Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
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1 SPECIFICA~ION
3 Background of the Invention
This invention relates to an improved comparator circuit
6 particularly adaptable for implementation as an integrated
7 circuit device using complementary metal-oxide-silicon (CMOS)
8 technology.
9 Comparators have long been used extensively as building
10 blocks in electronic circuits for the purpose of comparing and
11 amplifying the difference between two signal sources, as for
12 example, in analog to digital conversion circuits. Often this
13 difference between two signal sources is required to be sensed
14 at a very rapid rate. Such speed requirements became especially
15 difficult to obtain in the attempted implementation of compara-
16 tor circuits as part of larger integrated circuit devices where
17 the difference in the signal values is small. Previous attempts
18 to achieve relatively high speed are described, for example, in
19 IEEE Journal of Solid State Operation Circuits, Feb. 1979,
20 pp. 38-46, and Memorandum No. UCB/ERL M7~/27 24 May 1978,
21 College of Engineering, University of California, Berkeley, CA,
2" Page 128. However, such circuits as disclosed therein require
23 a relatively large amount of integrated circuit 'Ichip'' area and
24 also large amounts of power. In providing a comparator as part
25 of a monolithic integrated circuit, such as a "codec" for use
26 in digital transmission, such e~cessive requirements for chip
27 area and power are not desirable. The present invention solves
28 this problem.
29 It is therefore one object of the present invention to
30 provide an improved comparator circuit particularly adaptable
31 for implementation as an integrated circuit device.
32 Another object of the invention is to provide a compara-
33 tor which has a high resolution capability with high speed,
3~ (e.g., a comparator capable of resolving less than 3~ ~V in
35 less than 2 ~secs.)
Still another object of the invention is to provide a
37 comparator having good common mode rejection characteristics
38 which is an important criteria for high resoluti~n systems.
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Another object of the invention is to provide a comparator with rela-
tively low power dissipation using Class A-B drive for the output.
; A comparator according to the principles of the present invention
comprises a CMOS circuit consisting of four stages. The first stage is an input
preamplifier in the form of a differential amplifier which receives the two
input signals to be compared. Connected to this differential amplifier is a
source follower stage that provides a low impedance output which drives an-
other differential amplifier. This second differential amplifier drives as
connected to a level shift stage to drive another cascoded gain stage. The
input preamplifier is a high gain, broad banded stage that serves to deliver,
with speed, a relatively large signal to the succeeding gain stages which in
turn are designed to respond rapidly to large signal stimuli. The broadbanding
is achieved by the source followers which buffer the input capacitance of
elements from the second differential amplifier. Diode clamping is used to
force the preamplifier to remain in the saturation region to provide adequate
gain during operation with a relatively small voltage differential between the
; two input signals and also a relatively fast response for the input stage.
In summary, the present invention is an electronic comparator circuit
comprising: a first differential amplifier stage having a relatively high outputimpedance including: a first current source; an inverting input leg containing
a load device, an inverting input transistor having an inverting input lead,
and a first output node; and a noninverting input leg containing a load de-
vice, a noninverting input transistor having a noninverting input lead, and a
second output node; a second differential amplifier stage having a relatively
high input capacitance including: a second current source, an inverting leg
containing a load device and an inverting transistor having an inverting input
lead; and a noninverting leg containing a load device, a noninverting transis-
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tor having a noninverting input lead, and a third output node; an impedance
converting stage for reducing the relatively high output impedance of said first
differential amplifier stage to drive the high input capacitance of said
second differential amplifier stage, said impedance converting stage containing
a first and a second leg, said firs~ leg of said impedance converting stage
containing a fourth output node, a third current source and a transistor
having its control electrode connected to said first output node of said in-
verting input leg of said first differential amplifier stage, said fourth out-
put node of said first leg of said impedance converting stage being connected
to said noninverting input lead of said second differential amplifier stage,
said second leg of said impedance converting stage containing a fifth output
node, a fourth current source, and a transistor having its control electrode
connected to said second output node of said noninverting input leg of said
first differential amplifier stage, said fifth output node of said second leg
of said impedance converting stage being connected to said inverting input
lead of said second differential amplifier stage; a level shift stage having
an input lead connected to said third output node of said second differential
amplifier stage, and having a sixth output node; and an output stage including
a first output transistor having its control electrode connected to said third
output node of said second differential amplifier stage, a second output
transistor having its control electrode connected to said sixth output node
of said level shift stage, a third output transistor having its control elec-
trode connected to a voltage source, and a seventh output node.
