KR101494878B1 - Multiple input multiple output system for performing transmission of the accumulative layered video signal by applying network coding method and, transmission apparatus and reception apparatus thereof - Google Patents

Abstract

A multi-antenna system for performing cumulative layer video signal transmission employing a network coding technique and a transmitting and receiving apparatus of the system are disclosed.
The transmitting apparatus of this system converts the video data into an SVC bit stream, wherein the SVC bit stream is divided into a base layer signal to be transmitted and an enhancement layer signal which is combined with the base layer signal and improves the quality of the video information And performs network coding for accumulating signals having higher priority than the self and the self based on the priority of the converted SVC bit stream to generate respective cumulative layer signals, And allocates the accumulated layer signals on a channel-by-channel basis and transmits the accumulated layer signals through multiple antennas. The receiving apparatus includes a receiving apparatus for receiving a cumulative layer signal transmitted from the transmitting apparatus, converting the received cumulative layer signal into a signal for each channel, and decoding the signal based on the priority of the SVC bit stream to recover the video data. The transmitting apparatus inserts a pilot signal for each channel and transmits the pilot signal. The receiving apparatus estimates a channel state through a pilot signal included in a channel-specific signal transmitted from the transmitting apparatus, And feedback is performed to the transmission apparatus as priority information for each channel.

Description

Technical Field [0001] The present invention relates to a multi-antenna system for performing a cumulative layer video signal transmission using a network coding scheme, and a transmitting / receiving apparatus for the system. }

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multi-antenna system for performing transmission of a cumulative layer video signal using a network coding technique, and a transmitting and receiving apparatus for the system.

The multiple input multiple output (MIMO) system, which is promising as a next generation wireless communication technology that can guarantee a high data rate, can guarantee a high data rate by applying the space division multiplexing technique, It is a system that can expect performance improvement.

However, in the multi-antenna system, when different information signals are transmitted to the individual antennas, interference occurs between antennas using the same frequency band, resulting in degraded performance.

On the other hand, many studies have been made to transmit high quality video signals through a communication network. SVC (Scalable Video Coding) is a kind of H.264 / MPEG4-AVC standard video codec for time-varying channels. SVC technique enables high-level video bitstream coding. These SVC signals are divided into layered coded signals in two group hierarchies. One is the base layer signal, which has the highest priority in the video signal and must be transmitted. And the other is an enhancement layer signal, which is combined with the base layer signal to improve the quality of the received video. Thus, the enhancement layer signal has a lower priority than the base layer signal.

Therefore, there is a need for a method capable of overcoming the performance degradation due to interference and noise of the wireless communication channel in the multi-antenna using the characteristics of the video signal layered to satisfy the requirements of users in the next generation wireless communication service do.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide a method and apparatus for controlling a transmission rate of a video signal, A multi-antenna system for performing video signal transmission, and a transmitter / receiver of the system.

According to one aspect of the present invention,

A transmitting apparatus for a multi-antenna system, comprising: a scalable video coding (SVC) bitstream for video data, wherein the SVC bitstream is combined with a base layer signal to be transmitted and an enhancement Layered signal, and outputs the converted signal; And accumulating a signal having a higher priority than itself and a cumulative layer signal based on the priority of the SVC bit stream output from the encoder to generate a cumulative layer signal, To a receiving device via a network.

A modulator for modulating the accumulated layer signal output from the network coder; An IFFT unit for IFFT-converting a signal output from the modulator; And a guard interval inserter for inserting a guard interval into the signal converted by the IFFT unit and transmitting the guard interval to the receiver through a plurality of transmission antennas.

In addition, the network coder may be configured such that the base layer signal is network-coded and output as the first accumulation layer signal as it is for the base layer signal.

For the enhancement layer signal excluding the base layer signal from the SVC bitstream, the enhancement layer signal is generated by network-coding an enhancement layer signal having a higher priority with respect to the enhancement layer signal, And generating and outputting a cumulative layer signal.

In addition, the network coding is performed by an XOR operation.

According to another aspect of the present invention,

An apparatus for receiving a multi-antenna system, the apparatus comprising: an SVC bitstream for an accumulation layer signal transmitted from a transmitter of the multi-antenna system, the SVC bitstream comprising a base layer signal to be transmitted and a base layer signal, A network decoder for performing network decoding to decode based on a priority of the enhancement layer signal and outputting the resultant to a corresponding SVC bitstream; And an SVC decoder for combining the SVC bit stream output from the network decoder and outputting the combined signal as a video signal.

A guard interval canceller for removing a guard interval from the accumulated layer signal transmitted from the transmitting apparatus through a plurality of receiving antennas and outputting the guard interval; An FFT unit for FFT-converting the signal output from the guard interval eliminator and outputting the signal; And a demodulator that demodulates the signal output from the FFT unit.

