MA-COM AG312

AG312
Design with PIN Diodes
Rev. V3
Introduction
The PIN diode finds wide usage in RF, UHF and microwave circuits. It is fundamentally a device whose
impedance, at these frequencies, is controlled by its
DC excitation. A unique feature of the PIN diode is its
ability to control large amounts of RF power with
much lower levels of DC.
PIN Diode Modeling
The PIN diode is a current controlled resistor at radio
and microwave frequencies. It is a silicon semiconductor diode in which a high resistivity intrinsic Iregion is sandwiched between a P-type and N-type
region. When the PIN diode is forward biased, holes
and electrons are injected into the I-region. These
charges do not immediately annihilate each other;
Instead they stay alive for an average time called the
carrier lifetime, τ. This results in an average stored
charge, Q, which lowers the effective resistance of
the I-region to a value RS.
When the PIN diode is at zero or reverse bias there is
no stored charge in the I-region and the diode appears as a capacitor, CT, shunted by a parallel resistance RP.
PIN diodes are specified for the following parameters:
RS
series resistance under forward bias
CT
total capacitance at zero or reverse bias
Rp
parallel resistance at zero or reverse bias
VR
maximum allowable DC reverse voltage
τ
carrier lifetime
θAVE
average thermal resistance or
PD
maximum average power dissipation
θpulse
pulse thermal impedance or
PP
maximum peak power dissipation
By varying the I-region width and diode area it is possible to construct PIN diodes of different geometrics
to result in the same RS and CT characteristic.
Figure 1
These devices may have similar small signal characteristics. However, the thicker I-region diode
would have a higher bulk or RF breakdown voltage
and better distortion properties. On the other hand
the thinner device would have faster switching
speed.
These is a common misconception that carrier life
time, τ , is the only parameter that determines the
lowest frequency of operation and distortion produced. This is indeed a factor, but equally important is the thickness of the I-region, W, which relates to the transit time frequency of the PIN diode.
Low Frequency Model
At low frequencies (below the transit time frequency
of the I-region) and DC the PIN diode behaves like
a silicon PN junction semiconductor diode. Its I-V
characteristics determines the DC voltage at the
forward bias current level. PIN diodes often are
rated for the forward voltage, VF, at a fixed DC bias.
The reverse voltage ratings on a PIN diode, VR, are
a guarantee from the manufacturer that no more
than a specified amount, generally 10µA, of reverse
current will flow when VR is applied. It is not necessarily the avalanche or bulk breakdown voltage, VB,
which is determined by the I-region width
(approximately 10 V / µm.) PIN diodes of the same
bulk breakdown voltage may have different voltage
ratings. Generally, the lower the voltage rating the
less expensive the PIN diode.
1
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Commitment to produce in volume is not guaranteed.
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AG312
Design with PIN Diodes
Rev. V3
Large Signal Model
When the PIN diode is forward biased the stored
charge, Q, must be much greater than the incremental stored charge added or removed by the RF
current, IRF. To insure this the following inequality
must hold:
Q>> IRF
2πƒ
Under reverse bias the diode should not be biased
beyond its DC voltage rating, VR. The avalanche or
bulk breakdown voltage, VB, of a PIN diode is
proportional to the I-region width, W, and is always
higher than VR. In a typical application maximum
negative voltage swing should never exceed VB.
An instantaneous excursion of the RF signal into
the positive bias direction generally does not cause
the diode to go into conduction because of the slow
reverse to forward switching speed, TRF, of the PIN
diode. Refer to Figure 2.
Figure 2
RF Electrical Modeling of PIN Diode
Forward Bias Model
W2
(ohms)
RS =
(µn +µp) Q
Zero or Reverse Bias Model
Cτ = eA
W
Where
Where
e = dielectric constant of silicon
A = area of diode junction
Q = IF χ τ (coulombs)
W = I-region width
IF = forward bias current
τ = carrier lifetime
µn = electron mobility
µp = hole mobility
Notes:
1. In practical diode the parasitic resistance of the
diode package and contact limit the lowest resistance value
2. The lowest impedance will be affected by the
parasitic inductance, L, which is generally less
than 1 nH.
3. The equation is valid at frequencies higher than
the I-region transmit time frequency, i.e.,
Notes:
1. The above equation is valid at frequencies
above the dielectric relaxation frequency of the
I-region, i.e.
ƒ=
1
2πp
(where p is the resistivity of the I-region)
At lower frequencies the PIN diode acts
like a varactor.
2. The value of RP is proportional to voltage and
inversely proportional to frequency. In most RF
applications its value Is higher than the reactance of the capacitance, CT, and is less significant.
ƒ > 1300 (where frequency is in MHz and W in µm).
W2
4. The equation assumes that the RF signal does
2
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• India Tel: +91.80.43537383
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and/or prototype measurements. Commitment to develop is not guaranteed.
Visit www.macomtech.com for additional data sheets and product information.
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Solutions has under development. Performance is based on engineering tests. Specifications are
typical. Mechanical outline has been fixed. Engineering samples and/or test data may be available. M/A-COM Technology Solutions Inc. and its affiliates reserve the right to make
Commitment to produce in volume is not guaranteed.
changes to the product(s) or information contained herein without notice.
AG312
Design with PIN Diodes
Rev. V3
Switching Speed Model
The switching speed in any application depends on the
driver circuit as well as the PIN diode. The primary PIN
properties that influence switching speed may be explained as follows:
A PIN diode has two switching speeds from forward bias
to reverse bias TFR, and from reverse bias to forward
bias TRF. The diode characteristic that affects TFR is τ,
carrier lifetime. The value of TFR may be computed from
the forward current IF, and the initial reverse current IR,
as follows:
For CW applications the value of thermal resistance, θ,
used is the average thermal resistance, θAV.
