JP2011109248A - Optical repeater-amplifier, master station side optical transmitter-receiver, and optical subscriber transmission system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain an optical repeater-amplifier which is inexpensive and has high reliability. <P>SOLUTION: In an optical subscriber transmission system wherein a master station-side optical transmitter-receiver 7 and a subscriber-side optical transmitter-receiver 1 transmit and receive optical signals to and from each other, the optical repeater-amplifier 5 which relays an optical signal and performs amplification processing, includes: a fixed-output burst optical amplifier 52 and a linear-gain burst optical amplifier 53 which receive an up burst optical signal transmitted from the subscriber-side optical transmitter-receiver 1 and perform amplification processing in accordance with the signal strength of the burst optical signal; and a fixed-output continuous optical amplifier 55 and a linear-gain continuous optical amplifier 56 which receive a down continuous optical signal transmitted from the master station-side transmitter-receiver 7 and perform amplification processing in accordance with the signal strength of the continuous optical signal. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an optical repeater amplifier for amplifying an optical signal in an optical subscriber transmission system.

  In an access optical transmission system in which an optical fiber is used to connect an optical line terminal (OLT) and an optical network unit (ONU) to a subscriber side, one OLT passes through an optical splitter. By accommodating a large number of ONUs, the equipment cost per subscriber can be reduced. Such an access type optical transmission system is called a PON (Passive Optical Networks) system, and is a mainstream in recent FTTH (Fiber-to-the-Home) systems. The configuration of the PON system is disclosed in Non-Patent Document 1 below.

  In the PON system, since multi-branching is performed using an optical splitter, the transmission path loss increases remarkably when the number of subscribers increases, and the transmission distance is limited to about 20 km or less. Further, the number of subscribers that can be accommodated by one optical splitter is limited to about 32 subscribers. Therefore, the number of subscribers and the subscriber accommodation range are limited, and there is a problem that it is difficult to further reduce the apparatus cost.

  As a technique for solving the above problem, a technique using a gain clamp type rare earth doped optical amplifier as an optical repeater amplifier is disclosed in Non-Patent Document 2 below. By applying an optical amplifier to the PON system, it is possible to compensate for transmission line loss and increase the number of subscribers and the accommodation distance. Also, since the optical repeater amplifier is provided in common to a plurality of subscribers, when the optical repeater amplifier is inserted, the effect of reducing the equipment cost according to the number of subscribers can be obtained, and the number of subscribers and transmission distance A low-cost PON system can be provided. In addition, as an optical amplification means for burst optical signals from temporally intermittent subscribers, the optical feedback control method using gain-clamped light is applied to a fluoride-doped rare earth optical fiber amplifier, so that the burst optical signal is not distorted. An optical repeater amplifier that can be amplified with a constant gain can be obtained.

IEEE Standard, 802.3ah 2004 Kenichi Suzuki et al. “Application of burst-capable optical amplifier to gigabit PON system” 2005 IEICE Society Conference BS-4-2

  However, according to the above conventional technique, a transient gain fluctuation occurs in the feedback control, and the excessive transient gain fluctuation generates an excessively high intensity optical signal and causes a failure of the receiving apparatus. On the other hand, in order to solve the cause of the failure, it is necessary to sufficiently suppress the transient gain fluctuation over the period until the feedback control converges, but in order to sufficiently suppress the transient gain fluctuation, It is necessary to limit the gain of an effective optical repeater amplifier for improving the system budget to about 10 dB. That is, in the conventional optical repeater amplification apparatus, if the cause of the failure is to be solved, a sufficient gain for improving the system budget cannot be obtained. Therefore, the number of subscribers can be greatly increased and the transmission distance can be greatly increased. As a result, there is a problem that it is difficult to reduce the substantial system cost.

  In general, a fluoride-doped rare earth optical fiber amplifier to which the above optical feedback control technique is applied has a complicated apparatus configuration, and a fluoride-doped rare earth optical fiber to be used is also expensive. For this reason, there has been a problem that it is difficult to reduce device costs and improve device reliability.

  The present invention has been made in view of the above, and an object of the present invention is to obtain an optical amplification repeater capable of realizing low cost and high reliability.

  In order to solve the above-described problems and achieve the object, the present invention relays an optical signal in an optical subscriber transmission system in which the optical transmission / reception apparatus on the master station side and the optical transmission / reception apparatus on the subscriber side transmit and receive optical signals. An optical repeater amplifier that performs amplification processing, receives an upstream burst optical signal transmitted from the subscriber side optical transceiver, and performs amplification processing while changing the gain according to the signal intensity of the burst optical signal. Burst optical amplifying means to perform and continuous optical amplifying means for receiving a continuous optical signal in the downstream direction transmitted from the optical transmission / reception apparatus on the master station side and performing amplification processing while changing the gain according to the signal intensity of the continuous optical signal And.

  According to the present invention, it is possible to obtain a low-cost and highly reliable optical amplification repeater.

