KR20220038566A - A Recording medium on which repeater data transmission/reception program of DisplayPort side channel is recorded - Google Patents

Abstract

The present invention relates to a recording medium on which a repeater data transmission/reception program of a display port side channel is recorded, which overcomes limitation on a transmission distance. According to one embodiment of the present invention, a source device includes a source device processor and a sync device includes a sync device processor. Each processor provides an electrical interface for data transmission/reception between devices and an optical interface for data transmission/reception between the processors. The recording medium stores a program to execute a method in a computer, wherein the method encodes a cable connection state (unpluged), a transmission state (idle), and auxiliary (AUX) data into one optical signal on the basis of preset clock signal patterns of different frequencies to transmit the optical signal, and transfers the AUX data to a corresponding device by detecting the pattern of the received optical signal, thereby transmitting/receiving side channel repeater data as an optical signal.

Description

A Recording medium on which repeater data transmission/reception program of DisplayPort side channel is recorded

The present invention relates to a displayport side channel repeater data transmission/reception method, and more particularly, to a displayport side channel repeater data transmission/reception method for transmitting and receiving displayport side channel repeater data through an optical repeater, in which a computer can execute It relates to a recording medium on which a program is recorded.

With the recent development of imaging technology, high-density images are becoming popular, and 3D images are also increasing. With the development of such technology, various next-generation display technologies are emerging, and DisplayPort is widely used as an interface of the next-generation display. The DisplayPort may be configured with a connector that is respectively connected to interfaces provided by the source device and the sink device, and the DisplayPort includes a main link, an auxiliary channel, and a HPD (Hot Plug Detect) signal line for the source device and the sink device. Enables physical access. The main link is a high-bandwidth channel for transmitting video and audio data from a source device to a sink device. In addition, it is composed of an auxiliary channel through which signals providing control and management functions of links and devices are transmitted and received in both directions, and a channel through which HPD signals are transmitted.

In relation to a technology for assisting the normal output of such high-density images, Korean Patent Registration No. 10-1169282 discloses an HDMI control method using a hot-plug detection signal and an imaging device employing the method. The registered patent describes an HDMI control method and method for efficiently stabilizing the synchronization of data received from an external input device by controlling the equalizer of the HDMI receiver using the hot plug detection delay time of the hot plug detection signal. there is.

However, this prior art is limited to the HDMI (High Definition Multimedia Interface) interface method, and there is a limit to its application to DisplayPort.

In addition, it describes a method that can overcome the noise effect, data loss, and limit on transmission distance that may occur when the component link for control signals other than the main link through which video and audio data is transmitted and received is composed of copper waveguides, etc. There are limits that have not been established.

Republic of Korea Patent Publication No. 10-1169282 (2012.08.02)

The present invention is to solve the above problems of the related art, and an auxiliary channel (AUX-Channel) that enables a link and device setting and control for connection between a source providing device and a source output device and high-speed video and audio data transmission/reception Displayport side channel repeater data transmission/reception method that can be transmitted and received between both ends at high speed through fiber optic cable by composing signal transaction and HPD (Hot Plug Detect) into a one-way signal and converting it into an optical signal An object of the present invention is to provide a recording medium on which a program that can be executed is recorded.

A program recording medium according to an embodiment of the present invention for solving the above problems is provided with a source device processor in a source device and a sink device processor in a sink device, and an optical signal is transmitted between the source device processor and the sink device processor. A program capable of executing a method of transmitting and receiving display port side channel repeater data on a computer. When the power is turned on, the source device processor and the sink device processor transmit an optical unplug pattern based on whether an optical signal is received or not. sending to a processor; transmitting a device unplug pattern for a connection state with a device to a counterpart processor in a state in which the optical signal is normally received; receiving the device unplug pattern transmitted from the counterpart processor, detecting whether the counterpart device is connected, controlling the HDP signal, and waiting until the device is connected; transmitting an idle pattern to a counterpart processor and waiting for AUX data reception from the device when the source device and the sink device are connected by the device unplug pattern detection; when the AUX data is received from the device, transmitting the AUX data to a counterpart processor based on a preset data pattern; when the AUX data transmission is completed, transmitting an idle pattern and waiting for AUX data reception from a counterpart processor; when AUX data is received from a counterpart processor, transmitting the AUX data to a corresponding device; A program for executing a method comprising

In addition, an apparatus according to an embodiment of the present invention for solving the above problems, a source device processor for processing the repeater data by transmitting or receiving an electrical signal and a source device; and a sink device processor for processing repeater data by transmitting or receiving an electrical signal to or from a sink device, wherein the source device processor converts the electrical signal received from the source device into an optical signal and converts the processed repeater data to the sink and a source controller that transmits to a device processor, converts the optical signal received from the sink device processor into an electrical signal, and transfers the processed repeater data to the source device, wherein the sink device processor receives from the sink device A sink control unit that converts an electrical signal into an optical signal and transfers the processed repeater data to the source device processor, and converts the optical signal received from the source device processor into an electrical signal and transfers the processed repeater data to the sink device It includes a repeater device containing ;.

