JP4839895B2 - Optical communication system - Google Patents

Description

The present invention is a computer relates to an optical communication system applied with the exchange or general communication devices and more particularly to an optical communication system capable of coping when an error or failure of the reception of the optical signal is generated.

  In an optical communication system that transmits and receives an optical signal using an optical fiber, the optical signal is converted into an electric signal on the receiving side, and necessary processing using an electric circuit is performed (for example, see Patent Document 1). . In such an optical communication system, it is necessary to determine whether a signal converted into an electrical signal is valid or invalid on the receiving side. Even if the transmission side normally transmits the transmission data as an optical signal, a failure may occur in the transmission path and this may not be transmitted to the reception side, or the optical signal may not be originally transmitted due to a failure on the transmission side. .

  FIG. 6 shows a main part of a conventional optical communication system. In this optical communication system 100, the optical signal 102 output from the transmission-side electrical / optical conversion unit 101 is transmitted to the reception side via the optical transmission path 103 and input to the optical / electrical conversion unit 104. It has become. The optical / electrical conversion unit 104 is provided with an optical / electrical conversion circuit 105 that converts the optical signal 102 into an electrical signal and an optical signal detection circuit 106 that detects the optical signal 102 in parallel.

  Among these, the optical signal detection circuit 106 is a circuit that detects the input of the optical signal 102. When the optical signal detection circuit 106 detects the optical signal 102, the optical detection signal 107 is input to the determination circuit 109 in the reception unit 108 arranged at the subsequent stage of the optical / electrical conversion unit 104. Data 111 output from the optical / electrical conversion circuit 105 of the optical / electrical conversion unit 104 is input to the determination circuit 109 in the reception unit 108 via the AC coupling capacitor 112. The determination circuit 109 uses the light detection signal 107 as an enable signal, determines that the data 111 is valid only when it is input, and outputs it as received data 113.

  As described above, in the optical communication system shown in FIG. 6, there is an error or failure (hereinafter simply referred to as failure) such that invalid data is transmitted to the reception side due to failure of the electrical / optical conversion unit 101 on the transmission side. If it occurs, the determination circuit 109 determines this and prevents the reception data 113 from being output. However, in this conventional optical communication system, when one optical / electrical conversion unit 104 has a parallel configuration that handles a plurality of optical signals, an optical signal detection circuit 106 and a determination circuit 109 are provided for each optical signal. There is a need. For this reason, the number of signals handled by the receiving unit 108 increases. In general, since the receiving unit 108 is configured by LSI (Large Scale Integration), there is a problem that the number of signal pins increases.

  Therefore, in the case where one optical / electrical conversion unit 104 has a parallel configuration that handles a plurality of optical signals, an AND circuit that takes the logical product of the optical detection signals 107 output from the respective optical signal detection circuits 106 is disposed. It has been proposed to do. In this proposal, the photodetection signal 107 is effectively handled only when all the photodetection signals 107 are detected simultaneously. Thereby, an increase in the number of signal pins input to the receiving unit 108 can be avoided.

  However, if the number of the optical detection signals 107 input to the determination circuit 109 is reduced by taking a logical product, this is satisfied when there is a request to handle the validity / invalidity of a plurality of optical signals independently. I can't. Therefore, it has been conventionally performed to remove the determination circuit 109 from the reception unit 108 by using a squelch circuit in the optical / electrical conversion unit 104.

  FIG. 7 shows the main part of this optical communication system using a squelch circuit. In FIG. 7, the same parts as those in FIG. 6 are denoted by the same reference numerals, and description thereof will be omitted as appropriate. In this optical communication system 120, a squelch circuit 121 is disposed on the output side of the optical signal detection circuit 106 in the optical / electrical converter 104A. A selector 122 is arranged on the output side of the optical / electrical conversion circuit 105, and one of the data 111 as the output of the optical / electrical conversion circuit 105 and the “0” signal 124 output from the “0” fixed output circuit 123. Is selected and output as selection data 125. The output of the squelch circuit 121 is supplied to the selector 122 as the selection signal 126. The selection data 125 is input to the receiving unit 108A as data 127 via the AC coupling capacitor 112.

