TELCOM TC9401CPD

TC9400
TC9401
TC9402
VOLTAGE-TO-FREQUENCY/FREQUENCY-TO-VOLTAGE CONVERTERS
FEATURES
Voltage-to-Frequency
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GENERAL DESCRIPTION
Choice of Guaranteed Linearity:
TC9401 ......................................................... 0.01%
TC9400 ......................................................... 0.05%
TC9402 ......................................................... 0.25%
DC to 100 kHz (F/V) or 1Hz to 100kHz (V/F)
Low Power Dissipation .......................... 27mW Typ
Single/Dual Supply Operation .................................
+ 8V to + 15V or ± 4V to ± 7.5V
Gain Temperature Stability .......... ± 25 ppm/°C Typ
Programmable Scale Factor
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Operation ........................................... DC to 100 kHz
Choice of Guaranteed Linearity:
TC9401 ......................................................... 0.02%
TC9400 ......................................................... 0.05%
TC9402 ......................................................... 0.25%
Programmable Scale Factor
APPLICATIONS
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2
3
ORDERING INFORMATION
Frequency-to-Voltage
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The TC9400/TC9401/TC9402 are low-cost voltage-tofrequency (V/F) converters utilizing low power CMOS
technology. The converters accept a variable analog input
signal and generate an output pulse train whose frequency
is linearly proportional to the input voltage.
The devices can also be used as highly-accurate frequency-to-voltage (F/V) converters, accepting virtually any
input frequency waveform and providing a linearly-proportional voltage output.
A complete V/F or F/V system only requires the addition
of two capacitors, three resistors, and reference voltage.
1
µP Data Acquisition
13-Bit Analog-to-Digital Converters
Analog Data Transmission and Recording
Phase-Locked Loops
Frequency Meters/Tachometer
Motor Control
FM Demodulation
Part No.
Linearity
(V/F)
TC9400COD
0.05%
TC9400CPD
0.05%
TC9400EJD
0.05%
TC9401CPD
0.01%
TC9401EJD
0.01%
TC9402CPD
0.25%
TC9402EJD
0.25%
Package
Temperature
Range
14-Pin
0°C to +70°C
SOIC (Narrow)
14-Pin
0°C to +70°C
Plastic DIP
14-Pin
– 40°C to +85°C
CerDIP
14-Pin
0°C to +70°C
Plastic DIP
14-Pin
– 40°C to +85°C
CerDIP
14-Pin
0°C to +70°C
Plastic DIP
14-Pin
– 40°C to +85°C
CerDIP
FUNCTIONAL BLOCK DIAGRAM
4
5
6
TC9400
Integrator
Capacitor
Input
Voltage
Integrator
OpAmp
Threshold
Detector
One
Shot
RIN
IIN
7
Pulse Output
÷2
Reference
Capacitor
Pulse/2 Output
IREF
8
Reference
Voltage
TC9400/1/2-5 11/6/96
TELCOM SEMICONDUCTOR, INC.
3-287
VOLTAGE-TO-FREQUENCY/
FREQUENCY-TO-VOLTAGE CONVERTERS
TC9400
TC9401
TC9402
*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.
ABSOLUTE MAXIMUM RATINGS*
VDD – VSS ................................................................. +18V
IIN ...........................................................................10mA
VOUT Max –VOUT Common .......................................... 23V
VREF – VSS ..............................................................– 1.5V
Storage Temperature Range ................ – 65°C to +150°C
Operating Temperature Range
C Device ................................................ 0°C to +70°C
E Device ........................................... – 40°C to +85°C
Package Dissipation (TA ≤ 70°C)
8-Pin CerDIP .................................................. 800mW
8-Pin Plastic DIP ............................................. 730mW
8-Pin SOIC .....................................................470mW
Lead Temperature (Soldering, 10 sec) ................. +300°C
ELECTRICAL CHARACTERISTICS: VDD = +5V, VSS = – 5V, VGND = 0V, VREF = – 5V, RBIAS = 100kΩ,
Full Scale = 10kHz, unless otherwise specified. TA = +25°C, unless temperature range is specified (– 40°C to +85°C
for E device, 0°C to +70°C for C device).
