ETC SPT104

SPT104
DC TO 1.1GHz LINEAR AMPLIFIER
FEATURES
APPLICATIONS
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–3dB bandwidth of 1.1 GHz
325psec rise and fall times
14dB gain, 50Ω input and output
Low distortion, linear phase
1.4:1 VSWR (output, DC-1.1 GHz)
Direct replacement for CLC104
GENERAL DESCRIPTION
The SPT104 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 excellent VSWR and phase linearity
gives outstanding pulse fidelity and low signal distortion.
Designed for 50Ω systems, the SPT104 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.
Fast rise time, low overshoot and linear phase make the
SPT104 ideal for high-speed pulse amplification. These
properties plus low distortion combine to produce an amplifier well suited to many communications applications. With a
1.1GHz bandwidth, the SPT104 can handle the fastest digital traffic, even when the demodulation scheme or the digital
Basic Circuit Diagram
Digital and wideband analog communications
Radar, IF and RF processors
Fiber optic drivers and receivers
Photomultiplier preamplifiers
coding format requires that DC be maintained. It is also ideal
for traditional video amplifier applications such as radar or
wideband analog communications systems.
These same characteristics make the SPT104 an excellent
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.
The SPT104 is constructed using thin film resistor/bipolar
transistor technology, and is available in the following versions:
SPT104AI
–25 °C to +85 °C
14-pin double-wide DIP
Equivalent Circuit Diagram
Signal Processing Technologies, Inc.
4755 Forge Road, Colorado Springs, Colorado 80907, USA
Phone: (719) 528-2300 FAX: (719) 528-2370 Website: http://www.spt.com E-Mail: [email protected]
SPT104 ELECTRICAL CHARACTERISTICS (TA = +25 °C, VCC = ±15V, RL = 50Ω, RS = 50Ω; unless specified)
PARAMETERS
CONDITIONS
Ambient Temperature
FREQUENCY DOMAIN RESPONSE
† -3dB bandwidth
† non-inverting gain (note 1)
† gain flatness
linear phase deviation
group delay
reverse isolation
input return loss
output return loss
TIME DOMAIN RESPONSE
rise and fall time
(10% to 90%)
settling time to 0.8%
overshoot
overload recovery
TYP
MIN & MAX RATINGS
+25°C
Min
1100
1050
14.2
±0.4
1.5
600
1000
0dBm out
10dBm out
@ 100MHz
DC - 750MHz
DC - 600MHz
DC - 750MHz
750MHz - 1100MHz
DC - 750MHz
750MHz - 1100MHz
DC - 750MHz
750MHz - 1100MHz
40
35
18
11
17
10
1V step
2V step
1V step
1V step
Vinpeak = ±0.5V
325
375
1.2
3
1.2
NOISE AND DISTORTION RESPONSE
† 2nd harmonic distortion
0dBm, 100MHz
† 3rd harmonic distortion
0dBm, 100MHz
† 2nd harmonic distortion
10dBm, 100MHz
† 3rd harmonic distortion
10dBm, 100MHz
3rd order intermodulation intercept 100MHz
2-tone, 1MHz separation
500MHz
equivalent input noise voltage
10Hz to 1200MHz
noise figure
usable dynamic range
100MHz
500MHz
47
53
40
43
26
17
55
11
71
65
STATIC, DC PERFORMANCE
input bias current
input bias current (drift)
output offset voltage
output offset voltage (drift)
* supply current
supply rejection ratio
80
0.6
50
375
54
55
note 2
note 2
note 3
note 3
no load
1KHz
13.8
-0.6
UNITS
SYM
Max
14.9
+0.6
3
375
450
1.6
30
35
MHz
MHz
dB
dB
°
ps
SSBW
SSBW
dB
dB
dB
dB
dB
dB
RINI
RIIN
ps
ps
ns
%
ns
TRS
TRL
TS
OS
OR
-dBc
-dBc
-dBc
-dBc
+dBm
HD2
HD3
HD2
HD3
LPD
GD
dB
dB
dB
dB
280
2.0
250
625
60
µA
µA/°C
mV
µV/°C
mA
dB
IBN
IBN
ICC
PSRR
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
VCC
IO
input voltage
junction temperature
operating temperature
storage temperature
SPT
Notes
±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.
† AI Sample tested at 25°C.
SPT104
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TYPICAL PERFORMANCE CHARACTERISTICS (TA = +25 °C, VCC = ±15V, RL = 50Ω, RS = 50Ω; unless specified)
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PC Board Layout Considerations
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.
The SPT104 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.
Figure 1: Basic Circuit
If lower offset and offset drift are required, a low frequency
op amp may be used in conjunction with the SPT104 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 CS reduces the bandwidth of the op amp
correction circuit to limit the op amp’s effect on the SPT104
to frequencies below f45, the frequency at which the op amp
has 45dB of open loop gain. Using an LM108, f45 is about
7Hz with CS = 0.1µF. Thus the op amp can correct DC and
low frequency errors below f45, without affecting SPT104
performance above f45. Also note that the noise performance of the op amp will dominate below f45.
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.
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.
Reducing DC Offset
DC offset of the SPT104 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 SPT104.
SPT
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 f45, the composite gain is equal to (1 +
49.9k/(Ra + Rb)) and the output impedance is very low. As
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the signal frequency increases beyond f45, the op amp loses
influence and the SPT104 gain and output impedance dominate. To ensure a smooth transition and matched gain at all
frequencies, adjust Rb for a minimum op amp output swing
with a 0.1VPP sinewave input (to the SPT104) at the frequency f45. Since the SPT104 has a 50Ω output impedance,
its output voltage is a function of the load impedance
(Av ~ 10RL/(RL + 50)), whereas the gain of the composite
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(f45).
sipation. A minimum voltage across the regulator of 3.6V
and a minimum regulator current of 10mA will satisfy the
regulator dropout voltage and current limits.
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 SPT104. Figure 3 shows two possible
power reduction circuits from fixed ±15V supplies.
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 SPT104 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 SPT104 case must be maintained at or below 140°C.
Note that because of the amplifier design, power dissipation
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.
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.
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 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 dis-
Figure 3: Reducing Power Dissipation
Package Dimensions
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Signal Processing Technologies, Inc. reserves the right to change products and specifications without notice. Permission is hereby expressly
granted to copy this literature for informational purposes only. Copying this material for any other use is strictly prohibited.
WARNING – LIFE SUPPORT APPLICATIONS POLICY – SPT products should not be used within Life Support Systems without the specific
written consent of SPT. A Life Support System is a product or system intended to support or sustain life which, if it fails, can be reasonably
expected to result in significant personal injury or death.
Signal Processing Technologies believes that ultrasonic cleaning of its products may damage the wire bonding, leading to device
failure. It is therefore not recommended, and exposure of a device to such a process will void the product warranty.
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