KR20100091570A - Wireless access system for high definition multimedia - Google Patents

Abstract

PURPOSE: A wireless access system with a high-definition multimedia is provided to satisfy the demand of consumers by operating the high-definition multimedia without mechanical attenuation. CONSTITUTION: A packet dispersion part(1) transfers data packets through a multichannel. A packet alignment part(2) aligns the data packets received through the multichannel. A packet-access-management unit(3) transfers parameter-vector for the multichannel-interface to the packet dispersion part and to the packet alignment part. The packet access management unit controls the packet dispersion part and the packet alignment part.

Description

High Definition Multimedia Wireless Access System {Wireless Access System for High Definition Multimedia}

The present invention relates to a high definition multimedia wireless access system, and more particularly, to a high definition multimedia wireless access system capable of transmitting and receiving wirelessly without compressing high definition multimedia.

AV (Audio-Video) equipment is evolving to higher definition and higher definition to satisfy consumer needs.

Among these devices, expensive video cables such as HDMI (High Definition Multimedia Interface) are used to transmit video streams without compression.

They deliver more than about 2Gbps of data at 1080p 60Hz, enabling HD to be delivered from media to display without any physical decay.

Wireless Personal Area Network (WPAN) was developed for wireless applications in these AV equipment and peripherals. The strength of WiMedia Ultra WideBand (UWB) is that it has a much higher data rate (480Mbps in ver1.2) compared to other wireless standards.

However, even in the system that intends to transmit full HD, even the WiMedia UWB standard has a technical limitation in transmitting uncompressed pixel data wirelessly.

Accordingly, an object of the present invention is to provide a high-definition multimedia wireless access system that can operate a plurality of bands of WiMedia UWB at the same time to transmit and receive a high-definition multimedia wirelessly.

The high definition multimedia wireless access system according to the present embodiment includes: a packet distributing unit configured to receive data packets and distribute them in multiple channels; A packet alignment unit for receiving and sorting data packets in multiple channels; And transmitting a parameter vector for a multi-channel interface to the packet distributing unit and the packet arranging unit so that the packet distributing unit distributes and transmits the data packet for each channel, and the packet arranging unit receives the data packet for each channel. It characterized in that it comprises a packet access management unit for controlling to align.

The packet distributing unit distributes the ordered input data packets into multiple channels and transmits the bursts in each channel.

The packet aligner may receive the data packets in bursts in multiple channels, and order the data packets.

The packet access management unit transmits the parameter vector for the multi-channel interface to the packet distributing unit and the packet arranging unit, and controls the other device to transmit and receive the same packet in more than one channel according to the number of available channels. It is done.

The packet access management unit transmits the parameter vector for the multi-channel interface to the packet distributing unit and the packet arranging unit, and controls the multi-channel to be selectively used according to the transmission / reception failure rate of each channel.

The packet access management unit transmits the parameter vector for the multi-channel interface to the packet distributing unit and the packet arranging unit to control the power level of the interface.

The parameter vector may include whether each channel interface is used and power level information of each channel interface.

The packet access management unit updates the parameter vector by calculating a transmission / reception rate and a packet loss for each channel for each data packet transmission and reception.

The high-definition multimedia wireless access system configured as described above is capable of transmitting and receiving wirelessly by compressing high-definition multimedia by simultaneously operating a plurality of bands, so that the high-definition multimedia can be reproduced without physical attenuation to satisfy the needs of consumers.

In addition, the present invention simplifies the complex connection lines of the digital devices to improve the user's convenience and has an excellent external design effect.

Hereinafter, the present invention will be described in more detail with reference to Examples. These embodiments are only for illustrating the present invention, and the scope of rights of the present invention is not limited by these embodiments.

1 is a block diagram of a high definition multimedia wireless access system according to the present embodiment.

One WiMedia UWB PHY can achieve 480Mbps through VR 1.2 and 1Gpbs through VR 1.5. This removes the general PHY overhead, and can process data packets with a user application data rate of about 700 Mbps to 800 Mbps.

In addition, when six bands are used simultaneously, data packets can be processed at a physics rate of 6 Gbps and a data rate of about 4 Gbps based on PHY VR 1.5.

The wireless access system according to the present embodiment relates to a method of simultaneously operating a plurality of bands of the WiMedia UWB. The wireless access system can operate with a device that uses only one band, and can transmit uncompressed high-capacity video data such as wireless HDMI. For the application, N bands are tied together to enable a multi-channel interface, and data throughput is proportional to N.

Referring to FIG. 1, the high-definition multimedia wireless access system according to the present embodiment includes a packet spreader (TX Scatter Matrix) 1, a packet sorter (RX Gather Matrix) 2, and a packet access manager (PATH Matrix Manager) ( 3) and Direct Memory Access (DMA) for WiMedia UWB communication (4), Wireless Universal Serial Bus Control Plane (WUSB CP) (5), Control Interface (6), RX Sequence Manager (RXSM) (7) , TX Sequence Manager (TXSM) 8, Multi Point Interface (MPIF) 9, SecretKey Manager (SKM) 10, and Beacon Manager (BM) 11.

