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| United States Patent |
5,838,731
|
|
Nagahori
|
November 17, 1998
|
Burst-mode digital receiver
Abstract
A burst-mode digital receiver which minimizes any reduction in the minimum
input level as compared with a continuous-signal digital receiver includes
a unipolar code-to-bipolar code converter for converging unipolar code
pulses of an inputted burst signal into bipolar code pulses, an
identifying circuit for identifying logic levels of "1" and "0" with an
identifying level at a center of a pulse duration of bipolar code pulses
outputted from the unipolar code-to-bipolar code converter, and a burst
on/off detecting circuit for continuously outputting a signal until the
inputted burst signal is finished when a pulse amplitude of the inputted
burst signal exceeds a constant value. The burst-mode digital receiver
produces an output signal when an AND gate connected to the output
terminal of the identifying circuit is turned on at the time the output
signal from the burst on/off detecting circuit is turned on.
| Inventors:
|
Nagahori; Takeshi (Tokyo, JP)
|
| Assignee:
|
NEC Corporation (Tokyo, JP)
|
| Appl. No.:
|
565098 |
| Filed:
|
November 30, 1995 |
Foreign Application Priority Data
| Current U.S. Class: |
375/289; 329/361; 375/318; 375/340 |
| Intern'l Class: |
H04L 025/34 |
| Field of Search: |
375/289,328,340,351,222,318
329/309,310,361
327/76
|
References Cited [Referenced By]
U.S. Patent Documents
| 3894288 | Jul., 1975 | Musser, Jr. | 327/76.
|
| 4524462 | Jun., 1985 | Cottatelucci | 375/289.
|
| 4581731 | Apr., 1986 | Tomikashi et al. | 370/4.
|
| 4714828 | Dec., 1987 | Bacou et al. | 250/214.
|
| 4754273 | Jun., 1988 | Okada et al. | 375/222.
|
| 5025456 | Jun., 1991 | Ota et al. | 375/76.
|
| 5371763 | Dec., 1994 | Ota et al. | 375/318.
|
| 5381052 | Jan., 1995 | Kolte | 327/76.
|
| Foreign Patent Documents |
| 57009154 | Jan., 1982 | EP.
| |
| 0347359 | Dec., 1989 | EP.
| |
| 0597632 | May., 1994 | EP.
| |
Other References
Japanese Institution of Electronics Information and Communication; Meeting
of Spring, 1993 (B-987); "Development of Optical Receiver Circuit for
Passive Double Star".
C.A. Brackett et al.; "A Noise Immune 32Mb/s Optical Data Link"; Sixth
European Conference On Optical Communication, University of York, United
Kingdom; Sep. 16-19-1980; pp. 458-461.
|
Primary Examiner: Chan; Jason
Assistant Examiner: Tran; Congvan
Attorney, Agent or Firm: Sughrue, Mion, Zinn, Macpeak & Seas, PLLC
Claims
What is claimed is:
1. A burst-mode digital receiver comprising:
a unipolar code-to-bipolar code converter for converting unipolar code
pulses of an inputted burst signal into bipolar code pulses;
an identifying circuit for identifying logic levels of "1" and "0" with an
identifying level set at a center of a pulse amplitude of the bipolar code
pulses outputted from said unipolar code-to-bipolar code converter;
a burst on/off detecting circuit that continuously outputs a signal until
the inputted burst signal is finished, after a pulse amplitude of the
inputted burst signal exceeds a constant value; and
a gate for selectively turning on and off an output signal from said
identifying circuit depending on the signal outputted from said burst
on/off detecting circuit.
2. A burst-mode digital receiver according to claim 1, wherein said
burst-mode on/off detecting circuit comprises means for continuously
outputting a signal until the inputted burst signal is finished, after a
pulse amplitude of the bipolar code pulses outputted from said unipolar
code-to-bipolar code converter exceeds a constant value.
3. A burst-mode digital receiver comprising:
a unipolar code-to-bipolar code converter for converting unipolar code
pulses of an inputted burst signal into bipolar code pulses;
an identifying circuit for identifying logic levels of "1" and "0" with an
identifying level set at a center of a pulse amplitude of the bipolar code
pulses outputted from said unipolar code-to-bipolar code converter;
a burst on/off detecting circuit that continuously outputs a signal with a
logic level of "1" until the inputted burst signal is finished, after a
pulse amplitude of the inputted burst signal exceeds a constant value; and
a gate for selectively turning on and off an output signal from said
identifying circuit depending on the signal outputted from said burst
on/off detecting circuit.
