KH104 [CADEKA]
DC to 1.1GHz Linear Amplifier; DC到1.1GHz的线性放大器型号: | KH104 |
厂家: | CADEKA MICROCIRCUITS LLC. |
描述: | DC to 1.1GHz Linear Amplifier |
文件: | 总6页 (文件大小:321K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
www.cadeka.com
KH104
DC to 1.1GHz Linear Amplifier
Features
General Description
The KH104 linear amplifier represents a significant
advance in linear amplifiers. Proprietary design
techniques have yielded an amplifier with 14dB of
gain and a -3dB bandwidth of DC to 1100MHz. Gain
flatness to 750MHz of 0.4dB coupled with eꢀcellent
VSWR and phase linearity gives outstanding pulse
fidelity and low signal distortion.
I
-3dB bandwidth of 1.1GHz
I
325psec rise and fall times
I
14dB gain, 50Ω input and output
I
Low distortion, linear phase
I
1.4:1 VSWR (output, DC-1.1GHz)
I
Direct replacement for CLC104
Applications
Designed for 50Ω systems, the KH104 is very easy to
use, requiring only properly bypassed power supplies
for operation. This translates to time and cost savings
in all stages of design and production.
I
Digital and wideband analog communications
I
Radar, IF and RF processors
I
Fiber optic drivers and receivers
I
Photomultiplier preamplifiers
Fast rise time, low overshoot and linear phase make
the KH104 ideal for high speed pulse amplification.
These properties plus low distortion combine to
produce an amplifier well suited to many communi-
cations applications. With a 1.1GHz bandwidth, the
KH104 can handle the fastest digital traffic, even
when the demodulation scheme or the digital coding
format requires that DC be maintained. It is also
ideal for traditional video amplifier applications such
as radar or wideband analog communications systems.
Basic Circuit Diagram
+15V
+15V
39
0.01
2.2
10K
0.01
Offset
Adjust
0.01
14
12
4
-15V
1
11
Vin
Vo
KH104
3,5-10
2
13
These same characteristics make the KH104 an eꢀcellent
choice for use in fiber optics systems, on either the
transmitting or receiving end of the fiber. The low
group delay distortion insures that pulse integrity
will be maintained. As a photomultiplier tube pre-
amp, its fast response and quick overload recovery
provide for superior system performance.
0.01
2.2
Capacitance if µF
39
0.01
-15V
Equivalent Circuit Diagram
The KH104 is constructed using thin film resistor/
bipolar transistor technology, and is available in the
following versions:
+VCC
1
KH104AI
-25°C to +85°C 14-pin double-wide DIP
+5.4V
Reg
14
11
13
Offset
+VR
Vo
12
Adjust
4
KH104
Vin
Ground
-VR
*
-5.4V
Reg
2
*Pins 3, 5-10 case is ground
REV. 1A January 2004
DATA SHEET
KH104
(
V
= 15V, RL = 50Ω, Rs = 50Ω; unless specified)
CC
TA = +25°C,
KH104 Electrical Characteristics
PARAMETERS
CONDITIONS
TYP
MIN & MAX RATINGS
UNITS
SYM
Ambient Temperature
KH104AI
+25°C
Min
Max
FREQUENCY DOMAIN RESPONSE
¦ -3dB bandwidth
0dBm out
1100
1050
14.2
±0.4
1.5
1000
MHz
MHz
dB
dB
°
SSBW
SSBW
10dBm out
@ 100MHz
DC - 750MHz
DC - 600MHz
¦ non-inverting gain (note 1)
¦ gain flatness
linear phase deviation
group delay
13.8
-0.6
14.9
+0.6
3
LPD
GD
600
ps
reverse isolation
DC - 750MHz
750MHz - 1100MHz
DC - 750MHz
750MHz - 1100MHz
DC - 750MHz
750MHz - 1100MHz
40
35
18
11
17
10
dB
dB
dB
dB
dB
dB
RINI
RIIN
input return loss
output return loss
TIME DOMAIN RESPONSE
