TC7136ACKW713 [MICROCHIP]
1-CH DUAL-SLOPE ADC, PQFP44, PLASTIC, QFP-44;型号: | TC7136ACKW713 |
厂家: | MICROCHIP |
描述: | 1-CH DUAL-SLOPE ADC, PQFP44, PLASTIC, QFP-44 转换器 |
文件: | 总22页 (文件大小:288K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
Obsolete Device
TC7136/TC7136A
Low Power 3-1/2 Digit Analog-to-Digital Converter
Features
General Description
• Fast Over Range Recovery, Ensured First Reading
Accuracy
The TC7136 and TC7136A are low power, 3-1/2 digit
with liquid crystal display (LCD) drivers and analog-to-
digital converters. These devices incorporate an "inte-
grator output zero" phase, which enables over range
recovery. The performance of existing TC7126,
TC7126A and ICL7126 based systems may be
upgraded with minor changes to external, passive
components.
• Low Temperature Drift Internal Reference
- TC7136: 70ppm/°C (Typ.)
- TC7136A: 35ppm/°C (Typ.)
• Zero Reading with Zero Input
• Low Noise: 15μVP-P
• High Resolution: 0.05%
The TC7136A has an improved internal zener refer-
ence voltage circuit which maintains the analog com-
mon temperature drift to 35ppm/°C (typical) and
75ppm/°C (maximum). This represents an improve-
ment of two to four times over similar 3-1/2 digit con-
verters. The costly, space consuming external
reference source may be removed.
• Low Input Leakage Current: 1pA (Typ.)/10pA (Max.)
• Precision Null Detectors with True Polarity at Zero
• High-Impedance Differential Input
• Convenient 9V Battery Operation with Low Power
Dissipation: 500μW (Typ.)/900μW (Max.)
The TC7136 and TC7136A limit linearity error to less
than 1 count on 200mV or 2V full scale ranges. The roll-
over error (the difference in readings for equal magni-
tude, but opposite polarity input signals) is below ±1
count. High-impedance differential inputs offer 1pA
leakage currents and a 1012Ω input impedance. The
differential reference input allows ratiometric measure-
ments for ohms or bridge transducer measurements.
The 15μVP-P noise performance ensures a "rock solid"
reading. The auto-zero cycle enables a zero display
readout for a 0V input.
Applications
• Thermometry
• Bridge Readouts: Strain Gauges, Load Cells,
Null Detectors
• Digital Meters: Voltage/Current/Ohms/Power, pH
• Digital Scales, Process Monitors
• Portable Instrumentation
Device Selection Table
Temperature
Part Number
Package
Range
TC7136 CPI
TC7136 CKW
TC7136 CLW
TC7136A CPI
TC7136A CKW
TC7136A CLW
40-Pin PDIP
44-Pin PQFP
44-Pin PLCC
40-Pin PDIP
44-Pin PQFP
44-Pin PLCC
0°C to +70°C
0°C to +70°C
0°C to +70°C
0°C to +70°C
0°C to +70°C
0°C to +70°C
© 2005 Microchip Technology Inc.
DS21461C-page 1
TC7136/TC7136A
Package Type
44-Pin PLCC
44-Pin PQFP
6
5
4
3
2
1
44 43 42 41 40
44 43 42 41 40 39 38 37 36 35 34
33
32
31
30
29
28
27
26
25
24
23
1
2
3
4
NC
NC
NC
F
G
E
7
8
39
38
37
36
35
34
33
32
31
30
29
REF LO
1
G
2
C
+
1
REF
C
3
TEST
OSC3
NC
C
-
9
1
REF
ANALOG
COMMON
A
3
D
10
2
2
G
3
5
6
TC7136CLW
TC7136ACLW
C
11
12
13
14
15
16
17
IN HI
TC7136CKW
TC7136ACKW
BP
OSC2
OSC1
V+
NC
NC
POL
7
B
2
IN LO
AZ
AB
4
8
A
2
D
1
E
3
9
F
2
BUFF
INT
F
3
10
11
C
1
E
2
B
3
B
1
D
3
V-
25 26 27 28
18 19 20 21 22 23 24
19 20 21 22
12 13 14 15 16 17 18
40-Pin PDIP
40-Pin PDIP
OSC1
OSC2
1
2
40 OSC1
1
2
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
V+
V+
Normal Pin
Configuration
Reverse Pin
Configuration
D
1
D
1
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
OSC2
C
1
C
1
3
3
OSC3
TEST
OSC3
TEST
B
1
4
4
B
1
V
+
-
A
1
A
1
5
5
1's
V
V
+
-
REF
1's
REF
F
1
F
1
V
C
6
6
REF
REF
+
-
G
1
G
1
C
C
+
7
7
REF
REF
C
TC7136RCPL
TC7136ARCPL
E
1
E
1
-
8
8
REF
REF
TC7136CPL
TC7136ACPL
ANALOG
COMMON
ANALOG
COMMON
9
9
D
D
2
2
V
+
10
11
12
13
14
15
16
17
18
19
20
10
11
12
13
14
15
16
17
18
19
20
C
C
2
V
+
IN
2
IN
V
-
B
B
2
V
-
IN
2
IN
10's
10's
C
A
C
V
A
2
AZ
2
AZ
V
F
F
2
BUFF
2
BUFF
INT
V
E
E
2
V
INT
2
D
V-
G
V-
D
3
3
B
B
3
G
2
3
2
100's
100's
C
3
F
F
3
C
3
3
100's
100's
A
3
A
E
E
3
3
3
G
3
AB
AB
1000's
G
1000's
4
4
3
POL
(MINUS SIGN)
POL
(Minus Sign)
BP
(Backplane)
BP
(Backplane)
NC = No Internal Connection
DS21461C-page 2
© 2005 Microchip Technology Inc.
