KR20070094316A - Apparatus for receiving broadcasting - Google Patents

Abstract

A broadcasting receiving apparatus is provided to achieve correct error correction to improve confidence of received signals. A broadcasting receiving apparatus includes a channel state information generator(110), a gain calculator(120), a reference calculator(130), an equalizer(20), and a confidence determination unit(30). The channel state information generator calculates channel transfer function power from a received signal. The gain calculator calculates a gain of the signal output from the channel state information generator. The reference calculator calculates a confidence reference value of the channel transfer function power output from the channel state information generator. The equalizer compensates the channel of the received signal. The confidence determination unit determines confidence of the channel-compensated signal using the reference value calculated by the reference calculator.

Description

Apparatus for receiving broadcasting

1 is a structural diagram showing an embodiment of a broadcast receiving device according to the present invention

2 illustrates an example of a channel transfer function according to an OFDM symbol of a received signal.

FIG. 3 is a diagram illustrating a resolution of a result when a division operation is performed using a table value stored by an equalizer. FIG.

<Explanation of symbols in the main part of the drawing>

10: temporary storage 20: equalizer

30: reliability determination unit 40: power compensation unit

100: channel estimation 110: CSI decision

120: gain generation unit 130: reference calculation unit

The present invention relates to a broadcast receiving apparatus, and more particularly, to a broadcast receiving apparatus capable of increasing the reliability of a received signal.

Orthogonal frequency division multiplexing (OFDM), which is used as a digital broadcast signal modulation technique such as DVB-H, is a special form of multiple carrier transmission, and transmits one data string through a sub-carrier having a low data rate. do. Using the OFDM scheme increases the robustness against frequency selective fading or narrowband interference.

In a single carrier system, the entire link may fail due to one fade or interference, but in a multicarrier system, only some subcarriers are affected. Therefore, error correction coding can correct a few error subcarriers with error correction algorithms such as forward error correction. An apparatus receiving an ODFM signal generally performs channel compensation before performing error correction coding.

However, when a broadcast is received in a long delay spread channel, the size of a channel transfer function (CTF) of a distorted subcarrier is reduced. Such a reduction in the size of the received signal deteriorates the performance of the error correction algorithm, thereby lowering the reliability of the signal.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to provide a broadcast receiving apparatus which can increase the reliability of a received signal by enabling more accurate error correction.

In order to achieve the above object, the present invention provides a channel state information (CSI) generation unit for calculating a channel transfer function (CTF) power from the received signal; A gain calculation unit calculating a gain of a signal output by the CSI generation unit; A reference calculation unit for calculating a reliability reference value of the CTF power output by the CSI generation unit; An equalizer for compensating and outputting a channel of the received signal; And a reliability determiner configured to determine and output reliability of channel-compensated signals by using the reference value calculated by the reference calculator.

Preferably, the reference calculating unit adaptively calculates a reliability reference value according to the gain calculated by the gain calculating unit.

The reliability determination unit preferably calculates logic information for determining the reliability of the channel compensated signal.

The reliability determiner may calculate a channel compensated signal and the logic information.

The equalizer may compensate the channel of the received signal by using the gain of the signal calculated by the gain calculator.

The broadcast receiving apparatus may further include a power compensator for compensating power of the signal by the gain when the equalizer performs channel compensation using gain.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention that can specifically realize the above object will be described.

Hereinafter, information on the reliability of the encoded signal according to the channel state is called channel state information. By applying the information according to the channel state to the received signal as follows, it is possible to increase the bit error rate (bit error rate).

Channel state information (CSI) may be calculated using a CTF signal.

If the received signal is Y, the transmission signal is X, the channel component is H, and the noise component is N, the received signal can be represented by Equation 1.

k is the subcarrier index in the symbol and l is the symbol index.

In this case, the signal received by the signal receiving apparatus may be calculated by the following equation.

는 추정된 수신 신호를,

는 추정된 채널을 각각 나타낸다. 만약

라면 추정된 수신 신호는 다음의 식과 같다.In equation (2)

Is the estimated received signal,

Denote each estimated channel. if

In this case, the estimated received signal is given by the following equation.

