JP2007258813A - Optical transmission unit and optical cable inspection method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical transmission unit and an optical cable inspection method for securely carrying out optical transmission even on the occurrence of trouble such as breakage or the like of an optical signal cable. <P>SOLUTION: A power-saving microcomputer 14 produces a pulse signal S1 with a prescribed width PW and at a prescribed interval PI, a power-saving microcomputer 26 detects the width PW and the interval PI on the basis of the pulse signal S1 and produces a pulse signal S4 for an optical signal cable 2A, the power-saving microcomputer 14 detects a connection state of the optical signal cable 2A on the basis of the pulse signal S4, produces a pulse signal S7 on the basis of a result of the detection, and a power-saving microcomputer 26 recognizes the optical signal cable 2A in a normal operation (normally connected) on the basis of the pulse signal S7. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an optical transmission unit and an optical cable inspection method for transmitting a signal between a source device and a sink device.

  As a standard for transmitting a digital video signal by an electric signal between a source device that outputs a video signal such as a TV tuner or an HDD recorder and a sink (monitor) device that displays an image such as a display, DVI (Digital Visual Interface) ) And HDMI (High Definition Multimedia Interface).

  In these standards, a video signal is transmitted by a differential electrical signal called TMDS (Transition Minimized Differential Signaling), and a configuration of RGB (or YUV) video signal 3ch + clock signal 1ch is possible.

  In addition, when a format called Full HD is transmitted using an electric cable compliant with DVI or HDMI standard, the pixel rate is 148.5 Mbps (@ 60 Hz), and the transmission band per TMDS channel is 1.485 Gbps. . In transmission at such a high bit rate, the transmission distance is limited to several meters.

  Therefore, in order to overcome the limitation of the transmission distance, a technique of converting each of the RGB (or YUV) video signal and the clock signal into an optical signal and transmitting the signal over a long distance (see Patent Document 1), WDM (Wavelength Division) A technique (see Patent Document 2) realized by multiplexing transmission has been proposed.

  According to these proposed technologies, an RGB (or YUV) video signal or a clock signal is temporarily converted into an optical signal by an E / O converter (Electrical / Optical Converter) on the transmitter side. Signal transmission is performed by converting the optical signal again into an electrical signal by an / E converter (Optical / Electrical Converter).

JP 2002-366340 A JP 2003-273434 A

  However, according to such a method, long-distance communication by optical transmission becomes possible, but a problem that has not occurred in signal transmission by conventional electric signals occurs. For example, for some reason, the optical signal cable is cut halfway, or the connector of the optical signal cable is disconnected, and the optical transmission signal (strong laser beam) leaks out of the optical signal cable. There is a case.

  Therefore, the present invention has been proposed in view of such circumstances, and enables long-distance communication by optical transmission, and enables safe optical transmission even when trouble such as disconnection of an optical signal cable occurs. An object is to provide an optical transmission unit and an optical cable inspection method.