TC7136/TC7136A
Typical Application
0.1μF
33
34
C
LCD
+
C
-
REF
REF
1MΩ
31
9-19
22-25
Segment
Drive
+
V
+
IN
Analog
Input
–
TC7136
TC7136A
0.01μF
20
30
32
POL
BP
V
-
IN
Minus Sign
21
1
Backplane
ANALOG
COMMON
V+
28
V
240kΩ
BUFF
+
9V
0.47
180kΩ
0.15μF
36
μF
V
+
REF
29
10kΩ
C
AZ
35
26
V
-
REF
27
V
INT
V-
1 Conversion/Sec
OSC2 OSC3 OSC1
C
39
38
40
OSC
To Analog Common (Pin 32)
50pF
R
OSC
560kΩ
© 2005 Microchip Technology Inc.
DS21461C-page 3
TC7136/TC7136A
Functional Block Diagram
DS21461C-page 4
© 2005 Microchip Technology Inc.
TC7136/TC7136A
*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
operation sections of the specifications is not implied.
Exposure to Absolute Maximum Rating conditions for
extended periods may affect device reliability.
1.0
ELECTRICAL
CHARACTERISTICS
Absolute Maximum Ratings*
Supply Voltage (V+ to V-).......................................15V
Analog Input Voltage (Either Input) (Note 1)... V+ to V-
Reference Input Voltage (Either Input)............ V+ to V-
Clock Input.................................................TEST to V+
Package Power Dissipation (TA ≤ 70°C) (Note 2):
Plastic DIP ...................................................1.23W
Plastic Quad Flat Package ..........................1.00W
PLCC ...........................................................1.23W
Operating Temperature Range:
C Devices.......................................... 0°C to +70°C
I Devices ........................................-25°C to +85°C
Storage Temperature Range..............-65°C to +150°C
TC7136 AND TC7136A ELECTRICAL SPECIFICATIONS
Electrical Characteristics: V = 9V, f
= 16kHz, and T = +25°C, unless otherwise noted.
A
S
CLK
Symbol
Input
Parameter
Min
Typ
Max
Unit
Test Conditions
Zero Input Reading
-000.0
±000.0
+000.0
Digital
V
= 0V, Full Scale = 200mV
IN
Reading
Zero Reading Drift
—
0.2
1
μV/°C
V
V
= 0V, 0°C ≤ T ≤ +70°C
IN
A
Ratiometric Reading
999
999/1000
1000
Digital
= V , V
= 100mV
IN
REF REF
Reading
NL
Non-Linearity Error
—
1
±0.2
Count Full Scale = 20mV or 2V Max.
Deviation from best Straight Line
E
Rollover Error
Noise
-1
—
—
—
—
-1
15
1
±0.2
—
1 Count
V
V
V
V
V
- = V + ≈ 200mV
R
IN
IN
IN
IN
e
μV
= 0V, Full Scale = 200mV
= 0V
N
P-P
I
Input Leakage Current
10
—
pA
L
CMRR
Common Mode Rejection Ratio
50
1
μV/V
= ±1V, V = 0V, Full Scale = 200mV
CM
IN
TC
Scale Factor Temperature
Coefficient
5
ppm/°C
= 199mV, 0°C ≤ T ≤ +70°C
IN A
SF
Ext. Ref. Temp. Coeff. = 0ppm/°C
Note 1: Input voltages may exceed supply voltages when input current is limited to 100μA.
2: Dissipation rating assumes device is mounted with all leads soldered to PC board.
3: Refer to "Differential Input" discussion.
4: Backplane drive is in phase with segment drive for "OFF" segment and 180° out-of-phase for "ON" segment. Frequency
is 20 times conversion rate. Average DC component is less than 50mV.
5: See "Typical Application".
6: A 48kHz oscillator increases current by 20μA (typical). Common current not included.
© 2005 Microchip Technology Inc.
DS21461C-page 5
TC7136/TC7136A
TC7136 AND TC7136A ELECTRICAL SPECIFICATIONS (CONTINUED)
Electrical Characteristics: V = 9V, f
= 16kHz, and T = +25°C, unless otherwise noted.
A
S
CLK
Symbol
Parameter
Min
Typ
Max
Unit
Test Conditions
Analog Common
V
Analog Common Temperature
Coefficient
250kΩ between Common and V+
CTC
TC7136A
TC7136
—
—
35
70
75
ppm/°C 0°C ≤ T ≤ +70°C
A
150
100
150
3.35
ppm/°C "C" Commercial Temp. Range Devices
TC7136A
—
35
ppm/°C -25°C ≤ T ≤ +85°C
A
TC7136
—
70
ppm/°C "I" Industrial Temp. Range Devices
V
Analog Common Voltage
2.7
3.05
V
250kΩ Between Common and V+
C
LCD Drive
V
V
LCD Segment Drive Voltage
LCD Backplane Drive Voltage
4
4
5
5
6
6
V
V
V+ to V- = 9V
V+ to V- = 9V
SD
P-P
BD
P-P
Power Supply
Power Supply Current
I
—
70
100
μA
V
= 0V, V+ to V- = 9V (Note 6)
S
IN
Note 1: Input voltages may exceed supply voltages when input current is limited to 100μA.
2: Dissipation rating assumes device is mounted with all leads soldered to PC board.
3: Refer to "Differential Input" discussion.
4: Backplane drive is in phase with segment drive for "OFF" segment and 180° out-of-phase for "ON" segment. Frequency
is 20 times conversion rate. Average DC component is less than 50mV.
5: See "Typical Application".
