U.S. patent application number 13/753544 was filed with the patent office on 2014-07-31 for relaxation oscillator with self-biased comparator.
The applicant listed for this patent is Anand Kumar Sinha, Sanjay K. Wadhwa. Invention is credited to Anand Kumar Sinha, Sanjay K. Wadhwa.
Application Number | 20140210564 13/753544 |
Document ID | / |
Family ID | 51222260 |
Filed Date | 2014-07-31 |
United States Patent
Application |
20140210564 |
Kind Code |
A1 |
Sinha; Anand Kumar ; et
al. |
July 31, 2014 |
RELAXATION OSCILLATOR WITH SELF-BIASED COMPARATOR
Abstract
A relaxation oscillator for generating an output clock signal
includes an RC circuit, a self-biased comparator stage, and a logic
circuit. The RC circuit generates first and second comparator input
signals that are provided to the self-biased comparator stage. The
self-biased comparator stage includes first and second input stages
and a voltage reference circuit. Each of the first and second input
stages in conjunction with the voltage reference circuit forms a
comparator, i.e., first and second comparators corresponding to the
first and second input stages, respectively. The self-biased
comparator stage generates first and second comparator output
signals, based on the first and second comparator input signals.
The first and second comparator output signals are provided to the
logic circuit that generates the output clock signal.
Inventors: |
Sinha; Anand Kumar; (Noida,
IN) ; Wadhwa; Sanjay K.; (Noida, IN) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
Sinha; Anand Kumar
Wadhwa; Sanjay K. |
Noida
Noida |
|
IN
IN |
|
|
Family ID: |
51222260 |
Appl. No.: |
13/753544 |
Filed: |
January 30, 2013 |
Current U.S.
Class: |
331/111 ;
327/50 |
Current CPC
Class: |
H03K 3/0231
20130101 |
Class at
Publication: |
331/111 ;
327/50 |
International
Class: |
H03K 3/36 20060101
H03K003/36 |
Claims
1. A relaxation oscillator for generating an output clock signal,
comprising: a resistor-capacitor (RC) circuit for generating first
and second comparator input signals and receiving first and second
control signals; a self-biased comparator stage connected to the RC
circuit for generating first and second comparator output signals,
the self-biased comparator stage comprising: a self-biased
comparator for receiving the first and second comparator input
signals and generating first and second intermediate output signals
and the first and second comparator output signals, wherein the
self-biased comparator comprises: a first input stage for receiving
the first comparator input signal and generating the first
intermediate output signal, wherein the first input stage includes:
a first transistor having a source terminal for receiving a supply
voltage; and a second transistor having a drain terminal connected
to a drain terminal of the first transistor, and a gate terminal
for receiving the first comparator input signal, wherein the first
intermediate output signal is generated at the drain terminals of
the first and second transistors; a second input stage for
receiving the second comparator input signal and generating the
second intermediate output signal, wherein the second input state
includes: a third transistor having a source terminal for receiving
the supply voltage; and a fourth transistor having a drain terminal
connected to a drain terminal of the third transistor, a gate
terminal for receiving the second comparator input signal, and a
source terminal connected to a source terminal of the second
transistor, wherein the second intermediate output signal is
generated at the drain terminals of the third and fourth
transistors; a voltage reference circuit for generating a voltage
bias signal, wherein the voltage reference circuit comprises: a
fifth transistor having a source terminal for receiving the supply
voltage, a gate terminal connected to a gate terminal of the third
transistor, and a drain terminal connected to a gate terminal of
the first transistor and the gate terminal of the third transistor,
wherein the voltage bias signal is generated at the drain terminal
of the fifth transistor; and a sixth transistor having a drain
terminal connected to the drain terminal of the fifth transistor, a
gate terminal for receiving a reference voltage, and a source
terminal connected to the source terminals of the second and fourth
transistors; a seventh transistor having a drain terminal connected
to the source terminals of the second, fourth, and sixth
transistors; and a first resistor having a first terminal connected
to a source terminal of the seventh transistor and a second
terminal connected to ground; an eighth transistor having a source
terminal for receiving the supply voltage, and a gate terminal
connected to the gate and drain terminals of the first and fifth
transistors, respectively; a ninth transistor having a drain
terminal connected to a drain terminal of the eighth transistor, a
gate terminal connected to the drain terminal thereof and to a gate
terminal of the seventh transistor, and a source terminal connected
to ground; a tenth transistor having a source terminal for
receiving the supply voltage, and a gate terminal connected to the
drain terminals of the first and second transistors for receiving
the first intermediate output signal; an eleventh transistor having
a drain terminal connected to a drain terminal of the tenth
transistor, a gate terminal connected to the drain terminals of the
eighth and ninth transistors, and a source terminal connected to
ground, wherein the first comparator output signal is generated at
the drain terminals of the tenth and eleventh transistors; a
twelfth transistor having a source terminal for receiving the
supply voltage, and a gate terminal connected to the drain
terminals of the third and fourth transistors for receiving the
second intermediate output signal; and a thirteenth transistor
having a drain terminal connected to a drain terminal of the
twelfth transistor, a gate terminal connected to the gate terminals
of the seventh and ninth transistors, and a source terminal
connected to ground, wherein the second comparator output signal is
generated at the drain terminals of the twelfth and thirteenth
transistors.
