JP2007036712A - Communication system, communication method, its master station device, and satellite station device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent a communication system from being deteriorated in transmission efficiency or to suppress deterioration in transmission efficiency when an FEC technology is applied, wherein the communication system has a configuration that a master station device and satellite station devices use a transmission medium and a transmission frequency band in common. <P>SOLUTION: In the communication system, a redundancy control unit (FEC coding/decoding unit 105, PON control unit 109) is provided to an OLT1 to control the redundancy of code error correction codes added to communication data between the OLT1 itself and an ONU4 for each ONU4, and the redundancy control unit of the OLT1 controls redundancy on the basis of the receiving output of a signal received by itself. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a communication system and a communication method in which a master station device and a slave station device share a transmission medium and a transmission band.

  A PON (Passive Optical Network) system is known as a conventional access network for transmitting a multimedia service to each home (for example, see Non-Patent Document 1). In this PON system, a plurality of subscriber side communication devices (Optical Network Unit: hereinafter abbreviated as “ONU”) and a station side communication device (Optical Line Terminal: hereinafter abbreviated as “OLT”) are connected via an optical fiber cable via a star coupler. Since a plurality of ONUs can share a single OLT, they are attracting attention as an economical communication system.

  On the other hand, as a conventional technique related to a data communication system or a data communication method that enables high-quality data reproduction based on an error correction processing technique such as FEC (Forward Error Correction), a round trip time (Round Trip Time) is described below. A dynamic error correction control technique is disclosed in which error correction by resending request processing is selected if the abbreviation of “RTT” is short, and error correction by FEC is selected if the RTT is long. (For example, refer to Patent Document 1).

JP 2003-179580 A (first page) IEEE (Institute of Electrical and Electronics Engineers) 802.3ah

  The conventional technique disclosed in Patent Document 1 only controls whether or not to apply FEC based on the length of RTT. For example, when FEC is applied to the PON system disclosed in Non-Patent Document 1. There is a necessity that the FEC intensity becomes constant for all ONUs connected to the same PON system. For this reason, in a PON system in which ONUs with different connection distances, for example, ONUs with different connection distances coexist, an FEC strength that matches the ONU at the farthest end, for example, is required, and is unnecessary in the near-end ONU. There is a problem that a long FEC redundant code is added and transmission efficiency is lowered.

  The present invention has been made in view of the above, and prevents or reduces a decrease in transmission efficiency when FEC technology is applied to a communication system in which a master station device and a slave station device share a transmission medium and a transmission band. An object of the present invention is to provide a communication system and a communication method that can be performed, and a master station device and a slave station device that constitute the communication system.

  In order to solve the above-described problems and achieve the object, a communication system according to the present invention includes a master station device and a slave station device connected to the master station device via a predetermined transmission medium. In a communication system using a shared transmission band, the master station device controls redundancy of a code error correction code added to communication data between itself and the slave station device for each slave station device. And the redundancy control unit of the master station apparatus controls the redundancy based on a reception output of a signal received by itself.

  According to the communication system of the present invention, the redundancy of the code error correction code added to the communication data between the master station device and the slave station device is controlled for each slave station device, and the signal received by itself is controlled. Since the redundancy of the code error correction code is controlled based on the received output, there is an effect that a decrease in transmission efficiency when the FEC technology is applied to the communication system is prevented or reduced.

  DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments embodying a communication system according to the present invention and a master station device, a slave station device, and a communication method in the communication system will be described below in detail with reference to the drawings. Note that the present invention is not limited to these embodiments.

Embodiment 1 FIG.
(Features of communication system)
First, as for the features of the communication system according to the first embodiment, a subscriber side communication device (ONU) as a slave station device and a station side communication device (OLT) as a master station device are connected by an optical fiber cable. The PON system will be described as an example. In the communication system according to the first exemplary embodiment of the present invention, the redundancy of the FEC redundancy code (code error correction code) added to the communication data is controlled based on the received optical power of the ONU and / or OLT. With this control, for example, when the FEC technology is applied to a GE-PON system to which a GE (Gigabit Ethernet (registered trademark)) protocol is applied as a transmission protocol in the PON system, the connection transmission path state between the OLT and the ONU It is possible to perform communication to which the FEC strength (redundancy) corresponding to is applied.

(Configuration of communication system)
Next, a configuration of the communication system according to the first exemplary embodiment will be described. FIG. 1 is a diagram illustrating a connection configuration of a PON system according to the first exemplary embodiment of the present invention. In the PON system shown in the figure, a plurality of ONUs 4 (4 ₁ , 4 ₂ ,..., 4 _n ) serving as subscriber side communication devices and one OLT 1 serving as a station side communication device signal the optical fiber 3. The transmission medium is connected via the optical coupler 2. In such a PON system, a plurality of ONUs 4 having different connection distances are mixed depending on the connection form.

  FIG. 2 is a block diagram showing a configuration of the OLT according to the first exemplary embodiment of the present invention. The OLT 1 shown in FIG. 1 includes a photoelectric conversion unit (hereinafter abbreviated as “O / E conversion unit”) 101, a received light power measurement unit 102, a bit synchronization unit 103, an 8B / 10B conversion unit 104 serving as a bit conversion unit, and an FEC code. The decoding / decoding unit 105, the control frame extraction unit 106, the control frame insertion unit 107, the control frame termination unit 108, the PON control unit 109, and the frame buffer 110 are configured. The FEC encoding / decoding unit 105 and the PON control unit 109 constitute a redundancy control unit.