VOLTAGE-TO-FREQUENCY
Parameter
Definition
TC9401
TC9400
TC9402
Min Typ Max Min Typ Max Min Typ Max
Accuracy
Linearity 10 kHz
Output Deviation From Straight
Line Between Normalized Zero
and Full-Scale Input
Output Deviation From Straight
Line Between Normalized Zero
Reading and Full-Scale Input
Variation in Gain A Due to
Temperature Change
Variation From Ideal Accuracy
—
0.004 0.01
—
0.01 0.05
— 0.05
0.25
% Full
Scale
—
0.04
0.08
—
0.1
— 0.25
0.5
% Full
Scale
—
± 25 ± 40
—
± 25 ± 40
—
± 10
—
± 10
Correction at Zero Adjust for Zero
Output When Input is Zero
Variation in Zero Offset Due to
Temperature Change
—
± 10 ± 50
—
± 10 ± 50
— ± 50 ± 100 ppm/°C
Full Scale
— ± 10
–
% of
Nominal
— ± 20 ± 100
mV
—
± 25
± 50
—
± 25
± 50
— ± 50 ± 100
Full-Scale Analog Input Current to
Achieve Specified Accuracy
Overrange Current
Settling Time to 0.1% Full Scale
—
10
—
—
10
—
—
—
—
2
50
—
—
—
—
2
50
—
Logic "0" Output Voltage (Note 3)
Voltage Range Between Output
and Common
—
—
0.2
—
0.4
18
—
—
0.2
—
—
3
—
—
3
Linearity 100 kHz
Gain Temperature
Drift (Note 1)
Gain Variance
Zero Offset (Note 2)
Zero Temperature
Drift (Note 1)
Analog Input
IIN Full Scale
IIN Overrange
Response Time
Digital Section
VSAT @ IOL = 10mA
VOUT Max – VOUT
Common (Note 4)
Pulse Frequency
Output Width
3-288
–
0.25
—
Unit
µV/°C
10
—
µA
—
—
—
2
50
—
µA
Cycle
0.4
18
—
—
0.2
—
0.4
18
V
V
—
—
3
—
µsec
TELCOM SEMICONDUCTOR, INC.
VOLTAGE-TO-FREQUENCY/
FREQUENCY-TO-VOLTAGE CONVERTERS
TC9400
TC9401
TC9402
ELECTRICAL CHARACTERISTICS: (Cont.) VDD = +5V, VSS = – 5V, VGND = 0, VREF = – 5V, RBIAS = 100kΩ,
Full Scale = 10kHz, unless otherwise specified. TA = +25°C, unless temperature range is specified – 40°C to +85°C for
E device, 0°C to +70°C for C device.
FREQUENCY-TO-VOLTAGE
Parameter
Definition
Supply Current
IDD Quiescent
(Note 5)
ISS Quiescent
(Note 5)
VDD Supply
VSS Supply
Current Required From Positive
Supply During Operation
Current Required From Negative
Supply During Operation
Operating Range of Positive Supply
Operating Range of Negative Supply
Reference Voltage
VREF –VSS
Range of Voltage Reference Input
Accuracy
Nonlinearity (Note 10)
Input Frequency
Range (Note 7 and 8)
Frequency Input
Positive Excursion
Negative Excursion
Minimum Positive
Pulse Width (Note 8)
Minimum Negative
Pulse Width (Note 8)
Deviation From Ideal Transfer
Function as a Percentage
Full-Scale Voltage
Frequency Range for Specified
Nonlinearity
Voltage Required to Turn
Threshold Detector On
Voltage Required to Turn
Threshold Detector Off
Time Between Threshold
Crossings
Time Between Threshold
Crossings
Input Impedance
Analog Outputs
Output Voltage
(Note 9)
Output Loading
Voltage Range of Op Amp Output
for Specified Nonlinearity
Resistive Loading at Output of
Op Amp
Supply Current
IDD Quiescent
(Note 10)
ISS Quiescent
(Note 10)
VDD Supply
VSS Supply
Current Required From Positive
Supply During Operation
Current Required From Negative
Supply During Operation
Operating Range of Positive Supply
Operating Range of Negative Supply
Reference Voltage
VREF –VSS
Range of Voltage Reference Input
NOTES:
1.
2.
3.
4.
5.
Full temperature range. Guaranteed, Not Tested.
IIN = 0.
Full temperature range, IOUT = 10mA.
IOUT = 10µA.