4. A burst-mode digital receiver according to claim 3, wherein said burst
on/off detecting circuit comprises a level detector for outputting a
signal pulse when an input signal applied thereto reaches a predetermined
value, and a set-reset flip-flop which can be set by the signal pulse
outputted from said level detector and by a reset signal supplied from a
source external to the burst-mode digital receiver.
5. A burst-mode digital receiver according to claim 3, wherein said
burst-mode on/off detecting circuit comprises means for continuously
outputting a signal with a logic level of "1" until the inputted burst
signal is finished, after a pulse amplitude of the bipolar code pulses
outputted from said unipolar code-to-bipolar code converter exceeds a
constant value.
6. A burst-mode digital receiver comprising:
a unipolar code-to-bipolar code converter for converting unipolar code
pulses of an inputted burst signal into bipolar code pulses;
an identifying circuit for identifying logic levels of "1" and "0" with an
identifying level set at a center of a pulse amplitude of the bipolar code
pulses outputted from said unipolar code-to-bipolar code converter;
a burst on/off detecting circuit that continuously outputs a signal until
the inputted burst signal is finished, after a pulse amplitude of the
inputted burst signal exceeds a constant value; and
a gate for selectively turning on and off an output signal from said
identifying circuit depending on the signal outputted from said burst
on/off detecting circuit;
wherein said burst on/off detecting circuit comprises a level detector for
outputting a signal pulse when an input signal applied thereto reaches a
predetermined value, and a set-reset flip-flop which can be set by the
signal pulse outputted from said level detector and by a reset signal
supplied from a source external to the burst-mode digital receiver.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a receiver for use in a burst transmission
system such as a passive optical network (PON) or the like.
2. Description of the Prior Art
There has been devised a PON system in which one transmission path
extending from a station is branched to provide service to a plurality of
subscribers in order to establish an economical optical subscriber data
transmission system. In the PON system, a signal received by the station
comprises a burst signal whose signal intensity changes abruptly because
signals transmitted from subscribers to the station are multiplexed by
time-division multiplex access (TDMA).
If an input signal is a digital binary signal produced by modulating an
analog signal with digital binary modulation, then an output signal from
the receiver in the station can be of either one of three values, i.e.,
"1" corresponding to a mark, "0" corresponding to a space, and "undefined"
corresponding to a non-signal region between bursts. When no signal is
inputted, however, it is desirable for the receiver to keep outputting a
constant logic level of "1" or "0" in order to simplify a synchronizing
circuit and TDMA control circuit that are connected to the output terminal
of the receiver.
FIGS. 1 and 2 of the accompanying drawings show a conventional burst-mode
optical receiver. In order for the conventional burst-mode optical
receiver to keep outputting a logic level of "0" when no signal is
inputted, a certain offset level is imparted to the input section of an
identifying circuit to determine whether an input signal pulse is of a
logic level of "1" or "0" at a position that deviates by a certain value
from the center of the amplitude of the input signal pulse. Such
conventional burst-mode optical receiver is disclosed in U.S. Pat. No.
5,025,456 or B-987, Spring National Convention of Electronic Information
Communication Society, 1993. According to the latter document, one station
device and a plurality of subscriber devices are connected by optical
couplers, making up an optical reception circuit including a high-speed
AGC circuit to establish an inexpensive optical transmission network.
For identifying a logic level of "1" or "0" with respect to an input signal
pulse that has been modulated by digital binary modulation in a system
where the signal-to-noise ratio (the ratio of signal power to noise power)
is determined only by the noise in a reception circuit such as an optical
reception circuit using a PIN diode, it is preferable to identify the
logic level at the center of the amplitude of the input signal pulse in
order to maximize the signal-to-noise ratio and also equalize the duration
of an output pulse from the identifying circuit to a clock period TO for
maximizing the margin for the identifying position.