On the other hand, the method according to an embodiment of the present invention for solving the above problems may be implemented as a program for executing the method in a computer and a recording medium in which the program is recorded.

According to an embodiment of the present invention, noise effects and data loss are prevented by using an optical fiber cable as a path through which a side channel consisting of setting and control signals between devices other than the main link for video and audio data transmission and reception in DisplayPort is transmitted and received. and can overcome the limitation on the transmission distance.

In addition, the side channel with characteristics such as bidirectional communication along with the main link composed of fiber optic cable is a display that provides the effect of reducing the complexity of maintenance and the composition of mixing copper wires to transmit electrical signals A port side channel repeater device and an operating method thereof can be provided.

1 is a conceptual diagram schematically illustrating an entire system according to an embodiment of the present invention.
2 is a block diagram for explaining the structure of a displayport side channel repeater device according to an embodiment of the present invention.
3 is a ladder diagram illustrating a method of operating a repeater device according to an embodiment of the present invention.
4 is a flowchart illustrating data signal processing through a source device processor of a repeater apparatus according to an embodiment of the present invention.
5 is a flowchart illustrating data signal processing through a sink device processor of a repeater apparatus according to an embodiment of the present invention.
6 is a view for explaining the form of an auxiliary channel (AUX-Channel) signal that can be confirmed by the source signal pattern detector and the sink signal pattern detector of the repeater device according to an embodiment of the present invention.
7 is a diagram for explaining the shape of a pattern of an optical signal generated by an optical signal pattern generator of a repeater device according to an embodiment of the present invention.

Since the present invention can have various changes and can have various embodiments, specific embodiments are illustrated in the drawings and described in detail.

However, this is not intended to limit the present invention to specific embodiments, and it should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention.

The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present application, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. In describing the present invention, in order to facilitate the overall understanding, the same reference numerals are used for the same components in the drawings, and duplicate descriptions of the same components are omitted.

1 is a conceptual diagram schematically illustrating an entire system including a display port side channel repeater device according to an embodiment of the present invention, and FIG. 2 is a block diagram illustrating the structure of a repeater device according to an embodiment of the present invention. am.

First, referring to FIG. 1 , a system according to an embodiment of the present invention includes a source device 100 , a DisplayPort 200 , and a sink device 300 .

The source device 100 is a device that provides video or audio data, and provides data that can be output through a DVD player or a PC so that a person can recognize visual and auditory information.

The source device 100 may include a multimedia interface including a cable and a terminal for transmitting image and sound signals between the image source device and an image display device such as a TV or monitor.

The DisplayPort 200 may be physically connected to an interface provided by the source device 100 and the sink device 300 . The display port 200 may include a main link processor 210 . The main link processor 210 transmits video data and voice data from the source device 100 to the sink device 300 through the main link. The main link is a communication channel for unidirectionally transmitting a data signal from the source device 100 to the sink device 300 . And the main link is composed of a fiber optic cable to prevent data loss and overcome the data signal transmission limit that is attenuated according to the transmission distance.

In addition, the DisplayPort 200 is a side channel that is a link including a main link required for transmitting and receiving multimedia data between the source device 100 and the sink device 300 and a device setting and control signal. ) may include a repeater device 220 that processes through.

The repeater device 220 classifies data that needs to be transmitted from the bidirectional signal generated by the source device 100 or the sink device 300 to the device connected to the other end into a unidirectional signal. After that, the repeater device 220 converts a unidirectional signal, which is an electrical signal, into an optical signal to be transmitted through an optical cable.

The side channel is an auxiliary channel (AUX) for processing so that the source device 100 such as a Blu-ray player or PC can check and output information of the sink device 300 that is a display device such as a monitor. ) may include a signal. In detail, the auxiliary channel (AUX) signal may include a connection link through which video and audio data are transmitted and a control and management signal of a connection device. To this end, it may include EDID (Extended Display Identification Data) containing product information of the sink device 300 and information on output variables such as video input type, display size, power management, color characteristics, and timing information of resolution. .

In addition, the auxiliary channel (AUX) signal may include high-bandwidth digital content protection (HDCP). The HDCP is a copyright protection technology for preventing content from being illegally copied by encrypting a digital signal transmitted from an image reproducing device to a display device. This allows the use of the ability to protect the copyright of the owner and holder of the source content.

Additionally, the side channel may include a Hot Plug Detect (HPD) signal that can check whether the source device 100 and the sink device 300 are connected.

In addition, the side channel may include a signal capable of confirming whether the devices are connected through a cable connection detection signal, CCD (Cable Connected Detect).

The sink device 300 may include a device capable of receiving multimedia data, such as an image or audio, provided by the source device 100 and outputting it as visual and auditory information. For example, it may include a display terminal or device such as a television (TV), a monitor, and the like.