  That is, in the optical communication system 120 shown in FIG. 7, when the optical signal 102 is not input to the optical / electrical conversion circuit 105, the squelch circuit 121 on the output side of the optical signal detection circuit 106 detects this, and as a result The selector 122 selects the “0” fixed output circuit 123 side by the selection signal 126. In this case, the optical / electrical conversion unit 104A outputs the continuous signal “0” as the selection data 125.

  As described above, when the transmission-side electrical / optical conversion unit 101 fails and invalid data is sent to the reception side, the signal “0” is continuously output as the selection data 125 to the reception unit 108A. As a premise, there is a technique for determining the validity of data.

  This technique uses a data transmission coding rule that a signal “0” does not occur for a predetermined length or longer unlike a non-return-to-zero (NRZ) signal. That is, when it is detected on the receiving unit 108A side in FIG. 7 that “0” continues for a predetermined length or more, it is determined that the optical signal 102 is not input to the input side of the optical / electrical conversion circuit 105. In this case, it is determined that the selection data 125 sent is invalid.

  In this technique, in order to recognize the optical signal 102 sent from the electrical / optical conversion unit 101 as valid again, when the receiving unit 108A can receive a specific data string, it performs handshaking between transmission and reception. I have to. As a result of this handshake, when it is confirmed that normal data communication is possible, the data 111 sent from the electrical / optical converter 101 is validated thereafter.

  However, this technique has an advantage that it is possible to avoid an increase in the number of signal pins of the receiving unit because the optical detection signal in the optical communication system 120 shown in FIG. 7 is omitted. However, there is a problem that the receiving unit 108A may malfunction due to the presence of the AC coupling capacitor 112.

FIG. 8 is a diagram for explaining how this malfunction occurs. This will be described with reference to FIG. FIG. 8A shows the state of the optical signal 102 output from the electrical / optical conversion unit 101 on the transmission side. A valid optical signal 102 is transmitted from time t _1, but the optical signal 102 is disconnected at time t ₂ .

FIG. 8B shows the state of the selection data 125 output from the optical / electrical converter 104A. When the optical signal 102 is cut off at time t ₂ , the squelch circuit 121 operates, and the selector 122 selects the “0” fixed output circuit 123 side by the selection signal 126. Until this time t ₂ , the same data 127 ((c) in the figure) as the selection data 125 as the data 111 is input to the receiving unit 108A. When the squelch operation is performed at time t ₂ and the selector 122 selects the “0” fixed output circuit 123 side, the signal “0” is continuously output thereafter, as shown in FIG.

However, when constant by "0" warranty period T _G when defined by the terminating resistor (not shown) in the receiving unit 108A has passed, from the time t _3, the potential of the output side of the data 127 of the AC coupling capacitor 112 is unstable become. That is, the data 127 is kept at the signal “0” from the time t ₂ to the time t ₃ , but thereafter, the signal “0” or the signal “1” becomes the indefinite value data 128 where the signal is undefined. As a result, after time t ₃ , the indefinite value data 128 may be converted into valid data, which may cause the reception unit 108A to malfunction.
JP2003-188828 (paragraph 0010, FIG. 2)

SUMMARY OF THE INVENTION An object of the present invention is to provide an optical communication system capable of reflecting a failure in the case where an optical signal has not been received in a subsequent circuit without increasing the number of transmission lines. It is in.

