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University of
Pennsylvania
Department of
Electrical and
Systems
Engineering
ABSTRACT: PIN diodes are used
in solid state transmit-receive (TR)
switches that allow either the
transmitter or the receiver to
communicate with the antenna while
protecting the device not in use. In
some devices, e.g. radar and radios,
PIN diodes are required to handle
powers on the order of 1 kW at radio
frequencies (RF).
The problem that a designer of solid
state switches faces is testing the
diodes and the switch circuit with
stresses of high power. Test
equipment that provides power of 1 kW
is expensive to purchase or rent. One
method to limit the need of a high
power RF transmitter is to create
resonant circuits that can provide
either the high voltage or high current
that would be seen from a high power
source.
High voltage can be achieved through
series resonating circuits while high
current can be produced with parallel
resonating circuits. The circuits will be
designed to resonate at several
frequencies ranging between 10 MHz
and 300 MHz. The PIN diode can be
stressed with these tuned circuits and
a designer would have the ability to
find faults in the solid state TR switch
being designed without the costs and
dangers associated with a high power
transmitter. The resonating circuits will
provide solid state TR switch designers
a low power and low cost method of
testing PIN diodes.
Authors:
Philip Chan ESE ’05
Michael Chakardjian ESE ’05
Thomas Leonard ESE ’05
Advisor:
Philip Farnum
Demo Times: Thursday April 21st
10:00AM, 10:30AM, 11:00AM, 1:00PM
Group number 17
PIN Diode Tester
Design Approach:
The PIN diode under test is connected
across two terminals from a passive LC
circuit. The output of an AC signal generator
is fed to the system and amplified by the
High Power Amplifier. Then the amplified
signal excites the passive Tuned Circuit,
generating in one case a high AC voltage
(~220 Vrms) or in the other a large AC
current. The high voltage mode is used to
test the blocking properties of a reverse
biased PIN, while large AC currents are used
to characterize the PIN in the forward bias.
There is a separate tuned circuit for each
mode of operation at four operating
frequencies in the range from 10 to 300 MHz.
System Block Diagram
Signal Generator
DC Voltage Supply
High Powered Amplifier
Tuned Circuit
PIN Diode
PIN Diodes
The PIN diode contains intrinsic material in
between p-type and n-type material. The
wider the intrinsic region is made, the
slower the switching speed of the diode. If
the intrinsic region is large enough, then
there can be a voltage swing that is
opposite of the bias direction but it will not
switch because of the slow switching
speed. As a result, a low DC bias; low as
compared to the amplitude of the RF signal
can be used and the diode will stay biased
in the desired direction. This allows for
more affordable operation of RF circuits
since the DC bias would have to be very
large if fast response diodes were used.
Antenna
Probe
Tuned Circuits
To maximize the “gain” generated at resonance, inductors were wound from
thick copper wire. This construction reduces the resistive losses due to skin
effect and therefore allows for a greater gain. Ceramic capacitors were used
for their low ESR and more importantly for their high operating voltage
tolerance (1 kV). Circuit models are shown below for the large current (left)
and high voltage generating circuits (right).