Referring to FIG. 2 , the DisplayPort 200 according to an embodiment of the present invention may include a repeater device 220 . The repeater device 220 includes a source device processor 221 and a sink device processor 222 .

The source device processor 221 may include a source controller 221a, a source signal pattern detector 221b, a source reception optical signal pattern detector 221c, and a source transmission optical signal pattern generator 221d.

The source control unit 221a may include a first state information management module 221aa.

The first state information management module 221aa synthesizes and analyzes a pattern of an electrical signal or an optical signal corresponding to a preset cable pin with respect to the repeater data comprising the electrical signal and the optical signal received by the source control unit 221a. can do. Accordingly, the first state information management module 221aa may distinguish a state transition step corresponding to a preset condition according to an incoming signal. In addition, the source control unit 221a may control the processing of the repeater data based on the divided state transition step.

In addition, the sink device processor 222 may include a sync controller 222a, a sync signal pattern detector 222b, a sync receive optical signal pattern detector 222c, and a sync transmit optical signal pattern generator 222d.

The sync control unit 222a may include a second state information management module 222aa.

The second state information management module 222aa synthesizes and analyzes the pattern of an electrical signal or optical signal corresponding to a preset cable pin with respect to the repeater data composed of the electrical signal and the optical signal received by the sync control unit 222a. can do. Accordingly, the second state information management module 222aa may distinguish a state transition step corresponding to a preset condition according to an incoming signal. In addition, the sync control unit 222a may control the processing of the repeater data based on the divided state transition stage.

The source device processor 221 transmits or receives an electrical signal to or from the source device 100 to process repeater data. The electrical signal may be transmitted through a side channel.

The side channel includes control and management signals of the main link through which video and audio data are transmitted, EDID including product information and output information of the sink device 300, HDCP enabling copyright protection of video and audio content; It may include an HPD that checks whether a device is connected or not, a CCD signal that detects whether a cable is connected, and the like.

The source control unit 221a may convert the electrical signal received from the source device 100 into an optical signal and transmit the repeater data to the sink device processor 222 .

In addition, the source control unit 221a may convert the optical signal received from the sink device processor 222 into an electrical signal to transmit the repeater data to the source device 100 .

The source signal pattern detector 221b may transmit a control and management processing signal for a connection link with the source device 100 and a connection device to the source controller 221a. The control and management processing signal is included in a side channel divided into an auxiliary channel (AUX-Channel).

Also, according to the optical signal pattern received from the sink device processor 222 , the source received optical signal pattern detector 221c may transmit matching information matching a preset pattern to the source controller 221a.

In addition, the source transmission optical signal pattern generator 221d may generate a preset optical signal pattern based on the optical signal received from the source controller 221a and transmit the optical signal to the sink device processor 222 .

The sink device processor 222 transmits or receives an electrical signal to or from the sink device 300 to process repeater data. The electrical signal may include a side channel.

The sink control unit 222a may convert the electrical signal received from the sink device 300 into an optical signal and transmit the repeater data to the source device processor 221 .

In addition, the sink control unit 222a may convert the optical signal received from the source device processor 221 into an electrical signal to transmit repeater data to the sink device 300 .

The sync signal pattern detector 222b may transmit a control and management processing signal for a connection link with the sink device 300 and a connection device to the sync controller 222a.

Also, according to the optical signal pattern received from the source device processor 221 , the sync received optical signal pattern detector 222c may transmit matching information matching a preset pattern to the sync controller 222a.

The sync transmit optical signal pattern generator 222d may generate a preset optical signal pattern based on the optical signal received from the sync controller 222a and transmit the optical signal to the source device processor 221 .

At this time, both ends of the source device processor 221 and the sink device processor 222 may be connected by at least two or more optical fiber cables, and for example, when connected by two optical fiber cables, it is said that they are connected by two optical fiber cable cores. can do. A first of the two cores corresponding to the optical fiber cable may be used as a cable 410 of an optical signal transmitter (OTX) in the source device processor 221 . In addition, as the second core, the source device processor 221 may be used as a cable 420 of an optical signal receiver (ORX). This distinction is applied in reverse to transmission and reception in terms of devices connected to the other end. For example, the cable for transmitting the optical signal from the source device processor 221 is used as the cable 410 for the optical signal receiver in the sink device processor 222 . Also, the cable for receiving the optical signal from the source device processor 221 may be connected to the cable 420 of the optical signal transmitter in the sink device processor 222 to be used.

The source signal pattern detector 221b or the sink signal pattern detector 222b may transmit/receive a side channel that is a signal generated by the source device 100 or the sink device 300, respectively. The signal of the auxiliary channel (AUX) included in the side channel is EDID (Extended Display Identification Data) containing information of the sink device 300, which is a display device such as a monitor, etc. of a source device 100 such as a Blu-ray player or a PC. , so that the output can be processed. In addition, HDCP (High-bandwidth Digital Content Protection) can be managed to protect the copyright of the content.

