kh231 Fairchild Semiconductor, kh231 Datasheet - Page 4
kh231
Manufacturer Part Number
kh231
Description
Fast Settling, Wideband Buffer/amplifier Av = 1 To 5
Manufacturer
Fairchild Semiconductor
Datasheet
1.KH231.pdf
(6 pages)
DATA SHEET
Operation
The KH231 Buffer/Amplifier is based on the current feed-
back op amp topology, a design that uses current feed-
back instead of the usual voltage feedback.
The use of the KH231 is basically the same as that of the
conventional op amp (see Figures 1 and 2). Since the
device is designed specifically for low gain applications,
the best performance is obtained when the circuit is used
at gains between ±1 and ±5. Additionally, performance is
optimum when a 250Ω feedback resistor is used.
Layout Considerations
To assure optimum performance the user should follow
good layout practices which minimize the unwanted
coupling of signals between nodes. During initial bread-
boarding of the circuit use direct point to point wiring,
keeping the lead lengths to less than 0.25”. The use of
solid, unbroken ground plane is helpful. Avoid wire-wrap
4
+15V
-15V
Figure 1: Recommended non-inverting gain circuit
49.9Ω
V
V
in
in
Figure 2: Recommended inverting gain circuit
+15V
-15V
R
3.9
R
i
i
3.9
100Ω
R
3.9
g
0.1
R
3.9
g
0.1
6
5
0.1
KH231
+
-
6
5
1
9
33Ω
33Ω
0.1
+
KH231
-
3,7
9
12
1
33Ω
33Ω
3,7
10
12
11
.01
.01
10
11
250Ω
.01
.01
Capactance in µF
250Ω
R
For Z
R
A
f
g
v
Capactance in µF
= 250Ω
|| R
= −
R
R
100Ω
A
in
f
i
L
v
= 50Ω, select
= 250Ω
= 50Ω
V
= 1+
R
R
R
100Ω
o
f
g
L
V
o
R
R
f
g
type pc boards and methods. Sockets with small, short
pin receptacles may be used with minimal performance
degradation although their use is not recommended.
During pc board layout keep all traces short and direct
The resistive body of R
to pin 5 to minimize capacitance at that point. For the
same reason, remove ground plane from the vicinity of
pins 5 and 6. In other areas, use as much ground plane
as possible on one side of the board. It is especially
important to provide a ground return path for current from
the load resistor to the power supply bypass capacitors.
Ceramic capacitors of 0.01 to 0.1µf (with short leads)
should be less than 0.15 inches from pins 1 and 9.
Larger tantalum capacitors should be placed within one
inch of these pins. V
can be made directly from pins 9 and 1, but better supply
rejection and settling time are obtained if they are
separately bypassed as in figures 1 and 2. To prevent
signal distortion caused by reflections from impedance
mismatches, use terminated microstrip or coaxial cable
when the signal must traverse more than a few inches.
Since the pc board forms such an important part of the
circuit, much time can be saved if prototype boards of any
high frequency sections are built and tested early in the
design phase. Evaluation boards designed for either
inverting or non-inverting gains are available.
Distortion and Noise
The graphs of intercept point, I
frequency on the preceding page make it easy to predict
the distortion at any frequency given the output voltage of
the KH231. First, convert the output voltage (V
= (V
power output in dBm. At the frequency of interest, its 2nd
harmonic will be S
third harmonic will be S
two-tone third order intermodulation products. These
approximations are useful for P < -1dB compression levels.
Approximate noise figure can be determined for the
KH231 using the equivalent input noise graph on the
preceding page. The following equation can be used to
determine noise figure (F) in dB.
Where V
current. Beyond the breakpoint of the curves (i.e., where
they are flat), broadband noise figure equals spot noise fig-
ure, so ∆f should equal one (1) and V
read directly off the graph. Below the breakpoint, the noise
must be integrated and ∆f set to the appropriate bandwidth.
F 10log 1
=
pp
/2√2) and then to P = [(10log
n
is the rms noise voltage and i
+
V
n
4kTR
2
+
2
i R
n
= (I
2
A
CC
s
v
3
∆
g
f
2
f
2
= 2(I
should be as close as possible
connections to pins 10 and 12
2
-P)dB below the level of P. Its
3
- P)dB below P, as will the
10
(20V
2
n
n
REV. 1A February 2001
and I
and i
is the rms noise
rms
2
n
)] to get the
3
should be
o
, versus
) to V
KH231
rms
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