KR101372196B1 - Adaptive modulation method using psnr and apparatus thereof - Google Patents

Abstract

The present invention relates to an adaptive modulation method using a PSNR and a device thereof. According to the present invention, the present invention provides an adaptive modulation method using a PSNR which includes: a step of rearranging a bit order of a plurality of transmission data corresponding to one pixel of image data which is to be transmitted and dividing the transmission data into a first symbol which corresponds to a first subcarrier and a second symbol which corresponds to a second subcarrier; a step of transmitting a preamble signal formed with a plurality of preamble symbols to a reception stage a plurality of times; a step of receiving a QoS value which is acquired for the each preamble signal from the reception stage; a step of matching a modulation method which has the highest PSNR value corresponding to the acquired QoS measurement value to the each of the preamble symbols; a step of modulating the first and second symbols which are included in the transmission data in correspondence to the modulation method matched by preamble symbol; and a step of successively transmitting the first symbols and second symbols. According to the adaptive modulation method and device thereof, the MSB error rate of uncompressed image data and the quality of received image data can be improved by determining a modulation method having the highest PSNR value by QoS measurement section based on the PSNR. [Reference numerals] (AA) Start; (BB) End; (S410) Rearranging the bit order of a plurality of transmission data corresponding to one pixel of the image data and dividing into the first and second symbols; (S420) Transmitting a preamble signal formed with a plurality of preamble symbols a plurality of times; (S430) Receiving the acquired SNR value for each of the preamble symbol from the reception stage; (S440) Matching a demodulation method having the highest PSNR value corresponding to the acquired SNR for the each of preamble symbols; (S450) Demodulating the first and second symbols included in the plurality of transmission data corresponding to a demodulation method by matched preamble symbol; (S460) Successively transmitting the demodulated first symbols and second symbols

Description

Adaptive modulation method using PSNR and apparatus

The present invention relates to an adaptive modulation method and apparatus using PSNR, and more particularly, to an adaptive modulation method and apparatus using PSNR for adaptively modulating and transmitting transmission data according to a channel environment.

In general, the adaptive modulation scheme is a method of changing the transmission scheme according to the situation of the communication channel. 1 is a diagram illustrating a conventional AMC (Adaptive Modulation & Coding) scheme.

FIG. 1 determines one of BPSK, QPSK and 16QAM based on a value of 10 ⁻³ using a BER (Bit Error Rate) according to a reception channel environment. If the signal-to-noise ratio (SNR) of the receiver is less than about 9.8 dB, data modulation is performed using the BPSK method, the QPSK method if more than 9.8 dB to less than 16.4 dB, and the 16 QAM method if more than 16.4 dB.

By the way, in the conventional method, it is used on the condition that the importance of each bit constituting the transmission data is the same. That is, since the error rates of the Most Significant Bit (MSB) and the Least Significant Bit (LSB) are the same, it is difficult to find an optimal performance when transmitting uncompressed image data. In other words, when using the conventional method, since the basic characteristics of the uncompressed image data carrying important data in the MSB are transmitted and transmitted, there is a limit in deriving an optimal performance of the received image data.

The background technology of the present invention is disclosed in Korean Patent Publication No. 2011-0019105.

An object of the present invention is to provide an adaptive modulation method and apparatus using PSNR that can reduce the error rate of image data and improve the quality of received image data.

According to an embodiment of the present invention, a bit order of a plurality of transmission data corresponding to one pixel of image data to be transmitted is rearranged, and a first symbol corresponding to a first subcarrier and a second subcarrier corresponding to a second subcarrier are respectively transmitted. Dividing the signal into a plurality of symbols including a symbol, transmitting a preamble signal composed of a plurality of preamble symbols to the receiver a plurality of times, receiving a signal quality measurement value obtained for each of the preamble symbols from the receiver; Matching a modulation scheme having a highest PSNR value with respect to each of the plurality of preamble symbols in response to the obtained signal quality measurement value, and matching the plurality of transmission data to the plurality of preamble symbols according to the matching modulation scheme for each preamble symbol. Modulating each of the first and second symbols included, and a plurality of phases Claim to provide an adaptive modulation method using the PSNR comprising first sequentially transmitted to the symbol and the second symbol.