  FIG. 3 is a block diagram showing the configuration of the ONU according to the first embodiment of the present invention. The ONU 4 shown in the figure includes an O / E conversion unit 201, a received light power measurement unit 202, a bit synchronization unit 203, a bit conversion unit 8B / 10B conversion unit 204, an FEC encoding / decoding unit 205, and a control frame insertion unit. 206, a control frame extraction unit 207, a control frame termination unit 208, a PON control unit 209, and a frame buffer 210. As in the OLT 1, the FEC encoding / decoding unit 205 and the PON control unit 209 constitute a redundancy control unit.

(Operation of communication system)
Next, the operation of the communication system according to the first exemplary embodiment will be described. First, the ranging process in auto-discovery defined in IEEE802.3ah will be described. Auto-discovery is a function for the OLT to detect an ONU in order to register an ONU that can be operated by turning on the power on the PON system.

  FIG. 4 is a sequence diagram showing an auto-discovery sequence in the PON system. In the figure, the ONU 4 receives a Discovery_GATE message periodically transmitted from the OLT 1 (SQ101). If the ONU 4 is not registered, the ONU 4 receives only the Discovery_GATE message. In response to this message, the ONU 4 sends a REGISTER_REQ (Request) message to the OLT 1 to request establishment of a logical link (SQ102). In response to this logical link probability request, the OLT 1 reserves a logical link user identification number (hereinafter abbreviated as “LLID”), inserts the reserved LLID into the REGISTER message, and notifies the ONU 4 (SQ103). ). Thereafter, a timing instruction when the ONU 4 returns a REGISTER_ACK message to the OLT 1 is included, and a Normal_GATE message that is a permission message for the ONU 4 to use the upstream band is transmitted (SQ104). The ONU 4 sets the designated LLID and transmits a REGISTER_ACK message at the timing indicated in Normal_GATE (SQ105). By these procedures, when the OLT 1 receives the REGISTER_ACK message transmitted from the ONU 4, a logical link between the OLT 1 and the ONU 4 is established.

  By the way, in the above, as shown in FIG. 1, it has been mentioned that each ONU 4 connected to one PON system is individually located at a different distance from the OLT 1. In a GE-PON system to which a GE (Gigabit Ethernet (registered trademark)) protocol is applied as a transmission protocol, a round trip time (RTT) corresponding to the distance between the OLT 1 and the ONU 4 is set as the OLT 1 and the ONU 4. A transmission control process is performed to measure based on a time stamp embedded in a control message (GATE message and REPORT message) communicated between the two, and to perform time division multiplexing control of an uplink frame in consideration of the RTT.

  Next, RTT measurement processing performed in the OLT will be described. FIG. 5 is an explanatory diagram showing a sequence of RTT measurement. In the figure, each of the OLT 1 and each ONU 4 has, for example, a 32-bit counter. These counters count up, for example, every 2 bytes of the main signal transfer rate. Note that the speed (count-up speed) at this time corresponds to, for example, 16 ns in the case of a GE-PON system having a main signal transfer speed of 1.25 Gbps.

  Returning to FIG. 5, the OLT 1 autonomously counts up a counter (not shown), and sets the counter value (T1) in the time stamp area in the message when the GATE message is transmitted (SQ201). On the other hand, when the ONU 4 receives the GATE message, the value of the time stamp (T1) is set in the counter (SQ202). The ONU 4 sets the counter value (T4: T4 = T1 + (T3-T2)) at the time of transmission of the REPORT message in the time stamp area in the message (SQ203). The OLT 1 receives the REPORT message and calculates a difference value between the counter value (T5) of the OLT and the time stamp area value (T4) in the REPORT message (SQ204). The difference value T5-T4 calculated at this time is T5-T4 = T5- {T1 + (T3-T2)} = (T5-T3) + (T2-T1) = RTT, and T5-T4 is RTT will be represented.

  As described above, in the RTT measurement process, the OLT 1 is the master device, the ONU 4 is the slave device, and the procedure using the GATE / REPORT message as described above is periodically performed, so that the oscillator accuracy and propagation speed of the ONU 4 are increased. Variations in RTT due to fluctuations, synchronization loss, etc. are corrected.

  Next, a transmission processing procedure in the OLT 1 of a control message (downward control message) transmitted from the OLT 1 to the ONU 4 will be described. In FIG. 2, the PON control unit 109 of the OLT 1 instructs the control frame termination unit 108 to generate a control message (for example, Discovery_GATE message), and the control frame termination unit 108 generates a control message. The generated control message is multiplexed with the downlink main signal frame by the control frame insertion unit 107 and transmitted to the FEC encoding / decoding unit 105. In the FEC encoding / decoding unit 105, the FEC redundant code is added. The frame to which the FEC redundancy code is added is converted into 10B by the 8B / 10B conversion unit 104, and then converted into an optical signal by the photoelectric conversion unit (hereinafter referred to as "O / E conversion unit") 101. It is transmitted to ONU4.

