JP6065093B2 - Optical transmission / reception system and transmission / reception apparatus - Google Patents

Description

  The present invention relates to an optical transmission / reception system and a transmission / reception apparatus.

  When a video signal is played back by a playback device and transmitted to a remote video display device, the electrical signal from the wire has a large transmission loss and cannot display an accurate video. Therefore, the reproduced video signal is converted to an optical signal. There has been proposed a signal transmission device that transmits from a transmitter to a receiver via an optical fiber (see, for example, Patent Document 1).

  In addition, the laser of the light emitting section of the optical signal can generate a powerful output that is potentially harmful to the human body and the device, so if the link of the optical fiber is broken, it is inactive or pulsed laser Is output, and when the link recovers normally and the pulsed return light can be detected, a communication system that continuously outputs the activity, that is, the laser has been proposed (see, for example, Patent Document 2).

JP 2010-166546 A Japanese Patent Laid-Open No. 03-212266

  An object of the present invention is to compare a case in which a plurality of optical transmission units emit light regardless of whether or not transmission paths are connected in a configuration in which optical signals are transmitted from a plurality of optical transmission units to a partner apparatus via a plurality of transmission paths. Accordingly, an optical transmission / reception system and a transmission / reception apparatus with reduced power consumption are provided.

  The present invention provides the following optical transmission / reception system and transmission / reception apparatus.

[1] A plurality of first optical transmission units that transmit optical signals;
A first optical receiver for receiving an optical signal;
A first transmitting / receiving device comprising:
A plurality of second optical receivers for receiving optical signals from the plurality of first optical transmitters;
A second optical transmitter for transmitting an optical signal to the first optical receiver;
A second transmitting / receiving device comprising:
The first transmission / reception device transmits an optical signal from a part of the first optical transmission units of the plurality of first optical transmission units, and the first optical reception unit as a response to the optical signal When receiving an optical signal from the second optical transmission unit, the optical transmission / reception system transmits an optical signal from the remaining first optical transmission unit among the plurality of first optical transmission units.

[2] An optical signal transmitted from a part of the first optical transmission units among the plurality of first optical transmission units is control system data, and the remaining of the plurality of first optical transmission units. The optical transmission / reception system according to [1], wherein the optical signal transmitted from the first optical transmission unit is video data.
[3] The first transmission / reception device receives an optical signal from a part of the first optical transmission units among the plurality of first optical transmission units in synchronization with power-on of the first transmission / reception device. The optical transmission / reception system according to [1] or [2] for transmission.

[4] A plurality of optical transmitters that transmit optical signals;
An optical receiver for receiving an optical signal,
When the plurality of optical transmission units transmit optical signals from some of the optical transmission units to the counterpart transmission / reception device, and the optical reception unit receives an optical signal from the counterpart transmission / reception device as a response to the optical signal An optical transmitter / receiver that transmits an optical signal from the remaining optical transmitter to the counterpart transmitter / receiver.

  According to the first to fourth aspects of the present invention, in a configuration in which optical signals are transmitted from a plurality of optical transmission units to a partner apparatus via a plurality of transmission lines, the plurality of optical transmission units are irrespective of whether or not the transmission lines are connected. As compared with the case of emitting light, power consumption can be suppressed.

FIG. 1 is a block diagram showing a configuration of an optical transmission / reception system according to the first embodiment of the present invention. 2A is a diagram for explaining the function of the first control unit according to the first embodiment, and FIG. 2B is a laser drive signal and an optical signal according to the first embodiment. FIG. FIG. 3 is a block diagram showing a configuration of an optical transmission / reception system according to the second embodiment of the present invention. FIG. 4 is a block diagram showing the configuration of the first and second transmission / reception devices according to the second embodiment. FIG. 5 is a diagram illustrating an overall flow of link establishment between the first and second transmission / reception apparatuses according to the second embodiment. FIG. 6 is a diagram illustrating a flow relating to link establishment of control data between the first and second transmission / reception apparatuses according to the second embodiment. FIG. 7 is a diagram illustrating a flow relating to video data link establishment between the first and second transmission / reception apparatuses according to the second embodiment. FIG. 8 is a diagram showing a flow related to link establishment of control system data between the first and second transmission / reception apparatuses according to the third embodiment of the present invention. FIG. 9 is a diagram showing a flow relating to establishment of a link of video data between the first and second transmission / reception apparatuses according to the third embodiment of the present invention. FIG. 10 is a block diagram showing a configuration of an optical transmission / reception system according to the fourth embodiment of the present invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In addition, in each figure, about the component which has the substantially same function, the same code | symbol is attached | subjected and the duplicate description is abbreviate | omitted.