In the present invention, the optical communication system includes (a) a transmission unit that transmits an optical signal encoded by a predetermined specific coding rule, and (b) an optical signal transmitted from the transmission unit as a signal “0”. An optical / electrical conversion means for converting into an electrical signal containing ", a fault detection means for detecting a fault, a pulse output circuit for repeatedly generating a pulse signal in a cycle shorter than a predetermined time constant corresponding to the fault, When the failure detection means does not detect the failure, the electrical signal after the conversion by the optical / electrical conversion means is selected, and when the failure is detected, the pulse signal generated by the pulse output circuit is selected. Selection means, and selection signal sending means for sending to a signal line connected via an AC coupling capacitor to a subsequent circuit portion where decoding means for decoding the output of the selection means in accordance with the specific coding rule described above exists And (c) the pulse output circuit described above repeatedly generates a pulse signal in a cycle shorter than the predetermined time constant determined by the AC coupling capacitor and the termination circuit. Abnormality information indicating the above-mentioned failure detected by the receiving means is transmitted to the receiving means using a signal line connected via the AC coupling capacitor.

In the optical communication system of the present invention, a plurality of pulse signals other than the optical signal encoded with a specific coding rule can generally be created, so that it is possible to cope with the occurrence of a plurality of failures. In addition, even in a system that is limited by the continuous time of “0” in the transmission of the pulse signal, it is possible to perform highly reliable communication by preparing the pulse signal pattern within the limit corresponding to the failure. be able to.

  Hereinafter, the present invention will be described in detail with reference to examples.

  FIG. 1 shows an outline of an optical communication system in an embodiment of the present invention. The optical communication system 200 according to this embodiment includes a transmission-side electrical / optical conversion unit 201 and a reception-side optical / optical conversion unit 201 that receives an optical signal 202 output from the electrical / optical conversion unit 201 via an optical transmission path 203. An electrical conversion unit 204 is provided. Data 205 output from the optical / electrical converter 204 is input to the receiver 208 as data 207 after passing through the AC coupling capacitor 206.

  Here, the optical / electrical conversion unit 204 includes an optical / electrical conversion circuit 211 and an optical signal detection circuit 212 for branching and inputting the optical signal 202 transmitted from the transmission side. The optical / electrical conversion circuit 211 is a circuit that converts the optical signal 202 into an electric signal, and the data 213 as an electric signal output from the optical signal 202 becomes one input of the selector 214. The selector 214 receives, as the other input, a pulse signal 216 output from the pulse output circuit 215 and periodically changing “0” and “1”. The selector 214 selects one of these two inputs and outputs it as data 205.

  The optical signal detection circuit 212 outputs a light detection signal 217 indicating whether or not the optical signal 202 is detected. The light detection signal 217 is input to the squelch circuit 218. The output of the squelch circuit 218 is supplied to the selector 214 as the selection signal 219. That is, when the squelch circuit 218 does not detect the optical signal 202, the pulse signal 216 output from the pulse output circuit 215 is selected by the selection signal 219 to that effect, and in other cases, the data 213 is selected. Is done. The input on the selected side is output as data 205 from the selector 214.

  On the other hand, the reception unit 208 includes a termination circuit 221 and a serial / parallel conversion circuit 222 that inputs the data 207 sent from the optical / electrical conversion unit 204 and performs serial / parallel conversion. The converted parallel data 223 output from the serial / parallel conversion circuit 222 is branched and input to both the decoding circuit 224 and the pulse detection circuit 225. Among these, the decoding circuit 224 decodes the encoded parallel data 223 and supplies the obtained data 226 to a circuit (not shown) in the subsequent stage. The pulse detection circuit 225 outputs a data enable signal 227 on the assumption that the data 207 that is the basis of the parallel data 223 is valid when no pulse is detected. When the pulse detection circuit 225 detects a pulse, the received data 207 is determined to be invalid. In this case, the output of the data enable signal 227 is suppressed.

  In such an optical communication system 200, when the optical signal 202 is no longer input from the electrical / optical conversion unit 201 to the optical / electrical conversion unit 204, the pulse signal 216 is output as data 205 from the selector 214. The pulse signal 216 is distinguished from the data 213 in the case where the optical signal 202 is valid data and is distinguished from the reception unit 208 side. As a result, it is not necessary to output the data 111 as the light detection signal from the optical / electrical conversion circuit 105 in the prior art shown in FIG.