6: A 48kHz oscillator increases current by 20μA (typical). Common current not included.
DS21461C-page 6
© 2005 Microchip Technology Inc.
TC7136/TC7136A
2.0
PIN DESCRIPTIONS
The descriptions of the pins are listed in Table 2-1.
TABLE 2-1:
PIN DESCRIPTION
Pin Number
(40-Pin PDIP)
Normal
(Reverse)
Symbol
Description
1
(40)
(39)
(38)
(37)
(36)
(35)
(34)
(33)
(32)
(31)
(30)
(29)
(28)
(27)
(26)
(25)
(24)
(23)
(22)
(21)
(20)
(19)
(18)
(17)
(16)
(15)
(14)
V+
Positive supply voltage.
2
D
C
B
A
Activates the D section of the units display.
Activates the C section of the units display.
Activates the B section of the units display.
Activates the A section of the units display.
Activates the F section of the units display.
Activates the G section of the units display.
Activates the E section of the units display.
Activates the D section of the tens display.
Activates the C section of the tens display.
Activates the B section of the tens display.
Activates the A section of the tens display.
Activates the F section of the tens display.
Activates the E section of the tens display.
Activates the D section of the hundreds display.
Activates the B section of the hundreds display.
Activates the F section of the hundreds display.
Activates the E section of the hundreds display.
Activates both halves of the 1 in the thousands display.
Activates the negative polarity display.
1
1
1
1
1
3
4
5
6
F
7
G
1
1
2
2
2
2
2
2
8
E
D
C
B
A
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
F
E
D
B
3
3
3
3
F
E
AB
4
POL
BP
Backplane drive output.
G
Activates the G section of the hundreds display.
Activates the A section of the hundreds display.
Activates the C section of the hundreds display.
Activates the G section of the tens display.
Negative power supply voltage.
3
3
3
A
C
G
2
V-
V
The integrating capacitor should be selected to give the maximum voltage swing
that ensures component tolerance buildup will not allow the integrator output to sat-
urate. When analog common is used as a reference and the conversion rate is 3
readings per second, a 0.047μF capacitor may be used. The capacitor must have a
low dielectric constant to prevent rollover errors. See Section 6.3, Integrating
Capacitor for additional details.
INT
28
29
(13)
(12)
V
Integration resistor connection. Use a 180kΩ for a 20mV full scale range and a
1.8MΩ for 2V full scale range.
BUFF
C
The size of the auto-zero capacitor influences the system noise. Use a 0.47μF
capacitor for a 200mV full scale and a 0.1μF capacitor for a 2V full scale.
See Section 6.1, Auto-Zero Capacitor for more details.
AZ
30
31
32
(11)
(10)
(9)
V
-
The low input signal is connected to this pin.
IN
V
+
The high input signal is connected to this pin.
IN
ANALOG
This pin is primarily used to set the Analog Common mode voltage for battery
COMMON operation, or in systems where the input signal is referenced to the power supply.
See Section 7.3, Analog Common for more details. It also acts as a reference
voltage source.
33
(8)
C
-
See Pin 34.
REF
© 2005 Microchip Technology Inc.
DS21461C-page 7
TC7136/TC7136A
TABLE 2-1:
PIN DESCRIPTION (CONTINUED)
Pin Number
(40-Pin PDIP)
Normal
(Reverse)
Symbol
Description
34
(7)
C
+
A 0.1μF capacitor is used in most applications. If a large Common mode voltage
REF
exists (for example, the V - pin is not at analog common) and a 200mV scale is
IN
used, a 1μF capacitor is recommended, which will hold the rollover error to
0.5 count.
35
(6)
(5)
V
-
See Pin 36.
REF
V
+
The analog input required to generate a full scale output (1999 counts). Place
100mV between Pins 35 and 36 for 199.9mV full scale. Place 1V between Pins 35
and 36 for 2V full scale. See Section 6.6, Reference Voltage.
REF
36
(4)
TEST
Lamp test. When pulled HIGH (to V+), all segments will be turned ON and the
display should read -1888. It may also be used as a negative supply for externally
generated decimal points. See Section 7.4, Test for additional information.
37
38
39
(3)
(2)
(1)
OSC3
OSC2
OSC1
See Pin 40.
See Pin 40.
Pins 40, 39 and 38 make up the oscillator section. For a 48kHz clock
(3 readings per second), connect Pin 40 to the junction of a 180kΩ resistor and a
50pF capacitor. The 180kΩ resistor is tied to Pin 39 and the 50pF capacitor is tied
to Pin 38.
DS21461C-page 8
© 2005 Microchip Technology Inc.
TC7136/TC7136A
FIGURE 3-1:
BASIC DUAL SLOPE
CONVERTER
3.0
DETAILED DESCRIPTION
(All Pin Designations Refer to 40-Pin PDIP.)
C
INT
3.1
Dual Slope Conversion Principles
Analog Input
Signal
Integrator
–
The TC7136/A is a dual slope, integrating analog-to-
digital converter. An understanding of the dual slope
conversion technique will aid in following detailed
TC7136/A operational theory.
Comparator
–
+
+
Switch
Driver
The conventional dual slope converter measurement
cycle has two distinct phases (see Figure 3-1).
Clock
Phase
Control
REF
Voltage
Control
Logic
1. Input signal integration
Polarity Control
Display
2. Reference voltage integration (de-integration)
The input signal being converted is integrated for a
fixed time period (tSI), measured by counting clock
pulses. An opposite polarity constant reference voltage
is then integrated until the integrator output voltage
returns to zero. The reference integration time is
directly proportional to the input signal (tRI).