  In the above processing procedure, an arbitrary value of FEC redundancy added by the FEC encoding / decoding unit 105 can be used. However, if the maximum FEC redundancy is set as the initial value of the FEC redundancy, for example, in the PON system, the desired communication can be ensured even if the transmission path is the worst ONU (for example, the farthest end ONU). It can be carried out.

  Further, the reception processing procedure in the ONU 4 of the control message transmitted from the OLT 1 to the ONU 4 is as follows. In FIG. 3, the O / E conversion unit 201 converts an optical signal into an electrical signal, and further converts the optical signal into 8B by the 8B / 10B conversion unit 204, and then transmits the converted signal to the FEC encoding / decoding unit 205. The FEC encoding / decoding unit 205 performs FEC decoding. The control message frame subjected to FEC decoding is extracted from the main signal data frame by the control frame extraction unit 207 and then transmitted to the control frame termination unit 208. The control frame termination unit 208 analyzes the frame and notifies the PON control unit 209 of necessary information.

  In the above processing procedure, the initial value of the FEC redundancy used when the FEC encoding / decoding unit 205 performs decoding may be the same as that used on the transmission side. For example, if the maximum FEC redundancy is set as the initial value of the FEC redundancy on the transmission side, the maximum FEC redundancy may be used also on the reception side.

  Next, a transmission processing procedure in the ONU 4 of a control message (uplink control message) transmitted from the ONU 4 to the OLT 1 will be described. In FIG. 3, the PON control unit 209 of the ONU 4 instructs the control frame termination unit 208 to generate a control message (for example, REGISTER_REQ message), and the control frame termination unit 208 generates a control message. The generated control frame is multiplexed with the downlink main signal frame by the control frame insertion unit 206 and transmitted to the FEC encoding / decoding unit 205. In the FEC encoding / decoding unit 205, the FEC redundant code is added. The frame to which the FEC redundancy code is added is converted to 10B by the 8B / 10B converter 204, then converted to an optical signal by the O / E converter 201, and transmitted to the OLT 1. As in the case of the downlink direction, an arbitrary value can be used as the initial value of the FEC redundancy, but it is particularly preferable to set the maximum redundancy.

  Further, the reception processing procedure in the OLT 1 of the control message transmitted from the ONU 4 to the OLT 1 is as follows. In FIG. 2, an optical signal is converted into an electric signal in the O / E conversion unit 101, further converted into 8B in the 8B / 10B conversion unit 104, and then transmitted to the FEC encoding / decoding unit 105. The FEC encoding / decoding unit 105 performs FEC decoding. The control message frame subjected to FEC decoding is extracted from the main signal data frame by the control frame extraction unit 106 and then transmitted to the control frame termination unit 108. The control frame termination unit 108 analyzes the frame and notifies the PON control unit 109 of necessary information.

  Note that, during the above processing procedure, the initial value of the FEC redundancy at the time of decoding by the FEC encoder / decoder 105 may be the same as that used on the transmission side. For example, if the maximum FEC redundancy is set as the initial value of the FEC redundancy on the transmission side, the maximum FEC redundancy may be used also on the reception side.

  Next, the processing procedure of FEC redundancy control using a control message will be described with reference to FIGS.

  In the auto-discovery operation, when the Discovery_GATE message and the REGISTER_REQ message are transmitted / received, the RTT is measured by the OLT 1 as shown in FIG. 5 in which the GATE message and the REPORT message are transmitted / received.

  When the RTT is measured, the FEC redundancy corresponding to the RTT is selected by the OLT 1 and notified to the ONU 4 corresponding to the RTT by a REGISTER message. In FIG. 2, the PON control unit 109 of the OLT 1 sets the FEC redundancy corresponding to the RTT of each ONU 4 measured when the logical link is established in the FEC encoding / decoding unit 105. The transmission frame for the ONU 4 corresponding to the RTT is subsequently operated with the set FEC redundancy.

  For example, in the GE-PON system, regarding the upstream frame, the PON control unit 109 performs bandwidth control so as to avoid collision of frames transmitted from a plurality of ONUs 4. It can be determined by the timing at which the OLT 1 receives. In this way, the OLT 1 can determine from which ONU 4 the received frame is transmitted, and a frame decoded with the FEC redundancy corresponding to the ONU 4 is transmitted to the ONU 4.

  On the other hand, in FIG. 3, the PON control unit 209 of the ONU 4 sets the FEC redundancy notified by the REGISTER message from the OLT 1 in the FEC encoding / decoding unit 205. The transmission frame is encoded with the set FEC redundancy and is transmitted to the OLT 1 according to the information in the GATE message. The received frame is decoded with the set FEC redundancy.

  The first operation is started with the above FEC redundancy. During operation, the received light power of the signal transmitted from each ONU 4 is measured and operated by the received light power measuring unit 102 in the OLT 1. Whether the FEC redundancy is appropriate is monitored. For example, if the light receiving power from the ONU 4 decreases, it means that the transmission path condition has deteriorated. Therefore, the strength of the FEC redundancy is increased. Conversely, if the received light power increases, it means that the transmission path state has been improved, so that the strength of the FEC redundancy can be reduced to increase the transmission efficiency.