  In order to solve the above-described problems, an optical transmission unit according to the present invention includes a plurality of actual data transmission optical cables whose one end is used for transmitting actual data and an optical cable for control data transmission used for transmitting control data. The other end side is connected to the sink device side, the optical signal supplied via the actual data transmission optical cable is converted into an electrical signal, the converted signal is subjected to predetermined processing, and the processing is performed. A first module that supplies a later signal to the sink device, converts the signal supplied from the sink device into an optical signal, and outputs the converted optical signal to the control data transmission optical cable; Connected to the other end of the plurality of optical cables for actual data transmission and the optical cable for control data transmission, and the other end side is connected to the source device side and supplied from the source device The signal is converted into an optical signal, the converted optical signal is output to the actual data transmission optical cable, and the optical signal supplied via the control data transmission optical cable is converted into an optical signal. In the optical transmission unit including the second module that converts the electric signal into the electric signal and outputs the converted electric signal to the source device, the first module includes a first pulse having an arbitrary pulse width. First signal generating means for generating a pulse signal at an arbitrary pulse interval; and the first pulse signal generated by the first signal generating means is converted into a first optical signal, and the first light A first electro-optical converting means for supplying a signal to the second module via the control data transmission optical cable; and a second optical signal supplied from the source device via the actual data transmission optical cable. First photoelectric conversion means for converting into a first signal, first signal detection means for detecting a pulse width and a pulse interval of the electric signal converted by the first photoelectric conversion means, and the first Based on the pulse interval detected by the signal detection means, a connection state of the optical cable for actual data transmission is determined, and a third pulse signal having a pulse width indicating the connection state is generated. Control means for controlling the first signal generation means, wherein the first signal generation means generates a third optical signal from the third pulse signal according to the control of the control means, and the second signal generation means. The module converts the first optical signal supplied by the first electro-optical conversion means via the control data transmission optical cable into a first electric signal, and converts the third optical signal into a first electric signal. Convert to electrical signal 3 Second photoelectric detection means, and second signal detection means for detecting the pulse width and pulse interval of the first electric signal and the third electric signal converted by the second photoelectric conversion means. And a pulse width that is the same as the pulse width of the first electric signal detected by the second signal detection means, and is determined by a pulse interval determined based on the number of optical cables for actual data transmission. Second signal generating means for generating a second pulse signal, and converting the second pulse signal generated by the second signal generating means into the second optical signal, A second electro-optical converting means for supplying a signal to the first module via the optical cable for actual data transmission; and a pulse width and a pulse of the third electric signal detected by the second signal converting means. From the interval, the actual data And a determination means for connection state of data transmission for optical cables to determine if normal.

  The optical cable inspection method according to the present invention includes a plurality of actual data transmission optical cables whose one end is used for transmitting actual data and control data transmission used for transmitting control data in order to solve the above-described problems. Connected to one end of the optical cable, the other end is connected to the sink device side, converts the optical signal supplied via the actual data transmission optical cable into an electrical signal, and performs predetermined processing on the converted signal A first module that supplies the processed signal to the sink device, converts the signal supplied from the sink device into an optical signal, and outputs the converted optical signal to the control data transmission optical cable; The end side is connected to the other end of the plurality of optical cables for actual data transmission and the control data transmission optical cable, and the other end side is connected to the source device side. The received signal is subjected to predetermined processing, the processed signal is converted into an optical signal, the converted optical signal is output to the actual data transmission optical cable, and supplied via the control data transmission optical cable. In the optical cable inspection method in an optical transmission unit configured to convert an optical signal into an electrical signal and output the converted electrical signal to the source device, the first module has an arbitrary pulse width. A first pulse signal composed of: is generated at an arbitrary pulse interval, the first pulse signal is converted into a first optical signal, and the first optical signal is transmitted via the control data transmission optical cable. The second module supplies the second optical module, the second module converts the first optical signal supplied via the control data transmission optical cable into a first electric signal, and converts the first electric signal into the first electric signal. A pulse width and a pulse interval of the signal are detected, and the pulse width is the same as the pulse width of the first electric signal, and the pulse interval is determined based on the number of the actual data transmission optical cables. A second pulse signal is generated, the second pulse signal is converted into the second optical signal, and the second optical signal is supplied to the first module via the actual data transmission optical cable. The first module converts the second optical signal supplied via the actual data transmission optical cable into an electrical signal, detects a pulse width and a pulse interval of the electrical signal, and detects the detected signal. Based on the pulse interval, the connection state of the optical cable for actual data transmission is determined, a third pulse signal having a pulse width indicating the connection state is generated, and the third pulse signal is converted into a third pulse signal. Optical signal And the third optical signal is supplied to the second module via the control data transmission optical cable, and the second module is supplied to the second module via the control data transmission optical cable. 3 is converted into an electrical signal, and it is determined from the pulse width and pulse interval of the electrical signal whether or not the connection state of the actual data transmission optical cable is normal.

