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| United States Patent |
5,796,767
|
|
Aizawa
|
August 18, 1998
|
Driver circuit of light-emitting device
Abstract
A driver circuit of a light-emitting device that is able to reduce the
current consumption. This circuit includes a reference current source for
generating a reference current, a cascode current source circuit for
generating a driving current for the light-emitting device with the use of
the reference current, and an input circuit for switching the driving
current according to a data signal. The cascode current source circuit has
a first current mirror formed by first and second transistors and a second
current mirror formed by third and fourth transistors. The first
transistor is supplied with a first constant current proportional to the
reference current, and controls the second transistor so that the driving
current flows through the second transistor. The third transistor is
supplied with a second constant current proportional to the reference
current, and generates a mirror current with respect to the second
constant current. The second mirror current flows through the second
transistor as the driving current. The input circuit serves to turn on and
off the fourth transistor according to the data signal, thereby
controlling the output of the driving current to the light-emitting
device.
| Inventors:
|
Aizawa; Yukio (Tokyo, JP)
|
| Assignee:
|
NEC Corporation (Tokyo, JP)
|
| Appl. No.:
|
803370 |
| Filed:
|
February 20, 1997 |
Foreign Application Priority Data
| Current U.S. Class: |
372/38.02 |
| Intern'l Class: |
H01S 003/00 |
| Field of Search: |
372/25,38
315/209 R,209 T,219,225
|
References Cited [Referenced By]
Other References
R. Coppoolse et al., "Burst Mode Bipolar . . . to Point Passive Optical
Network at 155.52 Mbit/s", 1995 Digest of the LEOS Summer Topical
Meetings, Aug. 7-11, 1995, pp. 14-15.
Gray et al., Analysis and Design of Analog Integrated Circuits, Third
Edition, John Wiley & Sons, Inc., 1993, pp. 279-283 No month.
|
Primary Examiner: Bovernick; Rodney B.
Assistant Examiner: Wise; Robert E.
Attorney, Agent or Firm: Sughrue, Mion, Zinn, Macpeak & Seas, PLLC
Claims
What is claimed is:
1. A driver circuit of a light-emitting device comprising:
a reference current source for generating a reference current;
a cascode current source circuit for generating a driving current for said
light-emitting device with the use of said reference current;
an input circuit for switching said driving current according to a data
signal;
said cascode current source circuit having a first current mirror formed by
first and second transistors and a second current mirror formed by third
and fourth transistors;
said first transistor of said first current mirror being supplied with a
first constant current proportional to said reference current, and
controlling said second transistor so that said driving current flows
through said second transistor;
said third transistor of said second current mirror being supplied with a
second constant current proportional to said reference current, and
generating a mirror current with respect to said second constant current;
said second mirror current flowing through said fourth transistor as said
driving current;
said input circuit serving to turn on and off said fourth transistor
according to said data signal, thereby controlling said output of said
driving current to said light-emitting device.
2. A circuit as claimed in claim 1, wherein said first transistor of said
first current mirror is supplied with said first constant current through
a transistor;
and wherein said third transistor of said second current mirror is supplied
with said second constant current through another transistor.
3. A circuit as claimed in claim 1, wherein said first transistor of said
first current mirror is supplied with said first constant current through
a transistor;
and wherein said third transistor of said second current mirror is supplied
with said second constant current through the same transistor as that of
said first transistor.
4. A circuit as claimed in claim 1, wherein said input circuit includes a
timing circuit and fifth and sixth transistors;
and wherein said fifth transistor serves as a switch for turning on or off
the control of said fourth transistor of said second current mirror by
said third transistor of said second current mirror;
and wherein said fifth transistor is driven by a first timing signal from
said timing circuit;
and wherein said sixth transistor serves as a switch for turning on or off
said fourth transistor of said second current mirror;
and wherein said sixth transistor is driven by a second timing signal from
said timing circuit.
5. A circuit as claimed in claim 4, wherein said first and second timing
signals have a time delay.
6. A circuit as claimed in claims 4, wherein said timing circuit of said
input circuit includes cascaded inverters;
and wherein said first timing signal is derived from an output of said
inverters, and said second timing signal is derived from another output of
said inverters.
7. A circuit as claimed in claim 4, wherein each of said first to sixth
transistors is a MOS transistor;
and wherein said fifth MOS transistor of said input circuit has a gate
length L5 and a gate width W5, and said sixth MOS transistor of said input
circuit has a gate length L6 and a gate width W6;
and wherein L5, W5, L6, and W6 satisfy a relationship of
##EQU12##
8. A circuit as claimed in claim 1, wherein each of said first to fourth
transistors is a MOS transistor.
9. A circuit as claimed in claim 8, further comprising:
a first capacitor connected to a gate and a source of said second MOS
transistor; and
a second capacitor connected to a gate and a source of said third MOS
transistor.
10. A circuit as claimed in claim 8, wherein said fifth MOS transistor of
said input circuit has a gate applied with said first timing signal, and a
drain and a source connected to respective gates of said third and fourth
MOS transistors;
and wherein said sixth MOS transistor of said input circuit has a gate
applied with said second timing signal, and a drain and a source connected
between a gate and a source of said fourth MOS transistor.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a driver circuit of a light-emitting
device such as a Light-Emitting Diode (LED) or a Laser Diode (LD) and more
particularly, to a driver circuit of a light-emitting device applicable to
a burst-mode optical communication system for subscribers which requires
low voltage operation, low power consumption, and low cost fabrication.