Here, the i-th transmitted symbol included in the transmission data may be modulated corresponding to the i-th preamble symbol.

In the transmitting of the preamble signal to the receiver a plurality of times, the plurality of preamble symbols may be transmitted by BPSK modulation.

The bit corresponding to the MSB of the transmission data corresponds to the MSB of the real and imaginary parts of the first and second symbols, and the bit corresponding to the LSB of the transmission data is the first. The bit order of the transmission data may be rearranged to correspond to the LSBs of the real and imaginary parts of the first symbol and the second symbol.

Here, the transmission data is uncompressed image data including an MSB consisting of 1 to 4 bits and an LSB consisting of 5 to 8 bits, and the first symbol includes 1, 5, 3, and 7 bits. The symbols may be sequentially arranged in 4-bit units, and the second symbol may be a symbol in 4-bit units in which second, sixth, fourth, and eighth bits of the transmission data are sequentially arranged.

In this case, the modulation scheme may be any one of BPSK, QPSK, and 16QAM.

In the step of sequentially transmitting a plurality of the first symbol and the second symbol, in the case of the BPSK modulation scheme, only the first bit of the 4 bits constituting the first or second symbol is transmitted, and the QPSK modulation scheme In the case of transmitting only the first and third bits, in the case of the 16QAM modulation scheme, all the bits are transmitted, and the receiving end may arbitrarily set an unreceived bit value.

The signal quality measurement value may be one of SNR (signal-to-noise ratio), BER (bit error rate), and BLER (block error rate).

In addition, the present invention rearranges the bit order of a plurality of transmission data corresponding to one pixel of the image data to be transmitted, and sets each transmission data to a first symbol corresponding to the first subcarrier and a second subcarrier corresponding to the second subcarrier. A data disposition unit divided into a plurality of symbols including two symbols, a preamble transmitter configured to transmit a preamble signal composed of a plurality of preamble symbols to a receiver a plurality of times, and a signal quality measurement value obtained for each of the preamble symbols from the receiver; A signal quality measurement value receiving unit for receiving a signal; a modulation scheme matching unit for matching a modulation scheme having a highest PSNR value with respect to each of the plurality of preamble symbols corresponding to the obtained signal quality measurement value, and the matched preamble symbol The plurality of transmission data included in the plurality of transmission data corresponding to a respective modulation scheme; Provided is an adaptive modulation apparatus using a PSNR including a symbol modulator for modulating a first symbol and a second symbol, and a packet transmitter for sequentially transmitting a plurality of the first and second symbols.

According to the adaptive modulation method and apparatus using PSNR according to the present invention, the MSB error rate of uncompressed image data can be reduced by determining the modulation method having the highest PSNR value for each signal quality measurement interval based on the PSNR. There is an advantage that can improve the quality of the received image data.

1 is a diagram illustrating a conventional AMC scheme.
2 is a diagram illustrating a PSNR-based AMC scheme used in an embodiment of the present invention.
3 is a block diagram of an adaptive modulation device using PSNR according to an embodiment of the present invention.
4 is a flowchart of an adaptive modulation method using FIG. 3.
FIG. 5 is a diagram illustrating transmission data in step S410 of FIG. 4.
6 is an exemplary diagram of a data transmission arrangement according to an embodiment of the present invention.
FIG. 7 is a configuration diagram illustrating steps S450 to S460 of FIG. 4.

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 relates to an adaptive modulation method and apparatus using PSNR, and based on PSNR (Peak Signal to Noise Ratio) when transmitting data symbols constituting image data, an optimal modulation method according to signal quality measurement values is provided. Choose. Here, the signal quality measurement value may be one of SNR (signal-to-noise ratio), BER (bit error rate), and BLER (block error rate). In the present invention, the case where the signal quality measurement value is an SNR value will be described as an example.

2 is a diagram illustrating a PSNR-based AMC scheme used in an embodiment of the present invention. 2 corresponds to a result measured in an additive white Gaussian noise (AWGN) channel environment. The larger the PSNR value, the better the channel condition.