Here, a carrier to noise ratio (CNR), which is a ratio of power of a received signal to noise, is expressed by the following equation.

When the CNR according to Equation 4 is large, the reliability of the signal is high, and when the CNR is low, the reliability is low. The CNR is channel state information using the power of the CTF, and may be used to calculate the reliability of the received signal.

1 is a structural diagram showing an embodiment of a broadcast receiving apparatus according to the present invention. Referring to FIG. 1, an operation of an embodiment of a broadcast reception device according to the present invention will be described.

An embodiment of the broadcast receiving apparatus according to the present invention is a temporary storage unit 10, equalizer 20, reliability determination unit 30, power compensation unit 40, channel estimation unit 100, channel state information ( Channel state information (hereinafter referred to as CSI) generation unit 110, a gain calculation unit 120 and a reference calculation unit 130.

The temporary storage unit 10 temporarily stores and outputs the demodulated received signal. The temporary storage unit 10 may temporarily store and output a signal in symbol units of a received signal.

The channel estimator 100 may calculate and output channel characteristics of the received signal.

The CSI generator 110 may calculate and output the power magnitude of the received signal. Preferably, the power magnitude of the received signal of one symbol period may be calculated and output.

The gain calculator 120 may calculate a gain of power of the output signal.

The gain of the power of the received signal calculated by the gain calculator 120 may be defined as the following example.

은 전송 신호를 그대로 수신할 수 있는 채널 환경(clean channel)에서 CTF 신호의 파워를 나타낸다. 또한, k는 심볼 내 부반송파 인덱스(index)를, N은 부반송파 개수, l은 심볼 인덱스를 각각 나타낸다.here,

Denotes the power of the CTF signal in a clean channel that can receive the transmitted signal as it is. K denotes a subcarrier index within a symbol, N denotes the number of subcarriers, and l denotes a symbol index.

) 1보다 작다는 것은 심볼 내 CNR이 낮다는 것을 의미하고, 이득이 1보다 크다는 것은 심볼 내 CNR이 높다는 것을 의미한다.Gain of Equation 5

) Less than 1 means that the CNR in the symbol is low, and a gain greater than 1 means that the CNR in the symbol is high.

Therefore, it is preferable that the gain calculator 120 calculates and outputs the gain of the received signal as described above.

The equalizer 20 may compensate for the channel of the received signal by using the gain generated by the gain calculator 120.

If the equalizer 20 does not use the gain, the channel of the received signal may be compensated using the CTF signal received by Equation 6.

The equalizer 20 may calculate the division of Equation 6 as a multiplication operation of previously stored table values. However, since the range that the stored table values can have is limited, when the division is multiplied as described above, an accurate calculation value may not be calculated.

Therefore, the gain calculator 120 may output the gain α of the CTF signal power to the equalizer 20 so that the equalizer 20 may calculate the correct division into a limited range of table values. The equalizer 20 may compensate the channel of the received signal with the gain of the power.

The concept of compensating for the channel by performing the division operation of Equation 7 by using the equalizer 20 will be described in detail with reference to FIG. 3.

The reference calculator 130 may calculate and output a reference value for determining the reliability of the received CTF signal using the gain output by the gain calculator 120. The concept of determining the reliability of the received signal by the reference calculation unit 130 will be described in detail with reference to FIG. 2.

The reliability determiner 30 may determine and output reliable subcarrier signals among channel compensated signals output by the equalizer 20 according to the reference value output from the reference calculator 130.

When the equalizer 20 compensates for the channel using the gain of Equation 7, the power compensator 40 may compensate and output the power of the signal according to the gain.

An error correction algorithm may be performed on the output signal to increase the reliability of the signal.

2 illustrates an example of a channel transfer function (CTF) according to an OFDM symbol of a received signal.

