KR20080007928A - Video apparatus for transceiving a/v signal and control signal and optical communication method thereof - Google Patents

Abstract

A video apparatus for transceiving a video signal and a control signal through an optical cable and an optical communication method thereof are provided to reduce installation costs by reducing the number of necessary cables, simply connect video devices and stably communicate with video apparatus at a distant place due to transferring data through optical cable. An optical interface(130) transmits a video signal of a first format to an external device, receives a video signal of a second format from the external device through one optical cable(300), and transceives a control signal with the external device(200). A function block(110) provides the video signal of the first format which will be transmitted to the external device through the optical interface, and receives the video signal of the second format received from the external device through the optical interface. A controller(120) generates the control signal which will be transmitted to the external device through the optical interface, and receives a control signal received from the external device through the optical interface.

Description

Image apparatus for transmitting / receiving video signal and control signal through optical cable and optical communication method thereof {Video apparatus for transceiving A / V signal and control signal and optical communication method

1 is a diagram illustrating a DTV and a PVR performing communication through three cables according to the prior art, and

2 is a diagram illustrating a DTV and a PVR which optically communicate a video signal and a control signal through one optical cable according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

100: DTV 110: DTV Function Block

120: DTV control unit 130: DTV optical-interface

200: PVR 210: PVR Function Block

220: PVR control unit 230: PVR optical interface

300: optical cable

The present invention relates to an image device and an optical communication method thereof, and more particularly, to an image device and an optical communication method thereof for transmitting and receiving an image signal and a control signal through an optical cable.

1 is a diagram illustrating a DTV and a PVR performing communication through a cable according to the prior art. As shown in FIG. 1, the DTV 10 and the PVR 20 perform communication through three cables 31, 32, and 33.

Specifically, the DTV 10 transmits the MPEG-TS to the PVR 20 through the first cable 31, and the PVR 20 transmits the image of the HDMI format to the DTV 10 through the third cable 33. Send the signal. Further, the control signal is transmitted and received between the DTV 10 and the PVR 20 through the second cable 32. At this time, the control signal used is a control signal of the RS-232C interface format.

As shown in FIG. 1, since the DTV 10 and the PVR 20 need to be connected with three cables to transmit and receive the video signal and the control signal, the connection is very complicated. This can be a major inconvenience and confusion for end users who are ignorant of cable connections.

In addition, when the distance between the DTV 10 and the PVR 20 is far apart, a problem arises in that the cost of the cable required to connect both is greatly increased. In addition, there are distance limitations in the case of electrical cables that can carry signals. In other words, if the distance is far away, the signal transmission through the electrical cable is inadequate.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a video device and an optical communication method for transmitting and receiving video signals and control signals through one optical cable.

According to the present invention for achieving the above object, a video device, through a single optical cable, transmits the video signal of the first format to the external device, and receives the video signal of the second format from the external device, An optical interface for transmitting and receiving a control signal; A function block for providing a video signal of a first format to be transmitted to the external device through the optical interface and receiving a video signal of a second format received from the external device through the optical interface; And a controller configured to generate a control signal to be transmitted to the external device through the optical interface and to receive a control signal received from the external device through the optical interface.

The optical-interface is configured to transmit at least one of an image signal of the first format and a control signal generated by the controller to the external device through the optical cable, from the external device through the optical cable. Preferably, at least one of a video signal of a format and a control signal generated by the external device is received.

The first format and the second format may be any one of an MPEG format and an HDMI (High Definition Multimedia Interface) format, and the format of the control signal may be an RS-232C interface format.

The video signal of the second format received from the external device may be stored or displayed through the optical interface.

On the other hand, according to the present invention, an optical communication method of a video device, transmitting a video signal and a first control signal of a first format to an external device through one optical cable; And receiving a video signal and a second control signal of a second format from the external device through the optical cable.

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

2 is a diagram illustrating a digital TV (DTV) and a personal video recorder (PVR) according to an embodiment of the present invention. The illustrated DTV 100 and the PVR 200 are connected by one optical cable 300, and perform optical communication with each other through the connected optical cable 300.

As shown in FIG. 2, the DTV 100 includes a DTV function block 110, a DTV control unit 120, and a DTV light-interface 130.

The DTV function block 110 performs an inherent function of the DTV 100 under the control of the DTV controller 120 to be described later. That is, the DTV function block 110 receives and displays an image.

The image that can be displayed by the DTV function block 110 includes not only an image received from a broadcasting station through wire or wireless, but also an image received from the PVR 200 through the DTV light-interface 130 to be described later. In addition, the DTV function block 110 may transmit the image secured by the DTV function block to the PVR 200 through the DTV optical interface 130.

The DTV control unit 120 controls the operation of the DTV function block 110 and the DTV light-interface 130. In addition, the DTV controller 120 may transmit a control signal to the PVR 200 through the DTV optical interface 130 to control the operation of the PVR 200 or to request specific information or an image from the PVR 200. have.

In addition, the DTV controller 120 may receive a control signal from the PVR 200 through the optical-interface 130 to be controlled by the PVR 200 or to receive specific information or an image from the PVR 200.

The DTV optical interface 130 is connected to the PVR 200 through one optical cable 300 to perform optical communication. Specifically, the DTV optical-interface 130 converts the video signal received from the DTV function block 110 or the control signal received from the DTV control unit 120 into an optical signal to the PVR 200 through the optical cable 300. send.

In addition, the DTV optical interface 130 transmits the image signal and the control signal restored from the optical signal received from the PVR 200 through the optical cable 300 to the DTV function block 110 and the DTV controller 120, respectively. .