2. Description of the Prior Art
FIG. 1 is a circuit diagram of a conventional driver circuit of a
light-emitting device of this sort, in which Metal-Oxide-Semiconductor
(MOS) transistors are used and to be realized on a semiconductor
integrated circuit (IC).
In FIG. 1, the conventional driver circuit is used for driving a laser
diode LD100. This circuit includes a pair of input terminals 100 and 101,
and a differential input circuit 102 to be applied with a digital data
signal for driving the laser diode LD100, a current source circuit 105 for
supplying a constant current I.sub.101 as a driving current to the laser
diode LD100 through the differential input circuit 102, and a current
source circuit 106 for supplying a constant current I.sub.102 as a dc bias
current to the laser diode LD100.
The differential input circuit 102 is formed by n-channel MOS transistors
Q101 and Q102 whose sources are coupled together, i.e., by a
source-coupled pair of MOS transistors Q101 and Q102. The digital data
signal is applied across the non-inverted input terminal 100 and the
inverted input terminal 101. The terminal 100 is connected to a gate of
the MOS transistor Q102. The terminal 101 is connected to a gate of the
MOS transistor Q101.
A drain of the transistor Q101 is connected to one end of a load resistor
R101. The other end of the resistor R101 is applied with a power supply
voltage V.sub.DD.
A drain of the transistor Q102, which serves as an output terminal of the
conventional driver circuit, is connected to the cathode of the laser
diode LD100. The anode of the laser diode LD100 is applied with the power
supply voltage V.sub.DD.
The current source circuit 105 is formed by n-channel MOS transistors Q103
and Q104 serving as a current mirror, and a reference current source 103
for supplying a constant reference current I.sub.ref1 to the transistor
Q104. The current mirror has a mirror ratio of m.sub.101.
A drain of the transistor Q103 is connected to the coupled sources of the
transistors Q101 and Q102. A source of the transistor Q103 is connected to
the ground. A drain and a gate of the transistor Q104 is connected in
common to a gate of the transistor Q103. A source of the transistor Q104
is connected to the ground. The commonly-connected drain and gate of the
transistor Q104 is connected to one end of the reference current source
103. The other end of the reference current source 103 is applied with the
power supply voltage V.sub.DD.
The current source circuit 106 is formed by n-channel MOS transistors Q105
and Q106 serving as a current mirror, and a reference current source 104
for supplying a constant reference current I.sub.ref2 to the transistor
Q106. The current mirror has a mirror ratio of m.sub.102.
A drain of the transistor Q105 is connected to the drain of the cathode of
the laser diode LD100, i.e., the output terminal of the conventional
driver circuit of FIG. 1. A source of the transistor Q105 is connected to
the ground. A drain and a gate of the transistor Q106 is connected in
common to a gate of the transistor Q105. A source of the transistor Q106
is connected to the ground. The commonly-connected drain and gate of the
transistor Q106 is connected to one end of the reference current source
104. The other end of the reference current source 104 is applied with the
power supply voltage V.sub.DD.
The operation of the conventional driver circuit of FIG. 1 is as follows:
The transistors Q103 and Q104 in the current source circuit 105 constitute
the current mirror with the mirror ratio m.sub.101 and as a result, the
transistor Q103 generates the mirror current I.sub.101, which is equal to
m.sub.101 times as much as the constant reference current I.sub.ref1,
i.e., (m.sub.101 .multidot.I.sub.ref1).
Similarly, the transistors Q105 and Q106 in the current source circuit 106
constitute the current mirror with the mirror ratio m.sub.102 and as a
result, the transistor Q105 generates the mirror current I.sub.102, which
is equal to m.sub.102 times as much as the reference current I.sub.ref2,
i.e., (m.sub.102 .multidot.I.sub.ref2).
The constant bias current I.sub.102 is set as a value lower than the
threshold current of the laser diode LD100 in order not to actually drive
the diode LD100 for light emission. The constant driving current I.sub.101
is set as a value at which the laser diode LD100 is actually driven by the
sum of the currents I.sub.101 and I.sub.102, i.e., (I.sub.101 +I.sub.102).
When the digital data signal is inputted across the input terminals 100 and
101 so that the terminal 100 is in a high level "H" and the terminal 101
is in a low level "L", the transistor Q102 is turned ON and the transistor
Q101 is turned OFF. At this time, the sum current (I.sub.101 +I.sub.102)
flows through the laser diode LD100 and the transistor Q102, thereby
actually driving the diode LD100. Thus, specific light is emitted from the
LD100.
Contrarily, when the digital data signal is inputted across the pair of
input terminals 100 and 101 so that the terminal 100 is in a low level "L"
and the terminal 101 is in a high level "H", the transistor Q102 is turned
OFF and the transistor Q101 is turned ON. At this time, only the driving
current I.sub.101 flows through the resistor R101 and the transistor Q101
and simultaneously, only the bias current I.sub.102 flows through the
laser diode LD100. No current flows through the transistor Q102. Thus, no
light is emitted from the LD100.
With the above-described conventional driver circuit of FIG. 1 has the
following problems:
Specifically, a first problem is that the current consumption of the
circuit of FIG. 1 is large, because the dc bias current I.sub.102 is
always consumed during operation independent upon the existence and
absence of light emission and because the driving current I.sub.101 is
consumed even when no light is emitted from the laser diode LD100. This
problem becomes eminent for a burst-mode optical transmitter where the
light-emitting period is very short with respect to the no light-emitting
period.
A second problem is that the optical output from the laser diode LD100
tends to contain some overshoot during the high-speed switching operation.
This is caused by the use of the analog switch formed by the transistor
Q102.