[First Embodiment]
FIG. 1 is a block diagram showing a configuration of an optical transmission / reception system according to the first embodiment of the present invention. The optical transmission / reception system 1 includes a first transmission / reception device 2 and a second transmission / reception device 4 connected to the first transmission / reception device 2 via a plurality of optical transmission media 3.

  The first transmitter / receiver 2 includes a plurality of first optical transmitters 21a to 21d that transmit optical signals, a first optical receiver 22 that receives optical signals, and a plurality of first optical transmitters 21a to 21a. And a first control unit 23 that controls 21d.

  The optical transmission medium 3 is an optical fiber in the present embodiment, but may be an optical transmission medium such as a sheet-like optical transmission medium in which a plurality of cores are covered with a clad.

  The second transmission / reception device 4 sends optical signals to the plurality of second optical reception units 41 a to 41 d that receive optical signals from the plurality of first optical transmission units 21 a to 21 d and the first optical reception unit 22. A second optical transmission unit 42 for transmission and a second control unit 43 for controlling the second optical transmission unit 42 are provided.

(Configuration of each part of first transmission / reception device)
The first optical transmission units 21 a to 21 d include a light emitting unit 210 and a driving unit 211 that drives the light emitting unit 210. The light emitting unit 210 is, for example, a laser diode (LD). The drive unit 211 is an LD driver that drives the LD by supplying a drive current to the LD, for example.

  The first light receiving unit 22 includes a light receiving unit 220 and an amplification unit 221. The light receiving unit 220 is, for example, a photodiode (PD). The amplifying unit 221 amplifies the output signal of the PD to a necessary signal level. Although the number of the first optical receivers 22 is one in the present embodiment, two or more may be used.

  The first controller 23 transmits an optical signal from a part of the first optical transmitters, for example, the first optical transmitter 21d, among the plurality of first optical transmitters 21a to 21d. When the first optical receiver 22 receives an optical signal as a response to signal transmission, the optical signals are transmitted from other first optical transmitters 21a to 21c other than the first optical transmitter 21d. . The timing for transmitting the optical signal from the first optical transmission unit 21d may be transmitted in synchronization with the power-on of the first transmission / reception device 2, for example. In addition, when transmitting an optical signal from some of the first optical transmission units, the optical signal is not limited to one first optical transmission unit and may be transmitted from two or more first optical transmission units. .

  The above control of the first control unit 23 will be described more specifically. When the first control unit 23 transmits an optical signal from a part of the first optical transmission units, that is, the first optical transmission unit 21d, the first control unit 23 transmits the optical signal with the first light amount, and When the first optical receiver 22 receives an optical signal as a response to transmission, the optical signal is transmitted from the first optical transmitter 21d with a second light quantity that is larger than the first light quantity, and partly The first optical transmitters other than the first optical transmitters, that is, the first optical transmitters 21a to 21c transmit the optical signal with the first light amount, and the first optical transmitters 21a to 21c transmit the first optical signals. When the first optical receiver 22 receives the optical signal as a response to the transmission of the optical signal with the light quantity of light, the first light transmitter 21a to 21c emits light with the second light quantity that is larger than the first light quantity. Send a signal. Note that the first light amount in the first light transmission unit 21d and the first light amounts in the first light transmission units 21a to 21c do not have to coincide completely, and the first light transmission unit 21d. There may be a difference in the light amount as long as the second light amount is lower than the second light amount in the first optical transmitters 21a to 21c. The first light amount is preferably a light amount that ensures safety to the human body even when the optical transmission medium 3 is disconnected from the transmission / reception devices 2 and 4, for example, a light amount in a light amount range that satisfies safety standards.