  Next, the operation for changing the FEC redundancy will be described. In FIG. 2, the received light power measurement unit 102 of the operating OLT 1 detects a change in received light power from a predetermined ONU 4. The change in the received light power of the ONU 4 is notified to the PON control unit 109, and the PON control unit 109 determines whether or not to change the FEC redundancy. When changing the FEC redundancy, the PON control unit 109 instructs the control frame termination unit 108 to generate an FEC control frame including an FEC redundancy change instruction. The generated FEC control frame is inserted between downlink data frames by the control frame insertion unit 107, and after a predetermined process, is notified to a predetermined ONU 4.

  Also, in FIG. 3, the FEC control frame is extracted by the control frame extraction unit 207, analyzed by the control frame termination unit 208, and necessary information is notified to the PON control unit 209. The change in the FEC redundancy is transmitted from the PON control unit 209 to the FEC encoding / decoding unit 205. Note that an FEC response control frame in response to the FEC control frame from the OLT 1 is transmitted to the OLT 1, and data frames after the FEC response control frame are encoded with a new FEC redundancy.

  The FEC response control frame from the ONU 4 instructed to change the redundancy is received by the OLT 1, and the data frame from the ONU 4 after receiving the FEC response control frame is decoded with the new FEC redundancy. Further, the FEC control frame is transmitted again from the OLT 1 to the ONU 4, and the data frames after the retransmitted FEC control frame are encoded with the new FEC redundancy.

  In addition, a change in received light power is also measured in the received light power measurement unit 202 in the ONU 4 to monitor whether the FEC redundancy during operation is appropriate. If it is necessary to change the FEC redundancy, the FEC change request control frame generated by the ONU 4 is transmitted to the OLT 1.

  The FEC change request control frame is received by the OLT 1, and the PON control unit 109 of the OLT 1 instructs the control frame termination unit 108 to generate an FEC control frame including an FEC redundancy change instruction. The subsequent operation is the same as the above operation.

  In this embodiment, as shown in FIGS. 2 and 3, the OLT 1 and the ONU 4 are both provided with the received light power measuring unit. However, it is not necessary to provide both, and one of them is not provided. It only has to have.

  As described above, in this embodiment, the redundancy of the FEC redundancy code added to the communication data is controlled based on the received optical power in a plurality of ONUs and / or OLTs. -When FEC technology is applied to the PON system, communication can be performed with the FEC strength (redundancy) according to the connection transmission line state between the OLT and the ONU, and transmission according to the connection transmission line state of the ONU Efficiency can be controlled appropriately.

Embodiment 2. FIG.
(Features of communication system)
The communication system according to the second embodiment is based on the degree of disturbance of the clock signal extracted from the received signal of the ONU that is the slave station apparatus and / or the OLT that is the master station apparatus (hereinafter referred to as “disturbance degree”). By controlling the redundancy in the FEC redundancy code added to the communication data, for example, when the FEC technology is applied to the GE-PON system, the FEC strength (corresponding to the connection transmission path state between the OLT and the ONU ( The communication is performed with redundancy).

(Configuration of communication system)
Next, the configuration of the communication system according to the second exemplary embodiment will be described. FIG. 6 is a block diagram showing the configuration of the OLT according to the second embodiment of the present invention, and FIG. 7 is a block diagram showing the configuration of the ONU according to the second embodiment of the present invention. The OLT shown in FIG. 6 is configured to include an extracted CLK (clock) disturbance detection unit 302 that detects the disturbance of the clock signal extracted from the received signal, instead of the configuration of the received light power measurement unit 102 of the first embodiment. Is done. Similarly, the ONU shown in FIG. 7 includes an extracted CLK disturbance detection unit 402 that detects the disturbance of the clock signal extracted from the received signal, instead of the configuration of the received light power measurement unit 202 of the first embodiment. Is done. 6 and 7, the configuration other than the above-described extracted CLK disturbance detection units 302 and 402 is the same as or equivalent to the configuration of the first embodiment.

(Operation of communication system)
Next, the operation of the communication system according to the second exemplary embodiment will be described. Since the operation up to the start of the initial operation is the same as that in the first embodiment, the description thereof will be omitted, and the operation for changing the FEC redundancy will be described below.

  In the communication system of this embodiment, the operation is started with the initial FEC redundancy by the same operation as that of the first embodiment. On the other hand, during operation, the extracted CLK disturbance detection unit 302 in the OLT 1 extracts the clock signal of the signal transmitted from each ONU 4, and the FEC redundancy that is operated based on the disturbance level of the clock signal. It is monitored for appropriateness. For example, if the clock disturbance extracted from the received signal increases, it means that the transmission path condition has deteriorated, so the strength of FEC redundancy is increased. Conversely, if the extracted clock disturbance is reduced, it means that the transmission path state has been improved, so that the strength of the FEC redundancy can be reduced and the transmission efficiency can be increased.