  In addition, even when the optical / electrical conversion unit 104 of FIG. 6 includes a plurality of optical / electrical conversion circuits 105, by changing the type of the pulse signal 216, an optical signal can be input for each of these circuits. It is possible to detect individually whether or not there has been. Further, when there is no optical signal input, a pulse signal 216 that can be identified on the receiving unit 208 side is output as data 205, so that invalid data can be prevented from being erroneously recognized as valid data. .

  In the optical communication system 200 of this embodiment, when the optical signal 202 is not input from the transmission-side electrical / optical conversion unit 201, the data 205 output from the reception-side optical / electrical conversion unit 204 is a pulse signal 216. is there. Therefore, the data 207 input to the receiving unit 208 does not become an indefinite value. Therefore, the receiving unit 208 does not cause a malfunction that erroneously recognizes invalid data as valid data.

FIG. 2 shows the signal state of each part in this optical communication system. A description will be given with FIG. FIG. 2A shows the state of the optical signal 202 output from the electrical / optical converter 201. The electrical / optical converter 201 converts data consisting of electrical signals to be transmitted into optical signals 202 and transmits them to the optical transmission path 203. In this embodiment, encoding by 8B10B code is performed, and an optical signal 202 is transmitted. This is a system in which 8-bit parallel data is converted into 10 bits and serially transmitted. In FIG. 2 (a), the effective data from the time t ₁₁ to time t ₁₂ is transmitted, the optical signal 202 at time t ₁₂ is a cross-sectional. Then, the input optical signal 202 is resumed at time t _13.

FIG. 4B shows the state of a signal transmitted from the receiving-side optical / electrical conversion unit 204 to the receiving unit 208. Valid data from the time t ₁₁ to time t ₁₂ is transmitted. A squelch circuit 218 that operates in the absence of the optical signal 202 selects a data 213 for the selector 214 based on the result of detection of the optical signal 202 by the optical signal detection circuit 212. Is output. As a result, valid data is output as data 205 from time t ₁₁ to time t ₁₂ .

At time t ₁₂ , the optical signal 202 is disconnected, so that the squelch circuit 218 operates. As a result, during the period from time t ₁₂ to time t ₁₃ , the selector 214 selects the pulse signal 216 output from the pulse output circuit 215 by the selection signal 219. As a result, the pulse signal 216 is output from the optical / electrical converter 204 as data 205 as shown in FIG.

Becomes the subsequent time t _13, the input optical signal 202 is resumed, the operation of the squelch circuit 218 is turned off. As a result of the selector 214 selecting the data 213 output from the optical / electrical conversion circuit 211 again from this point in time, valid data is output from the optical / electrical conversion unit 204 as data 205.

FIG. 8C shows the state of the data 226 output from the decoding circuit 224 in the receiving unit 208, and FIG. 9D shows the state of the data enable signal 227. Between the time t ₁₁ to time t _12, the data 207 is sent to the receiving unit 208. The base data 205 is obtained by converting the optical signal 202 encoded by the 8B10B code as described above into an electrical signal. In this algorithm, “0” is not continued more than a predetermined number shorter than the time constant determined by the AC coupling capacitor 206 and the termination circuit 221. Specifically, the continuation of “0” and “1” is limited to 5 bits or less, and a situation in which only one of them continues for 6 bits or more does not occur.

  Therefore, the data 205 is input to the serial / parallel conversion circuit 222 as data 207 without being influenced by the AC coupling capacitor 206. Although not shown, the pulse detection circuit 225 preselects a signal pattern that does not exist in the 8B10B code rule. This signal pattern is associated with the pulse signal 216 output from the pulse output circuit 215 in advance. For example, a pulse signal 216 can be a repetition of a signal in which “0” continues for 10 bits and “1” continues for 10 bits thereafter. With such a signal, the transmission rate can be regarded as one-tenth of the normal rate. In general, if the signal is continuous for about 10 bits, the time constant condition is also satisfied.

Between the time t ₁₁ to time t _12, the pulse detection circuit 225 has not been detected pulse signal 216 output from the pulse output circuit 215, it is effective data, as shown in FIG. 2 (d) A data enable signal 227 indicating this is output. Therefore, as shown in FIG. 3C, the data 226 output from the decoding circuit 224 is valid data.