In the time-varying channel environment, the characteristics of the channel may be different for each symbol. Therefore, if the reliability of the signal according to the channel state is determined by using a predetermined reference value of the power of the received CTF, all signals for a symbol are evaluated to have low reliability. If the evaluation result is used for error correction, all signals for the symbol may become meaningless. Therefore, when evaluating the reliability of the signal by the power of the CTF, it is desirable to adaptively determine the reference value.

A reference value for determining the reliability of the signal with the power of the received CTF signal may be calculated as an example as follows.

If the gain of Equation 5 is greater than 1, a constant reference value may be set as shown in Equation 8.

As shown in Equations 9 to 11, a reference value for determining the reliability of the CTF signal power may be adjusted according to the gain.

As shown in Equations 9 to 11, when the gain is less than 1, the reference value of the CTF power is lowered, and when the gain is greater than 1, the reference value of the reliability may be changed for each symbol by using the preset reference value of the CTF power as it is.

According to the above criteria, if the reliability of the CTF signal power is differently evaluated according to the channel state of the symbol, even if the symbol of the CTF signal has a small power, a certain amount of subcarrier signal can evaluate a reliable value.

The criteria according to Equations 9 to 11 above are arbitrary and different reference values may be applied to each symbol. In addition, if reliability is adaptively applied to the received signal, error correction can be performed.

3 is a diagram illustrating a division result according to a table value in order to explain a concept for accurately performing the operation of Equation 7 using the table value stored by the equalizer.

In order to calculate the reciprocal of A, if the value of A is large, the range of the reciprocal of A may be relatively large, thereby sufficiently securing the resolution of the calculated value. However, if A is small, the range of the inverse value of A may be small, which may reduce the accuracy of the division operation.

Therefore, if the multiplication is performed by multiplying the denominator by a gain value in order to increase the value of A, an accurate division operation can be performed. Further, even if the power of the signal decreases, the power compensation unit after the equalizer output can compensate for the power.

)를 생성하는 일 예를 나타냈다.Equation 12 is a logic information when the reliability determining unit 30 determines that the information is reliable (

) Shows an example of generating

In addition, the reliability determination unit 30 may calculate and output the logic information generated as described above to the output signal of the equalizer 20.

는 신뢰도결정부(30)의 출력 신호,

는 등화기 출력신호를 각각 나타낸다. In equation (13)

Is an output signal of the reliability determination unit 30,

Denote equalizer output signals, respectively.

When the reference calculation unit 130 outputs a reference value using the received gain, the reliability determination unit 30 has a reliability as shown in Equation 13 for a signal lower than the reference value among the signals output by the equalizer 20. It can output with no signal.

Therefore, since the output signal is a CTF signal considering the channel environment in the symbol, error correction of the output signal can provide a reliable broadcast signal.

It is easy for a person skilled in the art to change or modify the present invention from the present specification. Therefore, although an embodiment of the present invention has been described above clearly, various modifications thereof should be made without departing from the spirit and the scope of the present invention.

The effects of the broadcast receiving apparatus according to the present invention described above are as follows. According to the broadcast receiving apparatus according to the present invention, the reliability of the received signal can be improved by demodulating the signal to enable more accurate error correction.

Claims (6)

A channel state information (CSI) generation unit for calculating a channel transfer function (CTF) power from the received signal; A gain calculation unit calculating a gain of a signal output by the CSI generation unit; A reference calculation unit for calculating a reliability reference value of the CTF power output by the CSI generation unit; An equalizer for compensating and outputting a channel of the received signal; And And a reliability determiner configured to determine and output reliability of channel-compensated signals using the reference value calculated by the reference calculator. The method of claim 1, And the reference calculating unit adaptively calculates a reliability reference value according to the gain calculated by the gain calculating unit. The method of claim 1, The reliability determining unit may calculate logic information for determining the reliability of the channel-compensated signal. The method of claim 3, wherein And the reliability determiner calculates and outputs a channel compensated signal and the logic information. The method of claim 1, And the equalizer compensates for the channel of the received signal by using the gain of the signal calculated by the gain calculator. The method of claim 5, And the broadcast receiving apparatus further comprises a power compensator for compensating power of the signal by the gain when the equalizer performs channel compensation using gain.

Images