MOTOROLA AN211A

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SEMICONDUCTOR APPLICATION NOTE
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INTRODUCTION
There are two types of field-effect transistors, the Junction
Field-Effect Transistor (JFET) and the “Metal-Oxide
Semiconductor” Field-Effect Transistor (MOSFET), or
Insulated-Gate Field-Effect Transistor (IGFET). The
principles on which these devices operate (current controlled
by an electric field) are very similar — the primary difference
being in the methods by which the control element is made.
This difference, however, results in a considerable difference
in device characteristics and necessitates variances in circuit
design, which are discussed in this note.
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increase in channel resistance that prevents any further
increase in drain current. The drain-source voltage that
causes this current limiting condition is called the “pinchoff”
voltage (Vp). A further increase in drain-source voltage
produces only a slight increase in drain current.
The variation in drain current (ID) with drain-source
voltage (VDS) at zero gate-source voltage (VGS) is shown
in Figure 2a. In the low-current region, the drain current is
linearly related to VDS. As ID increases, the “channel” begins
to deplete and the slope of the ID curve decreases. When
the VDS is equal to Vp, ID “saturates” and stays relatively
constant until drain-to-gate avalanche, VBR(DSS) is reached.
If a reverse voltage is applied to the gates, channel pinch-off
occurs at a lower ID level (Figure 2b) because the depletion
region spread caused by the reverse-biased gates adds to
that produced by VDS. Thus reducing the maximum current
for any value of VDS.
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JUNCTION FIELD-EFFECT TRANSISTOR (JFET)
In its simplest form the junction field-effect transistor starts
with nothing more than a bar of doped silicon that behaves
as a resistor (Figure 1a). By convention, the terminal into
which current is injected is called the source terminal, since,
as far as the FET is concerned, current originates from this
terminal. The other terminal is called the drain terminal.
Current flow between source and drain is related to the
drain-source voltage by the resistance of the intervening
material. In Figure 1b, p-type regions have been diffused into
the n-type substrate of Figure 1a leaving an n-type channel
between the source and drain. (A complementary p-type
device is made by reversing all of the material types.) These
p-type regions will be used to control the current flow
between the source and the drain and are thus called gate
regions.
As with any p-n junction, a depletion region surrounds
the p-n junctions when the junctions are reverse biased
(Figure 1c). As the reverse voltage is increased, the
depletion regions spread into the channel until they meet,
creating an almost infinite resistance between the source and
the drain.
If an external voltage is applied between source and drain
(Figure 1d) with zero gate voltage, drain current flow in the
channel sets up a reverse bias along the surface of the gate,
parallel to the channel. As the drain-source voltage
increases, the depletion regions again spread into the
channel because of the voltage drop in the channel which
reverse biases the junctions. As VDS is increased, the
depletion regions grow until they meet, whereby any further
increase in voltage is counterbalanced by an increase in the
depletion region toward the drain. There is an effective
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Figure 1. Development of Junction
Field-Effect Transistors
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Figure 2. Drain Current Characteristics
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Due to the difficulty of diffusing impurities into both sides
of a semiconductor wafer, a single ended geometry is
normally used instead of the two-sided structure discussed
above. Diffusion for this geometry (Figure 3) is from one side
only. The substrate is of p-type material onto which an n-type
channel is grown epitaxially. A p-type gate is then diffused
into the n-type epitaxial channel. Contact metallization
completes the structure.
The substrate, which functions as Gate 2 of Figure 1, is
of relatively low resistivity material to maximize gain. For the
same purpose, Gate 1 is of very low resistivity material,
allowing the depletion region to spread mostly into the n-type
channel. In most cases the gates are internally connected
together. A tetrode device can be realized by not making
this internal connection.
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absence of gate voltage is extremely low because the
structure is analogous to two diodes connected back to back.
