conductive
material. Protect devices from static discharge and static fields. Stresses
above those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings only and functional
operation of the device at these or any other conditions above those
indicated in the operational sections of the specifications is not implied.
Exposure to Absolute Maximum Rating Conditions for extended periods
may affect device reliability.
ELECTRICAL CHARACTERISTICS: V+ to V– = 9V, VREF = 1V, TA = +25°C, fCLK = 120 kHz, unless otherwise
indicated. Pin numbers refer to 40-pin DIP.
Symbol
Parameter
Test Conditions
Min
Zero Input Reading
Zero Reading Drift
Ratiometric Reading
Range Change Accuracy
VIN = 0V, 200 mV Scale
VIN = 0V, 0°C < TA < +70°C
VIN = VREF = 1000 mV, Range = 2V
VIN = 0.1V on Low Range
4VIN = 1V on High Range
–VIN = +VIN = 199 mV
200 mV Scale
VCM = 1V, VIN = 0V, 200 mV Scale
VIN = 0V
200 mV Scale
VIN = 0V
200 mV Scale
VIN = 0V, Pins 32, 33
VIN = 199 mV, 0°C < TA < +70°C
External VREF = 0 ppm/°C
Typ
Max
Unit
Input
RE
NL
CMRR
CMVR
Roll-Over Error
Linearity Error
Common-Mode Rejection Ratio
Common-Mode Voltage Range
eN
Noise (Peak-to-Peak Value Not
Exceeded 95% of Time)
Input Leakage Current
Scale Factor Temperature
Coefficient
IIN
Power
VCOM
DGND
IS
fCLK
– 0000 0000
—
±0.5
9997
9999
0.9999 1.0000
+0000
—
10000
1.0001
Counts
µV/°C
Counts
Ratio
—
—
—
—
—
—
1
1
110
(V–) +1.5
(V+) –1
14
2
—
—
—
—
—
Counts
Counts
dB
V
V
µVP-P
—
—
1
2
10
7
pA
ppm/°C
3.2
0.6
10
5.3
1.2
9
0.8
120
50
7.2
3.5
—
—
5.8
—
12
1.3
360
—
7.7
V
mA
µA
V
mA
V
mA
kHz
kΩ
V
200
200
2
—
400
10
mV
mV
µA
Common Voltage
Common Sink Current
Common Source Current
Digital Ground Voltage
Sink Current
Supply Voltage Range
Supply Current Excluding Common Current
Clock Frequency
VDISP Resistance
Low-Battery Flag Activation Voltage
V+ to Pin 28
∆Common = +0.1V
∆Common = –0.1V
V+ to Pin 36, V+ to V– = 9V
∆DGND = +0.5V
V+ to V–
V+ to V– = 9V
VDISP to V+
V+ to V–
2.8
—
—
4.5
—
6
—
—
—
6.3
Continuity Comparator
Threshold Voltages
Pull-Down Current
VOUT Pin 27 = High
VOUT Pin 27 = Low
Pins 37, 38, 39
100
—
—
Digital
3-232
TELCOM SEMICONDUCTOR, INC.
4-1/2 DIGIT ANALOG-TO-DIGITAL
CONVERTER WITH ON-CHIP LCD DRIVERS
1
TC7129
ELECTRICAL CHARACTERISTICS: V+ to V– = 9V, VREF = 1V, TA = +25°C, fCLK = 120 kHz, unless otherwise
indicated. Pin numbers refer to 40-pin DIP.
Symbol
Parameter
Test Conditions
"Weak Output" Current
Sink/Source
Pin 22 Source Current
Pin 22 Sink Current
Pins 20, 21 Sink/Source
Pin 27 Sink/Source
Min
Typ
Max
—
—
—
—
3/3
3/9
40
3
—
—
—
—
Unit
µA
µA
µA
µA
PIN CONFIGURATIONS
1
40 OSC2
2
39
ANNUNICATOR DRIVE
3
38 DP2
B1, C1, CONT
4
37 RANGE
A1, G1, D1
5
36 DGND
F1, E1, DP1
6
35 REF LO
B2, C2, LO BATT
7
34 REF HI
A2, G2, D2
8
33 IN HI
F2, E2, DP2
9
32
B3, C3, MINUS 10
DISPLAY
A3, G3, D3 11
OUTPUT
F
LINES
3, E3, DP3 12
B4, C4, BC5 13
31
TC7129CPL
4
IN LO
BUFF
–
30 CREF
+
29 CREF
28 COM
14
27 CONT
15
26 INT OUT
BP3
16
BP2
17
25 INT IN
+
24 V
BP1
18
23 V –
VDISP
DP4/OR
19
22 LATCH/HOLD
20
21 DP3/UR
F1, E1, DP1 1
33 REF LO
32 REF HI
B2, C2, BATT 2
A2, G2, D2 3
31 IN HI
DP1
DP2
RANGE
DGND
34
OSC2
35
NC
DGND
36
OSC1
RANGE
37
OSC3
DP2
38
A.D.