In the conventional burst-mode optical receiver, however, since a certain
offset level is imparted to the input section of an identifying circuit to
identify the logic level at a position higher than the center of the pulse
amplitude, and the offset level has a large effect especially when the
input pulse amplitude is small. Specifically, as shown in FIG. 2, when the
input pulse amplitude is small, the logic level is identified at a
position deviation from the maximum signal-to-noise ratio, and the
duration of output pulses is reduced, failing to provide an identifying
phase margin sufficient to operate a bit synchronizing circuit connected
to the output terminal of the receiver. The latter problem can be solved
by setting the reception system to a wider frequency range. The reception
range of a receiver for receiving a continuous signal having a clock
frequency of fc is usually set to 0.7 fc, whereas the conventional
burst-mode optical receiver is set to 1.0 fc.about.1.5 fc. However, the
wider frequency range results in a poor signal-to-noise ratio because the
noise range of the receiver is also increased. Due to the poor
signal-to-noise ratio and the reduced identifying phase margin, the
conventional burst-mode optical receiver has been problematic in that the
minimum level of light detection is 3 dB through 5 dB lower than the
continuous signal receiver where the identifying level is established at
the center of the signal amplitude at all times.
SUMMARY OF THE INVENTION
It is therefore an object of the present invention to provide a burst-mode
digital receiver which minimizes any reduction in the minimum input level
as compared with a continuous-signal digital receiver.
According to the present invention, there is provided a burst-mode digital
receiver comprising a unipolar code-to-bipolar code converter for
converging unipolar code pulses of an inputted burst signal into bipolar
code pulses, an identifying circuit for identifying logic levels of "1"
and "0" with an identifying level at a center of a pulse duration of
bipolar code pulses outputted from the unipolar code-to-bipolar code
converter, sa burst on/off detecting circuit for continuously outputting a
signal until the inputted burst signal is finished when a pulse amplitude
of the inputted burst signal exceeds a constant value, and a gate for
selectively turning on and off an output signal from the identifying
circuit depending o n the signal out putted from the burst on/off
detecting circuit.
The burst on off detecting circuit may comprise a level detector for
outputting a signal pulse when an input signal applied thereto reaches a
predetermined value, and a set-reset flip-flop which can be set by the
signal pulse outputted from the level detector and reset by a reset signal
supplied from a source external to the burst-mode digital receiver.
Alternatively, the burst on/off detecting circuit may comprise means for
continuously outputting a signal until the inputted burst signal is
finished when the pulse amplitude of bipolar code pulses outputted from
the unipolar code-to-bipolar code converter exceeds a constant value.
In a conventional burst-mode optical signal receiver, an offset a is given
to an identifying level so that the receiver outputs a logic level of "0"
when no signal is inputted. According to the present invention, the
identifying level of the identifying circuit is set to the center of the
signal amplitude at all times. When no signal is inputted, the identifying
circuit produces an undefined output signal. However, since the set-reset
flip-flop produces an output signal of "0", the receiver produces an
output sign al of "0" which is obtained through the gate.
When a burst optical signal is inputted, the level detector produces an
output signal of "1" and the set-reset flip-flop produces an output signal
of "1", so that the output signal from the identifying circuit is
outputted as it is through the AND gate. When the burst optical signal is
finished, since the reset signal is applied to the set-reset flip-flop,
the set-reset flip-flop continuously produces an output signal "0" until a
next burst optical signal is inputted. Consequently, the receiver
continuously produces an output signal of "0" which is obtained through
the AND gate.
Inasmuch as the identifying level of the identifying circuit is set to the
center of the signal amplitude at all times, the signal-to-noise ratio and
the identifying phase margin of the burst-mode digital receiver are
similar to those of the continuous signal digital receiver , and the
reception sensitivity of the burst-mode digital receiver is improved.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a block diagram of a conventional burst-mode optical receiver;
FIG. 2 is a diagram showing the waveforms of signals which are illustrative
of operation of the conventional burst-mode optical receiver;
FIG. 3 is a block diagram of a burst-mode digital receiver according to the
present invention;
FIG. 4 is a diagram showing the waveforms of signals which are illustrative
of operation of the burst-mode digital receiver according to the present
invention;
FIG. 5 is a block diagram of a unipolar code-to-bipolar code converter
according to a first embodiment of the present invention;
FIG. 6 is a block diagram of a unipolar code-to-bipolar code converter
according to a second embodiment of the present invention;
FIG. 7 is a block diagram of a unipolar code-to-bipolar code converter
according to a third embodiment of the present invention; and
FIG. 8 is a block diagram of a unipolar code-to-bipolar code converter
according to a fourth embodiment of the present invention.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
FIG. 3 shows in block form a burst-mode digital receiver according to the
present invention, and FIG. 4 shows the waveforms of signals which are
illustrative of operation of the burst-mode digital receiver according to
the present invention.