Specifically, since the MOS transistor Q102 is used for switching the
driving current I.sub.101, a spike voltage tends to occur during the
high-speed switching operation at the output terminal of the driver
circuit of FIG. 1, i.e., at the connection point of the cathode of the
diode LD100 and the drain of the transistor Q102. The spike voltage is due
to the gate-drain parasitic capacitance of the transistor Q102.
A third problem is that the available range of the driving current
I.sub.101 for linear control is narrow under the condition that the laser
diode LD100 is driven by the current I.sub.101 while keeping the mirror
ratio m.sub.101 at a fixed value with respect to the reference current
I.sub.ref1. This means that the conventional driver circuit of FIG. 1 is
not cope with light-emitting device having various current-light
conversion characteristics. This problem is caused by the following fact:
Specifically, the current mirror formed by the transistors Q103 and Q104 is
able to be rewritten to an equivalent circuit as shown in FIG. 2, where
the transistor Q102 is operating in the non-saturation (i.e., the triode
region) for the purpose of high-speed switching operation. In FIG. 2,
I.sub.out denotes an output current of the current mirror formed by the
transistors Q103 and Q104, where I.sub.out =I.sub.101, and V.sub.out
denotes an output voltage thereof.
The equivalent circuit of FIG. 2 has the I.sub.out -V.sub.out
characteristic as shown in FIG. 3. This I.sub.out -V.sub.out
characteristic is obtained by the fact that the small signal output
impedance of this equivalent circuit is approximately determined by only
the self conductance of the transistor Q103. In other words, this
I.sub.out -V.sub.out characteristic is due to the fact that the small
signal output impedance of this equivalent circuit is approximately
determined by (1/g.sub.ds), where g.sub.ds is the self conductance of the
transistor Q103.
In FIG. 3, the region B1 is the non-saturation or triode region of the
transistor Q103 and the region B2 is the saturation region thereof.
.lambda. is the output conductance of this current mirror, where
.lambda.=I.sub.out /V.sub.out.
It is seen from FIG. 3 that the output current I.sub.out varies dependent
upon the output voltage V.sub.out in the saturation region B2. This
variation of I.sub.out will be especially large in the case of
miniaturized MOS transistors, because the miniaturized MOS transistors
typically have a large output conductance .lambda.. For this reason, the
driving current I.sub.101 is readily affected by the output voltage
V.sub.out of the conventional driver circuit of FIG. 1 (i.e., by the drain
voltage of the transistor Q102).
As a result, to keep the mirror ratio m.sub.101 at a fixed value with
respect to the reference current I.sub.ref1, the available range of the
driving current I.sub.101 needs to be narrow.
A fourth problem is that the conventional driver circuit of FIG. 1 is
readily affected by the variation of the external impedance, because the
conventional driver circuit of FIG. 1 has a low output impedance. This
leads to the restriction for mounting condition of the laser diode LD100
and its relating components.
SUMMARY OF THE INVENTION
Accordingly, an object of the present invention is to provide a driver
circuit of a light-emitting device that is able to reduce the current
consumption.
Another object of the present invention is to provide a driver circuit of a
light-emitting device that is able to solve the problem relating to the
optical output waveform.
Still another object of the present invention is to provide a driver
circuit of a light-emitting device that is able to cope with
light-emitting devices having various current-light conversion
characteristics.
A further object of the present invention is to provide a driver circuit of
a light-emitting device that is able to relax the mounting restriction for
a light-emitting device and its relating components, thereby enabling the
realization of the driver circuit at a low fabrication cost.
A driver circuit of a light-emitting device according to the present
invention includes a reference current source for generating a reference
current, a cascode current source circuit for generating a driving current
for the light-emitting device with the use of the reference current, and
an input circuit for switching the driving current according to a data
signal.
The cascode current source circuit has a first current mirror formed by
first and second transistors and a second current mirror formed by third
and fourth transistors.
The first transistor of the first current mirror is supplied with a first
constant current proportional to the reference current, and controls the
second transistor of the first current mirror so that the driving current
flows through the second transistor.
The third transistor of the second current mirror is supplied with a second
constant current proportional to the reference current, and generates a
mirror current with respect to the second constant current. The second
mirror current flows through the second transistor as the driving current.
The input circuit serves to turn the fourth transistor on and off according
to the data signal, thereby controlling the output of the driving current
to the light-emitting device.
With the driver circuit of a light-emitting device according to the present
invention, first, the driving current for the light-emitting device is
realized by the mirror current generated by the second current mirror of
the cascode current source circuit. The output of the driving current thus
realized is controlled by turning on or off the fourth transistor of the
second current mirror of the cascode current source circuit with the use
of the input circuit.
Therefore, no bias current is necessary for the light-emitting device.
Also, the driving current is not supplied to the light-emitting device
when no light is emitted from the light-emitting device. As a result, the
current consumption is able to be reduced.
Second, since the output of the driving current is controlled by turning on
or off the fourth transistor of the second current mirror with the use of
the input circuit, no analog switch is used therefor. Accordingly, the
problem relating to the optical output waveform is able to be solved.
Third, because the cascode current source circuit is used for the purpose
of generating the driving current, the output current (i.e., the driving
current) of the driver circuit according to the present invention may have
almost no dependence upon the output voltage change at the output terminal
of this driver circuit. Accordingly, the available range of the driving
current can be expanded.
This means that the driver circuit according to the present invention is
able to cope with light-emitting devices having various current-light
conversion characteristics.
Fourth, because the cascode current source circuit is provided for the
purpose of generating the driving current, the output impedance of the
driver circuit according to the present invention is high. Therefore, the
driver circuit according to the present invention is difficult to be
affected by the change of the external impedance.