At time t _12, the squelch circuit 218 to operate. As a result, as shown in FIG. 2B, a pulse signal 216 is transmitted from the optical / electrical converter 204 as data 205. Similar to the optical signal 202 as effective data, the pulse signal 216 is determined to have a signal pattern in which “0” is not continued for a predetermined number shorter than the time constant determined by the AC coupling capacitor 206 and the termination circuit 221. . Therefore, the data 205 including the pulse signal 216 passes through the AC coupling capacitor 206 as it is and is input to the receiving unit 208 as data 207. The pulse detection circuit 225 of the reception unit 208 detects this as a pulse signal when data is invalid. Therefore, the data enable signal 227 is not output as shown in FIG. 6D, and the data 226 output from the decoding circuit 224 is invalidated as shown in FIG.

At time t ₁₃ , the pulse detection circuit 225 cannot detect the pulse signal 216. Therefore, the pulse detection circuit 225 thereafter outputs a data enable signal 227 indicating that the data 207 that is the basis of the parallel data 223 is valid ((d) in the figure). Therefore, the data 226 output from the decryption circuit 224 becomes valid data again after time t ₁₃ ((c) in the figure).

  As described above, according to this embodiment, when the optical / electrical conversion unit 204 on the receiving side receives the optical signal 202, the data 213 after the optical / electrical conversion circuit 211 converts the optical signal 202 into an electrical signal. Is output as data 205, and when the optical signal 202 is not received, the pulse signal 216 output from the pulse output circuit 215 is output as data 205. The receiving unit 208 determines whether the received data 207 is valid or invalid by detecting the pulse signal 216 generated by the pulse output circuit 215. As a result, there is an effect that the light detection signal that is an interface signal between the optical / electrical conversion unit 204 and the reception unit 208 that is conventionally required can be made unnecessary. Thereby, hardware for signal detection of the reception unit 208 can be reduced.

  When there is no input of the optical signal 202 from the electrical / optical conversion unit 201, the optical / electrical conversion unit 204 outputs a pulse signal 216 as the data 205. The pulse signal 216 has a cycle shorter than the time constant determined by the AC coupling capacitor 206 and the termination circuit 221. Therefore, the data 207 based on the pulse signal 216 can be correctly transmitted to the receiving unit 208, and when the optical signal 202 is not input, the state can be always transmitted to the receiving unit 208.

  <Deformability of invention>

  FIG. 3 shows an outline of an optical communication system in a modification of the present invention. In FIG. 3, the same parts as those in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted as appropriate. The optical communication system 200 </ b> A according to this modification includes a reception-side optical / electrical conversion unit 204 </ b> A that receives the optical signal 202 output from the transmission-side electric / optical conversion unit 201 via the optical transmission path 203. Data 205A output from the optical / electrical converter 204A is input to the receiver 208A as data 207A after passing through the AC coupling capacitor 206.

  The optical / electrical conversion unit 204A branches the optical signal 202 transmitted from the transmission side and inputs the optical signal 202 other than the failure that the optical signal is not received in addition to the optical / electrical conversion circuit 211 and the optical signal detection circuit 212. A first failure detection circuit 301 that detects one failure and a second failure detection circuit 302 that detects a second failure different from the first failure detection circuit 301 are provided. The optical communication system 200A may include a larger number of failure detection circuits or only the first failure detection circuit 301 and the optical signal detection circuit 212. The detection outputs 217, 311, and 312 of the optical signal detection circuit 212, the first failure detection circuit 301, and the second failure detection circuit 302 are all input to the squelch circuit 218, and are also input to the pulse output circuit 215A. It has become.

  FIG. 4 shows the configuration of the pulse output circuit of this modification. The pulse output circuit 215A receives three types of detection outputs 217, 311, and 312 and detects a type of failure detected. The pulse output circuit 215A inputs a pulse signal 216A by inputting this determination result and outputting a pulse signal 216A. A switching output circuit 322 is provided. The multiple pulse switching output circuit 322 outputs three types of pulse signals different from each other in a data configuration not defined by the 8B10B code rule, as a pulse signal 216A corresponding to the determination result.