Electrical signals transmitted and received from the source device 100 and the source device processor 221 , and the sink device 300 and the sink device processor 222 are a connection link, a control and management signal (AUX) of the connection device, and the sink device It may include a connection confirmation signal (HPD) with the sink device processor, a cable connection confirmation signal (CCD) between the source device and the source device processor, and the like.

The electrical signal may include a Hot Plug Detect (HPD) capable of confirming whether the sink device 300 is connected to the sink device processor 222 .

The HPD (Hot Plug Detect) signal is used to request an interrupt from the sink device 300 or to detect whether the sink device 300 is connected. For example, if the signal of the HPD is not connected to the sink device, the state information is processed as 'LOW' and transmitted to the sink control unit 222a. On the other hand, when the sink device 300 is connected, the state information is processed as 'HIGH' and transmitted to the sink control unit 222a.

In addition, it may be used as a signal for confirming whether the source device 100 is connected to the source device processor 221 through Cable Connected Detect (CCD). When the source device 100 is connected to the source device processor 221 , the state information of the CCD becomes 'LOW' and is transmitted to the source controller 221a. On the other hand, when the source device 100 is not connected to the source device processor 221 , the state information of the CCD becomes 'HIGH' and is transmitted to the source controller 221a.

The source transmit optical signal pattern generator 221d or the sink transmit optical signal pattern generator 222d selects an optical signal transmission method according to an optical signal clock cycle, an unplug pattern, an idle pattern, and data ( data) pattern, etc. Through this, a transmission pattern of the repeater data can be generated by selecting one transmission method among the patterns.

The unplug pattern may be selected when a link between devices is not connected. The idle pattern may be selected when the control and management signals of the connection link and the connection device are not transmitted and received while the device-to-device link is connected. In addition, the data pattern may be selected during transmission of control and management signals of a connection link and a connection device to transmit an optical signal.

The unplug pattern is transmitted when the DisplayPort is not connected to the interface of the sink device 300 or the optical fiber cable is not connected.

According to an embodiment of the present invention, the data pattern is actual auxiliary channel (AUX) signal data transmitted by the source device 100 or the sink device 300, and is an optical signal with a specified clock period within the range of 1us to 4us. may include a method of transmitting

In addition, the idle pattern may include a method of transmitting an optical signal with a specified clock period in a range of less than 1us of the data pattern. For example, as for the idle pattern, a method of transmitting an optical signal with a clock period of 0.5us may be selected.

In addition, the unplug pattern may include a method of transmitting an optical signal with a specified clock period in a range exceeding 4us of the data pattern.

Among the above three pattern methods, an unplug pattern and an idle pattern for transmitting device state information may be determined by avoiding a period that the data pattern may have. For example, the pre-charge included in the auxiliary channel (AUX) signal data has an AUX_SYNC_END pattern having a clock cycle of 1us and a clock cycle of 4us. At this time, the source transmit optical signal pattern generator 221d or the sink transmit optical signal pattern generator 222d converts an idle pattern or an unplug pattern having a period of 1us to 4us to the sink receive optical signal pattern detector 222c ) or the source received optical signal pattern detector 221c, it may be mistaken for auxiliary channel (AUX) signal data. Therefore, an idle pattern or an unplug pattern indicating device state information may use a pattern having a period faster or slower than a transmission period of auxiliary channel (AUX) signal data.

3 is a ladder diagram for explaining a method of operating a repeater device according to an embodiment of the present invention.

Referring to FIG. 3 , in the repeater apparatus according to an embodiment of the present invention, an operation method of the source device 100 will be described as follows.

The source device 100 transmits an electrical signal that is repeater data to the source device processor 221 through the side channel (S101). Accordingly, the source device processor 221 receives the electrical signal of the source device 100 (S103). In this case, the source device processor 221 may transmit an electrical signal to the source device 100 in response to a signal requiring a response or processing signal to the received electrical signal.

The side channel is an auxiliary channel for processing so that the source device 100 such as a Blu-ray player or PC can check and output information of the sink device 300 that is a display device such as a monitor; AUX) signal. In detail, the auxiliary channel (AUX) signal may include a connection link through which video and audio data are transmitted and a control and management signal of a connection device. To this end, it may include EDID (Extended Display Identification Data) containing product information of the sink device 300 and information on output variables such as video input type, display size, power management, color characteristics, and timing information of resolution. .

In addition, the auxiliary channel (AUX) signal may include high-bandwidth digital content protection (HDCP). The HDCP is a copyright protection technology for preventing content from being illegally copied by encrypting a digital signal transmitted from an image reproducing device to a display device. This allows the use of the ability to protect the copyright of the owner and holder of the source content.

Additionally, the side channel may include a Hot Plug Detect (HPD) signal that can check whether the source device 100 and the sink device 300 are connected.

In addition, the side channel may include a signal capable of confirming whether the devices are connected through a cable connection detection signal, CCD (Cable Connected Detect).