Threshold Detect = 5V, Amp Out = 0V, Full Temperature
Range
TELCOM SEMICONDUCTOR, INC.
TC9401
TC9400
TC9402
Min Typ Max Min Typ Max Min Typ Max
—
1.5
—
4
–4
6
—
1.5
6
– 1.5 – 6 — – 1.5 – 6
—
7.5
4
— 7.5
— – 7.5 – 4 — – 7.5
—
—
3
10
mA
4
–4
–3
—
—
– 10
7.5
– 7.5
mA
V
V
– 2.5
—
—
V
— 0.05
0.25
% Full
Scale
—
—
– 2.5
—
0.01
0.02
—
10
—
100k
10
—
100k
10
—
100k
Hz
0.4
—
VDD
0.4
—
VDD
0.4
—
VDD
V
– 2 – 0.4
—
–2
– 0.4 —
–2
V
—
µsec
0.02 0.05
—
5
—
—
5
—
—
5
—
0.5
—
—
0.5
—
—
0.5
—
10
—
—
10
—
—
10
—
VDD – 1
—
— VDD – 1 —
2
—
—
2
—
—
1.5
6
—
1.5
—
4
–4
– 2.5
MΩ
— VDD – 1
—
V
—
2
—
—
kΩ
6
—
3
10
mA
– 10
7.5
– 7.5
mA
V
V
—
—
– 2.5
—
—
V
—
–3
4
—
–4 —
– 2.5 —
3
4
5
µsec
—
– 1.5 – 6
– 1.5 – 6
—
7.5
4
— 7.5
— – 7.5 – 4 — – 7.5
2
Unit
– 2.5
– 0.4
—
1
6
6. 10Hz to 100kHz.; Guaranteed, Not Tested
7. 5µsec minimum positive pulse width and 0.5 µsec minimum
negative pulse width.
8. tR = tF = 20 nsec.
9. RL ≥ 2kΩ.; Tested @ 10kΩ
10. Full temperature range, VIN = – 0.1V.
7
8
3-289
VOLTAGE-TO-FREQUENCY/
FREQUENCY-TO-VOLTAGE CONVERTERS
TC9400
TC9401
TC9402
PIN CONFIGURATIONS
14-Pin Plastic DIP/CerDIP
IBIAS 1
14-Pin SOIC (Narrow)
IBIAS
1
14
VDD
ZERO ADJ
2
13
NC
12
AMPLIFIER OUT
11
THRESHOLD DETECTOR
10
FREQ/2 OUT
14 VDD
ZERO ADJ 2
13 NC
IIN 3
I
IN
12 AMPLIFIER OUT
TC9400
TC9401
TC9402
VSS 4
VREF OUT 5
V
11 THRESHOLD DETECTOR
10 FREQ/2 OUT
GND 6
9
OUTPUT COMMON
VREF 7
8
PULSE FREQ OUT
V
REF
3
TC9400
TC9401
TC9402
SS
4
OUT
5
GND
6
9
OUTPUT COMMON
7
8
PULSE FREQ OUT
V
REF
NC = NO INTERNAL CONNECTION
PIN DESCRIPTIONS
Pin No.
3-290
Symbol
Description
1
IBIAS
This pin sets bias current in the TC9400. Connect to VSS through a 100 kΩ resistor.
See text.
2
Zero Adj
3
IIN
4
VSS
5
VREFOUT
6
GND
Analog ground.
7
VREF
Voltage reference input, typically – 5V.
8
Pulse Freq Out
9
Output Common
10
Freq/2 Out
This open drain output is a square wave at one half the frequency of the pulse
output (pin 8). Output transitions of this pin occur on the rising edge of pin 8.
11
Threshold Detect
Input to the threshold detector. This pin is the frequency input during F/V operation.
12
Amplifier Out
13
NC
No internal connection
14
VDD
Positive power supply connection, typically +5V.
Low frequency adjustment input. See text.
Input current connection for the V/F converter.
Negative power supply voltage connection, typically – 5V.
Reference capacitor connection.
Frequency output. This open drain output will pulse LOW each time the Freq
threshold detector limit is reached. The pulse rate is proportional to input voltage.
Source connection for the open drain output FETs. See text.
Output of the integrator amplifier.
TELCOM SEMICONDUCTOR, INC.
