KR101136727B1 - Display-Port optical connector - Google Patents

Abstract

PURPOSE: A display-port optical connector is provided to transmit and receive sub signals in a display-port system and to transmit a main signal from a host device to a display device. CONSTITUTION: A host-sided connection unit(21) is connected to main signal terminals and sub signal terminals. A display-sided connection unit(22) is connected to the main signal terminals and sub signal terminals. An optical cable(23) connects the host-sided connection unit and the display-sided connection unit. A sub light signal and a main light signal are transmitted to the display-sided connection unit through an optical fiber line.

Description

Display-Port optical connector

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display-port optical connector. More particularly, the present invention relates to a display-port optical connector. It relates to a port optical connector.

Figure 1 shows a typical display-port system in accordance with VESA's Display-Port communication provisions. Referring to FIG. 1, a conventional display-port system will be described.

The control unit 121 in the display apparatus 12 includes Extended Display Identification Data (EDID), which is configuration information and control information of the display apparatus 12, and Display-Port Configuration Data, which is reception-condition information, of the display apparatus 12. ) Is recorded.

The control unit 111 in the host device 11 receives the EDID and the DPCD stored in the serial EEPROM in the display device 12 according to the Display-Port communication standard, and then receives the received EDID and the DPCD. Accordingly, the main data is transmitted to the control unit 121 in the display device 12. Here, the main data refers to video signals in which clock signals are embedded.

In this transmission process, the control unit 111 in the host device 11, according to the Display-Port communication regulations of the Video Electronics Standards Association (VESA), the DP 121 and the DPCD in the display device 12 Performs communication. The communication of this DPCD (called communication for "link training") is as follows.

First, the control unit 111 in the host device 11 transmits the predetermined transmission-condition information of the host device 11 to the control unit 121 in the display device 12 in accordance with the received DPCD.

Secondly, the control unit 121 in the display device 12 receives the main data according to the received transmission-condition information.

Third, if an error occurs in the process of receiving the main data, the controller 121 in the display apparatus 12 receives a signal indicating that the transmission condition is not suitable for itself through the access signal HPD. 111). For example, the control unit 121 in the display device 12 transmits the connection signal HPD of the pulse train repeating logics 1 and 0 to the control unit 111 in the host device 11. For reference, while the display apparatus 12 is operating normally, the controller 121 in the display apparatus 12 transmits a logic 1 connection signal (HPD: Hot Plug Detection) to the controller 111 in the host apparatus 11. do.

Fourth, when a signal indicating that the transmission condition is not suitable for itself is generated via the connection signal HPD, the control unit 111 in the host device 11 changes the predetermined transmission-condition information of the host device 11, and changes the changed transmission. Condition information is transmitted to the control unit 121 in the display apparatus 12.

And fifth, the second to fourth steps are repeatedly performed.

On the other hand, the display-port interface 112 in the host apparatus 11 includes a main data transmitter 112m and an auxiliary data receiver 112s.

The main data transmitter 112m converts the parallel main data from the control unit 111 into differential auxiliary signals, and four pairs of differential auxiliary signals L1 + L1-, L2 + L2-, and L3 + formed of eight lines. L3-, L4 + L4-).

The auxiliary data receiver 112s receives a pair of differential auxiliary signals AUX + and AUX- composed of two lines from the display apparatus 12 and parallelly stores them according to the Display-Port communication standard. The signal is converted into an input signal and input to the controller 111. For this communication, the auxiliary data receiving unit 112s converts the parallel output signal from the control unit 111 into differential auxiliary signals in accordance with the Display-Port communication standard, thereby making one pair of two lines. Differential differential signals AUX + and AUX- are transmitted to the display device 12.

In FIG. 1, reference numeral V _D denotes a power supply voltage from each of the host apparatus 11 and the display apparatus 12, and HPD denotes a connection signal from the display apparatus 12. Since the connection signal HPD is in the logical " 1 " state when the display apparatus 12 is in operation, the controller 111 in the host apparatus 11 may determine whether the display apparatus 22 is connected to the display apparatus 22. FIG.

The control unit 121 in the display device 12 transmits the EDID and the DPCD recorded according to the Display-Port communication rule to the control unit 111 in the host device 11, and the host device 11. The main data from the control part 111 in the inside is received.

The display-port interface 122 in the display device 12 includes a primary data receiver 122m and an auxiliary data transmitter 122s.

The main data receiver 122m is configured to display-port communication four pairs of differential auxiliary signals (L1 + L1-, L2 + L2-, L3 + L3-, and L4 + L4-) of eight lines. According to the regulation, the signal is converted into a parallel input signal and input to the controller 121.

The auxiliary data transmitter 122s converts the parallel output signal from the controller 121 into differential auxiliary signals according to the Display-Port communication standard, so that a pair of differential auxiliary signals composed of two lines are provided. (AUX +, AUX-) is transmitted to the host device 11. For this communication, the auxiliary data transmitter 122s receives a pair of differential auxiliary signals AUX + and AUX- composed of two lines from the host device 11 and displays them in a display-port. According to a communication rule, the signal is converted into a parallel input signal and input to the controller 121.

According to the conventional Display-Port system described above with reference to FIG. 1, when long-distance communication is performed, problems of noise generation and signal attenuation occur.

It is an object of the present invention to provide a display-port optical connector which can effectively reduce the number of optical fiber lines in an optical cable while eliminating the problems of noise and signal attenuation caused by long distance communication by optical communication. .

The display-port optical connector of the present invention connects a host device and a display device to each other according to the Display-Port communication standard of the Video Electronics Standards Association (VESA). It includes an optical cable.

The host side connection is connected to the main signal terminals and auxiliary signal terminals of the host device.

The display side connection part is connected to main signal terminals and auxiliary signal terminals of the display device.

The optical cable connects between the host side connection portion and the display side connection portion.

Here, the optical auxiliary signal from the host side connector and the optical main signal of one channel are transmitted to the display side connector via one optical fiber line in the optical cable.

As described in the background art, auxiliary signals in a Display-Port system are mainly transmitted and received only at the initial operation time, and only the primary signals are transmitted from the host device to the display device at the subsequent operation time. do.

According to the display-port optical connector of the present invention using the same, the optical auxiliary signal from the host side connection portion and the optical main signal of one channel are transmitted to the display side connection portion through one optical fiber line in the optical cable.

Thus, the problem of noise and signal attenuation generated when long distance communication is performed is solved by optical communication, so that the number of optical fiber lines in the optical cable can be effectively reduced.