Thereafter, with respect to the repeater data received through the step of receiving an electrical signal from the source device 100 through a side channel, the source device processor 221 requires transmission from the source device 100 to the sink device 300 . It is determined whether it is repeater data (S105).

Accordingly, the source device processor 221 converts the electrical signal received from the source device 100 into an optical signal with respect to the repeater data that needs to be transmitted to the sink device 300 ( S107 ).

The source device processor 221 transmits the repeater data converted into an optical signal to the sink device processor 222 (S109).

In addition, the sink device processor 222 receives the repeater data converted into an optical signal by the source device processor 221 ( S111 ).

The sink device processor 222 checks the pattern of the received repeater data optical signal and converts it into an electrical signal (S113).

Thereafter, the sink device processor 222 transmits the repeater data converted into an electrical signal to the sink device 300 (S115).

The step of the source device processor 221 receiving the electrical signal of the source device 100 may include, when the electrical signal received from the source device 100 is control and management signal data of a connection link and a connection device, the The source device processor 221 may further include detecting the start and completion of transmission of the control and management signals of the connection link and the connection device.

In addition, the step of the source device processor 221 converting the electrical signal received from the source device 100 into an optical signal and transmitting the repeater data to the sink device processor 222 includes, based on the converted optical signal, a preset The method may further include generating an optical signal pattern according to the pattern information.

In addition, an operation method of the repeater apparatus based on the sink device 300 will be described as follows.

The sink device 300 transmits an electrical signal that is repeater data to the sink device processor 222 through a side channel (S117).

The sink device processor 222 receives the electrical signal of the sink device 300 (S119). In this case, the sink device processor 222 may transmit an electrical signal to the sink device 300 in response to a signal requesting a response or processing signal to the received electrical signal.

Thereafter, with respect to the repeater data received through the step of receiving an electrical signal through a side channel from the sink device 300 , the sink device processor 222 requires transmission from the sink device 300 to the source device 100 . It is determined whether it is repeater data (S121).

Accordingly, the sink device processor 222 converts the electrical signal received from the sink device 300 into an optical signal with respect to the repeater data that needs to be transmitted to the source device 100 ( S123 ).

The sink device processor 222 transmits the repeater data converted into an optical signal to the source device processor 221 (S125).

In addition, the source device processor 221 receives the repeater data converted into an optical signal by the sink device processor 222 (S127).

The source device processor 221 checks the pattern of the received repeater data optical signal and converts it into an electrical signal (S129).

Thereafter, the source device processor 221 transmits the repeater data converted into an electrical signal to the source device 100 ( S131 ).

The step of the sink device processor 222 receiving the electrical signal of the sink device 300 may include, when the electrical signal received from the sink device 300 is a control and management signal of a connection link and a connection device, the sink The device processor 222 may further include the step of detecting the start and completion of transmission of the control and management signals of the connection link and the connection device.

In addition, the step of the sink device processor 222 converting the electrical signal received from the sink device 300 into an optical signal and transmitting the repeater data to the source device processor 221 includes, based on the converted optical signal, a preset The method may further include generating an optical signal pattern according to the pattern information.

The source device processor 221 and the sink device processor 222 may be connected to each other by at least two or more optical fiber cable cores, and a data transmission path for each core may be unidirectional.

4 is a flowchart illustrating data signal processing through a source device processor of a repeater apparatus according to an embodiment of the present invention.

Referring to FIG. 4 , step-by-step data signal processing in the source device processor 221 of the repeater apparatus according to an embodiment of the present invention can be viewed in detail. In an embodiment of the present invention, the step of transmitting to the source device may be divided as follows.

In the first optical unplug (OPTICAL UNPLUG) state transition step S201 , the source device processor 221 is not connected to the source device 100 or the sink device 300 . When a call is not received, the signal can be processed as follows.

The source controller 221a processes the HPD as a 'LOW' state in which the sink device 300 is not connected. In addition, the source control unit 221a generates an optical signal of an unplug pattern having a clock period of 20 us or more through the source transmission optical signal pattern generator 221d and transmits it to the sink device processor 222 . .

At this time, the source control unit 221a determines whether an optical signal is input to the source device processor 221 ( S203 ).

When an optical signal is input to the source device processor 221 , the first source unplugging (SOURCE UNPLUG) state transition step S205 is switched to, and in a state in which the source device 100 and the sink device 300 are not connected The signal can be processed as follows.

The source control unit 221a processes the HPD in a 'LOW' state in which the sink device 300 is not connected and transmits an optical signal of an unplug pattern having a clock period of 20 us or more to the sink device processor ( 222) is sent.

In this case, the source control unit 221a determines whether the source device 100 is connected to the source device processor 221 ( S207 ).

When the source device 100 is connected to the source device processor 221 , a first SINK UNPLUG state transition step S209 may be performed to process a signal as follows.

The source controller 221a switches the CCD from 'HIGH' to 'LOW' and transmits an optical signal of an idle pattern having a clock period within a range of 10ns to 90ns to the sink device processor 222 . send to In addition, the source control unit 221a may include a state of receiving the optical signal of an unplug pattern transmitted from the sink device processor 222 .