As shown in FIGS. 3 and 4, a unipolar-code data signal pulse train (data
input (a)) detected as a photo current by a light detector 1 is supplied
through a preamplifier 2 to a unipolar code-to-bipolar code converter 3,
by which the unipolar-code data signal pulse train is converted into a
bipolar-code data signal pulse train (output signal (c) of the unipolar
code-to-bipolar code converter 3).
The bipolar-code data signal pulse train is supplied through a rolloff
low-pass filter 4 to an identifying circuit 5a which comprises a limiter
amplifier and also to a burst on/off detecting circuit 10. The burst
on/off detecting circuit 10 comprises a level detector 7 comprising a
limiter amplifier, an identifying level adjuster 6 for adjusting the
detection level of the level detector 7, and a set-reset flip-flop 8. The
set-reset flip-flop 8 is set by an output signal from the level detector
7, and reset by a reset input signal (b) which is supplied from a source,
external to the burst-mode digital receiver, between bursts.
The identifying circuit 5a has an identifying level D1 set at the center of
the pulse amplitude of the bipolar-code data signal pulse train that is
outputted from the unipolar code-to-bipolar code converter 3. Therefore,
the identifying circuit 5a produces an output data pulse signal (d) which
is undefined when no signal is inputted, and has a period that is
substantially the same as the clock period T0 of the data input (a) except
an initial portion of a burst of data when it is inputted.
The level detector 7 produces an output signal (e) which is the same as the
output signal of the conventional burst-mode digital receiver.
The burst on/off detecting circuit 10 produces an output signal (f) which
keeps an ON state from the first bit of the burst until a reset pulse is
supplied, because of operation of the set-reset flip-flop 8.
The output data pulse signal (d) from the identifying circuit 5a and the
output signal (f) from the burst on/off detecting circuit 10 are ANDed by
an AND gate 9, which produces a logic level of "0" when no signal is
inputted and a data output signal (g) when a burst is inputted, the data
output signal (g) being identified at the maximum signal-to-noise ratio
and having a pulse duration substantially the same as the clock period T0
of the data input (a).
As described above, the data output signal (g) is produced when the output
data pulse signal (d) from the identifying circuit 5a and the output
signal (f) from the burst on/off detecting circuit 10 are ANDed by the AND
gate 9. The output signal (f) from the burst on/off detecting circuit 10
is produced from the output signal (c) of the unipolar code-to-bipolar
code converter 3 based on an identifying level D2. Therefore, depending on
the setting of the identifying level D2, the level detector 7 may not
produce its output signal (e) when the detected level of the data input
(a) is too low. When this happens, the data output signal (g) is of a "0"
level. According to the present invention, therefore, it is necessary to
set the identifying level D2 to a value that can detect the minimum
detected level of the data input (a).
When the identifying level D2 is set to a sufficiently low value that can
detect the minimum detected level of the data input (a), a reduction in
the pulse duration of the data output (g) at low detected levels of the
data input (a) can be suppressed.
Since the pulse duration of the output data is prevented from being reduced
in the vicinity of the minimum detected level of the data input, as
described above, the burst-mode digital receiver according to the present
invention has an increased identifying phase margin for the received data
output. Furthermore, any reduction of the sensitivity of the burst-mode
digital receiver, which is constructed as a 3R receiver that includes a
bit synchronizing circuit compatible with bursts and requires a large
identifying phase margin, as compared with a receiver for receiving a
continuous signal of minimum detected level is smaller than the
conventional burst-mode digital receiver.
Since the reception frequency range of the burst-mode digital receiver
according to the present invention can be reduced to around 0.7 fc which
is of a general value in the continuous signal receiver, the
signal-to-noise ratio of the burst-mode digital receiver according to the
present invention is better than the conventional burst-mode digital
receiver. The identifying level D2 of the level detector 7 which
determines the minimum input level of the burst-mode digital receiver
according to the present invention can be set to a value lower than the
identifying level of the identifying circuit Sb shown in FIG. 1, i.e., the
identifying level DO shown at (c) in FIG. 2. Consequently, any reduction
of the sensitivity of the burst-mode digital receiver, which is
constructed even as a 2R receiver, as compared with a receiver for
receiving a continuous signal of minimum detected level is smaller than
the conventional burst-mode digital receiver.
Inasmuch as the logic level is identified at the center of the pulse
amplitude at all times, as described above, the logic level is identified
at the maximum signal-to-noise ratio and the maximum identifying phase
margin, and any reduction of the sensitivity of the minimum input level as
compared with the continuous signal receiver is reduced.