In most pulsed RF and microwave applications where the
duty factor, DF, is less than 10 percent and the pulse
width, tp, is less than the thermal time constant of the
diode, good approximation of the effective value of θ in
the above equation may be computed as follows:
Where θ tp is the thermal impedance of the diode for the
time interval corresponding to tp.
The following diagram indicates how junction
temperature is affected during a pulsed RF application.
PIN Diode Applications
Figure 3
TRF depends primarily on I-region width, W, as indicated
in the following chart which shows typical data:
I-Width To 10 mA from To 50 mA from To 100 mA from
µm
10 V
100 V
10 V
100 V
10 V
100 V
175
7.0 µS
5.0 µS
3.0 µS
2.5 µS
2.0 µS
1.5 µS
100
2.5 µS
2.0 µS
1.0 µS
0.8 µS
0.6 µS
0.6 µS
50
0.5 µS
0.4 µS
0.3 µS
0.2 µS
0.2 µS
0.1 µS
Thermal Model
The maximum allowable power dissipation, PD, is determined by the following equation:
Figure 4
where TJ is the maximum allowable junction temperature
(usually 175°C) and TA is the ambient or heat sink temperature. Power dissipation may be computed as the
product ot the RF current squared multiplied by the diode
resistance, RS.
3
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and/or prototype measurements. Commitment to develop is not guaranteed.
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Solutions has under development. Performance is based on engineering tests. Specifications are
typical. Mechanical outline has been fixed. Engineering samples and/or test data may be available. M/A-COM Technology Solutions Inc. and its affiliates reserve the right to make
Commitment to produce in volume is not guaranteed.
changes to the product(s) or information contained herein without notice.
AG312
Design with PIN Diodes
Switches
PIN diodes are commonly used as a switching element to control RF signals. In these applications,
the PIN diode can be biased to either a high or low
impedance device state, depending on the level of
stored charge in the I-region.
A simple untuned single-pole, single throw (SPST)
switch may be designed using either a single series
or shunt connected PIN diode as shown in Figure
5. The series connected diode switch is commonly
used when minimum insertion loss is required over
a broad frequency range. This design is also easier to physically realize using printed circuit techniques, since no through holes are required in the
circuit board.
Figure 5
Rev. V3
A single shunt mounted diode will, on the other
hand produce higher isolation values across a
wider frequency range and will result in a design
capable of handling more power since it is easier to
heat sink the diode.
Multi-throw switches are more frequently used than
single-throw switches. A simple multi-throw switch
may be designed employing a series PIN diode in
each arm adjacent to the common port. Improved
performance is obtained by using “compound
switches,” which are combinations of series and
shunt connected PIN diodes, in each arm.
For narrow-band applications, quarter-wave
spaced multiple diodes may also be used in various switch designs to obtain improved operation in
the following section, we shall discuss each of
these types of switching in detail and present design information for selecting PIN diodes and predicting circuit performance.
Figure 6
4
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and/or prototype measurements. Commitment to develop is not guaranteed.
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Commitment to produce in volume is not guaranteed.
changes to the product(s) or information contained herein without notice.
AG312
Design with PIN Diodes
Series Connected Switch
Figure 6 shows two basic types of PIN diode series
switches, (SPST and SPDT), commonly used in broadband designs. In both cases, the diode is in a “pass
power” condition when it is forward biased and presents
a low forward resistance, RS, between the RF generator
and load. For the “stop power” condition, the diode is at
zero or reverse bias so that it presents a high impedance
between the source and load. In series connected
switches, the maximum isolation obtainable depends
primarily on the capacitance of the PIN diode, while the
insertion loss and power dissipation are functions of the
diode resistance. The principal operating parameters of
a series switch may be obtained using the following
equations:
Rev. V3
B. Isolation (Series Switch)
This equation applies for a SPST diode switch. Add 6 dB
for a SPNT switch to account for the 50 percent voltage
reduction across the “off” diode due to the termination of
the generator in its characteristic impedance. Figure 8
graphically presents isolation as a function of capacitance for simple series switches. These curves are plotted for circuits terminated in 50 ohm loads.
A. Insertion Loss (Series Switch)
This equation applies for a SPST switch and is graphically presented in Figure 7 for a 50 ohm impedance design. For multi-throw switches, the insertion loss is
slightly higher due to any mismatch caused by the capacitance of the PIN diodes in the “off” arms. This additional insertion loss can be determined from Figure 10
after first computing the total shunt capacitance of all
“off” arms of the multi-throw switch.
Figure 8
Isolation for SPST Diode series switch in 50 Ω
system. Add 6 dB to isolation for multi-throw
switches (SPNT).
C. Power Dissipation
(Series Switch in Forward Bias)
For ZO >>RS, this becomes:
Where the maximum available power is given by:
Figure 7
Insertion Loss for PIN diode series
switch in 50 Ω system
It should be noted that Equations 3 and 4 apply only for
perfectly matched switches. For SWR (σ) values other
than unity, multiply these equations by [2σ / (σ + 1)]2 to
obtain the maximum required diode power dissipation
rating.
5
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• India Tel: +91.80.43537383
• China Tel: +86.21.2407.1588
and/or prototype measurements. Commitment to develop is not guaranteed.
Visit www.macomtech.com for additional data sheets and product information.
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Solutions has under development. Performance is based on engineering tests. Specifications are
typical. Mechanical outline has been fixed. Engineering samples and/or test data may be available. M/A-COM Technology Solutions Inc. and its affiliates reserve the right to make
Commitment to produce in volume is not guaranteed.
changes to the product(s) or information contained herein without notice.
