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| United States Patent |
6,151,150
|
|
Kikuchi
|
November 21, 2000
|
Method and apparatus for level decision and optical receiver using same
Abstract
In a method for deciding the level of an input signal, positive and
negative signals are provided in response to the input signal. A peak of
the positive signal is detected to provide a positive-peak value. A peak
of the negative signal is detected to provide a negative-peak value. The
positive signal and the negative-peak value are combined to provide a
first combination signal. The negative signal and the positive-peak value
are combined to provide a second combination signal. The first and second
combination signals are compared to provide an output signal of zero or
one.
| Inventors:
|
Kikuchi; Osamu (Tokyo, JP)
|
| Assignee:
|
Oki Electric Industry Co., Ltd. (Tokyo, JP)
|
| Appl. No.:
|
942619 |
| Filed:
|
October 2, 1997 |
Foreign Application Priority Data
| Oct 03, 1996[JP] | 8-262624 |
| Feb 27, 1997[JP] | 9-044073 |
| Current U.S. Class: |
398/209; 375/317; 375/318; 375/319; 398/1; 398/210 |
| Intern'l Class: |
H04B 010/06 |
| Field of Search: |
359/189,194
375/317,318,319
|
References Cited [Referenced By]
U.S. Patent Documents
| 5025456 | Jun., 1991 | Ota et al. | 375/76.
|
| 5612810 | Mar., 1997 | Inami et al. | 359/189.
|
| 5892609 | Apr., 1999 | Saruwatari | 359/189.
|
Primary Examiner: Pascal; Leslie
Assistant Examiner: Lieu; Vu
Attorney, Agent or Firm: Rabin & Champagne, P.C.
Claims
What is claimed is:
1. A method for deciding the level of an input signal, comprising the steps
of:
providing positive and negative signals in response to the input signal;
detecting a peak of the positive signal to provide a positive-peak value;
detecting a peak of the negative signal to provide a negative-peak value;
combining the positive signal, the negative-peak value and a feedback
voltage, to provide a first combination signal;
combining the negative signal, the positive-peak value and the feedback
voltage, to provide a second combination signal;
comparing the first and second combination signals to provide an output
signal of zero or one;
detecting the voltage levels of the first and second combination signals;
and
generating the feedback voltage in response to the voltage levels.
2. A level decision circuit, comprising:
a differential amplifier that generates positive and negative signals in
response to an input signal;
a first peak detector that detects a peak of the positive signal to provide
a positive-peak value;
a second peak detector that detects a peak of the negative signal to
provide a negative-peak value;
a first adder that combines the positive signal, the negative-peak value
and a feedback voltage, to provide a first combination signal;
a second adder that combines the negative signal, the positive-peak value
and the feedback voltage, to provide a second combination signal;
a comparator that compares the first and second combination signals to
provide an output signal of zero or one;
a first voltage detector that detects the voltage level of the first
combination signal;
a second voltage detector that detects the voltage level of the second
combination signal; and
a feedback voltage generator that generates the feedback voltage in
response to outputs of the first and second voltage detectors, and
supplies the feedback voltage to the first and second adders.
3. An optical receiver, which generates an electrical digital signal from
an optical signal, comprising:
an O/E converter which converts the optical signal into an electrical input
signal; and
a level decision circuit which comprises:
(1) a differential amplifier which generates positive and negative signals
in response to the electrical input signal;
(2) a first peak detector which detects a peak of the positive signal to
provide a positive-peak value;
(3) a second peak detector which detects a peak of the negative signal to
provide a negative-peak value;
(4) a first adder that combines the positive signal and the negative-peak
value with a feedback signal to provide a first combination signal;
(5) a second adder that combines the negative signal and the positive-peak
value with the feedback signal to provide a second combination signal;
(6) a comparator that compares the first and second combination signals to
provide an output signal of zero or one;
(7) a first voltage detector that detects the voltage level of the first
combination signal;
(8) a second voltage detector that detects the voltage level of the second
combination signal; and
(9) a feedback voltage generator that generates the feedback voltage in
response to the outputs of the first and second voltage detectors, and
supplies the feedback voltage to the first and second adders.
Description
CROSS REFERENCE TO RELATED APPLICATION
This application claims the priority of Applications No. H09-044073, filed
Feb. 27, 1997 and H08-262624 filed Oct. 3, 1996 both in Japan. The subject
matter of each application is incorporated herein by reference.
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a signal transmission system, and more
particularly to a level decision circuit used in a signal receiver.