The metal area of the gate forms a capacitor with the
insulating layers and the semiconductor channel. The metal
area is the top plate; the substrate material and channel are
the bottom plate.
For the structure of Figure 4, consider a positive gate
potential (see Figure 5). Positive charges at the metal side
of the metal-oxide capacitor induce a corresponding negative
charge at the semiconductor side. As the positive charge
at the gate is increased, the negative charge “induced” in
the semiconductor increases until the region beneath the
oxide effectively becomes an n-type semiconductor region,
and current can flow between drain and source through the
“induced” channel. In other words, drain current flow is
“enhanced” by the gate potential. Thus drain current flow can
be modulated by the gate voltage; i.e. the channel resistance
is directly related to the gate voltage. The n-channel structure
may be changed to a p-channel device by reversing the
material types.
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MOS FIELD-EFFECT TRANSISTORS (MOSFET)
The metal-oxide-semiconductor (MOSFET) operates with
a slightly different control mechanism than the JFET. Figure
4 shows the development. The substrate may be high
resistivity p-type material, as for the 2N4351. This time two
separate low-resistivity n-type regions (source and drain) are
diffused into the substrate as shown in Figure 4b. Next, the
surface of the structure is covered with an insulating oxide
layer and a nitride layer. The oxide layer serves as a
protective coating for the FET surface and to insulate the
channel from the gate. However the oxide is subject to
contamination by sodium ions which are found in varying
quantities in all environments. Such contamination results
in long term instability and changes in device characteristics.
Silicon nitride is impervious to sodium ions and thus is used
to shield the oxide layer from contamination. Holes are cut
into the oxide and nitride layers allowing metallic contact to
the source and drain. Then, the gate metal area is overlaid
on the insulation, covering the entire channel region and,
simultaneously, metal contacts to the drain and source are
made as shown in Figure 4d. The contact to the metal area
covering the channel is the gate terminal. Note that there
is no physical penetration of the metal through the oxide and
nitride into the substrate. Since the drain and source are
isolated by the substrate, any drain-to-source current in the
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Figure 3. Junction FET with Single-Ended Geometry
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Figure 4. Development of Enhancement-Mode
N-Channel MOSFET
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Figure 5. Channel Enhancement. Application of
Positive Gate Voltage Causes Redistribution of Minority
Carriers in the Substrate and Results in the Formation
of a Conductive Channel Between Source and Drain
An equivalent circuit for the MOSFET is shown in Figure
6. Here, Cg(ch) is the distributed gate-to-channel capacitance
representing the nitride-oxide capacitance. Cgs is the
gate-source capacitance of the metal gate area overlapping
the source, while Cgd is the gate-drain capacitance of the
metal gate area overlapping the drain. Cd(sub) and Cs(sub)
are junction capacitances from drain to substrate and source
to substrate. Yfs is the transadmittance between drain current
and gate-source voltage. The modulated channel resistance
is rds. RD and RS are the bulk resistances of the drain and
source.
The input resistance of the MOSFET is exceptionally high
because the gate behaves as a capacitor with very low
leakage (rin 1014 Ω). The output impedance is a function
of rds (which is related to the gate voltage) and the drain
and source bulk resistances (RD and RS).
To turn the MOSFET “on”, the gate-channel capacitance,
Cg(ch), and the Miller capacitance, Cgd, must be charged.
In turning “on”, the drain-substrate capacitance, Cd(sub), must
be discharged. The resistance of the substrate determines
the peak discharge current for this capacitance.
The FET just described is called an enhancement-type
MOSFET. A depletion-type MOSFET can be made in the
following manner: Starting with the basic structure of Figure
4, a moderate resistivity n-channel is diffused between the
source and drain so that drain current can flow when the
gate potential is at zero volts (Figure 7). In this manner, the
MOSFET can be made to exhibit depletion characteristics.
For positive gate voltages, the structure enhances in the
same manner as the device of Figure 4. With negative gate
voltage, the enhancement process is reversed and the
channel begins to deplete of carriers as seen in Figure 8.
