FAIRCHILD RV4152N

www.fairchildsemi.com
RC4152
Voltage-to-Frequency Converters
Features
•
•
•
•
•
•
•
•
•
•
•
• Signal isolation:
– VFC—opto-isolaton—FVC
– ADC with opto-isolation
• Signal encoding:
– FSK modulation/demodulation
– Pulse-width modulation
• Frequency scaling
• DC motor speed control
Single supply operation
Pulse output DTL/TTL/CMOS compatible
Programmable scale factor (K)
High noise rejection
Inherent monotonicity
Easily transmittable output
Simple full scale trim
Single-ended input, referenced to ground
V-F or F-V conversion
Voltage or current input
Wide dynamic range
Description
The RC4152 is a monolithic circuit containing all of the
active components needed to build a complete voltage-tofrequency converter. Circuits that convert a DC voltage to a
pulse train can be built by adding a few resistors and capacitors to the internal comparator, one-shot, voltage reference,
and switched current source. Frequency-to-voltage converters (FVCs) and many other signal conditioning circuits are
also easily created using these converters.
Applications
•
•
•
•
•
•
•
Precision voltage-to-frequency converters
Pulse-width modulators
Programmable pulse generators
Frequency-to-voltage converters
Integrating analog-to-digital converters
Long-term analog integrators
Signal conversion:
– Current-to-Frequency
– Temperature-to-Frequency
– Pressure-to-Frequency
– Capacitance-to-Frequency
– Frequency-to-Current
The RC4151 was the first monolithic VFC available and
offers guaranteed temperature and accuracy specifications.
The converter is available in a standard 8-pin plastic DIP.
Functional Block Diagram
4152
Switched
Current
Source Output
1
Switched
Reference
Output
2
Open Collector
Output
3
Switched
Current
Source
Voltage
Reference
8 -VS
Open Loop
Comparator
Switched
Voltage
Reference
7
Comparator
Inputs
6
Precision
One Shot
Ground
4
5
Open Collector
Logic Output
Transistor
One Shot
Timing
4152-01
Rev. 1.0.1
PRODUCT SPECIFICATION
RC4152
Pin Assignments
Pin Descriptions
Pin
Function
8 +VS
1
Switched Current Source Output (IOUT)
RS 2
7 VIN
2
Switched Voltage Reference (RS)
3
FOUT 3
6 VTH
Logic Output (Open Collector) (FOUT)
4
Ground (GND)
GND 4
5 CO
5
One-Shot R, C Timing (CO)
6
Threshold (VTH)
7
Input Voltage (VlN)
8
+VS
IOUT 1
4152-02
Absolute Maximum Ratings
Parameter
Min.
Typ.
Supply Voltage
Internal Power Dissipation
Input Voltage
-0.2
Output Sink Current
(Frequency Output)
Output Short Circuit to Ground
Max.
Units
+22
V
500
mW
+VS
V
20
mA
Continuous
Storage Temperature Range
-65
+150
°C
0
+70
°C
-25
+85
°C
Operating Temperature Range
RC4152
RV4152N
Note:
1. “Absolute maximum ratings” are those beyond which the safety of the device cannot be guaranteed. They are not meant to
imply that the device should be operated at these limits. If the device is subjected to the limits in the absolute maximum ratings
for extended periods, its reliability may be impaired. The tables of Electrical Characteristics provides conditions for actual
device operation.
Thermal Characteristics
8-Lead Plastic DIP
Small Outline SO-8
Max. Junction Temp.
+125°C
+125°C
Max. PD TA<50°C
468 mW
300mW
Therm. Res qJC
—
—
Therm. Res qJC
160°C/W
240°C/W
6.25 mW/°C
4.17mW/°C
For TA>50°C Derate at
2
RC4152
PRODUCT SPECIFICATION
Electrical Characteristics
(VS = +15V, and TA = +25°C unless otherwise noted)
Parameters
Test Conditions
Min.
Typ.
Max.