rise and fall time
(10% to 90%)
settling time to 0.8%
overshoot
1V step
2V step
1V step
1V step
325
375
1.2
3
375
450
ps
ps
ns
%
TRS
TRL
TS
OS
overload recovery
Vinpeak = ±0.5V
1.2
1.6
ns
OR
NOISE AND DISTORTION RESPONSE
¦ 2nd harmonic distortion
¦ 3rd harmonic distortion
¦ 2nd harmonic distortion
¦ 3rd harmonic distortion
3rd order intermolulation intercept
2-tone, 1MHz separation
equivalent input noise voltage
noise figure
0dBm, 100MHz
0dBm, 100MHz
10dBm, 100MHz
10dBm, 100MHz
100MHz
500MHz
10Hz to 1200MHz
47
53
40
43
26
17
55
11
71
65
-dBc
-dBc
-dBc
-dBc
+dBm
HD2
HD3
HD2
HD3
30
35
dB
dB
dB
dB
usable dynamic range
100MHz
500MHz
STATIC, DC PERFORMANCE
input bias current
input bias current (drift)
output offset voltage
output offset voltage (drift)
* supply current
note 2
note 2
note 3
note 3
no load
1KHz
80
0.6
50
375
54
280
2.0
250
625
60
µA
µA/°C
mV
µV/°C
mA
IBN
IBN
ICC
PSRR
supply rejection ratio
55
dB
Min/max ratings are based on product characterization and simulation. Individual parameters are tested as noted. Outgoing quality levels are
determined from tested parameters.
Absolute Maximum Ratings
Notes
VCC
Io
±9V to ±16V
±40mA
±0.5V
+175°C
AI: -25°C to +85°C
-65°C to +150°C
1. Nominal gain only - gain variation over temperature is ±0.1dB.
2. Input offset voltage = (input bias current) x (Rs || 50Ω).
3. Output offset can be adjusted to zero with an external
potentiometer – see “Reducing DC Offset”.
4. * AI 100% tested at 25°C.
input voltage
junction temperature
operating temperature
storage temperature
¦ AI Sample tested at 25°C.
2
REV. 1A January 2004
KH104
DATA SHEET
(
VCC = 15V, RL = 50Ω, Rs = 50Ω; unless specified)
TA = +25°C,
KH104 Performance Characteristics
Forward Gain and Phase
Reverse Gain and Phase
Input Return Loss
16
14
12
10
8
180
0
20
40
60
80
360
180
0
0
20
40
60
80
Po = 0dBm
Po = 0dBm
|S21|
0
S21
S12
-180
-360
540
|S12|
-180
-360
0
260
520
780
1.04G
1.3G
0
260
520
780
1.04G
1.3G
0
260
520
780
1.04G
1.3G
Frequency (MHz)
Frequency (MHz)
Frequency (MHz)
Output Return Loss
Pulse Response
2nd and 3rd Harmonic Distortion
0
20
40
60
80
-20
-30
-40
Po = 0dBm
Input
Output
-50
-60
-70
-80
2nd
3rd
0
260
520
780
1.04G
1.3G
500ps/div
100k
1M
10M
100M
1G
Frequency (MHz)
Frequency (Hz)
-1dB Gain Compression
2-Tone, 3rd Order Intermod. Intercept
Noise Spectral Density
16
12
8
30
25
20
-120
-130
-140
-150
-160
-170
15
10
5
4
0
0
0
200
400
600
800
1000
0
200
400
600
800
1000
10
1k
100k
10M
1G
Frequency (MHz)
Frequency (MHz)
Frequency (Hz)
Usable Dynamic Range
Relative Bandwidth vs. Case Temp.
Power Supply Rejection Ratio
72
70
68
105
100
95
70
60
50
66
64
62
60
40
30
20
10
90
85
Pd = 1.6W
ΘCA = 30°C/W
80
0
200
400
600
800
1000
0
20
40
60
80
100
120
140
1
10
100
1k
10k
100k
1M
Frequency (MHz)
Case Temperature (°C)
Frequency (Hz)
REV. 1A January 2004
3
DATA SHEET
KH104
PC Board Layout Considerations
+15V
-15V
+15V
39
0.01
Proper layout of printed circuit boards is important to
achieve optimum performance of a circuit operating in
the 1GHz frequency range. Use of microstripline is
recommended for all signal-carrying paths and low
resistance, low inductance signal return and bypass
paths should be used. To keep the impedance of
these paths low, use as much ground plane as possible.