As with the JFET, drain-current flow depletes the channel
area nearest the drain first.
The structure of Figure 7, therefore, is both a
depletion-mode and an enhancement-mode device.
to the increase of carriers in the channel due to application
of gate voltage. A third type of FET that can operate in both
the depletion and the enhancement modes has also been
described.
The basic differences between these modes can most
eas i l y be unders tood by ex ami ni ng th e t r ans f er
characteristics of Figure 9. The depletion-mode device has
considerable drain-current flow for zero gate voltage. Drain
current is reduced by applying a reverse voltage to the gate
terminal. The depletion-type FET is not characterized with
forward gate voltage.
The depletion/enhancement mode type device also has
considerable drain current with zero gate voltage. This type
device is defined in the forward region and may have usable
forward characteristics for quite large gate voltages. Notice
that for the junction FET, drain current may be enhanced
by forward gate voltage only until the gate-source p-n
junction becomes forward biased.
The third type of FET operates only in the enhancement
mode. This FET has extremely low drain current flow for zero
gate-source voltage. Drain current conduction occurs for a
VGS greater than some threshold value, VGS(th). For gate
voltages greater than the threshold, the transfer
characteristics are similar to the depletion/enhancement
mode FET.
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MODES OF OPERATION
There are two basic modes of operation of FET’s —
depletion and enhancement. Depletion mode, as previously
mentioned, refers to the decrease of carriers in the channel
due to variation in gate voltage. Enhancement mode refers
Figure 7. Depletion Mode MOSFET Structure.
This Type of Device May Be Designed to Operate in
Both the Enhancement and Depletion Modes
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and characteristics are necessary to evaluate their
comparative merits from data-sheet specifications.
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Static Characteristics
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Static characteristics define the operation of an active
device under the influence of applied dc operating conditions.
Of primary interest are those specifications that indicate the
effect of a control signal on the output current. The VGS –
ID transfer characteristics curves are illustrated in Figure 9
for the three types of FETs. Figure 10 lists the data-sheet
specifications normally employed to describe these curves,
as well as the test circuits that yield the indicated
specifications.
Of additional interest is the special case of
tetrode-connected devices in which the two gates are
separately accessible for the application of a control signal.
The pertinent specifications for a junction tetrode are those
which define drain-current cutoff when one of the gates is
connected to the source and the bias voltage is applied to
the second gate. These are usually specified as VG1S(off),
Gate 1 — source cutoff voltage (with Gate 2 connected to
source), and VG2S(off), Gate 2 — source cutoff voltage (with
Gate 1 connected to source). The gate voltage required for
drain current cutoff with one of the gates connected to the
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Figure 8. Channel Depletion Phenomenon.
Application of Negative Gate Voltage Causes
Redistribution of Minority Carriers in Diffused Channel
and Reduces Effective Channel Thickness. This Results
in Increased Channel Resistance.
ELECTRICAL CHARACTERISTICS
Because the basic mode of operation for field-effect
devices differs greatly from that of conventional junction
transistors, the terminology and specifications are
necessarily different. An understanding of FET terminology
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Figure 9. Transfer Characteristics and Associated Scope Traces for the Three FET Types
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source is always higher than that for the triode-connected
case where both gates are tied together.
Reach-through voltage is another specification uniquely
applicable to tetrode-connected devices. This defines the
amount of difference voltage that may be applied to the two
gates before the depletion region of one spreads into the
junction of the other — causing an increase in gate current
to some small specified value. Obviously, reach-through is
an undesirable condition since it causes a decrease in input
resistance as a result of an increased gate current, and large
amounts of reach-through current can destroy the FET.