(Configuration of each part of second transmission / reception device)
The second light receiving units 41 a to 41 d include a light receiving unit 410 and an amplifying unit 411. The light receiving unit 410 is, for example, a photodiode (PD). The amplifying unit 411 amplifies the output signal of the PD to a necessary signal level.

  The second optical transmission unit 42 includes a light emitting unit 420 and a driving unit 421. The light emitting unit 420 is, for example, a laser diode (LD). The driving unit 421 is an LD driver that drives the LD by supplying a driving current to the LD, for example.

  When the second optical reception unit 41d corresponding to the first optical transmission unit 21d receives an optical signal, the second control unit 43 transmits light from the second optical transmission unit 42 as a response to reception of the optical signal. Send a signal.

  2A is a diagram for explaining the function of the first control unit according to the first embodiment, and FIG. 2B is a laser drive signal and an optical signal according to the first embodiment. FIG.

  The first control unit 23 generates the control system data Dc, the video system data Di, and the data output control signal Sp for controlling the data output of the driving unit 211. Here, the control system data Dc is output to the first optical transmission unit 21d, the video system data Di is output to the first optical transmission units 21a to 21c, and the data output control signal Sp is the first optical transmission unit 21a. The pulse period of the data output control signal Sp is set longer than the pulse period of the control system data Dc and the video system data Di. When the data output control signal Sp is low, the driving unit 211 of the first optical transmission unit 21d transmits the control system data Dc to the light emitting unit 210, and when the data output control signal Sp is high (Hi). Then, a laser drive signal Sd for controlling the control system data Dc so as not to be transmitted to the light emitting unit 210 is generated. When the data output control signal Sp is low, the driving units 211 of the first optical transmission units 21a to 21c transmit the video data Di to the light emitting unit 210, and the data output control signal Sp is high (Hi). ), A laser drive signal Sd for controlling the video data Di so as not to be transmitted to the light emitting unit 210 is generated. And the light emission part 210 of each drive part 211 of the 1st optical transmission parts 21a-21d outputs the optical signal SL synchronizing with the laser drive signal Sd.

  In consideration of the safety of the laser, when it is unclear whether the optical transmission medium 3 with the first transmitter / receiver 2 turned on is connected on the second transmitter / receiver 4 side, the first controller 23 is intermittent. A data output control signal Sp is generated, the laser is intermittently emitted to reduce the laser light amount, and the optical transmission medium 3 is connected to both the first transmission / reception device 2 and the first transmission / reception device 4. If it can be confirmed that the first control unit 23 maintains the data output control signal Sp low, the drive unit 211 performs control to increase the laser light amount by constantly emitting the laser. ing. Here, “light quantity” means an average light quantity, and in this embodiment, the average light quantity is controlled by controlling the number of pulses of control system data Dc or video system data Di per unit time without changing the peak. Although the control is performed, it may be a control for changing the peak without changing the number of pulses per unit time, or a control in which both are combined. In the case shown in FIG. 2B, the light emission period Tr is 3 ms, the light emission period Ton is 2 ms, and the non-light emission period Toff is 1 ms. The laser drive signal Sd in the light emission period Ton is a pulse signal corresponding to the control system data Dc or the video system data Di, and its cycle tr is 31.25 ns. The “light emission period” refers to a period during which the light is lit by a pulse, and the “non-light emission period” refers to a period during which the light is not lit by a pulse. “Intermittent light emission” refers to light emission in which light emission periods and non-light emission periods exist alternately.

(Effects of the first embodiment)
According to the first embodiment, the following effects are obtained.
(1) Presence / absence of connection of the optical transmission medium 3 by transmitting an optical signal from some of the first optical transmitters 21a to 21d of the first transmitter / receiver 2 Regardless of the case, the power consumption is suppressed compared to the case where optical signals are transmitted from all the first optical transmission units 21a to 21d.
(2) Transmitting an optical signal that emits light intermittently from the first transmission / reception device 2, and transmitting an optical signal that emits light only after receiving a response from the second transmission / reception device 4, thereby transmitting light. Safety is enhanced compared to the case where a high-power laser is continuously output regardless of whether or not the medium 3 is connected.