2. The relaxation oscillator of claim 1, wherein the first, third,
fifth, eighth, tenth, twelfth transistors are p-channel metal-oxide
semiconductor (PMOS) transistors.
3. The relaxation oscillator of claim 1, wherein the second,
fourth, sixth, seventh, ninth, eleventh, thirteenth transistors are
n-channel metal-oxide semiconductor (NMOS) transistors.
4. The relaxation oscillator of claim 1, further comprising a logic
circuit connected to the self-biased comparator stage for receiving
the first and second comparator output signals and generating the
first and second control signals and the output clock signal,
wherein the logic circuit transmits the first and second control
signals to the RC circuit.
5. A self-biased comparator stage for generating first and second
comparator output signals, the self-biased comparator stage
comprising: a self-biased comparator for receiving first and second
comparator input signals and generating first and second
intermediate output signals and the first and second comparator
output signals, wherein the self-biased comparator comprises: a
first input stage for receiving the first comparator input signal
and generating the first intermediate output signal, wherein the
first input stage includes: a first transistor having a source
terminal for receiving a supply voltage; and a second transistor
having a drain terminal connected to a drain terminal of the first
transistor, and a gate terminal for receiving the first comparator
input signal, wherein the first intermediate output signal is
generated at the drain terminals of the first and second
transistors; a second input stage for receiving the second
comparator input signal and generating the second intermediate
output signal, wherein the second input state includes: a third
transistor having a source terminal for receiving the supply
voltage; and a fourth transistor having a drain terminal connected
to a drain terminal of the third transistor, a gate terminal for
receiving the second comparator input signal, and a source terminal
connected to a source terminal of the second transistor, wherein
the second intermediate output signal is generated at the drain
terminals of the third and fourth transistors; a voltage reference
circuit for generating a voltage bias signal, wherein the voltage
reference circuit comprises: a fifth transistor having a source
terminal for receiving the supply voltage, a gate terminal
connected to a gate terminal of the third transistor, and a drain
terminal connected to a gate terminal of the first transistor and
the gate terminal of the third transistor, wherein the voltage bias
signal is generated at the drain terminal of the fifth transistor;
and a sixth transistor having a drain terminal connected to the
drain terminal of the fifth transistor, a gate terminal for
receiving a reference voltage, and a source terminal connected to
the source terminals of the second and fourth transistors; a
seventh transistor having a drain terminal connected to the source
terminals of the second, fourth, and sixth transistors; and a first
resistor having a first terminal connected to a source terminal of
the seventh transistor and a second terminal connected to ground;
an eighth transistor having a source terminal for receiving the
supply voltage, and a gate terminal connected to the gate and drain
terminals of the first and fifth transistors, respectively; a ninth
transistor having a drain terminal connected to a drain terminal of
the eighth transistor, a gate terminal connected to the drain
terminal thereof and to a gate terminal of the seventh transistor,
and a source terminal connected to ground; a tenth transistor
having a source terminal for receiving the supply voltage, and a
gate terminal connected to the drain terminals of the first and
second transistors for receiving the first intermediate output
signal; an eleventh transistor having a drain terminal connected to
a drain terminal of the tenth transistor, a gate terminal connected
to the drain terminals of the eighth and ninth transistors, and a
source terminal connected to ground, wherein the first comparator
output signal is generated at the drain terminals of the tenth and
eleventh transistors; a twelfth transistor having a source terminal
for receiving the supply voltage, and a gate terminal connected to
the drain terminals of the third and fourth transistors for
receiving the second intermediate output signal; and a thirteenth
transistor having a drain terminal connected to a drain terminal of
the twelfth transistor, a gate terminal connected to the gate
terminals of the seventh and ninth transistors, and a source
terminal connected to ground, wherein the second comparator output
signal is generated at the drain terminals of the twelfth and
thirteenth transistors.