AG312
Design with PIN Diodes
D. Peak Current (Series Switch)
In the case of a 50 ohm system, this reduces to:
E. Peak RF Voltage (Series Switch)
Rev. V3
Figure 9 shows two typical shunt connected PIN diode
switches. These shunt diode switches offer high isolation for many applications and since the diode may be
heat sinked at one electrode, it is capable of handling
more RF power than a diode in a series type switch.
In shunt switch designs, the isolation and power dissipation are functions of the diode’s forward resistance,
whereas the insertion loss is primarily dependent on the
capacitance of the PIN diode. The principal equations
describing the operating parameters shunt switches are
given by:
A. Insertion Loss (Shunt Switch)
For a 50 ohm system this becomes:
This equation applies for both SPST and SPNT shunt
switches and is graphically presented in Figure 10 for a
50 ohm load impedance design.
Shunt Connected Switch
Figure 10
Insertion loss for shunt PIN switch in 50 Ω system
B. Isolation (Shunt Switch)
This equation, which is illustrated in Figure 11, applies
for a SPST shunt switch. Add 6 dB to these values to
obtain the correct isolation for a multi-throw switch.
Figure 9
Shunt Connected Switches 2-5
6
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and/or prototype measurements. Commitment to develop is not guaranteed.
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Solutions has under development. Performance is based on engineering tests. Specifications are
typical. Mechanical outline has been fixed. Engineering samples and/or test data may be available. M/A-COM Technology Solutions Inc. and its affiliates reserve the right to make
Commitment to produce in volume is not guaranteed.
changes to the product(s) or information contained herein without notice.
AG312
Design with PIN Diodes
Rev. V3
F. Peak RF Voltage (Shunt Switch)
In the case of a 50 ohm system, this reduces to:
Compound and Tuned Switches
Figure 11
Isolation for SPST shunt PIN switches in 50 Ω
system. Add 6 dB to isolation for multi-throw
switches (SPNT).
C. Power Dissipation (Shunt Switch in Forward Bias)
For ZO>>RS2 this becomes:
Where the maximum available power is given by:
In practice, it is usually difficult to achieve more than 40
dB isolation using a single PIN diode, either in shunt or
series, at RF and higher frequencies. The causes of this
limitation are generally radiation effects in the transmission medium and inadequate shielding. To overcome
this there are switch designs that employ combinations of
series and shunt diodes (compound switches) and
switches that employ resonant structures (tuned
switches) affecting improved isolation performance.
The two most common compound switch configurations
are PIN diodes mounted in either ELL (series-shunt) or
TEE designs as shown in Figure 12. In the insertion loss
state for a compound switch the series diode is forward
biased and the shunt diode is at zero or reverse bias.
The reverse is true for the isolation state. This adds
some complexity to the bias circuitry in comparison to
simple switches. A summary of formulas used for calculating insertion loss and isolation for compound and simple switches is given in Figure 13.
D. Power Dissipation (Shunt Switch in Reverse)
Where Rp is the reverse biased diode’s parallel resistance.
E. Peak RF Current (Shunt Switch)
For a 50 ohm system, this becomes:
Figure 12
Compound Switches
7
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and/or prototype measurements. Commitment to develop is not guaranteed.
Visit www.macomtech.com for additional data sheets and product information.
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Solutions has under development. Performance is based on engineering tests. Specifications are
typical. Mechanical outline has been fixed. Engineering samples and/or test data may be available. M/A-COM Technology Solutions Inc. and its affiliates reserve the right to make
Commitment to produce in volume is not guaranteed.
changes to the product(s) or information contained herein without notice.
AG312
Design with PIN Diodes
Type
Rev. V3
Isolation
Insertion Loss (dB)
Series
Shunt
Series-Shunt
TEE
Figure 13
Summary of Formulas for SPST Switches. (Add 6 dB to Isolation to obtain value for SPNT switch)
A. Circuit Diagram
C. Insertion Loss Bias Current in D1-mA
(D2 Reverse Biased)
B.
Isolation
Bias Current in D2-mA (D1 Reverse Biased)
Note: Add 6 dB for SPNT Switch
Figure 14
Series Shunt Switch
8
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and/or prototype measurements. Commitment to develop is not guaranteed.
Visit www.macomtech.com for additional data sheets and product information.
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Solutions has under development. Performance is based on engineering tests. Specifications are
typical. Mechanical outline has been fixed. Engineering samples and/or test data may be available. M/A-COM Technology Solutions Inc. and its affiliates reserve the right to make
Commitment to produce in volume is not guaranteed.
changes to the product(s) or information contained herein without notice.
AG312
Design with PIN Diodes
Rev. V3
Transmit-Receive Switches
There is a class of switches used in transceiver applications whose function is to connect the antenna to the
transmitter (exciter) in the transmit state and to the receiver during the receiver state. When PIN diodes are
used as elements in these switches they offer high reliability, better mechanical ruggedness and faster switching speed than electro-mechanical designs.
The basic circuit for an electronic switch consists of a
PIN diode connected in series with the transmitter, and a
shunt diode connected a quarter wavelength (λ / 4 section (Figure 16) and of course, are preferable from transceivers that operate at long wavelengths.
Figure 15
Figure 14 shows the performance of an ELL type of
switch utilizing M/A-COM MA4P709 series diodes.
These diodes are rated at 3.3 pF, maximum capacitance,
and 0.25 Ω, RS maximum at 100 mA. In comparison, a
simple series connected using the same diode switch
would have similar insertion loss to the 100 MHz contour
and the isolation would be 15 dB maximum at 100 MHz,
falling off at the rate of 6 dB per octave.