BACKGROUND OF THE INVENTION
For realizing an all-optical subscriber network, the PDS (Passive Double
Star) technique has been considered to be useful and important, in which
variety types of multiplexing schemes are used. In a PDS subscriber
network system, it is required to use an optical receiver which performs
AGC (Automatic Gain Control) or ATC (Automatic Threshold Control) to
process burst mode optical signals. Such an optical receiver includes a
level decision circuit, which decides the level of the input signal to
generate a digital output signal of zero or one.
In a PON (Passive Optical Network) system, burst mode signals are
transmitted from a transmitter to the optical receiver. For maintaining a
high transmission rate in the PON system, it is required to start a level
decision operation within the first several bits in the burst mode signal.
According to a conventional level decision circuit, however, in order to
maintain a high transmission rate, the structure of the circuitry becomes
complicated. Further, the duty ratio becomes worse and an output error may
occur frequently.
OBJECTS OF THE INVENTION
Accordingly, an object of the invention is to provide method and apparatus
for level decision which is easily designed to be simple so as to realize
a quick start of a level decision process without duty distortion and
without output errors.
Another object of the invention is to provide an optical receiver in which
a level decision circuit is designed to be simple so as to realize a quick
start of a level decision process without duty distortion and without
output errors.
Additional objects, advantages and novel features of the invention will be
set forth in part in the description that follows, and in part will become
apparent to those skilled in the art upon examination of the following or
may be learned by practice of the invention. The objects and advantages of
the invention may be realized and attained by means of the
instrumentalities and combinations particularly pointed out in the
appended claims.
SUMMARY OF THE INVENTION
According to a first aspect of the invention, a method for deciding the
level of an input signal includes the step of providing positive and
negative signals in response to the input signal. The method further
includes the steps of: detecting a peak of the positive signal to provide
a positive-peak value; detecting a peak of the negative signal to provide
a negative-peak value; combining the positive signal and the negative-peak
value to provide a first combination signal; and combining the negative
signal and the positive-peak value to provide a second combination signal.
The method still further includes the step of comparing the first and
second combination signals to provide an output signal of zero or one.
According to a second aspect of the invention, a level decision circuit
includes a differential amplifier which generates positive and negative
signals in response to an input signal; a first peak detector which
detects a peak of the positive signal to provide a positive-peak value;
and a second peak detector which detects a peak of the negative signal to
provide a negative-peak value. The circuit further includes a first adder
which combines the positive signal and the negative-peak value to provide
a first combination signal; and a second adder which combines the negative
signal and the positive-peak value to provide a second combination signal.
The circuit still further includes a comparator which compares the first
and second combination signals to provide an output signal of zero or one.
According to a third aspect of the invention, an optical receiver, which
generates an electrical digital signal from an optical signal, includes an
O/E converter which converts the optical signal into an electrical input
signal and a level decision circuit, which includes the same elements as
the second aspect of the invention.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a circuit diagram showing a conventional level decision circuit
using an AGC scheme.
FIG. 2 is a circuit diagram showing another conventional level decision
circuit using an ATC scheme.
FIG. 3 is a circuit diagram showing still another conventional level
decision circuit.
FIG. 4 is an explanatory view showing a PON system.
FIGS. 5A and 5B are timing charts showing the operation of the conventional
level decision circuit shown in FIG. 3.
FIG. 6 is a block diagram showing an optical receiver to which the
invention is applied.
FIG. 7 is a circuit diagram showing the structure of a level decision
circuit according to a first preferred embodiment of the invention.
FIG. 8 is a timing chart showing the operation of the first preferred
embodiment.
FIG. 9 is a circuit diagram showing the structure of a level decision
circuit according to a second preferred embodiment of the invention.
DETAILED DISCLOSURE OF THE INVENTION
For better understanding of the invention, background technology is first
described. FIG. 1 shows a conventional level decision circuit using an AGC
(Automatic Gain Control) scheme, which is generally mounted in an optical
receiver. The level decision circuit includes a gain-variable amplifier 1,
which receives an input signal and amplifies it in accordance with a
controlled gain level. The gain-variable amplifier 1 is connected at an
output terminal to a peak detector 2, which detects a peak voltage "Vpk"
of the output signal of the gain-variable amplifier 1, and to an input
terminal of a comparator 5. The peak detector 2 is connected at an output
terminal to an input terminal of an operational amplifier 3, of which the
other input terminal is connected to a control voltage source 7.