6. The self-biased comparator stage of claim 5, wherein the
self-biased comparator stage is connected to a resistor-capacitor
(RC) circuit.
7. The self-biased comparator stage of claim 6, wherein the RC
circuit is associated with a relaxation oscillator.
8. The self-biased comparator stage of claim 7, wherein the first
and second comparator input signals are generated by the RC
circuit.
9. The self-biased comparator stage of claim 8, wherein the first
and second comparator output signals are provided to a logic
circuit associated with the relaxation oscillator.
10. The self-biased comparator stage of claim 9, wherein the logic
circuit generates an output clock signal based on the first and
second comparator output signals.
Description
BACKGROUND OF THE INVENTION
[0001] The present invention generally relates to relaxation
oscillators, and, more particularly, to a relaxation oscillator
with a self-biased comparator.
[0002] Relaxation oscillators are widely used in modern electronic
systems including radios, telecommunications, computers, and other
electronic systems to generate oscillator signals. The oscillator
signals are required to meet timing critical requirements such as
modulation and demodulation of message signals in communication
systems, synchronous operation of electronic circuits, and so
forth. A conventional relaxation oscillator includes a
resistor-capacitor (RC) circuit connected to a power supply, first
and second comparators, and a logic circuit. The RC circuit
includes a resistor and first and second capacitors. The first and
second capacitors are connected to the first and second comparators
to provide first and second capacitor voltages to negative
terminals of the first and second comparators, respectively. The
first and second comparators receive a threshold voltage generated
by a resistor-divider circuit connected between a power supply and
ground or receive a suitably divided bandgap reference voltage. The
first and second capacitors are alternately charged by the power
supply by way of the resistor. When a capacitor voltage
corresponding to the first capacitor reaches the threshold voltage,
the corresponding comparator that receives the capacitor voltage
trips and causes a transition in an output signal generated by the
comparator. Subsequently, the first capacitor discharges and
simultaneously the second capacitor is charged until its capacitor
voltage reaches the threshold voltage. Thereafter, the charging and
discharging of the first and second capacitors is repeated. The
logic circuit is connected to outputs of the first and second
comparators and generates an oscillator signal based on transitions
in output signals generated by the first and second comparators and
control signals for charging and discharging the first and second
capacitors.
[0003] The first and second comparators require a current source to
operate, which occupies silicon area and consumes power. Since cost
and battery life of electronic devices have placed strict
constraints on system-on-a-chip (SoC) area and power consumption,
having separate circuits for the first and second comparators and
the current source considerably increases the area and power
consumed by the SoC. Additionally, propagation delays of the first
and second comparators vary substantially across process corners,
which leads to a variation in the frequency of the oscillator
signal and deterioration in the fidelity of the oscillator
signal.
[0004] Therefore, it would be advantageous to have a relaxation
oscillator that has low frequency spread across low supply voltage
and process and temperature corners, that consumes less power, has
a small area footprint, and that overcomes the above-mentioned
limitations of existing relaxation oscillators.
BRIEF DESCRIPTION OF THE DRAWINGS
[0005] The following detailed description of the preferred
embodiments of the present invention will be better understood when
read in conjunction with the appended drawings. The present
invention is illustrated by way of example, and not limited by the
accompanying figures, in which like references indicate similar
elements.
[0006] FIG. 1 is a schematic block diagram of a relaxation
oscillator in accordance with an embodiment of the present
invention; and
[0007] FIG. 2 is a detailed schematic circuit diagram of a
self-biased comparator stage in accordance with an embodiment of
the present invention.