Units
2.5
6.0
mA
+15
+18
V
VOS
±2.0
±10
mV
Input Bias Current
-50
-300
nA
Input Offset Current
±30
±100
nA
0
VS-2
VS-3
V
0.65
0.67
0.69
VS
-50
-500
nA
I = 2.2 mA
0.1
0.5
V
T = 75 ms over the specified
temperature range
±30
±50
ppm/°C
Power Supply Requirements (Pin 8)
Supply Current
VS = +15V
Supply Voltage
+7.0
Input Comparator (Pins 6 and 7)
Input Voltage Range
One Shot (Pin 5)
Threshold Voltage
Input Bias Current
Saturation Voltage
Drift of Timing vs.
Temperature2
Timing Drift vs. Supply Voltage
Switched Current Source (pin
Output Current
Drift vs.
±100
ppm/V
+138
mA
1)1
RS = 16.7K
Temperature2
±50
over specified temperature range
Drift vs. Supply Voltage
±100
0.10
Leakage Current
Off State
Compliance
Pin 1 = 0V to +10V
1.0
1.0
2.5
2.0
ppm/°C
%/V
50
nA
mA
Reference Voltage (Pin 2)
VREF
2.25
2.5
V
Drift vs. Temperature2
over specified temperature range
±50
±100
ppm/°C
Logic output (Pin 3)
Saturation Voltage
ISINK = 3 mA
0.1
0.5
V
ISINK = 10 mA
0.8
Leakage Current
Off State
0.1
1.0
mA
0.007
0.05
%
±75
±150
ppm/°C
Nonlinearity Error
(Voltage Sourced Circuit of Figure 3)
Voltage2
Temperature Drift
(Voltage Sourced Circuit of Figure 3)
1.0 Hz to 10 kHz
FOUT = 10 kHz,
over specified temperature range
V
Notes:
1. Temperature coefficient of output current source (pin 1 output) exclusive of reference voltage drift.
2. Guaranteed but not tested.
3
PRODUCT SPECIFICATION
RC4152
Typical Performance Characteristics
100 KHz Current-Sourced VFC
Nonlinearity vs. Input Voltage
+0.01
+0.06
+0.005
+0.03
NL (% Error)
NL (% Error)
10 KHz Current-Sourced VFC
Nonlinearity vs. Input Voltage
0
-0.005
-0.01
0
-0.03
-0.06
-0.015
-0.09
0
1
2
3
4
5
6
7
8
9
10
0
1
2
3
4
+0.01
+0.10
+0.005
+0.05
0
-0.005
7
8
9
10
8
9
10
9
10
0
-0.05
-0.10
-0.01
-0.15
-0.015
0
1
2
3
4
5
6
7
8
9
10
0
1
2
3
4
VIN (V)
5
6
7
VIN (V)
10 KHz Precision VFC
Nonlinearity vs. Input Frequency
100 KHz Precision VFC
Nonlinearity vs. Input Frequency
+0.01
+0.12
+0.005
+0.08
0
-0.005
+0.04
0
4152-03
NL (% Error)
NL (% Error)
6
100 KHz Voltage-Sourced VFC
Nonlinearity vs. Input Voltage
NL (% Error)
NL (% Error)
10 KHz Voltage-Sourced VFC
Nonlinearity vs. Input Voltage
-0.04
-0.01
-0.015
-0.08
0
1
2
3
4
5
6
FIN (kHz)
4
5
VIN (V)
VIN (V)
7
8
9
10
0
1
2
3
4
5
6
FIN (kHz)
7
8
RC4152
PRODUCT SPECIFICATION
Principles of Operation
The RC4152 contains the following components: an open
loop comparator, a precision one-shot timer, a switched voltage reference, a switched current source, and an open collector logic output transistor. These functional blocks are
internally interconnected. Thus, by adding some external
resistors and capacitors, a designer can create a complete
voltage-to-frequency converter.
The comparator’s output controls the one-shot (monostable
timer). The one-shot in turn controls the switched voltage
reference, the switched current source and the open collector
output transistor. The functional block diagram shows the
components and their interconnection.
To detail, if the voltage at pin 7 is greater than the voltage at
pin 6, the comparator switches and triggers the one-shot.