  In the present invention, since the negotiation for checking the connection state of the optical signal cable is performed between the first module and the second module with light having low intensity, the optical signal cable is cut off halfway, or Even when the connection terminal is disconnected, safety can be ensured.

  Hereinafter, specific embodiments to which the present invention is applied will be described in detail with reference to the drawings. The present embodiment is applied to the optical transmission unit 1 responsible for transmission of video signals and control signals performed between the sink device and the source device.

  As shown in FIG. 1, the optical transmission unit 1 includes a first module 3 and a second module 4 that are responsible for transmission of video signals and control signals performed between a sink (monitor) device and a source device. Composed.

  The first module 3 includes an O / E conversion unit 10 that converts an optical signal supplied via the optical signal cable 2 into an electrical signal, and a SERDES unit 11 that converts the converted signal (serial signal) into a parallel signal. A logic unit 12 connected to the control signal I / F 101 of the monitor device 100 and performing predetermined signal processing, an RGB I / F device 13 connected to the RGB I / F 102 of the monitor device 100, and a first module 3 includes a power saving microcomputer 14 that saves power of the main body and an E / O conversion unit 15 that converts an electrical signal into an optical signal. In this embodiment, the O / E conversion unit 10 is composed of an O / E conversion unit 10A, an O / E conversion unit 10B, and an O / E conversion unit 10C. The SERDES unit 11 is a SERDES unit 11A. , SERDES unit 11B and SERDES unit 11C.

  The second module 4 is connected to the RGB I / F device 21 connected to the RGB I / F 202 of the source device 200 and the control signal I / F 201 of the source device 200, and is supplied from the RGB I / F device 21. A logic unit 22 that performs predetermined signal processing on the signal, a SERDES unit 23 that converts a signal (parallel signal) supplied from the logic unit 22 into a serial signal, and an E / O conversion unit 24 that converts an electrical signal into an optical signal. And an O / E conversion unit 25 that converts an optical signal into an electric signal, and a power saving microcomputer 26 that saves power of the second module 4 main body. In the present embodiment, the E / O conversion unit 24 includes three parts: an E / O conversion unit 24A, an E / O conversion unit 24B, and an E / O conversion unit 24C. The SERDES unit 23 is a SERDES unit 23A. , SERDES unit 23B and SERDES unit 23C.

  The optical signal cable 2 includes a plurality of actual data transmission optical signal cables 2A used for transmission of actual data such as video data and a control data transmission optical signal cable 2B used for transmission / reception of control data. Composed. In this embodiment, the actual data transmission optical signal cable 2A is described as being composed of three, but the number is not limited to this.

  Signals transmitted and received by the RGB I / F units 102 and 202 mounted on the source device 200 and the monitor device 100 are interfaced by an RGB I / F device.

  The RGB I / F devices 13 and 21 are devices compliant with DVI (Digital Visual Interface) or HDMI (High Definition Multimedia Interface) standards.

  The logic units 12 and 22 have a function of time division multiplexing / separating signals transmitted and received by the RGB I / Fs 102 and 202 and the control signals I / Fs 101 and 201 into one stream in each direction. The logic units 12 and 22 are realized by an FPGA (Field Programmable Gate Array) or the like.

  The SERDES units 11 and 23 serialize or deserialize the video signal and control signal multiplexed in the stream, and perform code conversion (encoding) or reverse code (decoding) conversion (decoding) suitable for optical transmission. The SERDES units 11 and 23 have functions such as serialization + 8B10B encoding / deserialization + 8B10B decoding.

  The E / O converters 15 and 24 are converters that convert electrical signals into optical signals, and the O / E converters 10 and 25 are converters that convert optical signals into electrical signals. The optical signals converted by the E / O converters 15 and 24 are optically transmitted to the O / E converters 25 and 10 via the optical signal cable 2.