DETAILED DESCRIPTION OF THE PRESENT INVENTION
[0008] The detailed description of the appended drawings is
intended as a description of the currently preferred embodiments of
the present invention, and is not intended to represent the only
form in which the present invention may be practiced. It is to be
understood that the same or equivalent functions may be
accomplished by different embodiments that are intended to be
encompassed within the spirit and scope of the present
invention.
[0009] In an embodiment of the present invention, a relaxation
oscillator for generating an output clock signal is provided. The
relaxation oscillator includes a resistor-capacitor (RC) circuit
for generating first and second comparator input signals and
receiving first and second control signals. A self-biased
comparator stage is connected to the RC circuit for generating
first and second comparator output signals. The self-biased
comparator stage includes a self-biased comparator that receives
the first and second comparator input signals and generates first
and second intermediate output signals. The self-biased comparator
includes a first input stage for receiving the first comparator
input signal and generating the first intermediate output signal.
The first input stage includes: a first transistor having a source
terminal for receiving a supply voltage and a second transistor
having a drain terminal connected to a drain terminal of the first
transistor, and a gate terminal for receiving the first comparator
input signal. The first intermediate output signal is generated at
the drain terminals of the first and second transistors. The
self-biased comparator further includes a second input stage for
receiving the second comparator input signal and generating the
second intermediate output signal. The second input stage includes:
a third transistor having a source terminal for receiving the
supply voltage and a fourth transistor having a drain terminal
connected to a drain terminal of the third transistor, a gate
terminal for receiving the second comparator input signal, and a
source terminal connected to a source terminal of the second
transistor. The second intermediate output signal is generated at
the drain terminals of the third and fourth transistors.
[0010] The self-biased comparator further includes a voltage
reference circuit for generating a voltage bias signal. The voltage
reference circuit includes fifth and sixth transistors of which the
fifth transistor has a source terminal for receiving the supply
voltage, a gate terminal connected to a gate terminal of the third
transistor, and a drain terminal connected to a gate terminal of
the first transistor and the gate terminal of the third transistor.
The voltage bias signal is generated at the drain terminal of the
fifth transistor. The sixth transistor has a drain terminal
connected to the drain terminal of the fifth transistor, a gate
terminal for receiving a reference voltage, and a source terminal
connected to the source terminals of the second and fourth
transistors. The self-biased comparator stage further includes a
seventh transistor having a drain terminal connected to the source
terminals of the second, fourth, and sixth transistors; a first
resistor having a first terminal connected to a source terminal of
the seventh transistor and a second terminal connected to ground;
an eighth transistor having a source terminal for receiving the
supply voltage, and a gate terminal connected to the gate and drain
terminals of the first and fifth transistors, respectively; a ninth
transistor having a drain terminal connected to a drain terminal of
the eighth transistor, a gate terminal connected to the drain
terminal thereof and to a gate terminal of the seventh transistor,
and a source terminal connected to ground; a tenth transistor
having a source terminal for receiving the supply voltage, and a
gate terminal connected to the drain terminals of the first and
second transistors for receiving the first intermediate output
signal; and an eleventh transistor having a drain terminal
connected to a drain terminal of the tenth transistor, a gate
terminal connected to the drain terminals of the eighth and ninth
transistors, and a source terminal connected to ground. The first
comparator output signal is generated at the drain terminals of the
tenth and eleventh transistors.
[0011] The self-biased comparator stage further includes a twelfth
transistor having a source terminal for receiving the supply
voltage, and a gate terminal connected to the drain terminals of
the third and fourth transistors for receiving the second
intermediate output signal and a thirteenth transistor having a
drain terminal connected to a drain terminal of the twelfth
transistor, a gate terminal connected to the gate terminals of the
seventh and ninth transistors, and a source terminal connected to
ground. The second comparator output signal is generated at the
drain terminals of the twelfth and thirteenth transistors.
[0012] In another embodiment of the present invention, a
self-biased comparator stage is provided. The self-biased
comparator stage includes a self-biased comparator for receiving
first and second comparator input signals and generating first and
second intermediate output signals. The self-biased comparator
includes a first input stage for receiving the first comparator
input signal and generating the first intermediate output signal.