A tuned switch may be constructed by spacing two series
diodes or two shunt diodes a wavelength apart as shown
in Figure 15. The resulting value of isolation in the tuned
switch is twice that obtainable in a single diode switch.
The insertion loss of the tuned series switch is higher
than that of the simple series switch and may be computed using the sum of the diode resistance as the RS
value in equation 1. In the tuned shunt switch the insertion loss may even be lower than in a simple shunt
switch because of a resonant effect of the spaced diode
capacitance.
Quarter-wave spacing need not be limited to frequencies
where the wavelength is short enough to install a discrete length of line. There is a lumped circuit equivalent
which simulates the quarter-wave section and may be
used in RF band. This is shown in Figure 16. These
tuned circuit techniques are effective in applications having bandwidths on the order of 10 percent of the center
frequency.
Figure 16
Quarter Wave Line Equivalent
When switched into the transmit state each diode becomes forward biased. The series diode appears as a
low impedance to the signal heading toward the antenna
and the shunt diode effectively shorts the receiver’s antenna terminals to prevent overloading. Transmitter insertion loss and receiver isolation depend on the diode
resistance. If RS is 1 Ω greater than 30 dB isolation and
less than 0.2 dB insertion, loss can be expected. This
performance is achievable over a 10 percent bandwidth.
In the receive condition the diodes are at zero or reverse
bias and present essentially a low capacitance, CT, which
creates a direct low-insertion-loss path between the
antenna and receiver. The off-transmitter is isolated
from this path by the high imperdance series diodes.
The amount of power, PA, this switch can handle
depends on the power rating of the PIN diode, PD, and
the diode resistance.
The equation showing this
relationship is as follows for an antenna maximum SWR
of σ :
9
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and/or prototype measurements. Commitment to develop is not guaranteed.
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Solutions has under development. Performance is based on engineering tests. Specifications are
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Commitment to produce in volume is not guaranteed.
changes to the product(s) or information contained herein without notice.
AG312
Design with PIN Diodes
Rev. V3
In a 50 ohm system where the condition of a totally mismatched antenna must be considered this equation reduced to:
By using these equations it can be shown that using a
MA4P709 (or equivalent) insulated stud and MA4P709150 stud mounted diode biased at 1 ampere where the
RS value is < .2 Ω and is installed in a 50°C heat sink
where the MA4P709-985 is rated at 20 watts that a
power level of 2.5 kW may be safely controlled even for a
totally mismatched antenna. For a perfectly matched
antenna, 10 kW may be controlled.
Broadband antenna switches using PIN diodes may be
designed using the series connected diode circuit shown
in Figure 18. The frequency limitation of this switch results primarily from the capacitance of D2.
In this case forward bias is applied either to D1 during
transmit or D2 during receive. In high power application
(<50 W) it is often necessary to apply reverse voltage on
D2 during transmit. This may be accomplished either by
a negative polarity power supply at Bias 2 or by having
the forward bias current of D1 flow through resistor R to
apply the required negative voltage.
The MA47266 is an axial leaded PIN diode rated at 1.5
W dissipation at 1/2” (12.7 mm) total length to a 50°C
contact. The resistance of this diode is a 0.5 Ω (max) at
50 mA. A quarter-wave switch using 2 MA47266s may
then be computed to handle 40 watts with a totally
mismatched antenna.
The selection of diode D1 is based primarily on its power
handling capability. It nee not have a high voltage rating
since it is always forward biased in its low resistance
state when high RF power is applied. Diode D2 does not
pass high RF current but must be able to hold off the RF
voltage generated by the transmitter. It is primarily selected on the basis of its capacitance which determines
the upper frequency limit and its ability to operate at low
distortion.
It should be pointed out that the shunt diode of the
quarter-wave antenna switch dissipates about as much
power as the series diode. This may not be apparent
from Figure 17; however, it may be shown that the RF
current in both the series and shunt diode is practically
identical.
Using an MA47266 as D1, and a 1N5767 which is rated
at 0.4 pF max, as D2, greater than 25 dB receiver isolation may be achieved up to 400 MHz. The expected
transmit and receive insertion loss with the PIN diodes
biased at 50 mA are 0.1 dB and 0.3 dB respectively.
This switch can handle RF power levels up to 40 watts.
Figure 17
Quarter Wave Antenna Switches
10
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and/or prototype measurements. Commitment to develop is not guaranteed.
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Solutions has under development. Performance is based on engineering tests. Specifications are
typical. Mechanical outline has been fixed. Engineering samples and/or test data may be available. M/A-COM Technology Solutions Inc. and its affiliates reserve the right to make
Commitment to produce in volume is not guaranteed.
changes to the product(s) or information contained herein without notice.
AG312
Design with PIN Diodes
Rev. V3
In the selection of a PIN diode for an attenuator application the designer must often be concerned about the
range of diode resistance which will define the dynamic
range of the attenuator. PIN diode attenuators tend to be
more distortion sensitive than switches since their operating bias point often occurs at a low value of quiescent
stored charge. A thin I-region PIN will operate at lower
forward bias currents than thick PIN diodes but the
thicker one will generate less distortion.
Figure 18
Broadband Antenna Switch
Practical Design Hints
PIN diode circuit performance at RF frequencies is predictable and should conform closely to the design equations. When a switch is not performing satisfactorily, the
fault is often not due to the PIN diode but to other circuit
limitations such as circuit loss, bias circuit interaction or
lead length problems (primarily when shunt PIN diodes
are employed).
It is good practice in a new design to first evaluate the
circuit loss by substituting alternatively a wire short or
open in place of the PIN diode. This will simulate the
circuit performance with “ideal PIN diodes.” Any deficiency in the external circuit may then be corrected before inserting the PIN diodes.