FIG. 1 is a diagram illustrating a configuration example of an optical amplification repeater and an optical subscriber transmission system. FIG. 2 is a diagram illustrating an example of an optical signal level diagram in the upstream direction. FIG. 3 is a diagram illustrating a configuration example of an optical amplification repeater and an optical subscriber transmission system. FIG. 4 is a diagram showing the optical amplification gain with respect to the input signal intensity. FIG. 5 is a diagram illustrating a configuration example of an optical amplification repeater and an optical subscriber transmission system. FIG. 6 is a diagram illustrating the amount of reception sensitivity improvement with respect to the transmission band. FIG. 7 is a diagram illustrating a configuration example of an optical subscriber transmission system. FIG. 8 is a diagram illustrating a configuration example of the OLT and the optical subscriber transmission system. FIG. 9 is a diagram showing threshold levels of each ONU.

  Embodiments of an optical repeater amplifier according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment 1 FIG.
FIG. 1 is a diagram showing a configuration example of an optical amplification repeater and an optical subscriber transmission system in the present embodiment. The optical subscriber transmission system includes a subscriber side optical transceiver (hereinafter referred to as ONU) 1, an optical fiber transmission line 2, an optical distributor 3, an optical fiber transmission line 4, an optical repeater amplifier 5, An optical fiber transmission line 6 and a master station side optical transceiver (hereinafter referred to as OLT) 7 are configured. The OLT 7 and the ONU 1 constitute a 1: N (N> 1) bidirectional communication system in which one OLT 7 is connected to a plurality of ONUs 1. The ONU 1 is a terminating device arranged on the subscriber side. The optical fiber transmission lines 2, 4, and 6 are optical fibers (transmission lines) that connect the components. The optical distributor 3 is an optical splitter that can branch to 1: N. The optical repeater amplifier 5 amplifies and repeats the optical signal. The OLT 7 is a termination device arranged on the master station side.

  The optical repeater / amplifier 5 includes a wavelength multiplexer / demultiplexer 51, a constant output burst optical amplifier 52, a linear gain burst optical amplifier 53, a wavelength multiplexer / demultiplexer 54, a constant output continuous optical amplifier 55, a linear And a continuous gain optical amplifier 56. The wavelength multiplexer / demultiplexer 51 outputs the upstream optical signal from the optical fiber transmission line 4 to the constant output burst optical amplifier 52, and the downstream optical signal from the linear gain continuous optical amplifier 56 to the optical fiber transmission line. Output to 4. The constant output burst optical amplifier 52 amplifies by changing the gain according to the intensity of the input signal. The linear gain burst optical amplifier 53 amplifies with a constant linear gain regardless of the intensity of the input signal. The wavelength multiplexer / demultiplexer 54 outputs the downstream optical signal from the optical fiber transmission line 6 to the constant output continuous optical amplifier 55 and the upstream optical signal from the linear gain burst optical amplifier 53 to the optical fiber transmission line. Output to 6. The constant output continuous optical amplifier 55 amplifies by changing the gain according to the intensity of the input signal. The linear gain continuous optical amplifier 56 amplifies with a constant linear gain regardless of the intensity of the input signal. Here, the constant output burst optical amplifier 52, the linear gain burst optical amplifier 53, the constant output continuous optical amplifier 55, and the linear gain continuous optical amplifier 56 are constituted by semiconductor-type optical amplifiers.

  Next, an operation for transmitting and receiving an optical signal in the optical subscriber transmission system will be described. First, an operation for transmitting and receiving an upstream optical signal will be described. The plurality of ONUs 1 are accommodated and connected to a single-core optical fiber transmission line 4 by an optical distributor 3 through an optical fiber transmission line 2. Here, the transmission distance between the ONU 1 and the optical distributor 3 may be any distance within the allowable range of system loss. The upstream optical signal is a burst optical signal that is intermittent in time according to an instruction from the OLT 7 so that the optical signals from the ONUs 1 do not overlap in time at the receiving end of the OLT 7.

  When the ONU 1 outputs the upstream optical signal, the optical repeater amplifier 5 inputs the upstream optical signal via the optical fiber transmission path 2, the optical distributor 3, and the single-core optical fiber transmission path 4. In the optical repeater amplifier 5, the wavelength multiplexer / demultiplexer 51 outputs the input upstream optical signal to the constant output burst optical amplifier 52 that performs upstream optical amplification. The constant output burst optical amplifier 52 operates so as to have a constant output intensity for input intensity light that is larger than a predetermined input intensity range. Next, the linear gain burst optical amplifier 53 receives the output signal of the constant output burst optical amplifier 52, amplifies the linear optical gain with a predetermined constant gain by the linear amplification gain, and then passes the upstream optical signal through the wavelength multiplexing / demultiplexing device 54. And output to the optical fiber transmission line 6. The OLT 7 receives the upstream optical signal via the optical fiber transmission line 6.

  Next, an operation for transmitting and receiving a downstream optical signal will be described. When the OLT 7 outputs the downstream optical signal, the optical repeater amplification apparatus 5 inputs the downstream optical signal via the optical fiber transmission line 6. In the optical repeater amplifier 5, the wavelength multiplexer / demultiplexer 54 outputs the input downstream optical signal to a constant output continuous optical amplifier 55 that performs downstream optical amplification. The constant output continuous optical amplifier 55 operates so as to have a constant output intensity for input intensity light that is larger than a predetermined input intensity range. Next, the linear gain continuous optical amplifier 56 receives the output signal of the constant output continuous optical amplifier 55, amplifies the linear optical gain with a predetermined constant gain, and then the downstream optical signal passes through the wavelength multiplexing / demultiplexing unit 51. And output to the optical fiber transmission line 4. The ONU 1 receives the downstream optical signal via the optical fiber transmission line 4, the optical distributor 3, and the optical fiber transmission line 2.

