KR20110097680A - Transmitter and transmitting method for multiple input multiple output transmission, receiver and receiving method - Google Patents

Abstract

A transmitter for transmitting data using multiple antennas performs multiple representation coding on the data to generate a plurality of representation data, and performs channel encoding on the plurality of representation data and transmits the channel encoded representation data through the multiple antennas. It includes a multiple input and output transmission unit. A receiver for receiving a signal transmitted from a transmitter using at least one antenna includes a channel estimator for estimating a channel corresponding to the at least one antenna based on the received signal, and feedback information to the received signal based on the channel estimation value. A multi-input / output decoder for generating a plurality of first decoding information by performing multiple input / output decoding of the applied input signal, and channel decoding the plurality of first decoding information, respectively, and generating feedback information as a result of the channel decoding is repeated a predetermined number of times. Subsequently, it includes a repetitive decoding unit for channel decoding the plurality of first decoding information, respectively, to generate a plurality of second decoding information, and a multi-expression decoding unit for multi-expression decoding the plurality of second decoding information.

Description

TRANSMITTER AND TRANSMITTING METHOD FOR MULTIPLE INPUT MULTIPLE OUTPUT TRANSMISSION, RECEIVER AND RECEIVING METHOD}

The present invention relates to a multiple input / output transmitter and transmission method, and a receiver and a reception method.

The mobile broadcast system includes a transmitter for transmitting image information and a receiver for receiving and playing the same. The transmitter and the receiver may be multiple input multiple output (MIMO) devices transmitting and receiving through multiple antennas. The channel capacity of the multiple input / output device is determined by the smaller number of transmit / receive antennas. Therefore, the receiver can inform the transmitter of the number of antennas thereof and can receive a signal suitable for the reception capability of the receiver. However, a transmitter that broadcasts video information does not transmit a signal considering only one receiver. Therefore, the receiver may not reproduce the image information according to its wireless environment or reception capability. In particular, when a transmitter transmits different information through a plurality of transmitting antennas, a receiver having fewer receiving antennas than the number of transmitting antennas may be difficult to receive due to signal interference between the antennas. As such, since a plurality of receivers receive signals in different radio environments and have different reception capabilities, it is difficult for a transmitter to provide an optimal service to all receivers.

SUMMARY OF THE INVENTION An object of the present invention is to provide a transmitter and a transmission method for performing multiple representation encoding and multiplexing of data, and to provide a receiver and a reception method for decoding the multiple representation encoded data regardless of the number of antennas of the receiver.

A transmitter for transmitting data using multiple antennas according to an embodiment of the present invention, the multiple representation coding unit for generating a plurality of representation data (descriptions) by multiple description coding (MDC) the data, and And a multiple input / output transmitter configured to channel-code the plurality of representation data and to transmit the channel-coded representation data through the multiple antennas.

The multiple representation code part makes the data into the plurality of representation data including information associated with each other.

The multiple input / output transmission unit corresponds to each of the plurality of packets and a parallel conversion unit for outputting the plurality of expression data into a plurality of packets in parallel, and generates a plurality of first transmission information by channel coding each of the plurality of packets. A plurality of channel encoders, a serial converter converting the plurality of first transmission information into a plurality of second transmission information corresponding to each of the plurality of antennas based on the number of the multiple antennas, and the plurality of second transmission informations It may include the multiple antenna for transmitting.

The parallel converter may determine the number of packets based on the plurality of representation data and the information of the channel coder.

The serial converter may align the plurality of first transmission information in series, and then generate the plurality of second transmission information corresponding to the multiple antennas based on the plurality of first transmission information aligned in series. .

The transmitter may further include a plurality of interleaving units for interleaving the plurality of first transmission information, respectively, before converting the plurality of first transmission information into the plurality of second transmission information.

A receiver for receiving a signal transmitted from a transmitter using at least one antenna according to an embodiment of the present invention, comprising: a channel estimator for estimating a channel corresponding to the at least one antenna based on a received signal; A first decoder for generating a plurality of first decoding information by multiple input / output decoding the input signal to which the feedback information is applied to the received signal based on the value, and channel decoding the plurality of first decoding information, respectively, After repeating the process of generating the feedback information a predetermined number of times as a result, a plurality of second decoding unit for generating a plurality of second decoding information by channel decoding each of the plurality of first decoding information, and the plurality of second And a third decoding unit for multiple representation decoding of the two decoding information.

The first decoder may determine the number of the plurality of first decoding information based on the number of representation data included in the received signal.