Counter
V
≈ V
IN
IN
REF
≈ 1/2 V
V
REF
Fixed Variable
Signal Reference
Integrate Integrate
Time Time
In a simple dual slope converter, a complete conver-
sion requires the integrator output to "ramp up" and
"ramp down."
FIGURE 3-2:
NORMAL MODE
REJECTION OF DUAL
SLOPE CONVERTER
A simple mathematical equation relates the input
signal, reference voltage, and integration time:
EQUATION 3-1:
30
20
10
0
t
V t
R RI
SI
1
RC
--------
V
(t)dt = ------------
RC
∫
0
IN
Where:
VR = Reference voltage
tSI = Signal integration time (fixed)
tRI = Reference voltage integration time
(variable)
t = Measured Period
For a constant VIN:
EQUATION 3-2:
0.1/t
1/t
10/t
Input Frequency
t
RI
-------
V
= V
R
IN
t
The dual slope converter accuracy is unrelated to the
integrating resistor and capacitor values, as long as
they are stable during a measurement cycle. Noise
immunity is an inherent benefit. Noise spikes are inte-
grated or averaged to zero during integration periods.
Integrating ADCs are immune to the large conversion
errors that plague successive approximation convert-
ers in high noise environments. Interfering signals with
frequency components at multiples of the averaging
period will be attenuated. Integrating ADCs commonly
operate with the signal integration period set to a
multiple of the 50Hz/60Hz power line period.
SI
© 2005 Microchip Technology Inc.
DS21461C-page 9
TC7136/TC7136A
The differential input voltage must be within the device
Common mode range when the converter and mea-
sured system share the same power supply common
(ground). If the converter and measured system do not
share the same power supply common, VIN- should be
tied to analog common.
4.0
ANALOG SECTION
In addition to the basic integrate and de-integrate dual
slope cycles discussed above, the TC7136 and
TC7136A designs incorporate an "integrator output
zero cycle" and an "auto-zero cycle." These additional
cycles ensure the integrator starts at 0V (even after a
severe over range conversion) and that all offset volt-
age errors (buffer amplifier, integrator and comparator)
are removed from the conversion. A true digital zero
reading is assured without any external adjustments.
Polarity is determined at the end of signal integrate
phase. The sign bit is a true polarity indication, in that
signals less than 1LSB are correctly determined. This
allows precision null detection, limited only by device
noise and auto-zero residual offsets.
A complete conversion consists of four distinct phases:
4.4
Reference Integrate Phase
1. Integrator output zero phase
2. Auto-zero phase
The third phase is reference integrate or de-integrate.
VIN- is internally connected to analog common and
VIN+ is connected across the previously charged refer-
ence capacitor. Circuitry within the chip ensures that
the capacitor will be connected with the correct polarity
to cause the integrator output to return to zero. The
time required for the output to return to zero is propor-
tional to the input signal and is between 0 and 2000
internal clock periods. The digital reading displayed is:
3. Signal integrate phase
4. Reference de-integrate phase
4.1
Integrator Output Zero Phase
This phase ensures the integrator output is at 0V
before the system zero phase is entered. This ensures
that true system offset voltages will be compensated
for, even after an over range conversion. The count for
this phase is a function of the number of counts
required by the de-integrate phase. The count lasts
from 11 to 140 counts for non over range conversions
and from 31 to 640 counts for over range conversions.
EQUATION 4-2:
V
IN
1000 = ----------------
V
REF
4.2
Auto-Zero Phase
FIGURE 4-1:
CONVERSION TIMING
DURING NORMAL
OPERATION
During the auto-zero phase, the differential input signal
is disconnected from the circuit by opening internal
analog gates. The internal nodes are shorted to analog
common (ground) to establish a zero input condition.
Additional analog gates close a feedback loop around
the integrator and comparator. This loop permits com-
parator offset voltage error compensation. The voltage
level established on CAZ compensates for device offset
voltages. The auto-zero phase residual is typically
10μV to 15μV.
1000
INT
1-2000
DENT
11-140
ZI
AZ
910-2900
4000
The auto-zero duration is from 910 to 2900 counts for
non over range conversions and from 300 to 910
counts for over range conversions.
FIGURE 4-2:
CONVERSION TIMING
DURING OVER RANGE
OPERATION
4.3
Signal Integration Phase
The auto-zero loop is entered and the internal differen-
tial inputs connect to VIN+ and VIN-. The differential
input signal is integrated for a fixed time period. The
TC7136/A signal integration period is 1000 clock peri-
ods or counts. The externally set clock frequency is
divided by four before clocking the internal counters.
The integration time period is:
1000
INT
2001-2090
31-640
DEINT
EQUATION 4-1:
ZI
AZ
4
300-910
4000
tSI
=
x 1000
FOSC
Where FOSC = external clock frequency.
DS21461C-page 10
© 2005 Microchip Technology Inc.
TC7136/TC7136A
Each phase of the measurement cycle has the
following length:
5.0
DIGITAL SECTION
The TC7136/A contains all the segment drivers neces-
sary to directly drive a 3-1/2 digit LCD. An LCD back-
plane driver is included. The backplane frequency is
the external clock frequency divided by 800. For three
conversions per second, the backplane frequency is
60Hz with a 5V nominal amplitude. When a segment
driver is in phase with the backplane signal, the seg-
ment is OFF. An out-of-phase segment drive signal
causes the segment to be ON, or visible. This AC drive
configuration results in negligible DC voltage across
each LCD segment, ensuring long LCD life. The polar-
ity segment driver is ON for negative analog inputs. If
VIN+ and VIN- are reversed, this indicator would
reverse.