VOLTAGE-TO-FREQUENCY/
FREQUENCY-TO-VOLTAGE CONVERTERS
TC9400
TC9401
TC9402
+5V
2
+5V
14
VDD
11
fOUT 8
THRESHOLD
DETECT
1
RL
10kΩ
3µsec
DELAY
+5V
THRESHOLD
DETECTOR
fOUT/2 10
SELFSTART
÷2
9
OUTPUT
COMMON
–3V
12
5
4
VREF OUT
CREF
180pF
RIN
1MΩ
VIN
0V –10V
AMP OUT
20kΩ
CINT
820pF
INPUT
510kΩ
12pF
3
IIN
2
ZERO
ADJUST
+5V
–
OpAmp
5
+
IBIAS
–5V
10kΩ
TC9400
TC9401
TC9402
60pF
50kΩ
OFFSET
ADJUST
3
RL
10kΩ
1
VSS
VREF
4
7
GND
6
RBIAS
100kΩ
REFERENCE
VOLTAGE
(TYPICALLY –5V)
–5V
Figure 1.
6
10 Hz to 10 kHz V/F Converter
VOLTAGE-TO-FREQUENCY (V/F)
CIRCUIT DESCRIPTION
The TC9400 V/F converter operates on the principal
of charge balancing. The operation of the TC9400 is easily
understood by referring to Figure 1. The input voltage (VIN)
is converted to a current (IIN) by the input resistor. This
current is then converted to a charge on the integrating
capacitor and shows up as a linearly decreasing voltage at
the output of the op amp. The lower limit of the output
swing is set by the threshold detector, which causes the
reference voltage to be applied to the reference capacitor
for a time period long enough to charge the capacitor to
the reference voltage. This action reduces the charge on
the integrating capacitor by a fixed amount (q = CREF ×
VREF), causing the op amp output to step up a finite
amount.
TELCOM SEMICONDUCTOR, INC.
At the end of the charging period, CREF is shorted out.
This dissipates the charge stored on the reference capacitor, so that when the output again crosses zero the system
is ready to recycle. In this manner, the continued discharging of the integrating capacitor by the input is balanced out
by fixed charges from the reference voltage. As the input
voltage is increased, the number of reference pulses required to maintain balance increases, which causes the
output frequency to also increase. Since each charge increment is fixed, the increase in frequency with voltage is
linear. In addition, the accuracy of the output pulse width
does not directly affect the linearity of the V/F. The pulse
must simply be long enough for full charge transfer to take
place.
3-291
7
8
VOLTAGE-TO-FREQUENCY/
FREQUENCY-TO-VOLTAGE CONVERTERS
TC9400
TC9401
TC9402
3 µsec
TYP
fOUT
fOUT/2
1/f
VREF
CREF
CINT
0V
AMP
OUT
NOTES: 1. To adjust fMIN, set VIN = 10mV and adjust the 50kΩ offset for 10Hz output.
2. To adjust fMAX, set VIN = 10V and adjust RIN or VREF for 10 kHz output.
3. To increase fOUT MAX to 100kHz, change CREF to 2pF and CINT to 75pF.
4. For high-performance applications, use high-stability components for RIN, CREF, VREF (metal film
resistors and glass capacitors). Also, separate output ground (pin 9) from input ground (pin 6).
Figure 2 . Output Waveforms
The TC9400 contains a "self-start" circuit to ensure the
V/F converter always operates properly when power is first
applied. In the event that, during power-on, the Op Amp
output is below the threshold and CREF is already charged,
a positive voltage step will not occur. The op-amp output will
continue to decrease until it crosses the –3.0V threshold of
the "self-start" comparator. When this happens, an internal
resistor is connected to the op-amp input, which forces the
output to go positive until the TC9400 is in its normal
operating mode.
The TC9400 utilizes low power CMOS processing for
low input bias and offset currents with very low power
dissipation. The open-drain N-channel output FETs provide
high voltage and high current sink capability.
PIN FUNCTIONS
Threshold Detector Input
VOLTAGE-TO-TIME MEASUREMENTS
Pulse Freq Out
The TC9400 output can be measured in the time domain as well as the frequency domain. Some microcomputers, for example, have extensive timing capability but
limited counter capability. Also, the response time of a time
domain measurement is only the period between two output pulses, while the frequency measurement must accumulate pulses during the entire counter timebase period.
Time measurements can be made from either the
TC9400's Pulse Freq Out output or from the Freq/2 output.