In the present embodiment, when the data symbol is transmitted, the modulation scheme that is optimal for the SNR value obtained at the receiving end is switched. For example, if the SNR value of the receiver is less than about 2.9dB, the data symbol is transmitted using the BPSK method, the QPSK method when the 2.9dB or more is less than 14.8dB, and the 16QAM method when the receiver's SNR is 14.8dB or more.

Hereinafter, an adaptive modulation apparatus using PSNR according to an embodiment of the present invention will be described. 3 is a block diagram of an adaptive modulation device using PSNR according to an embodiment of the present invention.

The apparatus 100 includes a data relocator 110, a preamble transmitter 120, a signal quality measurement value receiver 130, a modulation scheme matcher 140, a symbol modulator 150, and a packet transmitter 160. It includes. Such an apparatus 100 corresponds to a transmitting end for transmitting data.

The data rearranging unit 110 rearranges the bit order of the plurality of transmission data corresponding to one pixel of the image data to be transmitted, and then transmits each transmission data with a first symbol corresponding to a first subcarrier (subcarrier). It is divided into a plurality of symbols including a second symbol corresponding to a second subcarrier (subcarrier). The transmission data may be divided into two or more symbols, but in the present embodiment, divided into two symbols will be described as an embodiment.

The preamble transmitter 120 transmits a preamble signal composed of a plurality of preamble symbols to the receiver a plurality of times. Here, the preamble signal may be transmitted at least twice or more times. The signal quality measurement value receiver 130 receives a signal quality measurement value, that is, an SNR value, obtained for each of the preamble symbols from the receiver.

The modulation scheme matching unit 140 matches a modulation scheme having the highest PSNR value with respect to each of the plurality of preamble symbols in response to the obtained SNR.

The symbol modulator 150 modulates the first symbol and the second symbol included in the plurality of transmission data, respectively, in response to the matching preamble symbol-based modulation scheme. Finally, the packet transmitter 160 sequentially transmits a plurality of modulated first symbols and second symbols.

4 is a flowchart of an adaptive modulation method using FIG. 3. Hereinafter, an adaptive modulation method using PSNR according to an embodiment of the present invention will be described in detail.

First, the data rearranging unit 110 rearranges the bit order of the plurality of transmission data corresponding to one pixel of the image data to be transmitted, and transmits the first symbol and the second sub to each transmission data corresponding to the first subcarrier. The second symbol corresponding to the carrier is divided (S410).

FIG. 5 is a diagram illustrating transmission data in step S410 of FIG. 4. In the following embodiment, a case in which transmission data is 8 bits is an example, but the present invention is not necessarily limited thereto. When the transmission data is 8 bits, one pixel constituting the image data is represented by 8 bits.

At the top of FIG. 5 is shown a basic form of transmission data. The transmission data corresponds to uncompressed image data including an MSB composed of 1 to 4 bits and an LSB composed of 5 to 8 bits. Here, the reason for rearranging the order of bits constituting the transmission data is that MSB, which is the most significant bit, is the most important in the image data.

5 shows a first symbol and a second symbol divided into two after the bit order is rearranged. The first symbol Symbol 1 is a symbol of a 4-bit unit in which 1, 5, 3, and 7th bits of the transmission data are sequentially arranged. The second symbol Symbol 2 is a symbol in units of 4 bits in which 2nd, 6th, 4th, and 8th bits of the transmission data are sequentially arranged.

That is, in step S410, the bit order of the transmission data is rearranged, and the bits corresponding to the MSBs of the transmission data correspond to MSBs of real and imaginary parts of the first and second symbols. The bit order of the transmission data is rearranged such that the bits corresponding to the LSBs of the transmission data correspond to the LSBs of the real and imaginary parts of the first and second symbols.

More specifically, of the first to fourth bits corresponding to the MSB of the transmission data, the first bit is the MSB of the real part of the first symbol, and the third bit is the MSB of the imaginary part of the first symbol. As a result, it can be seen that the second bit is arranged as the MSB of the real part of the second symbol, and the fourth bit is arranged as the MSB of the imaginary part of the second symbol. That is, all of the existing MSB bits in the transmission data are located in the MSB of the real / imaginary part even in the first and second symbols.