The first input stage includes: a first transistor having a source
terminal for receiving a supply voltage and a second transistor
having a drain terminal connected to a drain terminal of the first
transistor, and a gate terminal for receiving the first comparator
input signal. The first intermediate output signal is generated at
the drain terminals of the first and second transistors.
[0013] The self-biased comparator further includes a second input
stage for receiving the second comparator input signal and
generating the second intermediate output signal. The second input
stage includes: a third transistor having a source terminal for
receiving the supply voltage and a fourth transistor having a drain
terminal connected to a drain terminal of the third transistor, a
gate terminal for receiving the second comparator input signal, and
a source terminal connected to a source terminal of the second
transistor. The second intermediate output signal is generated at
the drain terminals of the third and fourth transistors. The
self-biased comparator further includes a voltage reference circuit
for generating a voltage bias signal. The voltage reference circuit
includes fifth and sixth transistors of which the fifth transistor
has a source terminal for receiving the supply voltage, a gate
terminal connected to a gate terminal of the third transistor, and
a drain terminal connected to a gate terminal of the first
transistor and the gate terminal of the third transistor. The
voltage bias signal is generated at the drain terminal of the fifth
transistor. The sixth transistor has a drain terminal connected to
the drain terminal of the fifth transistor, a gate terminal for
receiving a reference voltage, and a source terminal connected to
the source terminals of the second and fourth transistors. The
self-biased comparator stage further includes a seventh transistor
having a drain terminal connected to the source terminals of the
second, fourth, and sixth transistors; a first resistor having a
first terminal connected to a source terminal of the seventh
transistor and a second terminal connected to ground; an eighth
transistor having a source terminal for receiving the supply
voltage, and a gate terminal connected to the gate and drain
terminals of the first and fifth transistors, respectively; a ninth
transistor having a drain terminal connected to a drain terminal of
the eighth transistor, a gate terminal connected to the drain
terminal thereof and to a gate terminal of the seventh transistor,
and a source terminal connected to ground; a tenth transistor
having a source terminal for receiving the supply voltage, and a
gate terminal connected to the drain terminals of the first and
second transistors for receiving the first intermediate output
signal; and an eleventh transistor having a drain terminal
connected to a drain terminal of the tenth transistor, a gate
terminal connected to the drain terminals of the eighth and ninth
transistors, and a source terminal connected to ground. The first
comparator output signal is generated at the drain terminals of the
tenth and eleventh transistors.
[0014] The self-biased comparator stage further includes a twelfth
transistor having a source terminal for receiving the supply
voltage, and a gate terminal connected to the drain terminals of
the third and fourth transistors for receiving the second
intermediate output signal and a thirteenth transistor having a
drain terminal connected to a drain terminal of the twelfth
transistor, a gate terminal connected to the gate terminals of the
seventh and ninth transistors, and a source terminal connected to
ground. The second comparator output signal is generated at the
drain terminals of the twelfth and thirteenth transistors.
[0015] Various embodiments of the present invention provide a
relaxation oscillator that includes a resistor-capacitor (RC)
circuit, a self-biased comparator stage, and a logic circuit. The
RC circuit generates first and second comparator input signals that
are provided to the self-biased comparator stage. The self-biased
comparator stage includes first and second input stages and a
voltage reference circuit. Each of the first and second input
stages form a comparator (i.e., the first and second comparators
corresponding to the first and second input stages, respectively),
in conjunction with the voltage reference circuit (a
delta-V.sub.GS/R current reference circuit). Since, the first and
second comparators and the voltage reference circuit are formed as
a single module (i.e., the self-biased comparator stage) and the
voltage reference circuit is shared by the first and second
comparators, considerable reduction in power consumption and area
footprint of the relaxation oscillator is realized. Additionally,
the integration enables operation of the relaxation oscillator
using a low voltage power supply.
[0016] The first and second comparators receive first and second
comparator input signals and a voltage bias signal (a reference
current) generated by the voltage reference circuit. The first and
second comparators generate first and second intermediate output
signals, that are transmitted to first and second gain stages,
respectively. The first and second gain stages provide gain to the
first and second intermediate output signals to generate first and
second comparator output signals that are transmitted to the logic
circuit. The logic circuit generates an output clock signal based
on the first and second comparator output signals. The design of
the self-biased comparator stage ensures smooth and consistent
transitions in the first and second intermediate output signals at
a predetermined threshold voltage and across various process and
temperature corners, thereby ensuring a low frequency spread across
various process and temperature corners.