1 is a block diagram illustrating a typical Display-Port system.
2 is a block diagram illustrating a Display-Port system using a Display-Port optical connector according to an embodiment of the present invention.
FIG. 3 is a block diagram illustrating an internal configuration of a host side auxiliary connector of the display-port optical connector of FIG. 2.
4 is a block diagram illustrating an internal configuration of another all-optical converting unit that may replace the all-optical converting unit of FIG. 3.
5 is a block diagram illustrating an internal configuration of the bidirectional conversion unit of FIGS. 3 and 4.
FIG. 6 is a block diagram illustrating an internal configuration of a display side auxiliary connector of the display-port optical connector of FIG. 2.
FIG. 7 is a block diagram illustrating an internal configuration of the bidirectional converter of FIG. 6.
8 is a waveform diagram illustrating a relationship between differential auxiliary signals and single auxiliary signals in FIGS. 5 and 7.
FIG. 9 is a block diagram illustrating an internal configuration of a host-side main connector of the display-port optical connector of FIG. 2.
FIG. 10 is a block diagram illustrating an internal configuration of a display-side main connector of the display-port optical connector of FIG. 2.
FIG. 11 is a block diagram illustrating a Display-Port system using a Display-Port optical connector according to another embodiment of the present invention.
FIG. 12 is a block diagram illustrating an internal configuration of a display side auxiliary connector of the display-port optical connector of FIG. 11.
FIG. 13 is a block diagram illustrating an internal configuration of a host side auxiliary connector of the display-port optical connector of FIG. 11.

The following description and the annexed drawings are for understanding the operation according to the present invention, and a part that can be easily implemented by those skilled in the art may be omitted.

In addition, the specification and drawings are not provided to limit the invention, the scope of the invention should be defined by the claims. Terms used in the present specification should be interpreted as meanings and concepts corresponding to the technical spirit of the present invention so as to best express the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

2 shows a Display-Port system using Display-Port optical connectors 21 to 23 according to one embodiment of the present invention. In FIG. 2, the same reference numerals as used in FIG. 1 indicate objects of the same function. That is, since the Display-Port system has been described with reference to FIG. 1, only the Display-Port optical connectors 21 to 23 and related matters according to an embodiment of the present invention will be described. Shall be.

Referring to FIG. 2, the display-port optical connectors 21 to 23 according to an embodiment of the present invention may be configured according to the display-port communication standard of the Video Electronics Standards Association (VESA). 11 and the display device 12, which are connected to each other, include a host side connection part 21, a display side connection part 22, and an optical cable 23.

The host side connection portion 21 is connected to the main signal terminals and auxiliary signal terminals of the host device 11. The display side connecting portion 22 is connected to the main signal terminals and the auxiliary signal terminals of the display device 12. The optical cable 23 connects between the host side connector 21 and the display side connector 22.

Here, the optical auxiliary signal AUXhml from the host side connector 21 and the optical main signal L4l of one channel are transmitted to the display side connector 22 through one optical fiber line in the optical cable 23. .

As described in the background art, a pair of differential auxiliary signals (AUX +, AUX-) in a Display-Port system are mainly transmitted and received only at the initial operation time, and at the subsequent operation time. Only differential main signals L1 + to L4- are transmitted from the display-port interface 112 of the host device 11 to the display-port interface 122 of the display device 12.

In the display-port optical connectors 21 to 23 of the present embodiment using the same, the optical auxiliary signal AUXhml from the host side connecting portion 21 and the optical main signal L4l of one channel are 1 in the optical cable 23. Are transmitted to the display side connecting portion 22 through the two optical fiber lines.

Therefore, the noise and signal attenuation problems generated when long distance communication is performed are solved by optical communication, so that the number of optical fiber lines in the optical cable 23 can be effectively reduced.

More specifically, the host side connecting portion 21 includes a host side main connecting portion 21b, a host side auxiliary connecting portion 21a, and a host side connecting signal-terminal connecting portion 21c.

The host side main connecting portion 21b is connected to the main signal terminals of the three channels of the host device 11 and is connected to the main light signals L11 to 1 through each of the first to third optical fiber lines in the optical cable 23. L3l) is transmitted to the display side connecting portion 22, respectively.

The host side auxiliary connector 21a is connected to the main signal terminals and the auxiliary signal terminals of the other channel of the host device 11 to connect the optical auxiliary signal AUXhml and the remaining 1 through the fourth optical fiber line. The light main signal L41 of the channel is transmitted to the display side connecting portion 22. Thus, the number of optical fiber lines in the optical cable 23 can be effectively reduced.

In addition, the host side auxiliary connector 21a restores the optical auxiliary signal AUXmhl received from the display side connector 22 through the fifth optical fiber line to a pair of differential auxiliary signals AUX + and AUX-. Input to the (auxiliary) signal terminals.

The host side connection signal-terminal connection part 21c is connected to the connection signal terminal of the host apparatus 11, and electrically connects the optical connection signal HPD1 received from the display side connection part 22 via the sixth optical fiber line. (HPD: Hot Plug Detection) is converted, and the converted connection signal (HPD) is input to the connection signal terminal of the host device (11).

The display side connecting portion 22 includes a display side main connecting portion 22b, a display side auxiliary connecting portion 22a and a display side connecting signal-terminal connecting portion 22c.

The display side main connector 22b is connected to the main signal terminals of the three channels of the display apparatus 12 to connect each of the first to third optical fiber lines in the optical cable 23 from the host side main connector 21b. Each of the main light signals L11 to L31 received through the signal is restored to the differential main signals L1 + to L3- and input to the main signal terminals of the three channels of the display apparatus 12.

The display side auxiliary connector 22a is connected to the main signal terminals and auxiliary signal terminals of the other channel of the display device and is received through the fourth optical fiber line from the host side auxiliary connector 21a through the fourth optical fiber line. The signal AUXhml is restored to a pair of differential auxiliary signals AUX + and AUX- and input to the auxiliary signal terminals of the display device 12.

In addition, the display-side auxiliary connection unit 22a restores the optical main signal L41 received through the fourth optical fiber line in the optical cable 23 to a pair of differential main signals L4 + and L4-, and rests the rest. Input to the main signal terminals of 1 channel.

The display side auxiliary connector 22a converts the pair of differential auxiliary signals AUX + and AUX- from the auxiliary signal terminals of the display device 12 into optical auxiliary signals AUXmhl. Transmission is performed to the host side auxiliary connection portion 21a through the fifth optical fiber line in the cable 23.

The display side connection signal-terminal connection part 22c converts the connection signal HPD from the connection signal terminal of the display apparatus 12 into the optical connection signal HPDl, and converts the converted optical connection signal HPDl to the sixth. It transmits to a host side connection signal-terminal connection part 21c via an optical fiber line.

FIG. 3 shows the internal configuration of the host side auxiliary connection 21a of the display-port optical connectors 21 to 23 of FIG.

2 and 3, the host-side auxiliary connection unit 21a includes a bidirectional conversion unit 31, a DC balance codec 32, a subtraction unit 33, a transmission control unit 34, and an all-optical conversion unit. 35 and the photoelectric conversion unit 36.