DP1
41 40 39
B1, C1, CONT
OSC2
42
5
A1, G1, D1
NC
44-Pin QFP
OSC1
3
DP1
A4, G4, D4
F4, E4, DP4
OSC3
44 43
OSC1
OSC3
A.D.
B1, C1, CONT
A1, G1, D1
40-Pin PDIP
6
5
4
3
2
1
44
43
42
41
40
44-Pin PLCC
6
F1, E1, DP1
7
39 REF LO
B2, C2, BATT
A2, G2, D2
8
38 REF HI
9
37 IN HI
F2, E2, DP2 4
30 IN LO
F2, E2, DP2 10
36 IN LO
B3, C3, MINUS 5
29 BUFF
B3, C3, MINUS 11
35 BUFF
NC 6
28 NC
TC7129CKW
NC 12
34 NC
TC7129CLW
7
–
27 CREF
A3, G3, D3 13
33 CREF
F3, E3, DP3
8
26 C +
REF
F3, E3, DP3 14
32 CREF
25 COM
B4, C4, BC5 15
31 COM
24 CONT
A4, G4, D4 16
30 CONT
21 22 23
24
25
26
27
28
LATCH/HOLD
V–
V+
INT IN
V+
20
DP3/UR
V–
18 19
NC
LATCH/HOLD
TELCOM SEMICONDUCTOR, INC.
29 INT OUT
F4, E4, DP4 17
DP4/OR
21 22
VDISP
20
BP1
19
INT IN
18
DP3/UR
VDISP
17
NC
BP1
DP4/OR
15 16
BP2
14
BP3
23 INT OUT
12 13
BP2
F4, E4, DP4 11
+
BP3
A4, G4, D4 10
7
–
A3, G3, D3
B4, C4, BC5 9
2
8
3-233
4-1/2 DIGIT ANALOG-TO-DIGITAL
CONVERTER WITH ON-CHIP LCD DRIVERS
TC7129
PIN DESCRIPTIONS
Pin No.
40-Pin
TC7129CPL
3-234
Pin No.
44-Pin
TC7129CKW
Pin No.
44-Pin
TC7129CLW
Symbol
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
40
41
2
3
43
44
1
2
3
4
5
7
8
9
10
11
12
13
14
15
16
5
6
7
8
9
10
11
13
14
15
16
17
18
19
20
21
22
OSC1
OSC3
ANNUNCIATOR
B1, C1, CONT
A1, G1, D1
F1, E1, DP1
B2, C2, LO BATT
A2, G2, D2
F2, E2, DP2
B3, C3, MINUS
A3, G3, D3
F3, E3, DP3
B4, C4, BC5
A4, D4, G4
F4, E4, DP4
BP3
BP2
BP1
VDISP
DP4/OR
21
18
24
DP3/UR
22
19
25
LATCH/HOLD
23
24
20
26
27
V–
V+
25
26
27
21
23
24
28
29
30
INT IN
INT OUT
CONTINUITY
28
25
31
COMMON
29
30
31
32
33
26
27
29
30
31
32
33
35
36
37
C+REF
C–REF
BUFFER
IN LO
IN HI
Function
Input to first clock inverter.
Output of second clock inverter.
Backplane square-wave output for driving annunciators.
Output to display segments.
Output to display segments.
Output to display segments.
Output to display segments.
Output to display segments.
Output to display segments.
Output to display segments.
Output to display segments.
Output to display segments.
Output to display segments.
Output to display segments.
Output to display segments.
Backplane #3 output to display.