The network decoder may be configured such that the first accumulation layer signal is network-decoded and output as a base layer signal as it is for a first accumulation layer signal corresponding to a base layer signal among the accumulation layer signals.

In addition, the cumulative layer signal, excluding the first cumulative layer signal, is subjected to network decoding of the cumulative layer signal corresponding to the enhancement layer signal having a higher priority with respect to the cumulative layer signal, And generates and outputs a signal.

In addition, the network decoding is performed by an XOR operation.

A multi-antenna system according to another aspect of the present invention includes:

Video data to an SVC bitstream, wherein the SVC bitstream is divided into a base layer signal to be transmitted and an enhancement layer signal that is combined with the base layer signal and improves the quality of video information, A transmission apparatus for performing network coding by accumulating signals of higher priority than the base station and a higher priority than the base station and generating respective accumulated layer signals based on the priority of the stream, And a receiving apparatus for receiving the accumulated layer signal transmitted from the transmitting apparatus and decoding the packet based on the priority of the SVC bit stream to recover the video data.

Here, the transmitting apparatus includes: an encoder for converting video data into an SVC bit stream and outputting the converted SVC bit stream; And a network coding unit for performing the network coding on the SVC bit stream output from the encoder and outputting an accumulated layer signal.

The receiving apparatus may further include: a network decoder for performing the network decoding on the accumulated layer signal transmitted from the transmitting apparatus and outputting the resultant signal as a corresponding SVC bitstream; And an SVC decoder for combining the SVC bit stream output from the network decoder and outputting the combined signal as a video signal.

According to another aspect of the present invention,

There is provided a transmission apparatus for a multi-antenna system, comprising a base layer signal for transmitting video data to an SVC bitstream, wherein the SVC bitstream is divided into enhancement layer signals, which are combined with the base layer signal, ; A network coder for performing network coding for accumulating signals having higher priority than the self and the self based on the priority of the SVC bit stream outputted from the encoder and generating respective accumulated layer signals; A generator for generating a pilot signal; And assigning a cumulative layer signal output from the network coder according to a channel priority order, which is determined by channel priority information, for each channel, inserting a pilot signal generated by the generator for each channel, Wherein the transmitting apparatus estimates a channel state through a pilot signal included in a signal for each channel by the receiving apparatus, determines a priority for each channel, Is received.

Here, the allocator may include: a priority checker for each channel, the priority checker for each channel to be assigned to the accumulated layer signals output from the network coder based on priority information for each channel fed back from the receiving device; A pilot signal inserter for inserting a pilot signal generated by the generator into a cumulative layer signal output from the network coder and outputting a cumulative layer signal in which a pilot signal is inserted; And a channel selector for assigning a cumulative layer signal output from the pilot signal inserter to each channel based on a channel-specific priority identified by the channel-specific priority checker.

In addition, the channel selector allocates a cumulative layer signal accumulated for the base layer signal to a channel having the highest priority among the channels, and assigns a cumulative layer signal accumulated for the enhancement layer signal to a channel having a lower priority among the channels .

According to another aspect of the present invention,

An apparatus for receiving a multi-antenna system, comprising: an allocator for classifying cumulative layer signals transmitted from a transmitter of the multi-antenna system for each channel; Wherein the SVC bitstream is divided into a base layer signal to be transmitted and an enhancement layer signal which is combined with the base layer signal to improve the quality of the video information, A network decoder for performing network decoding to decode based on a priority of the network decoder and outputting the decoded result to a corresponding SVC bitstream; An SVC decoder for combining the SVC bitstream output from the network decoder and outputting the combined signal as a video signal; And estimating a channel state of the multi-antenna system using a pilot signal included in a channel-specific signal output from the network decoder, determining a priority for each channel based on the estimated channel state, Wherein the allocator classifies the accumulated layer signals transmitted from the transmission apparatus according to the channel priority determined by the feedback unit and outputs the accumulated layer signals for each channel.

Here, the feedback unit may be configured to identify channel state information of the multi-antenna system using a pilot signal included in a signal output from the network decoder, estimate a channel environment based on the channel state to be checked, A channel estimator outputting the channel estimator; And a channel-specific prioritizer for determining a priority for each channel based on the channel estimation value output from the channel estimator.

According to the present invention, performance degradation due to interference and noise of a wireless communication channel can be overcome.

In addition, the stability and transmission rate of the video signal transmission are improved, thereby improving the efficiency of the system.