The bidirectional conversion unit 31 is connected to the auxiliary signal terminals of the host device 11 to convert the differential auxiliary signals AUX + and AUX- from the host device 11 into a single auxiliary signal AUXhm and output the same. The single auxiliary signal AUXmh from the display device 12 is converted into differential auxiliary signals AUX + and AUX- and input to the auxiliary signal terminals of the host device 11.

Therefore, the difficulty in which bidirectional differential signals AUX + and AUX- cannot be transmitted and received as an optical signal can be solved by the bidirectional converter 31.

Here, EDID (Extended Display Identification Data), Display-Port Configuration Data (DPCD), and communication data for "link training" of the DPCD are DC unbalanced.

The DC balance codec Codec 32 performs DC balance encoding on the single auxiliary signal AUXhm from the bidirectional conversion unit 31 to output the encoded single auxiliary signal AUXhmc, and to display the display device 12. Decoded single auxiliary signal (AUXmhc) from) and input to the bi-directional conversion unit 31.

Therefore, the difficulty that the differential signals AUX + and AUX- cannot be transmitted and received as an optical signal due to DC unbalance can be solved by the DC balance codec 32.

Hereinafter, "single signal" is used in the sense of an electrical signal corresponding to "differential signal".

The subtracting section 33 is connected to the main signal terminals of the other channel of the host device 11, so that the main channel of the other channel in the differential main + signal L4 + from the main + signal terminal of the other channel. Generate a fourth single main signal L4 that is the result of the subtraction of the differential main-signal L4- from the signal terminal.

The transmission control unit 34 outputs a switching control signal Scon as a signal is generated from the bidirectional conversion unit 31 or the subtraction unit 33. As described above, the pair of differential auxiliary signals AUX + and AUX- in the Display-Port system are transmitted and received only during the initial operation time, and the differential main signals L1 + during the subsequent operation time. To L4- only are transmitted from the display-port interface 112 of the host device 11 to the display-port interface 122 of the display device 12. That is, at any point in time, the main signals L1 + to L4- and the auxiliary signals AUX + and AUX- may not be transmitted at the same time. Using this, the transmission controller 34 may output a switching control signal Scon as a signal is generated from the bidirectional converter 31 or the subtractor 33.

The pre-optical conversion section 35 operates in accordance with the switching control signal Scon from the transmission control section 34, so that the encoded single auxiliary signal AUXhmc or the subtraction section from the DC balance codec 32 is obtained. Converts the fourth single main signal L4 from 33 to the optical signals AUXhml and L4l, and converts the converted optical auxiliary signal AUXhml or the fourth optical main signal L4l through the fourth optical fiber line. To the display-side auxiliary connector 22a.

The photoelectric conversion unit 36 converts the encoded optical auxiliary signal AUXmhl received from the display side auxiliary connection unit 22a through the fifth optical fiber line into a single encoded auxiliary signal AUXmhc for DC balancing. Input to Codec (32).

More specifically, the DC balance codec Codec 32 includes a DC balance encoder 32c and a decoder 32d.

The DC balance encoder 32c performs DC balance encoding on the single auxiliary signal AUXhm from the bidirectional converter 31 and transmits the encoded single auxiliary signal AUXhmc to the pre-optical converter 35. Enter it.

The decoding unit 32d decodes the encoded single auxiliary signal AUXmhc from the photoelectric conversion unit 36, and inputs the decoded single auxiliary signal AUXmh to the bidirectional conversion unit 31.

In the present embodiment, 8-bit auxiliary data is encoded into 10 bits and DC-encoded data is decoded into 8-bit auxiliary data for DC balance encoding.

The pre-light conversion unit 35 includes a light emitting device 354, a first light emitting device driver 351, a second light emitting device driver 352, and a switching device 353.

The light emitting element 354 generates an optical signal AUXhml or L4l by operating in response to an input driving signal, and transmits the generated optical signal AUXhml or L4l to the display side auxiliary connector 22a through the fourth optical fiber line. send.

The first light emitting device driver 351 outputs a driving signal of the light emitting device 354 according to the fourth single main signal L4 from the subtracting part 33.

The second light emitting device driver 352 outputs a drive signal of the light emitting device 354 according to the encoded single auxiliary signal AUXhmc from the DC balancing coder 32c in the DC balancing codec Codec 32. .

The switching element 353 selects a driving signal from the first light emitting device driver 351 or a driving signal from the second light emitting device driver 352 according to the switching control signal Scon from the transmission control unit 34 to emit light. Input to element 354.

The photoelectric conversion unit 36 includes a light receiving element 364 and a reception amplifier 362.

The light receiving element 364 converts the encoded optical auxiliary signal AUXmhl received from the display side auxiliary connector 22a through the fifth optical fiber line into a single encoded auxiliary signal AUXmhc.

The reception amplifier 362 amplifies the encoded single auxiliary signal AUXmhc from the light receiving element 364 and inputs it to the decoder 32d in the DC balance codec 32.

4 shows an internal configuration of another all-optical converting unit 45 that may replace the all-optical converting unit 35 of FIG. In FIG. 4, the same reference numerals as used in FIG. 3 indicate objects of the same function. Therefore, only the internal configuration of another all-optical converting unit 45 that can replace the all-optical converting unit 35 of FIG. 3 will be described below.

2 and 4, the all-light conversion unit 45 may include the light emitting device 455, the first buffer 451, the second buffer 452, the switching device 453, and the light emitting device driver 454. Include.

The light emitting element 455 generates an optical signal AUXhml or L4l by operating in response to an input driving signal, and transmits the generated optical signal AUXhml and L4l to the display side auxiliary connector 22a through the fourth optical fiber line. send.

The first buffer 451 delays and outputs the fourth single main signal L4 from the subtraction section 33 in accordance with the operation time of the transmission control section 34.

The second buffer 452 delays and outputs the encoded single auxiliary signal AUXhmc from the DC balancing encoder 32c in the DC balancing codec Codec 32 in accordance with the operation time of the transmission control unit 34. .

The switching element 453 is the fourth single main signal L4 from the first buffer 451 or the encoded single auxiliary from the second buffer 452 in accordance with the switching control signal Scon from the transmission control section 34. Select and output the signal AUXhmc.

The light emitting device driver 454 inputs a driving signal to the light emitting device 455 according to the fourth single main signal L4 or the encoded single auxiliary signal AUXhmc from the switching device 453.

5 shows an internal configuration of the bidirectional conversion unit 31 of FIGS. 3 and 4.

2 to 5, the bidirectional converter 31 of FIGS. 3 and 4 includes a subtractor 51 and a differential signal generator 52.