  Here, the detailed operation of the optical repeater amplifier 5 will be described. FIG. 2 is a diagram illustrating an example of an optical signal level diagram in the upstream direction in the optical repeater amplifying apparatus 5. The input intensity range and the amplifier gain shown in the drawing are merely examples for convenience of explanation, and the present invention is not limited thereto. The downstream direction can also be indicated by the same optical signal level diagram.

  The constant output burst optical amplifier 52 and the constant output continuous optical amplifier 55 have their drive currents controlled so as to have a constant gain that does not depend on the input signal intensity in a desired optical signal level range. Further, when it is larger than the desired optical signal level range, the drive current is controlled so as to obtain a saturation gain. By applying this saturation gain function, the constant output burst optical amplifier 52 and the constant output continuous optical amplifier 55 do not depend on the input signal light intensity when it is larger than the desired optical signal level range, and the output is always approximately constant. The operation of emitting strength can be performed.

  The drive current of the linear gain burst optical amplifier 53 and the linear gain continuous optical amplifier 56 is controlled so as to have a constant linear gain in a desired optical signal level range determined from the system level diagram. The drive current control value is always set to a desired constant value independent of the input signal intensity by feedforward control. As a control method for setting a constant drive current, it can be realized by a current-voltage conversion circuit or the like using a general fixed bias as a target value.

  Conventionally, when a fluoride-doped rare earth optical fiber amplifier to which an optical feedback control technique is applied is used, the inversion distribution time constant inherent in the fluoride-doped rare earth optical fiber amplifier is gradual, so that a burst optical signal that switches at high speed is distorted. In order to amplify with a constant gain, it is necessary to limit the input signal intensity range to the optical repeater amplifier to a narrow range. Further, it is necessary to handle the optical signal section as an invalid section until the transient gain fluctuation generated in the feedback control converges. Therefore, there is a problem that the system dynamic range and system throughput are limited.

  In the present embodiment, the constant output burst optical amplifier 52, the constant output continuous optical amplifier 55, the linear gain burst optical amplifier 53, and the linear gain continuous optical amplifier 56 operate as described above, so that the maximum output light intensity is obtained at the receiving end. Is limited (limited), and the system dynamic range limited by the maximum received light intensity can be greatly improved.

  Note that, here, the connection configuration of the constant output burst optical amplifier 52 and the linear gain burst optical amplifier 53 and the connection configuration of the constant output continuous optical amplifier 55 and the linear gain continuous optical amplifier 56 are set for the input signal. Depending on the design, the linear gain burst optical amplifier 53, the constant output burst optical amplifier 52, the linear gain continuous optical amplifier 56, and the constant output continuous optical amplifier 55 may be connected in this order.

  In this manner, by applying the linear gain function of the linear gain burst optical amplifier 53 and the linear gain continuous optical amplifier 56, which are semiconductor optical amplifiers, as the amplifier gain of the optical repeater amplifying device 5, an input signal can be input within a desired input signal strength range. Optical amplification can always be performed with a constant linear gain regardless of the signal intensity. In addition, the constant gain control method in the linear gain burst optical amplifier 53 and the linear gain continuous optical amplifier 56, which are semiconductor optical amplifiers, can be simple feedforward type drive current constant control, and therefore can be simply configured by a general driving method. Is possible. The response time constant in the linear region of the linear gain burst optical amplifier 53 and the linear gain continuous optical amplifier 56, which are semiconductor optical amplifiers, is generally about several tens of ps, so even when a high-speed burst optical signal is input. Thus, it is possible to achieve good optical amplification characteristics without waveform distortion.

  When the input light intensity is excessive, the output constant control amplifier (limiting amplifier) using the saturation region of the constant output burst optical amplifier 52 and the constant output continuous optical amplifier 55 which are semiconductor optical amplifiers, It is possible to always keep the input light intensity range below a certain value. Since the response time constant in the saturation region of the constant output burst optical amplifier 52 and the constant output continuous optical amplifier 55 which are semiconductor optical amplifiers is generally about several tens of ps, even when a high-speed burst optical signal is input, Good constant output light amplification characteristics without waveform distortion are possible.

  As described above, in this embodiment, a semiconductor optical amplifier based on simple feedforward control is used as a linear gain optical amplifier and a constant output optical amplifier to constitute an optical repeater amplifier. As a result, it is possible to obtain an optical amplification repeater that can realize low cost and high reliability while improving the system dynamic range.

  Also, by using the optical repeater amplifier, it is possible to easily expand the system dynamic range, and to obtain a low-cost and flexible optical subscriber transmission system that greatly expands the subscriber accommodation range. be able to.

Embodiment 2. FIG.
In this embodiment, one semiconductor optical amplifier performs linear gain operation and constant output operation. A different part from Embodiment 1 is demonstrated.