  As in the pulse signal 216 of the previous embodiment, the pulse signal 216A is configured such that “0” does not continue for a predetermined number shorter than the time constant determined by the AC coupling capacitor 206 and the termination circuit 221. Specifically, the continuation of “0” and “1” is limited to 5 bits or less, and a situation in which only one of them continues for 6 bits or more does not occur.

  Returning to FIG. 3, the description will be continued. The pulse signal 216A output from the pulse output circuit 215A is input to one of the selectors 214, and the data 213 is input from the photoelectric conversion circuit 211 to the other. The squelch circuit 218 operates when any one of the detection outputs 217, 311 and 312 of the optical signal detection circuit 212, the first failure detection circuit 301, and the second failure detection circuit 302 is present, and the selector 214 is operated as a pulse signal 216A. A selection signal 219 for switching to the side is output. In other cases, that is, when none of the detection outputs 217, 311 and 312 is input to the squelch circuit 218, the selector 214 selects and outputs the data 213 from the photoelectric conversion circuit 211.

  The data 205A output from the optical / electrical conversion unit 204A in this way is input to the reception unit 208A as data 207A via the AC coupling capacitor 206. The reception unit 208A includes a pulse detection circuit 225A unique to this modification. The pulse detection circuit 225A determines the types of faults and their types by determining the type of the pulse signal 216A output from the pulse output circuit 215A in the optical / electrical converter 204A. If the data 226 may be valid, a data enable signal 227 indicating that the data is valid is output. In addition, a determination result signal 331 for determining the type of failure is output.

  FIG. 5 shows a processing state of a circuit portion that copes with the occurrence of a failure in the receiving unit. This processing is realized by a CPU (not shown) that controls the receiving unit 208A shown in FIG. 3 executing a control program stored in a storage medium such as a ROM (Read Only Memory) (not shown). This will be described with reference to FIG.

  The CPU monitors whether the pulse detection circuit 225A detects data corresponding to the pulse pattern corresponding to the failure. If this is detected (step S401: Y), which failure has occurred. Is determined (step S402). This is realized by the pulse detection circuit 225A preparing in advance a data pattern corresponding to the failure-specific pulse generated by the pulse output circuit 215A, and performing pattern matching therewith. When the type of failure is determined, a determination result signal 331 is output (step S403). Based on this, failure notification data corresponding to the failure is sent to a system administrator (not shown) (step S404). This sending may be sent to a mobile phone (not shown) of the system administrator in an e-mail format. Of course, the failure content may be displayed on a receiving unit 208A or a display (not shown) arranged in the vicinity thereof.

  If no data corresponding to the pulse pattern corresponding to the failure is detected in step S401 (N), the data enable signal 227 is output (step S405). In this case, the data 226 output from the decryption circuit 224 is valid.

  In this modification, the system administrator can determine the type of failure that has occurred. Further, since the contents of the failure can be grasped by a notification means such as a display or a telephone, it is possible to take measures for recovery promptly and appropriately. Of course, the output of the discrimination result signal 331 may be omitted depending on the optical communication system 200A.

  In the embodiment and the modification described above, the 8B10B code rule is used, but other codes may be used. For example, various methods such as 4B5B and 64B66B are also applicable. In such a case, the pulse output circuits 215 and 215A may output a pulse signal having a data structure not defined by the corresponding code rule.

  In the embodiment and the modification, the interface between the optical / electrical converters 204 and 204A and the receivers 208 and 208A is an AC coupling system using an AC coupling capacitor 206, but other interfaces may be used. Any signal format may be used as long as the data 205 and 205A including the pulse signals 216 and 216A generated by the pulse output circuits 215 and 215A can be correctly transmitted to the receiving units 208 and 208A.