The packet distributing unit 1 distributes the application data packet to the N-channel MPIF 9 and transmits the distributed packets in bursts in each channel. These packets are distributed, but are actually ordered as coming from one application system. That is, the packet distributing unit 1 is responsible for spraying in parallel a method of sequentially interfacing packet data in a line.

At this time, the packet distributing unit 1 receives parameter vectors for the N channel interfaces from the packet access management unit 3 and applies them to packet dispersing and transmission operations. Scale factor 1 of the packet spreader means a 1-channel interface.

The packet aligning unit 2 performs a function of combining and receiving packets distributed and received from the M-channel MPIF 9 in a row. The distributed packets are bursted to increase the sequence while crossing the channel. Is received in the form. That is, the packet aligner aligns M (or smaller than M) packets received at one time from the M-channel MPIF 9 and delivers them to the application system.

At this time, the packet aligner 2 receives the parameter vectors for the M channel interfaces from the packet access manager 3 and applies them to the packet reception and alignment operation. And, regardless of the way in which the packets received by the random number of the M channel received in the buffer for the packets received normally, it is possible to transmit them in the form of Acknowledge (Acknowledge). Scale factor 1 of the packet alignment unit means a 1-channel interface.

The packet access management unit 3 transmits a parameter vector for a multi-channel interface to the packet distributing unit and the packet arranging unit, so that the packet distributing unit 1 distributes and transmits a data packet for each channel, and the packet arranging unit (2) controls to receive and arrange the data packets for each channel.

Here, the parameter vector means that parameters are transmitted for each channel to the N-channel MPIF (9) of the packet distributing unit 1, and also for each channel for the M-channel MPIF (9) of the packet arranging unit (2). This means that the parameters will be applied. The parameters for the packet distributor 1 include contents related to the use of each channel interface, the power level of each channel interface, and the like. The parameters for the packet aligning unit 2 are similar to those of the packet distributing unit 1 with respect to the reception of data packets.

The packet access management unit 3 weights the weights of the channels with a relatively high transmission failure rate and the channels with good transmission rates through the number of channels available to the counterpart device and the history transmitted to the device. By setting the factor differently, you can control whether to use it or not, to transmit more power or less, or to send the same packet to more than one channel. In addition, the packet access management section 3 updates the parameter vector of the packet distribution section 1 for each transmission of the data packet.

The packet access management unit 3 also updates the parameter vector of the packet alignment unit 2 for each reception of the data packet. It calculates reception rate, packet loss, etc. for each channel, and puts a large weight on the best reception channel in the current high-definition multimedia wireless access system configuration to control the communication to be improved at the next reception.

The DMA 4 transmits a data packet from the frame buffer memory of the application system to the packet distributing unit 1, and the WUSB CP (Control Plane) 5 is a micro-scheduled management control (MMC), a device notification (DN), or the like. Signal is transmitted to and received from the packet distributing unit 1 and the packet arranging unit 2. CI (Control Interface) 6 interfaces between the CPU and the devices for WiMedia UWB communication. The RX Sequence Manager (RXSM) 7 and the TX Sequence Manager (TXSM) 8 transmit and receive the transmit / receive Ack signals ACRX and ACKTX, respectively, to the packet distributing unit 1 and the packet arranging unit 2. The MPIF (Multi Point Interface) 9 transmits the distributed data packet from the packet distributing unit 1 to another device, and transmits the distributed data packet received from the other device to the packet arranging unit 2. SKM (SecretKey Manager) 10 is responsible for encryption and decryption in the transmission of the data packet of the MPIF (9), the BM (Beacon Manager) (11) is the CMA (packet data arranged in sequence in the packet alignment unit 2) 4) Manage to synchronize with application system when transmitting.

2 is a block diagram of a high definition multimedia wireless access system according to another embodiment.

Referring to FIG. 2, there is shown a system that bundles N 1Gbps PHYs (Physical Layer) to obtain a total NGbps. If the image received HDMI input through DVDP was an 8bit color image at 1080p 60Hz, the transmission rate of 2.23Gbps should be secured, so in the example, if the theoretical PER is 0 and there is no overhead, the wireless access system is a 3x3 structure. The service can be solved.

FIG. 3 is a block diagram of a home network using a high-definition multimedia wireless access system according to the present embodiment, and FIG. 4 is a diagram showing an interface channel allocation between the devices of FIG.

3 and 4, a WiMedia network in which five devices exist is shown. First, Dev1 and Dev4 are WiMedia devices, which use only one band. Dev1 uses only ch1, Dev4 uses only ch5. Here ch refers to the UWB band and numbers are randomly attached.

It is assumed that Dev 0 is HDTV, Dev2 is PC, and Dev3 is DVDP, and PC is running WUSB Host at ch4.

The PC can read Cam files via WUSB and use HDTV as the monitor screen. Use ch4 to read the cam file. At this time, the wireless access system of the PC is set to a minimum configuration of 1x1. You can use ch0 through ch5 to send the monitor screen to the HDTV. At this time, the PC's wireless access system is set to 5x5, the maximum configuration.