1. Auto-zero phase: 3000 to 2900 counts
(1200 to 11,600 clock pulses)
2. Signal integrate: 1000 counts
(4000 clock pulses)
This time period is fixed. The integration period is:
EQUATION 5-1:
Where:
1
⎛
⎝
⎞
⎠
tSI = 4000
F
OSC
FOSC is the externally set clock frequency.
3. Reference integrate: 0 to 2000 counts
4. Zero integrator: 11 to 640 counts
On the TC7136/A, when the TEST pin is pulled to V+,
all segments are turned ON. The display reads -1888.
During this mode, the LCD segments have a constant
DC voltage impressed.
The TC7136 is a drop-in replacement for the TC7126
and ICL7126. The TC7136A offers a greatly improved
internal reference temperature coefficient. Minor com-
ponent value changes are required to upgrade existing
designs and improve the noise performance.
Note: Do not leave the display in this mode for
more than several minutes. LCDs may be
destroyed if operated with DC levels for
extended periods.
6.0
COMPONENT VALUE
SELECTION
The display font and segment drive assignment are
shown in Figure 5-1.
6.1
Auto-Zero Capacitor (C
)
AZ
FIGURE 5-1:
DISPLAY FONT AND
The CAZ capacitor size has some influence on system
noise. A 0.47μF capacitor is recommended for 200mV
full scale applications, where 1LSB is 100μV. A 0.1μF
capacitor is adequate for 2V full scale applications. A
Mylar type dielectric capacitor is adequate.
SEGMENT ASSIGNMENT
Display Font
1000's
100's
10's
1's
6.2
Reference Voltage Capacitor
(C
)
REF
The reference voltage, used to ramp the integrator out-
put voltage back to zero during the reference integrate
phase, is stored on CREF. A 0.1μF capacitor is accept-
able when VREF- is tied to analog common. If a large
Common mode voltage exists (VREF- ≠ analog com-
mon) and the application requires a 200mV full scale,
increase CREF to 1μF. Rollover error will be held to less
than 0.5 count. A Mylar type dielectric capacitor is
adequate.
5.1
System Timing
The oscillator frequency is divided by 4 prior to clocking
the internal decade counters. The four-phase mea-
surement cycle takes a total of 4000 counts, or 16,000
clock pulses. The 4000 count cycle is independent of
input signal magnitude.
6.3
Integrating Capacitor (CINT)
CINT should be selected to maximize integrator output
voltage swing without causing output saturation. Ana-
log common will normally supply the differential voltage
reference in this case, a ±2V full scale integrator output
swing is satisfactory. For 3 readings per second
(FOSC = 48kHz), a 0.047μF value is suggested. For
one reading per second, 0.15μF is recommended. If a
different oscillator frequency is used, CINT must be
changed in inverse proportion to maintain the nominal
±2V integrator swing.
© 2005 Microchip Technology Inc.
DS21461C-page 11
TC7136/TC7136A
An exact expression for CINT is:
6.5
Oscillator Components
EQUATION 6-1:
COSC should be 50pF. ROSC is selected from the
equation:
VFS
1
⎛
⎝
⎞ ⎛
⎞
⎠
(4000)
F
R
EQUATION 6-2:
OSC ⎠ ⎝
VINT
INT
CINT
=
0.45
RC
FOSC
=
Where:
FOSC =Clock frequency at Pin 38
VFS =Full scale input voltage
RINT = Integrating resistor
Note that FOSC is ÷ 4 to generate the TC7136A's inter-
nal clock. The backplane drive signal is derived by
dividing FOSC by 800.
To achieve maximum rejection of 60Hz noise pickup,
the signal integrate period should be a multiple of
60Hz. Oscillator frequencies of 240kHz, 120kHz,
80kHz, 60kHz, 40kHz, etc. should be selected. For
50Hz rejection, oscillator frequencies of 200kHz,
100kHz, 66-2/3kHz, 50kHz, 40kHz, etc. would be suit-
able. Note that 40kHz (2.5 readings per second) will
reject both 50Hz and 60Hz.
VINT = Desired full scale integrator output swing
CINT must have low dielectric absorption to minimize
rollover error.
recommended.
A
polypropylene capacitor is
6.4
Integrating Resistor (R
)
INT
The input buffer amplifier and integrator are designed
with Class A output stages. The output stage idling cur-
rent is 6μA. The integrator and buffer can supply 1μA
drive currents with negligible linearity errors. RINT is
chosen to remain in the output stage linear drive
region, but not so large that PC board leakage currents
induce errors. For a 200mV full scale, RINT is 180kΩ. A
2V full scale requires 1.8MΩ (see Table 6-1).
6.6
Reference Voltage Selection
A full scale reading (2000 counts) requires the input
signal be twice the reference voltage.
Required Full Scale Voltage*
VREF
200mV
2V
100mV
1V
Note:
*V
= 2V
TABLE 6-1:
REF REF.
In some applications, a scale factor other than unity
may exist between a transducer output voltage and the
required digital reading. Assume, for example, a pres-
sure transducer output for 2000 lb/in2 is 400mV. Rather
than dividing the input voltage by two, the reference
voltage should be set to 200mV. This permits the trans-
ducer input to be used directly. The differential refer-
ence can also be used when a digital zero reading is
required, when VIN is not equal to zero. This is common
in temperature measuring instrumentation. A compen-
sating offset voltage can be applied between analog
common and VIN-. The transducer output is connected
between VIN+ and analog common.
Nominal Full Scale Voltage
Component
Value
200mV
2V
CAZ
RINT
CINT
0.47μF
180kΩ
0.047μF
0.1μF
1.8MΩ
0.047μF
Note:
F
= 48kHz (3 reading per sec).
OSC
R
= 180kΩ, C
= 50pF.
OSC
OSC
DS21461C-page 12
© 2005 Microchip Technology Inc.