At this time, the source control unit 221a determines whether the sink device 300 is connected to the sink device processor 222 ( S211 ).

When the sink device 300 is connected to the sink device processor 222 , the first idle state transition step S213 may be performed to process a signal as follows.

In the first SINK UNPLUG state transition step, an optical signal of an idle pattern having a clock period within a range of 10 ns to 90 ns is transmitted from the sink device processor 222 to the source device processor 221 . ), the source control unit 221a determines that the sink device 300 is connected, switches the HPD from 'LOW' to 'HIGH', and performs control and management signal transactions of the connection link and the connection device. wait for you to

In this case, the source control unit 221a determines whether the source device processor 221 receives the control and management signals of the connection link of the source device 100 and the connection apparatus (S215).

When the source device processor 221 receives the connection link of the source device 100 and the control and management signal of the connection device, the signal is converted to a first SEND state transition step S217 and the signal is transmitted as follows. can be processed

The source control unit 221a converts the control and management signals of the connection link and the connection device received from the source device 100 into optical signals and transmits them to the sink device processor 222 .

At this time, the source device processor 221 determines whether the control and management signal transmission of the connection link and the connection device in the source device 100 is completed (S219).

When the control and management signal transmission of the connection link from the source device 100 and the connection device is completed, the first WAIT state transition step S221 may be performed to process the signal as follows.

The source control unit 221a determines that the control and management signal transmission of the connection link and the connection device is completed, and waits to receive data from the sink device processor 222 . The source controller 221a transmits to the sink device processor 222 an optical signal having an idle pattern having a clock period within a range of 10 ns to 90 ns.

At this time, the source control unit 221a determines whether the control and management signals of the connection link and the connection device are transmitted from the sink device processor 222 (S223).

When the source control unit 221a receives the control and management signal of the connection link and the connection device from the sink device processor 222, it switches to the first reception (RECV) state transition step S225 and transmits the signal as follows. can be processed

It is determined whether the control and management signals of the connection link and the connection device are received from the sink device processor 222 to the source control unit 221a (S227), and the received control and management signal signals of the connection link and the connection device are transmitted to the source device ( 100) is sent.

5 is a flowchart illustrating data signal processing through a sink device processor of a repeater apparatus according to an embodiment of the present invention.

Referring to FIG. 5 , step-by-step data signal processing in the sink device processor 222 of the repeater apparatus according to an embodiment of the present invention can be viewed in detail. In an embodiment of the present invention, the step of transmitting to the sink device may be divided as follows.

A case in which an optical signal is not received from the source device processor 221 while the sink device 300 is not connected to the sink device processor 222 may be processed as follows.

In the second optical unplug (OPTICAL UNPLUG) state transition step (S301), in a state in which an optical signal is not received from the source device processor 221, the sync control unit 222a performs the sync transmission optical signal pattern generator 222d for more than 20us. An optical signal of an unplug pattern having a clock cycle is transmitted to the source device processor 221 .

At this time, the sync controller 222a determines whether an optical signal is input to the sync device processor 222 (S303).

When an optical signal is input to the sink device processor 222 , the sync controller 222a may switch to a second SINK UNPLUG state transition step S305 to process the signal as follows.

In a state in which the sink device 300 is not connected, the sync control unit 222a transmits an optical signal of an unplug pattern having a clock period of 20 us or more to the source through the sync transmission optical signal pattern generator 222d. It is transmitted to the device processor 221 .

At this time, the sink control unit 222a determines whether the sink device 300 is connected (S307).

When the sink device 300 is connected to the sink controller 222a, the second source unplugged (SOURCE UNPLUG) state transition step S309 may be switched to process a signal as follows.

The sync controller 222a monitors a connection state between the source device 100 and the source device processor 211 while receiving an unplug pattern signal from the source device processor 221 . In parallel with this, the sync control unit 222a generates an optical signal of an idle pattern having a clock period within the range of 10 ns to 90 ns through the sync transmission optical signal pattern generator 222d to generate the source device. It is transmitted to the processor 221 .

At this time, it is determined whether an optical signal of an idle pattern is received from the source device processor 221 through the sink reception optical signal pattern detector 222c of the sink device processor 222 ( S311 ).

When receiving an idle pattern optical signal from the source device processor 221 through the sink reception optical signal pattern detector 222c of the sink device processor 222 , the sink controller 222a controls the source device 100 ) is considered to be connected.

Through this, the second idle state transition step ( S313 ) is switched to, and the signal can be processed as follows.

The sink control unit 222a waits to receive the control and management signals of the connection link and the connection device transmitted from the source device processor 221 .

In this case, the sync control unit 222a determines whether to receive a control and management signal of a connection link and a connection device transmitted from the source device processor 221 (S315).

When the sync control unit 222a receives the control and management signal of the connection link and the connection device transmitted from the source device processor 221, it is switched to a second reception (RECV) state transition step S317 as follows. signal can be processed.