  In FIG. 6, the extracted CLK disturbance detection unit 302 in the operating OLT 1 detects the degree of disturbance (variation) of the clock signal extracted from the received signal. The change is notified to the PON control unit 309, and the PON control unit 309 determines whether or not to change the FEC redundancy. When changing the FEC redundancy, the PON control unit 309 instructs the control frame termination unit 308 to generate an FEC control frame including an FEC redundancy change instruction. The generated FEC control frame is inserted between downlink data frames by the control frame insertion unit 307, and after a predetermined process thereafter, is notified to a predetermined ONU 4.

  In FIG. 7, the FEC control frame is extracted by the control frame extraction unit 407, analyzed by the control frame termination unit 408, and necessary information is notified to the PON control unit 409. The change of the FEC redundancy is transmitted from the PON control unit 409 to the FEC encoding / decoding unit 405. Note that an FEC response control frame in response to the FEC control frame from the OLT 1 is transmitted to the OLT 1, and data frames after the FEC response control frame are encoded with a new FEC redundancy.

  The FEC response control frame from the ONU 4 instructed to change the redundancy is received by the OLT 1, and the data frame from the ONU 4 after receiving the FEC response control frame is decoded with the new FEC redundancy. Further, the FEC control frame is transmitted again from the OLT 1 to the ONU 4, and the data frames after the retransmitted FEC control frame are encoded with the new FEC redundancy.

  The extracted CLK disturbance detection unit 402 in the ONU 4 also detects the disturbance level (variation) of the clock signal extracted from the received signal, and monitors whether the FEC redundancy in operation is appropriate. If it is necessary to change the FEC redundancy, the FEC change request control frame generated by the ONU 4 is transmitted to the OLT 1.

  The FEC change request control frame is received by the OLT 1, and the PON control unit 309 of the OLT 1 instructs the control frame termination unit 308 to generate an FEC control frame including an FEC redundancy change instruction. The subsequent operation is the same as the above operation.

  In this embodiment, as shown in FIG. 6 and FIG. 7, both the OLT 1 and the ONU 4 are provided with the extracted CLK disturbance detection unit. However, it is not necessary to have both, and either one is provided. Should just have.

(Configuration of Extracted CLK Disturbance Detection Unit)
Next, the configuration of the extracted CLK disturbance detection unit will be described. FIG. 8 is a block diagram illustrating a configuration example of the extracted CLK disturbance detection unit. The extracted CLK disturbance detection unit shown in the figure includes a phase comparator 501, a loop filter 502, a VCO (Voltage Control Oscillator) 503, a frequency division 504, and a voltage fluctuation detection unit 505, and a general PLL (Phase Locked Loop). ) It has the same configuration as the circuit.

(Operation of Extracted CLK Disturbance Detection Unit)
Next, the operation of the extracted CLK disturbance detection unit will be described. In the phase comparator 501, the output signal (received electrical signal) from the O / E converter 301 or O / E converter 401 and the output clock from the VCO 503 are 1 / N (N is a predetermined natural number) in a division cycle 504. Are divided in phase and a clock synchronized with the received signal is generated. On the other hand, in a situation where the transmission path is deteriorated, the clock phase is frequently corrected, so that the fluctuation of the output voltage of the phase comparator 501 increases. This fluctuation component is detected by the voltage fluctuation detection unit 505 and output to the PON control unit 309 or the PON control unit 409. As described above, the extracted CLK disturbance detection unit has a function of detecting the degree of fluctuation of the clock signal phase generated from the received signal as the degree of disturbance of the clock signal.

  FIG. 9 is a block diagram illustrating another configuration example of the extracted CLK disturbance detection unit different from FIG. The extracted CLK disturbance detection unit shown in the figure includes a phase comparator 601, a loop filter 602, a VCO 603, a division period 604, and a voltage fluctuation detection unit 605. Although the configuration is similar to that of the extracted CLK disturbance detection unit illustrated in FIG. 8, the time constant of the loop filter 602 is set to a smaller value compared to FIG. 8. When the time constant of the loop filter 602 is reduced, the control to the VCO 603 is frequently performed, so that the fluctuation of the output voltage of the loop filter 602 increases. Therefore, if the transmission path is deteriorated, the fluctuation component of the output voltage of the loop filter 602 increases, so that the fluctuation of the output of the loop filter 602 can be detected as the degree of disturbance of the clock signal.

  As described above, in this embodiment, the FEC added to the communication data based on the degree of disturbance of the clock signal extracted from the received signals in the plurality of ONUs and / or OLTs (that is, equivalent to the transmission path state). Since the redundancy of the redundant code is controlled, for example, when the FEC technology is applied to the GE-PON system, communication is performed with the FEC strength (redundancy) corresponding to the connection transmission path state between the OLT and the ONU. The transmission efficiency according to the connection transmission path state of the ONU can be appropriately controlled.

Embodiment 3 FIG.
(Features of communication system)
When the FEC redundancy is controlled according to the connection distance between the ONU that is the slave station device and the OLT that is the master station device or the state of the connection transmission path, the communication system according to the third embodiment The communication speed between the ONU and the OLT is controlled according to the above. If such speed control is performed, the transmission efficiency can be controlled to be substantially constant regardless of the connection distance between the ONU and the OLT and the connection transmission path condition.