Ground plane also serves to increase the flow of heat out
of the package.
2.2
10K
Offset
Adjust
0.01
0.01
14
12
4
1
11
Vin
Vo
KH104
3,5-10
2
13
0.01
2.2
Capacitance if µF
The KH104 has three types of connections: signal paths
(input and output), DC inputs (supplies and offset adjust),
and grounds. 50Ω microstrip is recommended for
connection to the input (pin 4) and output (pin 11).
Microstrip on a doublesided PC board consists of a
ground plane on one side of the board and a constant-
width signal-carrying trace on the other side of the board.
For 1/16” G10 or FR-4 PC board material, a 0.1” wide
trace will have a 50Ω characteristic impedance. The
ground plane beneath the signal trace must extend at
least one trace width on either side of the trace. Also, all
traces (including ground) should be kept at least one
trace width from the signal carrying traces.
39
0.01
-15V
Figure 1: Basic Circuit
If lower offset and offset drift are required, a low frequency
op amp may be used in conjunction with the KH104 in a
composite configuration. The suggested circuit appears
in Figure 2. Its method of operation is to compare an
attenuated version of the output signal to the input signal
and apply a correcting voltage at the offset adjust pin. A
compensation capacitor C reduces the bandwidth of the
s
op amp correction circuit to limit the op amp’s effect on
To keep power supply noise and oscillations from
appearing at the amplifier output, all supply pins should
be capacitively bypassed to ground. The power
supply pins (1 and 2) are the inputs to a pair of voltage
regulators whose outputs are at pins 13 and 14. It is
recommended that 0.01µF or larger ceramic capacitors
be connected from pins 1, 2, 13 and 14 to ground, within
0.2” of the pins. A 1µF or larger solid tantalum capacitor
to ground is required within 3” of pins 1 and 2, and
for good low frequency performance, solid tantalum
capacitors of at least 15µF should be connected from
pins 13 and 14 to ground within 3” of the pins. Use
0.025” or wider traces for the supply lines. The offset
adjust pin (12) also requires bypassing; a 0.01µF or
larger ceramic capacitor to ground within 0.2” of the pin
is recommended.
the KH104 to frequencies below f , the frequency at
45
which the op amp has 45dB of open loop gain. Using an
LM108, f is about 7Hz with C = 0.1µF. Thus the op
45
s
amp can correct DC and low frequency errors below f ,
45
without affecting KH104 performance above f . Also
45
note that the noise performance of the op amp will dom-
inate below f .
45
12
4
11
+15V Vin
KH104
Vo
RL
0.01
49.9k
50Ω
Rc
9.76k
0.01
2k
7
2
3
Ra
11.8k
6
LM108
8
Rb
1k
Grounding is the final layout consideration. Pins 3 and 5-
10 should all be connected to a ground plane which
should cover as much of one side of the board around
the amplifier as possible.
4
Cs
0.01
0.01
Capacitance in µF
Rc = (Ra + Rb ) || 49.9k
-15V
Reducing DC Offset
DC offset of the KH104 may be adjusted by applying a
DC voltage to the amplifier’s offset adjust pin (12). The
simplest method is shown in Figure 1. Using this method
of offset adjust it is possible to vary the output offset by
approximately ±400mV. This simple adjustment has no
effect on the offset drift characteristics of the KH104.
Figure 2: Composite Amplifier
With an LM108 op amp in this composite configuration,
input offset is typically 2mV and drift is 15mV/°C. At
frequencies well below f , the composite gain is equal
45
to (1 + 49.9k/(R + R )) and the output impedance is
a
b
4
REV. 1A January 2004
KH104
DATA SHEET
very low. As the signal frequency increases beyond f ,
the op amp loses influence and the KH104 gain and
output impedance dominate. To ensure a smooth
voltage across the regulator of 3.6V and a minimum
regulator current of 10mA will satisfy the regulator
dropout voltage and current limits.
45
transition and matched gain at all frequencies, adjust R
b
Given the maximum anticipated power supply voltages,
the shunt resistor should be calculated to yield a 35mA
current from that voltage to the regulated voltage of 5.4V.