The operational amplifier 3 compares the peak voltage "Vpk" and a control
voltage "Vagc," supplied from the control voltage source 7, to generate a
gain control signal so that the peak voltage "Vpk" approximates the
control voltage "Vagc." The operational amplifier 3 is connected at an
output terminal to a time constant circuit 4, which generates a time
constant ".tau. a" for gain control of the gain-variable amplifier 1. The
time constant circuit 4 is connected at an output terminal to the
gain-variable amplifier 1. The gain-variable amplifier 1 is also supplied
with a reference voltage from a reference voltage source 6. The comparator
5 is supplied with a threshold voltage "Vth" from a reference voltage
source 8. The threshold voltage "Vth" is determined suitably to provide
the maximum SIN ratio between the control voltage "Vagc" and the output
level of the gain-variable amplifier 1 in the condition of no input. The
comparator 5 compares the output level of the gain-variable amplifier 1 to
the threshold voltage "Vth" to output a digital signal of zero or one.
FIG. 2 shows another conventional level decision circuit using ATC
(Automatic Threshold Control) scheme, which includes a differential
amplifier 11 to which an input signal is supplied. The differential
amplifier 11 is connected at positive and negative output terminals to one
end of each of resistors 13 and 14, respectively. The resistor 13 is
connected at its other end to an input terminal of an operational
amplifier 12 and a resistor 15. The resistor 14 is connected at its other
end to the other input terminal of the operational amplifier 12 and a
resistor 16. The operational amplifier 12 is connected at positive and
negative output terminals to input terminals of a limiter amplifier 18.
The positive output terminal of the operational amplifier 12 is also
connected to a peak detector 17, whose output terminal is connected to one
of the input terminals of the operational amplifier 12. The other end of
the resistor 15 is connected to the input terminal of the limiter
amplifier 18, which is also connected to the negative output terminal of
the operational amplifier 12. The differential amplifier 11 is connected
at the other input terminal to a reference voltage source 19, which is
grounded.
In the conventional level decision circuit shown in FIG. 2, negative
feedback is provided to the operational amplifier 12 to detect a mid-point
voltage of the input signal. An example of this kind of level decision
circuit is described in a report "DC Coupled Burst Mode Optical Receiver
with High Speed ATC Circuit," B-717 Nagahori et al., 1992 Autumn
Conference of The Institute of Electronics, Information and Communication
Engineers.
FIG. 3 shows another conventional level decision circuit, which includes a
comparator 21 to which an input signal is supplied, and a decision voltage
source 22 connected to an input terminal of the comparator 21. The
decision voltage source 22 provides a fixed voltage that is determined to
be slightly higher than the minimum level of the input signal. The
comparator 21 compares the input signal to the decision voltage to
generate an output signal of zero or one.
FIG. 4 shows a PON (Passive Optical Network) system including an optical
receiver to which the above-mentioned level decision circuit can be
applied. In the PON system, burst mode signals are supplied from an
optical transmitter. The burst mode signals are transmitted through a star
coupler and an optical fiber to the optical receiver. The burst mode
signal is a signal whose level (light power) varies for each time slot.
For maintaining a high transmission rate in the PON system, it is required
to start a level decision operation within first several bits in the burst
mode signal.
When the conventional level decision circuits are applied to the PON
system, the following disadvantages arise:
In the conventional level decision circuit shown in FIG. 1, it is required
that the time constant ".tau. a" is determined to be very low in order to
maintain a high transmission efficiency. Further, it is required that the
gain of the gain-variable amplifier 1 and the gain of the operational
amplifier 3 are determined to be lower to provide enough phase margin for
preventing the occurrence of oscillation. If the gain of the gain-variable
amplifier 1 and the operational amplifier 3 are set low, the error between
the control voltage "Vagc" and the peak voltage of the output signal of
the gain-variable amplifier 1 becomes large. Therefore, a great effort for
circuit design is needed.
In the conventional level decision circuit shown in FIG. 2, the negative
feedback is made with the resistors 13 to 16 and the peak detector 17, so
that an ATC operation starts quickly. However, it is required to perform
phase compensation on the circuitry for preventing the occurrence of
oscillation. As a result, the structure of the circuitry becomes
complicated, as in the case of the level decision circuit shown in FIG. 1.
In the conventional level decision circuit shown in FIG. 3, the level
decision process can be started with the first bit of the input signal,
because no feedback circuit is used, and therefore the circuitry can be
designed simply. However, the error rate does not get remarkably better
even if the amplitude of the input signal is set high, because the
decision voltage is fixed. FIG. 5A shows the relationship between the
input signal level and the output signal level when the input signal has a
lower amplitude. FIG. 5B shows the relationship between the input signal
level and the output signal level when the input signal has a higher
amplitude. As can be understood from the drawings, the duty distortion
appears remarkable when the input signal has a higher amplitude.