~ith reference to the drawing, a circuit diagram is sho~n for a com-
parator 10 embodying principles of the present invention which are particu-
larly adapted for implementation as part of a monolithic integrated circuit
semiconductor device. In broad terms, the circuit comprises a first differen-
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tial amplifier section 12 which is essentially an input preamplifier that re-
ceives the two voltage inputs to be compared. Connected to the amplifier
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section 12 is a source-follower stage 14 which supplies inputs to a second dif-
ferential amplifier section 16. The latter is connec~ed through a level shift
network 18 to a third cascoded gain stage 20 that provides the circuit output.
All of the aforesaid circuit components may be comprised of MOSFET
elements as part of a monolithic integrated circuit structure. Thus, as shown,
all circuit elements are connected between V~D and Vss power leads 22 and 24.
The first differential amplifier 12 is comprised of a constant current MOSFET
26 having its drain connected to the Vss power line 24 and its source connected
to a lead 28 that also interconnects the drains of each of a pair of signal
input ~OS~ETS 30 and 32. The gate of MOS~ET 30 is connected ~ia lead 34 to an
input signal source to be compared, and the gate of MOSFET 32 is connected b~ a
; lead 36 to ground. The source leads o~ MOSFETS 30 and 32 are connected by a
pair of leads 38 and 40 to the drain terminals of another pair of MOSFETS 42
and 44. The source terminals of each of these latter MOS~ETS 42 and 44 are
connected to the VD~ power lead 22 and their gates are interconnected by a lead
46. A lead 48 from this lead 46 extends to the interconnecting lead 38 between
MOSFETS 30 and 42. In two separate leads extending between leads 38 and 40 are
two clamping diodes 50 and 52 which are important to the operation of the cir-
cuit.
The source-follower stage 14 comprises a first pair of MOSFET de-
vices 54 and 56 connected in series between the power leads 22 and 24 and a
second pair of MOSFET devices 58 and 60 that are similarly connected. The gate
of MOSPET 54 is connected to a junction 62 in the lead 38 of ~he first differ-
ential amplifier which is also the junction for one end of the interconnecting
lead from diode 50. The otber end of the lead from diode 50 is connected to a
junction 64 in ~he interconnecting lead 40. This latter junction is also con-
nected to the gate of the source-follower MOSFET 58. The gate of MOSFET 56 is
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supplied with a ~ias voltage VBB and is connected to the gate of the differen-
tial amplifier MOSFET 26 whose gate in turn is also connected to source-follow-
er MOSFET 60.
The source-follower MOSFETS 54 and 55 are interconnected by a lead
66 and the MOSFETS 58 and 60 are similarl~ interconnected by a lead 68. Con-
nected to and extending from these leads 66 a~d 68 is a pair of leads 70 and 72
respectively, extending to the gates of a pair of MOSFETS 7~ and 76. These
latter MOSFETS are the input devices for the second differential amplifier 16.
The drain leads of ~hese latter MOSFETS 74 and 76 are interconnected by a lead
78 which is connected to the source of a ~OSFET 80 whose drain is connected to
the Vss power line 24. The gate of MOSFEI' 80 is colmected to the gate of the
source-follower device 60 and thus to the bias voltage V~B. Connected to the
sources of MOSFETS 7~ and 76 by a pair of leads 82 and 8~ respectively, are the
drains of another pair of MOSFETS 86 and 88. The source leads of these latter
devices 86 and 88 are connected to the V~v power line 22 and the gates of
MOSFETS 86 and 88 are interconnected by a lead 90 ~hich is connec~ed by a lead
92 to a junction 9~ in the lead 82.