1 is a diagram illustrating a transmitting apparatus of a multiplexing system according to an embodiment of the present invention.
2 is a diagram showing a specific configuration of the network coder shown in FIG.
3 is a diagram illustrating a reception apparatus of a multi-antenna system according to an embodiment of the present invention.
FIG. 4 is a diagram showing a specific configuration of the network decoder shown in FIG.
5 is a diagram illustrating a transmitting apparatus of a multi-antenna system according to another embodiment of the present invention.
FIG. 6 is a diagram showing a specific configuration of the channel allocator shown in FIG. 5. Referring to FIG.
7 is a diagram illustrating a receiving apparatus of a multi-antenna system according to an embodiment of the present invention.
8 is a diagram showing a specific configuration of the channel information feedback unit shown in FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise. Also, the terms " part, "" module," and " module ", etc. in the specification mean a unit for processing at least one function or operation and may be implemented by hardware or software or a combination of hardware and software have.

1 is a diagram illustrating a transmitting apparatus 100 of a multiplexing system according to an embodiment of the present invention.

1, a transmitting apparatus 100 of a multiplexing system according to an embodiment of the present invention includes an SVC encoder 110, a network coder 120, a modulator 130, an IFFT (Inverse Fast Fourier Transform) And a guard interval (hereinafter referred to as "GI") inserter 150.

The SVC encoder 110 generates the SVC bitstream of the video data to be transmitted and outputs the SVC bitstream. That is, the SVC encoder 110 converts the video data into a base layer signal, a first enhancement layer signal, a second enhancement layer signal, , And outputs it as an n-th enhancement layer signal. Here, the priority of the video layer signal having different significance levels is the highest for the base layer signal, then the first enhancement layer signal, the second enhancement layer signal, , And the nth enhancement layer signal. On the other hand, a layer signal generated by the SVC encoder 110, i.e., a base layer signal, a first enhancement layer signal, , The number of the n-th layer signals is equal to the number of the multiple antenna transmission channels allocated by the number of antennas having a small number of the number of transmission antennas and the number of reception antennas of the multi-antenna system. For example, when the number of multi-antenna transmission channels is n + 1, one base layer signal and n number of enhancement layer signals are output as the first enhancement layer signal to the nth enhancement layer signal.

The network coder 120 receives the base layer signal, the first enhancement layer signal, the second enhancement layer signal, and the second enhancement layer signal output from the SVC encoder 110. [ , Receives the n-th enhancement layer signal, performs network coding, and outputs it. In this case, the network coding performed by the network coding unit 120 is output as the same number of signals as those received from the SVC encoder 110, I.e., a cumulative layer signal. For example, the base layer signal is output as it is because there is no higher priority signal than the base layer signal, and the first layer signal is accumulated and output together with the base layer signal having higher priority than the base layer signal. The signal accumulation at this time can be performed through various methods, but it is assumed that the signal accumulation is performed by the XOR operation in the embodiment of the present invention. The network coding method performed by the network coding device 120 will be described later.

The modulator 130 performs modulation on the accumulated layer signals output from the network coder 120 and outputs the modulated signals. Here, since the modulation technique in the multiplexing system is well known, a detailed description thereof will be omitted.

The IFFT unit 140 IFFT-converts the signal output from the modulator 130 and outputs the signal.

The GI inserter 150 inserts a guard interval GI into a signal output from the IFFT unit 140 and outputs the guard interval GI to the receiver 200 through a transmission antenna 170.

FIG. 2 is a diagram showing a specific configuration of the network coder 120 shown in FIG.

2, the network coder 120 includes a first coding unit 121, a second coding unit 122, and an n-th coding unit 123. The first coding unit 121, the second coding unit 122, Here, the first coding unit 121, the second coding unit 122 and the n-th coding unit 123 are all XOR operators.

)는 '0'과 XOR 연산이 수행되어 기본 계층 신호(

)에 대응하여 출력된다. 이 때 출력되는 신호는

이다. 여기서, 기본 계층 신호(

)와 '0'의 XOR 연산은 그대로 기본 계층 신호(

)이므로 실질적으로는 XOR 연산 없이 그대로 기본 계층 신호(

)를

신호로써 출력하는 것이다. 이를 수식으로 나타내면

이다, 여기서,

는 0이다.First, the base layer signal (SV) output from the SVC encoder 110

) Is subjected to XOR operation with '0' to generate a base layer signal (

). The signal output at this time is

to be. Here, the base layer signal (

) And '0' are used as the base layer signal (

), So that the base layer signal (

)

Signal. When expressed as an equation

Lt; / RTI >

Is zero.