Also, among the fifth through eighth bits corresponding to the LSB, the fifth bit is the LSB of the real part of the first symbol, the seventh bit is the LSB of the imaginary part of the first symbol, 6 The first bit is the LSB of the real part of the second symbol, and the eighth bit is the LSB of the imaginary part of the second symbol. That is, all of the existing LSB bits in the transmission data are located in the LSB of the real / imaginary part even in the first and second symbols.

Next, the preamble transmitter 120 transmits a preamble signal composed of a plurality of preamble symbols to the receiver a plurality of times (S420).

6 is an exemplary diagram of a data transmission arrangement according to an embodiment of the present invention. In the present embodiment, a transmission symbol in a preamble signal transmission interval is called a preamble symbol, and a transmission symbol in a packet transmission interval is defined as a data symbol or simply a symbol.

First, before transmitting the data symbol, the preamble symbol is transmitted to the receiving end. As an example, the preamble transmitter 120 continuously transmits 256 preamble symbols twice over the same channel. Here, each preamble symbol is transmitted by BPSK modulation. Accordingly, only the first bit of the 4 bits constituting the preamble symbol is transmitted.

The receiver estimates a channel state and obtains an SNR value for each of the preamble symbols. Channel estimation uses the same conventional channel estimation method. That is, the channel is estimated through Equation 1 using two consecutively transmitted symbols.

는 j번째 프리앰블 신호에 포함된 i번째 프리앰블 심볼에 대한 채널 추정 값,

는 상기 i번째 프리앰블 심볼의 수신 데이터 값,

는 상기 i번째 프리앰블 심볼의 송신 데이터 값이다. here,

Is a channel estimate value for the i th preamble symbol included in the j th preamble signal,

Is a received data value of the i th preamble symbol,

Is the transmission data value of the i-th preamble symbol.

In this embodiment, since the preamble signal is transmitted twice in succession, j = 1,2. In addition, since the preamble signal includes 256 preamble symbols, i = 1 to N and N = 256 in this embodiment.

By calculating the channel estimation values for each of the two preamble signals through Equation 1 and then averaging them, an average channel for the i th preamble symbol can be estimated as shown in Equation 2. The estimated channel is used for channel compensation.

Here, CH _i represents an average estimated channel value for the i-th preamble symbol.

In addition to channel estimation, the receiver must find an SNR value for each preamble symbol. To this end, first, the noise power P _noise is measured using the received preamble signal.

을 수학식 4와 같이 구한다.Subsequently, the SNR value for the i th preamble symbol

Is obtained as in Equation 4.

The SNR value for each preamble symbol thus obtained is used to select a modulation method of data symbols transmitted from the transmitter to each subcarrier. That is, the signal quality measurement value receiver 130 receives the SNR values obtained for each of the preamble symbols from the receiver (S430).

Thereafter, the modulation scheme matching unit 140 matches a modulation scheme having the highest PSNR value with respect to each of the plurality of preamble symbols in response to the obtained SNR (S440).

Here, matching of the modulation scheme may be referred to the drawing of FIG. 2. As an example, if the SNR value obtained for the first preamble symbol among a total of 256 preamble symbols is less than 2.9 dB, the BPSK modulation scheme is corresponded. In addition, if the SNR value obtained for the second preamble symbol is more than 2.9 dB or less than 14.8 dB, the QPSK modulation scheme is corresponded. In addition, if the SNR value obtained for the third preamble symbol is 14.8 dB or more, the 16QAM modulation scheme is corresponded. When the modulation is performed based on the PSNR, the MSB error rate of the uncompressed image data can be reduced and optimal performance can be exhibited.

In this way, an appropriate modulation scheme is matched to the i-th subcarrier corresponding to the i-th preamble symbol.

Next, the symbol modulator 150 modulates the first symbol and the second symbol included in the plurality of transmission data, respectively, in response to the matched modulation scheme for each preamble symbol (S450). Thereafter, the packet transmitter 160 sequentially transmits the plurality of first symbols and the second symbols modulated in operation S450 to the receiver (S360).