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Gate Leakage Current
Of interest to circuit designers is the input resistance of
an active component. For FETs, this characteristic is
specified in the form of I GSS — the reverse-bias
gate-to-source current with the drain shorted to the source
(Figure 11). As might be expected, because the leakage
current across a reverse-biased p-n junction (in the case of
a JFET) and across a capacitor (in the case of a MOSFET)
is very small, the input resistance is extremely high. At a
temperature of 25°C, the JFET input resistance is hundreds
of megohms while that of a MOSFET is even greater. For
junction devices, however, input resistance may decrease
by several orders of magnitude as temperature is raised to
150°C. Such devices, therefore, have gate-leakage current
specified at two temperatures. Insulated-gate FETs are not
drastically affected by temperature, and their input resistance
remains extremely high even at elevated temperatures.
Gate leakage current may also be specified as IGDO
(leakage between gate and drain with the source open), or
as I GSO (leakage between gate and source with the drain
open). These usually result in lower values of leakage current
and do not represent worst-case conditions. The IGSS
specification, therefore, is usually preferred by the user.
Voltage Breakdown
A variety of specifications can be used to indicate the
maximum voltage that may be applied to various elements
of a FET. Among those in common use are the following:
V(BR)GSS =
V(BR)DGO =
V(BR)DSX =
Gate-to-source breakdown voltage
Drain-to-gate breakdown voltage
Drain-to-source breakdown voltage
(normally used only for MOSFETs)
In addition, there may be ratings and specifications
indicating the maximum voltages that may be applied
between the individual gates and the drain and source (for
tetrode connected devices). Obviously, not all of these
specifications are found on every data sheet since some of
them provide the same information in somewhat different
form. By understanding the various breakdown mechanisms,
however, the reader should be able to interpret the intent
of each specification and rating. For example:
In junction FETs, the maximum voltage that may be
applied between any two terminals is the lowest voltage that
will lead to breakdown or avalanche of the gate junction. To
measure V(BR)GSS (Figure 12a), an increasingly higher
reverse voltage is applied between the gate and the source.
Junction breakdown is indicated by an increase in gate
current (beyond IGSS) which signals the beginning of
avalanche.
Some reflection will reveal that for junction FETs, the
V (BR)DGO specification really provides the same information
as V (BR)GSS. For this measurement, an increasing voltage
is applied between drain and gate. When this applied voltage
becomes high enough, the drain-gate junction will go into
avalanche, indicated either by a significant increase in drain
current or by an increase in gate current (beyond I DGO). For
both V (BR)DGO and V (BR)GSS specifications, breakdown
should normally occur at the same voltage value.
From Figure 2 it is seen that avalanche occurs at a lower
value of VDS when the gate is reverse biased than for the
zero-bias condition. This is caused by the fact that the
reverse-bias gate voltage adds to the drain voltage, thereby
increasing the effective voltage across the junction. The
maximum amount of drain-source voltage that may be
applied V DS(max) is, therefore, equal to V (BR)DGO minus
VGS, which indicates avalanche with reverse bias gate
voltage applied.
For MOSFETs, the breakdown mechanism is somewhat
different. Consider, for example, the enhancement-mode
structure of Figure 5. Here, the gate is completely insulated
from the drain, source, and channel by an oxide-nitride layer.
The breakdown voltage between the gate and any of the
other elements, therefore, is dependent on the thickness and
purity of this insulating layer, and represents the voltage that
will physically puncture the layer. Consequently, the voltage
must be specified separately.
The drain-to-source breakdown is a different matter. For
enhancement mode devices, with the gate connected to the
source (the cutoff condition) and the substrate floating, there
is no effective channel between drain and source and the
applied drain-source voltage appears across two opposed
series diodes, represented by the source-to-substrate and
substrate-to-drain junctions. Drain current remains at a very
low level (picoamperes) as drain voltage is increased until
the drain voltage reaches a value that causes reverse
(avalanche) breakdown of the diodes. This particular
condition, represented by V (BR)DSS, is indicated by an
increase in ID above the IDSS level, as shown in Figure 12b.