The subtraction unit 51 is a single auxiliary signal Auxhm that is a result of the subtraction of the differential auxiliary signal AUX- from the auxiliary signal terminal from the differential auxiliary signal AUX + from the auxiliary signal terminal of the host device 11. ). In this case, since the bidirectional control unit 53 generates an enable logic signal of high logic, the enable logic signal of high logic is input to the enable terminal EN of the subtractor 51 so that the subtractor 51 ) Is enabled, a low logic enable control signal is input from the inverter 54 to the enable terminal EN of the differential signal generator 52, and the differential signal generator 52 is disabled ( disable).

The differential signal generator 52 converts a single auxiliary signal Auxmh from the decoder 32d in the DC balance codec Codec 32 into differential auxiliary signals AUX + and AUX- to convert the host device 11 into a host device 11. Output to the auxiliary signal terminals of. In this case, since the bidirectional control unit 53 generates the low logic enable control signal, the low logic enable control signal is input to the enable terminal EN of the subtraction unit 51 so that the subtraction unit 51 can be used. ) Is disabled, and a high logic enable control signal from the inverter 54 is input to the enable terminal EN of the differential signal generator 52 so that the differential signal generator 52 is enabled ( enable).

FIG. 6 shows an internal configuration of the display side auxiliary connection portion 22a of the display-port optical connectors 21 to 23 of FIG.

2 and 6, the display side auxiliary connector 22a of the display-port optical connectors 21 to 23 of FIG. 2 includes the photoelectric conversion unit 61, the reception control unit 64, the buffer 62, And a switching element 63, a differential signal generator 65, a bidirectional converter 67, a DC balance codec 66 and an all-optical converter 68.

The photoelectric conversion unit 61 converts the fourth optical main signal L4l or the encoded optical auxiliary signal AUXhml received from the host side auxiliary connector 21a through the fourth optical fiber line into a fourth single main signal ( L4) or a single coded auxiliary signal AUXhmc.

The reception control unit 64 determines whether the output signal of the photoelectric conversion unit 61 is the fourth single main signal L4 or the encoded single auxiliary signal AUXhmc to generate the switching control signal Scon.

The buffer 62 delays the output signal of the photoelectric conversion unit 61 according to the operation time of the reception control unit 64.

The switching element 63 operates in accordance with the switching control signal Scon from the reception control unit 64, outputs the fourth single main signal L4 from the buffer 62 to the first terminal, and outputs the buffer 62. A coded single auxiliary signal (AUXhmc) from) is output to the second terminal.

The differential signal generator 65 is connected to the main signal terminals of the remaining one channel of the display device 12 so as to receive a fourth single main signal L4 from the first terminal of the switching element 63 by the fourth. The differential main + signal L4 + and the fourth differential main signal L4- are converted into the main signal terminals of the other channel of the display device 12.

The bidirectional conversion unit 67 is connected to the auxiliary signal terminals of the display device 12 to convert the differential auxiliary signals AUX + and AUX- from the display device 12 into a single auxiliary signal AUXmh and output the same. Then, the input single auxiliary signal AUXhm is converted into differential auxiliary signals AUX + and AUX- and input to the auxiliary signal terminals of the display device 12.

The DC balancing codec Codec 66 performs DC balancing encoding on the single auxiliary signal AUXmh from the bidirectional converter 66 to output the encoded single auxiliary signal AUXmhc, and then outputs the switching element 63. Decoded single auxiliary signal (AUXhmc) from the () is input to the bi-directional conversion section 67.

The all-optical conversion unit 68 converts the encoded single auxiliary signal AUXmhc from the DC balance codec Codec 66 into an optical auxiliary signal AUXmhl, and converts the converted optical auxiliary signal AUXmhl into the above-mentioned. It transmits to the host side auxiliary connection part 21a through a 5th optical fiber line.

The DC balance codec Codec 66 includes a DC balance encoder 662 and a decoder 661.

The DC balance encoder 662 performs DC balance encoding on the single auxiliary signal AUXmh from the bidirectional converter 67 and transmits the encoded single auxiliary signal AUXmhc to the pre-optical converter 68. Enter it.

The decoder 661 decodes the encoded single auxiliary signal AUXhmc from the switching element 63, and inputs the decoded single auxiliary signal AUXhm to the bidirectional conversion unit 67.

As described above, in the present embodiment, 8-bit auxiliary data is encoded into 10 bits and DC-encoded data is decoded into 8-bit auxiliary data for DC balanced encoding.

The pre-light conversion unit 68 includes a light emitting element driver 681 and a light emitting element 682.

The light emitting element driver 681 generates a drive signal in accordance with the encoded single auxiliary signal AUXmhc from the DC balance encoder 662 in the DC balance codec Codec 66.

The light emitting element 682 operates according to a driving signal from the light emitting element driver 681 to output the light auxiliary signal AUXmhl to the fifth optical fiber line.

The photoelectric conversion unit 61 includes a light receiving element 611 and a reception amplifier 612.

The light receiving element 611 receives the fourth optical main signal L4l or the encoded optical auxiliary signal AUXhml received from the host side auxiliary connector 21a through the fourth optical fiber line, or the fourth single main signal L4 or Convert to a single coded auxiliary signal (AUXhmc).

The reception amplifier 612 amplifies the output signal from the light receiving element 611 and outputs it to the buffer 62 and the reception control unit 64.

7 illustrates an internal configuration of the bidirectional conversion unit 67 of FIG. 6.

2, 6 and 7, the bidirectional converter 67 includes a subtractor 72 and a differential signal generator 71.

The subtraction unit 72 is a single auxiliary signal Auxmh which is a result of subtraction of the differential auxiliary signal AUX- from the auxiliary signal terminal AUX + from the auxiliary signal terminal A + of the display device 12. ). In this case, since the bidirectional control unit 73 generates an enable logic signal with a high logic, the enable logic signal with a high logic is input to the enable terminal EN of the subtractor 72 so that the subtractor 72 ) Is enabled, a low logic enable control signal is input from the inverter 74 to the enable terminal EN of the differential signal generator 71, and the differential signal generator 71 is disabled ( disable).

The differential signal generator 71 converts and displays the single auxiliary signal Auxhm from the decoder 661 in the DC balance codec Codec 66 into differential auxiliary signals AUX + and AUX-. In this case, since the bidirectional control unit 73 generates the low logic enable control signal, the low logic enable control signal is inputted to the enable terminal EN of the subtraction unit 72 so that the subtraction unit 72 is reduced. ) Is disabled, and a high logic enable control signal is input from the inverter 74 to the enable terminal EN of the differential signal generator 52 so that the differential signal generator 71 is enabled ( enable).

FIG. 8 shows a relationship between differential auxiliary signals AUX + and AUX- and single auxiliary signals AUXmh and AUXhm in FIGS. 5 and 7. In FIG. 8, (a) shows waveforms of differential auxiliary signals AUX + and AUX-, and (b) shows waveforms of single auxiliary signals AUXmh and AUXhm.

