KR101254408B1 - By-directional cec system of 60ghz frequency band - Google Patents

Abstract

The present invention relates to a 60 GHZ frequency band bidirectional CEC system for providing high definition multimedia interface-consumer electronics control (HDMI-CEC) bidirectional communication in a 60 GHz frequency band high-definition video transmission system.
The bidirectional CEC system of the 60 GHZ frequency band according to the present invention is a CEC (Consumer Electronics Control) system for transmitting an image using the 60 GHZ frequency band, each of which includes an image device including a source device 200 and a sink device 300 and HDMI. An HDMI port 120 for performing communication; Is connected to the HDMI port 120 and the CEC line, and performs the HDMI-CEC bidirectional communication with the source device 200 and the sink device 300 to determine the state of the source device 200 and the sink device 300 And a main controller 110 for controlling and controlling the other video device according to the state of one video device.

Description

Bi-directional ECC system with 60Hz frequency band {BY-DIRECTIONAL CEC SYSTEM OF 60GHZ FREQUENCY BAND}

The present invention relates to a bidirectional CEC system of the 60GHZ frequency band, and more particularly to a bidirectional CEC system of the 60GHZ frequency band to provide HDMI-CEC (High Definition Multimedia Interface-Consumer Electronics Control) bidirectional communication in a high-definition video transmission system of the 60GHZ frequency band. It is about.

The 60 GHz millimeter wave frequency band is a frequency band of 57 to 64 GHz (7 GHz wide), which is classified as 'FACS', a new frequency range that is divided into unlicensed bands that can be used without permission from radio stations. The millimeter wave band can achieve data rates of 3 to 5 Gbps using ultra-wide bands, and it has strong technical characteristics due to its strong straightness, high resistance to surrounding interference, high security, and easy frequency reuse. In addition, since the wavelength is short, various devices can be miniaturized and reduced in weight, and thus, as an optimal frequency band for high-speed wireless communication, it is recognized as the latest technology field suitable for supporting a recent home network and high-definition multimedia transmission and application service.

In order to transmit high definition (HD) -class high-definition video, which is the mainstream of the video market, by using existing wireless LAN (WLAN) or ultra-wideband (UWB) communication, it is necessary to transmit compared to the data size of the video. Speed is an issue, so you must compress and transfer the image and restore it to reproduce the transmitted image. At this time, if there are many changes between frames, image deterioration or crushing phenomenon occurs, which is an important dissatisfaction factor for consumers who are not satisfied with the expectation of high quality images. Currently, the transmission of full HD content uses a high definition multimedia interface (HDMI) (hereinafter, abbreviated as HDMI), which is mainly a wired interface method, and UWB technology for transmitting full HD content wirelessly. However, since data transmission speed is only 480Mbps at a short distance within 10m, it is difficult to realize high quality due to a problem caused by compression transmission.

On the other hand, in the 60GHz millimeter frequency band, it achieves a transmission speed of 3Gbps which is at least 6 times higher than that of the existing technology, and it is possible to transmit high-definition and high-definition screens without any compression technology when transmitting full HD quality high-definition screen. If full HD quality high-definition transmission technology is applied to general data transmission of portable multimedia device, it takes about 1 hour and 30 minutes to download one CD with 650MB capacity when using Bluetooth technology that is widely used. High speed communication is enough to download in 1-2 seconds. Therefore, 60GHz wireless transmission technology is an optimal frequency band for high-speed wireless personal area network (PAN) and is recently recognized as an optimal technology for supporting high-definition multimedia transmission and application services of home networks and indoor wireless PANs.

In today's homes and offices, HDMI wired cables are often used to transfer high-definition video between devices. To connect many video devices in homes and offices to high-definition video output devices at some distance, you need to use a relatively thick HDMI cable, which is both visually uncomfortable and inconvenient in connectivity. . The final goal of the home theater market is to increase consumer dignity by connecting all devices wirelessly except power, while maintaining the high quality and high sound quality. Therefore, the development of high-definition wireless video transmission technology is currently required in the home appliance and video market.

On the other hand, in a CEC (Consumer Electronics Control) system that transmits a high-definition image using the 60GHZ frequency band, an image device, that is, a source device and a sink device, is provided to enable only one-way communication. That is, data can be transmitted from the source device to the sink device, but conversely, data transmission from the sink device to the source device is impossible. Therefore, in the CEC system supporting only one-way communication, there is a problem in that it is impossible to perform a function of controlling the state of the source device according to the state of the sink device.

The present invention has been proposed to solve the problems of the conventional unidirectional CEC system, and an object of the present invention is to support two-way communication of the CEC system to control the other video device according to the state of the sink device and the source device. To provide a bidirectional CEC system in the 60GHZ frequency band.

The bidirectional CEC system of the 60GHZ frequency band according to the present invention for achieving the above object is a CEC (Consumer Electronics Control) system for transmitting an image using the 60GHZ frequency band, the video device consisting of a source device and a sink device and each HDMI An HDMI port for performing communication; And a main controller connected to the HDMI port through a CEC line to perform HDMI-CEC bidirectional communication with the source device and the sink device to identify and control the states of the source device and the sink device.

The main controller transmits a message requesting a power state to the source device or the sink device, and receives a response message indicating the power state from the source device or the sink device to determine the power state of the source device or the sink device.

Here, the main controller detects the power states of the source device and the sink device, and when the power of one video device to be determined is turned off, transmits a message to the other video device to turn off the power of the other video device. It will change the power state.