  FIG. 3 is a diagram illustrating a configuration example of the optical amplification repeater and the optical subscriber transmission system in the present embodiment. The optical subscriber transmission system includes an ONU 1, an optical fiber transmission line 2, an optical distributor 3, an optical fiber transmission line 4, an optical repeater amplifier 5a, an optical fiber transmission line 6, and an OLT 7. The The optical repeater amplifier 5a amplifies and repeats the optical signal.

  The optical repeater amplifier 5a includes a wavelength multiplexing / demultiplexing device 51, a burst optical amplifier 57, a wavelength multiplexing / demultiplexing device 54, and a continuous optical amplifier 58. The wavelength multiplexer / demultiplexer 51 outputs the upstream optical signal from the optical fiber transmission line 4 to the burst optical amplifier 57 and outputs the downstream optical signal from the continuous optical amplifier 58 to the optical fiber transmission line 4. . The burst optical amplifier 57 amplifies by changing the gain according to the intensity of the input signal. The wavelength multiplexer / demultiplexer 54 outputs the downstream optical signal from the optical fiber transmission line 6 to the continuous optical amplifier 58 and outputs the upstream optical signal from the burst optical amplifier 57 to the optical fiber transmission line 6. . The constant output continuous optical amplifier 55 amplifies by changing the gain according to the intensity of the input signal. Here, the burst optical amplifier 57 and the continuous optical amplifier 58 are composed of a single semiconductor optical amplifier.

  Next, an operation for transmitting and receiving an optical signal in the optical subscriber transmission system will be described. First, an operation for transmitting and receiving an upstream optical signal will be described. When the ONU 1 outputs an upstream optical signal, the optical repeater amplifier 5a inputs the upstream optical signal via the optical fiber transmission path 2, the optical distributor 3, and the single-core optical fiber transmission path 4. In the optical repeater amplifier 5a, the wavelength multiplexer / demultiplexer 51 outputs the input upstream optical signal to the burst optical amplifier 57 that performs upstream optical amplification. The burst optical amplifier 57 operates so as to have a constant output intensity for input intensity light that is larger than a predetermined input intensity range, and as a linear gain amplifier for input intensity light in a predetermined input intensity range. Operate. The burst optical amplifier 57 outputs the amplified upstream optical signal to the optical fiber transmission line 6 via the wavelength multiplexer / demultiplexer 54. The OLT 7 receives the upstream optical signal via the optical fiber transmission line 6.

  Next, an operation for transmitting and receiving a downstream optical signal will be described. When the OLT 7 outputs the downstream optical signal, the optical repeater amplifier 5a inputs the downstream optical signal via the optical fiber transmission line 6. In the optical repeater amplifier 5a, the wavelength multiplexing / demultiplexing device 54 outputs the input downstream optical signal to the continuous optical amplifier 58 that performs optical amplification in the downstream direction. The continuous optical amplifier 58 operates so as to have a constant output intensity for input intensity light that is larger than a predetermined input intensity range, and as a linear gain amplifier for input intensity light in a predetermined input intensity range. Operate. The continuous optical amplifier 58 outputs the amplified downstream optical signal to the optical fiber transmission line 4 via the wavelength multiplexer / demultiplexer 51. The ONU 1 receives the downstream optical signal via the optical fiber transmission line 4, the optical distributor 3, and the optical fiber transmission line 2.

  Here, the detailed operation of the optical repeater amplifier 5a will be described. FIG. 4 is a diagram showing a typical example of the optical amplification gain with respect to the input signal intensity in the optical repeater amplifier 5a. The input intensity range and the amplifier gain shown in the figure are only examples for convenience of explanation, and the present invention is not limited to these.

  In the case where the burst optical amplifier 57 and the continuous optical amplifier 58 have a constant linear gain in the input intensity range of a desired optical signal level determined from the system level diagram and are larger than the input intensity range of the desired optical signal level. The drive current is controlled so as to achieve a saturation gain operation with a constant output intensity. The drive current control value is always set to a desired constant value independent of the input signal intensity by feedforward control. As a control method for setting a constant drive current, a current / voltage conversion circuit or the like using a general fixed bias as a target value can be used.

  As a result, as in the first embodiment, the maximum output light intensity is limited (limited) at the receiving end, and the system dynamic range limited by the maximum received light intensity can be greatly improved.

  As described above, in this embodiment, the optical repeater amplification apparatus is configured by using one semiconductor optical amplifier that performs linear gain operation and constant output operation. As a result, it is possible to obtain an optical amplification repeater that can realize low cost and high reliability while improving the system dynamic range.

  Also, by using the optical repeater amplifier, it is possible to easily expand the system dynamic range, and to obtain a low-cost and flexible optical subscriber transmission system that greatly expands the subscriber accommodation range. be able to.

  The continuous optical amplifier 58 may be constituted by a rare earth doped optical fiber amplifier that operates in the saturation region in a predetermined input signal light intensity range, instead of the semiconductor optical amplifier.

Embodiment 3 FIG.
In the present embodiment, the optical repeater amplification apparatus includes an optical band transmission filter for improving reception sensitivity. A different part from Embodiment 1 is demonstrated.

  FIG. 5 is a diagram showing a configuration example of the optical amplification repeater and the optical subscriber transmission system in the present embodiment. The optical subscriber transmission system includes an ONU 1, an optical fiber transmission line 2, an optical distributor 3, an optical fiber transmission line 4, an optical repeater amplification device 5 b, an optical fiber transmission line 6, and an OLT 7. The The optical repeater amplifier 5b amplifies and repeats the optical signal.