The Freq/2 output changes state on the rising edge of
Pulse Freq Out, so Freq/2 is a symmetrical square wave at
one half the pulse output frequency. Timing measurements
can therefore be made between successive Pulse Freq
Out pulses, or while Freq/2 is high (or low).
This output is an open-drain N-channel FET which
provides a pulse waveform whose frequency is proportional
to the input voltage. This output requires a pull-up resistor
and interfaces directly with MOS, CMOS, and TTL logic.
3-292
In the V/F mode, this input is connected to the amplifier
output (pin 12) and triggers a 3 µsec pulse when the input
voltage passes through its threshold. In the F/V mode, the
input frequency is applied to this input.
The nominal threshold of the detector is halfway between the power supplies, or (VDD + VSS)/2 ±400mV. The
TC9400's charge balancing V/F technique is not dependent
on a precision comparator threshold, because the threshold
only sets the lower limit of the op-amp output. The op-amp's
peak-to-peak output swing, which determines the frequency,
is only influenced by external capacitors and by VREF.
Freq/2 Out
This output is an open-drain N-channel FET which
provides a square wave one-half the frequency of the pulse
frequency output. The Freq/2 output will change state on the
rising edge of Pulse Freq Out. This output requires a pullup resistor and interfaces directly with MOS, CMOS, and
TTL logic.
TELCOM SEMICONDUCTOR, INC.
VOLTAGE-TO-FREQUENCY/
FREQUENCY-TO-VOLTAGE CONVERTERS
TC9400
TC9401
TC9402
Output Common
VREF Out
The sources of both the Freq/2 out and the Pulse Freq
Out are connected to this pin. An output level swing from the
drain voltage to ground or to the VSS supply may be obtained
by connecting this pin to the appropriate point.
The charging current for CREF is supplied through this
pin. When the op amp output reaches the threshold level,
this pin is internally connected to the reference voltage and
a charge, equal to VREF x CREF, is removed from the
integrator capacitor. After about 3 µsec, this pin is internally
connected to the summing junction of the op amp to discharge CREF. Break-before-make switching ensures that
the reference voltage is not directly applied to the summing
junction.
RBIAS
An external resistor, connected to VSS, sets the bias
point for the TC9400. Specifications for the TC9400 are
based on RBIAS = 100kΩ ±10%, unless otherwise noted.
Increasing the maximum frequency of the TC9400
beyond 100kHz is limited by the pulse width of the Pulse
Output (typically 3µsec). Reducing RBIAS will decrease the
pulse width and increase the maximum operating frequency,
but linearity errors will also increase. RBIAS can be reduced
to 20kΩ, which will typically produce a maximum full scale
frequency of 500kHz.
This pin is the noninverting input of the operational
amplifier. The low-frequency set point is determined by
adjusting the voltage at this pin.
IIN
The inverting input of the operational amplifier and the
summing junction when connected in the V/F mode. An
input current of 10µA is specified, but an overrange current
up to 50µA can be used without detrimental effect to the
circuit operation. IIN connects the summing junction of an
operational amplifier. Voltage sources cannot be attached
directly, but must be buffered by external resistors.
VREF
A reference voltage from either a precision source or the
VSS supply is applied to this pin. Accuracy of the TC9400 is
dependent on the voltage regulation and temperature characteristics of the reference circuitry.
Since the TC9400 is a charge balancing V/F converter,
the reference current will be equal to the input current. For
this reason, the DC impedance of the reference voltage
source must be kept low enough to prevent linearity errors.
For linearity of 0.01%, a reference impedance of 200Ω or
less is recommended. A 0.1µF bypass capacitor should be
connected from VREF to ground.
TELCOM SEMICONDUCTOR, INC.
3
The output frequency (fOUT) is related to the analog input
voltage (VIN) by the transfer equation:
Amplifier Out
Zero Adjust
2
V/F CONVERTER DESIGN INFORMATION
Input/Output Relationships
Frequency out =
The output stage of the operational amplifier. During
V/F operation, a negative-going ramp signal is available at
this pin. In the F/V mode, a voltage proportional to the
frequency input is generated.
1
VIN
1
×
RIN
(VREF) (CREF)
4
External Component Selection
RIN
The value of this component is chosen to give a fullscale input current of approximately 10µA:
5
RIN ≅ VIN Full Scale .