  The power saving microcomputers 14 and 26 check the connection state of the optical signal cable 2 when the source device 200 and the monitor device 100 are powered on.

  Here, the checking operation of the optical signal cable 2 by the optical transmission unit 1 will be described with reference to the flowchart shown in FIG. In the following description, the O / E conversion unit 10, the power saving microcomputer 14, and the E / O conversion unit 15 of the first module 3 are in the power saving mode (standby power mode), and SERDES. No power is supplied to the unit 11 and other components. Further, the E / O conversion unit 24, the O / E conversion unit 25, and the power saving microcomputer 26 of the second module 4 are in the power saving mode, and the SERDES unit 23 and other components include a power source. Is not supplied.

  In step ST1, the power saving microcomputer 14 generates a first pulse signal S1 having an arbitrary pulse width PW at an arbitrary pulse interval PI. The power saving microcomputer 14 is a pulse configured with, for example, a pulse width PW of 10 ms and a pulse interval PI of 110 ms in accordance with a signal (for example, an activation signal) supplied from the monitor device 100 via the control signal I / F 101. A signal S1 is generated. Further, the power saving microcomputer 14 supplies the generated pulse signal S <b> 1 to the E / O conversion unit 15.

  By doing so, the optical power of the pulse signal S1 can be reduced to 1/11. Therefore, even when the optical signal cable 2 is cut, the power of light emitted from the cut surface is weak, and thus safety can be ensured.

  In step ST2, the E / O conversion unit 15 converts the supplied pulse signal S1 into an optical signal S2, and outputs the optical signal S2 to the control signal transmission / reception optical signal cable 2B.

  In step ST3, the O / E converter 25 of the second module 4 receives the optical signal S2 supplied via the control data transmission / reception optical signal cable 2B and converts it into an electrical signal S3. The O / E converter 25 supplies the converted electric signal S3 to the power saving microcomputer 26.

  In step ST4, the power saving microcomputer 26 detects the pulse width PW and the pulse interval PI from the supplied electric signal S3. When the electric signal S3 is not supplied from the O / E converter 25, the power saving microcomputer 26 is not supplied with an optical signal from the monitor device 100 side, or the optical signal cable 2 is not connected. The power saving mode is maintained.

  In step ST5, the power saving microcomputer 26 recognizes that the optical signal cable 2 is currently being checked from the pulse width PW and the pulse interval PI detected in the process of step ST4, and is the same as the pulse width PW. A pulse signal P4 having a pulse width PW and a predetermined interval PI (for example, PI = PW × N, where N is the number of optical signal cables 2A for actual data transmission) is equal to the pulse width PW. The phase is delayed by an amount corresponding to the number of optical signal cables 2A for actual data transmission (for example, three waves). The power saving microcomputer 26 supplies the generated three pulse signals S4 to the E / O converter 15.

  In step ST6, the E / O conversion unit 24 converts the supplied pulse signal S4 into an optical signal S5, and outputs the optical signal S5 to the optical signal cable 2A for actual data transmission.

  In step ST <b> 7, the O / E converter 10 converts the supplied three-wave optical signal S <b> 5 into an electric signal S <b> 6 and supplies the electric signal S <b> 6 to the power saving microcomputer 14. Hereinafter, a signal having no phase delay is referred to as an electric signal S6A, a signal having a phase delayed by 1PW is referred to as an electric signal S6B, and a signal having a phase delayed by 2PW is referred to as an electric signal S6C.

  In step ST8, the power saving microcomputer 14 detects the pulse width PW and the pulse interval PI based on the electric signal S6A supplied first, confirms that the pulse width PW is a predetermined width, The number N (N = PI / PW) of the optical signal cable 2A for actual data transmission is obtained from the pulse interval PI. When the number of electrical signals S6 supplied from the O / E conversion unit 10 matches the obtained number N of optical signal cables 2A for actual data transmission, the power saving microcomputer 14 determines all the O / Es. It is determined that the actual data transmission optical signal cable 2A is correctly connected to the conversion unit 10. Further, the power saving microcomputer 14 determines that the O / E conversion unit is in a case where the number of the electrical signals S6 supplied from the O / E conversion unit 10 does not match the determined number N of the actual data transmission optical signal cables 2A. 10, it is determined that the optical signal cable 2 </ b> A for actual data transmission is not correctly connected.