Backplane #2 output to display.
Backplane #1 output to display.
Negative rail for display drivers.
Input: When HI, turns on most significant decimal point.
Output: Pulled HI when result count exceeds ±19,999.
Input: Second most significant decimal point on when HI.
Output: Pulled HI when result count is less than ±1000.
Input: When floating, ADC operates in the free-run mode.
When pulled HI, the last displayed reading is held. When
pulled LO, the result counter contents aren shown
inincrementing during the deintegrate phase of cycle.
Output: Negative-going edge occurs when the data latches
are updated. Can be used for converter status signal.
Negative power supply terminal.
Positive power supply terminal and positive rail for display
drivers.
Input to integrator amplifier.
Output of integrator amplifier.
Input: When LO, continuity flag on the display is OFF.
When HI, continuity flag is ON.
Output: HI when voltage between inputs is less than +200
mV. LO when voltage between inputs is more than +200
mV.
Sets common-mode voltage of 3.2V below V + for DE,
10X, etc. Can be used as preregulator for external
reference.
Positive side of external reference capacitor.
Negative side of external reference capacitor.
Output of buffer amplifier.
Negative input voltage terminal.
Positive input voltage terminal.
TELCOM SEMICONDUCTOR, INC.
4-1/2 DIGIT ANALOG-TO-DIGITAL
CONVERTER WITH ON-CHIP LCD DRIVERS
1
TC7129
PIN DESCRIPTIONS
2
Pin No.
40-Pin
TC7129CPL
Pin No.
44-Pin
TC7129CKW
Pin No.
44-Pin
TC7129CLW
Symbol
Function
34
35
36
32
33
34
38
39
40
REF HI
REF LO
DGND
37
35
41
RANGE
38
39
40
36
37
38
42
43
44
DP2
DP1
OSC2
Positive reference voltage in
Negative reference voltage
Internal ground reference for digital section. See "±5V Power
Supply" paragraph.
3 µA pull-down for 200 mV scale. Pulled HI externally for 2V
scale.
Internal 3 µA pull-down. When HI, decimal point 2 will be on.
Internal 3 µA pull-down. When HI, decimal point 1 will be on.
Output of first clock inverter. Input of second clock inverter.
6,17, 28, 39
12, 23, 34,1
NC
No Connection
COMPONENT SELECTION
(All pin designations refer to 40-Pin Dip)
The TC7129 is designed to be the heart of a highresolution analog measurement instrument. The only additional components required are a few passive elements, a
voltage reference, an LCD, and a power source. Most
component values are not critical; substitutes can be chosen
based on the information given below.
The basic circuit for a digital multimeter application is
shown in Figure 1. See "Special Applications" for variations.
Typical values for each component are shown. The sections
below give component selection criteria.
Oscillator (XOSC, CO1, CO2, RO)
The primary criterion for selecting the crystal oscillator
is to chose a frequency that achieves maximum rejection of
line-frequency noise. To do this, the integration phase
should last an integral number of line cycles. The integration
phase of the TC7129 is 10,000 clock cycles on the 200 mV
range and 1000 clock cycles on the 2V range. One clock
cycle is equal to two oscillator cycles. For 60 Hz rejection, the
oscillator frequency should be chosen so that the period of
one line cycle equals the integration time for the 2V range:
1/60 second = 16.7 msec =
1000 clock cycles * 2 osc cycles/clock cycle ,
oscillator frequency
3
4
The resistor and capacitor values are not critical; those
shown work for most applications. In some situations, the
capacitor values may have to be adjusted to compensate for
parasitic capacitance in the circuit. The capacitors can be
low-cost ceramic devices.
Some applications can use a simple RC network instead
of a crystal oscillator. The RC oscillator has more potential
for jitter, especially in the least significant digit. See "RC
Oscillator."
5
Integrating Resistor (RINT)
The integrating resistor sets the charging current for
the integrating capacitor. Choose a value that provides a
current between 5 µA and 20 µA at 2V, the maximum fullscale input. The typical value chosen gives a charging
current of 13.3 µA:
ICHARGE =
6
2V
13.3 µA
150 kΩ
Too high a value for RINT increases the sensitivity to
noise pickup and increases errors due to leakage current.
Too low a value degrades the linearity of the integration,
leading to inaccurate readings.