The sink control unit 222a converts the control and management signals of the connection link and the connection device received from the source device 100 into electrical signals and transmits them to the sink device 300 . In addition, the sync controller 222a transmits an optical signal having an idle pattern having a clock period within a range of 10 ns to 90 ns to the source device processor 221 .

In this case, in the second reception (RECV) state transition step, it is determined whether the transmission of the control and management signals of the connection link received from the source device and the connection device is terminated ( S319 ).

When it is determined that the transmission of the control and management signals of the connection link and the connection device has been completed by receiving the optical signal of the idle pattern from the source device processor 221, a second WAIT state transition step (S321) , and the signal can be processed as follows.

The sink control unit 222a is switched to a standby state capable of receiving the data signal of the sink device 300 . In addition, the sync control unit 222a generates an optical signal having an idle pattern having a clock period within a range of 10 ns to 90 ns through the sync transmit optical signal pattern generator 222d to generate an optical signal for the source device processor 221 . ) is sent to

At this time, the sync controller 222a determines whether a connection link and a control and management signal of the connection device are received from the sink device 300 (S323).

When the sync control unit 222a receives the control and management signal of the connection link and the connection device from the sink device 300, it switches to the second transmission (SEND) state transition step S325 and transmits the signal as follows. can be processed

The sync control unit 222a converts the control and management signals of the connection link and the connection device received as electrical signals into optical signals and transmits them to the sync transmission optical signal pattern generator 222d. In addition, the sync control unit 222a converts an optical signal having a data pattern having a clock period within a range of 1us to 4us through the sync transmission optical signal pattern generator 222d, and converts it into an optical signal, and the source device processor (221).

Through this, the sync control unit 222a determines whether the control and management signal transmission of the connection link and the connection device has been completed ( S327 ), and the data signal is normally processed.

6 is a diagram for distinguishing the types of signal patterns that can be confirmed by the source signal pattern detector and the sink signal pattern detector of the repeater device according to an embodiment of the present invention.

Referring to FIG. 6 , a connection link and a connection device control and management signal transmission process in the source signal pattern detector 221b and the sink device processor 222b of the repeater device according to an embodiment of the present invention can be viewed in detail.

When starting the connection link of the auxiliary channel (AUX) and the control and management signal transmission of the connection device from the source device 100 or the sink device 300 to the source signal pattern detector 221b or the sink signal pattern detector 222b, respectively, Before actual data transmission, a SYNC pattern that can confirm that it is valid data is transmitted.

The SYNC pattern may be composed of three patterns: Pre-Charge, Pre-amble, and AUX_SYNC_END pattern.

An initial pre-charge signal is transmitted from the source device 100 or the sink device 300 to the source signal pattern detector 221b or the sink signal pattern detector 222b, respectively.

The pre-charge signal may be transmitted 10 to 16 times in a clock pattern of 1 us.

Thereafter, the source device 100 or the sink device 300 transmits a pre-amble signal to the source signal pattern detector 221b or the sink signal pattern detector 222b, respectively.

The pre-amble signal may be transmitted 16 times in a clock pattern of 1 us.

Then, the AUX_SYNC_END pattern signal is transmitted from the source device 100 or the sink device 300 to the source signal pattern detector 221b or the sink signal pattern detector 222b, respectively. The AUX_SYNC_END pattern signal may have a clock pattern having a period of 4us.

When the SYNC pattern is transmitted, the actual connection link and control and management signal data of the connection device are transmitted through Manchester coding, and then the AUX_SYNC_END pattern is transmitted.

Based on the auxiliary channel (AUX) signal transmission process, the source signal pattern detector 221b or the sink signal pattern detector 222b detects the transmission start and transmission completion signals of the control and management signals of the connection link and the connection device, It can be transmitted to the control unit 221a or the sync control unit 222a.

The source signal pattern detector 221b or the sink signal pattern detector 222b determines the start of transmission of control and management signal data of the connection link and the connection device through the pre-charge signal. The source signal pattern detector 221b or the sink signal pattern detector 222b counts the retention time of data when data starts to come from the AUX pin. The counting of the holding time ends when data is changed from 'HIGH' to 'LOW' or from 'LOW' to 'HIGH'. Also, when the retention time of data is 400 ~ 600ns, it can be called pre-charge. When the data coming in through the AUX pin is confirmed three or more times as pre-charge, the source signal pattern detector 221b or the sink signal pattern detector 222b starts the transmission of control and management signal data of the connection link and the connected device. It is transmitted to the source control unit 221a or the sink control unit 222a, respectively.