For depletion/enhancement mode devices, the V(BR)DSS
symbol is sometimes replaced by V (BR)DSX. Note that the
principal difference between the two symbols is the
replacement of the last subscript s with the subscript x.
Whereas the s normally indicates that the gate is shorted
to the source, the x indicates that the gate is biased to cutoff
or beyond. To achieve cutoff in these devices, a depleting
bias voltage must be applied to the gate, Figure 12b.
An important static characteristic for switching FETs is the
“on” drain-source voltage VDS(on). This characteristic for the
MOSFETs is a function of VGS, and resembles the V CE(sat)
versus IB characteristics of junction transistors. The curve
for these characteristics can be used as a design guide to
determine the minimum gate voltage necessary to achieve
a specified output logic level.
Dynamic Characteristics
Unlike the static characteristics, the dynamic
characteristics of field-effect transistors apply equally to all
FETs. The conditions and presentation of the dynamic
characteristics, however, depend largely upon the intended
application. For example, the following table indicates the
dynamic characteristics needed to adequately describe a
FET for various applications.
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Figure 10. Static Characteristics for the Three FET Types Are Defined by the Above Curves, Tables, and Test Circuits
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tr, tf
y fs The forward transadmittance is a key dynamic
characteristic for field-effect transistors. It serves as a basic
design parameter in audio and rf circuits and is a widely
accepted figure of merit for devices.
Because field-effect transistors have many characteristics
similar to those of vacuum tubes, and because many
engineers still are more comfortable with tube parameters,
the symbol gm used for tube transconductance is often
specified instead of yfs. To further confuse things, the “g”
school also uses a variety of subscripts. In addition to gm,
some data sheets show gfs while others even show g21.
Regardless of the symbol used, yfs defines the relation
between an input signal voltage and an output signal current:
It is interesting to note that yfs varies considerably with
ID due to nonlinearity in the ID – VGS characteristics. This
variation, for a typical n-channel, JFET is illustrated in Figure
14. Obviously, the operating point must be carefully selected
to provide the desired yfs and signal swing.
For tetrode-connected FETs, three yfs measurements are
usually specified on data-sheet tables. One of these, with
the two gates tied together, provides a yfs value for the
condition where a signal is applied to both gates
simultaneously; the others provide the yfs for the two gates
individually. Generally, with the two gates tied together, yfs
is higher and more gain may be realized in a given circuit.
Because of the increased capacitance, however,
gain-bandwidth product is much lower.
For rf field-effect transistors, an additional value of yfs is
sometimes specified at or near the highest frequency of
operation. This value should also be measured at the same
voltage conditions as those used for ID(on) or IDSS. Because
of the importance of the imaginary component at radio
frequencies, the high frequency yfs specification should be
a complex representation, and should be given either in the
specifications table or by means of curves showing typical
variations, as in Figure 15 for the MPF102 JFET.
The real portion of this high-frequency yfs, Re (yfs) or G21,
is usually considered a significant figure of merit.
yos Another FET parameter that offers a direct vacuum
tube analogy is yos, the output admittance:
yos = ∆ID/∆VDS
VGS = K
In this case, the analogous tube parameter is rp — i.e.,
yos = 1/rp. For depletion mode devices, yos is measured with
gate and source grounded (see Figure 16). For enhancement
mode units, it is measured at some specified VGS that
permits substantial drain-current flow.
As with yfs, many expressions are used for yos. In addition
to the obvious parallels such as y22, gos, and g22, it is also
sometimes specified as rd, where rd = 1/yos.
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The unit is the mho — current divided by voltage. Figure
13 is a typical yfs test circuit for a junction FET.
As a characteristic of all field-effect devices, yfs is
specified at 1 kHz with a VDS the same as that for which
ID(on) or IDSS is characterized. Since yfs has both real and
imaginary components, but is dominated by the real
component at low frequency, the 1 kHz characteristic is given
as an absolute magnitude and indicated as yfs.