7
giving an oscillator frequency of 120 kHz. A similar calculation gives an optimum frequency of 100 kHz for 50 Hz
rejection.
8
TELCOM SEMICONDUCTOR, INC.
3-235
4-1/2 DIGIT ANALOG-TO-DIGITAL
CONVERTER WITH ON-CHIP LCD DRIVERS
TC7129
LOW BATTERY
CONTINUITY
+
V
14
13
11
12
9
10
7
8
6
5
4
ANNUNC
OSC3
REF HI
REF LO
DGND
RANGE
DP2
DP1
OSC2
27
28
30
29
31
1
IN HI
26
2
IN LO
25
32
33
34
35
36
37
38
39
40
TC7129
BUFFER
24
CREF–
CREF+
COMMON
23
3
OSC1
15
CONTINUITY
VDISP
22
16
DISPLAY DRIVE OUTPUTS
V–
LATCH/
HOLD
DP3 /UR
21
17
INT OUT
DP4 /OR
18
INT IN
19
V+
20
5 pF
CO1
120
kHz
CRYSTAL
330 kΩ
RO
10 pF
CINT
0.1
µF
CREF
1 µf
+
150 kΩ
RINT
+
9V
RREF DREF
20
kΩ
0.1
µF
V+
TC04
CIF
10 kΩ
RBIAS
CRF
0.1 µF
CO2
RIF
100 kΩ
–
+
V
IN
Figure 1.
3-236
Standard Circuit
TELCOM SEMICONDUCTOR, INC.
4-1/2 DIGIT ANALOG-TO-DIGITAL
CONVERTER WITH ON-CHIP LCD DRIVERS
1
TC7129
Integrating Capacitor (CINT)
Voltage Reference (DREF, RREF, RBIAS, CRF)
The charge stored in the integrating capacitor during
the integrate phase is directly proportional to the input
voltage. The primary selection criterion for CINT is to choose
a value that gives the highest voltage swing while remaining within the high-linearity portion of the integrator output
range. An integrator swing of 2V is the recommended
value. The capacitor value can be calculated from the
equation:
A TC04 band-gap reference provides a high-stability
voltage reference of 1.25V. The reference potentiometer
(RREF) provides an adjustment for adjusting the reference
voltage; any value above 20 kΩ is adequate. The bias
resistor (RBIAS) limits the current through DREF to less than
150 µA. The reference filter capacitor (CRF) forms an RC
filter with RBIAS to help eliminate noise.
Input filter (RIF, CIF)
tINT x IINT
CINT =
,
VSWING
where tINT is the integration time.
Using the values derived above (assuming 60 Hz
operation), the equation becomes:
CINT = 16.7msec x 13.3 µA = 0.1 µF.
2V
The capacitor should have low dielectric absorption to
ensure good integration linearity. Polypropylene and Teflon
capacitors are usually suitable. A good measurement of the
dielectric absorption is to connect the reference capacitor
across the inputs by connecting:
Pin to Pin
20 → 33 (CREF+ to IN HI)
30 → 32 (CREF– to IN LO)
For added stability, an RC input noise filter is usually
included in the circuit. The input filter resistor value should
not exceed 100 kΩ. A typical RC time constant value is
16.7msec to help reject line-frequency noise. The input filter
capacitor should have low leakage for a high-impedance
input.
2
3
4
Battery
The typical circuit uses a 9V battery as a power source.
Any value between 6V and 12V can be used. For operation
from batteries with voltages lower than 6V and for operation
from power supplies, see "Powering the TC7129."
SPECIAL APPLICATIONS
The TC7129 as a Replacement Part
A reading between 10,000 and 9998 is acceptable;
anything lower indicates unacceptably high dielectric absorption.
The TC7129 is a direct pin-for-pin replacement part for
the ICL7129. Note, however, that part requires a capacitor
and resistor between pins 26 and 28 for phase compensation. Since the TC7129 uses internal phase compensation,
these parts are not required and, in fact, must be removed
from the circuit for stable operation.
Reference Capacitor (CREF)
Powering the TC7129
The reference capacitor stores the reference voltage
during several phases of the measurement cycle. Low
leakage is the primary selection criterion for this component.
The value must be high enough to offset the effect of stray
capacitance at the capacitor terminals. A value of at least
1 µF is recommended.