[Second Embodiment]
FIG. 3 is a block diagram showing a configuration of an optical transmission / reception system according to the second embodiment of the present invention. The optical transmission / reception system 1 includes a first transmission / reception device 2, a plurality of optical transmission media 3, and a second transmission / reception device 4 corresponding to the first embodiment, and is further connected to the first transmission / reception device 2. And a video display device 6 connected to the second transmission / reception device 4. In FIG. 3, the video data is transmitted in one direction from the playback device 5 to the video display device 6, and the control data is transmitted in both directions between the playback device 5 and the video display device 6. It is configured.

  The playback device 5 plays back video from a recording medium such as a DVD (Digital Versatile Disc) or BlueRayDisc (registered trademark). Note that the information to be reproduced is not limited to video, and may be only a still image or audio, or both video or still image and audio. The playback device 5 of the present embodiment outputs, for example, red (R), green (G), and blue (B) digital video signals and a clock signal (CLK) as video system data, and as control system data, for example, A DDC signal for data communication with the video display device 6 such as a DDC_SCL (Serial Clock for Display Data Channel) signal and a DDC_SDA (Serial Data for Display Data Channel) signal is output to the first transmitting / receiving device 2.

  The video display device 6 displays the video data output from the second transmission / reception device 4 on the display screen based on the control data.

  FIG. 4 is a block diagram showing the configuration of the first and second transmission / reception devices according to the second embodiment.

  The first transmission / reception device 2 includes a data input / output control unit 24, a packet control unit 25, a link control unit 26, and a plurality of first optical transmission units 21a to 21d provided corresponding to video data. And parallel / serial (paraserial) converters 27a to 27d, a first optical transmitter 21e, a first optical receiver 22, a parallel / serial (paraserial) converter 27e provided corresponding to the control system data, and And a serial / parallel (serial-parallel) converter 28.

  The second transmission / reception device 4 corresponds to a plurality of second optical transmission units 41a to 41d and a plurality of serial / parallel (serial-serial) conversion units 44a to 44d provided corresponding to the video system data, and to the control system data. A second optical receiver 41e, a second optical transmitter 42, a serial / parallel (serial-parallel) converter 44e and a parallel / serial (para-serial) converter 45, a link controller 46, and packet control. Unit 47 and a data input / output control unit 48.

(Configuration of each part of first transmission / reception device)
The first optical transmission units 21a to 21e are configured in the same manner as the first optical transmission units 21a to 21d of the first embodiment.

  The data input / output control unit 24 exchanges data with the playback device 5.

  For the data direction (DS direction) from the playback device 5 to the video display device 6, the packet control unit 25 packetizes the data for serial data transfer, and goes from the video display device 6 to the playback device 5. For the data direction (US direction), data is extracted from the packet data.

  The link control unit 26 performs link control when performing serial transmission between the first and second transmission / reception devices 2 and 4, and similarly to the first control unit 23 of the first embodiment, Light emission control is performed on the first optical transmitters 21a to 21e.

  The parallel-serial conversion units 27a to 27e convert the parallel data into serial data and perform 8B10B conversion for converting from 8 bits to 10 bits. The serial-parallel converter 28 converts serial data into parallel data and performs 8B10B reverse conversion for converting from 10 bits to 8 bits. In this 8B10B conversion, DC balance adjustment is performed so that transmission data appropriately includes 0 and 1, and in a method known as 8B10B, a block of data for each 8 bits is set to predetermined 0s and 1s. The DC balance is adjusted by converting the data to 10-bit data close to 50%.

  The data input / output control unit 24, the packet control unit 25, the link control unit 26, the parallel-serial conversion units 27a to 27e, and the serial-parallel conversion unit 28 are partly or entirely reconfigurable circuits (FPGA: Field Programmable Gate Array), specific You may comprise by hardware circuits, such as an application specific integrated circuit (ASIC: Application Specific Integrated Circuit) and dedicated LSI (Large Scale Integration).

(Configuration of each part of second transmission / reception device)
The second optical receivers 41a to 41e are configured similarly to the second optical receivers 41a to 41d of the first embodiment.