  The optical repeater amplifier 5b includes a wavelength multiplexer / demultiplexer 51, a constant output burst optical amplifier 52, a linear gain burst optical amplifier 53, an optical band pass filter 59, a wavelength multiplexer / demultiplexer 54, and a constant output. A continuous optical amplifier 55 and a linear gain continuous optical amplifier 56 are provided. The optical band transmission filter 59 removes noise components outside the filter optical band.

  Next, an operation for transmitting and receiving an optical signal in the optical subscriber transmission system will be described. First, an operation for transmitting and receiving an upstream optical signal will be described. The operation up to the linear gain burst optical amplifier 53 is the same as in the first embodiment. The linear gain burst optical amplifier 53 outputs an upstream optical signal to the optical band transmission filter 59 after being amplified with a predetermined constant gain by the linear amplification gain. The optical band transmission filter 59 outputs the upstream optical signal after removing the noise component outside the filter optical band from the input upstream optical signal to the optical fiber transmission line 6 via the wavelength multiplexer / demultiplexer 54. To do. The OLT 7 receives the upstream optical signal via the optical fiber transmission line 6. The operation for transmitting and receiving the downstream optical signal is the same as in the first embodiment.

  Next, the effect of improving the reception sensitivity by the optical band transmission filter 59 will be described. FIG. 6 is a diagram illustrating an example of a calculation result of the reception sensitivity improvement amount with respect to the transmission band of the optical band transmission filter 59. In the optical subscriber transmission system in the present embodiment, the system minimum reception level is determined by the optical noise intensity to signal intensity ratio (OSNR). When a semiconductor optical amplifier is applied to the optical repeater amplifier 5b, spontaneous emission light noise generated in the semiconductor optical amplifier significantly deteriorates the OSNR, and the equivalent gain in the optical repeater amplifier 5b is greatly reduced. In such a case, by inserting the optical band transmission filter 59 into the optical repeater amplification device 5b, it is possible to improve the reception sensitivity and to secure more equivalent gain.

  Here, the transmission wavelength fluctuation in the ONU 1 is generally about 20 nm or less when a semiconductor laser is used as a transmission light source. Therefore, even if the optical band transmission filter 59 having the characteristics shown in FIG. 6 is used, it is possible to improve the reception sensitivity without limiting the ONU 1.

  As described above, in the present embodiment, the optical repeater amplifier 5b includes the optical band transmission filter 59 for improving the reception sensitivity, and the optical band transmission filter 59 removes noise components. Thereby, an optical subscriber transmission system with high receiving sensitivity can be obtained.

  In addition, based on Embodiment 1, although the case where the optical band transmission filter 59 was applied to the optical repeater amplifier 5 was demonstrated, it is not limited to this. It is also possible to apply the optical band transmission filter 59 to the optical repeater amplification device 5a in the second embodiment.

Embodiment 4 FIG.
In the present embodiment, a case will be described in which an optical multi-branch optical subscriber transmission system is configured using an optical repeater amplifier. A different part from Embodiment 1 is demonstrated.

  FIG. 7 is a diagram illustrating a configuration example of the optical subscriber transmission system according to the present embodiment. The optical subscriber transmission system includes an ONU 1, an optical fiber transmission path 2, an optical distributor 3, an optical fiber transmission path 4, an optical repeater amplification device 5, an optical fiber transmission path 6, an optical distributor 8, It comprises an optical fiber transmission line 9 and an OLT 7. The optical distributor 8 is an optical splitter that can branch to 1: M (M> 1). The optical fiber transmission line 9 is an optical fiber (transmission line) that connects the optical distributor 8 and the OLT 7.

  The intra-station apparatus 100 is composed of the optical repeater amplifier 5, the optical fiber transmission line 6, the optical distributor 8, the optical fiber transmission line 9, and the OLT 7. The intra-station device 100 performs an operation from the time when the OLT 7 outputs the downstream optical signal to the branching and amplifying in the downstream direction, and after the upstream optical signal from each ONU 1 is amplified in the upstream direction. The operation until it is accommodated and received by the OLT 7 is performed.

  Next, an operation for transmitting and receiving an optical signal in the optical subscriber transmission system will be described. First, an operation for transmitting and receiving an upstream optical signal will be described. When the ONU 1 outputs the upstream optical signal, the optical repeater amplifier 5 of the intra-station device 100 inputs the upstream optical signal via the optical fiber transmission path 2, the optical distributor 3, and the single-core optical fiber transmission path 4. . The optical repeater amplifying device 5 sets a constant output intensity for light having an input intensity greater than a predetermined input intensity range, and further amplifies the optical signal in the upstream direction after amplification at a predetermined constant gain by a linear amplification gain. Output to the fiber transmission line 6. The OLT 7 receives the upstream optical signal via the optical fiber transmission line 6, the optical distributor 8, and the optical fiber transmission line 9.