[0017] Referring now to FIG. 1, a schematic block diagram of a
relaxation oscillator 100, in accordance with an embodiment of the
present invention is shown. The relaxation oscillator 100 includes
a resistor-capacitor (RC) circuit 102, a self-biased comparator
stage 104, and a logic circuit 106.
[0018] The RC circuit 102 is formed using first and second
capacitors (not shown) that are connected to a power supply
V.sub.DD by way of a first resistor (not shown), respectively, in a
manner known to those of skill in the art. The first and second
capacitors are alternately charged by the power supply V.sub.DD by
way of the first resistor. The RC circuit 102 generates first and
second comparator input signals that are provided to the
self-biased comparator stage 104. The self-biased comparator stage
104 generates first and second comparator output signals that are
provided to the logic circuit 106. In an embodiment of the present
invention, the self-biased comparator stage 104 includes a
self-biased comparator for receiving the first and second
comparator input signals and generating first and second
intermediate output signals.
[0019] The logic circuit 106 receives the first and second
comparator output signals and generates first and second control
signals and an output clock signal. The logic circuit 106 transmits
the first and second control signals to the RC circuit 102. The
first and second control signals control charging and discharging
of the first and second capacitors (not shown). The logic circuit
106 includes combinational logic formed using logic gates in a
manner known to those of skill in the art.
[0020] Referring now to FIG. 2, a detailed schematic circuit
diagram of the self-biased comparator stage 104, in accordance with
an embodiment of the present invention, is shown. The self-biased
comparator stage 104 includes a self-biased comparator 202. The
self-biased comparator 202 includes first and second input stages
204 and 206, a voltage reference circuit 208, a first transistor
210, and a second resistor 212. The first input stage 204 includes
second and third transistors 214 and 216, the second input stage
206 includes fourth and fifth transistors 218 and 220, and the
voltage reference circuit 208 includes sixth and seventh
transistors 222 and 224. The self-biased comparator stage 104
further includes six transistors (eighth through thirteenth)
226-236.
[0021] A source terminal of the second transistor 214 receives a
supply voltage (V.sub.DD). A drain terminal of the third transistor
216 is connected to a drain terminal of the second transistor 214,
and a gate terminal of the third transistor 216 receives a first
comparator input signal (Cap1). In an embodiment of the present
invention, the first comparator input signal Cap1 is generated by
the RC circuit 102. A source terminal of the fourth transistor 218
receives the supply voltage V.sub.DD. A drain terminal of the fifth
transistor 220 is connected to a drain terminal of the fourth
transistor 218, and a gate terminal of the fifth transistor 220
receives a second comparator input signal (Cap2). The second
comparator input signal Cap2 is also generated by the RC circuit
102.
[0022] A source terminal of the sixth transistor 222 receives the
supply voltage V.sub.DD and a gate terminal thereof is connected to
a gate terminal of the fourth transistor 218. A drain terminal of
the seventh transistor 224 is connected to a gate terminal of the
second transistor 214, the gate terminals of the fourth and sixth
transistors 218 and 222, and a drain terminal of the sixth
transistor 222. A gate terminal of the seventh transistor 224
receives a reference voltage (V.sub.DD/2). In an embodiment of the
present invention, the reference voltage V.sub.DD/2 is generated by
a reference voltage generating circuit (not shown). A drain
terminal of the first transistor 210 is connected to source
terminals of the third, fifth, and seventh transistors 216, 220,
and 224. A first terminal of the second resistor 212 is connected
to a source terminal of the first transistor 210 and a second
terminal of the second resistor 212 is connected to ground.