(Configuration of communication system)
Next, the configuration of the communication system according to the third exemplary embodiment will be described. FIG. 10 is a block diagram showing the configuration of the OLT according to the third embodiment of the present invention, and FIG. 11 is a block diagram showing the configuration of the ONU according to the third embodiment of the present invention. The OLT shown in FIG. 10 is inserted between the FEC encoding / decoding unit 705, the control frame extraction unit 706, and the control frame insertion unit 707 in addition to the configuration of the first embodiment shown in FIG. It is comprised so that the speed adjustment part 711 may be provided. Similarly, the ONU shown in FIG. 9 includes the FEC encoding / decoding unit 805, the control frame insertion unit 806, and the control frame extraction unit 807 in addition to the configuration of the first embodiment shown in FIG. It is comprised so that the speed adjustment part 811 inserted in may be provided. 10 and 11, the configuration other than the above-described speed adjustment units 711 and 811 is the same as or equivalent to the configuration of the first embodiment.

(Operation of communication system)
Next, the operation of the communication system according to the third exemplary embodiment will be described. First, in the auto-discovery operation, the RTT (round trip propagation delay time) is measured by the OLT 1 when the Discovery_GATE message and the REGISTER_REQ message are transmitted and received, as in the first embodiment. When the RTT is measured, the FEC redundancy corresponding to the RTT is selected by the OLT 1, and the reception / transmission circuit operating frequency (communication speed) corresponding to the RTT is selected, and the REGISTER message The ONU 4 corresponding to the RTT is notified. Here, when the value of RTT is large (for example, in the case of long-distance connection ONU), it is necessary to increase the redundancy, and as a result, the FEC redundancy code becomes longer, the user data area is reduced, and the transmission efficiency is lowered. To do. Therefore, when the value of RTT is large, the reception / transmission circuit operating frequency (communication speed) is also set high.

  In FIG. 10, the PON control unit 709 of the OLT 1 corresponds to the FEC redundancy / corresponding RTC of each ONU 4 measured at the time of establishing the logical link to the FEC encoding / decoding unit 705 and also corresponds to the RTT of each ONU 4. The reception / transmission circuit operating frequency (communication speed) is set in the bit synchronization unit 703, 8B / 10B conversion unit 704, FEC encoding / decoding unit 705, and rate adjustment unit 711. The transmission frame for the ONU 4 corresponding to the RTT is thereafter operated with the set FEC redundancy and communication speed.

  For example, in the GE-PON system, regarding the upstream frame, the PON control unit 709 performs bandwidth control so as to avoid collision of frames transmitted from a plurality of ONUs 4. It can be determined by the timing at which the OLT 1 receives. In this way, the OLT 1 can determine from which ONU 4 the received frame is transmitted, and the bit synchronization unit 703, 8B / 10B conversion unit at the circuit operating frequency (communication speed) corresponding to the ONU 4 704, the frame reception in which the FEC encoding / decoding unit 705 and the speed adjustment unit 711 are operated, and the decoding by the FEC redundancy corresponding to the ONU 4 are executed.

  On the other hand, in FIG. 11, the PON control unit 809 of the ONU 4 sets the FEC redundancy notified by the REGISTER message from the OLT 1 in the FEC encoding / decoding unit 805, and the circuit operating frequency corresponding to the RTT of the ONU 4 (Communication speed) is set in the bit synchronization unit 803, 8B / 10B conversion unit 804, FEC encoding / decoding unit 805, and speed adjustment unit 811. The transmission frame is transmitted to the OLT 1 according to the information in the GATE message with the set FEC redundancy and communication speed. The received frame is a frame received by operating the bit synchronization unit 803, 8B / 10B conversion unit 804, FEC encoding / decoding unit 805, and speed adjustment unit 811 at the set circuit operating frequency (communication speed). Decoding with the set FEC redundancy is executed.

  Further, the operation is started with the FEC redundancy and the circuit operating frequency. During the operation, the light reception power measurement unit 702 in the OLT 1 receives the signals transmitted from the respective ONUs 4 as in the first embodiment. The power is measured and it is monitored whether the operating FEC redundancy is appropriate. When it becomes necessary to correct the FEC redundancy, the FEC redundancy is changed as in the first embodiment, and the circuit operating frequency is also changed.

  As described above, in this embodiment, the redundancy of the FEC redundancy code added to the communication data is controlled based on the received optical power in the plurality of ONUs and / or OLTs, and the redundancy is determined according to the redundancy. Since the communication speed is controlled, for example, when the FEC technology is applied to the GE-PON system, the transmission efficiency can be controlled to be almost constant without depending on the connection distance of the ONU and the connection transmission path condition. it can.

Embodiment 4 FIG.
(Features of communication system)
In the communication system according to the fourth embodiment, the FEC redundancy code added to the communication data based on the degree of disturbance of the clock signal extracted from the received signal of the ONU that is the slave station device and / or the OLT that is the master station device. When controlling, it has the feature in controlling the communication speed between ONU and OLT according to the said redundancy. If such speed control is performed, the transmission efficiency can be controlled to be substantially constant regardless of the connection distance between the ONU and the OLT and the connection transmission path condition.