  Next, an operation for transmitting and receiving a downstream optical signal will be described. In the intra-station apparatus 100, when the OLT 7 outputs the downstream optical signal, the optical distributor 8 branches the downstream optical signal input via the optical fiber transmission line 9. The optical repeater amplifier 5 inputs the branched downstream optical signal via the optical fiber transmission line 6. The optical repeater amplifying device 5 sets a constant output intensity for input intensity light that is larger than a predetermined input intensity range, and further amplifies the downstream optical signal after amplification with a predetermined constant gain by a linear amplification gain. Output to the fiber transmission line 4. The ONU 1 receives the downstream optical signal via the optical fiber transmission line 4, the optical distributor 3, and the optical fiber transmission line 2.

  In this way, by arranging the optical repeater amplification device 5 installed between the OLT 7 and the ONU 1 immediately after the first branch in the station (intra-station device 100), it is possible to obtain a super multi-branch system. For example, in FIG. 7, it is assumed that the downstream optical signal is branched into 16 by the optical distributor 8. The optical repeater amplifying device 5 arranged immediately after the optical distributor 8 guarantees the loss caused by the optical distributor 8, so that the optical distributor 3 can perform the same 32-branch as before, and the maximum number of subscribers is 512. An ultra-multi-branch optical subscriber system configuration can be achieved. The increase in the number of branches improves the cost reduction effect per subscriber in the 1: N (N> 1) bidirectional communication system. Furthermore, by installing the optical repeater amplification device 5 that is generally installed in an outdoor column shape in the station (intra-station device 100), installation and management become easier, and maintenance operability and reliability are improved. It becomes possible to make it.

  As described above, in the present embodiment, in the intra-station apparatus 100, the downstream optical signal from the OLT 7 is branched by the optical distributor 8, and the downstream optical signal after branching is amplified by the optical repeater amplifier 5. It was. As a result, an ultra-multi-branch optical subscriber transmission system can be obtained at low cost. Further, it is possible to obtain an optical subscriber transmission system that is low in cost and excellent in maintenance operation and reliability.

  Note that the optical repeater amplifier 5 in the intra-station apparatus 100 can be replaced with the optical repeater amplifiers 5a and 5b.

  In FIG. 7, the optical repeater amplifier 5 is inserted into all the optical fiber transmission lines 6 branched by the optical distributor 8, but the present invention is not limited to this. For example, when connecting to the ONU 1 at a short distance from the intra-station device 100, it is possible to adopt a configuration in which the optical repeater amplifier 5 is not passed.

Embodiment 5 FIG.
In the present embodiment, the OLT controls the reception threshold to improve the reception sensitivity in the optical subscriber transmission system. A different part from Embodiment 1-4 is demonstrated.

  FIG. 8 is a diagram illustrating a configuration example of the OLT and the optical subscriber transmission system in the present embodiment. The optical subscriber transmission system includes ONUs 1a and 1b, optical fiber transmission lines 2a and 2b, an optical distributor 3, an optical fiber transmission line 4, an optical repeater amplification device 5, an optical fiber transmission line 6, and an OLT 7a. Is composed of. The ONUs 1a and 1b are terminating devices arranged on the subscriber side. The optical fiber transmission lines 2 a and 2 b are optical fibers (transmission lines) that connect each ONU and the optical distributor 3. The OLT 7a is a termination device arranged on the master station side. Here, in the ONUs 1a and 1b, the distance to the OLT 7a is longer in the ONU 1b, and the ONU 1b is the ONU farthest from the OLT 7a among the ONUs accommodated in the OLT 7a.

  The OLT 7a includes a preamplifier 71, a 2R amplifier 72, a clock data recovery module (hereinafter referred to as CDR) 73, a serial / parallel data converter (hereinafter referred to as Serdes) 74, and a forward error correction function control unit ( (Hereinafter referred to as FEC) 75, a photocurrent intensity monitor 76, and an external threshold value controller 77. The preamplifier 71 amplifies the upstream optical signal received from the ONU. The 2R amplifier 72 identifies and reproduces the amplified upstream optical signal. The CDR 73 extracts timing from the reproduced received signal. The Serdes 74 performs serial / parallel conversion. The FEC 75 includes a bit error counter and counts the number of errors. The photocurrent intensity monitor 76 measures the light intensity from each ONU and detects the ONU having the weakest light intensity (the farthest distance). The external threshold control unit 77 outputs an external threshold control signal based on the difference in the number of errors.

  Next, an operation for transmitting and receiving an upstream optical signal will be described as an operation for transmitting and receiving an optical signal in the optical subscriber transmission system. The operation from when the ONUs 1a and 1b output the upstream optical signal to when the OLT 7a inputs is the same as in the first embodiment. In the OLT 7a, when a plurality of ONUs are accommodated and connected, the photocurrent intensity monitor 76 measures the light intensity from each ONU and detects the ONU having the weakest light intensity, that is, the farthest distance. In the case of FIG. 8, the ONU 1b is detected as the furthest ONU.