In addition, if an unexpected offset voltage is applied between the input
signal and the reference voltage, an output error occurs easily in any of
the conventional level decision circuits shown in FIGS. 1 to 3.
FIG. 6 shows the structure of an optical receiver 100, which includes a
PD-AMP module 110 and a level decision circuit 30. The PD-AMP module 110
includes a photo-diode, which converts an optical input signal into an
electrical signal, and a pre-amplifier, which amplifies the electrical
signal. The level decision circuit 30 generates a digital output signal in
response to the electrical signal supplied from the PD-AMP module 110.
FIG. 7 shows the structure of the level decision circuit 30, according to a
first preferred embodiment of the invention. The level decision circuit 30
includes a differential amplifier 31, to which an input signal (electrical
signal) "Vin" is supplied. The other input terminal of the differential
amplifier 31 is connected to a first reference voltage source 37. The
differential amplifier 31 is connected at a positive output terminal to an
input terminal of a first peak detector 32 and an input terminal of a
first adder 34. A negative output terminal of the differential amplifier
31 is connected to an input terminal of a second peak detector 33 and an
input terminal of a second adder 35. The first peak detector 32 is
connected at an output terminal to another input terminal of the second
adder 35. The second peak detector 33 is connected at an output terminal
to another input terminal of the first adder 34. The first adder 34 is
connected at the other input terminal to an offset voltage source 39,
which is connected to a second reference voltage source 38. The second
adder 35 is connected at the other input terminal to the second reference
voltage source 38. The output terminals of the first and second adders 34
and 35 are connected to negative and positive input terminals of a
comparator 36, respectively.
Next, the operation of the level decision circuit 30 is described in
conjunction with FIG. 8. The input signal "Vin" is amplified by the
differential amplifier 31 to provide positive and negative signals
"Vdata-p" and "Vdata-n," which have the same amplitude in the opposite
logic. The first and second peak detectors 32 and 33 detect peak voltage
values "Vpk1" and "Vpk2" of the positive signal Vdata-p and negative
signal Vdata-n, supplied from the differential amplifier 31, respectively.
The first adder 34 combines (sums) the positive signal Vdata-p and the
peak voltage "Vpk2" using a reference voltage of "Vref2+Voff" to provide a
first sum-voltage signal (combination signal) "Vsum1." The second adder 35
combines (sums) the negative signal Vdata-n and the peak signal "Vpk1"
using a reference voltage of "Vref2" to provide a second sum-voltage
signal (combination signal) "Vsum2." The sum-voltage signal "Vsum1" and
"Vsum2" are in the opposite logic to each other, and have bottom levels
(offset levels) that differ from each other by 2Voff. The comparator 36
compares the sum-voltage signals "Vsum1" and "Vsum2" to provide a digital
output signal "Vout" of zero or one. When input signals of zero are
successively inputted, the offset voltage source 39 provides a
micro-offset voltage "Voff" to shift the reference level so that the first
sum-voltage signal "Vsum1" becomes 2Voff lower than the second sum-voltage
signal "Vsum2." As a result, the signal level zero is accurately decided
(identified).
In the above-mentioned embodiment, the mid-point voltage "Vref2" of the
output of the differential amplifier 31 is used as the reference voltage
for the summing operation. The reference voltage, however, is not limited
by the mid-point voltage "Vref2" of the output of the differential
amplifier 31, but can be any other voltage in the dynamic range of the
adders 34 and 35. In the level decision circuit 30, different types of
differential amplifiers, peak detectors and adders can be used. Any values
of reference voltages, offset voltage and signal level do not limit the
invention.
According to the embodiment, the differential amplifier 31, peak detectors
32 and 33, adders 34 and 35, and comparator 36 are serially connected
without negative feedback circuits. Therefore, it is easy to design the
circuitry simple to realize a quick start of level decision process.
Further, the sum-voltage signals "Vsum1" and "Vsum2" have substantially
the same bottom level, as shown in FIG. 8, so that the comparator 36
supplies the output signal "Vout" without duty distortion. In addition,
even if the offset voltage between the input signal "Vin" and the
reference voltage "Vref1" is large, the level decision process can be
performed without output errors.