10µA
Example: RIN ≅
10V
= 1MΩ.
10µA
Note that the value is an approximation and the exact
relationship is defined by the transfer equation. In practice,
the value of RIN typically would be trimmed to obtain fullscale frequency at VIN full scale (see "Adjustment Procedure"). Metal film resistors with 1% tolerance or better are
recommended for high-accuracy applications because of
their thermal stability and low-noise generation.
6
CINT
The exact value is not critical but is related to CREF by
the relationship:
7
3CREF ≤ CINT ≤ 10 CREF.
Improved stability and linearity are obtained when
CINT ≤ 4CREF. Low-leakage types are recommended,
although mica and ceramic devices can be used in applications where their temperature limits are not exceeded.
Locate as close as possible to pins 12 and 13.
8
3-293
VOLTAGE-TO-FREQUENCY/
FREQUENCY-TO-VOLTAGE CONVERTERS
TC9400
TC9401
TC9402
CREF
The exact value is not critical and may be used to trim the
full-scale frequency (see "Input/Output Relationships"). Glass
film or air trimmer capacitors are recommended because of
their stability and low leakage. Locate as close as possible
to pins 5 and 3.
VDD, VSS
Power supplies of ±5V are recommended. For highaccuracy requirements, 0.05% line and load regulation and
0.1µF disc decoupling capacitors located near the pins are
recommended.
Adjustment Procedure
Figure 1 shows a circuit for trimming the zero location.
Full scale may be trimmed by adjusting RIN, VREF, or CREF.
Recommended procedure for a 10kHz full-scale frequency
is as follows:
(1) Set VIN to 10 mV and trim the zero adjust circuit to
obtain a 10Hz output frequency.
Improved Single Supply V/F Converter
Operation
A TC9400 which operates from a single 12 to 15V
variable power source is shown in Figure 5. This circuit uses
two Zener diodes to set stable biasing levels for the TC9400.
The Zener diodes also provide the reference voltage, so the
output impedance and temperature coefficient of the Zeners
will directly affect power supply rejection and temperature
performance.
Full scale adjustment is accomplished by trimming the
input current. Trimming the reference voltage is not recommended for high accuracy applications unless an op amp is
used as a buffer, because the TC9400 requires a low
impedance reference (see the VREF pin description section
for more information).
The circuit of Figure 5 will directly interface with CMOS
logic operating at 12V to 15V. TTL or 5V CMOS logic can be
accommodated by connecting the output pullup resistors to
the +5V supply. An optoisolator can also be used if an
isolated output is required.
(2) Set VIN to 10V and trim either RIN, VREF, or CREF to
obtain a 10kHz output frequency.
If adjustments are performed in this order, there should be
no interaction and they should not have to be repeated.
500
VDD = +5V
VSS = – 5V
RIN = 1MΩ
VIN = +10V
TA = +25°C
CREF (pF) +12pF
400
300
1 kHz
200
100
100kHz
0
–1
Figure 3.
3-294
–2
–3
–4
VREF (V)
–5
–6
–7
Recommended CREF vs VREF
TELCOM SEMICONDUCTOR, INC.
VOLTAGE-TO-FREQUENCY/
FREQUENCY-TO-VOLTAGE CONVERTERS
TC9400
TC9401
TC9402
V+ = 8V TO 15V (FIXED)
R2
0.9
R1
GAIN
ADJUST
OFFSET
ADJUST
RIN
1MΩ
2
14
V2
10kΩ
2
6
5V
8
8.2
kΩ
0.01
µF
2
kΩ
7
VREF
11
0.01
µF
0.2
R1
fOUT
10kΩ
10
fOUT/2
3
TC9400
12
5
820
pF
1
180
pF 3
IIN
VIN
0V–10V
IIN
1
4
9
100 kΩ
R1
R2
V+
10V
1 MΩ 10kΩ
12V 1.4 MΩ 14kΩ
15V
2 MΩ 20kΩ
4
1
fOUT = IIN ×
(V2–V7) (CREF)
(VIN–V2)
(V+–V2)
+
IIN=
RIN
(0.9 R1+0.2 R1)
5
Figure 4 . Fixed Voltage — Single Supply Operation
+12 to +15V
1.2k*
14
VDD
1µF
R1
910k
R4
100k
CINT
D2
5.1VZ
11 THRESHOLD
DETECT
12 AMP OUT
CREF 5 CREF
R3
GAIN
TC9400
3 IIN
2 ZERO
ADJUST
6 GND
100k
R2
910k
INPUT
VOLTAGE
(0 to 10V)
10k
R5
91k
D1
5.1VZ
0.1µ
7 V
REF
1 I
BIAS
Rp
OFFSET
20k
100k
10k
6
fOUT 8
fOUT/2
10
OUTPUT
FREQUENCY
OUTPUT 9
COMMON
VSS
4
7
DIGITAL
GROUND
ANALOG GROUND
COMPONENT SELECTION
F/S FREQ.