  In step ST9, the power saving microcomputer 14 notifies the power saving microcomputer 26 of the second module 4 of a status report of the actual data transmission optical signal cable 2A. The power saving microcomputer 14 has a predetermined pulse width PW and a predetermined pulse interval PI (for example, PI = PW × (M + 1). M is an actual data transmission determined to be operating normally. Is the number of optical signal cables 2A for use). Further, the power saving microcomputer 14 is a pulse signal S8 (for example, PI = PW × (Nmax + 2)) when there is no actual data transmission optical signal cable 2A operating normally. Is the maximum value of the number N of optical signal cables 2A for actual data transmission.

  In step ST10, the E / O converter 15 converts the pulse signal S7 or the pulse signal S8 into an optical signal S9, and outputs the optical signal S9 to the control signal transmission / reception optical signal cable 2B.

  In step ST11, the O / E converter 25 of the second module 4 receives the optical signal S9 supplied via the control data transmission / reception optical signal cable 2B and converts it into an electrical signal S10. The O / E converter 25 supplies the converted electric signal S10 to the power saving microcomputer 26.

  In step ST12, the power saving microcomputer 26 detects the pulse width PW and the pulse interval PI from the supplied electric signal S10. The power saving microcomputer 26 confirms that the pulse width PW is a predetermined width, and from the pulse width PW and the pulse interval PI, the number M of actual data transmission optical signal cables 2A operating normally (M = PI / PW). The power saving microcomputer 26 operates normally when M is “Nmax + 2”, and when the actual data transmission optical signal cable 2A is “0”. It is recognized that the number of optical signal cables 2A for actual data transmission is “0”.

  The power saving microcomputer 26 can grasp the connection status of the optical signal cable 2 from the steps ST4 to ST12, and notifies the source device 200 of the connection status. The source device 200 operates so as to supply a signal only to the optical signal cable 2 that is correctly connected.

  Here, the check operation by the power saving microcomputer 14 of the first module 3 will be described in more detail with reference to the flowcharts shown in FIGS. Hereinafter, the output terminal of the power saving microcomputer 14 is referred to as “Serial Out”, the input terminal of the power saving microcomputer 26 is referred to as “Serial In”, and each output terminal of the E / O conversion unit 24 is referred to as “I / O”. Called “O1 Out”, “I / O2 Out” and “I / O3 Out”, the respective input terminals of the O / E converter 10 are “I / O1 In”, “I / O2 In” and “I / O3”. Call it “In”.

  As an initial setting, the power saving microcomputer 14 sets the number “M” of the optical signal cable 2A for actual data transmission that is determined to be operating normally to “0” (step ST21), and “I / O In” Is set (step ST22), the interrupt timer is set to an arbitrary pulse width “PW” (step ST23), and “Serial Out” is set to “High” (step ST24).

  Next, the power saving microcomputer 14 determines whether or not a timer interrupt has occurred (step ST25). If it is determined that a timer interrupt has occurred, the interrupt timer is set to an arbitrary pulse interval “PI” (in this embodiment, for convenience). PI is set to 110 ms) (step ST26), "Serial Out" is set to "Low" (step ST27), and it is determined whether or not a timer interrupt has occurred (step ST28).

  Next, the power saving microcomputer 14 determines whether or not there is an interrupt in “I / O1 In” when it is determined in step ST28 that there is a timer interrupt (step ST29). Returns to step ST23.