  The parallel-serial conversion unit 45 converts parallel data into serial data. The serial-parallel converters 44a to 44e convert serial data into parallel data.

  The link control unit 46 performs link control when serial transmission is performed between the first and second transmission / reception devices 2 and 4, and similarly to the second control unit 43 of the first embodiment, Light emission control is performed on the second optical transmission unit 42.

  The packet control unit 47 extracts data from packet data in the DS direction, and packetizes data for serial data transfer in the US direction.

  The data input / output control unit 48 exchanges data with the video display device 6.

  The link control unit 46, the packet control unit 47, the data input / output control unit 48, the parallel-serial conversion unit 45, and the serial-parallel conversion units 44a to 44e are partially or entirely configured by hardware circuits such as FPGA, ASIC, and dedicated LSI. May be.

(Operation of Second Embodiment)
FIG. 5 is a diagram illustrating an overall flow of link establishment between the first and second transmission / reception apparatuses according to the second embodiment.

  First, links in the downlink (DS) direction and uplink (US) direction of control system data are established (S1). When the link in the DS direction and the US direction of the control system data is established (S1: Yes), all the links in the DS direction of the video system data are established (S2: Yes). In this case, the DS link of the video system data is established (S2) while confirming that the DS direction link and the US direction link of the control system data are held (S3: Yes).

  When all the links of the video data DS are established (S2: Yes), it is confirmed that all the links in the DS direction of the video data are held (S4: Yes). It is determined whether or not the US direction link is held (S6). In the above step S4, if some links in the DS direction of the video system data are not held (S4: No), it is confirmed that the DS direction link and the US direction link of the control system data are held ( S5: Yes), the process returns to step S2.

The following factors can be considered when the link in the DS / US direction of the control system data in steps S3 and S4 is broken without being held.
(A) When light is no longer detected on the receiving side (b) When an error occurs during serial / parallel conversion on the receiving side (for example, 8B10B error or byte alignment error)
Even when the link in the DS direction of the video data in step S4 is broken without being held, the same factors as in (a) and (b) above can be considered.

(Control system data flow)
FIG. 6 is a diagram illustrating a flow relating to link establishment of control data between the first and second transmission / reception apparatuses according to the second embodiment. In FIG. 6, (A), (B), and (C) represent different data. In the present embodiment, the 8B10B K character is changed. (A) is K28.5, (B) is K28.6, and (C) is K28.0. (A) and (B) in FIG. 7 are the same as those in FIG.

  When the power of the first transmission / reception device 2 is turned on, the link control unit 26 instructs steady light emission in the DS direction of the control system data. The first optical transmission unit 21 e for control system data transmits an optical signal that emits light constantly to the second transmission / reception device 4.

  When the second transmitter / receiver 4 is turned on and the second optical receiver 41e detects light, the link controller 46 is notified that the light has been detected. When notified from the second optical receiver 41e that the light has been detected, the link controller 46 instructs the second optical transmitter 42 for control system data to emit light constantly. The second optical transmitter 42 transmits an optical signal that regularly emits light to the first transmitter / receiver 2.

  When the first optical receiver 22 of the first transmission / reception device 2 detects light, the link controller 26 is notified that the light has been detected. The link control unit 26 instructs the first paraserial conversion unit 27e for control system data to output serialization / deserialization (SerDes: Serialize Deserialize) link establishment data. The first parallel-serial conversion unit 27 e outputs SerDes link establishment data, and the first optical transmission unit 21 e transmits an optical signal to the second transmission / reception device 4.

  When the serial-parallel conversion unit 44e of the second transmission / reception device 4 receives the SerDes link establishment data, the SerDes (DS) link is established. The serial-parallel converter 44e notifies the link controller 46 that the SerDes (DS) link has been established. The link control unit 46 instructs the paraserial conversion unit 45 for control system data to output SerDes link establishment data. The parallel-serial converter 45 outputs SerDes link establishment data, and the second optical transmitter 42 transmits an optical signal to the first transmitter / receiver 2.