The main controller transmits a message for turning on the power of the other video device to the other video device when the power of one video device is turned on while the source device and the sink device are both turned off. Will change.

The bidirectional CEC system of the 60GHZ frequency band according to the present invention supports bidirectional communication, and thus, it is possible to control the other video device according to the state of the sink device or the source device. That is, when the power of the sink device or the source device is turned off, unnecessary power loss can be prevented by turning off the power of the video device located on the other side by grasping the power of the sink device or the source device. When the power of the video device is turned on, by turning on the power of the other video device, there is an effect of eliminating the inconvenience that the user has to manually turn on the power of the other video device.

1 is a network connection diagram of a bidirectional CEC system of a 60GHZ frequency band according to the present invention;
2 is a flowchart illustrating a process of controlling a power state of another video device according to a power state of one video device according to an embodiment of the present invention;
3 is a flowchart illustrating a process of controlling a power state of another video device according to a power state of one video device according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a network connection diagram of a bidirectional CEC system in a 60GHZ frequency band according to an embodiment of the present invention.

As shown in FIG. 1, the bidirectional CEC system 100 of the 60GHZ frequency band according to the present invention is installed between a sink device 300, which is an imaging device, and a source device 200 to perform bidirectional communication. Control) system.

The bidirectional CEC system 100 includes a main controller 110 for relaying and controlling the communication between the sink device 300 and the source device 200. The bidirectional CEC system 100 includes an HDMI ( (High Definition Multimedia Interface) port 120 is connected to the source device 200 and the sink device 300, respectively, to perform communication.

The main controller 110 provided in the bidirectional CEC system 100 directly accesses the power states of the sink device 300 and the source device 200 through the CEC line. That is, the main controller 110 transmits and receives data through the sink device 300 or the source device 200 (hereinafter, collectively referred to as "video device") and the HDMI-CEC communication line.

The main controller 110 transmits a POWER_STATUS_REQUEST message to the video device through the HDMI-CEC to determine the power state of the video device. When the transmitted POWER_STATUS_REQUEST reaches the target video device, the video device responds to the main controller 110 with a POWER_STATUS_RESPONSE message including a Power Status operand, which is preferably transmitted when the power state of the video device changes. .

The main controller 110 controls to turn on the power to the other video device when power is applied to any one of the video device of the source device 200 or the sink device 300 that is turned off. do. In addition, if one video device is powered off by the power off button while both video devices are powered on, the power of the video device is turned off by sending a POWER_STATUS_REQUEST [OFF] message to the other video device. To control.

2 is a flowchart illustrating a process of controlling a power state of another video device according to a power state of one video device according to an embodiment of the present invention.

As shown in FIG. 2, when the power of one video device (TV) is turned off, the main controller 110 of the bidirectional CEC system 100 transmits a POWER_STATUS_REQUEST message to the other video device (Divice). The other video device responds to the main controller 110 of the bidirectional CEC system 100 with a POWER_STATUS_RESPONSE [ON] message indicating that the power is on. Through the POWER_STATUS_RESPONSE [ON] message, the main controller 110 of the bidirectional CEC system 100 confirming that the power of the other video device is turned on transmits a POWER_STATUS_REQUEST [OFF] message to the corresponding video device. To control the power off.

3 is a flowchart illustrating a process of controlling a power state of another video device according to a power state of one video device according to another embodiment of the present invention.

As shown in FIG. 3, when the power of one video device (TV) is turned on, the main controller 110 of the bidirectional CEC system 100 transmits a POWER_STATUS_REQUEST message to the other video device (Divice). The other video device (Diver) responds with a POWER_STATUS_RESPONSE [OFF] message indicating that the power is off. Through the POWER_STATUS_RESPONSE [OFF] message, the main controller 110 of the bidirectional CEC system 100 confirming that the power of the other video device is turned off is set to POWER_STATUS_REQUEST [ OFF] message to control the power off.

As described above, the bidirectional CEC system 100 according to the present invention is located between the source device 200 and the sink device 300 to perform bidirectional communication through the HDMI-CEC. Turn off the video device so that unnecessary power loss can be prevented. In addition, when the power of one video device is turned on while both the source device 200 and the sink device 300 are turned off, the user manually turns on the power of the other video device by turning on the power of the other video device. It helps to solve the inconvenience of having to turn on.

The bidirectional CEC system of the 60GHZ frequency band according to the present invention is not limited to the above-described embodiment, and the technical idea of the present invention and the claims to be described below by those skilled in the art to which the present invention pertains. Of course, various modifications and variations can be made within the equivalent range of the.

100: bidirectional CEC system 110: main controller
120: HDMI port 200: source device
300: sink device

Claims (4)

HDMI port 120 performing HDMI communication with the source device 200 and the sink device 300, and HDMI-CEC bidirectional communication with the source device 200 and the sink device 300 using a 60 GHz frequency band. In the bidirectional CEC system provided with a main controller 110 to perform and determine the state of the source device 200 and the sink device 300,
The main controller 110 transmits a message requesting a power state to the source device 200 or the sink device 300, and then receives a response message to determine the power state of the source device 200 or the sink device 300. If the grasp of one video device is turned off, a message is sent to the other video device to turn off the power of the other video device.
When the source device 200 and the sink device 300 are both turned off, when the power of one video device is turned on, the power state of the video device is transmitted by sending a message for turning on the power of the other video device to the other video device. Bidirectional CEC system, characterized in that for changing. delete delete delete

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