As a result, the driver circuit according to the present invention can
relax the mounting-condition restriction for a light-emitting device and
its relating components. This leads to a low fabrication cost.
In a preferred embodiment of the circuit according to the present
invention, the first transistor of the first current mirror is supplied
with the first constant current through a transistor, and the third
transistor of the second current mirror is supplied with the second
constant current through another transistor.
In this case, an additional advantage that the driving current generated by
the first current mirror is not affected by the turn-on and turn-off of
the fourth transistor of the second current mirror which is caused by the
input circuit.
In another preferred embodiment of the circuit according to the present
invention, the first transistor of the first current mirror is supplied
with the first constant current through a transistor, and the third
transistor of the second current mirror is supplied with the second
constant current through the same transistor.
In this case, there arises an additional advantage that the circuit
configuration is simple.
In still another preferred embodiment of the circuit according to the
present invention, the input circuit includes a timing circuit and fifth
and sixth transistors.
The fifth transistor serves as a switch for turning on or off the control
of the fourth transistor of the second current mirror by the third
transistor of the second current mirror. The fifth transistor is driven by
a first timing signal from the timing circuit.
The sixth transistor serves as a switch for turning on or off the fourth
transistor of the second current mirror. The sixth transistor is driven by
a second timing signal from the timing circuit.
The first and second timing signals preferably have a time delay, because
some problem will take place if the fifth and sixth transistors are
simultaneously turn on or off.
In a further preferred embodiment of the circuit according to the present
invention, the timing circuit of the input circuit includes cascaded
inverters. The first timing signal is derived from an output of the
inverters, and the second timing signal is derived from another output of
the inverters.
Each of the first to sixth transistors may be a Field-Effect Transistor
(FET) such as a MOS transistor, or a gallium arsenide (GaAs) FET, a
bipolar transistor, or the like, if it is capable of the corresponding
function as above.
BRIEF DESCRIPTION OF THE DRAWINGS
In order that the present invention may be readily carried into effect, it
will now be described with reference to the accompanying drawings.
FIG. 1 is a circuit diagram of a conventional driver circuit of a
light-emitting device.
FIG. 2 is an equivalent circuit diagram of the current mirror formed by the
MOS transistors Q103 and Q104 in the conventional driver circuit of FIG.
1.
FIG. 3 is a graph showing an I-V characteristic of the equivalent circuit
of FIG. 2.
FIG. 4 is a circuit diagram of a driver circuit of a light-emitting device
according to a first embodiment of the present invention.
FIG. 5 is a circuit diagram of the timing circuit of the input circuit in
the driver circuit according to the first embodiment of FIG. 4.
FIG. 6 is a circuit diagram of the inverter of the timing circuit in the
driver circuit according to the first embodiment of FIG. 4.
FIG. 7A is a timing chart of the data signal used in the driver circuit
according to the first embodiment of FIG. 4.
FIG. 7B is a timing chart of the gate voltage of the transistor Q9 in the
driver circuit according to the first embodiment of FIG. 4.
FIG. 7C is a timing chart of the gate voltage of the transistor Q10 in the
driver circuit according to the first embodiment of FIG. 4.
FIG. 7D is a timing chart of the gate voltage of the transistor Q8 in the
driver circuit according to the first embodiment of FIG. 4.
FIG. 7E is a timing chart of the optical output power of the laser diode
driven by the driver circuit according to the first embodiment of FIG. 4.
FIG. 8 is an equivalent circuit diagram of the cascode current source
circuit in the driver circuit according to the first embodiment of FIG. 4.
FIG. 9 is an I-V characteristic of the equivalent circuit of FIG. 8.
FIG. 10 is an equivalent circuit diagram of the output stage of the driver
circuit according to the first embodiment of FIG. 4.
FIG. 11 is a small signal equivalent circuit of the output stage of the
driver circuit according to the first embodiment of FIG. 4.
FIG. 12 is a circuit diagram of a driver circuit of a light-emitting device
according to a second embodiment of the present invention.
FIG. 13 is a circuit diagram of a driver circuit of a light-emitting device
according to a third embodiment of the present invention.
FIG. 14 is a circuit diagram of a driver circuit of a light-emitting device
according to a fourth embodiment of the present invention
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
Preferred embodiments of the present invention will be described below
referring to the drawings attached.
FIRST EMBODIMENT
A driver circuit of a light-emitting device according to a first embodiment
is shown in FIG. 4, in which MOS transistors are used and to be realized
on a semiconductor IC.
In FIG. 4, the driver circuit according to the first embodiment is used for
driving a laser diode LD1. This circuit includes a reference current
source 4 for generating a constant reference current I.sub.ref0, a cascode
current source circuit 1 for generating a driving current I.sub.p for the
laser diode LD1, and an input circuit 2 for switching the driving current
I.sub.p on or off according to a digital data signal DT.
The cascode current source circuit 1 has two n-channel MOS transistors Q3
and Q7 in a first stage, and three n-channel MOS transistors Q4, Q6 and Q8
in a second stage. The transistors Q3 and Q7 in the first stage constitute
a first current mirror with a first mirror ratio m.sub.1. The transistors
Q6 and Q8 in the second stage constitute a second current mirror with a
second mirror ratio m.sub.2.
The cascode current source circuit 1 further has three p-channel MOS
transistors Q1, Q2, and Q5. The transistors Q1 and Q2 serve as a third
current mirror with a mirror ratio m.sub.3. The transistors Q1 and Q5
serve as a fourth current mirror with a mirror ratio m.sub.4.