While the most common power source for the TC7129
is a 9V battery, there are other possibilities. Some of the
more common ones are explained below.
5
6
7
8
TELCOM SEMICONDUCTOR, INC.
3-237
4-1/2 DIGIT ANALOG-TO-DIGITAL
CONVERTER WITH ON-CHIP LCD DRIVERS
TC7129
±5V Power Supply
Measurements are made with respect to power supply
ground. DGND (pin 36) is set internally to about 5V less than
V+ (pin 24); it is not intended as a power supply input and
must not be tied directly to power supply ground. (It can be
used as a reference for external logic, as explained in
"Connecting to External Logic." (See Figure 2.)
24
V+
REF HI
36
+
3.8V
TO
6V
REF LO
COM
TC7129
IN HI
IN LO
V–
2
REF HI
0.1 µF
+
TC04
REF LO
36
8
34
10 µF
TC7660
35
28
33
32
+
VIN
–
23
4
5
DGND
COM
0.1 µF
IN HI
TC7129
0.1 µF
35
TC04
DGND
+5V
24
+
V
34
IN LO
V–
28
33
32
10 µF
3
+
+
VIN
–
Figure 3. Powering the TC7129 From a Low-Voltage Battery
23
+5V
–5V
Figure 2.
Powering the TC7129 From a ±5V Power Supply
24
V+
Low-Voltage Battery Source
Connecting to External Logic
External logic can be directly referenced to DGND (pin
36), provided that the supply current of the external logic
does not exceed the sink current of DGND (Figure 5). A safe
value for DGND sink current is 1.2 mA. If the sink current is
expected to exceed this value, a buffer is recommended.
(See Figure 6.)
3-238
TC04
35
36
DGND
28
0.1 µF
33
+5V Power Supply
Measurements are made with respect to power supply
ground. COMMON (pin 28) is connected to REF LO (pin 35).
A voltage doubler is needed, since the supply voltage is less
than the 6V minimum needed by the TC7129. DGND (pin
36) must be isolated from power supply ground.
(See Figure 4.)
34
0.1 µF
A battery with voltage between 3.8V and 6V can be used
to power the TC7129 when used with a voltage-doubler
circuit as shown in Figure 3. The voltage doubler uses the
TC7660 DC-to-DC voltage converter and two external capacitors.
TC7129
8
V+
32
V–
2
+
+
VIN
–
23
10 µF
TC7660
4
5
GND
3
10 µF
+
Figure 4. Powering the TC7129 From a +5V Power Supply
TELCOM SEMICONDUCTOR, INC.
4-1/2 DIGIT ANALOG-TO-DIGITAL
CONVERTER WITH ON-CHIP LCD DRIVERS
1
TC7129
V+
V
2
+
24
24
EXTERNAL
LOGIC
EXTERNAL
LOGIC
TC7129
36
DGND
ILOGIC
+
36
DGND
ILOGIC
23
23
V–
V
Figure 5. External Logic Referenced Directly to DGND
3
TC7129
–
–
Figure 6. External Logic Referenced to DGND With Buffer
4
Temperature Compensation
For most applications, VDISP (pin 19) can be connected
directly to DGND (pin 36). For applications with a wide
temperature range, some LCDs require that the drive levels
vary with temperature to maintain good viewing angle and
display contrast. Figure 7 shows two circuits that can be
adjusted to give temperature compensation of about 10
mV/°C between V+ (pin 24) and VDISP. The diode between
DGND and VDISP should have a low turn-ON voltage because VDISP cannot exceed 0.3V below DGND.
V+
1N4148
V+
39 kΩ
24
20 kΩ
19
5 kΩ
2N2222
TC7129
–
+
36
6
39 kΩ
24
200 kΩ
5
TC7129
19
VDISP
VDISP
7
36
DGND
DGND
75 kΩ
18 kΩ
23
V–
Figure 7.
TELCOM SEMICONDUCTOR, INC.