For example, whereas the minimum input level of the conventional burst-mode
digital receiver is 3 dB through 5 dB lower than that of a continuous
signal receiver composed of an equivalent device for an equivalent
transmission rate, the minimum input level of the burst-mode digital
receiver according to the present invention is 1 dB through 2 dB lower
than that of the continuous signal receiver. The minimum input level is
determined by the detection level of the burst on/off detecting circuit.
Various unipolar code-to-bipolar code converters according to the present
invention will be described below with reference to FIGS. 5 through 8.
FIG. 5 shows in block form a unipolar code-to-bipolar code converter
according to a first embodiment of the present invention. The unipolar
code-to-bipolar code converter according to the first embodiment comprises
a trans impedance amplifier in the form of a differential amplifier 11
which feeds back an inverted output signal through a resistor 21 to a
normal input terminal and a normal output signal through a peak detector
12 and a-resistor 22 to an inverting input terminal. The trans impedance
amplifier is disclosed in U.S. Pat. No. 5,025,456. Using the
transimpedance amplifier, it is possible to obtain a bipolar code from the
second bit of a burst signal.
FIG. 6 shows in block form a unipolar code-to-bipolar code converter
according to a second embodiment of the present invention. The unipolar
code-to-bipolar code converter according to the second embodiment
comprises a variable-gain differential amplifier 13 for performing gain
control and offset control, which is widely used in receivers in optically
coupled transmission systems or optical data links. As shown in FIG. 6,
the peak value of a normal input signal applied to a differential AGC
amplifier 15 is detected by a peak detector 12a, and the peak value of an
inverting input signal applied to the differential AGC amplifier 15 is
detected by a peak detector 12b. The gain of the variable-gain
differential amplifier 13 is controlled by equalizing output voltages of
the peak detectors 12a, 12b for thereby equalizing the average value of
the output voltages of the peak detectors 12a, 12b to a reference voltage
25.
FIG. 7 shows in block form a unipolar code-to-bipolar code converter
according to a third embodiment of the present invention. The unipolar
code-to-bipolar code converter according to the third embodiment includes
an offset canceler for making constant a time average of normal and
inverted output signals of a differential amplifier 11. An average
detector 16 comprises a pair of resistors 27, 28 and a capacitor 26. The
unipolar code-to-bipolar code converter according to the third embodiment
is advantageous in that a large dynamic range can be obtained by a simple
arrangement.
FIG. 8 shows in block form a unipolar code-to-bipolar code converter
according to a fourth embodiment of the present invention. The unipolar
code-to-bipolar code converter according to the fourth embodiment includes
a capacitor 17 coupling amplifiers.
In the burst-mode digital receiver according to the present invention, an
output signal from the unipolar code-to-bipolar code converter 3 is
applied through the low-pass filter 4 as an input signal to the burst
on/off detecting circuit 10. However, an output signal from another
element in the receiver, e.g., an output signal from the preamplifier 2,
may be applied as an input signal to the burst on/off detecting circuit
10. The set-reset flip-flop 8 of the burst on/off detecting circuit 10 may
be replaced with a peak detector or a monostable multivibrator. Depending
on a given guard time between bursts, the burst on/off detecting circuit
10 may be arranged without a reset signal.
The reset signal used in the burst-mode digital receiver according to the
present invention may be a reset signal which is generally supplied to
reset a unipolar code-to-bipolar code converter in an optical receiver of
the type described above.
With the arrangement of the present invention, as described above, the
burst on/off detecting circuit is employed, and when no signal is
inputted, the output signal from the set-reset flip-flop in the burst
on/off detecting circuit is set to "0" to turn off the AND gate for
identifying the logic level at the center of the pulse amplitude at all
times. Therefore, the logic level is identified at the maximum
signal-to-noise ratio and the maximum identifying phase margin. The
burst-mode digital receiver according to the present invention suffers no
substantial reduction in the minimum input level as compared with the
continuous signal digital receiver. Specifically, whereas the minimum
input level of the conventional burst-mode digital receiver is 3 dB
through 5 dB lower than that of a continuous signal receiver composed of
an equivalent device for an equivalent transmission rate, the minimum
input level of the burst-mode digital receiver according to the present
invention is 1 dB through 2 dB lower than that of the continuous signal
receiver. Since the AND gate is turned off when no signal is inputted, no
adverse effects are imposed on a synchronizing circuit and an access
control circuit which are connected to the output terminal of the
burst-mode digital receiver.
* * * * *
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