Each second decoder deinterleaves the interleaved first decoded information to generate a deinterleaved signal, a channel decoder to decode the deinterleaved signal to generate channel decoded information, and the channel decoded information. The interleaving unit may generate the feedback information by interleaving the channel decoding unit. The channel decoding unit may output the channel decoding information after repeating the predetermined number of times as the second decoding information.

The channel decoder may determine whether to stop repetition of channel decoding based on the reliability of the second decoding information.

The channel decoder may perform channel decoding by reflecting a decoding result of the third decoder.

The receiver further includes a serial converter for converting the plurality of second decoded information into serial before multiple representation decoding of the plurality of second decoded information.

A method for transmitting a signal using multiple antennas by a transmitter according to an embodiment of the present invention, the method comprising: generating a plurality of representation data by multiple representation encoding data, and making the plurality of representation data into a plurality of packets in parallel Generating a plurality of first transmission information by channel encoding the plurality of packets, respectively, and outputting the plurality of first transmission information corresponding to each of the plurality of antennas based on the number of the plurality of antennas. Converting the transmission information, and transmitting the plurality of second transmission information using the multiple antennas.

The generating of the representation data makes the data into the plurality of representation data including information associated with each other.

The converting into the plurality of second transmission information may include: arranging the plurality of first transmission information in series, and then converting the plurality of first transmission information corresponding to the plurality of antennas based on the plurality of first transmission information in series. 2 Transmission information can be generated.

A method for receiving a signal from a transmitter by a receiver according to an embodiment of the present invention, the method comprising: receiving the signal using at least one antenna, estimating a channel corresponding to the at least one antenna based on the received signal Generating decoding information corresponding to the received signal by repeatedly performing a decoding process including multiple input / output decoding and channel decoding based on the channel estimation value, and performing multi-expression decoding on the decoding information. Include.

The generating of the decoding information may include performing the multiple input / output decoding for decoding the input signal to which the feedback information is applied to the received signal based on the channel estimation value, and channel decoding each of the multiple input / output decoding results. And after repeating the process of generating the feedback information as a result of the channel decoding a predetermined number of times, generating the decoding information by channel decoding the result of the multiple input / output decoding.

The generating of the decoding information may generate the decoding information by determining whether to stop the repetition based on the reliability of the result of the channel decoding.

In the multi-expression decoding, the quality of the decoding information including the expression data may be determined, and the expression data may be selected and multi-expression decoded based on the determined result.

According to an embodiment of the present invention, a receiver may receive a signal and decode the received signal regardless of the channel environment and the number of receive antennas. Therefore, the transmitter can provide optimal service to all receivers while efficiently using radio resources.

1 is a diagram illustrating a transmitter according to an embodiment of the present invention.
2 is a diagram illustrating a receiver according to an embodiment of the present invention.
3 is a flowchart illustrating a transmission method according to an embodiment of the present invention.
4 is a flowchart illustrating a receiving method according to an embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement 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 the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise.

Referring now to the drawings will be described in detail with respect to multiple input / output transmitter and transmission method, and receiver and reception method according to an embodiment of the present invention.

1 is a diagram illustrating a transmitter according to an embodiment of the present invention.

Referring to FIG. 1, the transmitter 100 includes a multi-expression coder 110, a parallel converter 120, a plurality of channel coders 130, a plurality of interleaving units 140, a serial converter 150, and A plurality of transmit antennas 160 is included.

The multiple description coder 110 generates a plurality of description data by performing multiple description coding (MDC) on the data. The multiple representation encoding scheme is a technique of dividing one data into a plurality of representation data and encoding the plurality of representation data including information associated with each other. That is, the multiple representation code unit 110 makes the original data into a plurality of representation data. In this case, the plurality of representation data are represented by different information but associated with each other. Therefore, even if the receiver 200 does not receive some representation data due to the channel environment or the number of receive antennas, the receiver 200 may decode the original data based on the successfully received representation data.

The serial to parallel converter 120 outputs a plurality of representation data output from the multiple representation code unit 110 in parallel. The transmitter 100 individually encodes a plurality of representation data output from the multiple representation coder 110 and transmits them through different channels. For this purpose, the parallel converter 120 may include a plurality of serial inputs. Outputs the expression data in parallel. At this time, the parallel converter 120 generates a plurality of packets corresponding to the plurality of pieces of representation data, for example, L (L is a natural number) packets and outputs them in parallel.

The plurality of channel encoders 130 correspond to each of the plurality of packets transferred from the parallel converter 120, and channel-code the corresponding packets. The plurality of channel encoders 130 may channel-encode a packet to which information on a Cyclic Redundancy Check (CRC) to which the receiver 200 checks an error of a packet is added.