)와 제1 향상 계층 신호보다 우선순위가 높은 기본 계층 신호(

)가 코딩된

에 대해 XOR 연산을 수행하여 제1 향상 계층 신호(

)에 대응되는 신호

로써 출력한다. 이와 같이, 제1 코딩기(121)는 제1 향상 계층 신호(

)와 자신보다 우선순위가 높은 기본 계층 신호(

)를 네트워크 코딩을 통해 누적하여 출력하게 된다. 이를 수식으로 나타내면

이다.The first coding unit 121 receives the first enhancement layer signal (the first enhancement layer signal) output from the SVC encoder 110

And a base layer signal having a higher priority than the first enhancement layer signal

) Is coded

To perform an XOR operation on the first enhancement layer signal

≪ / RTI >

. As such, the first coding unit 121 receives the first enhancement layer signal (

) And a base layer signal having a higher priority than itself

) Are cumulatively output through network coding. When expressed as an equation

to be.

)와 제2 향상 계층 신호보다 우선순위가 높은 제1 향상 계층 신호(

)가 코딩된

에 대해 XOR 연산을 수행하여 제2 향상 계층 신호(

)에 대응되는 신호

로써 출력한다. 이와 같이, 제2 코딩기(122)는 제2 향상 계층 신호(

)와 자신보다 우선순위가 높은 기본 계층 신호(

) 및 제1 향상 계층 신호(

)를 네트워크 코딩을 통해 누적하여 출력하게 된다. 여기서, 기본 계층 신호(

)는 제2 코딩기(122)에서 XOR 연산되는 신호

에 이미 누적되어 있으므로 상기와 같은 네트워크 코딩이 될 수 있다. 이를 수식으로 나타내면

이다.The second coding unit 122 receives the second enhancement layer signal output from the SVC encoder 110

And a first enhancement layer signal having a higher priority than the second enhancement layer signal

) Is coded

To perform an XOR operation on the second enhancement layer signal

≪ / RTI >

. As such, the second coding unit 122 receives the second enhancement layer signal

) And a base layer signal having a higher priority than itself

) And the first enhancement layer signal (

) Are cumulatively output through network coding. Here, the base layer signal (

) Is a signal which is XOR-computed in the second coding unit 122

The network coding as described above can be performed. When expressed as an equation

to be.

)와 제n 향상 계층 신호보다 우선순위가 높은 제n-1 향상 계층 신호(

)가 코딩된

에 대해 XOR 연산을 수행하여 제n 향상 계층 신호(

)에 대응되는 신호

로써 출력한다. 이와 같이, 제n 코딩기(122)는 제n 향상 계층 신호(

)와 자신보다 우선순위가 높은 기본 계층 신호(

), 제1 향상 계층 신호(

) 내지 제n-1 계층 신호(

)를 네트워크 코딩을 통해 누적하여 출력하게 된다. 이를 수식으로 나타내면

이다.The n-th coder 123 receives the n-th enhancement layer signal (n) output from the SVC encoder 110

Th enhancement layer signal having a higher priority than the n-th enhancement layer signal

) Is coded

Lt; th > enhancement layer signal < RTI ID = 0.0 >

≪ / RTI >

. As described above, the n-th coder 122 converts the n-th enhancement layer signal

) And a base layer signal having a higher priority than itself

), A first enhancement layer signal (

Th to (n-1) th layer signals

) Are cumulatively output through network coding. When expressed as an equation

to be.

3 is a diagram illustrating a receiving apparatus 200 of a multi-antenna system according to an embodiment of the present invention.

3, a receiving apparatus 200 of a multi-antenna system according to an embodiment of the present invention includes a GI remover 210, an FFT unit 220, a demodulator 230, a network decoder 240, and an SVC And a decoder 250.

The GI eliminator 210 removes the guard interval GI from the signal received through the reception antenna 280 and outputs the guard interval GI.

The FFT unit 220 FFT-converts the signal output from the GI eliminator 210 and outputs the signal.

The demodulator 230 demodulates the signal output from the FFT unit 220 and outputs the demodulated signal. Here, since the demodulation technique in the multi-antenna system is well known, a detailed description thereof will be omitted.

The network decoder 240 performs network decoding on a signal output from the demodulator 230 to generate a base layer signal, a first enhancement layer signal, a second enhancement layer signal, , And outputs it as an n-th layer signal. Here, the network decoding performed by the network decoder 240 is the same as the reverse operation of network coding with the accumulation layer signal by network coding in the transmitting apparatus 120. [ In other words, the network coding unit 240 of the transmission apparatus 100 can accumulate the components of the hierarchical signal that are network-coded and accumulated in the base layer signal, the first enhancement layer signal, the second enhancement layer signal, , And outputs it as an n-th layer signal. The network decoding method performed by the network decoder 240 will be described later.

The SVC decoder 250 receives the base layer signal, the first enhancement layer signal, the second enhancement layer signal, and the second enhancement layer signal output from the network decoder 240. And the n-th enhancement layer signal, and outputs the result as a video signal.

FIG. 4 is a diagram showing a specific configuration of the network decoder 240 shown in FIG.