(Configuration of communication system)
Next, the configuration of the communication system according to the fourth embodiment will be described. FIG. 12 is a block diagram showing a configuration of the OLT according to the fourth embodiment of the present invention, and FIG. 13 is a block diagram showing a configuration of the ONU according to the fourth embodiment of the present invention. The OLT shown in FIG. 12 is inserted between the FEC encoding / decoding unit 905, the control frame extracting unit 906, and the control frame inserting unit 907 in addition to the configuration of the second embodiment shown in FIG. It is comprised so that the speed adjustment part 911 may be provided. Similarly, the ONU shown in FIG. 13 includes the FEC encoding / decoding unit 1005, the control frame insertion unit 1006, and the control frame extraction unit 1007 in addition to the configuration of the second embodiment shown in FIG. It is comprised so that the speed adjustment part 1011 inserted in may be provided. 12 and 13, the configuration other than the speed adjustment units 911 and 1011 described above is the same as or equivalent to the configuration of the second embodiment.

  If the communication system according to this embodiment is compared with the third embodiment, the received light power measuring unit 702 shown in FIG. 10 and the received light power measuring unit 802 shown in FIG. 11 are extracted CLK disturbance detecting unit 902. , 1002 respectively, and the FEC redundancy and communication speed are controlled based on the disturbance level of the clock signal extracted from the received signal instead of the received optical power. Therefore, the operations related to the FEC redundancy change procedure and the circuit operation frequency change procedure are common, and the description thereof is omitted.

  As described above, in this embodiment, the FEC added to the communication data based on the degree of disturbance of the clock signal extracted from the received signals in the plurality of ONUs and / or OLTs (that is, equivalent to the transmission path state). Since the redundancy of the redundant code is controlled and the communication speed is controlled according to the redundancy, for example, when the FEC technology is applied to the GE-PON system, the ONU connection distance and the connection transmission path status Without depending on the transmission efficiency, the transmission efficiency can be controlled almost constant.

  In the first to fourth embodiments described above, the case where an Ethernet (registered trademark) frame is used has been described as an example. However, the present invention is not limited to this type of frame, and is widely applied to packet communication. can do.

  Moreover, although Embodiment 1-4 demonstrated the case where it applied to a PON system as an example, an application system is not limited to this kind of system, Communication is performed between several communication apparatuses. As long as it is present, it can be applied to any system such as optical or electrical wired communication or wireless communication, and can be applied to communication in a one-to-one connection.

  As described above, the communication system according to the present invention is useful for a communication system to which the FEC technology is applied, and is particularly suitable for a PON system in which a master station device and a slave station device share a transmission medium and a transmission band. is there.

It is a figure which shows the connection structure of the PON system concerning Embodiment 1 of this invention. It is a block diagram which shows the structure of OLT concerning Embodiment 1 of this invention. It is a block diagram which shows the structure of ONU concerning Embodiment 1 of this invention. It is a sequence diagram which shows the sequence of the auto discovery in a PON system. It is explanatory drawing which shows the sequence of RTT measurement. It is a block diagram which shows the structure of OLT concerning Embodiment 2 of this invention. It is a block diagram which shows the structure of ONU concerning Embodiment 2 of this invention. It is a block diagram which shows the structural example of an extraction CLK disturbance detection part. It is a block diagram which shows the other structural example different from FIG. 8 of the extraction CLK disturbance detection part. It is a block diagram which shows the structure of OLT concerning Embodiment 3 of this invention. It is a block diagram which shows the structure of ONU concerning Embodiment 3 of this invention. It is a block diagram which shows the structure of OLT concerning Embodiment 4 of this invention. It is a block diagram which shows the structure of ONU concerning Embodiment 4 of this invention.

Explanation of symbols

1 OLT
2 Optical coupler 3 Optical fiber 4 ONU
101, 201, 301, 401, 701, 801, 901, 1001 O / E converters 102, 202, 702, 802 Light reception power measuring units 103, 203, 303, 403, 703, 803, 903, 1003 Bit synchronization unit 104 204, 304, 404, 704, 804, 904, 1004 8B / 10B converter 105, 205, 305, 405, 705, 805, 905, 1005 FEC encoder / decoder 106, 207, 306, 407, 706 , 807, 906, 1007 Control frame extraction unit 107, 206, 307, 406, 707, 806, 907, 1006 Control frame insertion unit 108, 208, 308, 408, 708, 808, 908, 1008 Control frame termination unit 109, 209, 309, 409, 709, 80 9, 909, 1009 PON control unit 110, 210, 310, 410, 710, 810, 910, 1010 Frame buffer 302, 402, 902, 1002 Extracted CLK disturbance detection unit 501, 601 Phase comparator 502, 602 Loop filter 503 603 VCO
504, 604 minute period 505, 605 Voltage fluctuation detection unit 703 Bit synchronization unit 711, 811, 911, 1011 Speed adjustment unit

Claims (14)