23
V–
8
Temperature Compensating Circuits
3-239
4-1/2 DIGIT ANALOG-TO-DIGITAL
CONVERTER WITH ON-CHIP LCD DRIVERS
TC7129
RC Oscillator
For applications in which 3-1/2 digit (100 µV) resolution
is sufficient, an RC oscillator is adequate. A recommended
value for the capacitor is 51 pF. Other values can be used as
long as they are sufficiently larger than the circuit parasitic
capacitance. The resistor value is calculated from:
R=
0.45
freq * C
For 120 kHz frequency and C = 51 pF, the calculated
value of R is 75 kΩ. The RC oscillator and the crystal
oscillator circuits are shown in Figure 8.
measurement of the time to ramp the integrated voltage to
zero, and is therefore proportional to the input voltage being
measured. This count can then be scaled and displayed as
a measurement of the input voltage. Figure 9 shows the
phases of the dual-slope conversion.
The dual-slope method has a fundamental limitation.
The count can only stop on a clock cycle, so that measurement accuracy is limited to the clock frequency. In addition,
a delay in the zero-crossing comparator can add to the
inaccuracy. Figure 10 shows these errors in an actual
measurement.
DEINTEGRATE
INTEGRATE
Measuring Techniques
Two important techniques are used in the TC7129:
successive integration and digital auto-zeroing. Successive
integration is a refinement to the traditional dual-slope
conversion technique.
ZERO
CROSSING
Dual-Slope Conversion
TIME
A dual-slope conversion has two basic phases: integrate and deintegrate. During the integrate phase, the input
signal is integrated for a fixed period of time; the integrated
voltage level is thus proportional to the input voltage. During
the deintegrate phase, the integrated voltage is ramped
down at a fixed slope, and a counter counts the clock cycles
until the integrator voltage crosses zero. The count is a
1
5 pF
40
120 kHz
Figure 9. Dual-Slope Conversion
Successive Integration
The successive integration technique picks up where
dual-slope conversion ends. The overshoot voltage shown
in Figure 10, called the "integrator residue voltage," is
measured to obtain a correction to the initial count. Figure 11
shows the cycles in a successive integration measurement.
The waveform shown is for a negative input signal. The
sequence of events during the measurement cycle is:
TC7129
Phase
Description
2
INT1
Input signal is integrated for fixed time. (1000 clock
cycles on 2V scale, 10,000 on 200 mV)
Integrator voltage is ramped to zero. Counter counts
up until zero crossing to produce reading accurate
to 3-1/2 digits. Residue represents an overshoot of
the actual input voltage.
Rest; circuit settles.
Residue voltage is amplified 10 times and inverted.
Integrator voltage is ramped to zero. Counter counts
down until zero crossing to correct reading to 4-1/2
digits. Residue represents an undershoot of the
actual input voltage.
Rest; circuit settles.
Residue voltage is amplified 10 times and inverted.
Integrator voltage is ramped to zero. Counter counts
up until zero crossing to correct reading to 5-1/2
digits. Residue is discarded.
270 kΩ
10 pF
DE1
V+
V+
REST
X10
DE2
TC7129
1
40
2
75 kΩ
51 pF
REST
X10
DE3
Figure 8. Oscillator Circuits
3-240
TELCOM SEMICONDUCTOR, INC.
4-1/2 DIGIT ANALOG-TO-DIGITAL
CONVERTER WITH ON-CHIP LCD DRIVERS
1
TC7129
2
DEINTEGRATE
INTEGRATE
OVERSHOOT DUE TO ZERO CROSSING
BETWEEN CLOCK PULSES
TIME
OVERSHOOT CAUSED BY
COMPARATOR DELAY OF
1 CLOCK PULSE
CLOCK PULSES
Figure 10.
ZERO
INTEGRATE
AND LATCH
3
INTEGRATOR RESIDUE VOLTAGE
INT1
INTEGRATE
4
Accuracy Errors in Dual-Slope Conversion
DE1
DEINTEGRATE
REST X10
DE2
REST
X10
DE3
ZERO INTEGRATE
5
TC7129
6
NOTE: Shaded area greatly expanded
in time and amplitude.
INTEGRATOR
RESIDUAL VOLTAGE
Figure 11. Integrator Waveform
Digital Auto-Zeroing
Inside the TC7129
To eliminate the effect of amplifier offset errors, the
TC7129 uses a digital auto-zeroing technique. After the
input voltage is measured as described above, the measurement is repeated with the inputs shorted internally. The
reading with inputs shorted is a measurement of the internal
errors and is subtracted from the previous reading to obtain
a corrected measurement. Digital auto-zeroing eliminates
the need for an external auto-zeroing capacitor used in other
ADCs.