[0023] A source terminal of the eighth transistor 226 receives the
supply voltage V.sub.DD and a gate terminal thereof is connected to
the drain terminals of the second and third transistors 214 and
216. A drain terminal of the ninth transistor 228 is connected to a
drain terminal of the eighth transistor 226, and a source terminal
of the ninth transistor 228 is connected to ground. A source
terminal of the tenth transistor 230 receives the supply voltage
V.sub.DD and a gate terminal thereof is connected to the drain
terminal of the sixth transistor 222. A drain terminal of the
eleventh transistor 232 is connected to a drain terminal of the
tenth transistor 230 and to gate terminals of the ninth and
eleventh transistors 228 and 232, and a source terminal of the
eleventh transistor 232 is connected to ground. The gate terminal
of the eleventh transistor 232 is further connected to a gate
terminal of the first transistor 210.
[0024] A source terminal of the twelfth transistor 234 receives the
supply voltage V.sub.DD and a gate terminal thereof is connected to
the drain terminals of the fourth and fifth transistors 218 and
220. A drain terminal of the thirteenth transistor 236 is connected
to a drain terminal of the twelfth transistor 234, a gate terminal
of the thirteenth transistor 236 is connected to the gate terminals
of the first and eleventh transistors 210 and 232, and a source
terminal of the thirteenth transistor 236 is connected to
ground.
[0025] The first, sixth, seventh, tenth, and eleventh transistors
210, 222, 224, 230, and 232 form a current reference circuit that
generates a reference current (or a voltage bias signal) at the
drain terminal of the sixth transistor 222. The sixth and tenth
transistors 222 and 230 form a p-channel metal-oxide semiconductor
(PMOS) current mirror and the first and eleventh transistors 210
and 232 form a n-channel metal-oxide semiconductor (NMOS) current
mirror. The width-to-length (W/L) ratios of the first and eleventh
transistors 210 and 232 is M:1 (in which M>1). Since, the first
and eleventh transistors 210 and 232 carry identical current
imposed by the PMOS current mirror, the first transistor 210
(having a higher W/L ratio) has a smaller value of V.sub.GS.
Therefore, a potential difference is created across the second
resistor 212 due to the difference in the V.sub.GS values of the
first and eleventh transistors 210 and 232. The potential
difference is applied across the first and second terminals of the
second resistor 212 and the reference current is generated at the
drain terminal of the sixth transistor 222 and at the drain
terminal of the tenth transistor 230. The current reference circuit
may be a (delta-V.sub.GS/R) current reference circuit which is well
known to those skilled in art.
[0026] The reference current is transmitted to the drain terminals
of the second and fourth transistors 214 and 218. The third and
fifth transistors 216 and 220 receive first and second comparator
input signals Cap1 and Cap2. The second and third transistors 214
and 216 and the sixth and seventh transistors 222 and 224 form a
first comparator that generates a first intermediate output signal
at the drain terminal of the second transistor 214, based on the
first comparator input signal Cap1. The fourth and fifth
transistors 218 and 220 and the sixth and seventh transistors 222
and 224 form a second comparator that generates a second
intermediate output signal at the drain terminal of the fourth
transistor 218, based on the second comparator input signal Cap2.
The first intermediate output signal is transmitted to the gate
terminal of the eighth transistor 226. The eighth and ninth
transistors 226 and 228 provide gain to the first intermediate
output signal to generate a first comparator output signal
(Comp_out1) at the drain terminal of the eighth transistor 226. The
second intermediate output signal is transmitted to the gate
terminal of the twelfth transistor 234. The twelfth and thirteenth
transistors 234 and 236 provide gain to the second intermediate
output signal to generate a second comparator output signal
(Comp_out2) at the drain terminal of the twelfth transistor
234.
[0027] As the current reference circuit formed by the first, sixth,
seventh, tenth, and eleventh transistors 210, 222, 224, 230, and
232 is shared between the first and second comparators, the power
consumption and area footprint of the relaxation oscillator 100 is
considerably reduced. In an embodiment of the present invention,
the first, third, fifth, seventh, ninth, eleventh, and thirteenth
transistors 210, 216, 220, 224, 228, 232, and 236 are NMOS
transistors and the second, fourth, sixth, eight, tenth, twelfth
transistors 214, 218, 222, 226, 230, and 234 are PMOS
transistors.
[0028] While various embodiments of the present invention have been
illustrated and described, it will be clear that the present
invention is not limited to these embodiments only. Numerous
modifications, changes, variations, substitutions, and equivalents
will be apparent to those skilled in the art, without departing
from the spirit and scope of the present invention, as described in
the claims.
* * * * *