As described above, the second differential amplifler 16 is con-
nected to a level shift network 18 comprising a pair of ~OS~ETS 96 and 98 con-
nected in series between the power leads 22 and 2~. The gate of MOSFET 96 is
connected to a lead 100 from an output junction 102 in the lead 84 of the sec-
ond differential amplifier 16. The ga~e of ~OSFET 98 is connected to the lead
104 which is also connected to the gate of MOSPETS 26, 60 and 80 and in turn
to the bias voltage VBB. The two MOSFETS g6 and 98 are interconnected by a
lead 106 and an output junction 108 therein is connected to the gate of a
MOSFET 110 of the cascoded gain stage 20 of the comparator 10.
The latter gain stage 20 also includes ~OSFETS 112 and 11~ which
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are connected in series with MOSFET 110 between ~he power leads 22 and 24. The
gate of ~OSFET 112 is connected to the lead 100 from the second differential
amplifier 16 and the gate of MOSFET 114 is connected to ground. The MOSFETS 110
and 114 are interconnected by a lead 116~ having a junction 118 which provides
the output signal from the comparator 10.
In operation, when power is supplied across the leads 22 and 24, all
of the circuit elements are "on" and ready to operate. An input signal is ap-
plied to the gate of input MOS~ET 34 and the gate of input MOSFET 32 is ground-
ed. This causes the difference of the input signals to be amplified b~ the
first differential amplifier 12, and this amplified signal i9 present at junc-
tion 64. The function of the diodes 50 and 52 is to maintain or clamp node 64
within one diode voltage drop from node 62. This clamping limits the voltage
excursion of node 64 and thus keeps the first differential amplifier stage 12
in the saturation region of operation longer. Thus, this first differential
amplifier stage can recover faster from the linear region of operation, for ex-
ample, when a large differential input signal was present on its input and the
input leads 34 and 36 are then presented with small differential input signals
of the opposite polarity.
The output signal appearing on nodes 62 and 64 of the differential
amplifier 12 drives the source-follower MOSFETS 54, 56, 58 and 60. The source-
follower 14 buffers the output signal from the first differential stage 12 from
the input capacitance of the second differential stage 16. The input capaci-
tance of the second differential stage 16 can be large due to Miller multipli
cation of the gate drain overlap capacitance of the MOSFETS. Thus~ the source
follower stage 14 serves to "broadband" the first gain stage or differential
amplifier 12 providing increased circuit speed.
The output of the source follo~er stage 14 directly drives the in-
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put MOSFETS 74 and 76 of second gain stage or differential amplifier 16. This
stage 16 does not require diode clamping since it is designed to handle large
vol~age swings. This stage lG drives the flnal gain stage 20. The final gain
stage 20 is a cascoded stage, thus reducing the input capacitance of this final
stage 20 and thus increasing the band~idth o~ the comparator lO.
The cascode stage 20 comprises ~OSFETS 112, 11~, and 110. ~OSFET
114 limits the signal swing and thus the gain on the node between ~OS~ETS 112
and 114. This reduces the input capasitance of this gain stage. The ~OSFETS
96 and 98 are connected between the second and third gain stages so that power
is conserved by causing the ~hird ga~n stage-~OS~ETS 110 and 112 to operate in
Class A-B mode ~i.e., when 110 tends to turn on, 112 tends to turn off and vice
versa.~
[n summary, it is seen that the comparator circuit 10 operates to
receive and compare relatively small signals which are amplified by stages
which allow relatively large input signal swings. Thu~j the circuit has a wide
range of performance that can be applied to a variety of uses; and it also com-
prises relatively few components that can be compactly arranged in an integrated
circuit semiconductor device.
In one embodiment of the comparator according to this invention an
overall gain of 125 dB was achieved with 25 M~lz unit gain bandwidth. Compared
with prior art comparator circuits, this is a relativel~ high gain for a large
bandwidth.
To those skilled in the art to which this invention relates, many
changes in construction and widely differing embodiments and applications of
the invention will suggest themselves without departing from ~he spirit and
scope of the invention. The disclosures and the description herein are purely
illustrative and are not intended to be in any sense llmitlng.