When the one-shot is triggered, two things happen. First, the
one-shot begins its timing period. Second, the one-shot’s
output turns on the switched voltage reference, the switched
current source and the open collector output transistor.
The one-shot creates its timing period much like the popular
555 timer does, by charging a capacitor from a resistor tied
to +VS. The one-shot senses the voltage on the capacitor
(pin 5) and ends the timing period when the voltage reaches
2/3 of the supply voltage. At the end of the timing period, the
capacitor is discharged by a transistor similar to the open
collector output transistor.
Meanwhile, during the timing period of the one-shot, the
switched current source, the switched voltage reference, and
the open collector output transistor all will be switched on.
The switched current source (pin 1) will deliver a current
proportional to both the reference and an external resistor,
RS. The switched reference (pin 2) will supply an output
voltage equal to the internal reference voltage (2.25V). The
open collector output transistor we be turned on, forcing the
logic output (pin 3) to a low state. At the end of the timing
period all of these outputs will turn off. The switched voltage
reference has produced an off-on-off voltage pulse, the
switched current source has emitted a quanta of charge, and
the open collector output has transmitted a logic pulse.
To summarize, the purpose of the circuit is to produce a current pulse, well-defined in amplitude and duration, and to
simultaneously produce an output pulse which is compatible
with most logic families. The circuit's outputs show a pulse
waveform in response to a voltage difference between the
comparators inputs.
Integrator
CB
4152
I OUT
1
RB
2
RS
Current Setting Resistor
RS = 16.7K
Switched
Current
Source
Voltage
Reference
+VS
8
Open Loop
Comparator
Switched
Voltage
Reference
3
Ground
FOUT
4
V IN
0.01 m F
0 to +10V
6
Precision
One Shot
R LOAD
100K
7
Open Collector
Logic Output
Transistor
RO
One Shot
Timing
5
CO
Open Collector Output
4152-04
Figure 1. Single Supply VFC
5
PRODUCT SPECIFICATION
RC4152
Applications
1
T = ------------F OUT
Single Supply VFC
The stand-alone voltage-to-frequency converter is one of the
simplest applications for the RC4152. This application uses
only passive external components to create the least expensive VFC circuit (see Figure 1).
The positive input voltage VIN is applied to the input comparator through a low pass filter. The one-shot will fire repetitively and the switched current source will pump out current
pulses of amplitude VREF/RS and duration 1.1 ROCO into the
integrator. Because the integrator is tied back to the inverting
comparator input, a feedback loop is created. The pulse repetition rate will increase until the average voltage on the integrator is equal to the DC input voltage at pin 7. The average
voltage at pin 6 is proportional to the output frequency
because the amount of charge in each current pulse is
precisely controlled.
TP
V IN
----------- = I OUT -----T
RB
where TP = 1.1 R O C O
V REF
I OUT = ------------RS
By rearranging and substituting,
V IN R S
1
F OUT = ------------- ------- ----------------------V REF R B 1.1R O C O
Recommended component values for different operating
frequencies are shown in the table below.
Range
Input VIN
Output
FO
Scale
Factor
RO
CO
0 to -10V 0 to 1.0 kHz 0.1 KHz/V 6.8 kW 0.1 mF
Because the one-shot firing frequency is the same as the
open collector output frequency, the output frequency is
directly proportional to VIN.
The external passive components set the scale factor. For
best linearity, RS should be limited to a range of 12 kW to
20 kW
The reference voltage is nominally 2.25V for the RC4152.
Recommended values for different operating frequencies are
shown in the table below.
Operating
Range
DC to 1.0 kHz
RO
CO
RB
CB
6.8 kW
0.1 mF
100 kW
10 mF
DC to 10 kHz
6.8 kW
0.01 mF
100 kW
10 mF
DC to 100 kHz
6.8 kW
0.001 mF
100 kW
10 mF
0 to -10V 0 to 10 kHz
1.0 KHz/V 6.8 kW 0.01 mF
CI
0.05 mF
RB
100 kW
0.005 mF 100 kW
0 to -10V 0 to 100 kHz 10 KHz/V 6.8 kW 0.001 mF 500 pF
100 kW
The graphs shown under Typical Performance Characteristics show nonlinearity versus input voltage for the precision
current sourced VFC. The best linearity is achieved by using
an op amp having greater than 1.0 V/ms slew rate, but any op
amp can be used.