TC7136/TC7136A
V+ – 1V to V- + 1V. Common mode voltages are
removed from the system when the TC7136A operates
from a battery or floating power source (isolated from
measured system), Common mode voltage removed
in battery operation with VIN = analog common and VIN-
7.0
7.1
DEVICE PIN FUNCTIONAL
DESCRIPTION
Differential Signal Inputs
V + (Pin 31), V - (Pin 30)
IN
IN
is connected to analog common (VCOM
Figure 7-1).
) (see
The TC7136/A is designed with true differential inputs
and accepts input signals within the input stage Com-
mon mode voltage range (VCM). The typical range is
FIGURE 7-1:
COMMON MODE VOLTAGE REMOVED IN BATTERY OPERATION WITH
V
IN = ANALOG COMMON
Segment
Drive
LCD
Measured
System
V
C
V
INT
POL BP
BUF
AZ
OSC1
V+
TC7136
V+
OSC3
V-
TC7136A
V-
OSC2
V-
GND
ANALOG
COMMON
V
- V
+
REF REF
V+
V+
V-
GND
Power
Source
+
9V
In systems where Common mode voltages exist, the
86dB Common mode rejection ratio minimizes error.
Common mode voltages do, however, affect the inte-
grator output level. A worst case condition exists if a
large positive VCM exists in conjunction with a full scale
negative differential signal. The negative signal drives
the integrator output positive along with VCM (see
Figure 7-2.) For such applications, the integrator out-
put swing can be reduced below the recommended 2V
full scale swing. The integrator output will swing within
0.3V of V+ or V- without increased linearity error.
7.2
Differential Reference
+ (Pin 36), V - (Pin 35)
V
REF
REF
The reference voltage can be generated anywhere
within the V+ to V- power supply range.
To prevent rollover type errors being induced by large
Common mode voltages, CREF should be large com-
pared to stray node capacitance. The TC7136/A offers
a significantly improved analog common temperature
coefficient. This potential provides a very stable volt-
age, suitable for use as a voltage reference. The
temperature coefficient of analog common is typically
35ppm/°C.
FIGURE 7-2:
COMMON MODE
VOLTAGE REDUCES
AVAILABLEINTEGRATOR
7.3
Analog Common (Pin 32)
SWING (V
≠ V )
COM
IN
The analog common pin is set at a voltage potential
approximately 3V below V+. The potential is between
2.7V and 3.35V below V+. Analog common is tied inter-
nally to an N-channel FET, capable of sinking 100μA.
This FET will hold the common line at 3V below V+ if an
external load attempts to pull the common line toward
V+. Analog common source current is limited to 1μA.
Analog common is, therefore, easily pulled to a more
negative voltage (i.e., below V+ – 3V).
C
I
Input Buffer
R
=
+
+
–
I
–
+
V
I
V
IN
Integrator
–
t
I
V
V
CM
= V
IN [
I
[
V
C
I
CM
Where:
4000
t = Integration time
=
I
F
OSC
C = Integration capacitor
I
R = Integration resistor
I
© 2005 Microchip Technology Inc.
DS21461C-page 13
TC7136/TC7136A
The TC7136/A connects the internal VIN+ and VIN-
inputs to analog common during the auto-zero phase.
During the reference integrate phase, VIN-is connected
to analog common. If VIN- is not externally connected to
analog common, a Common mode voltage exists, but
is rejected by the converter's 86dB Common mode
rejection ratio. In battery operation, analog common
and VIN- are usually connected, removing Common
mode voltage concerns. In systems where VIN- is con-
nected to the power supply ground or to a given
voltage, analog common should be connected to VIN-.
FIGURE 7-3:
ANALOG COMMON
TEMPERATURE
COEFFICIENT
200
180
No Maximum
Specified
160
140
120
100
Maximum
Typical
The analog common pin serves to set the analog sec-
tion reference, or common point. The TC7136A is spe-
cifically designed to operate from a battery, or in any
measurement system where input signals are not refer-
enced (float), with respect to the TC7136A power
source. The analog common potential of V+ – 3V gives
a 7V end of battery life voltage. The common potential
has a 0.001%/% voltage coefficient.
Maximum
80
60
40
20
Typical
Typical
TC7136A
TC7136
ICL7136
0
With sufficiently high total supply voltage
(V+ – V- > 7V), analog common is a very stable poten-
tial with excellent temperature stability (typically
35ppm/°C for TC7136A. This potential can be used to
generate the TC7136A's reference voltage. An external
voltage reference will be unnecessary in most cases,
because of the 35ppm/°C temperature coefficient. See
Section 7.5, TC7136A Internal Voltage Reference
discussion.
FIGURE 7-4:
TC7136A INTERNAL
VOLTAGE REFERENCE
CONNECTION
9V
+
26
1
240kΩ
10kΩ
V-
V+
7.4
TEST (Pin 37)
TC7136
TC7136A
The TEST pin potential is 5V less than V+. TEST may
be used as the negative power supply connection for
external CMOS logic. The TEST pin is tied to the inter-
nally generated negative logic supply through a 500Ω
resistor. The TEST pin load should not be more than
1mA. See Section 8.0, Typical Applications for addi-
tional information on using TEST as a negative digital
logic supply.
36
V
+
REF
V
REF
35
V
-
REF
32
ANALOG
COMMON
= 1/2 V
Set V
REF
REF
If TEST is pulled high (to V+), all segments plus the
minus sign will be activated. DO NOT OPERATE IN
THIS MODE FOR MORE THAN SEVERAL MINUTES.
With TEST = V+, the LCD segments are impressed with
a DC voltage which will destroy the LCD.