  Next, when it is determined in step ST29 that an interrupt has occurred, the power saving microcomputer 14 determines whether or not “I / O2 In” has been interrupted (step ST30). Proceed to step ST31. Further, the power saving microcomputer 14 sets “M” to “1” in the process of step ST31, and proceeds to the process of step ST35.

  If it is determined in step ST30 that “I / O2 In” has been interrupted, the power saving microcomputer 14 determines whether “I / O3 In” has been interrupted (step ST32), and there is no interrupt. If it is determined that there is an interrupt, the process proceeds to step ST33, and if it is determined that there is an interrupt, the process proceeds to step ST34. Further, the power saving microcomputer 14 sets “M” to “2” in the process of step ST33 and proceeds to the process of step ST35, and sets “M” to “3” in the process of step ST34. The process proceeds to step ST35.

  Next, the power saving microcomputer 14 sets an interrupt timer to a predetermined pulse width “PW” (step ST35), sets “Serial Out” to “High” (step ST36), and determines whether there is a timer interrupt. Is determined (step ST37). When there is a timer interruption, the power saving microcomputer 14 sets the interruption timer to a predetermined pulse width “PW × (M + 1)” based on “M” set by the process of step ST31, step ST33 or step ST34. (Step ST38) and "Serial Out" is set to "Low" (step ST39).

  Next, the power saving microcomputer 14 determines whether or not a timer interrupt has occurred (step ST40). If it is determined that a timer interrupt has occurred, whether or not a video (RGB) signal is supplied from the second module 4 is determined. If it is determined (step ST41) and it is determined that the video signal is not supplied, the process returns to step ST35, and if it is determined that the video signal is supplied, the operation right is transferred to the monitor device 100. (Step ST42).

  Further, the check operation by the power saving microcomputer 26 of the second module 4 will be further described in detail with reference to the flowchart shown in FIG.

  As an initial setting, the power saving microcomputer 26 sets the number “N” of the optical signal cables 2A for actual data transmission to “3” (step ST51), sets an interrupt of “Serial In” (step ST52), It is determined whether or not there is an interrupt in “Serial In” (step ST53).

  Next, when the power saving microcomputer 26 determines that there is an interrupt in “Serial In”, the count value of the up counter is set to “0” (step ST54), and whether or not there is a “Serial In” interrupt. Is determined (step ST55).

  If the power saving microcomputer 26 determines in step ST55 that an interrupt has occurred, the power saving microcomputer 26 determines whether the count value of the up-counter has a predetermined pulse width “PI” (step ST56). If not, the process returns to step ST53. If it is “PI”, the process proceeds to step ST57.

  Next, the power saving microcomputer 26 sets “N” to “3” (step ST57), sets an arbitrary pulse width “PW” in the interrupt timer (step ST58), and sets “Serial (N) Out”. It is set to “High” (step ST59), and it is determined whether or not a timer interruption has occurred (step ST60).

  If the power saving microcomputer 26 determines in step ST60 that the timer has been interrupted, it sets the interrupt timer to an arbitrary pulse width “PW” (step ST61) and sets “Serial (N) Out”. It is set to “Low” (step ST62), and it is determined whether or not a timer interruption has occurred (step ST63).

  If the power saving microcomputer 26 determines in step ST63 that the timer has been interrupted, it subtracts 1 from the set “N” (step ST64). The power saving microcomputer 26 determines whether or not “N” obtained in step ST64 is “0” (step ST65). If it is not “0”, the process returns to step ST58. If there is, the process proceeds to step ST66.

  Next, the power saving microcomputer 26 determines whether or not there has been a “Serial In” interrupt (step ST66). If it is determined that there is no interrupt, the process returns to step ST57, and if it is determined that an interrupt has occurred. Advances to step ST67.

  Next, the power saving microcomputer 26 sets the count value of the up counter to “0” (step ST67), and determines whether or not there is a “Serial In” interrupt (step ST68).