The input circuit 2 has a timing circuit 3, and two n-channel MOS
transistors Q9 and Q10. The timing circuit 3 has a configuration as shown
in FIG. 5, in which first, second, and third inverters 3a, 3b, and 3c are
connected in cascade. A gate of the transistor Q9 is applied with an
output signal from the second inverter 3b. A gate of the transistor Q10 is
applied with an output signal from the third inverter 3c, i.e., an output
signal of the timing circuit 3. Thus, the gates of the transistors Q9 and
Q10 are applied with the corresponding output signals at different
timings.
Each of the first, second, and third inverters 3a, 3b, and 3c has the same
configuration as shown in FIG. 6. As shown in FIG. 6, for example, each of
the inverters 3a, 3b, and 3c has the so-called CMOS configuration, in
which a p-channel MOS transistor Q21 and an n-channel MOS transistor Q22
are connected in series between the power supply voltage V.sub.DD and the
ground.
Specifically, a source of the transistor Q21 is applied with the power
supply voltage V.sub.DD. A drain of the transistor Q21 is connected to a
drain of the transistor Q22. A source of the transistor Q22 is connected
to the ground. Gates of the transistors Q21 and Q22 are connected in
common to an input terminal A of the inverter. Drains of the transistors
Q21 and Q22 are connected in common to an output terminal B of the
inverter.
Further, a gate and a drain of the transistor Q1 is connected in common to
one end of the constant current source 4. The other end of the source 4 is
connected to the ground. A source of the transistor Q1 is applied with the
power supply voltage V.sub.DD.
A gate of the transistor Q2 is connected to the gate of the transistor Q1.
A source of the transistor Q2 is applied with the power supply voltage
V.sub.DD. A drain of the transistor Q2 is connected to a drain of the
transistor Q3.
A gate of the transistor Q5 is connected to the gate of the transistor Q1.
A source of the transistor Q5 is applied with the power supply voltage
V.sub.DD. A drain of the transistor Q5 is connected to a drain of the
transistor Q6.
The drain and a gate of the transistor Q3 are connected in common to a gate
of the transistor Q7. A source of the transistor Q3 is connected to a
drain of the transistor Q4.
The drain and a gate of the transistor Q4 are coupled together. A source of
the transistor Q4 is connected to the ground.
The drain and a gate of the transistor Q6 are connected in common to a
drain of the transistor Q9. A source of the transistor Q6 is connected to
the ground.
A drain of the transistor Q7 is connected to the cathode of the laser diode
LD1. The anode of the diode LD1 is applied with the power supply voltage
V.sub.DD. A source of the transistor Q7 is connected to a drain of the
transistor Q8.
A gate of the transistor Q8 is connected to a source of the transistor Q9
and a drain of the transistor Q10. A source of the transistor Q10 is
connected to the ground.
A gate of the transistor Q9 is connected to the timing circuit 3, in other
words, to the output terminal of the second inverter 3b of the timing
circuit 3. A gate of the transistor Q10 also is connected to the timing
circuit 3, in other words, to the output terminal of the third inverter 3c
of the timing circuit 3.
The third current mirror formed by the transistors Q1 and Q2 supplies a
mirror current I.sub.1 to the transistors Q3 and Q4. Since the third
current mirror has the mirror ratio of m.sub.3, the mirror current I.sub.1
is equal to m.sub.3 times as much as the reference current I.sub.ref0,
i.e., I.sub.1 =m.sub.3 .multidot.I.sub.ref0.
The fourth current mirror formed by the transistors Q1 and Q5 supplies a
mirror current I.sub.2 to the transistor Q6. Since the fourth current
mirror has the mirror ratio of m.sub.4, the mirror current I.sub.2 is
equal to m.sub.1 times as much as the reference current I.sub.ref0, i.e.,
I.sub.2 =m.sub.4 .multidot.I.sub.ref0.
In the first current mirror formed by the transistors Q3 and Q7, the
current I.sub.1 flowing through the transistor Q3 serves as its reference
current. Because the gates of the transistors Q3 and Q7 are coupled
together, the voltages at the gates of the transistors Q3 and Q7 are equal
to each other, thereby turning the transistor Q7 on. Therefore it is said
that the first current mirror has a function of allowing the driving
current I.sub.p to flow through the transistor Q7.
In the second current mirror formed by the transistors Q6 and Q8, the
current I.sub.2 flowing through the transistor Q6 serves as its reference
current and therefore, a mirror current, i.e., the driving current I.sub.p
flows through the transistor Q8 under the condition that the transistor Q9
is in the ON state. Since the second current mirror has the mirror ratio
of m.sub.2, the mirror or driving current I.sub.p is equal to m.sub.2
times as much as the current I.sub.2, i.e., I.sub.p =m.sub.2
.multidot.I.sub.2.
The transistor Q9 in the input circuit 2 serves as a switch for connecting
or separating the gates of the transistors Q6 and Q8 of the second current
mirror. The transistor Q10 serves as a switch for changing the gate
voltage of the transistor Q8 between the ground and the gate voltage of
the transistor Q6, thereby switching on and off the transistor Q8 and
consequently the driving current I.sub.p.
In other words, to output the driving current I.sub.p to the diode LD1
according to the digital data signal DT, the transistors Q9 and Q10 are
alternately turned on or off by the input circuit 2.
The diode-connected transistor Q4 serves to adjust the gate voltage of the
transistors Q3 and Q7 of the first current mirror.
Next, the operation of the driver circuit according to the first embodiment
will be explained below with reference to FIGS. 7A to 7E.