5, 7 and 8, the differential auxiliary signals AUX + and AUX- input or output from the auxiliary + signal terminal and the auxiliary-signal terminal have a low positive value based on the intermediate positive potential V _CM . Have a polarity potential (V _D− ) or a positive potential (V _{D +} ), but are inverted from each other. That is, the differential auxiliary signals AUX + and AUX- have a constant potential difference V _DIFF .

In the case of the single auxiliary signals AUXmh and AUXhm, the differential positive signals AUX + and AUX are at the intermediate positive potential V _{CM of the} differential auxiliary signals AUX + and AUX- to 0 V (volts), the ground potential. The low positive potential V _{D− of −} ) corresponds to the negative potential, and the high positive potential V _{D + of the} differential auxiliary signals AUX + and AUX− corresponds to the positive potential, respectively.

In this state, by subtracting the auxiliary signal AUX- from the auxiliary signals AUX + of the differential auxiliary signals AUX + and AUX-, a single auxiliary signal AUXmh is obtained. Therefore, the pulse height 2V _DIFF of the single auxiliary signals AUXmh and AUXhm is twice the potential difference V _DIFF between the differential auxiliary signals AUX + and AUX-.

For example, a signal of logic 0 is obtained between t1 and t2, and a signal of logic 1 is obtained between t2 and t3.

Of course, the differential signal generator (52 of FIG. 5 or 71 of FIG. 7) performs the above processes in reverse.

FIG. 9 shows the internal configuration of the host side main connection 21b of the display-port optical connectors 21 to 23 of FIG.

2 and 9, the host-side main connecting unit 21b includes a first subtracting unit 901, a first pre-optical conversion unit 911, a second subtracting unit 902, and a second pre-optical conversion unit. 912, a third subtractor 903, and a third all-optical converter 913.

The first subtraction part 901 is a first differential main-signal from the main-signal terminal of the first channel in the first differential main + signal L1 + from the main-signal terminal of the first channel of the host device 11. Generates a first 'single main signal L1 which is the result of subtraction of (L1-).

The first pre-optical conversion unit 911 converts the first single signal L1 from the first subtraction unit 901 into a first optical main signal L1l, and converts the converted first optical main signal L1. L1l is transmitted to the display-side main connector 22b via the first optical fiber line in the optical cable 23.

The second subtractor 902 is configured to convert the second differential main signal from the main signal terminal of the second channel to the second differential main signal L2 + from the main channel signal terminal of the second channel of the host device 11. Generates a second 'single main signal L2 which is the result of subtracting (L2-).

The second pre-optical converter 912 converts the second single signal L2 from the second subtractor 902 into a second optical main signal L2l, and converts the second optical main signal L2l. L2l) is transmitted to the display-side main connector 22b via the second optical fiber line in the optical cable 23.

The third subtraction unit 903 is a third differential main-signal from the main-signal terminal of the third channel in the third differential main + signal L3 + from the main + signal terminal of the third channel of the host device 11. A third main signal L3 is generated which is the result of subtraction of (L3-).

The third pre-optical converter 913 converts the third single signal L3 from the third subtractor 903 into a third optical main signal L3l, and converts the converted third optical main signal. (L3l) is transmitted to the display side main connecting portion 22b via the third optical fiber line in the optical cable 23.

FIG. 10 shows the internal configuration of the display side main connection portion 22b of the display-port optical connectors 21 to 23 of FIG.

2 and 10, the display-side main connector 22b includes a first opto-electric converter 1001, a first differential signal generator 1011, a second opto-electric converter 1002, and a second And a differential signal generator 1012, a third photoelectric converter 1003, and a third differential signal generator 1013.

The first photoelectric conversion unit 1001 converts the first optical main signal L11 received through the first optical fiber line in the optical cable 23 into a first 'single main signal L1.

The first differential signal generator 1011 converts the first `single main signal L1 from the first photoelectric converter 1001 into first differential main signals L1 + and L1- to display the display device ( Input to the main signal terminals of the first channel of 12).

The second photoelectric conversion unit 1002 converts the second optical main signal L2l received through the second optical fiber line in the optical cable 23 into a second 'single main signal L2.

The second differential signal generator 1012 converts the second single signal L2 from the second photoelectric converter 1002 into second differential main signals L2 + and L2- to display the display device ( Input to the main signal terminals of the second channel of 12).

The third photoelectric conversion unit 1003 converts the third optical main signal L3l received through the third optical fiber line in the optical cable 23 into a third 'single main signal L3.

The third differential signal generator 1013 converts the third `single main signal L3 from the third photoelectric converter 1003 into third differential main signals L3 + and L3- and displays the display device. Input to the main signal terminals of the third channel of (12).

FIG. 11 shows a Display-Port system in which the Display-Port optical connectors 13 to 15 are used according to another embodiment of the present invention. In FIG. 11, the same reference numerals as used in FIG. 2 indicate objects of the same function.

The difference between the embodiment of FIG. 11 and the embodiment of FIG. 2 is that the host side connection signal-terminal connection portion 21c, the display side connection signal-terminal connection portion 22c and the sixth optical fiber line in the embodiment of FIG. In the eleventh embodiment. Therefore, the configurations of the display side auxiliary connecting portion 14a and the host side auxiliary connecting portion 13a are different from those of FIG.

Referring to FIG. 11, the display side connecting portion 14 includes a display side main connecting portion 22b and a display side auxiliary connecting portion 14a.

The display side main connector 22b is connected to the main signal terminals of the three channels of the display apparatus 12 and is connected from the host side connector 13 through each of the first to third optical fiber lines in the optical cable 15. Each of the received light main signals L11 to L31 is restored to the differential main signals L1 + to L3- and input to the main signal terminals of the three channels of the display apparatus 12.

The display side auxiliary connector 14a is connected to the main signal terminals and auxiliary signal terminals of the other channel of the display device 12 and received from the host side auxiliary connector 13a through the fourth optical fiber line. The auxiliary light auxiliary signal AUXhml is restored to a pair of differential auxiliary signals AUX + and AUX- and input to the auxiliary signal terminals of the display device 12.

In addition, the display-side auxiliary connection unit 14a restores the optical main signal L4l received through the fourth optical fiber line in the optical cable 15 to a pair of differential main signals L4 + and L4-, and rests the rest. Input to the main signal terminals of 1 channel.

And, the display side auxiliary connecting portion 14a is connected to the pair of differential auxiliary signals AUX + and AUX- from the auxiliary signal terminals of the display device 12 and the connection signal terminals of the display device 12. The connection signal HPD is converted into the optical complex signal AuxHpdl and transmitted to the host side auxiliary connector 13a through the fifth optical fiber line in the optical cable 15.

The host side connecting portion 13 includes a host side primary connecting portion 21b and a host side auxiliary connecting portion 13a.