  In the embodiment and the modification, the pulse signals 216 and 216A generated by the pulse output circuits 215 and 215A are transmitted when the optical signal 202 does not exist. However, the present invention is not limited to the pulse signals 216 and 216A. The data 205 and 205A output from the optical / electrical converters 204 and 204A when the optical signal 202 does not exist is a signal pattern of a data structure not defined in the coding rule of the data 205 and 205A when valid data exists. As long as the interface between the optical / electrical converters 204 and 204A and the receivers 208 and 208A can be correctly transmitted.

1 is a system configuration diagram showing an outline of an optical communication system in an embodiment of the present invention. It is signal state explanatory drawing showing the state of the signal of each part in the optical communication system of a present Example. It is a system block diagram showing the outline | summary of the optical communication system in the modification of this invention. It is a block diagram showing the structure of the pulse output circuit of this modification. It is a flowchart showing the process of the circuit part which copes with generation | occurrence | production of the failure in the receiver of a modification. It is a block diagram showing the circuit part which discriminate | determines the effectiveness of the transmission data in the conventional optical communication system. It is a system block diagram showing the principal part of the conventional optical communication system using a squelch circuit. It is signal state explanatory drawing for demonstrating a mode that malfunction occurs by the conventional 1st proposal.

Explanation of symbols

200, 200A Optical communication system 201 Electric / optical converter 202 Optical signal 204, 204A Optical / electric converter 205, 205A, 207, 207A, 213 Data 206 AC coupling capacitor 208, 208A Receiver 211 Optical / electric converter 212 Optical Signal detection circuit 214 selector 215, 215A pulse output circuit 216, 216A pulse signal 218 squelch circuit 219 selection signal 221 termination circuit 225, 225A pulse detection circuit 227 data enable signal 301 first failure detection circuit 302 second failure detection circuit 321 Detection type discrimination circuit 322 Pulse multiple switching output circuit 331 Discrimination result signal

Claims (6)

A transmission means for transmitting an optical signal encoded by a predetermined specific coding rule;
An optical / electrical conversion means for converting the optical signal sent from the transmission means into an electric signal including the signal “0”, a fault detection means for detecting a fault, and a predetermined time constant corresponding to the fault A pulse output circuit that generates a pulse signal in which “0” and “1” periodically change so that a predetermined number of “0” s do not continue in a short period, and when the failure detection means does not detect a failure, The electrical signal converted by the optical / electrical conversion means is selected, and when a failure is detected, the selection means for selecting the pulse signal generated by the pulse output circuit, and the output of the selection means is the specific coding rule. Receiving means comprising selection signal sending means for sending to a signal line connected via an AC coupling capacitor to a subsequent circuit portion where decoding means for decoding is present,
In the pulse output circuit, “0” and “1” periodically change so that a predetermined number of “0” s do not continue in a cycle shorter than the predetermined time constant determined by the AC coupling capacitor and the termination circuit. A pulse signal is generated, and abnormal information indicating the failure detected by the receiving means is transmitted to the receiving means by using the signal line connected via the AC coupling capacitor. Communications system. 2. The optical communication system according to claim 1, wherein the failure detection means includes an optical signal detection means for detecting that no optical signal is transmitted from the transmission means. 2. The optical communication system according to claim 1, wherein the failure detection means includes an internal failure detection means for detecting a failure in the reception means. 2. The optical communication system according to claim 1, wherein the failure detection means detects a plurality of failures, and the pulse output circuit generates a pulse signal of a type corresponding to each of the failures. The latter stage circuit portion includes pulse signal detection means for detecting the pulse signal, and data output prohibition means for prohibiting output of the decoded data of the decoding means when the pulse signal detection means detects the pulse signal. The optical communication system according to claim 1, further comprising: The post-stage circuit portion includes pulse signal detection means for detecting the pulse signal, and the pulse signal detection means is means for detecting a pulse signal of a type corresponding to each of the faults, and corresponds to the detected pulse signal. 5. The optical communication system according to claim 4, further comprising failure notifying means for notifying the details of the failure to be performed.

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