Here, it is supposed that the digital data signal DT has a pulse shown in
FIG. 7A, in which the signal DT is in a low level "L" (voltage=0) between
the times T.sub.0 and T.sub.1, and is in a high level "H"
(voltage=V.sub.DD) between the times T.sub.1 and T.sub.2.
Between the times T.sub.0 and T.sub.1, since the data signal DT is in the
low level "L", the gate of the transistor Q9 is applied with the signal in
the low level "L" from the timing circuit 3 of the input circuit 2. The
gate of the transistor Q10 is applied with the signal in the high level
"H" from the timing circuit 3 thereof. As a result, the transistor Q9 is
in the "OFF" state, and the transistor Q10 is in the "ON" state.
Thus, the gates of the transistors Q6 and Q8 are separated from each other,
and the gate of the transistor Q8 is connected to the ground. Therefore,
the transistor Q8 is in the "OFF" state and the driving current I.sub.p is
not supplied to the laser diode LD1 through the transistor Q7. This means
that no light is emitted from the laser diode LD1.
At the time T.sub.1, the data signal DT is turned to the high level "H"
(V.sub.DD). Then, the gate of the transistor Q9 is applied with the signal
in the high level "H" (V.sub.DD) from the timing circuit 3 of the input
circuit 2 at the time T.sub.3. The gate of the transistor Q10 is applied
with the signal in the low level "L" (0) from the timing circuit 3 thereof
at the time T.sub.5. As a result, the transistor Q9 is turned "ON", and
the transistor Q10 is turned "OFF".
Thus, the gate of the transistor Q8 is connected to the gate of the
transistor Q6 and is separated from the ground. Then, the gate of the
transistor Q8 is applied with the gate voltage V(I.sub.p) and
consequently, the transistor Q8 is turned "ON". As a result, the driving
current I.sub.p flows through the transistor Q7 and the laser diode LD1,
thereby emitting the light from the diode LD1 at the optical output power
K(I.sub.p) at the time T.sub.7.
Due to the action of the timing circuit 2, the gate voltage of the
transistor Q9 is changed after a time delay of (T.sub.3 -T.sub.1), and the
gate voltage of the transistor Q10 is changed after a time delay of
(T.sub.5 -T.sub.1), where the delay of (T.sub.5 -T.sub.1) is longer than
that of (T.sub.3 -T.sub.1). The light emission is started after a time
delay of (T.sub.7 -T.sub.1).
When the pulse of the data signal DT is changed to the low level "L" (0) at
the time T.sub.2, the gate of the transistor Q9 is applied with the signal
in the low level "L" from the timing circuit 3. The gate of the transistor
Q10 is applied with the signal in the high level "H" from the timing
circuit 3. As a result, the transistor Q9 is turned to the "OFF" state,
and the transistor Q10 is turned to the "ON" state.
Thus, the gates of the transistors Q6 and Q8 are separated from each other,
and the gate of the transistor Q8 is connected to the ground, thereby
turning the transistor Q8 to the "OFF" state. Accordingly, the driving
current I.sub.p and therefore the emission of the light is stopped at the
time T.sub.8.
Due to the action of the timing circuit 2, the gate voltage of the
transistor Q9 is changed after a time delay of (T.sub.4 -T.sub.2), and the
gate voltage of the transistor Q10 is changed after a time delay of
(T.sub.6 -T.sub.2), where the delay of (T.sub.6 -T.sub.2) is longer than
that of (T.sub.4 -T.sub.2). The light emission is stopped after a time
delay of (T.sub.8 -T.sub.2).
As seen from FIG. 7C, both of the transistors Q9 and Q10 are in the "ON"
state between the times T.sub.3 and T.sub.5, i.e., within the time period
.DELTA.t ›=(T.sub.5 -T.sub.3)!. In this case, the gate voltage of the
transistor Q8 is not equal to the gate voltage of the transistor Q6 and as
a result, a problem that the driving current I.sub.p does not have a
specific, wanted value will occur.
However, this problem is able to be substantially solved by satisfying the
following relationship
##EQU1##
where L9 and W9 are the gate length and the gate width of the transistor
Q9, and L10 and W10 are the gate length and the gate width of the
transistor Q10, respectively. The reason is as follows:
When the ON resistances of the transistors Q9 and Q10 are defined as
R9.sub.ON and R10.sub.ON, and the gate voltages of the transistors Q6 and
Q8 are defined as V6.sub.g and V8.sub.g, respectively, the following
equation (2) is established.
##EQU2##
Here, to keep the gate voltage V8.sub.g of the transistor Q8 equal to or
higher than the 90% of the gate voltage V6.sub.g of the transistor Q6, in
other words, to satisfy the following relationship (3), the following
relationship (4) needs to be satisfied.
0.9.times.V6.sub.g .ltoreq.V8.sub.g (3)
##EQU3##
The relationship (4) is rewritten to the following expression (5) as
##EQU4##
Typically, the ON resistance of a MOS transistor is proportional to a ratio
of the gate length L to the gate width W, i.e., (L/W). Therefore, the
following relationships (6) and (7) are established.
##EQU5##
If these relationships (6) and (7) are used, the above expression (5) is
able to further rewritten to the above-described expression (1).
The relationship (3) is selected because no problem will occur in the
practical use even if both of the transistors Q9 and Q10 are in the "ON"
state between the time period .DELTA.t.
The driving current I.sub.p of the laser diode LD1 is expressed as follows
##EQU6##
where W8 and L8 are the gate width and the gate length, C.sub.ox8 is the
gate oxide capacitance per unit area, .mu. is the carrier mobility,
V.sub.th is the threshold voltage, .lambda. is the self conductance,
V.sub.ds8 is the source-to-drain voltage of the transistor Q8,
respectively.
