Optical: systems and elements – Deflection using a moving element – Using a periodically moving element
Reexamination Certificate
1998-06-04
2003-02-25
Pascal, Leslie (Department: 2633)
Optical: systems and elements
Deflection using a moving element
Using a periodically moving element
C359S199200, C359S199200, C359S199200, C359S199200, C359S199200, C359S199200, C359S199200, C250S2140AG, C250S2140RC, C330S308000, C330S059000
Reexamination Certificate
active
06525858
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to an optical receiver and an optical network system using thereof, particularly to an optical receiver preferably used for a star-type optical network such as an optical subscriber system and a station-side apparatus of the star-type optical network.
2. Description of the Related Art
A PON (Passive Optical Network) system is known as means for economically realizing an optical subscriber system, which is disclosed in the official gazette of Japanese Patent Laid-Open No. 61-30139. The PON system aims at economization by connecting optical transceivers
121
and
131
in one station side
100
with optical transceivers
221
to
22
N and
231
to
23
N in a plurality of subscriber-sides
201
to
20
N by single-mode fibers
301
to
30
N through a passive splitter
141
and thereby, sharing one station-side optical transceiver by a plurality of subscribers as shown in FIG.
5
.
However, a lot of branch loss due to a passive splitter
141
and deterioration of the reception sensitivity of an up receiving section related to optical burst transmission for time-division multiple access cause the number of branches to be extremely restricted or the price of a subscriber-side optical transceiver for obtaining a required number of branches to rise.
In
FIG. 5
, symbols
110
and
211
to
21
N denote access control sections and
241
to
24
N denote optical couplers.
As means for effecting a system at less allowable loss between transmission and reception sides while making the best use of the access control system of the PON, the following are known instead of a passive splitter: passive multiplexing using a single-mode multi-mode combiner, passive multiplexing of leading the light emitted from a plurality of single fibers to a large-aperture photoelectric converter element by using a lens, and passive multiplexing of connecting a plurality of single-mode fibers with an array photoelectric converter element constituted with a plurality of photoelectric converter element and receiving the output light current of the array photoelectric converter element by one electronic circuit. These arts are described in “PDS constitution method reducing confluent loss of up signal” (p. 621) in the lecture number B-10-112 in the general meeting of IEICE (Institute of Electronics, Information, and Communication Engineers) in 1997.
Particularly, the passive multiplexing using the array photoelectric converter element shown in
FIG. 6
is prospective because expensive optical parts such as a single-mode multi-mode combiner and a large-aperture lens coupling system are unnecessary.
The structure of a passive-multiplexing optical receiver using a conventional array photoelectric converter element is described below by referring to FIG.
6
.
The optical receiver is a burst receiver in which amplitudes of a receiving-circuit input signal current are suddenly changed every reception packet, which uses a differential amplifier
20
at the initial stage of the receiving circuit similarly to the case of the burst receiving circuit disclosed in the official gazette of Japanese Patent Laid-Open No. 2-266630 or described in the lecture number C-501 of the society general meeting of IEICE.
Signal rays emitted from optical fibers
11
to
18
of an eight-core-ribbon optical fiber cable
10
are led to photoelectric converter planes of an 8-channel photodiode array
0
and photoelectrically converted. The photodiode array
0
is formed on a semi-insulating substrate and anode and cathode terminals are output from photoelectric converter elements
1
to
8
forming an array. Anodes of the photoelectric converter elements
1
to
8
are connected in common and connected to a positive-phase input terminal
21
of the differential amplifier
20
and cathodes of the elements
1
to
8
are connected in common and connected to a reverse-bias applying positive power supply VCC.
Moreover, a dummy capacitor
9
having a capacitance almost equal to a parasitic capacitance added to the positive-phase input terminal
21
due to mounting a photodiode on that terminal
21
are connected to the negative-phase input terminal
22
of the differential amplifier
20
.
When an optical signal is output from any one of the optical fibers
11
to
18
, a photo current enters the positive-phase input terminal
21
of the differential amplifier
20
, the potential of a positive-phase output terminal
23
rises, and the potential of a negative-phase output terminal
24
lowers. Thus, passive multiplexing is realized by using an array photoelectric converter element.
The output of the differential amplifier
20
is discriminated between two values of logics “1” and “0” by a discrimination circuit
40
by passing through a discrimination-level control circuit
30
corresponding to a burst signal and is output.
However, the optical receiver using the conventional array photoelectric converter element shown in
FIG. 6
has disadvantages that the junction capacitance of the element increases because a lot of photoelectric converter elements are connected in parallel and causes a response speed to deteriorate and noises to increase.
SUMMARY OF THE INVENTION
It is an object of the present invention to constitute an optical receiver having a small junction capacitance between photoelectric converter elements, that is, a high-speed low-noise optical receiver used for passive multiplexing of a time-division multiple-access optical transmission system.
It is another object of the present invention to inexpensively realize extension of a time-division multiple-access optical transmission system or increase of the number of systems to be accommodated, which is very useful.
An optical receiver of the present invention includes a differential input amplifier, a first photoelectric converter element whose cathode is connected to a reverse-bias power supply and whose anode is connected to one input terminal of the differential input amplifier, and a second photoelectric converter element whose anode is connected to a reverse-bias power supply and whose cathode is connected to the other input terminal of the differential input amplifier.
Moreover, the first photoelectric converter element comprises a plurality of photoelectric converter element groups whose cathodes are connected in common and whose anodes are connected in common and the second photoelectric converter element comprises a plurality of photoelectric converter element groups whose cathodes are connected in common and whose anodes are connected in common.
Moreover, at least one of a photoelectric converter element group comprising a plurality of the first photoelectric converter elements, a photoelectric converter element group comprising a plurality of the second photoelectric converter elements, and a photoelectric converter element group comprising the first and second photoelectric converter elements is integrated in a semiconductor substrate.
Furthermore, the differential input amplifier is a transimpedance amplifier returned from a negative-phase output to a positive-phase input and from a positive-phase output to a negative-phase input respectively through a circuit element including a resistance element.
Furthermore, the differential input amplifier includes a first transimpedance amplifier having an input terminal serving as the above one input terminal and a second transimpedance amplifier having an input terminal serving as the above other input terminal and having the same structure as the first transimpedance amplifier, and a differential amplifier using the outputs of the first and second transimpedance amplifiers as differential inputs.
An optical network system of the present invention includes a master station having the above optical receiver, a slave station having an optical transmitter, and an optical fiber for connecting the optical receiver of the master station with the optical transmitter of the slave station.
Moreover, the optical receiver of the master station and the optical transmitt
Pascal Leslie
Phan Hanh
Scully Scott Murphy & Presser
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