Figure 12 shows a simplified block diagram of the
TC7129.
TELCOM SEMICONDUCTOR, INC.
7
Integrator Section
The integrator section includes the integrator, comparator, input buffer amplifier, and analog switches used to
change the circuit configuration during the separate measurement phases described earlier.
3-241
8
4-1/2 DIGIT ANALOG-TO-DIGITAL
CONVERTER WITH ON-CHIP LCD DRIVERS
TC7129
LOW BATTERY
SEGMENT DRIVES
CONTINUITY
BACKPLANE
DRIVES
ANNUNCIATOR
DRIVE
OSC1
LATCH, DECODE DISPLAY MULTIPLEXER
VDISP
OSC2
UP/DOWN RESULTS COUNTER
OSC3
SEQUENCE COUNTER/DECODER
CONTROL LOGIC
RANGE
L/H
CONT
DP1
DP2
UR/DP3
OR/DP4
V+
V–
ANALOG SECTION
REF HI
REF LO
DGND
INT OUT
TC7129
INT IN
COMMON
IN IN
HI LO
Figure 12.
3-242
BUFF
Functional Block Diagram
TELCOM SEMICONDUCTOR, INC.
4-1/2 DIGIT ANALOG-TO-DIGITAL
CONVERTER WITH ON-CHIP LCD DRIVERS
1
TC7129
CREF
REF HI
RINT
CINT
2
REF LO
DE
DE
INTEGRATOR
–
INT1
10
pF
–
+
IN HI
DE–
DE+
BUFFER
X10
COMPARATOR 1
+
–
100 pF
DE–
DE+
COMMON
INT
INT1, INT2
TO DIGITAL
SECTION
+
COMPARATOR 2
ZI, X10
3
REST
IN LO
–
+
V
200 mV
–
CONTINUITY
+
500 kΩ
Figure 13.
4
TC7129
CONTINUITY
COMPARATOR
TO DISPLAY DRIVER
Integrator Block Diagram
Table I. Switch Legends
Label
Meaning
DE
DE–
Open during all deintegrate phases.
Closed during all deintegrate phases when input
voltage is negative.
Closed during all deintegrate phases when input
voltage is positive.
Closed during the first integrate phase
(measurement of the input voltage).
Closed during the second integrate phase
(measurement of the amplifier offset).
Open during both integrate phases.
Closed during the rest phase.
Closed during the zero-integrate phase.
Closed during the X10 phase.
Open during the X10 phase.
DE+
INT1
INT2
INT
REST
ZI
X10
X10
5
–
+
IN HI
6
COM
TC7129
IN LO
–
200 mV
The buffer amplifier has a common-mode input voltage
range from 1.5V above V– to 1V below V+. The integrator
amplifier can swing to within 0.3V of the rails, although for
best linearity the swing is usually limited to within 1V. Both
amplifiers can supply up to 80 µA of output current, but
should be limited to 20 µA for good linearity.
Continuity Indicator
A comparator with a 200 mV threshold is connected
between IN HI (pin 33) and IN LO (pin 32). Whenever the
voltage between inputs is less than 200 mV, the
TELCOM SEMICONDUCTOR, INC.
BUFFER
V
+
500 kΩ
TO DISPLAY
DRIVER
(NOT LATCHED)
CONT
Figure 14.
7
Continuity Indicator Circuit
CONTINUITY output (pin 27) will be pulled HIGH, activating
the continuity annunciator on the display. The continuity
pin can also be used as an input to drive the continuity
annunciator directly from an external source. A schematic
of the input/output nature of this pin is shown in Figure 15.
3-243
8
4-1/2 DIGIT ANALOG-TO-DIGITAL
CONVERTER WITH ON-CHIP LCD DRIVERS
TC7129
Sequence and Results Counter
A sequence counter and associated control logic provide signals that operate the analog switches in the integrator section. The comparator output from the integrator gates
the results counter. The results counter is a six-section up/
down decade counter which holds the intermediate results
from each successive integration.