The plurality of interleavers 140 correspond to the plurality of channel coders 130, respectively, and interleave the output signals of the corresponding channel coders 130 to generate interleaved signals. The plurality of interleaving units 140 may interleave different algorithms.

The parallel to serial converter 150 aligns the L signals input in parallel and reconstructs them in accordance with the number of transmission antennas N _T , thereby corresponding to each of the plurality of transmission antennas 160. Generate the output signal of. In this case, the serial converter 150 may receive L signals in which pilots for channel estimation of the receiver 200 are inserted, respectively, in parallel.

The plurality of transmit antennas 160 transmits multiple input / output signals (MIMO) transmitted from the serial converter 150.

2 is a diagram illustrating a receiver according to an embodiment of the present invention.

Referring to FIG. 2, the receiver 200 includes at least one receiving antenna 210, at least one channel estimator 220 corresponding to the receiving antenna 210, a multiple input / output decoder 230, and a plurality of iterative decodings. A unit 240, a serial converter 250, and a multi-expression decoder 260 are included. The plurality of repetitive decoders 240 correspond to signals transmitted from the multiple input / output decoders 230, and each repetitive decoder 240 includes a deinterleaving unit 241, a channel decoder 243, and an interleaving unit ( 245).

The receiving antenna 210 receives a signal transmitted from the transmitter 100. In this case, the reception antenna 210 may be at least one, and if there are a plurality of N _R , the plurality of reception antennas 210 operate in a multiple input, multiple output, MIMO scheme.

The channel estimator 220 estimates channel information of the corresponding antenna 210 based on the signal received through the corresponding antenna 210. The channel estimator 220 calculates channel information, that is, a radio channel matrix, using a pilot for channel estimation inserted by the transmitter 100. For example, when the transmitter 100 inserts L pilots and transmits the L pilots, the channel estimator 220 corresponding to the first antenna uses the L pilots to transmit the radio channel matrix H _{1 x Pilot 1, 2,. ., L} )

The MIMO decoder 230 repeatedly performs iterative MIMO decoding based on channel information of the reception antenna 210. The multiple input / output decoder 230 transmits the decoding result to the plurality of iterative decoders 240. In this case, the multiple input / output decoder 230 generates a plurality of signals based on the number of expression data L transmitted by the transmitter 100, and transmits the plurality of signals to the corresponding plurality of repeating decoders 240. I can deliver it. The multiple input / output decoder 230 repeats a process of receiving feedback information from the plurality of repetitive decoders 240.

The plurality of iterative decoders 240 correspond to each of a plurality of signals received from the multiple input / output decoders 230, and each of the iterative decoders 240 channel-decodes the received signal and multiplies the channel-decoded information. The process of feeding back to the input / output decoder 230 is repeated to output the final channel decoding result. To this end, each repetitive decoder 240 includes a deinterleaving unit 241, a channel decoding unit 243, and an interleaving unit 245.

The deinterleaver 241 deinterleaves the signal received from the multiple input / output decoder 230, and the interleaver 245 interleaves the output information of the channel decoder 243. ) To feed back to the multiple input / output decoder 230.

The channel decoder 243 repeatedly performs decoding while exchanging decoding results with the multiple input / output decoder 230. In particular, the channel decoder 243 receives a soft decision input from the multiple input / output decoder 230 and performs soft input soft output (SISO) decoding to output a soft decision decoding result. In particular, the channel decoder 243 repeatedly decodes to obtain a reliability that is an index for determining whether the decoding result is close to the original data. In this case, the apriori probability and the aposteriori probability may be used. The channel decoder 243 may use a log-likelyhood ratio obtained by using the probability for decoding. As described above, the channel decoder 243 repeatedly decodes to increase the reliability of the decoding result. Additionally, the channel decoder 243 reflects decoding information of the multi-expression decoding unit 260, for example, the multi-expression decoding result or redundancy information. The reliability of the decoding result can be obtained. Next, the channel decoder 243 repeatedly decodes a predetermined number of times and stops decoding. The channel decoder 243 may determine whether to stop decoding based on the reliability of the decoding result. Alternatively, the channel decoder 243 may complete decoding by repeating a predetermined number of repetitions, and may adjust the number of repetitions according to a delay time or power consumption of the receiver 200.