  In the OLT 7a, the preamplifier 71 amplifies the upstream optical signal sent from the detected ONU 1b, and the 2R amplifier 72 performs identification and reproduction according to the external threshold control signal. The CDR 73 extracts the timing from the regenerated received signal using a clock synchronized with the inside of the receiving apparatus (OLT 7a), and outputs it to the Serdes 74. The Serdes 74 outputs the input data to the FEC 75 after serial / parallel conversion. In the FEC 75, the number of errors on the “1” side that mistakes the “1” signal as “0” and the error on the “0” side that mistakes the “0” signal as “1” using the bit error counter provided in itself. Count the number. The FEC 75 outputs an error count difference between “0” and “1” to the external threshold value control unit 77. The external threshold value controller 77 outputs an arbitrary DC voltage level corresponding to the error count number difference. The 2R amplifier 72 performs feedback control to offset the threshold value using the output signal as an external threshold control signal. This threshold adjustment control is performed for a sufficiently long training period for the input signal frame.

  In this way, the 2R amplifier 72 determines the threshold control offset value so that the error rate of the ONU (here, ONU1b) farthest from the OLT 7a is the lowest, and the offset value is determined from all other ONUs. This signal is also used uniformly. For example, the same threshold value threshold adjustment as that of the ONU 1b is performed for the ONU 1a.

  In an optical transmission system using an optical amplifier, optical amplifier noise is generally excessive, and when the midpoint potential of a signal “0” level and “1” level is used as a threshold value, reception sensitivity is deteriorated. there is a possibility. For this reason, when there are many code words in which a signal of “1” is mistaken as “0” in the error count, the reception sensitivity can be improved by changing the optimum threshold to the “0” side in the received signal. On the other hand, when there are many code words in which a “0” signal is mistaken as “1”, the receiving sensitivity can be improved by changing the optimum threshold to the “1” side in the received signal.

  FIG. 9 is a diagram showing threshold levels of each ONU. FIG. 9B shows an example of a packet from the ONU 1b farthest from the OLT 7a shown in FIG. When the midpoint potential indicated by the broken line is used as the threshold value, the noise on the “1” side is large, and the probability of erroneously setting “1” to “0” increases. Therefore, it is possible to improve the reception sensitivity by adding an offset to the threshold and appropriately bringing the threshold closer to the “0” side.

  In general, the signal from the farthest ONU 1b has the smallest signal-to-noise ratio. In the OLT 7a, it is possible to improve the reception sensitivity for all ONUs, although it is not optimal, by using the offset according to the signal uniformly for the signal from each ONU. Furthermore, since it is not necessary to perform individual threshold adjustment processing for all ONUs, it is possible to realize with simple processing. For example, FIG. 9A shows an example of the packet of the ONU 1a shown in FIG. When the midpoint potential indicated by the broken line is used as a threshold value, the noise on the “1” side is large in the example in the figure, and the probability that “1” is mistaken as “0” increases. Therefore, the reception sensitivity can be improved by attaching the same offset as the ONU 1b to the threshold and bringing the threshold closer to the “0” side.

  Note that the optimum threshold for the ONU 1a is a long broken line, and optimum reception sensitivity cannot be obtained with the same offset as the ONU 1b. However, in the ONU 1a and ONU 1b, the ONU 1a has a higher signal-to-noise ratio and the change in the threshold is not so large and does not affect the reception sensitivity. Therefore, in the OLT 7a, it is not necessary to perform a complicated process of individually providing threshold adjustment amounts, and only the threshold adjustment amount for the ONU with the longest distance is obtained and applied to all ONUs, thereby improving the performance as a system. Can be improved.

  As described above, in the present embodiment, the OLT 7a performs control to optimize the reception threshold. Thereby, in the optical subscriber transmission system in which the optical noise is excessively amplified, the reception sensitivity can be improved and a highly sensitive optical subscriber transmission system can be obtained.

  As described above, the optical repeater amplification apparatus according to the present invention is useful in an access optical transmission system, and is particularly suitable for a PON system.

1, 1a, 1b Subscriber side optical transceiver (ONU)
2, 2a, 2b, 4, 6, 9 Optical fiber transmission path 3, 8 Optical distributor 5, 5a, 5b Optical repeater amplifier 7, 7a Master station side optical transceiver (OLT)
51, 54 Wavelength multiplexer / demultiplexer 52 Constant output burst optical amplifier 53 Linear gain burst optical amplifier 55 Constant output continuous optical amplifier 56 Linear gain continuous optical amplifier 57 Burst optical amplifier 58 Continuous optical amplifier 59 Optical band transmission filter 71 Preamplifier 72 2R Amplifier 73 Clock Data Recovery Module (CDR)
74 Serial to Parallel Data Converter (Serdes)
75 Forward error correction function controller (FEC)
76 Photocurrent intensity monitor 77 External threshold control unit 100 In-station device

Claims (15)