TC7129
'500 kΩ
DP4/OR, PIN 20
DP3/UR, PIN 21
LATCH/HOLD PIN 22
CONTINUITY, PIN 27
Overrange and Underrange Outputs
The common and digital ground (DGND) outputs are
generated from internal zener diodes. The voltage between
V+ and DGND is the internal supply voltage for the digital
section of the TC7129. Common can source approximately
12 µA; DGND has essentially no source capability.
When the results counter holds a value greater than
±19,999, the DP4/OR output (pin 20) is driven HIGH. When
the results counter value is less than ±1000, the DP3/UR
output (pin 21) is driven HIGH. Both signals are valid on the
falling edge of LATCH/HOLD (L/H) and do not change until
the end of the next conversion cycle. The signals are
updated at the end of each conversion unless the L/H input
(pin 22) is held HIGH. Pins 20 and 21 can also be used as
inputs for external control of decimal points 3 and 4. Figure
15 shows a schematic of the input/output nature of these
pins.
Low Battery
Latch/Hold
The low battery annunciator turns on when supply
voltage between V+ and V– drops below 6.8V. The internal
zener has a threshold of 6.3V. When the supply voltage
drops below 6.8V, the transistor tied to V– turns OFF, pulling
the "Low Battery" point HIGH. (See Figure 16.)
The L/H output goes LOW during the last 100 cycles of
each conversion. This pulse latches the conversion data into
the display driver section of the TC7129. This pin can also
be used as an input. When driven HIGH, the display will not
be updated; the previous reading is displayed. When driven
LOW, the display reading is not latched; the sequence
counter reading will be displayed. Since the counter is
counting much faster than the backplanes are being updated, the reading shown in this mode is somewhat erratic.
Figure 15.
Input/Output Pin Schematic
Common and Digital Ground
24
12 µA
V
+
3.2V
28
Display Driver
COM
–
5V
N
+
LOGIC
SECTION
36
P
DGND
N
TC7129
23
Figure 16.
3-244
V
–
Digital Ground (DGND) and Common Outputs
The TC7129 drives a triplexed LCD with three backplanes. The LCD can include decimal points, polarity sign,
and annunciators for continuity and low battery. Figure 17
shows the assignment of the display segments to the
backplanes and segment drive lines. The backplane drive
frequency is obtained by dividing the oscillator frequency by
1200. This results in a backplane drive frequency of 100 Hz
for 60 Hz operation (120 kHz crystal) and 83.3 Hz for 50 Hz
operation (100 kHz crystal).
Backplane waveforms are shown in Figure 18. These
appear on outputs BP1, BP2, BP3 (pins 16, 17, and 18). They
remain the same regardless of the segments being driven.
Other display output lines (pins 4 through 15) have
waveforms that vary depending on the displayed values.
Figure 19 shows a set of waveforms for the A, G, D outputs
(pins 5, 8, 11, and 14) for several combinations of "ON"
segments.
TELCOM SEMICONDUCTOR, INC.
4-1/2 DIGIT ANALOG-TO-DIGITAL
CONVERTER WITH ON-CHIP LCD DRIVERS
1
TC7129
LOW BATTERY
2
CONTINUITY
BP1
BP2
BACKPLANE
CONNECTIONS
3
BP3
LOW BATTERY
CONTINUITY
F4, E4, DP4
A4, G4, D4
B1, C1, CONTINUITY
B4, C4, BC4
F1, E1, DP1
A1, G1, D1
F3, E3, DP3
A3, G3, D3
B2, C2, LOW BATTERY
A2, G2, D2
B3, C3, MINUS
F2, E2, DP2
Figure 17.
5
Display Segment Assignments
VDD
VH
b SEGMENT
LINE
ALL OFF
BP1
BP2
a SEGMENT
ON
d, g OFF
BP3
a, g ON
d OFF
Figure 18.
4
VL
VDISP
VDD
VH
VL
VDISP
VDD
VH
VL
VDISP
TELCOM SEMICONDUCTOR, INC.
7
VDD
VH
Backplane Waveforms
The ANNUNCIATOR DRIVE output (pin 3) is a squarewave running at the backplane frequency (100 Hz or 83.3 Hz),
with a peak-to-peak voltage equal to DGND voltage. Connecting an annunciator to pin 3 turns it ON; connecting it to
its backplane turns it OFF.
6
ALL ON
VL
VDISP
Figure 19.
8
Typical Display Output Waveforms
3-245