  When the serial-parallel converter 28 of the first transmission / reception device 2 receives the SerDes link establishment data from the second transmission / reception device 4, the SerDes (US) link is established. The serial-parallel converter 28 notifies the link controller 26 that the SerDes (US) link has been established. The link control unit 26 instructs the parasite conversion unit 27e for control data to output data indicating that the SerDes (US) link has been established. The parallel-serial conversion unit 27 e outputs data indicating that the SerDes (US) link is established, and the first optical transmission unit 21 e transmits the optical signal to the second transmission / reception device 4.

  When the serial-parallel conversion unit 44e of the second transmission / reception device 4 receives data indicating that the SerDes (US) link has been established, it notifies the link control unit 46 that the SerDes (US) link has been established.

  After a certain time elapses, the first and second transmission / reception devices 2 and 4 are in a link state.

(Video data flow)
FIG. 7 is a diagram illustrating a flow relating to video data link establishment between the first and second transmission / reception apparatuses according to the second embodiment.

  When the power of the first transmission / reception device 2 is turned on, the link control unit 26 instructs steady light emission in the DS direction of the video data. The first optical transmitters 21 a to 21 d for video data transmit optical signals that emit light constantly to the second transmitter / receiver 4.

  When the power of the second transmission / reception device 4 is turned on and the second optical receivers 41a to 41d detect light, the link controller 46 is notified that the light has been detected. Upon receiving notification that light has been detected from all of the second optical receivers 41a to 41d, the link controller 46 detects the light in all channels of the video system with respect to the parallel conversion unit 45 for control data. Instructed to output data indicating that this has occurred. The parallel-serial converter 45 outputs data indicating that light has been detected in all channels of the video system, and the second optical transmitter 42 transmits an optical signal to the first transmitter / receiver 2.

  When the serial-parallel conversion unit 28 of the first transmission / reception device 2 receives data indicating that light has been detected in all channels of the video system from the second transmission / reception device 4, it is linked that light has been detected in all channels of the video system. The control unit 26 is notified.

  After a certain time elapses, the first and second transmission / reception devices 2 and 4 are in a link state.

(Effect of the second embodiment)
According to the second embodiment, an optical signal is transmitted from some of the first optical transmitters 21 a to 21 e of the first transmitter / receiver 2, by transmitting an optical signal. Power consumption is suppressed compared to the case where optical signals are transmitted from all the first optical transmission units 21a to 21e regardless of whether or not the transmission medium 3 is connected.

[Third Embodiment]
Next, an optical transmission / reception system according to the third embodiment of the present invention will be described. The present embodiment is different from the second embodiment in the control method by the link control units 26 and 46, and the other configuration is the same as the second embodiment. Since the optical transmission / reception system of the present embodiment is configured in the same manner as the second embodiment, illustration thereof is omitted. This embodiment is also suitable when the optical signal has a high output.

(Control system data flow)
FIG. 8 is a diagram showing a flow of control system data between the first and second transmission / reception apparatuses according to the third embodiment of the present invention. In FIG. 8, (A), (B), and (C) mean different data. In the present embodiment, the 8B10B K character is changed. (A) is K28.5, (B) is K28.6, and (C) is K28.0. FIG. 9A is the same as FIG.

  When the power of the first transmission / reception device 2 is turned on, the link control unit 26 instructs intermittent light emission in the DS direction of the control system data. The first optical transmission unit 21 e for control system data transmits an optical signal that emits light intermittently to the second transmission / reception device 4.

  When the second transmitter / receiver 4 is turned on and the second optical receiver 41e detects light, the link controller 46 is notified that the light has been detected. When the link controller 46 receives a notification from the second optical receiver 41e that light has been detected, the link controller 46 instructs the second optical transmitter 42 for control system data to emit light intermittently. The second optical transmitter 42 transmits an optical signal that emits light intermittently to the first transmitter / receiver 2.

  When the first optical receiver 22 of the first transmitter / receiver 2 detects light from the second transmitter / receiver 4, the link controller 26 is notified that the light has been detected. The link control unit 26 instructs the first optical transmission unit 21e for control system data to perform steady light emission. The first optical transmission unit 21 e transmits an optical signal that regularly emits light to the second transmission / reception device 4.