The host side main connecting portion 21b is connected to the main signal terminals of the three channels of the host device 11 and is connected to the main signal signals L11 to 1 through each of the first to third optical fiber lines in the optical cable 15. L3l) is transmitted to the display main connecting portion 22b.

The host side auxiliary connector 13a is connected to main signal terminals, auxiliary signal terminals, and connection signal terminals of the other channel of the host device 11, and provides an optical auxiliary signal ( AUXhml) and the optical main signal L4l of the remaining one channel are transmitted to the display side auxiliary connector 14a.

In addition, the host side auxiliary connector 13a connects the optical composite signal AuxHpdl received from the display side auxiliary connector 14a through the fifth optical fiber line to a pair of differential auxiliary signals AUX + and AUX-. The signal HPD is restored and output to the auxiliary signal terminals and the connection signal terminals of the host device 11, respectively.

FIG. 12 shows the internal configuration of the display side auxiliary connection 14a of the display-port optical connectors 13 to 15 of FIG. In Fig. 12, the same reference numerals as those in Fig. 6 indicate the objects of the same function. Thus, redundant descriptions will be omitted wherever possible.

11 and 12, the display-side auxiliary connection unit 14a includes a photoelectric conversion unit 61, a reception controller 64, a buffer 62, a switching element 63, a differential signal generator 65, A bidirectional converter 67, a DC balance codec 66, a multiplexer 141, and an all-optical converter 68 are included.

The photoelectric conversion unit 61 converts the fourth optical main signal L4l or the encoded optical auxiliary signal AUXhml received from the host side auxiliary connection unit 13a through the fourth optical fiber line into a fourth single main signal ( L4) or a single coded auxiliary signal AUXhmc.

The reception control unit 64 determines whether the output signal of the photoelectric conversion unit 61 is the fourth single main signal L4 or the encoded single auxiliary signal AUXhmc to generate the switching control signal Scon.

The buffer 62 delays the output signal of the photoelectric conversion unit 61 according to the operation time of the reception control unit 64.

The switching element 63 operates in accordance with the switching control signal Scon from the reception control unit 64, outputs the fourth single main signal L4 from the buffer 62 to the first terminal, and outputs the buffer 62. A coded single auxiliary signal (AUXhmc) from) is output to the second terminal.

The differential signal generator 65 is connected to the main signal terminals of the other channel of the display device 12 to remove the fourth single main signal L4 from the first terminal of the switching element 63. The fourth differential main signal L4 + and the fourth differential main signal L4- are converted into input signals to the main signal terminals of the other one channel of the display device 12.

The bidirectional conversion unit 67 is connected to the auxiliary signal terminals of the display device 12 to convert the differential auxiliary signals AUX + and AUX- from the display device 12 into a single auxiliary signal AUXmh and output the same. Then, the input single auxiliary signal AUXhm is converted into differential auxiliary signals AUX + and AUX- and input to the auxiliary signal terminals of the display device 12.

The DC balancing codec Codec 66 performs DC balancing encoding on the single auxiliary signal AUXmh from the bidirectional conversion unit 67 to output the encoded single auxiliary signal AUXmhc, and then switches the switching element 63. Decoded single auxiliary signal (AUXhmc) from the () is input to the bi-directional conversion section 67.

The multiplexer 141 converts the coded single auxiliary signal AUXmhc from the DC balance codec Codec 66 and the connection signal HPD from the connection signal terminal of the display device 12 into a composite signal AuxHpd. do.

The pre-optical conversion unit 68 converts the complex signal AuxHpd from the multiplexer 141 into an optical complex signal AuxHpdl, and converts the converted optical complex signal AuxHpdl into a host side through the fifth optical fiber line. It transmits to the connection part 13a.

FIG. 13 shows the internal configuration of the host side auxiliary connection 13a of the display-port optical connectors 13 to 15 of FIG. In FIG. 13, the same reference numerals as used in FIG. 3 indicate objects of the same function. Thus, redundant descriptions will be omitted wherever possible.

11 and 13, the host side auxiliary connection unit 13a includes a bidirectional conversion unit 31, a DC balance codec 32, a subtraction unit 33, a transmission control unit 34, and an all-optical conversion unit. 35, a photo-electric converter 36 and a demultiplexer 131.

The bidirectional conversion unit 31 is connected to the auxiliary signal terminals of the host device 11 to convert the differential auxiliary signals AUX + and AUX- from the host device 11 into a single auxiliary signal AUXhm and output the same. The single auxiliary signal AUXmh from the display device 12 is converted into differential auxiliary signals AUX + and AUX- and input to the auxiliary signal terminals of the host device 11.

The DC balance codec Codec 32 performs DC balance encoding on the single auxiliary signal AUXhm from the bidirectional conversion unit 31 to output the encoded single auxiliary signal AUXhmc, and to display the display device 12. Decoded single auxiliary signal (AUXmhc) from) and input to the bi-directional conversion unit 31.

The subtraction section 33 is connected to the main signal terminals of the remaining one channel of the host device 11, so that the differential main + signal L4 + from the main + signal terminal of the other one channel of the remaining one channel of The fourth main signal L4 is generated as a result of the subtraction of the main main signal L4- from the main signal terminal.

The transmission control unit 34 outputs a switching control signal Scon as a signal is generated from the bidirectional conversion unit 31 or the subtraction unit 33.

The pre-optical conversion section 35 operates in accordance with the switching control signal Scon from the transmission control section 34, so that the encoded single auxiliary signal AUXhmc or the subtraction section from the DC balance codec 32 is obtained. Converts the fourth single main signal L4 from 33 to the optical signals AUXhml and L4l, and converts the converted optical auxiliary signal AUXhml or the fourth optical main signal L4l through the fourth optical fiber line. To the display-side auxiliary connector 14a.

The photoelectric conversion unit 36 converts the optical composite signal AuxHpdl received from the display side auxiliary connection unit 14a through the fifth optical fiber line into the auxiliary-connection composite signal AuxHpd.

The demultiplexer 131 separates the auxiliary-connection composite signal AuxHpd from the photoelectric conversion unit 36 into the connection signal HPD and the encoded single auxiliary signal AUXmhc, and divides the connection signal HPD into the host device. It outputs to the connection signal terminal of (11), and outputs the encoded single auxiliary signal AUXmhc to the DC balance codec Codec.

As described above, the auxiliary signals in the Display-Port system are mainly transmitted and received only at the initial operation time, and only the main signals are transmitted from the host device to the display device at the subsequent operation time.

According to the display-port optical connector according to the present invention, the optical auxiliary signal from the host side connection portion and the optical main signal of one channel are transmitted to the display side connection portion through one optical fiber line in the optical cable.

Thus, the problem of noise and signal attenuation generated when long distance communication is performed is solved by optical communication, so that the number of optical fiber lines in the optical cable can be effectively reduced.