Precision Voltage Sourced VFC
This circuit is identical to the current sourced VFC, except
that the current pulses into the integrator are derived directly
from the switched voltage reference. This improves temperature drift at the expense of high frequency linearity.
The single supply VFC is recommended for uses where
dynamic range of the input is limited, and the input does not
reach 0V. With 10 kHz values, nonlinearity will be less than
1.0% for a 10 mV to 10V input range, and response time will
be about 135 ms.
The switched current source (pin 1) output has been tied to
ground, and RS has been put in series between the switched
voltage reference (pin 2) and the summing node of the op
amp. This eliminates temperature drift associated with the
switched current source. The graphs under the Typical
Performance Characteristics show that the nonlinearity error
is worse at high frequency, when compared with the current
sourced circuit.
Precision Current Sourced VFC
Single Supply FVC
This circuit operates similarly to the single supply VFC,
except that the passive R-C integrator has been replaced by
an active op amp integrator. This increases the dynamic
range down to 0V, improves the response time, and
eliminates the nonlinearity error introduced by the limited
compliance of the switched current source output.
A frequency-to-voltage converter performs the exact opposite of the VFCs function; it converts an input pulse train into
an average output voltage. Incoming pulses trigger the input
comparator and fire the one-shot. The one-shot then dumps a
charge into the output integrator. The voltage on the integrator becomes a varying DC voltage proportional to the
frequency of the input signal. Figure 4 shows a complete
single supply FVC.
The integrator algebraically sums the positive current pulses
from the switched current source with the current VIN/RB.
To operate correctly, the input voltage must be negative, so
that when the circuit is balanced, the two currents cancel.
6
RC4152
PRODUCT SPECIFICATION
CI
0.005 mF
1N914
-VS
+VS
RB
100K
V IN
0 to -10V
4
2
7
3
R S = 16.7K
R B+
100 k W
RL
5.1K
8
RL
10k W
1
+VL
100W
6
OP-27
Offset
Adjust
+VS
+VS
2
FOUT
Output Frequency
0 FO 10kHz
1
3
I OUT +V 8
FOUT R S
S
4152
4 Gnd
7
VFC
VTH VIN
CO
10 k W
6
5
5k W
CO
0.01 mF
1 mF
+VS
RO
6.8 k W
4152-05
Figure 2. Precision Current Sourced VFC
CI
0.005 mF
1N914
-V S
+VS
V IN
0 to -10V
RB
100K
4
2
R S = 16.7K
RZ
10k W
RB+
100 k W
Output Frequency
0 FOUT
10kHz
100W
Offset
Adjust
+VS
+VL
FOUT
6
8
3
1
RL
5.1K
7
OP-27
+VS
1
2
IOUT R S
3
+VS 8
FOUT
4152
4
VFC
7
Gnd
CO
VTH VIN
6
5
CO
0.01 mF
10 k W
5 kW
1 mF
+VS
RO
6.8 k W
4152-06
Figure 3. Precision Voltage Sourced VFC
7
PRODUCT SPECIFICATION
RC4152
Precision FVC
The input waveform must have fast slewing edges, and the
differentiated input signal must be less than the timing
period of the one-shot, 1.1 ROCO. A differentiator and
divider are used to shape and bias the trigger input; a negative going pulse at pin 6 will cause the comparator to fire the
one-shot. The input pulse amplitude must be large enough to
trip the comparator, but not so large as to exceed the ICs
input voltage ratings.
Linearity, offset and response time can be improved by
adding one or more op amps to form an active lowpass filter
at the output. A circuit using a single pole active integrator is
shown in Figure 5.
The positive output current pulses are averaged by the inverting integrator, causing the output voltage to be negative.