PIN Diode Attenuators
In an attenuator application the resistance characteristic
of the PIN diode is exploited not only at its extreme high
and low values as in switches but at the finite values in
between.
Figure 19
Typical Diode Resistance vs. Forward Current
PIN diode attenuator circuits are used extensively
in automatic gain control (AGC) and RF leveling
applications as well as in electronically controlled
attenuators and modulators. A typical configuration
of an AGC application is shown in Figure 20. The
PIN diode attenuator may take many forms ranging
from a simple series or shunt mounted diode acting
as a lossy reflective switch or a more complex
structure that maintains a constant matched input
impedance across the full dynamic range of the
attenuator.
The resistance characteristic of a PIN diode when forward biased to IF1 depends on the I-region width (W)
carrier lifetime (τ), and the hole and electron mobilities
(µP, µn) as follows:
For a PIN diode with an I-region width of typically 250
µm, carrier lifetime of 4 µS, and µn of .13, µp of .05 m2 /
v•s, Figure 19 shows the RS vs. current characteristic.
Figure 20
RF AGC/Leveler Circuit
11
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Commitment to produce in volume is not guaranteed.
changes to the product(s) or information contained herein without notice.
AG312
Design with PIN Diodes
Although there are other methods for providing AGC
functions such as varying the gain of the RF transistor
amplifier, the PIN diode approach generally results in
lower power drain, less frequency pulling, and lower RF
signal distortion. The latter results are especially true,
when diodes with thick I-region s and long carrier lifetimes are used in the attenuator circuits. Using these
PIN diodes, one can achieve wide dynamic range attenuation with low signal distortion at frequencies ranging
from below 1 MHz up to well over 1 GHz.
Rev. V3
exceeding a decade. Figures 21 and 22 show typical
quadrature hybrid circuits employing series and shunt
connected PIN diodes. The following equations summarize this performance:
Quadrature Hybrid (Series Connected PIN Diodes)
Quadrature Hybrid (Shunt Connected PIN Diodes)
Reflective Attenuators
An attenuator may be designed using single series or
shunt connected PIN diode switch configurations as
shown in figure 21. These attenuator circuits utilize the
current controlled resistance characteristic of the PIN
diode not only in its low loss states (very high or low resistance) but also at in-between, finite resistance values.
The attenuation value obtained using these circuits may
be computed from the following equations:
Attenuation of Series Connected PIN Diode Attenuator
Attenuation of Shunt Connected PIN Diode Attenuator
These equations assume the PIN diode to be purely resistive. The reactance of the PIN diode capacitance,
however, must also be taken into account at frequencies
where its value begins to approach the PIN diode resistance value.
Matched Attenuators
Attenuators built from switch design are basically reflective devices which attenuate the signal by producing a
mismatch between the source and the load. Matched
PIN diode attenuator designs, which exhibit constant
input impedance across the entire attenuation range, are
also available which use either multiple PIN diodes biased at different resistance points of band-width-limited
circuits utilizing tuned elements. They are described as
follows:
Quadrature Hybrid Attenuators
Although a matched PIN attenuator may be achieved by
combining a ferrite circulator with one of the previous
simple reflective devices, the more common approach
makes use of quadrature hybrid circuits. Quadrature hybrids are commonly available at frequencies from below
10 MHz to above 1 GHz, with bandwidth coverage often
Figure 21
SPST PIN Diode Switches
12
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and/or prototype measurements. Commitment to develop is not guaranteed.
Visit www.macomtech.com for additional data sheets and product information.
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Commitment to produce in volume is not guaranteed.
changes to the product(s) or information contained herein without notice.
AG312
Design with PIN Diodes
Rev. V3
The quadrature hybrid design approach is superior to the
circulator coupled attenuator from the standpoint of lower
cost and the achievement of lower frequency operation.
Because the incident power is divided into two paths, the
quadrature hybrid configuration is also capable of handling twice the power and this occurs at the 6 dB attenuation point. Each load resistor, however, must be
capable of dissipating one half the total input power at
the time of maximum attenuation.
Both the above types of hybrid attenuators offer good
dynamic range. The series connected diode configuration is, however, recommended for attenuators used primarily at high attenuation levels (greater than 6 dB) while
the shunt mounted diode configuration is better suited for
low attenuation ranges.
Constant impedance attenuator circuit. The power incident on
port A divides equally between ports B and C, port D is isolated. The mismatch produced by the PIN Diode resistance in
parallel with the load resistance at ports B and C reflects part
of the power. The reflected power exits ports D isolating port
A. Therefore, A appears matched to the input signal.
Figure 23
Quadrature Hybrid Matched Attenuator
(Shunt Connected Pin Diodes)
Quarter-Wave Attenuators
A matched attenuator may also be built using quarterwave techniques. Figures 24 and 25 show examples of
these circuits. For the quarter-wave section a lumped
equivalent may be employed at frequencies too low for
practical use of line lengths. This equivalent is shown in
Figure 26.
The performance equations for these circuits are given
below:
Figure 22
Quarter-Wave Attenuator (Series Connected Diode)
Quadrature Matched Hybrid Attenuator
(Series Connected Diodes)
Quadrature hybrid attenuators may also be constructed
without the load resistor attached in series or parallel to
the PIN diode as shown. In these circuits the forward
current is increased from the 50 Ω, maximum attenuation / RS value to lower resistance values. This results in
increased stored charge as the attenuation is lowered
which is desirable for lower distortion. The purpose of
the load resistor is both to make the attenuator less sensitive to individual diode differences and increase the
power handling capability by a factory of two.