As shown in FIG. 4, the network decoder 240 includes a first decoder 241, a second decoder 242, and an n-th decoder 243. Here, the first decoder 241, the second decoder 242, and the n-th decoder 243 are all XOR operators.

)는 '0'과 XOR 연산이 수행되어 기본 계층 신호(

)를 출력된다. 여기서, 제1 누적 계층 신호(

)와 '0'의 XOR 연산은 그대로 제1 누적 계층 신호(

)이므로 실질적으로는 XOR 연산 없이 그대로 제1 누적 계층 신호(

)를 기본 계층 신호(

)로써 출력하는 것이다. 이를 수식으로 나타내면

이다. 여기서,

는 0이다.First, the first accumulation layer signal (

) Is subjected to XOR operation with '0' to generate a base layer signal (

). Here, the first accumulation layer signal (

) And " 0 " are directly applied to the first accumulation layer signal (

), So that the first accumulation layer signal (

) To the base layer signal (

). When expressed as an equation

to be. here,

Is zero.

)와 기본 계층 신호(

)에 대해 XOR 연산을 수행하여 제1 향상 계층 신호(

)로써 출력한다. 이를 수식으로 나타내면

이다.The first decoder 241 demultiplexes the second accumulation layer signal outputted from the demodulator 230

) And the base layer signal (

) To perform the XOR operation on the first enhancement layer signal (

). When expressed as an equation

to be.

)와 제1 디코딩기(241)에 의해 네트워크 디코딩되어 출력되는 제1 향상 계층 신호(

)에 대해 XOR 연산을 수행하여 제2 향상 계층 신호(

)로써 출력한다. 이를 수식으로 나타내면

이다.The second decoder 242 demultiplexes the third accumulation layer signal output from the demodulator 230

) And a first enhancement layer signal (hereinafter referred to as " first enhancement layer signal ") decoded and output by the first decoder 241

) To perform an XOR operation on the second enhancement layer signal (

). When expressed as an equation

to be.

)와 이전에 네트워크 디코딩되어 출력되는 제n-1 향상 계층 신호(

)에 대해 XOR 연산을 수행하여 제n 향상 계층 신호(

)로써 출력한다. 이를 수식으로 나타내면

이다.The n-th coder 243 outputs the (n + l) -th accumulation layer signal (

(N-1) th enhancement layer signal

) To perform an XOR operation on the n-th enhancement layer signal

). When expressed as an equation

to be.

As described above, in the embodiment of the present invention, the multi-antenna system accumulates signals having higher priority than the signal strength of the multi-antenna system and accumulates the signals in the multi-antenna system using the characteristic that the video layer signals have different importance and mutual priorities are different from each other The performance degradation due to the interference and noise of the wireless communication channel can be overcome.

In the above description, only the accumulation layer signal generated after the network coding is performed on the video layer signal is transmitted as it is. However, the technical scope of the present invention is not limited thereto but can be applied in various ways.

For example, it is possible to transmit according to the priority of the accumulated layer signal according to the priority according to the channel state of the multi-antenna system.

Hereinafter, a multi-antenna system according to another embodiment of the present invention will be described.

5 is a diagram illustrating a transmitting apparatus 300 of a multi-antenna system according to another embodiment of the present invention.

5, a transmitting apparatus 300 of a multi-antenna system according to another embodiment of the present invention includes an SVC encoder 310, a network coder 315, a channel allocator 320, a modulator 330, An IFFT unit 340, a GI inserter 350, and a pilot signal generator 360. The SVC encoder 310, the network coder 315, the modulator 330, the IFFT unit 340, and the GI inserter 350 are connected to the SVC encoder 110, the network coder 120, The modulator 130, the IFFT unit 140, and the GI inserter 150, the description thereof will be omitted and only the other components will be described.

), 제2 누적 계층 신호(

), 제3 누적 계층 신호(

), …, 제n+1 누적 계층 신호(

)를 할당한다. 즉, 채널 할당기(320)는 제1 누적 계층 신호(

)를 우선순위가 가장 높은 채널에 할당하여 출력하고, 그 다음부터 제2 누적 계층 신호(

), 제3 누적 계층 신호(

), …, 제n+1 누적 계층 신호(

)를 그 우선순위에 따라 해당하는 채널에 할당하여 출력한다.The channel allocator 320 determines a priority for each channel to be used based on the priority information for each channel fed back from the receiving apparatus 400 and outputs the priority to the channel coder 315 according to the determined priority The accumulated layer signal, i.e., the first accumulated layer signal (

), A second cumulative layer signal (

), A third cumulative layer signal (

), ... , An (n + l) -th accumulation layer signal

). That is, the channel allocator 320 allocates the first accumulation layer signal (

) To the channel having the highest priority, and outputs the second cumulative layer signal (

), A third cumulative layer signal (

), ... , An (n + l) -th accumulation layer signal

) To the corresponding channel according to the priority order and outputs the allocated channel.