The present invention has been described above with reference to preferred embodiments. Those skilled in the art will understand that the present invention can be embodied in a modified form without departing from the essential characteristics of the present invention. Therefore, the above-described embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is defined by the appended claims rather than by the foregoing description, and the inventions claimed by the claims and the inventions equivalent to the claimed invention are to be construed as being included in the present invention.

The present invention can be used in all cases of long distance communication using bidirectional signals.

11 ... host unit, 111, 121 ... control unit,
112, 122 display-port interface, 112 m ... main data transmitter,
112s ... Auxiliary data receiver, 122m ... Main data receiver,
122s ... auxiliary data transmitter,
21 to 23, 13 to 15 ... display-port optical connector,
21, 13 ... host side connection, 22, 14 ... display side connection,
23, 15 ... optical cable,
21a, 13a ... host side auxiliary connection,
22a, 14a ... host side auxiliary connection,
21b ... host side connection, 22b ... display side main connection,
21c ... Host side connection signal-terminal connection,
22c ... Display side connection signal to terminal connection.

Claims (9)

delete A display-port optical connector for connecting a host device and a display device with each other according to the Display-Port communication regulation of the Video Electronics Standards Association (VESA),
A host side connection part connected to the main signal terminals and auxiliary signal terminals of the host device;
A display side connection part connected to the main signal terminals and the auxiliary signal terminals of the display device, and
An optical cable connecting the host side connection part and the display side connection part;
An optical auxiliary signal from the host side connection and an optical main signal of one channel are transmitted to the display side connection through one optical fiber line in the optical cable,
The host side connection portion,
A host side connected to the main signal terminals of the three channels of the host device to transmit each of the main optical signals L1 to L3l to the display side connection through each of the first to third optical fiber lines in the optical cable; Main connection;
Connected to the main signal terminals and the auxiliary signal terminals of the other channel of the host device, the optical auxiliary signal AUXhml and the optical main signal L4l of the remaining one channel through the fourth optical fiber line; The auxiliary signal terminal (AUXmhl), which is transmitted to the display side connection unit and received through the fifth optical fiber line from the display side connection unit, to the pair of differential auxiliary signals (AUX + and AUX-). A host side auxiliary connection unit for inputting into the field; And
Connected to the connection signal terminal of the host device, converts the optical connection signal HPDl received from the display side connection portion through the sixth optical fiber line into an electrical connection signal (HPD: Hot Plug Detection), and converts the converted connection signal ( And a host-side connection signal-terminal connection portion for inputting HPD) to the connection signal terminal of the host device. According to claim 2, The display side connection portion,
Connected to the main signal terminals of the three channels of the display device, and differentials each of the main light signals L1-L3l received from the host side main connection through each of the first to third optical fiber lines in the optical cable; A display side main connection unit for restoring the main signals L1 + to L3- and inputting the main signals to the main signal terminals of the three channels of the display device;
A pair of differential pairs of optical auxiliary signals AUXhml which are connected to the main signal terminals and auxiliary signal terminals of the other channel of the display device and received from the host side auxiliary connection unit through the fourth optical fiber line; A pair of optical main signals L4l received through the fourth optical fiber line in the optical cable by reconstructing the auxiliary signals AUX + and AUX- into the auxiliary signal terminals of the display device. A pair of differential auxiliary signals AUX +, which are restored to the differential main signals L4 + and L4-, are input to the main signal terminals of the remaining one channel, and are provided from the auxiliary signal terminals of the display device. A display side auxiliary connector for converting AUX-) into an optical auxiliary signal (AUXmhl) and transmitting it to the host side auxiliary connector through a fifth optical fiber line in the optical cable; And
The connection signal HPD from the connection signal terminal of the display device is converted into the optical connection signal HPDl, and the converted optical connection signal HPDl is connected to the host side connection signal-terminal connection portion through the sixth optical fiber line. Display-port optical connector with display-side connection signal-to-terminal connection. The method of claim 3, wherein the host side auxiliary connection,
Connected to the auxiliary signal terminals of the host device, converts the differential auxiliary signals AUX + and AUX- from the host device into a single auxiliary signal AUXhm, and outputs the single auxiliary signal AUXmh from the display device; Bi-directional conversion unit converts a) into differential auxiliary signals AUX + and AUX- and inputs them to auxiliary signal terminals of the host device;
DC encoding is performed on the single auxiliary signal AUXhm from the bidirectional conversion unit to output the encoded single auxiliary signal AUXhmc, and the encoded single auxiliary signal AUXmhc from the display device is decoded. A DC balance codec (Codec) input to the bidirectional conversion unit;
A differential main signal from the main signal terminal of the other channel in a differential main + signal L4 + from the main signal terminal of the other channel, connected to the main signal terminals of the other channel of the host device; A subtraction unit for generating a fourth single main signal L4 which is a result of subtracting the signals L4-;
A transmission controller which outputs a switching control signal Scon according to the signal generated from the bidirectional converter or the subtractor;
Operating in accordance with the switching control signal Scon from the transmission control unit, the optical signal is encoded by the single signal AUXhmc from the DC balance codec Codec or the fourth single main signal L4 from the subtraction unit. An all-optical converter for converting a signal AUXhml and L4l and transmitting the converted optical auxiliary signal AUXhml or the fourth optical main signal L4l to the display side auxiliary connection unit through the fourth optical fiber line; And
A photo-electric converter converting the encoded optical auxiliary signal AUXmhl received from the display side auxiliary connection unit through the fifth optical fiber line into the encoded single auxiliary signal AUXmhc and inputting it to the DC balancing codec Codec. Display-Port Optical Connector with Converter. The display device of claim 4, wherein the display side auxiliary connection unit comprises:
A fourth single main signal L4 or an encoded single auxiliary signal AUXhmc to the fourth optical main signal L4l or the encoded optical auxiliary signal AUXhml received through the fourth optical fiber line from the host side auxiliary connector; Photo-electric conversion unit for converting;
A reception controller configured to determine whether an output signal of the photoelectric conversion unit is the fourth single main signal L4 or the encoded single auxiliary signal AUXhmc to generate a switching control signal Scon;
A buffer delaying an output signal of the photoelectric conversion unit according to an operation time of the reception control unit;
Operating according to a switching control signal from the reception control unit, outputting the fourth single main signal L4 from the buffer to a first terminal, and outputting the encoded single auxiliary signal AUXhmc from the buffer to a second terminal; A switching element output to the terminal;
A fourth differential main + signal L4 + and a fourth differential connected to the fourth single main signal L4 from the first terminal of the switching element, connected to the main signal terminals of the other channel of the display device; A differential signal generator for converting a main signal (L4-) into the main signal terminals of the remaining one channel of the display device;