1 kHz
10 kHz
100 kHz
CREF
2200pF
180pF
27pF
CINT
4700pF
470pF
75pF
Figure 5.
TELCOM SEMICONDUCTOR, INC.
8
Voltage to Frequency
3-295
VOLTAGE-TO-FREQUENCY/
FREQUENCY-TO-VOLTAGE CONVERTERS
TC9400
TC9401
TC9402
Input Voltage Levels
FREQUENCY-TO-VOLTAGE (F/V)
CIRCUIT DESCRIPTION
When used as an F/V converter, the TC9400 generates
an output voltage linearly proportional to the input frequency
waveform.
Each zero crossing at the threshold detector's input
causes a precise amount of charge (q = CREF × VREF) to be
dispensed into the op amp's summing junction. This charge
in turn flows through the feedback resistor, generating
voltage pulses at the output of the op amp. A capacitor (CINT)
across RINT averages these pulses into a DC voltage which
is linearly proportional to the input frequency.
F/V CONVERTER DESIGN INFORMATION
Input/Output Relationships
The output voltage is related to the input frequency (fIN)
by the transfer equation:
VOUT = [VREF CREF RINT] fIN.
The response time to a change in fIN is equal to (RINT
CINT). The amount of ripple on VOUT is inversely proportional
to CINT and the input frequency.
CINT can be increased to lower the ripple. Values of 1µF
to 100µF are perfectly acceptable for low frequencies.
When the TC9400 is used in the single-supply mode,
VREF is defined as the voltage difference between pin 7 and
pin 2.
The input frequency is applied to the Threshold Detector
input (Pin 11). As discussed in the V/F circuit section of this
data sheet, the threshold of pin 11 is approximately (VDD +
VSS) /2 ±400mV. Pin 11's input voltage range extends from
VDD to about 2.5 V below the threshold. If the voltage on pin
11 goes more than 2.5 volts below the threshold, the V/F
mode startup comparator will turn on and corrupt the output
voltage. The Threshold Detector input has about 200 mV of
hysteresis.
In ±5 V applications, the input voltage levels for the
TC9400 are ±400mV, minimum. If the frequency source
being measured is unipolar, such as TTL or CMOS operating from a +5V source, then an AC coupled level shifter
should be used. One such circuit is shown in Figure 6a.
The level shifter circuit in Figure 6b can be used in single
supply F/V applications. The resistor divider ensures that
the input threshold will track the supply voltages. The diode
clamp prevents the input from going far enough in the
negative direction to turn on the startup comparator. The
diode's forward voltage decreases by 2.1 mV/°C, so for high
ambient temperature operation two diodes in series are
recommended.
+8V to +5V
+5V
14
VDD
14
VDD
10k
Frequency
Input
+5V
33k
TC9400
0.01µF
11
IN914
Frequency
Input
DET
1.0M
33k
+5V
0V
TC9400
0.01µF
11
IN914
DET
1.0M
0V
GND
VSS
6
4
0.1µF
10k
VSS
4
–5V
(A) ±5V Supply
(B) Single Supply
Figure 6.
3-296
Frequency Input Level Shifter
TELCOM SEMICONDUCTOR, INC.