The channel allocator 320 inserts pilot signals generated by the pilot signal generator 360 into signals output from the channel allocator 320 and outputs the pilot signals.

The pilot signal generator 360 generates a pilot signal used for grasping the state information of the channels in the multi-antenna system, and provides the pilot signal to the channel allocator 320.

FIG. 6 is a diagram illustrating a specific configuration of the channel allocator 320 shown in FIG.

6, the channel allocator 320 includes a channel-by-channel priority checker 321, a pilot signal inserter 323, and a channel selector 325.

), 제2 누적 계층 신호(

), 제3 누적 계층 신호(

), …, 제n+1 누적 계층 신호(

)에 실질적으로 각각 할당될 채널별 우선순위를 확인한다.The channel-by-channel priority checker 321 receives a first cumulative layer signal (a first cumulative layer signal) output from the network coder 315 based on priority information for each channel fed back from the receiving apparatus 400

), A second cumulative layer signal (

), A third cumulative layer signal (

), ... , An (n + l) -th accumulation layer signal

) To be allocated to the respective channels.

), 제2 누적 계층 신호(

), 제3 누적 계층 신호(

), …, 제n+1 누적 계층 신호(

)에 파일롯 신호 생성기(360)로부터 제공되는 파일롯 신호를 삽입하여 각각 파일롯 신호가 삽입된 네트워크 코딩기(315)에서 출력되는 제1 누적 계층 신호(

), 제2 누적 계층 신호(

), 제3 누적 계층 신호(

), …, 제n+1 누적 계층 신호(

)를 출력한다.The pilot signal inserter 323 receives the first cumulative layer signal (

), A second cumulative layer signal (

), A third cumulative layer signal (

), ... , An (n + l) -th accumulation layer signal

And outputs the first accumulation layer signal (the first accumulation layer signal) output from the network coder 315 into which the pilot signal is inserted

), A second cumulative layer signal (

), A third cumulative layer signal (

), ... , An (n + l) -th accumulation layer signal

).

)에 할당하여 출력하고, 다음 우선순위의 채널은 파일롯 신호 삽입기(323)에서 출력되는 제2 누적 계층 신호(

)에 할당하여 출력하며, 계속해서 다음의 우선순위의 채널들에 대해 제2 누적 계층 신호(

), 제3 누적 계층 신호(

), …, 제n+1 누적 계층 신호(

)를 출력한다.The channel selector 325 refers to the priority order of each channel identified by the channel priority checker 321 and the highest priority channel is the first cumulative hierarchical signal outputted from the pilot signal inserter 323

And the channel of the next priority order is output to the second accumulation layer signal output from the pilot signal inserter 323

And outputs the second cumulative layer signal (hereinafter, referred to as " second cumulative layer signal "

), A third cumulative layer signal (

), ... , An (n + l) -th accumulation layer signal

).

7 is a diagram illustrating a receiving apparatus 400 of a multi-antenna system according to an embodiment of the present invention.

7, a receiving apparatus 400 of a multi-antenna system according to an embodiment of the present invention includes a GI remover 410, an FFT unit 420, a channel allocator 430, a demodulator 440, A decoder 445, an SVC decoder 450 and a channel information feedback 460. [ The GI eliminator 410, the FFT unit 420, the demodulator 440, the network decoder 445 and the SVC decoder 450 are the GI eliminator 210, the FFT unit 220, The network decoder 230, the network decoder 240, and the SVC decoder 250, the description thereof will be omitted and only the other components will be described.

The channel allocator 430 separates signals output from the FFT unit 420 for each channel and outputs the signals. At this time, the channel allocator 430 receives the priority information for each channel by the channel information feedback unit 460, and for the signal allocated to the channel having the highest priority among the signals output from the FFT unit 420, The first cumulative layer signal 471 and the second cumulative layer signal 472 for the signal assigned to the channel having the next highest priority and outputs the signal as the second cumulative layer signal 472, The third cumulative layer signal 473, , And outputs it as an (n + 1) -th accumulation layer signal 474. Here, the channel allocator 430 does not receive the channel-specific priority information from the channel information feedback unit 460, but transmits substantially the first accumulation layer 460 in the transmitting apparatus 300 through the signal transmitted from the transmitting apparatus 300, Signal, a second cumulative layer signal, a third cumulative layer signal, ... And receives the priority information for each channel to which the (n + 1) th accumulation layer signal is allocated, and outputs the signals output from the FFT unit 420 for each channel.

The channel information feedback unit 460 estimates the channel state using the pilot signal included in the signal output from the network decoder 445, determines the priority for each channel based on the estimated channel state, 300) as priority information for each channel.