5 to 9 are application examples of the high definition multimedia wireless access system according to the present embodiment.

5 shows a structure of a wireless access system that communicates in the same format as a WiMedia device using only one band.

6 shows a structure in which a sander uses only one channel and a receiver uses an M channel. At this time, M channels of the receiver use the same band used by the sander (Sender) as one channel. Through this process, the receiver can find a channel with a better reception rate and can adjust the weight value for the channel. The packet aligner 2 orders and aligns packets normally received in four channels. At this time, packets received at the same time in several channels are selected and stored only in one of them and uploaded to the application system.

FIG. 7 shows an application in which a sander is using a two channel interface and a receiver is receiving through a four channel interface. Sander transmits using different bands for two channels, and receiver receives two bands commonly used by Sander for four channels. . The packet aligning unit 2 checks packets of channels received on a common band, and uploads one to the application system in the case of duplicate reception. Any ACK is adjusted as long as it is received normally and can be considered normal reception regardless of which channel it receives.

8 shows an application in which a sander is using an N-channel interface and a receiver is receiving through an M-channel interface. Sanders transmit different bands for each of the N channels, and a receiver receives N bands divided by N bands for the M channels. The packet aligning unit 2 uploads only one to the application system in case of duplicate reception. Any ACK is adjusted as long as it is received normally and can be considered normal reception regardless of which channel it receives.

9 is an application of a wireless access system at the time point used in the 3x5 structure. In Scalable NxM, N is only a maximum number, and when the actual data packet is transmitted and received, the actual channel number and parameters of the NxM are continuously changed. This changing number and parameter vector is determined by the packet access management unit 3, which is transmitted to the packet distributing unit 1 for packet dispersal and the packet arranging unit 2 for packet distributing and Used for operation.

As a result, the wireless access system is controlled to be arranged in the form of a matrix operation by matrix values calculated by the packet access management unit 3 every packet transmission and reception, and the result of performing the packet data exchange is again converted into a reception rate and a transmission rate. Calculated for each channel and based on this, the packet access manager 3 derives a matrix value to be used for the next packet data exchange.

For example, if packets currently received in the receiver of FIG. 9 are normally received in channel 1, channel 2, and channel 3, the interfaces of channel 4 and channel 5 do not actually need to be used, and the packet access management unit ( 3) may control the packet distribution unit 1 to disable the corresponding channels and apply to the next packet data transmission and reception.

Assuming channel 2's reception rate is still good, channel 5 may no longer need to receive band 2. In such a situation, if the reception rate of the channel 3 is rapidly falling, the packet distributing unit 1 may increase the reception rate by setting the channel 5 to receive the same band 3 as the channel 3.

As described above, the present invention has been described with reference to the embodiments shown in the drawings, but this is merely exemplary, and various modifications and equivalent other embodiments of the present invention may be made by those skilled in the art. I understand that it is possible. Therefore, the true technical protection scope of the present invention will be defined by the claims below.

1 is a block diagram of a high definition multimedia wireless access system according to the present embodiment;

2 is a block diagram of a high definition multimedia wireless access system according to another embodiment;

3 is a home network block diagram using a high definition multimedia wireless access system according to the present embodiment;

4 shows an example of interface channel allocation between the devices of FIG.

5 to 9 are application examples of the high definition multimedia wireless access system according to the present embodiment;

Claims (8)

A packet disperser which receives data packets and distributes the data packets in multiple channels; A packet alignment unit for receiving and sorting data packets in multiple channels; And The parameter vector for the multi-channel interface is transmitted to the packet distributing unit and the packet arranging unit, so that the packet distributing unit distributes and transmits data packets for each channel, and the packet arranging unit receives and sorts the data packets for each channel. High-definition multimedia wireless access system comprising a packet access management unit for controlling to. The method of claim 1, wherein the packet distribution unit High-definition multimedia wireless access system, characterized in that the ordered and input data packets are distributed in multiple channels to form a burst in each channel. The method of claim 1, wherein the packet alignment unit And receiving the data packets in bursts in multiple channels and sequencing and sorting the data packets. The method of claim 1, wherein the packet access management unit High-quality multimedia radio access, characterized in that for transmitting the parameter vector for the multi-channel interface to the packet distribution unit and the packet alignment unit, the counterpart device transmits and receives the same packet in more than one channel according to the number of available channels system. The method of claim 1, wherein the packet access management unit And transmitting the parameter vector for the multi-channel interface to the packet distributing unit and the packet arranging unit to control to selectively use the multi-channel according to the transmission / reception failure rate of each channel. The method of claim 1, wherein the packet access management unit And transmitting the parameter vector for a multi-channel interface to the packet distributing unit and the packet arranging unit to control the power level of the interface. 7. The method according to any one of claims 4 to 6, wherein the parameter vector A high-definition multimedia wireless access system comprising whether each channel interface is used, and power level information of each channel interface. The method of claim 1, wherein the packet access management unit High-quality multimedia wireless access system, characterized in that for updating the parameter vector by calculating the transmission and reception rate, packet loss for each channel for each data packet transmission and reception.

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