A matched condition is achieved in these circuits when
both diodes are at the same resistance. This condition
should normally occur when using similar diodes since
they are DC series connected, with the same forward
bias current flowing through each diode. The series circuit of Figure 24 is recommended for use at high attenuation levels while the shunt diode circuit of Figure 25
is better suited for low attenuation circuits.
13
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is considering for development. Performance is based on target specifications, simulated results,
• India Tel: +91.80.43537383
• China Tel: +86.21.2407.1588
and/or prototype measurements. Commitment to develop is not guaranteed.
Visit www.macomtech.com for additional data sheets and product information.
PRELIMINARY: Data Sheets contain information regarding a product M/A-COM Technology
Solutions has under development. Performance is based on engineering tests. Specifications are
typical. Mechanical outline has been fixed. Engineering samples and/or test data may be available. M/A-COM Technology Solutions Inc. and its affiliates reserve the right to make
Commitment to produce in volume is not guaranteed.
changes to the product(s) or information contained herein without notice.
AG312
Design with PIN Diodes
Rev. V3
Bridged TEE and PI Attenuators
For matched broadband applications, especially
those covering the low RF (1 MHz) through UHF,
attenuator designs using multiple PIN diodes are
employed. Commonly used for this application are
the bridged TEE and PI circuits shown in Figures
27 and 28.
Figure 24
Quarter Wave Matched Attenuator
(Series Connected Diodes)
Figure 27
Bridged Tee Attenuator
The attenuation obtained using a bridged TEE circuit
may be calculated from the following:
Where:
Figure 25
Quarter Wave Matched Attenuator
(Shunt Connected Diodes)
Figure 28
PI Attenuator
(The π and Tee are broadband matched
attenuator circuits.)
Figure 26
Lumped Circuit Equivalent
of Quarter Wave Line
The relationship between the forward resistance of the
two diodes insures maintenance of a matched circuit at
all attenuation values.
14
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and/or prototype measurements. Commitment to develop is not guaranteed.
Visit www.macomtech.com for additional data sheets and product information.
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Solutions has under development. Performance is based on engineering tests. Specifications are
typical. Mechanical outline has been fixed. Engineering samples and/or test data may be available. M/A-COM Technology Solutions Inc. and its affiliates reserve the right to make
Commitment to produce in volume is not guaranteed.
changes to the product(s) or information contained herein without notice.
AG312
Design with PIN Diodes
The expressions for attenuation and matching conditions
for the PI attenuator are given as follows:
Where:
Using these expressions, Figure 29 gives a graphical
display of diode resistance values for a 50 Ω PI attenuator. Note that the minimum value for RS1 and RS2 is 50
Ω. In both the bridged TEE and PI attenuators, the PIN
diodes are biased at two different resistance points simultaneously which must track in order to achieve proper
attenuator performance.
Rev. V3
PIN Diode Phase Shifters
PIN diodes are utilized as series or shunt connected
switches in phase shifter circuit designs. In such cases,
the elements switched are either lengths of transmission
line or reactive elements. The criteria for choosing PIN
diodes for use in phase shifters is similar to those used in
selecting diodes for other switching applications. One
additional factor, however, that must often be considered, is the possibility of introducing phase distortion
particularly at high RF power levels or low reverse bias
voltages. Of significant note is the fact that the properties inherent in PIN diodes which yield low distortion, i.e.,
a long carrier lifetime and thick I-regions, also result in
low phase distortion of the RF signal. Three of the most
common types of semiconductor phase shifter circuits,
namely: the switched line, loaded line and hybrid coupled
designs are described as follows:
A. Switched Line Phase Shifter
A basic example of a switched line phase shifter circuit is
shown in Figure 30. In this design, two SPDT switches
employing PIN diodes are used to change the electrical
length of transmission line by some length. The phase
shift obtained from this circuit varies with frequency and
is a direct function of this differential line length as shown
below:
The switched line phase shifter is inherently a broadband
circuit producing true time delay, with the actual
phase shift dependent only on Δ
Because
of
PIN
diode capacitance limitations
this design is most
frequently used at frequencies below 1 GHz.
Figure 29
Attenuation of PI Attenuators
PIN diode switches and attenuators may be used as RF
amplitude modulators. Square wave or pulse modulation
use PIN diode switch designs whereas linear modulators
use attenuator designs.
The design of high power or distortion sensitive modulator applications follows the same guidelines as their
switch and attenuator counterparts. The PIN diodes they
employ should have thick I-regions and long carrier lifetimes. Series connected or preferably back-to-back configurations always reduce distortion. The sacrifice in
using these devices will be lower maximum frequencies
and higher modulation current requirements.
The quadrature hybrid design is recommended as a
building block for PIN diode modulators. Its inherent
built-in isolation minimizes pulling and undesired phase
modulation on the driving source.
Figure 30
Switched Line Phase Shifter
15
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• India Tel: +91.80.43537383
• China Tel: +86.21.2407.1588
and/or prototype measurements. Commitment to develop is not guaranteed.
Visit www.macomtech.com for additional data sheets and product information.
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Solutions has under development. Performance is based on engineering tests. Specifications are
typical. Mechanical outline has been fixed. Engineering samples and/or test data may be available. M/A-COM Technology Solutions Inc. and its affiliates reserve the right to make
Commitment to produce in volume is not guaranteed.
changes to the product(s) or information contained herein without notice.
AG312
Design with PIN Diodes
The power capabilities and loss characteristics of the
switched line phase shifter are the same as those of a
series connected SPDT switch. A unique characteristic
of this circuit is that the power and voltage stress on
each diode is independent of the amount of differential
phase shift produced by each phase shifter. Thus, four
diodes are required for each bit with all diodes having the
same power and voltage ratings.