Connected to the auxiliary signal terminals of the display device, and converts the differential auxiliary signals AUX + and AUX- from the display device into a single auxiliary signal AUXmh and outputs the differential auxiliary signals AUXhm; A bidirectional conversion unit converting the auxiliary signals to AUX + and AUX- and inputting the auxiliary signals to the auxiliary signal terminals of the display device;
DC encoding is performed on the single auxiliary signal AUXmh from the bidirectional conversion unit to output the encoded single auxiliary signal AUXmhc, and the encoded single auxiliary signal AUXhmc from the switching element is decoded. A DC balance codec (Codec) input to the bidirectional conversion unit; And
The host-side auxiliary connection unit converts the encoded single auxiliary signal AUXmhc from the DC balance codec Codec into an optical auxiliary signal AUXmhl, and converts the converted optical auxiliary signal AUXmhl through the fifth optical fiber line. Display-port optical connector with all-optical conversion for transmitting to According to claim 2, The display side connection portion,
A differential main signal connected to the main signal terminals of the three channels of the display device, and receiving each of the main light signals L1 to L3l received from the host side connection through each of the first to third optical fiber lines in the optical cable; A display-side main connector for restoring signals L1 + to L3- and inputting the signals to the main signal terminals of the three channels of the display apparatus; And
A pair of differential pairs of optical auxiliary signals AUXhml which are connected to the main signal terminals and auxiliary signal terminals of the other channel of the display device and received from the host side auxiliary connection unit through the fourth optical fiber line; A pair of optical main signals L4l received through the fourth optical fiber line in the optical cable by reconstructing the auxiliary signals AUX + and AUX- into the auxiliary signal terminals of the display device. A pair of differential auxiliary signals AUX +, which are restored to the differential main signals L4 + and L4-, are input to the main signal terminals of the remaining one channel, and are provided from the auxiliary signal terminals of the display device. AUX-) and the connection signal HPD from the connection signal terminal of the display device are converted into an optical composite signal AuxHpdl and connected to the host side auxiliary via the fifth optical fiber line in the optical cable. Port optical connector - the display including a display-side connecting portion for transmitting to the secondary unit. The method of claim 6, wherein the host side connection portion,
A host connected to the main signal terminals of the three channels of the host device to transmit each of the main optical signals L1 to L3l through the first to third optical fiber lines in the optical cable to the display side main connector; Side main connection; And
An optical auxiliary signal (Auxhml) and an optical main signal of the remaining one channel through the fourth optical fiber line, connected to main signal terminals, auxiliary signal terminals, and a connecting signal terminal of the other channel of the host device; (L4l) is transmitted to the display side auxiliary connector, and a pair of differential auxiliary signals (AUX +, AUX-) and the optical composite signal AuxHpdl received from the display side auxiliary connector through the fifth optical fiber line. And a host-side auxiliary connector for restoring a signal (HPD) and outputting the auxiliary signal terminals and the connection signal terminals of the host device, respectively. The method of claim 7, wherein the display side auxiliary connection,
A fourth single main signal L4 or an encoded single auxiliary signal AUXhmc to the fourth optical main signal L4l or the encoded optical auxiliary signal AUXhml received through the fourth optical fiber line from the host side auxiliary connector; Photo-electric conversion unit for converting;
A reception controller configured to determine whether an output signal of the photoelectric conversion unit is the fourth single main signal L4 or the encoded single auxiliary signal AUXhmc to generate a switching control signal Scon;
A buffer delaying an output signal of the photoelectric conversion unit according to an operation time of the reception control unit;
Operating according to a switching control signal from the reception control unit, outputting the fourth single main signal L4 from the buffer to a first terminal, and outputting the encoded single auxiliary signal AUXhmc from the buffer to a second terminal; A switching element output to the terminal;
A fourth differential main + signal L4 + and a fourth differential connected to the fourth single main signal L4 from the first terminal of the switching element, connected to the main signal terminals of the other channel of the display device; A differential signal generator for converting a main signal (L4-) into the main signal terminals of the remaining one channel of the display device;
Connected to the auxiliary signal terminals of the display device, and converts the differential auxiliary signals AUX + and AUX- from the display device into a single auxiliary signal AUXmh and outputs the differential auxiliary signals AUXhm; A bidirectional conversion unit converting the auxiliary signals to AUX + and AUX- and inputting the auxiliary signals to the auxiliary signal terminals of the display device;
DC encoding is performed on the single auxiliary signal AUXmh from the bidirectional conversion unit to output the encoded single auxiliary signal AUXmhc, and the encoded single auxiliary signal AUXhmc from the switching element is decoded. A DC balance codec (Codec) input to the bidirectional conversion unit;
A multiplexer for converting the coded single auxiliary signal AUXmhc from the DC balance codec Codec and the connection signal HPD from the connection signal terminal of the display device into a complex signal AuxHpd; And
An all-optical conversion unit converting the complex signal AuxHpd from the multiplexer into the optical complex signal AuxHpdl and transmitting the converted optical complex signal AuxHpdl to the host side auxiliary connection through the fifth optical fiber line. Display-Port optical connector included. The method of claim 8, wherein the host side auxiliary connection,
Connected to the auxiliary signal terminals of the host device, converts the differential auxiliary signals AUX + and AUX- from the host device into a single auxiliary signal AUXhm, and outputs the single auxiliary signal AUXmh from the display device; Bi-directional conversion unit converts a) into differential auxiliary signals AUX + and AUX- and inputs them to auxiliary signal terminals of the host device;
DC encoding is performed on the single auxiliary signal AUXhm from the bidirectional conversion unit to output the encoded single auxiliary signal AUXhmc, and the encoded single auxiliary signal AUXmhc from the display device is decoded. A DC balance codec (Codec) input to the bidirectional conversion unit;
A differential main signal from the main signal terminal of the other channel in a differential main + signal L4 + from the main signal terminal of the other channel, connected to the main signal terminals of the other channel of the host device; A subtraction unit for generating a fourth single main signal L4 which is a result of subtracting the signals L4-;
A transmission controller which outputs a switching control signal Scon according to the signal generated from the bidirectional converter or the subtractor;
Operating in accordance with the switching control signal Scon from the transmission control unit, the optical signal is encoded by the single signal AUXhmc from the DC balance codec Codec or the fourth single main signal L4 from the subtraction unit. An all-optical converter for converting a signal AUXhml and L4l and transmitting the converted optical auxiliary signal AUXhml or the fourth optical main signal L4l to the display side auxiliary connection unit through the fourth optical fiber line;
An opto-electric conversion unit for converting the optical composite signal AuxHpdl received from the display side auxiliary connection unit through the fifth optical fiber line into an auxiliary-connection composite signal AuxHpd; And
The auxiliary-connection composite signal AuxHpd from the photoelectric conversion unit is separated into the connection signal HPD and the encoded single auxiliary signal AUXmhc, and the connection signal HPD is connected to the host device. And a demultiplexer for outputting the coded single auxiliary signal (Auxmhc) to the DC balance codec (Codec).

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