Here, the first symbol and the second symbol correspond to data symbols transmitted in the packet transmission section following the preamble signal transmission section in FIG. 6. In this case, since the first and second symbols are included in each transmission data, the plurality of transmission data transmitted in the packet transmission interval includes a plurality of first and second symbols. In actual data transmission, the first symbol and the second symbol of each transmission data are alternately transmitted. This can be confirmed through the following FIG. 7.

FIG. 7 is a configuration diagram illustrating steps S450 to S460 of FIG. 4. 7 shows an example of an i th data symbol transmitted for a plurality of transmission data.

In the case of FIG. 7, a total of 256 data symbols are generated by the first and second symbols individually included in a total of 128 transmission data. The even-numbered symbols of the plurality of transmission data may correspond to the first symbol of each transmission data, and the odd-numbered symbols may correspond to the second symbol. Accordingly, the first symbol and the second symbol of each transmission data are sequentially transmitted.

Here, the i-th transmitted symbol is modulated corresponding to the i-th preamble symbol. For example, in the above example, since the QPSK modulation scheme has been matched with respect to the second preamble symbol, the second transmitted data symbol (the second symbol with i = 2 in FIG. 7) is modulated with the corresponding QPSK modulation scheme. do.

In the modulation scheme item of FIG. 7, a modulation scheme applied to each i-th symbol is illustrated. In addition, the number assigned to each bit digit in the transmission symbol item means a bit digit rather than a bit value (see FIG. 5 above), and the first symbol and the second symbol are distinguished from each other.

In the case of the first symbol, since it is modulated and transmitted in the BPSK scheme, only the first bit of the four bits is transmitted (see shading processing). In the receiver side receiving the BPSK modulated first symbol, the second to fourth bit values which are not received are set to arbitrary (ex, 0) values.

In addition, in the case of the second symbol, since it is modulated and transmitted in the QPSK scheme, only the first and third bits of four bits are transmitted (see shading processing). The receiving end receiving the QPSK modulated second symbol sets the second and fourth bit values that are not received to random (ex, 0) values.

In addition, since the third symbol is modulated and transmitted in the 16QAM scheme, all the bits of the four bits are transmitted (see the shade processing). At this time, since all four bits are transmitted, there are no bits randomly processed at the receiving end.

According to this embodiment of the present invention, the modulation scheme is determined in consideration of the PSNR (maximum signal to noise ratio) of the image according to the signal-to-noise ratio (SNR) for the received signal. That is, when the channel efficiency is poor and transmission efficiency is low (when the SNR is very low), the reception performance is improved by using a BPSK modulation scheme that transmits only the MSB of data symbols. Use a modulation scheme. Accordingly, the maximum signal noise ratio of the image can be increased and the image quality can be improved.

According to the adaptive modulation method and apparatus using the PSNR according to the present invention as described above, the MSB error rate of the uncompressed image data can be reduced by determining the modulation method having the highest PSNR value for each SNR section based on the PSNR. There is an advantage that can improve the quality of the received image data.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: adaptive modulation device using PSNR
110: data relocator 120: preamble transmitter
130: signal quality measurement value receiving unit 140: modulation method matching unit
150: symbol modulation unit 160: packet transmission unit

Claims (16)