VOLTAGE-TO-FREQUENCY/
FREQUENCY-TO-VOLTAGE CONVERTERS
TC9400
TC9401
TC9402
1
2
+5V
V+
14
VDD
TC9400A
TC9401A
TC9402A
*
fOUT/2 10
42
OUTPUT
COMMON 9 *
SEE
FIGURE
6
fIN
THRESHOLD
DETECT
11
V+
3
*
fOUT 8
3 µsec
DELAY
* OPTIONAL
IF BUFFER
IS NEEDED
THRESHOLD
DETECTOR
4
VREF
OUT 5
CREF
56 pF
12pF
IIN 3
60pF
100kΩ
2 kΩ
2.2kΩ
–
OP
AMP
+
2 ZERO ADJUST
IBIAS
VSS
1
4
VREF
AMP
OUT 12
RINT
1 MΩ
+
OFFSET
ADJUST
+5V
SEE
EQUATION,
PAGE 12
CINT
1000pF
VO
5
GND
7
6
10 kΩ
VREF
–5V
6
(TYPICALLY –5V)
Figure 7.
DC — 10 kHz F/V Converter
Input Buffer
0.5µsec
MIN
5.0µsec
MIN
INPUT
fOUT
DELAY = 3µsec
fOUT and fOUT/2 are not used in the F/V mode. However,
these outputs may be useful for some applications, such as
a buffer to feed additional circuitry. Then, fOUT will follow the
input frequency waveform, except that fOUT will go high
3µsec after fIN goes high; fOUT/2 will be squarewave with a
frequency of one-half fOUT.
If these outputs are not used, pins 8, 9 and 10 should be
connected to ground.
7
fOUT/2
8
Figure 8 . F/V Digital Outputs
TELCOM SEMICONDUCTOR, INC.
3-297
VOLTAGE-TO-FREQUENCY/
FREQUENCY-TO-VOLTAGE CONVERTERS
TC9400
TC9401
TC9402
V+ = 10V to 15V
14
VDD
10k
6 GND
.01µF
6.2V
10k
TC9400
500k
2 ZERO
ADJUST
100k
33k
5
47pF
V+
Offset
Adjust
Frequency
Input
VREFOUT
3
IIN
1M
0.01µF
11 DET
GND
IN914
0.1µF
.001µF
AMP OUT 12
1.0k
1.0M
IBIAS
VOUT
6
VREF VSS
7
4
1.0k
100k
Note: The output is referenced to pin 6, which is at 6.2V (Vz). For frequency meter applications,
a 1 mA meter with a series-scaling resistor can be placed across pins 6 and 12.
Figure 9.
F/V Single Supply F/V Converter
Output Filtering
The output of the TC9400 has a sawtooth ripple superimposed on a DC level. The ripple will be rejected if the
TC9400 output is converted to a digital value by an integrating analog to digital converter, such as the TC7107 or
TC7109. The ripple can also be reduced by increasing the
value of the integrating capacitor, although this will reduce
the response time of the F/V converter.
The sawtooth ripple on the output of an F/V can be
eliminated without affecting the F/V's response time by
using the circuit in Figure 10. The circuit is a capacitance
multiplier, where the output coupling capacitor is multiplied
by the AC gain of the op amp. A moderately fast op amp,
such as the TL071, should be used.
VREFOUT 5
47pF
IIN 3
TC9400
1M
.001µF
200
AMP OUT 12
0.1µF
1M
.01µF
GND
6
+5
2
3
1M
–
VOUT
7
6
TL071
+ 4
–5
Figure 10.
3-298
Ripple Filter
TELCOM SEMICONDUCTOR, INC.
VOLTAGE-TO-FREQUENCY/
FREQUENCY-TO-VOLTAGE CONVERTERS
TC9400
TC9401
TC9402
F/V POWER-ON RESET
In some cases, however, the TC9400 output must be
zero at power-on without a frequency input. In such cases,
a capacitor connected from pin 11 to VDD will usually be
sufficient to pulse the TC9400 and provide a power-on reset
(see Figure 11A). Where predictable power-on operation is
critical, a more complicated circuit, such as Figure 11B, may
be required.
In F/V mode, the TC9400 output voltage will occasionally be at its maximum value when power is first applied. This
condition remains until the first pulse is applied to fIN. In most
frequency-measurement applications this is not a problem,
because proper operation begins as soon as the frequency
input is applied.
1
2
3
VDD
14
1000pF
1kΩ
11
fIN
THRESHOLD
DETECTOR
(A)
4
TC9400
VDD
(B)
16
3
VCC
CLRA
100kΩ
5
B
2
R
1
C
5
CD4538
4
Q
6
To TC 9400
A
1µF
VSS
8
Figure 11.
fIN
6
Power-On Operation/Reset
7
8
TELCOM SEMICONDUCTOR, INC.
3-299