The serial converter 250 aligns the signals received from the plurality of iterative decoders 240 in series and transfers them to the multiple representation decoder 260. In particular, since the signal received from the iterative decoding unit 240 by the serial converter 250 includes the expression data, the serial converter 250 transmits the plurality of expression data to the multiple expression decoder 260. In this case, the serial converter 250 may select and transmit the representation data having good quality to the multiple representation decoder 260. For example, the serial converter 250 may select an error-free representation data based on the information inserted by the transmitter 100 (Cyclic Redundancy Check, CRC), and deliver it to the serial stream.

The multiple description decoder (MD decoder) 260 combines and decodes a plurality of input expression data. Although the plurality of representation data are expressed with different information but are related to each other, the plurality of representation data may be decoded to a value close to the original data based on the plurality of input representation data.

3 is a flowchart illustrating a transmission method according to an embodiment of the present invention.

Referring to FIG. 3, the transmitter 100 generates a plurality of representation data by performing multi-expression encoding on data to be transmitted (S310). The plurality of representation data includes information associated with each other.

The transmitter 100 packetizes the plurality of expression data and outputs them in parallel (S320). The transmitter 100 outputs the representation data in parallel in a packet to transmit the plurality of representation data through different channels.

The transmitter 100 channel codes each of the plurality of packets (S330). The transmitter 100 may channel-encode a packet to which information (CRC) to which the receiver 200 checks an error of a packet is added. The transmitter 100 may interleave and transmit each channel encoded information. In addition, the transmitter 100 may insert a pilot for channel estimation into each channel encoded information.

The transmitter 100 makes a plurality of channel-coded information into a signal corresponding to each of the transmitting antennas (S340). The transmitter 100 aligns the plurality of channel-coded information in series and then reconfigures the plurality of channel encoded information to generate a plurality of output signals corresponding to each of the plurality of transmission antennas.

The transmitter 100 transmits a signal through a plurality of transmit antennas (S350).

4 is a flowchart illustrating a receiving method according to an embodiment of the present invention.

Referring to FIG. 4, the receiver 200 receives a signal through a reception antenna in step S410. In this case, there may be at least one receiving antenna. The received signal includes multiple representation encoded representation data.

The receiver 200 estimates a channel corresponding to each receive antenna based on the received signal (S420). The receiver 200 may calculate radio channel information by using the pilot inserted by the transmitter 100.

The receiver 200 decodes multiple input / output (MIMO) based on the channel information and the input signal (S430). The receiver 200 generates a plurality of input / output decoded pieces of decoded information in order to channel decode the separately encoded channel data. The receiver 200 outputs a plurality of decoding information in parallel. In this case, the receiver 200 may determine the number of decoded information to be output in parallel based on the number of representation data transmitted by the transmitter 100. The receiver 200 may know the number of representation data through the received signal.

The receiver 200 performs channel decoding on each of the plurality of decoding information (S440). In particular, the receiver 200 receives an input of a soft-determined multiple input / output decoding result and decodes a soft input / output (SISO) that outputs a soft-determined channel decoding result. To this end, the receiver 200 obtains a probability that the result of the channel decoding is close to the original data and uses the decoding.

The receiver 200 determines whether to repeat decoding (S450). The receiver 200 repeats multiple input / output (MIMO) decoding and soft input / output (SISO) decoding to increase the reliability of the decoding result. The receiver 200 determines whether to repeat decoding in various ways. For example, the receiver 200 may determine whether to repeat the decoding by a predetermined number of repetitions, or determine whether the decoding result exceeds a reference value. Alternatively, the receiver 200 may elastically adjust the number of repetitions according to a delay time or power consumption. When the decoding is repeated, the receiver 200 repeats the multiple input / output (MIMO) decoding of the operation S430 by reflecting the soft I / O (SISO) decoding result.

If the decoding does not repeat the decoding, the receiver 200 completes the decoding and decodes the multiple representations based on the result of the final soft I / O (SISO) decoding (S460). The receiver 200 combines and decodes a plurality of representation data included in the result of the final soft I / O decoding. In this case, the receiver 200 may select and decode the representation data having good quality and determine the quality of the representation data based on the information (CRC) inserted by the transmitter 100.