Rearranging the bit order of the plurality of transmission data corresponding to one pixel of the image data to be transmitted, each transmission data comprising a first symbol corresponding to the first subcarrier and a second symbol corresponding to the second subcarrier Dividing into a plurality of symbols;
Transmitting a preamble signal consisting of a plurality of preamble symbols to a receiving terminal a plurality of times;
Receiving a signal quality measurement value obtained for each of the preamble symbols from the receiving end;
Matching a modulation scheme having a highest PSNR value with respect to each of the plurality of preamble symbols corresponding to the obtained signal quality measurement value;
Modulating each of the first symbol and the second symbol included in the plurality of transmission data corresponding to the matched modulation scheme for each preamble symbol; And
Sequentially transmitting a plurality of said first and second symbols,
And an i-th transmitted symbol included in the transmission data is modulated to correspond to the i-th preamble symbol. delete The method according to claim 1,
The step of transmitting the preamble signal to the receiver a plurality of times,
Adaptive modulation method using PSNR for BPSK modulation and transmitting the plurality of preamble symbols, respectively. The method according to claim 1,
Bits corresponding to the MSB of the transmission data correspond to MSBs of the real and imaginary parts of the first and second symbols, and bits corresponding to the LSB of the transmission data are the first symbols. And reordering the bit order of the transmitted data to correspond to LSBs of a real part and an imaginary part of a second symbol. The method of claim 4,
The transmission data is uncompressed image data including an MSB composed of 1 to 4 bits and an LSB composed of 5 to 8 bits.
The first symbol is a symbol in units of 4 bits in which the 1st, 5th, 3rd, 7th bits of the transmission data are sequentially arranged, and the 2nd symbol is the 2nd, 6th, 4th, 8th bits of the transmission data sequentially. Adaptive modulation method using PSNR, which is a 4-bit symbol arranged by. The method according to claim 5,
The modulation method is an adaptive modulation method using PSNR which is any one of BPSK, QPSK, 16QAM. The method of claim 6,
In the step of sequentially transmitting a plurality of the first symbol and the second symbol,
In the case of the BPSK modulation scheme, only the first bit of four bits constituting the first or second symbol is transmitted, in the case of the QPSK modulation scheme, only the first and third bits are transmitted, and in the case of the 16QAM modulation scheme, all the bits are transmitted. To send,
Adaptive receiving method using the PSNR to the receiver to arbitrarily set the unreceived bit value. The method according to claim 1,
The signal quality measurement value,
Adaptive modulation method using PSNR which is one of signal to noise ratio (SNR), bit error rate (BER), and block error rate (BLER). Rearranging the bit order of the plurality of transmission data corresponding to one pixel of the image data to be transmitted, each transmission data comprising a first symbol corresponding to the first subcarrier and a second symbol corresponding to the second subcarrier A data placement unit dividing the plurality of symbols;
A preamble transmitter configured to transmit a preamble signal composed of a plurality of preamble symbols to a receiver a plurality of times;
A signal quality measurement value receiver configured to receive a signal quality measurement value obtained for each of the preamble symbols from the receiver;
A modulation scheme matching unit for matching the modulation scheme having the highest PSNR value with respect to each of the plurality of preamble symbols corresponding to the obtained signal quality measurement value;
A symbol modulator configured to modulate the first symbol and the second symbol included in the plurality of transmission data corresponding to the matched modulation method for each preamble symbol; And
It includes a packet transmission unit for sequentially transmitting a plurality of the first symbol and the second symbol,
And an i-th transmitted symbol included in the transmission data is modulated to correspond to the i-th preamble symbol. delete The method of claim 9,
The preamble transmitter,
Adaptive modulation apparatus using PSNR for BPSK modulation and transmitting the plurality of preamble symbols, respectively. The method of claim 9,
Bits corresponding to MSBs of the transmission data correspond to MSBs of real and imaginary parts of the first and second symbols, and bits corresponding to LSBs of the transmission data correspond to the first symbols. And a PSNR for rearranging the bit order of the transmitted data to correspond to LSBs of real and imaginary parts of a second symbol. The method of claim 12,
The transmission data is uncompressed image data including an MSB composed of 1 to 4 bits and an LSB composed of 5 to 8 bits.
The first symbol is a symbol in units of 4 bits in which the 1st, 5th, 3rd, 7th bits of the transmission data are sequentially arranged, and the 2nd symbol is the 2nd, 6th, 4th, 8th bits of the transmission data sequentially. Adaptive modulation device using PSNR, which is a symbol of 4 bit unit arranged by. The method according to claim 13,
The modulation method is an adaptive modulation device using PSNR which is any one of BPSK, QPSK, 16QAM. The method according to claim 14,
In the step of sequentially transmitting a plurality of the first symbol and the second symbol,
In the case of the BPSK modulation scheme, only the first bit of four bits constituting the first or second symbol is transmitted, in the case of the QPSK modulation scheme, only the first and third bits are transmitted, and in the case of the 16QAM modulation scheme, all the bits are transmitted. To send,
Adaptive receiver using the PSNR for the receiver to arbitrarily set the unreceived bit value. The method of claim 9,
The signal quality measurement value,
Adaptive modulation device using PSNR which is one of signal to noise ratio (SNR), bit error rate (BER), and block error rate (BLER).

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