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µ Closely related to yos and yfs is the amplification factor, µ:
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ID = K
The amplification factor does not appear on the field-effect
transistor registration format but can be calculated as yfs/yos.
For most small-signal applications, µ has little circuit
significance. It does, however, serve as a general indication
of the quality of the field-effect manufacturing process.
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Current for Typical JFETs
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Figure 15. Forward Transfer Admittance versus
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Figure 16. yos Measurement Circuit for Depletion FETs
Voltages and frequencies for measuring yos should be
exactly the same as those for measuring yfs. Like yfs, it is
a complex number and should be specified as a magnitude
at 1 kHz and in complex form at high frequencies.
8
Ciss The common-source-circuit input capacitance, Ciss,
takes the place of yis in low-frequency field-effect transistors.
This is because yis is entirely capacitive at low frequencies.
Ciss is conveniently measured in the circuit of Figure 17 for
the tetrode JFET. As with y fs , two measurements are
necessary for tetrode-connected devices.
At very high frequencies, the real component of yis
becomes important so that rf field-effect transistors should
have yis specified as a complex number at the same
conditions as other high-frequency parameters. For
tetrode-connected rf FETs, reading of both Gate 2 to source
and Gate 1 tied to Gate 2 are necessary.
In switching applications Ciss is of major importance since
a large voltage swing at the gate must appear across Ciss.
Thus, Ciss must be charged by the input voltage before
turn-on effectively begins.
Crss Reverse transfer admittance (yrs) does not appear on
FET data sheets. Instead C rss , the reverse transfer
capacitance, is specified at low frequency. Since yrs for a
field-effect transistor remains almost completely capacitive
and relatively constant over the entire usable FET frequency
spectrum, the low-frequency capacitance is an adequate
specification. Crss is measured by the circuit of Figure 18. For
tetrode FETs, values should be specified for Gate 1 and for
both gates tied together.
Again, for switching applications Crss is a critical
characteristic. Similar to the Cob of a junction transistor, Crss
must be charged and discharged during the switching
interval. For a chopper application, Crss is the feedthrough
capacitance for the chopper drive.
Cd(sub) For the MOSFET, the drain-substrate junction
capacitance becomes an important characteristic affecting
the switching behavior. Cd(sub) appears in parallel with the
load in a switching circuit and must be charged and
discharged between the two logic levels during the switching
interval.
Noise Figure (NF) Like all other active components,
field-effect transistors generate a certain amount of noise.
The noise figure for field-effect transistors is normally
specified on the data sheet as “spot noise”, referring to the
noise at a particular frequency. The noise figure will vary with
frequency and also with the resistance at the input of the
device. Typical graphs of such variations are illustrated in
Figure 19 for the 2N5458. From graphs of this kind the
designer can anticipate the noise level inherent in his design.
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Device Selection
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Figure 20. Circuit for Measuring JFET
Channel Resistance
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Figure 19. Typical Variations of FET Noise Figure with
Frequency and Source Resistance
rds(on) Channel resistance describes the bulk resistance of
the channel in series with the drain and source. From an
applications standpoint, it is important primarily for switching
and chopper circuits since it affects the switching speed and
determines the output level. To complete the confusion of
multiple symbols for FET parameters, channel resistance is
sometimes indicated as rd(on) and also as rDS and rds. In
either case, however, it is measured, for JFETs, by tying the
gates to the source, setting all terminals equal to 0 Vdc, and
applying an ac voltage from drain to source (see Figure 20).
The magnitude of the ac voltage should be kept low so that
there will be no pinchoff in the channel. Insulated-gate FETs
may be measured with dc gate bias in the enhancement
mode.
Obviously, different applications call for special emphasis
on specific characteristics so that a simple figure of merit
that compares devices for all potential uses would be hard
to formulate. Nevertheless, an attempt to pinpoint the
characteristics that are most significant for various
applications has been made* to permit a rapid, first-order
evaluation of competitive devices.