FIG. 8 is a diagram showing a specific configuration of the channel information feedback unit 460 shown in FIG.

As shown in FIG. 8, the channel information feedback unit 460 includes a channel estimator 461, a channel-specific prioritizer 463, and a feedback unit 465.

The channel estimator 461 estimates the channel state information of the channels of the multi-antenna system using the pilot signal included in the signal output from the network decoder 445, And outputs the channel estimation value.

The priority determiner 463 for each channel determines the priority for each channel based on the channel estimation value output from the channel estimator 461. [

The feedback unit 465 feeds back the priority information for each channel determined by the priority unit for each channel 463 to the transmission apparatus 300.

As described above, according to another embodiment of the present invention, in a multi-antenna system, a signal having a higher priority than itself and a signal having higher priority than the signal is accumulated and accumulated as a layer signal using characteristics that video layer signals have different importance and mutual priorities are different And perform channel coding for the layer signals accumulated according to the priority according to the channel states of the multi-antenna system, so that performance degradation due to interference and noise of the wireless communication channel can be overcome But the stability and transmission rate of the video signal transmission is improved and the efficiency of the system is improved.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

Claims (18)

A transmitting apparatus of a multi-antenna system,
The SVC bitstream is divided into a base layer signal to be transmitted and a plurality of enhancement layer signals which are combined with the base layer signal and improve the quality of the moving picture information. An encoder for converting and outputting the data; And
Performing a network coding for accumulating signals having higher priority than the self and the self based on the priority of the SVC bit stream output from the encoder to generate respective accumulated layer signals, To a receiving device,
Wherein the network coder includes a plurality of enhancement layer signals including a plurality of enhancement layer signals including a plurality of enhancement layer signals including a plurality of enhancement layer signals including a plurality of enhancement layer signals, Generates an accumulated layer signal corresponding to the one enhancement layer signal,
The transmitting apparatus allocates the base layer signal to one of the multiple antenna transmission channels formed between the transmitting apparatus and the receiving apparatus through the multiple antennas and transmits the base layer signal to the receiving apparatus, And transmits them to the receiving apparatus
And a transmission unit for transmitting the transmission data. The method according to claim 1,
A modulator for modulating an accumulated layer signal output from the network coder;
An IFFT unit for IFFT-converting a signal output from the modulator; And
A guard interval inserter for inserting a guard interval into the signal converted by the IFFT unit and transmitting the guard interval to the receiver through a plurality of transmission antennas,
Further comprising: The method according to claim 1,
The network coder includes:
And the base layer signal is network-coded and output as the first accumulation layer signal as it is for the base layer signal. The method of claim 3,
The enhancement layer signal excluding the enhancement layer signal from the SVC bitstream is network coded with respect to an enhancement layer signal having a higher priority with respect to the enhancement layer signal, And generates and outputs a signal. 5. The method according to any one of claims 1 to 4,
Wherein the network coding is performed by an XOR operation. A receiving apparatus of a multi-antenna system,
A scalable video coding (SVC) bit stream for a base layer signal and a plurality of accumulation layer signals received from the transmitting apparatus through a multiple antenna transmission channel formed between the transmitting apparatus and the receiving apparatus by multiple antennas, The base layer signal is divided into a plurality of enhancement layer signals which are combined with the base layer signal to enhance the quality of the moving picture information, A network decoder for outputting the stream as a stream; And
And an SVC decoder for combining the SVC bitstream output from the network decoder and outputting the combined signal as a video signal,
Wherein the accumulation layer signal includes the base layer signal for one enhancement layer signal among the plurality of enhancement layer signals in the transmitter, and all signals having a higher priority than the enhancement layer signal are transmitted to the enhancement layer signal And the second enhancement layer signal is a signal generated corresponding to the enhancement layer signal,
The base layer signal is received via one of the multi-antenna transmission channels, and the plurality of accumulation layer signals are received through the remaining multi-antenna transmission channel
. The method according to claim 6,
A guard interval eliminator for removing a guard interval from the accumulated layer signal transmitted and received from the transmitting apparatus through a plurality of receiving antennas and outputting the guard interval;
An FFT unit for FFT-converting the signal output from the guard interval eliminator and outputting the signal; And
A demodulator for demodulating a signal output from the FFT unit;
Further comprising: The method according to claim 6,
The network decoder includes:
Wherein the first accumulation layer signal is network-decoded as a base layer signal as it is for a first accumulation layer signal corresponding to a base layer signal among the accumulation layer signals. 9. The method of claim 8,
The cumulative layer signal excluding the first cumulative layer signal and the cumulative layer signal corresponding to the enhancement layer signal having a higher priority with respect to the cumulative layer signal are decoded by themselves to decode the cumulative layer signal, And outputs it. 10. The method according to any one of claims 6 to 9,
