Datasheet
VFC320
7
SBVS017A
where f
FS
is the full scale output frequency in Hz. The
temperature drift of C
1
is critical since it will add directly to
the errors of the transfer function. An NPO ceramic type is
recommended. Every effort should be made to minimize
stray capacitance associated with C
1
. It should be mounted
as close to the VFC320 as possible. Figure 8 shows pulse
width and full scale frequency for various values of C
1
at
D
FS
= 25%.
FIGURE 8. Output Pulse Width (D
FS
= 0.25) and Full Scale
Frequency vs External One-shot Capacitance.
OFFSET AND GAIN ADJUSTMENT PROCEDURES
To null errors to zero, follow this procedure:
1. Apply an input voltage that should produce an output
frequency of 0.001 • full scale.
2. Adjust R
5
for proper output.
3. Apply the full scale input voltage.
4. Adjust R
3
for proper output.
5. Repeat stems 1 through 4.
If nulling is unnecessary for the application, delete R
4
and
R
5
, and replace R
3
with a short circuit.
POWER SUPPLY CONSIDERATIONS
The power supply rejection ratio of the VFC320 is 0.015%
of FSR/% max. To maintain ±0.015% conversion, power
supplies which are stable to within ±1% are recommended.
These supplies should be bypassed as close as possible to the
converter with 0.01µF capacitors.
Internal circuitry causes some current to flow in the common
connection (pin 11 on DIP package). Current flowing into
the f
OUT
pin (logic sink current) will also contribute to this
current. It is advisable to separate this common lead ground
from the analog ground associated with the integrator input
to avoid errors produced by these currents flowing through
any ground return impedance.
DESIGN EXAMPLE
Given a full scale input of +10V, select the values of R
1
, R
2
,
R
3
, C
1
, and C
2
for a 25% duty cycle at 100kHz maximum
operation into one TTL load. See Figure 6.
Selecting C
1
(D
FS
= 0.25)
C
1
= [(33 • 10
6
)/f
MAX
] – 15 [(66 • 10
6
)/f
MAX
] – 15
if D
FS
= 0.5
= [(33 • 10
6
)/100kHz] – 15
= 315pF
Choose a 300pF NPO ceramic capacitor with 1% to 10%
tolerance.
Selecting R
1
and R
3
(D
RS
= 0.25)
R
1
+ R
3
= V
IN
max/0.25mA V
IN
max/0.5mA
if D
FS
= 0.5
= 10V/0.25mA
= 40kΩ
Choose 32.4kΩ metal film resistor with 1% tolerance and
R
3
= 10kΩ cermet potentiometer.
Selecting C
2
C
2
= 10
2
/F
MAX
= 10
2
/100kHz
= 0.001µF
Choose a 0.001µF capacitor with ±5% tolerance.
Integrating Capacitor, C
2
Since C
2
does not occur in the V/F transfer function equation
(9), its tolerance and temperature stability are not important;
however, leakage current in C
2
causes a gain error. A
ceramic type is sufficient for most applications. The value of
C
2
determines the amplitude of V
OUT
. Input amplifier satu-
ration, noise levels for the comparators and slew rate limit-
ing of the integrator determine a range of acceptable values,
100/f
FS
; if f
FS
≤ 100kHz
C
2
(µF) = 0.001; if 100kHz < f
FS
≤ 500kHz
0.0005; if f
FS
> 500kHz
Output Pull Up Resistor R
2
The open collector output can sink up to 8mA and still be
TTL-compatible. Select R
2
according to this equation:
R
2
min (Ω) V
PULLUP
/(8mA – I
LOAD
)
A 10% carbon film resistor is suitable for use as R
2
.
Trimming Components R
3
, R
4
, R
5
R
5
nulls the offset voltage of the input amplifier. It should
have a series resistance between 10kΩ and 100kΩ and a
temperature coefficient less than 100ppm/°C. R
4
can be a
10% carbon film resistor with a value of 10MΩ.
R
3
nulls the gain errors of the converter and compensates for
initial tolerances of R
1
and C
1
. Its total resistance should be
at least 20% of R
1
, if R
1
is selected 10% low. Its temperature
coefficient should be no greater than five times that of R
1
to
maintain a low drift of the R
3
- R
1
series combination.
(13)
10
1
Capacitance C
1
(pF)
10,000
1000
100
10
1
Pulse Width (µs)
10
6
10
5
10
4
10
3
10
2
Full Scale Frequency (Hz)
10
2
10
3
10
4
10
5
Full Scale Frequency
Pulse Width