The most important single FET parameter, one that
applies for any amplifier application, is yfs. This parameter,
or one of its many variations, is specified on most data
sheets, yet some evaluation is required to come up with a
reasonable comparison. For example, in the table of
electrical characteristics on most JFET data sheets, yfs is
specified at IDSS (VGS = 0) where, for JFETs devices, yfs
is maximum. This is illustrated in Figure 14, where typical
variations of yfs as a function of ID are plotted. For some
small-signal applications, the IDSS (VGS = 0) point can
actually be used as a dc operating point because
small-signal excursions into the forward bias region will not
actually cause the gate-source junction to become
forward-biased. However, in most practical uses, some bias
is necessary to allow for the anticipated signal swing; and
it must be recognized the yfs goes down as the bias is
increased.
It is seen, also, that maximum yfs increases as I DSS
increases so that, where maximum yfs is important, a device
with a high IDSS specification is normally desirable.
On the other hand, where power dissipation is a factor
to be considered, the figure of merit yfs/V GS(off) I DSS has
been proposed. This term factors in not only I DSS, which
should be low if power dissipation is to be low, but also
V GS(off), which indicates maximum input voltage swing.
Since the signal peaks are represented by VGS = V GS(off)
and V GS = 0, the lower V GS(off), the higher the figure of
merit. And, for amplifier applications requiring a large signal
swing, V (BR)GSS/V GS(off) (assuming that V GS(off) is the
“pinch-off” voltage) is a satisfactory merit figure because it
indicates the ratio of maximum and minimum drain voltages.
* Christiansen, Donald, “Semiconductors: The New Figures of Merit,”
EEE, October, 1965.
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For high-frequency circuits, the input capacitance (C iss)
and the Miller-effect capacitance (Crss) become important,
so yfs/(C iss + C rss) indicates a relative measure of device
performance. For switching and chopper circuits, a figure of
merit is not often useful. Here the magnitudes of Ciss, C rrs,
C d(sub ) and r ds are of primary interest.
With its high input impedance, the field-effect transistor
will play an important role in input circuitry for instrumentation
and audio applications where low-impedance junction
transistors have generally been least successful.
-
Freescale Semiconductor, Inc...
Circuits
The types of circuits that can utilize FETs are practically
unlimited. In fact, many circuits designed to utilize
small–signal pentode tubes can utilize FETs with only minor
modifications. For example, the circuit in Figure 21 shows
a typical rf stage for a broadcast-band auto radio. In this
circuit, a MPF102 n-channel JFET has replaced the 12BL6
pentode normally employed. The specifications for the two
devices, including the AGC characteristics, are similar
enough to perform adequately in the circuit of Figure 21.
In an audio application, a field-effect transistor such as
the 2N5460 can be combined with a high voltage bipolar
transistor to make a simple line-operated phonograph
amplifier such as that shown in Figure 22. The ceramic
pickup is connected through a potentiometer volume control
to the field-effect transistor. Collector current of the transistor,
in turn, is set by the potentiometer in the source of the FET.
With the proper bipolar output transistor, the circuit can be
driven directly from the rectified line voltage, while the low
voltage for the FET can be derived from a voltage divider
in the power supply line.
Figure 23 shows three basic chopper circuits. The
advantage of the more complex series-shunt circuit (24c) is
that it balances out the leakage currents of the FETs in order
to reduce voltage error and is used to attain high chopping
frequencies. From an applications standpoint, the FET circuit
is superior to a junction transistor circuit in that there is no
offset voltage with the FET turned on. On the minus side,
however, the field-effect-transistor chopper generally has a
higher series resistance (rds(on)) than the junction transistor.
As newer and better FETs are introduced and as a larger
number of designers learn to use them, the range of
applications of FETs should broaden considerably.
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