As described above, according to the exemplary embodiment of the present invention, the receiver 200 may decode the received signal by receiving the signal regardless of the channel environment and the number of receiving antennas. In addition, the transmitter 100 may provide an optimal service to all receivers while efficiently using radio resources.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Claims (19)

A transmitter for transmitting data using multiple antennas,
A multiple description coder for generating a plurality of description data by multiple description coding (MDC) of the data, and
A channel input / output unit configured to channel-code the plurality of representation data and to transmit the channel-coded representation data through the multiple antennas
Transmitter comprising a. In claim 1,
The multi-expression code part
A transmitter which makes said data into said plurality of representation data comprising information associated with each other. In claim 1,
The multiple input and output transmission unit
A parallel converter for outputting the plurality of expression data into a plurality of packets in parallel,
A plurality of channel coders corresponding to each of the plurality of packets, the plurality of channel encoders generating a plurality of first transmission information by channel coding each of the plurality of packets;
A serial converter converting the plurality of first transmission information into a plurality of second transmission information corresponding to each of the multiple antennas based on the number of the multiple antennas, and
The multiple antennas transmitting the plurality of second transmission information
Transmitter comprising a. 4. The method of claim 3,
The parallel converter
And a transmitter for determining the number of packets based on the plurality of representation data and information on the channel coder. 4. The method of claim 3,
The serial converter
And arranging the plurality of first transmission information in series, and generating the plurality of second transmission information corresponding to the multiple antennas based on the plurality of first transmission information arranged in series. 4. The method of claim 3,
And a plurality of interleaving units for interleaving the plurality of first transmission information, respectively, before converting the plurality of first transmission information into the plurality of second transmission information. A receiver for receiving a signal transmitted from a transmitter using at least one antenna,
A channel estimator estimating a channel corresponding to the at least one antenna based on a received signal;
A first decoder configured to generate a plurality of first decoding information by multiple input / output decoding of an input signal to which the feedback information is applied to the received signal based on the channel estimate value;
After the channel decoding of the plurality of first decoding information, respectively, the step of generating the feedback information as a result of the channel decoding is repeated a certain number of times, the plurality of first decoding information by channel decoding, respectively, a plurality of second decoding A plurality of second decoders for generating information, and
A third decoding unit to multi-express decode the plurality of second decoding information
Receiver comprising a. In claim 7,
The first decoder is
And determining the number of the plurality of first decoding information based on the number of representation data included in the received signal. In claim 7,
Each second decoder is
A deinterleaving unit configured to deinterleave corresponding first decoding information to generate a deinterleaved signal;
A channel decoder for generating channel decoding information by channel decoding the deinterleaved signal; and
An interleaving unit interleaving the channel decoding information to generate the feedback information
Including;
And the channel decoding unit outputs the channel decoding information after repeating the predetermined number of times as the second decoding information. In claim 9,
The channel decoder is
And determining whether to stop repeating channel decoding based on the reliability of the second decoding information. In claim 9,
The channel decoder is
A receiver for channel decoding reflecting the decoding result of the third decoder. In claim 7,
A serial converter converts the plurality of second decoded information into serial before multi-expression decoding the plurality of second decoded information.
Receiver comprising more. A method in which a transmitter transmits a signal using multiple antennas,
Generating a plurality of representation data by multiple representation encoding the data;
Outputting the plurality of representation data into a plurality of packets in parallel,
Generating a plurality of first transmission information by channel coding each of the plurality of packets;
Converting the plurality of first transmission information into a plurality of second transmission information corresponding to each of the multiple antennas based on the number of the multiple antennas, and
Transmitting the plurality of second transmission information using the multiple antennas
Transmission method comprising a. In claim 13,
Generating the expression data is
And transmitting the data into the plurality of representation data including information associated with each other. In claim 13,
Converting to the plurality of second transmission information
And arranging the plurality of first transmission information in series, and generating the plurality of second transmission information corresponding to the multiple antennas based on the plurality of first transmission information arranged in series. A method by which a receiver receives a signal from a transmitter,
Receiving the signal using at least one antenna,
Estimating a channel corresponding to the at least one antenna based on the received signal;
Generating decoding information corresponding to the received signal by repeatedly performing a decoding process including multiple input / output decoding and channel decoding based on the channel estimate value; and
Multi-express decoding the decoding information
Receiving method comprising a. The method of claim 16,
Generating the decoding information
Performing the multiple input / output decoding for decoding an input signal to which feedback information is applied to the received signal based on the channel estimate value, and
Channel decoding the result of the multi-input / output decoding, and generating the feedback information as a result of the channel decoding for a predetermined number of times, and generating the decoded information by channel decoding the result of the multi-input / output decoding respectively.
Receiving method comprising a. The method of claim 17,
Generating the decoding information
And determining whether to stop the repetition based on the reliability of the result of the channel decoding to generate the decoding information. The method of claim 17,
The multi-expression decoding step
A receiving method of determining the quality of the decoded information including the representation data, and selecting and expressing the representation data based on the determination result.

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