7.5
TC7136A Internal Voltage
Reference
The TC7136 analog common voltage temperature sta-
bility has been significantly improved (Figure 7-3). The
"A" version of the industry standard TC7136 device
allows users to upgrade old systems and design new
systems without external voltage references. External
R and C values do not need to be changed; however,
noise performance will be improved by increasing CAZ
(see Section 6.1, Auto-Zero Capacitor). Figure 7-4
shows analog common supplying the necessary
voltage reference for the TC7136/A.
DS21461C-page 14
© 2005 Microchip Technology Inc.
TC7136/TC7136A
The unknown resistance is put in series with a known
standard and a current passed through the pair. The
voltage developed across the unknown is applied to the
input and the voltage across the known resistor applied
to the reference input. If the unknown equals the stan-
dard, the display will read 1000. The displayed reading
can be determined from the following expression:
8.0
8.1
TYPICAL APPLICATIONS
Liquid Crystal Display Sources
Several manufacturers supply standard LCDs to inter-
face with the TC7136A 3-1/2 digit analog-to-digital
converter.
Representative
Part Numbers*
EQUATION 8-1:
Manufac.
Address/Phone
RUNKNOWN
Displayed(Reading) =
x 1000
Crystaloid
Electronics
5282 Hudson Dr.
Hudson, OH 44236
216-655-2429
C5335, H5535,
T5135, SX440
RSTANDARD
The display will over range for:
RUNKNOWN ≥ 2 x RSTANDARD
AND
720 Palomar Ave.
Sunnyvale, CA 94086 FE 0203, 0701
408-523-8200 FE 2201
FE 0201, 0501
VGI, Inc.
1800 Vernon St. Ste.2, I1048, I1126
Roseville,
CA 95678
FIGURE 8-1:
DECIMAL POINT AND
ANNUNCIATOR DRIVES
916-783-7878
Simple Inverter for Fixed Decimal Point
or Display Annunciator
Hamlin, Inc. 612 E. Lake St.
Lake Mills,
3902, 3933, 3903
V+
WI 53551
414-648-236100
V+
TC7136
TC7136A
4049
Note:
Contact LCD manufacturer for full product listing/
specifications.
To LCD
Decimal Point
21
37
BP
8.2
Decimal Point and Annunciator
Drive
GND
TEST
The TEST pin is connected to the internally generated
digital logic supply ground through a 500Ω resistor. The
TEST pin may be used as the negative supply for exter-
nal CMOS gate segment drivers. LCD annunciators for
decimal points, low battery indication, or function indi-
cation may be added without adding an additional sup-
ply. No more than 1mA should be supplied by the TEST
pin; its potential is approximately 5V below V+.
To LCD Backplane
Multiple Decimal Point or
Annunciator Driver
V+
V+
BP
TC7136
TC7136A
To LCD
Decimal Point
Decimal
Point
Select
8.3
Ratiometric Resistance
Measurements
The TC7136A's true differential input and differential
reference make ratiometric readings possible. In ratio-
metric operation, an unknown resistance is measured
with respect to a known standard resistance. No
accurately defined reference voltage is needed.
4030
GND
TEST
© 2005 Microchip Technology Inc.
DS21461C-page 15
TC7136/TC7136A
FIGURE 8-2:
LOW PARTS COUNT
RATIOMETRIC
RESISTANCE
FIGURE 8-4:
POSITIVE TEMPERATURE
COEFFICIENT RESISTOR
TEMPERATURE SENSOR
MEASUREMENT
9V
+
V+
V
V
+
-
5.6kΩ
160kΩ
REF
R
V+
V-
REF
STANDARD
R
20kΩ
V
IN
-
1
1N4148
LCD
V
+
IN
V
+
TC7136
IN
R
UNKNOWN
TC7136A
TC7136
TC7136A
0.7%/°C
R
20kΩ
2
R
3
V
-
V
V
+
PTC
IN
REF
ANALOG
COMMON
-
REF
COMMON
FIGURE 8-3:
TEMPERATURE SENSOR
+
9V
160kΩ
300kΩ
300kΩ
V+
V-
V
IN
-
R
50kΩ
1N4148
Sensor
1
V
+
IN
TC7136
TC7136A
REF
R
50kΩ
2
V
V
+
-
REF
COMMON
DS21461C-page 16
© 2005 Microchip Technology Inc.
TC7136/TC7136A
9.0
9.1
PACKAGING INFORMATION
Package Marking Information
Package marking data not available at this time.
9.2
Taping Form
Component Taping Orientation for 44-Pin PQFP Devices
User Direction of Feed
PIN 1
W
P
Standard Reel Component Orientation
for TR Suffix Device
Carrier Tape, Number of Components Per Reel and Reel Size
Package
Carrier Width (W)
Pitch (P)
Part Per Full Reel
Reel Size
44-Pin PQFP
24 mm
16 mm
500
13 in
Note: Drawing does not represent total number of pins.
Component Taping Orientation for 44-Pin PLCC Devices
User Direction of Feed
PIN 1
W
P
Standard Reel Component Orientation
for TR Suffix Device
Carrier Tape, Number of Components Per Reel and Reel Size
Package
Carrier Width (W)
Pitch (P)
Part Per Full Reel
Reel Size
44-Pin PLCC
32 mm
24 mm
500
13 in
Note: Drawing does not represent total number of pins.
© 2005 Microchip Technology Inc.
DS21461C-page 17
TC7136/TC7136A
9.3
Package Dimensions
40-Pin PDIP (Wide)
PIN 1
.555 (14.10)
.530 (13.46)
2.065 (52.45)
2.027 (51.49)
.610 (15.49)
.590 (14.99)
.200 (5.08)
.140 (3.56)
.040 (1.02)
.020 (0.51)
.015 (0.38)
.008 (0.20)
.150 (3.81)
.115 (2.92)
3° MIN.