The mirror ratio m.sub.1 is defined as a ratio of (W7/L7)/(W3/L3), i.e.,
m.sub.1 =(W7/L7)/(W3/L3), where W7 and L7 are the gate width and the gate
length of the transistor Q7, and W3 and L3 are the gate width and the gate
length of the transistor Q3, respectively.
The mirror ratio m.sub.2 is defined as a ratio of (W8/L8)/(W6/L6), i.e.,
m.sub.2 =(W8/L8)/(W6/L6), where W8 and L8 are the gate width and the gate
length of the transistor Q8, and W6 and L6 are the gate width and the gate
length of the transistor Q6, respectively.
The mirror ratio m.sub.3 is defined as a ratio of (W2/L2)/(W1/L1), i.e.,
m.sub.1 =(W2/L2)/(W1/L1), where W1 and L1 are the gate width and the gate
length of the transistor Q1, and W2 and L2 are the gate width and the gate
length of the transistor Q2, respectively.
The mirror ratio m.sub.4 is defined as a ratio of (W5/L5)/(W1/L1), i.e.,
m.sub.4 =(W5/L5)/(W1/L1), where W5 and L5 are the gate width and the gate
length of the transistor Q5, respectively.
The mirror ratio affects the accuracy of the linearity of the driving
current I.sub.p. Therefore, the accuracy of the mirror ratio will be
described below.
To cope with light-emitting devices having various current-light conversion
characteristics, the driver circuit needs to have a wide available range
of the driving current I.sub.p in which the laser diode LD1 can be
linearly controlled. This requires the small dependence of the mirror
ratio of each current mirror upon the driving current I.sub.p in the
cascode circuit 1. Thus, the dependence of the mirror ratio will be
explained below.
The cascode current source circuit 1 can be expressed as an equivalent
circuit as shown in FIG. 8 when the transistor Q9, is ON and the
transistor Q10 is OFF. FIG. 9 shows the I-V characteristic of the
equivalent circuit of FIG. 8.
With the previously-described conventional equivalent circuit of FIG. 2,
the small signal output resistance of this circuit is determined by
(1/g.sub.ds), where g.sub.ds is the self conductance of the transistor
Q103. As a result, this circuit has the I-V characteristic as shown in
FIG. 3.
However, with the equivalent circuit of FIG. 8 of the cascode current
source circuit 1 according to the first embodiment, the small signal
output resistance of this circuit is determined by
##EQU7##
where g.sub.ds1 and g.sub.ds2 are the self conductance of the transistors
Q8 and Q7, and g.sub.m1 and g.sub.m2 are the mutual conductance of the
transistors Q8 and Q7, respectively.
Generally, when a MOS transistor is operating in the saturation region, the
self conductance is in the order of 10.sup.-5 and the mutual conductance
is in the order of 10.sup.-3. Therefore, the small signal output
resistance is in the order or 10.sup.5 in the conventional equivalent
circuit of FIG. 2. On the other hand, the small signal output resistance
is in the order or 10.sup.7 in the equivalent circuit of FIG. 8 according
to the first embodiment.
This means that the small signal output resistance of FIG. 8 according to
the first embodiment is approximately 100 times as much as that of the
conventional circuit of FIG. 2.
Further, in the cascode circuit of FIG. 8, the gate-drain parasitic
capacitance (i.e., the Miller capacitance) of the transistor Q8 is low,
resulting in the good high-frequency characteristics. Therefore, both of
the transistors Q7 and Q8 are able to operate in the saturation region,
which corresponds to the region A3 in FIG. 9. The I-V characteristic is
approximately flat in the region A3.
The output conductance obtained by the I-V characteristic in FIG. 9 is
approximately (1/100) times as much as that of the I-V characteristic in
FIG. 3.
In the region A2 of FIG. 9, only the transistor Q8 is operating in the
saturation region, and the transistor Q7 is operating in the
non-saturation or triode region. In the region A1 of FIG. 9, both of the
transistors Q7 and Q8 are operating in the non-saturation or triode
region.
In the cascode circuit of FIG. 8, because of its large small-signal output
resistance, the mirror ratio of each current mirror is kept almost
unchanged, even if the output or driving current I.sub.out is changed and
as consequently, the output voltage V.sub.out (i.e., the operating point)
varies. This means that the mirror ratio has a small dependence upon the
output voltage V.sub.out and the driving current I.sub.out or I.sub.p. The
driving current I.sub.out or I.sub.p is approximately determined only by
the gate voltage of the transistor Q8.
Thus, the driver circuit according to the first embodiment is able to cope
with light-emitting devices having various current-light conversion
characteristics.
The above consideration about the cascode circuit of FIGS. 8 and 9 is
disclosed in the book entitled "Analysis and Design of Analog Integrated
Circuits", third edition, pp 279-283, written by Paul R. Gray and Robert
G. Meyer, published in 1993 by John Wiley & Sons, Inc.
For the spike voltage, which is caused by the gate-drain parasitic
capacitance of the transistor Q8 on its switching operation, the power
supply that sets the gate voltage of the transistor Q7 through the
gate-source parasitic capacitance of the transistor Q7 absorbs such the
spike voltage. Therefore, the problem about the optical output waveform is
not caused by the spike voltage.
Next, the resistance of the driver circuit according to the first
embodiment against the external impedance change will be shown below with
reference to FIGS. 10 and 11.