When the control and management signal data transmission of the connection link and the connection device is completed in the source device 100 or the sink device 300, the AUX_SYNC_END pattern is sent to the source signal pattern detector 221b or the sink signal pattern detector 222b, respectively, and the last data will be maintained The AUX_SYNC_END pattern is a clock pattern with a period of 4us. This may be included in a data pattern that is an optical signal having a clock cycle within the range of 1us to 4us. Through this, the source signal pattern detector 221b or the sink signal pattern detector 222b may check the completion of transmission of control and management signal data of the connection link and the connection device. When counting the data retention time, if the data retention time is longer than the AUX_SYNC_END pattern, the source control unit 221a or the sink control unit 222a transmits a signal for determining that the control and management signal data transmission of the connection link and the connection device is complete. pass it on to

7 is a diagram for explaining the shape of a pattern of an optical signal generated by an optical signal pattern generator of a repeater device according to an embodiment of the present invention.

Referring to FIG. 7 , a pattern of an optical signal generated by an optical signal pattern generator of a repeater device according to an embodiment of the present invention can be viewed.

The source transmit optical signal pattern generator 221d or the sync transmit optical signal pattern generator 222d determines the state according to the processed side channel signal, the sink receive optical signal pattern detector 222c and the source receive optical signal pattern detector 222c connected to the other end, respectively. 221c). In this case, the source transmit optical signal pattern generator 221d or the sink transmit optical signal pattern generator 222d may form three patterns to provide an optical signal.

The source transmit optical signal pattern generator 221d or the sink transmit optical signal pattern generator 222d selects an optical signal transmission method according to an optical signal clock cycle, an unplug pattern, an idle pattern, and data ( data) pattern.

The unplug pattern may be selected when a link between devices is not connected. The idle pattern may be selected when the control and management signals of the connection link and the connection device are not transmitted and received while the device-to-device link is connected. In addition, the data pattern may be selected during transmission of control and management signals of a connection link and a connection device to transmit an optical signal.

The unplug pattern is transmitted when the DisplayPort is not connected to the interface of the sink device 300 or the optical fiber cable is not connected. As an embodiment of the present invention, the unplug pattern may include a method of transmitting an optical signal with a clock period of 20 us or more. Also, the idle pattern may include a method of transmitting an optical signal in a clock cycle within a range of 10 to 90 ns. The idle pattern may indicate a state in which an auxiliary channel (AUX) signal is not transmitted. And the data pattern is the actual auxiliary channel (AUX) signal data transmitted by the source device 100 or the sink device 300, and includes a method of transmitting an optical signal in a clock cycle within the range of 1us to 4us. can do.

In the above, preferred embodiments of the present invention have been illustrated and described, but the present invention is not limited to the specific embodiments described above, and it is common in the technical field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Various modifications may be made by those having the knowledge of, of course, and these modifications should not be individually understood from the technical spirit or perspective of the present invention.

100. Source Device 200. DisplayPort
210. Main link handler 220. Repeater device
221. Source Device Handler 222. Sink Device Handler
300. Sink Device

Claims (4)

A source device includes a source device processor and a sink device includes a sink device processor, and a computer can execute a method for transmitting and receiving side channel repeater data of DisplayPort using an optical signal between the source device processor and the sink device processor. As a recording medium on which a program is recorded,
The source device processor and the sink device processor,
when the power is turned on, transmitting an optical unplug pattern to a counterpart processor based on whether an optical signal is received;
transmitting a device unplug pattern for a connection state with a device to a counterpart processor in a state in which the optical signal is normally received;
receiving the device unplug pattern transmitted from the counterpart processor, detecting whether the counterpart device is connected, controlling the HDP signal, and waiting until the device is connected;
transmitting an idle pattern to a counterpart processor and waiting for AUX data reception from the device when the source device and the sink device are connected by the device unplug pattern detection;
when the AUX data is received from the device, transmitting the AUX data to a counterpart processor based on a preset data pattern;
when the AUX data transmission is completed, transmitting an idle pattern and waiting for AUX data reception from a counterpart processor;
when AUX data is received from a counterpart processor, transmitting the AUX data to a corresponding device; containing
A recording medium on which a program that can execute the display port side channel repeater data transmission/reception method on a computer is recorded.
The method of claim 1,
The source device processor,
Further comprising returning a CCD (Cable Connected Detect) signal to the source device so that the source device can check whether the cable is connected
A recording medium on which a program that can execute the display port side channel repeater data transmission/reception method on a computer is recorded.
The method of claim 1,
The optical signal exchanged between the processors includes at least one of a control and management signal of a connection link and a connection device, a connection confirmation signal between the device and the device processor, and an optical cable connection confirmation signal between the processors
A recording medium on which a program that can execute the display port side channel repeater data transmission/reception method on a computer is recorded.
The method of claim 1,
The cable connection state (unplug), the transmission state (idle), and the AUX data (data) are encoded and transmitted into one optical signal based on preset clock signal patterns of different frequencies,
The received optical signal is converted into an electrical signal to detect the pattern of the received signal, the cable connection state (unplug), the transmission state (idle), and the AUX data (data) are detected, and the HDP signal and AUX data are sent to the corresponding device. to convey
A recording medium on which a program that can execute the display port side channel repeater data transmission/reception method on a computer is recorded.

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