B. Loaded Line Phase Shifter
The loaded line shifter design shown in Figure 31 operates on a different principle than the switched line phase
shifter. In this design the desired maximum phase shift
sections, each containing a pair of PIN diodes which do
not completely pertubate the main transmission line. A
major advantage of this phase shifter is its extremely
high power capability due partly to the use of shunt
mounted diodes plus the fact that the PIN diodes are
never in the direct path of the full RF power.
Figure 31
Rev. V3
Where:
Ømax = maximum phase angle
PL = power transmitted
VBR = diode breakdown voltage
IF = diode current rating
The above factors limit the maximum phase shift angle in
practical circuits to about 45°. Thus, a 180°C phase shift
would require the use of four 45° phase shift sections in
its design.
C. Reflective Phase Shifter
A Circuit design which handles both high RF power and
large incremental phase shifts with the fewest number of
diodes is the hybrid coupled phase shifter shown in figure 32. The phase shift for this circuit is given below:
Figure 32
Loaded Line Phase Shifter
Hybrid Coupler Reflective Phase Shifter
In loaded line phase shifters, a normalized susceptance,
Bn, is switched in and out of the transmission path by the
PIN diodes. Typical circuits use valurd of Bn, much less
than unity, thus resulting in considerable decoupling of
the transmitted RF power from the PIN diode. The
phase shift for a single section is given as follows:
The voltage stress on the shunt PIN diode in this circuit
also depends on the amount of desired phase shift or
“bit” size. The greatest voltage stress is associated with
the 180° bit and is reduced by the factor (sinØ/2)1/2 for
other bit sizes. The relationship between maximum
phase shift, transmitted power, and PIN diode ratings is
as follows:
The maximum phase shift obtainable from a loaded line
section is limited by both bandwidth and diode power
handling considerations. The power constraint on obtainable phase shift is shown as follows:
In comparison to the loaded line phase shifter, the hybrid
design can handle up to twice the peak power when using the same diodes. In both hybrid and loaded line designs, the power dependency of the maximum bit size
relates to the product of the maximum RF current and
peak RF voltage the PIN diodes can handle. By judicious choice of the nominal impedance in the plane of
16
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• China Tel: +86.21.2407.1588
and/or prototype measurements. Commitment to develop is not guaranteed.
Visit www.macomtech.com for additional data sheets and product information.
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Solutions has under development. Performance is based on engineering tests. Specifications are
typical. Mechanical outline has been fixed. Engineering samples and/or test data may be available. M/A-COM Technology Solutions Inc. and its affiliates reserve the right to make
Commitment to produce in volume is not guaranteed.
changes to the product(s) or information contained herein without notice.
AG312
Design with PIN Diodes
the nominal impedance in the plane of the PIN diode, the
current and voltage stress can usually be adjusted to be
within the device ratings. In general, this implies lowering the nominal impedance to reduce the voltage stress
in favor of higher RF currents. For PIN diodes, the maximum current rating should be specified or is dependent
upon the power dissipation rating while the maximum
voltage stress at RF frequencies is dependent on Iregion thickness.
PIN Diode Distortion Model
The beginning sections of this article concerned with
large signal operation and thermal considerations allows
the circuit designer to avoid conditions that would lead to
significant changes in PIN diode performance or excessive power dissipation. A subtle but often significant
operating characteristic is the distortion or change in
signal shape which is always produced by a PIN diode in
the signal it controls.
The primary cause of distortion is any variation or nonlinearity of the PIN diode impedance during the period of
the applied RF signal. These variations could be in the
diode’s forward bias resistance, RS, parallel resistance,
RP, capacitance, CT, or the effect of the low frequency IV characteristic. The level of distortion can range from
better than 100 dB below, to levels approaching the desired signal. The distortion could be analyzed in a fourier
series and takes the traditional form of harmonic distortion of all orders, when applied to a single input signal,
and harmonic intermodulation distortion when applied to
multiple input signals.
Non-linear, distortion generating behavior is often desired in PIN and other RF oriented semiconductor diodes. Self-biasing limiter diodes are often designed as
thin I-region PIN diodes operating near or below their
transmit time frequency. In a detector or mixer diode the
distortion that results from the ability of the diode to follow its I-V characteristic at high frequencies is exploited.
In this regard the term “square law detector” applied to a
detector diode implies a second order distortion generator. In the PIN switch circuits discussed at the beginning
of this article, and the attenuator and other applications
discussed here, methods of selecting and operating PIN
diodes to obtain low distortion are described.
There is a common misconception that minority carrier
lifetime is the only significant PIN diode parameter that
affects distortion. This is indeed a major factor, but another important parameter is the width of the I-region,
which determines the transit time of the PIN diode. A
diode with a long transmit time will have more of a tendency to retain its quiescent level of stored charge. The
longer transmit time of a thick PIN diode reflects its ability
to follow stored charge model for PIN diode resistance
Rev. V3
according to:
Where:
IF = forward bias current
τ = carrier lifetime
W = I region width
µn = electron mobility
µp = hole mobility
Rather than the non-linear I-V characteristic.
The effect of a carrier lifetime on distortion related to the
quiescent level of stored charge induced by the DC
forward bias current and the ratio of this stored charge to
the incremental stored charge added or removed by the
RF signal.
Distortion in PIN Diode Switches
The distortion generated by a forward biased PIN diode
switch has been analyzed* and has been shown to be
related to the ratio of stored charge to diode resistance
and the operating frequency. Prediction equations for
the second order intermodutation intercept point (IP2)
and the third order intermodutation intercept point (IP3)
have been developed from PIN semiconductor analysis
are presented as follows:
Where:
F = frequency
RS = PIN diode resistance ohms
Q = Stored charge in nC
In most applications, the distortion generated by a reversed biased diode is smaller than forward biased generated distortion for small or moderate signal size. This
is particularly the case when the reverse bias applied to
the PIN diode is larger than the peak RF voltage preventing any instantaneous swing into the forward bias direction.