FIG. 10 is an equivalent circuit diagram of the output stage of the driver
circuit according to the first embodiment of FIG. 4, and FIG. 11 is a
small signal equivalent circuit thereof, in which Z1 denotes the external
impedance of this driver circuit, g.sub.m7 and g.sub.ds7 are the mutual
conductance and the self conductance of the transistor Q7, respectively, v
is a source voltage of the transistor Q7, and v' is the drain voltage of
the transistor Q7.
From FIG. 11, the following equation is obtained.
##EQU8##
A current i flowing through the external impedance Z1 is expressed as
##EQU9##
Here, the output impedance of the driver circuit according to the first
embodiment with respect to the source of the transistor Q7, i.e., the
combination of the external impedance Z1 and the impedance of transistor
Q7, is defined as Z.sub.OUT. Then, Z.sub.OUT is expressed as follows:
##EQU10##
Here, g.sub.m7 .congruent.10.sup.-3 and g.sub.ds7 .congruent.10.sup.-5, and
therefore, the equation (12) can be approximated to the following:
##EQU11##
From the equation (13), it is seen that the variation of the external
impedance Z1 is suppressed due to the self conductance of the transistor
Q7 by a factor of g.sub.ds7 (=10.sup.-5) with respect to the impedance
Z.sub.OUT.
Accordingly, the external terminal, i.e., the connection point of the
transistor Q7 and the laser diode LD1 is difficult to be affected by the
change of the external impedance Z1. Thus, (a) the jitter, which are
generated by the fact that the driver circuit drives the diode LD1 with no
bias current, (b) the ringing due to the parasitic inductance, (c) the
waveform deformation due to the parasitic capacitance are all able to be
suppressed. This leads to relaxation of the device mounting condition and
to reduction of the fabrication cost.
As described above, with the driver circuit of a light-emitting device
according to the first embodiment, the driving current I.sub.p is realized
by the first mirror current I.sub.1 generated by the first current mirror
of the cascode current source circuit 1. The supply or output of the
driving current I.sub.p is controlled by turning on or off the transistor
Q8 of the second current mirror of the cascode current source circuit 1
with the use of the input circuit 2.
Therefore, first, no bias current is necessary for the laser diode LD1. The
driving current I.sub.p is not supplied to the diode LD1 when no light is
emitted from the light-emitting device. As a result, the current
consumption is able to be reduced.
Second, no analog switch is directly connected to the laser diode LD1 for
turning on and off the driving current I.sub.p and accordingly, the
problem relating to the optical output waveform is able to be solved.
Third, the cascade current source circuit 1 is provided for the purpose of
generating the driving current I.sub.p. Therefore, the output current
I.sub.OUT of the driver circuit according to the present invention (i.e.,
the driving current I.sub.p) has almost no dependence upon the change of
the output voltage V.sub.OUT at the output terminal of the driver circuit.
Accordingly, the available range of the driving current I.sub.p can be
expanded. This means that the driver circuit according to the present
invention is able to cope with light-emitting devices having various
current-light conversion characteristics.
Fourth, because the cascade current source circuit 1 is provided for the
purpose of generating the driving current I.sub.p, the output impedance of
the driver circuit according to the present invention is high. Therefore,
this driver circuit is difficult to be affected by the change of the
external impedance. As a result, this driver circuit can relax the
mounting restriction for a light-emitting device and its relating
components. This leads to a low fabrication cost.
SECOND EMBODIMENT
FIG. 12 shows a driver circuit for driving a laser diode according to a
second embodiment.
This circuit has the same configuration as that of the first embodiment
except that a capacitor C1 is connected between the gate of the transistor
Q6 and the ground and another capacitor C2 is connected between the gate
of the transistor Q7 and the ground in a cascode current source 1A.
Therefore, for the sake of simplification, the description about the same
configuration is omitted here by adding the same reference characters to
the corresponding elements in the second embodiment of FIG. 12.
In the driver circuit according to the second embodiment, there is an
additional advantage that the fluctuation or deviation of the gate
voltages of the transistors Q6 and Q7 can be suppressed on switching
operation, in addition to the same advantages as those in the first
embodiment.
THIRD EMBODIMENT
FIG. 13 shows a driver circuit for driving a laser diode according to a
third embodiment.
This circuit has the same configuration as that of the first embodiment
except that the transistors Q5 and Q6 are omitted and that the gate of the
transistor Q8 is connected to the gate of the transistor Q4 in a cascode
current source 1B.
In the driver circuit according to the third embodiment, there is an
additional advantage that the configuration of the cascode current source
1B is simpler than that of the first embodiment, in addition to the same
advantages as those in the first embodiment.
FOURTH EMBODIMENT
FIG. 14 shows a driver circuit for driving a laser diode according to a
fourth embodiment.
This circuit has the same configuration as that of the third embodiment
except that a capacitor C3 is connected between the gate of the transistor
Q4 and the ground and another capacitor C2 is connected between the gate
of the transistor Q7 and the ground in a cascode current source 1C.
In the driver circuit according to the fourth embodiment, there is an
additional advantage that the fluctuation or deviation of the gate
voltages of the transistors Q4 and Q7 can be suppressed on switching
operation, and that the configuration of the cascode current source 1C is
simpler than that of the first embodiment, in addition to the same
advantages as those in the first embodiment.
MOS transistors are used in the above embodiments. However, bipolar
transistors, or any other transistors such as GaAs FETs may be used in the
present invention if they are able to realize the corresponding functions.
While the preferred forms of the present invention have been described, it
is to be understood that modifications will be apparent to those skilled
in the art without departing from the spirit of the invention. The scope
of the invention, therefore, is to be determined solely by the following
claims.
* * * * *
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