FIG. 9 shows the structure of a level decision circuit 40, according to a
second preferred embodiment of the invention. The level decision circuit
includes a differential amplifier 41, to which an input signal (electrical
signal) "Vin" is supplied. The other input terminal of the differential
amplifier 31 is connected to a first reference voltage source 47. The
differential amplifier 41 is connected at a positive output terminal to an
input terminal of a first peak detector 42 and to an input terminal of a
first adder 44. A negative output terminal of the differential amplifier
41 is connected to an input terminal of a second peak detector 43 and to
an input terminal of a second adder 45. The first peak detector 42 is
connected at an output terminal to another input terminal of the second
adder 45. The second peak detector 43 is connected at an output terminal
to another input terminal of the first adder 44. The first adder 44 is
connected at the other input terminal to a positive output terminal of an
operational amplifier 54. The second adder 45 is connected at the other
input terminal to a negative output terminal of the operational amplifier
54. The output terminals of the first and second adders 44 and 45 are
connected to negative and positive input terminals of a comparator 46,
respectively. The first adder 44 is also connected at an output terminal
to an input terminal of a voltage detector 51. The second adder 45 is also
connected at an output terminal to an input terminal of a voltage detector
52. The output terminals of the voltage detector 51 and 52 are connected
to negative and positive input terminals of a differential amplifier 53,
respectively. The operational amplifier 54 is connected at input terminals
to an output terminal of the differential amplifier 53 and to a second
reference voltage source 48. The second reference voltage source 48
supplies an offset voltage to sum-voltage signals (combination signals)
outputted from the first and second adders 44 and 45.
The input signal "Vin" is amplified by the differential amplifier 41 to
provide positive and negative signals Vdata-p and Vdata-n, which have the
same amplitude in the opposite logic. The first and second peak detectors
42 and 43 detect peak voltage signals "Vpk1" and "Vpk2" of the positive
signal Vdata-p and negative signal Vdata-n, supplied from the differential
amplifier 41, respectively. The first adder 44 combines (sums) the
positive signal Vdata-p, the peak voltage "Vpk2" and "Voff" to provide the
sum-voltage signal "Vsum1." The second adder 45 combines the negative
signal Vdata-n, the peak voltage "Vpk1" and Voff to provide the
sum-voltage signal "Vsum2." The comparator 46 compares the signals "Vsum1"
and "Vsum2" to provide a digital output signal "Vout" of zero or one. The
voltage detectors 51 and 52 detect the output voltages of the first and
second adders 44 and 45. The differential amplifier 53 generates a
feedback voltage in response to the output signals of the voltage
detectors 51 and 52. The operational amplifier 54 supplies the feedback
voltage signals to the first and second adders 44 and 45.
In FIG. 9, each of the first and second adders 44 and 45 has a single
output, however, each adder may have two output terminals. That is, each
adder has positive output terminal and a negative output terminal. For
instance, the first adder 44 may output signals of "Vsum1" and
inverted-Vsum1, and the mid-point of the two output signals is generated
by a resistance-division technique, or the like. The mid-point voltage is
supplied to the differential amplifier. According to this modification, a
stable offset voltage, which is the difference between the signals "Vsum1"
and "Vsum2" can be applied to the comparator 46 without affecting a
difference in a DC bias between the two adders, which occurs with
temperature variation.
In another modification, bottom detector circuits may be used instead of
the voltage detectors 51 and 52. The output signals of the bottom detector
circuits are supplied to the differential amplifier. According to this
modification, a more stable offset voltage, which is the difference
between the signals "Vsum1" and "Vsum2," can be provided without affecting
the differences in DC bias and gain between the two adders, and other
errors.
In the above-mentioned embodiment, the output voltage of the adders 44 and
45 are applied to the differential amplifier 53, and the output of the
differential amplifier is supplied to the operational amplifier 54. The
voltage source 48 provides an offset voltage between the signals "Vsum1"
and "Vsum2." The operational amplifier 54 outputs offset voltage signals
"Voff" and inverted-Voff, which are supplied to the first and second
adders 44 and 45, respectively. Such feedback signals function as a
micro-offset voltage to shift the reference level when input signals of
zero are successively inputted, so that the output signal of zero is
accurately outputted. Accordingly, the level decision circuit operates
stably even if a signal of zero is inputted.
According to the embodiment, it is easy to design the circuitry to be
simple, to realize a quick start of a level decision process. The level
decision process can be performed without output errors and duty
distortion.
The level decision circuits 30 and 40 are suitable for an optical receiver
of a PON system, which processes burst mode signals whose level (light
power) varies for each time slot. The invention is applicable to a signal
receiver in a LAN (Local Area Network) system using TDMA (Time Division
Multiple Access) scheme. Further, the invention is applicable to any kinds
of signal receiver which receives digital signals.
Although the invention has been described with respect to the specific
embodiments for complete and clear disclosure, the appended claims are not
be thus limited but are to be construed as embodying all modification and
alternative constructions that may occur to one skilled in the art which
fairly fall within the basic teaching herein set forth.
* * * * *
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