  When the second optical receiving unit 41e of the second transmission / reception device 4 detects light for a predetermined time, the second optical receiving unit 41e notifies the link control unit 46 that the light has been detected for a predetermined time. Notice. The link control unit 46 instructs the second light transmission unit 42 to emit steady light. The second optical transmitter 42 transmits an optical signal that regularly emits light to the first transmitter / receiver 2.

  When the first optical receiver 22 of the first transmitter / receiver 2 detects the light from the second transmitter / receiver 4 for a predetermined time, the first optical receiver 22 detects the predetermined time of light. This is notified to the link control unit 26. The link control unit 26 instructs the paraserial conversion unit 27e for control system data to output SerDes link establishment data. The parallel-serial conversion unit 27e outputs data for SerDes link establishment, and the first optical transmission unit 21e transmits an optical signal to the second transmission / reception device 4.

  When the serial-parallel converter 44e of the second transmission / reception device 4 detects the SerDes link establishment data from the second transmission / reception device 4, the SerDes (DS) link is established. The serial-parallel converter 44e of the second transmission / reception device 4 notifies the link controller 46 that the SerDes (DS) link has been established. The link control unit 46 instructs the paraserial conversion unit 45 for control system data to output SerDes link establishment data. The parallel-serial converter 45 outputs SerDes link establishment data, and the second optical transmitter 42 transmits an optical signal to the first transmitter / receiver 2.

  When the serial-parallel converter 28 of the first transmission / reception device 2 detects the SerDes link establishment data from the second transmission / reception device 4, the SerDes (US) link is established. The serial-parallel converter 28 notifies the link controller 26 that the SerDes (US) link has been established. The link control unit 26 instructs the parasite conversion unit 27e for control data to output data indicating that the SerDes (US) link has been established. The parallel-serial conversion unit 27 e outputs data indicating that the SerDes (US) link is established, and the first optical transmission unit 21 e transmits the optical signal to the second transmission / reception device 4.

  When the serial-parallel converter 44e of the second transmission / reception device 4 detects light indicating that the SerDes (US) link has been established, it notifies the link controller 46 that the SerDes (US) link has been established.

  After a certain time elapses, the first and second transmission / reception devices 2 and 4 are in a link state.

(Video data flow)
FIG. 9 is a diagram showing a flow relating to establishment of a link of video data between the first and second transmission / reception apparatuses according to the third embodiment of the present invention.

  When the power of the first transmission / reception device 2 is turned on, the link control unit 26 instructs intermittent light emission in the DS direction of the video data. The first optical transmitters 21 a to 21 d for video data transmit optical signals that emit light intermittently to the second transmitter / receiver 4.

  When the power of the second transmission / reception device 4 is turned on and the second optical receivers 41a to 41d detect light, the link controller 46 is notified that the light has been detected. Upon receiving notification that light has been detected from all of the second optical receivers 41a to 41d, the link controller 46 detects the light in all channels of the video system with respect to the parallel conversion unit 45 for control data. Instructed to output data indicating that this has occurred. The parallel-serial converter 45 outputs data indicating that light has been detected in all channels of the video system, and the second optical transmitter 42 transmits an optical signal to the first transmitter / receiver 2.

  When the serial-parallel converter 28 of the first transmission / reception device 2 detects data indicating that light has been detected in all channels of the video system from the second transmission / reception device 4, it indicates that light has been detected in all channels of the video system. The link control unit 26 is notified.

  The link control unit 26 instructs the first optical transmission units 21a to 21d (DS direction of the video data) to emit light constantly. The first optical transmitters 21 a to 21 d for video data transmit optical signals that emit light constantly to the second transmitter / receiver 4.

  When all the second optical receivers 41a to 41d of the second transceiver 4 detect light for a certain period of time, the link controller 46 is notified that the light has been detected.

  After a certain time elapses, the first and second transmission / reception devices 2 and 4 are in a link state.

(Effect of the third embodiment)
According to the third embodiment, the following effects are obtained.
(1) Presence / absence of connection of the optical transmission medium 3 by transmitting an optical signal from some of the first optical transmission units 21a to 21e of the first transmission / reception device 2 Regardless of the case, the power consumption is suppressed compared to the case where optical signals are transmitted from all the first optical transmission units 21a to 21e.
(2) Transmitting an optical signal that emits light intermittently from the first transmission / reception device 2, and transmitting an optical signal that emits light only after receiving a response from the second transmission / reception device 4, thereby transmitting light. Safety is enhanced compared to the case where a high-power laser is continuously output regardless of whether or not the medium 3 is connected.