  Next, when the power saving microcomputer 26 determines that the “Serial In” interrupt has occurred, the power saving microcomputer 26 determines whether the count value of the up counter is a pulse interval “PI” of NG = PW × (Nmax + 2) ms. If the count value is “PI” (for example, the pulse interval PI is 110 ms), the process returns to step ST57. If the count value is not “PI”, the process proceeds to step ST70. .

  Then, when the count value is not “PI” in step ST69, the power saving microcomputer 26 obtains “M” by a predetermined calculation (for example, M = (PI / PW) −1) (step ST70). Then, the obtained “M” is notified to the source device 200 (step ST71).

  In this way, the optical transmission unit 1 executes the negotiation for checking the connection state of the optical signal cable 2 as shown in FIG. 2 between the first module 3 and the second module 4. Even when the signal cable 2 is cut off in the middle or the connection terminal is disconnected, the power of light emitted from the cut surface or the terminal surface is weak, so that safety can be ensured.

  Further, since the optical transmission unit 1 executes a negotiation for checking the connection state of the optical signal cable 2 as shown in FIG. 2 between the first module 3 and the second module 4, the optical signal cable 2 Therefore, the reliability of the total system can be improved.

  Further, since the optical transmission unit 1 executes a complicated negotiation for checking the connection state of the optical signal cable 2 using the power saving microcomputers 14 and 26, control by software can be easily realized. In addition, an increase in hardware can be avoided, costs can be reduced, and space can be saved.

  Furthermore, since the power saving microcomputers 14 and 26 of the optical transmission unit 1 are microcomputers for low power consumption specialized in low power consumption of mobile devices or the like, a sleep mode (standby power mode) function or a function activated by an interrupt Can be used properly and power saving can be achieved.

  Further, the power saving microcomputers 14 and 26 of the optical transmission unit 1 can be flexibly shared with other microcomputers for standby activation.

  In the above-described embodiment, the operation for checking the connection state of the optical signal cable 2 is performed immediately after power-on. However, the operation is not limited to this, and the check operation may be performed periodically after power-on.

  Furthermore, in the above-described embodiment, the operation for checking the connection state of the optical signal cable 2 is performed immediately after power-on. However, the operation is not limited to this, and the configuration is such that the check operation is performed when the system detects a video signal transmission abnormality. It may be.

  Further, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the present invention.

It is a block diagram which shows the structure of the optical transmission unit which concerns on this invention. It is a flowchart with which it uses for description about the negotiation which performs the check operation | movement of an optical signal cable. It is a 1st flowchart with which it uses for description about the check operation | movement by the power saving microcomputer of a 1st module. It is a 2nd flowchart with which it uses for description about the check operation | movement by the power saving microcomputer of a 1st module. It is a flowchart with which it uses for description about the check operation | movement by the power saving microcomputer of a 2nd module.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Optical transmission unit, 3 1st module, 4 2nd module, 10, 25 O / E conversion part, 11, 23 SERDES part, 12, 22 logic part, 13, 21 RGB I / F device, 14, 26 Power-saving microcomputer, 15, 24 E / O converter

Claims (2)