In a communication system in which each of a master station device and a slave station device connected to the master station device via a predetermined transmission medium shares and uses the transmission band of the transmission medium,
The master station device includes a redundancy control unit that controls the redundancy of a code error correction code added to communication data between itself and the slave station device for each slave station device,
The redundancy control unit of the master station device controls the redundancy based on a reception output of a signal received by itself. In a communication system in which each of a master station device and a slave station device connected to the master station device via a predetermined transmission medium shares and uses the transmission band of the transmission medium,
The master station device includes a redundancy control unit that controls the redundancy of a code error correction code added to communication data between itself and the slave station device for each slave station device,
The redundancy control unit of the master station device controls the redundancy based on a disturbance degree of a clock signal extracted from a signal received by the master station apparatus. The master station device further includes a speed adjustment unit that controls a communication speed between itself and the slave station device for each slave station device,
The speed adjustment unit of the master station device controls a communication speed between the master station device and the slave station device according to redundancy set between the master station device and the slave station device. Item 3. The communication system according to Item 1 or 2. In a communication system in which each of a master station device and a slave station device connected to the master station device via a predetermined transmission medium shares and uses the transmission band of the transmission medium,
The master station device includes a redundancy control unit that controls the redundancy of a code error correction code added to communication data between itself and the slave station device for each slave station device,
The slave station device includes a redundancy control unit that controls redundancy of a code error correction code added to communication data between itself and the master station device,
The redundancy control unit of the slave station device receives the signal output received by itself when it is necessary to change the redundancy of the code error correction code added to the communication data between itself and the master station device. A message for changing the redundancy based on the base station device,
The redundancy control unit of the master station device adds communication data between the slave station device including the slave station device that has transmitted the redundancy change request and itself based on the message transmitted from the slave station device. A communication system characterized by controlling redundancy of a code error correction code. In a communication system in which each of a master station device and a slave station device connected to the master station device via a predetermined transmission medium shares and uses the transmission band of the transmission medium,
The master station device includes a redundancy control unit that controls the redundancy of a code error correction code added to communication data between itself and the slave station device for each slave station device,
The slave station device includes a redundancy control unit that controls redundancy of a code error correction code added to communication data between itself and the master station device,
The redundancy control unit of the slave station device is extracted from the signal received by the slave station device when it is necessary to change the redundancy of the code error correction code added to the communication data between the slave station device and the master station device. A message for changing the redundancy based on the disturbance level of the clock signal is transmitted to the master station device,
The redundancy control unit of the master station device adds a code error added to communication data between the slave station device including the slave station device that has transmitted the message based on the message transmitted from the slave station device and itself A communication system characterized by controlling redundancy of a correction code. The slave station device further includes a speed adjustment unit that controls a communication speed between itself and the master station device,
The speed adjustment unit of the slave station device controls a communication speed between the slave station device and the slave station device according to a redundancy set between the slave station device and the slave station device. The communication system according to 1 or 2.   The communication system according to claim 1, wherein the redundancy of the code error correction code is set to a maximum strength at an initial stage of communication. In a master station device connected to a slave station device that shares and uses a transmission band of a predetermined transmission medium,
The master station device includes a redundancy control unit that controls the redundancy of a code error correction code added to communication data between itself and the slave station device for each slave station device,
The redundancy control unit of the master station device controls the redundancy based on a reception output of a signal received by the master station device. In a master station device connected to a slave station device that shares and uses a transmission band of a predetermined transmission medium,
The master station device includes a redundancy control unit that controls the redundancy of a code error correction code added to communication data between itself and the slave station device for each slave station device,
The redundancy control unit of the master station device controls the redundancy based on a disturbance level of a clock signal extracted from a signal received by the master station device. The master station device further includes a speed adjustment unit that controls a communication speed between itself and the slave station device for each slave station device,
The speed adjustment unit of the master station device controls a communication speed between the master station device and the slave station device according to redundancy set between the master station device and the slave station device. Item 10. The master station device according to Item 8 or 9. In the slave station apparatus connected to the master station apparatus via a predetermined transmission medium and using the transmission band of the transmission medium in common,
The slave station device includes a redundancy control unit that controls redundancy of a code error correction code added to communication data between itself and the master station device,
The redundancy control unit of the slave station device sends a request to change the redundancy of the code error correction code to be added to communication data between the master station device and the master station device based on the reception output of the signal received by the slave station device. A slave station device transmitting to a master station device. A communication method applied to a communication system in which each of a master station device and a slave station device connected to the master station device via a predetermined transmission medium uses the transmission band of the transmission medium in common,
A redundancy control step for controlling the redundancy of a code error correction code added to communication data between the master station device and the slave station device for each slave station device;
In the redundancy control step, redundancy of a code error correction code added to the communication data is controlled based on a reception output of a signal received by the master station device and / or the slave station device. Communication method. A communication method applied to a communication system in which each of a master station device and a slave station device connected to the master station device via a predetermined transmission medium uses the transmission band of the transmission medium in common,
A redundancy control step for controlling the redundancy of a code error correction code added to communication data between the master station device and the slave station device for each slave station device;
In the redundancy control step, the redundancy of the code error correction code added to the communication data based on the disturbance degree of the clock signal extracted from the signal received by the master station apparatus and / or the slave station apparatus is set. A communication method characterized by being controlled. A speed adjustment step of controlling a communication speed between the master station device and the slave station device for each slave station device;
In the speed adjustment unit step, the communication speed between the master station device and the slave station device is controlled according to the redundancy set between the master station device and the slave station device. The communication method according to claim 12 or 13, characterized in that:

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