This will leave 10mA through the regulator at the
minimum quiescent current of 45mA. The regulator input
voltages may be reduced directly by dropping the voltage
supplies, or, if that option is not available, using either
a zener or resistive dropping element in series with
the supply. If a series dropping element is used, the
decoupling capacitors must appear on pins 1 and 2 of the
KH104. Figure 3 shows two possible power reduction
circuits from fixed ±15V supplies.
for a minimum op amp output swing with a 0.1V
pp
sinewave input (to the KH104) at the frequency f .
45
Since the KH104 has a 50Ω output impedance, its
output voltage is a function of the load impedance
_
(A ~ 10R /(R + 50)), whereas the gain of the compos-
v
L
L
ite amplifier at low frequencies and DC is relatively
independent of the load impedance, due to the high
open-loop gain of the op amp. Thus, to avoid gain
mismatching and phase non-linearity, use the composite
amplifier only if the load impedance is constant from DC
to at least 10(f ).
45
Use of a composite amplifier reduces input offset voltage
and its corresponding drift, but has no effect on input bias
current. This current is converted to an input voltage by
the resistance to ground seen at the amplifier input and
the voltage appears, amplified, at the output. Typical
input offset voltage due to the bias current is 2mV and
input offset drift is approximately 15mV/°C.
Several methods of decreasing the thermal resistance
from case to ambient are possible. With no heat paths
other than still air at 25°C, the thermal resistance from
case to ambient for the KH104 is about 40°C/W. When
placed in a printed circuit board with all ground pins
soldered into a ground plane 1” X 1.5”, the thermal
resistance drops to about 30°C/W In this configuration,
the case rise will be 30°C for 9V supplies and 50°C
for 16V supplies. This results in maximum allowable
ambient temperatures of 110°C and 90°C, respectively. If
higher operating temperatures are required, heat sinking
of the package is recommended.
Thermal Considerations
The KH104 case must be maintained at or below 140°C.
Note that because of the amplifier design, power dissipa-
tion remains fairly constant, independent of the load or
drive level. Therefore, standard derating is not possible.
There are two ways to keep the case temperature low.
The first is to keep the amount of power dissipated inside
the package to a minimum and the second is to get the
heat out of the package quickly by reducing the thermal
resistance from case to ambient.
+15V
+15V
60Ω
D1
5.6V
+
+
2.2µF
0.01µF
2.2µF
0.01µF
115Ω
115Ω
200Ω
200Ω
1
2
1
2
A large portion of the heat dissipated inside the package
is in the voltage regulators. At the minimum +9V supply
level the regulators dissipate 390mW and at the
maximum ±16V supply level they dissipate 1.2W.
14
13
14
13
Vin
Vin
Vo
Vo
The amplifier itself dissipates a fairly constant 600mW
(55mA x 10.8V). Reducing the power dissipation of the
internal regulators will go far towards reducing the
internal junction temperatures without impacting the so
performance. Reducing either the input supply voltages
(on pins 1 and 2) and/or shunting the regulator current
through external resistors (from pins 1 to 14 and pins
2 to 13) are both effective means towards significantly
reducing the internal power dissipation. A minimum
2.2µF
0.01µF
2.2µF
0.01µF
+
+
D2
5.6V
60Ω
-15V
-15V
D1, D2 IN4734
nominal, no load Pd – 760mW
~
~
nominal, no load Pd – 900mW
Figure 3: Reducing Power Dissipation
REV. 1A January 2004
5
DATA SHEET
KH104
KH104 Package Dimensions
0.140 – 0.180
(3.56 – 4.57)
0.060 R (TYP)
0.016 – 0.020
(0.41 – 0.51)
0.740 – 0.760
(18.80 – 19.30)
0.740 – 0.760
(18.80 – 19.30)
0.590 – 0.610
(14.99 – 15.49)
0.240 – 0.260
(6.10 – 6.60)
0.090 – 0.110
(2.29 – 2.79)
0.590 – 0.610
(14.99 – 15.49)
0.050 R (TYP)
Life Support Policy
Cadeka’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 Cadeka Microcircuits, Inc.
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 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 to the user.
2. A critical component is 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.
Cadeka does not assume any responsibility for use of any circuitry described, and Cadeka reserves the right at any time without notice to change said circuitry and specifications.
www.cadeka.com
© 2004 Cadeka Microcircuits, LLC
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