Response time can be further improved by adding a double
pole filter to replace the single pole filter. Refer to the graphs
under Typical Performance Characteristics that show
nonlinearity error versus input frequency for the
precision FVC circuit.
The output voltage is directly proportional to the input
frequency:
1.1R O C O R B V REF
V OUT = --------------------------------------------- F IN ( Hz )
RS
Output ripple can be minimized by increasing CB, but this
will limit the response time. Recommended values for
various operating ranges are shown in the following table.
Input
Operating
Rage
CIN
RO
CO
0 to 1.0 kHz
0.02 mF
0 to 10 kHz
0.002 mF 6.8 kW 0.01 mF
0 to 100 kHz 200 pF
6.8 kW 0.1 mF
RB
CB
Ripple
100 kW 100 mF 1.0 mV
100 kW 10 mF
1.0 mV
6.8 kW 0.001 mF 100 kW 1.0 mF
1.0 mV
+15V
RO
6.8 kW
10 k W
CO
0.01 m F
10Ÿ k W
C IN
0.022 mF
FIN
Frequency
Input
0
FIN
5
7
VIN
CO
4152
VFC
6 V
TH
+VS
5 kW
8
Gnd
4
F OUT 3
RS
I OUT
1
2
10kHz
10 k W
+15V
RB
100K
V OUT
R S = 16.7K
CB
10 mF
4152-07
Figure 4. Single Supply FVC
8
RC4152
PRODUCT SPECIFICATION
RO
6.8 k W
+15V
10 k W
10 k W
7
CIN
0.022 mF
FIN
Frequency Input
0 FO
10kHz
CO
0.01 mF
5
C O Gnd 4
3
4152 VFC
6
FOUT
VTH
I OUT R S
+VS
1
2
8
5 kW
VIN
R S = 16.7K
5.0 VP-P
Squarewave
10 k W
+15V
CI
RB
100 k W
5 pF
-VS
+VS
4
2
7
6
OP-27
3
8
RB
100 k W
1
RZ
10 kW
+VS
100W
Offset
Adjust
VOUT
Voltage Output
-10V V O 0
4152-08
9
10
Q35
Q36
(7)
(6)
(2)
(1)
Q5
V IN
VTH
RS
I OUT
+VS
(8)
Q6
Q1
Q33
Q34
Q7
Q2
15K
2K
Q26
6.2K
Q4
Q8
Q25
Q27
7.8K
2K
Q3
Q30
3.6K
Q37
Q28
Q9
M
Q41
Z
Q10
N
2K
Q22
Q23
R
FoUT
2K
2K
Q32
2K
2K
Q11
Q21
Y
(3)
Q17
S
Q16
Q12
(5)
Q13
CO
Q18
D29
6.3V
X
T
Q19
Q14
U
Q20
Q42
Q40
V
Q15
Q38
12K
W
-VS
Gnd
4152-09
(4)
10K
10K
10K
D39
D43
PRODUCT SPECIFICATION
RC4152
Schematic Diagram
RC4152
PRODUCT SPECIFICATION
Notes:
11
PRODUCT SPECIFICATION
RC4152
Ordering Information
Part Number
Package
Operating Temperature Range
RC4152N
N
0°C to +70°C
RC4152M
M
0°C to 70°C
RV4152N
N
-25°C to +85°C
Notes:
N = 8-lead plastic DIP
M = 8-lead plastic SOIC
LIFE SUPPORT POLICY
FAIRCHILD’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES
OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF FAIRCHILD SEMICONDUCTOR
CORPORATION. As used herein:
1. Life support devices or systems are devices or systems
which, (a) are intended for surgical implant into the body,
or (b) support or sustain life, and (c) whose failure to
perform when properly used in accordance with
instructions for use provided in the labeling, can be
reasonably expected to result in a significant injury of the
user.
2. A critical component in any component of a life support
device or system whose failure to perform can be
reasonably expected to cause the failure of the life support
device or system, or to affect its safety or effectiveness.
www.fairchildsemi.com
6/25/98 0.0m 003
Stock#DS30004152
Ó 1998 Fairchild Semiconductor Corporation