[Fourth Embodiment]
FIG. 10 is a block diagram showing a configuration of an optical transmission / reception system according to the fourth embodiment of the present invention. This embodiment is different from the second embodiment in that the parallel-serial conversion units 27a to 27d and the serial-parallel conversion units 44a to 44d related to video data are omitted, and the rest is the same as the second embodiment. It is configured. The first transmission / reception device 2 includes a buffer (not shown) that temporarily stores video data received from the playback device 5, and the second transmission / reception device 4 includes a video system that is transmitted to the video display device 6. A buffer (not shown) for temporarily storing data is provided.

  Also in this configuration, serial / parallel conversion and parallel / serial conversion are not performed on the video data, and the first transmission / reception device 2 to the second transmission / reception device 4 from the reproduction device 5. Except that the serial data is transmitted from the second transmission / reception device 4 to the video display device 6 as it is, the same operations and effects as the second and third embodiments are obtained.

  Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications and implementations are possible without departing from the scope of the present invention. For example, the constituent elements of each embodiment can be arbitrarily combined within the scope not changing the gist of the present invention, and steps can be added, deleted, changed, replaced, etc. in the flow of each embodiment. is there.

DESCRIPTION OF SYMBOLS 1 ... Optical transmission / reception system, 2 ... 1st transmission / reception apparatus, 3 ... Optical transmission medium, 4 ... 2nd transmission / reception apparatus, 5 ... Reproduction | regeneration apparatus, 6 ... Video display apparatus, 21a-21e ... 1st optical transmission part, DESCRIPTION OF SYMBOLS 22 ... 1st optical receiving part, 23 ... 1st control part, 24 ... Data input / output control part, 25 ... Packet control part, 26 ... Link control part, 27a-27e ... Parasiri conversion part, 28 ... Serial conversion part , 41a to 41e ... second optical receiver, 42 ... optical transmitter, 43 ... second controller, 44a-44e ... serial-parallel converter, 45 ... para-serial converter, 46 ... link controller, 47 ... packet control 48, data input / output control unit, 210 ... light emitting unit, 211 ... driving unit, 220 ... light receiving unit, 221 ... amplification unit, 410 ... light receiving unit, 411 ... amplification unit, 420 ... light emitting unit, 421 ... amplification unit

Claims (4)

A plurality of first optical transmitters for transmitting optical signals;
A first optical receiver for receiving an optical signal;
A first transmitting / receiving device comprising:
A plurality of second optical receivers for receiving optical signals from the plurality of first optical transmitters;
A second optical transmitter for transmitting an optical signal to the first optical receiver;
A second transmitting / receiving device comprising:
The first transmission / reception device transmits an optical signal from a part of the first optical transmission units of the plurality of first optical transmission units, and the first optical reception unit as a response to the optical signal When receiving an optical signal from the second optical transmission unit, the optical transmission / reception system transmits an optical signal from the remaining first optical transmission unit among the plurality of first optical transmission units. An optical signal transmitted from a part of the first optical transmission units among the plurality of first optical transmission units is control system data,
2. The optical transmission / reception system according to claim 1, wherein an optical signal transmitted from the remaining first optical transmission unit among the plurality of first optical transmission units is video data.   The first transmission / reception device transmits an optical signal from a part of first optical transmission units of the plurality of first optical transmission units in synchronization with power-on of the first transmission / reception device. Item 3. The optical transmission / reception system according to Item 1 or 2. A plurality of optical transmitters for transmitting optical signals;
An optical receiver for receiving an optical signal,
When the plurality of optical transmission units transmit optical signals from some of the optical transmission units to the counterpart transmission / reception device, and the optical reception unit receives an optical signal from the counterpart transmission / reception device as a response to the optical signal An optical transmitter / receiver that transmits an optical signal from the remaining optical transmitter to the counterpart transmitter / receiver.

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