Distortion produced in a PIN diode circuit may be reduced by connecting an additional diode in a back to
back orientation, (cathode to cathode or anode to anode). This results in a cancellation of distortion currents.
17
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• India Tel: +91.80.43537383
• China Tel: +86.21.2407.1588
and/or prototype measurements. Commitment to develop is not guaranteed.
Visit www.macomtech.com for additional data sheets and product information.
PRELIMINARY: Data Sheets contain information regarding a product M/A-COM Technology
Solutions has under development. Performance is based on engineering tests. Specifications are
typical. Mechanical outline has been fixed. Engineering samples and/or test data may be available. M/A-COM Technology Solutions Inc. and its affiliates reserve the right to make
Commitment to produce in volume is not guaranteed.
changes to the product(s) or information contained herein without notice.
AG312
Design with PIN Diodes
The cancellation should be total, but distortion produced
by each PIN diode is not exactly equal in magnitude and
opposite in phase. Approximately 20 dB distortion improvement may be expected by this back to back configuration.
Distortion in Attenuator Circuits
In attenuator applications, distortion is directly relatable
to the ratio of RF to DC stored charge. In such applications, PIN diodes operated only in the forward bias state
and often at high resistance values where the stored
charge may be very low. Under these operating conditions, distortion will vary with charges in the attenuation
level. Thus, PIN diodes selected for use in attenuation
circuits need only be chosen for their thick I-region width,
since the stored charge at any fixed diode resistance,
Rs1, is only dependent on this dimension.
Consider an MA4PH451 PIN diode used in an application where a resistance of 50 Ω is desired. The
MA4PH451 datasheet indicates the 1 mA is the typical
diode current at which this occurs. Since the typical carrier lifetime for this diode is ≈ 5 µS, the stored charge for
the MA4PH451 diode at 50 Ω is 5 nC. If two MA4PH451
PIN diodes, however are inserted in series, to achieve
the same 50 Ω resistance level, each diode must be biased at 2 mA. This results in a stored charge of 10 nC
per diode or a net stored charge of 20 nC. Thus, adding
a second diode in series multiplies the effective stored
charge by a factor of 4. This would have a significant
positive impact on reducing the distortion produced by
attenuator circuits.
Measuring Distortion
Because distortion levels are often 50 dB or more below
the desired signal, special precautions are required in
order to make accurate second and third order distortion
measurements. One must first ensure that the signal
sources used are free of distortion and that the dynamic
range of the spectrum analyzer employed is adequate to
measure the specified level of distortion. These requirements often lead to the use of fundamental frequency
band stop frequencies at the device output as well as
pre-selectors to clean up the signal sources employed.
In order to establish the adequacy of the test equipment
and signal sources for making the desired distortion
measurements, the test circuit should be initially evaluated by removing the diodes and replacing them with
passive elements. This approach permits one to optimize the test setup and establish basic measurement
limitations.
Rev. V3
Second order distortion, caused by the mixing of two
input signals, will appear at the sum and difference of
these frequencies and may also be filtered. As an aid to
identifying the various distortion signals seen on a spectrum analyzer, it should be noted that the level of a second distortion signal will vary directly at the same rate as
any change of input signal level. Thus, a 10 dB signal
increase will cause a corresponding 10 dB increase in a
second order distortion.
Third order intermodulation distortion of two input signals
at frequencies FA and FB often produce in-band, nonfilterable distortion components at frequencies of 2FA - FB
and 2FB - FA. This type of distortion is particularly troublesome in receivers located nearby transmitters operating on equally spaced channels. In identifying and
measuring such signals, it should be noted that third order distortion signal levels vary at twice the rate of
change of the fundamental signal frequency. Thus a 10
dB change in input signal will result in a 20 dB change of
third order signal distortion power observed on a spectrum analyzer.
*G. Hiller, R.Caverly, “Predict Distortions Intercept Points in PIN
Diode Switches,” Microwaves and RF, Dec. 1985 and Jan.
1986.
References
 Garver, Robert V., “Microwave Control Devices,”
Artech House, Inc., Dedham, MA., 1976.
 Mortenson, K.E., and Borrego, J.M., “Design Performance and Application of Microwave Semiconductor Control Components,” Artech House, Inc,
Dedham, MA, 1972.
 Watson, H.A., “Microwave Semiconductor Devices
and their Circuit Applications.” McGraw Hill Book
Co., New York, NY., 1969.
 White, Joseph F., “Semiconductor Control,” Artech
House, Inc., Dedham, MA., 1977.
 Caverly, R.H., Hiller, G., “Distortion in PIN Diode
Control Circuits” IEEE Trans MIT, May 1987.
 Hiller, G., Caverly, R.H., “Establishing Reverse Bias
for PIN Diodes in High Power Switches,” IEEE Trans
MIT, Dec. 1990.
Since harmonic distortion appears only at multiples of the
signal frequency, these signals may be filtered out in
narrow band systems.
18
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• China Tel: +86.21.2407.1588
and/or prototype measurements. Commitment to develop is not guaranteed.
Visit www.macomtech.com for additional data sheets and product information.
PRELIMINARY: Data Sheets contain information regarding a product M/A-COM Technology
Solutions has under development. Performance is based on engineering tests. Specifications are
typical. Mechanical outline has been fixed. Engineering samples and/or test data may be available. M/A-COM Technology Solutions Inc. and its affiliates reserve the right to make
Commitment to produce in volume is not guaranteed.
changes to the product(s) or information contained herein without notice.