2, the PVR 200 includes a PVR function block 210, a PVR controller 220, and a PVR optical-interface 230.

The PVR function block 210 performs the original function of the PVR 200 under the control of the PVR controller 220 which will be described later. That is, the PVR function block 210 stores the received image on the recording medium or reproduces the image stored on the recording medium.

In particular, the PVR function block 210 may not only store an image received from the DTV 100 through the PVR optical interface 230, which will be described later, but also display the image reproduced from the recording medium. It may be transmitted to the DTV 100 through.

The PVR controller 220 controls the operation of the PVR function block 210 and the PVR optical interface 230. In addition, the PVR controller 220 may transmit a control signal to the DTV 100 through the optical interface 230 to control the operation of the DTV 100 or to request specific information or an image from the DTV 100. .

In addition, the PVR controller 220 may receive a control signal from the DTV 100 through the optical-interface 230 and may be controlled by the DTV 100 or request specific information or an image from the DTV 100.

The PVR optical-interface 230 is connected to the DTV 100 through one optical cable 300 to perform optical communication. In detail, the PVR optical interface 230 converts the image signal received from the PVR function block 210 or the control signal received from the PVR controller 220 into an optical signal to the DTV 100 through the optical cable 300. send.

In addition, the PVR optical interface 230 transmits the image signal and the control signal restored from the optical signal received from the DTV 100 through the optical cable 300 to the PVR function block 210 and the PVR controller 220, respectively. .

Hereinafter, optical communication performed by the DTV 100 and the PVR 200 shown in FIG. 2 will be described in detail.

First, MPEG-TS can be delivered from the DTV 100 to the PVR 200. Specifically, the MPEG-TS provided by the DTV function block 110 is converted into an optical signal in the DTV optical interface 130 and transmitted to the PVR optical interface 230 through the optical cable 300. Thereafter, when the PVR optical-interface 230 restores the received optical signal to MPEG-TS and transmits the received optical signal to the PVR functional block 210, the PVR functional block 210 stores it.

Secondly, an image signal of a high definition multimedia interface (HDMI) format may be transmitted from the PVR 200 to the DTV 100. Specifically, the video signal of the HDMI format reproduced by the PVR function block 210 is converted into an optical signal in the PVR optical interface 230 and transmitted to the DTV optical interface 130 through the optical cable 300. Thereafter, when the DTV optical interface 130 restores the received optical signal to an image signal of an HDMI format and transmits the received optical signal to the DTV functional block 110, the DTV functional block 110 displays the same.

Third, the control signal of the RS-232C interface format can be transferred from the DTV 100 to the PVR 200. In detail, the control signal generated by the DTV control unit 120 is converted into an optical signal at the DTV optical interface 130 and transmitted to the PVR optical interface 230 through the optical cable 300. Thereafter, when the PVR optical-interface 230 restores the received optical signal to a control signal and transmits the received optical signal to the PVR controller 220, the PVR controller 220 operates the PVR function block 210 according to the received control signal. To control.

Fourth, the control signal of the RS-232C interface format can be transmitted from the PVR 200 to the DTV 100. In detail, the RS-232C control signal generated by the PVR controller 220 is converted into an optical signal by the PVR optical interface 230 and transmitted to the DTV optical interface 130 through the optical cable 300. Subsequently, when the DTV optical interface 130 restores the received optical signal to the RS-232C control signal and transmits the received optical signal to the DTV control unit 120, the DTV control unit 120 performs the DTV function according to the received RS-232C control signal. Control operation of block 110.

On the other hand, since the bandwidth of the optical cable is wide enough, the four optical communications listed so far may be performed simultaneously. That is, while the MPEG-TS and RS-232C control signals are transmitted from the DTV 100 to the PVR 200, the video signals of the HDMI format and the RS-232C control signals are transmitted from the PVR 200 to the DTV 100. Can be.

In the present embodiment, the DTV and the PVR have been described as examples, but this is merely an example for convenience of description. Therefore, the present invention can be applied to other video devices other than DTV and PVR.

As described above, according to the present invention, it is possible to transmit and receive between video devices in both directions simultaneously with the video signal and the control signal through one optical cable. As a result, the number of cables required can be reduced, thereby reducing equipment costs, and the video devices can be connected in a simpler way. In addition, since data is transmitted and received using an optical cable, stable communication is possible even between video devices having a long distance.

In addition, although the preferred embodiment of the present invention has been shown and described above, the present invention is not limited to the specific embodiments described above, but the technical field to which the invention belongs without departing from the spirit of the invention claimed in the claims. Of course, various modifications can be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or the prospect of the present invention.

Claims (5)

An optical interface for transmitting an image signal of a first format to an external device, receiving an image signal of a second format from the external device, and transmitting and receiving a control signal with the external device through one optical cable; A function block for providing a video signal of a first format to be transmitted to the external device through the optical interface and receiving a video signal of a second format received from the external device through the optical interface; And And a controller configured to generate a control signal to be transmitted to the external device through the optical interface and to receive a control signal received from the external device through the optical interface. The method of claim 1, The optical-interface, While transmitting at least one of the video signal of the first format and the control signal generated by the controller through the optical cable, the video signal of the second format and the external device from the external device via the optical cable. And at least one of the control signals generated by the controller. The method of claim 1, The first format and the second format is any one of an MPEG format and a High Definition Multimedia Interface (HDMI) format. And the format of the control signal is an RS-232C interface format. The method of claim 1, The function block, And store or display the video signal of the second format received from the external device through the optical interface. Transmitting an image signal and a first control signal of a first format to an external device through one optical cable; And And receiving a video signal and a second control signal of a second format from the external device through the optical cable.

Images