Wherein the network decoding is performed by an XOR operation. The SVC bitstream is divided into a base layer signal to be transmitted and a plurality of enhancement layer signals which are combined with the base layer signal and improve the quality of the moving picture information. Performing a network coding for accumulating signals having higher priority than the self and the self based on the priority of the SVC bit stream to generate respective cumulative layer signals, and transmitting the multiplexed signals through multiple antennas; And
And a receiving apparatus for receiving a cumulative layer signal transmitted from the transmitting apparatus and performing network decoding for decoding based on the priority of the SVC bit stream to restore video data,
The transmitting apparatus may include a method for accumulating all enhancement layer signals including one or more enhancement layer signals including the base layer signal in the enhancement layer signal, Generates an accumulated layer signal corresponding to the one enhancement layer signal,
The transmitting apparatus allocates the base layer signal to one of the multiple antenna transmission channels formed between the transmitting apparatus and the receiving apparatus through the multiple antennas and transmits the base layer signal to the receiving apparatus, To the receiving device
Wherein the multi-antenna system is a multi-antenna system. 12. The method of claim 11,
The transmitting apparatus includes:
An encoder for converting the video data into an SVC bit stream and outputting the converted SVC bit stream; And
A network coding unit for performing the network coding on the SVC bit stream output from the encoder and outputting an accumulated layer signal,
≪ / RTI > 12. The method of claim 11,
The receiving apparatus includes:
A network decoder for performing the network decoding on an accumulated layer signal transmitted from the transmitting apparatus and outputting the resultant signal as a corresponding SVC bitstream; And
An SVC decoder for combining the SVC bitstream output from the network decoder and outputting the combined signal as a video signal,
≪ / RTI > A transmitting apparatus of a multi-antenna system,
The video data is converted into an SVC (Scalable Video Coding) bitstream, wherein the SVC bitstream is divided into a base layer signal to be transmitted and an enhancement layer signal, which is combined with the base layer signal and improves the quality of the video information An encoder;
A network coder for performing network coding for accumulating signals having higher priority than the self and the self based on the priority of the SVC bit stream outputted from the encoder and generating respective accumulated layer signals;
A generator for generating a pilot signal; And
The accumulation layer signals output from the network coder are allocated on a channel-by-channel basis based on channel-specific priority information per channel, and pilot signals generated by the generator are inserted for each channel, To the receiving device,
The transmitting apparatus estimates a channel state through a pilot signal included in a signal for each channel by the receiving apparatus, determines a priority for each channel, and receives priority information for each channel to be fed back
And a transmission unit for transmitting the transmission data. 15. The method of claim 14,
The allocator includes:
A priority checker for each channel to be assigned to a cumulative layer signal output from the network coder based on priority information for each channel fed back from the receiving device;
A pilot signal inserter for inserting a pilot signal generated by the generator into a cumulative layer signal output from the network coder and outputting a cumulative layer signal in which a pilot signal is inserted; And
A channel selector for allocating a cumulative layer signal output from the pilot signal inserter to each channel based on a channel-by-channel priority determined by the channel-
. 16. The method of claim 15,
The channel selector allocates a cumulative layer signal accumulated for the base layer signal to a channel having the highest priority among the channels and allocates cumulative layer signals accumulated for the enhancement layer signal to a channel having a lower priority among the channels And a transmission unit for transmitting the transmission data. A receiving apparatus of a multi-antenna system,
An allocator for classifying and outputting the accumulated layer signals transmitted from the transmitting apparatus of the multi-antenna system for each channel;
A Scalable Video Coding (SVC) bitstream for an accumulation layer signal output from the allocator, wherein the SVC bitstream includes a base layer signal to be transmitted and an enhancement layer A network decoder for performing network decoding to decode based on a priority of the layer-by-layer signal and outputting it as a corresponding SVC bitstream;
An SVC decoder for combining the SVC bitstream output from the network decoder and outputting the combined signal as a video signal; And
Estimates a channel state of the multi-antenna system using a pilot signal included in a channel-by-channel signal output from the network decoder, determines a priority for each channel based on the estimated channel state, And a feedback unit for feedback by priority information,
Wherein the allocator classifies the accumulated layer signals transmitted from the transmission apparatus according to the channel priority determined by the feedback unit and outputs the classified accumulated signal. 18. The method of claim 17,
The above-
A channel estimator for checking channel state information of the multi-antenna system using a pilot signal included in a signal output from the network decoder, outputting a corresponding channel estimation value by estimating a channel environment based on a checked channel state; And
A channel-specific priority determiner for determining a priority for each channel based on a channel estimation value output from the channel estimator;
.

Images