One end is connected to one end of a plurality of optical cables for actual data transmission used for transmission of actual data and an optical cable for control data transmission used for transmission of control data, and the other end is connected to the sink device side. The optical signal supplied via the optical cable for actual data transmission is converted into an electrical signal, the converted signal is subjected to predetermined processing, the processed signal is supplied to the sink device, and supplied from the sink device A first module for converting the signal into an optical signal and outputting the converted optical signal to the control data transmission optical cable; and one end side of the plurality of actual data transmission optical cables and the other end of the control data transmission optical cable. The other end is connected to the source device side, performs predetermined processing on the signal supplied from the source device, converts the processed signal into an optical signal, A second module that outputs an optical signal to the actual data transmission optical cable, converts the optical signal supplied via the control data transmission optical cable into an electrical signal, and outputs the converted electrical signal to the source device; In an optical transmission unit composed of
The first module is
First signal generating means for generating a first pulse signal having an arbitrary pulse width at an arbitrary pulse interval;
The first pulse signal generated by the first signal generation means is converted into a first optical signal, and the first optical signal is supplied to the second module via the control data transmission optical cable. First electro-optic conversion means
First photoelectric conversion means for converting a second optical signal supplied from the source device via the optical cable for actual data transmission into an electrical signal;
First signal detection means for detecting a pulse width and a pulse interval of the electrical signal converted by the first photoelectric conversion means;
Based on the pulse interval detected by the first signal detecting means, the connection state of the actual data transmission optical cable is determined, and a third pulse signal having a pulse width indicating the connection state is generated. Control means for controlling the first signal generating means as described above,
The first signal generation means generates a third optical signal from the third pulse signal according to the control of the control means,
The second module is
The first optical signal supplied from the first electrical / optical conversion means via the control data transmission optical cable is converted into a first electrical signal, and the third optical signal is converted into a third electrical signal. Second photoelectric conversion means for converting to
Second signal detection means for detecting a pulse width and a pulse interval of the first electric signal and the third electric signal converted by the second photoelectric conversion means;
A pulse width that is the same as the pulse width of the first electric signal detected by the second signal detecting means and is determined by a pulse interval determined based on the number of optical cables for actual data transmission. Second signal generating means for generating two pulse signals;
The second pulse signal generated by the second signal generation means is converted into the second optical signal, and the second optical signal is transmitted to the first module via the actual data transmission optical cable. Second electro-optical conversion means to be supplied;
And determining means for determining whether or not the connection state of the optical cable for actual data transmission is normal based on the pulse width and pulse interval of the third electric signal detected by the second signal converting means. An optical transmission unit. One end is connected to one end of a plurality of optical cables for actual data transmission used for transmission of actual data and an optical cable for control data transmission used for transmission of control data, and the other end is connected to the sink device side. The optical signal supplied via the optical cable for actual data transmission is converted into an electrical signal, the converted signal is subjected to predetermined processing, the processed signal is supplied to the sink device, and supplied from the sink device A first module for converting the signal into an optical signal and outputting the converted optical signal to the control data transmission optical cable; and one end side of the plurality of actual data transmission optical cables and the other end of the control data transmission optical cable. The other end is connected to the source device side, performs predetermined processing on the signal supplied from the source device, converts the processed signal into an optical signal, A second module that outputs an optical signal to the actual data transmission optical cable, converts the optical signal supplied via the control data transmission optical cable into an electrical signal, and outputs the converted electrical signal to the source device; In an optical cable inspection method in an optical transmission unit comprising:
The first module is
Generating a first pulse signal having an arbitrary pulse width at an arbitrary pulse interval;
Converting the first pulse signal into a first optical signal;
Supplying the first optical signal to the second module via the control data transmission optical cable;
The second module is
Converting the first optical signal supplied via the control data transmission optical cable into a first electrical signal;
Detecting the pulse width and pulse interval of the first electrical signal;
Generating a second pulse signal having the same pulse width as the pulse width of the first electric signal, and configured by a pulse interval determined based on the number of optical cables for actual data transmission;
Converting the second pulse signal into the second optical signal;
Supplying the second optical signal to the first module via the optical cable for actual data transmission;
The first module is
Converting the second optical signal supplied via the optical cable for actual data transmission into an electrical signal;
Detect the pulse width and pulse interval of the electrical signal,
Based on the detected pulse interval, the connection state of the optical cable for actual data transmission is determined, and a third pulse signal having a pulse width indicating the connection state is generated,
Converting the third pulse signal into a third optical signal;
Supplying the third optical signal to the second module via the control data transmission optical cable;
The second module is
Converting the third optical signal supplied via the control data transmission optical cable into an electrical signal;
A method for inspecting an optical cable, comprising determining whether or not a connection state of the optical cable for actual data transmission is normal from a pulse width and a pulse interval of the electric signal.

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