.700 (17.78)
.610 (15.50)
.110 (2.79)
.090 (2.29)
.070 (1.78)
.045 (1.14)
.022 (0.56)
.015 (0.38)
Dimensions: inches (mm)
Component Taping Orientation for 44-Pin PLCC Devices
User Direction of Feed
PIN 1
W
P
Standard Reel Component Orientation
for TR Suffix Device
Carrier Tape, Number of Components Per Reel and Reel Size
Package
Carrier Width (W)
Pitch (P)
Part Per Full Reel
Reel Size
44-Pin PLCC
32 mm
24 mm
500
13 in
Note: Drawing does not represent total number of pins.
Dimensions: inches (mm)
DS21461C-page 18
© 2005 Microchip Technology Inc.
TC7136/TC7136A
9.3
Package Dimensions (Continued)
44-Pin PQFP
7° MAX.
.009 (0.23)
.005 (0.13)
PIN 1
.041 (1.03)
.026 (0.65)
.018 (0.45)
.012 (0.30)
.398 (10.10)
.390 (9.90)
.557 (14.15)
.537 (13.65)
.031 (0.80) TYP.
.010 (0.25) TYP.
.398 (10.10)
.390 (9.90)
.083 (2.10)
.075 (1.90)
.557 (14.15)
.537 (13.65)
.096 (2.45) MAX.
Dimensions: inches (mm)
© 2005 Microchip Technology Inc.
DS21461C-page 19
TC7136/TC7136A
SALES AND SUPPORT
Data Sheets
Products supported by a preliminary Data Sheet may have an errata sheet describing minor operational differences and recom-
mended workarounds. To determine if an errata sheet exists for a particular device, please contact one of the following:
1. Your local Microchip sales office
2. The Microchip Corporate Literature Center U.S. FAX: (480) 792-7277
3. The Microchip Worldwide Site (www.microchip.com)
Please specify which device, revision of silicon and Data Sheet (include Literature #) you are using.
New Customer Notification System
Register on our web site (www.microchip.com/cn) to receive the most current information on our products.
DS21461C-page 20
© 2005 Microchip Technology Inc.
Note the following details of the code protection feature on Microchip devices:
•
Microchip products meet the specification contained in their particular Microchip Data Sheet.
•
Microchip believes that its family of products is one of the most secure families of its kind on the market today, when used in the
intended manner and under normal conditions.
•
There are dishonest and possibly illegal methods used to breach the code protection feature. All of these methods, to our
knowledge, require using the Microchip products in a manner outside the operating specifications contained in Microchip’s Data
Sheets. Most likely, the person doing so is engaged in theft of intellectual property.
•
•
Microchip is willing to work with the customer who is concerned about the integrity of their code.
Neither Microchip nor any other semiconductor manufacturer can guarantee the security of their code. Code protection does not
mean that we are guaranteeing the product as “unbreakable.”
Code protection is constantly evolving. We at Microchip are committed to continuously improving the code protection features of our
products. Attempts to break Microchip’s code protection feature may be a violation of the Digital Millennium Copyright Act. If such acts
allow unauthorized access to your software or other copyrighted work, you may have a right to sue for relief under that Act.
Information contained in this publication regarding device
applications and the like is provided only for your convenience
and may be superseded by updates. It is your responsibility to
ensure that your application meets with your specifications.
MICROCHIP MAKES NO REPRESENTATIONS OR WAR-
RANTIES OF ANY KIND WHETHER EXPRESS OR IMPLIED,
WRITTEN OR ORAL, STATUTORY OR OTHERWISE,
RELATED TO THE INFORMATION, INCLUDING BUT NOT
LIMITED TO ITS CONDITION, QUALITY, PERFORMANCE,
MERCHANTABILITY OR FITNESS FOR PURPOSE.
Microchip disclaims all liability arising from this information and
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life support systems is not authorized except with express
written approval by Microchip. No licenses are conveyed,
implicitly or otherwise, under any Microchip intellectual property
rights.
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The Microchip name and logo, the Microchip logo, Accuron,
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PRO MATE, PowerSmart, rfPIC, and SmartShunt are
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© 2005, Microchip Technology Incorporated, Printed in the
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devices, Serial EEPROMs, microperipherals, nonvolatile memory and
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and manufacture of development systems is ISO 9001:2000 certified.
© 2005 Microchip Technology Inc.
DS21461C-page 21
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Fax: 65-6334-8850
China - Shunde
Tel: 86-757-2839-5507
Fax: 86-757-2839-5571
Kokomo
Kokomo, IN
Tel: 765-864-8360
Fax: 765-864-8387
Taiwan - Hsin Chu
Tel: 886-3-572-9526
Fax: 886-3-572-6459
China - Wuhan
Tel: 86-27-5980-5300
Fax: 86-27-5980-5118
Taiwan - Kaohsiung
Tel: 886-7-536-4818
Fax: 886-7-536-4803
Los Angeles
Mission Viejo, CA
Tel: 949-462-9523
Fax: 949-462-9608
China - Xian
Tel: 86-29-8833-7250
Fax: 86-29-8833-7256
Taiwan - Taipei
Tel: 886-2-2500-6610
Fax: 886-2-2508-0102
San Jose
Mountain View, CA
Tel: 650-215-1444
Fax: 650-961-0286
Thailand - Bangkok
Tel: 66-2-694-1351
Fax: 66-2-694-1350
Toronto
Mississauga, Ontario,
Canada
Tel: 905-673-0699
Fax: 905-673-6509
10/31/05
DS21461C-page 22
© 2005 Microchip Technology Inc.
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