In the optical subscriber transmission system in which the optical transmission / reception apparatus on the master station side and the optical transmission / reception apparatus on the subscriber side transmit and receive optical signals, an optical repeater amplification apparatus that relays optical signals and performs amplification processing
Burst optical amplification means for receiving an upstream burst optical signal transmitted from the subscriber side optical transceiver and performing amplification processing while changing the gain according to the signal intensity of the burst optical signal;
Continuous optical amplifying means for receiving a continuous optical signal in the downstream direction transmitted from the optical transmission / reception apparatus on the master station side and performing amplification processing while changing the gain according to the signal intensity of the continuous optical signal;
An optical repeater amplification apparatus comprising: The burst light amplification means and the continuous light amplification means are each composed of two optical amplifiers, a linear gain semiconductor optical amplifier and a constant gain semiconductor optical amplifier.
The optical repeater amplifying apparatus according to claim 1. The linear gain semiconductor optical amplifier performs amplification processing with a predetermined linear gain in a predetermined input optical signal intensity range.
The optical repeater amplification apparatus according to claim 2. The constant gain semiconductor optical amplifier performs amplification processing with a saturation gain in a high-intensity input optical signal intensity range larger than the predetermined input optical signal intensity range, and outputs a signal with a constant intensity.
The optical repeater amplifier according to claim 3. The burst light amplifying unit and the continuous light amplifying unit are configured by a semiconductor optical amplifier capable of executing linear gain amplification processing and constant gain amplification processing.
The optical repeater amplifying apparatus according to claim 1. The semiconductor optical amplifier performs amplification processing with a predetermined linear gain in a predetermined input optical signal intensity range, and amplifies with a saturation gain in a high-intensity input optical signal intensity range larger than the predetermined input optical signal intensity range. Process and output a signal of constant intensity,
The optical repeater amplifier according to claim 5. The continuous light amplifying means is constituted by a rare earth doped optical fiber amplifier operating in a saturation region in a predetermined input signal light intensity range.
The optical repeater amplifier according to claim 5. further,
An optical band transmission filter disposed at a subsequent stage of the burst light amplifying means and having a transmission wavelength band that transmits all the transmission light wavelength ranges of the plurality of subscriber side optical transmission and reception devices;
The optical repeater amplification apparatus according to claim 1, comprising: A master-side optical transceiver that constitutes an optical subscriber transmission system together with a subscriber-side optical transceiver and the optical repeater amplifier according to any one of claims 1 to 8,
Optical signal regeneration means for performing amplification processing on the upstream optical signal received from the subscriber side optical transceiver, and performing regeneration processing based on a predetermined reception threshold;
Error correction that performs error correction processing and accumulates the error bits of the signal received within a predetermined period, and outputs a level signal corresponding to the difference between 1 and 0, and 0 and 1 Means,
A reception threshold value control means for generating a control signal for controlling the reception threshold value based on the level signal;
With
Based on the level signal, the reception threshold value control means generates a control signal for changing the reception threshold value to 0 side when 1 is erroneously set to 0 and 0 is erroneously set to 1 If the number is larger, generate a control signal to change the reception threshold to 1 side,
The optical signal regeneration means changes the predetermined reception threshold based on the control signal.
An optical transmission / reception device on the master station side. further,
A received signal strength detecting means for detecting a received signal strength of an upstream optical signal received from the subscriber side optical transceiver;
With
The reception threshold control means applies the control signal generated based on the uplink optical signal having the weakest received signal strength to other subscriber-side optical transceivers,
The master-station-side optical transceiver according to claim 9. An optical transceiver on the master station side;
A subscriber-side optical transceiver that transmits and receives optical signals to and from the master-station optical transceiver;
The optical repeater amplification apparatus according to any one of claims 1 to 8, wherein the optical signal is relayed and amplified.
An optical subscriber transmission system comprising: The optical transmission / reception apparatus according to any one of claims 1 to 8, wherein the optical transmission / reception apparatus at the master station repeats an optical signal and performs amplification processing, and the optical transmission / reception apparatus at the parent station and the optical relay amplification apparatus. An intra-station device including a first distributor that is disposed between the first distributor and branches the downstream optical signal;
A subscriber-side optical transceiver for transmitting and receiving optical signals to and from the master-station optical transceiver of the intra-station device;
A second optical distributor disposed between the intra-station apparatus and the subscriber-side optical transmission / reception apparatus for branching a downstream optical signal;
An optical subscriber transmission system comprising: In the in-station device,
If the distance between the own apparatus and the subscriber side optical transceiver is longer than a predetermined distance, the optical repeater amplifier is disposed between the first distributor and the subscriber side optical transceiver,
When the distance between the own apparatus and the subscriber-side optical transmission / reception apparatus is a predetermined distance or less, the optical repeater amplification apparatus is not disposed between the first distributor and the subscriber-side optical transmission / reception apparatus,
The optical subscriber transmission system according to claim 12. The master station side optical transceiver is:
Optical signal regeneration means for performing amplification processing on the upstream optical signal received from the subscriber side optical transceiver, and performing regeneration processing based on a predetermined reception threshold;
Error correction that performs error correction processing and accumulates the error bits of the signal received within a predetermined period, and outputs a level signal corresponding to the difference between 1 and 0, and 0 and 1 Means,
A reception threshold value control means for generating a control signal for controlling the reception threshold value based on the level signal;
With
Based on the level signal, the reception threshold value control means generates a control signal for changing the reception threshold value to 0 side when 1 is erroneously set to 0 and 0 is erroneously set to 1 If the number is larger, generate a control signal to change the reception threshold to 1 side,
The optical signal regeneration means changes the predetermined reception threshold based on the control signal.
The optical subscriber transmission system according to claim 11, 12 or 13. The master station side optical transceiver is:
A received signal strength detecting means for detecting a received signal strength of an upstream optical signal received from the subscriber side optical transceiver;
Further comprising
The reception threshold control means applies the control signal generated based on the uplink optical signal having the weakest received signal strength to other subscriber-side optical transceivers,
The optical subscriber transmission system according to claim 14.

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