KR100360473B1 - Method and apparatus for determining signal in digital signal receiving system - Google Patents

Abstract

PURPOSE: A method and an apparatus for determining a signal in a digital signal receiving system are provided to improve the complexity and the resolution of an analog/digital converter by selectively performing a soft decision on a receiving signal of an ambiguous region. CONSTITUTION: A hard decision unit(51) compares a baseband signal generated based on a signal received through a transmitting channel with each of predetermined reference voltages(VTH1,VTH2,,,VTH(L-1)) and performs a hard decision to output decoded data. An ambiguous signal detecting unit(52) receives the baseband signal, reference voltages, predetermined voltages(Vd1,Vd2,...,Vdi) of an ambiguous region, and hard decision data to determine whether or not the received signal is located within a predetermined decision of the ambiguous region and to output the determined result as a signal. A subtraction unit(53) receives the baseband signal, hard decision result data, and the predetermined voltages(Vd1,Vd2,...,Vdi)to calculate a difference voltage between the baseband signal and the predetermined voltages(Vd1,Vd2,...,Vdi). A switching unit(54) selects an output of the subtraction unit(53) to output it if the received signal is in the ambiguous region. Otherwise, the switching unit(54) selects a reference potential to output it. A soft decision unit(55) receives an output of the switching unit(54) and performs a soft decision to output soft decision data.

Description

Signal Judgment Method and Apparatus in Digital Signal Reception System

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital data transmission system applicable to satellite communications, terrestrial network communications, mobile communications, and wired communications. In particular, a signal distorted by noise of a transmission channel in a reception apparatus of a transmission system using a digital modulation scheme is used. In order to improve the complexity and resolution of the analog-to-digital converter by demodulating and decoding the transmitted data, the signal received in the ambiguous region is discriminated and the soft decision is performed selectively on only the received signal in the ambiguous region. A method and apparatus for determining a signal of a digital demodulator.

Digital communication method has become more mainstream of modern information communication because it is more reliable than conventional analog communication method and can transmit high quality information, and its use is increasing gradually. A method of modulating and transmitting a carrier frequency parameter such as amplitude and demodulating the data on a receiving side.

Modulation methods widely used in digital data transmission systems employing such digital communication methods include phase shift keying (PSK) and pulse amplitude modulation (PAM), which are mainly Non Return (NRZ). to zero) modulates the phase or amplitude of the carrier according to the input data in binary code.

1 shows a signal spatial diagram of 4-PAM among these digital modulation schemes. That is, when a digital modulation signal is received by the receiving apparatus of the transmission system and restored to the original signal, it is compared with the code points of the spatial signal of the signal used in the code point-on-transmission of the received signal. Judgment and decoding. A conventional Hard Decision L-level PAM demodulator for the 4-PAM signal shown in FIG. 1 is shown in FIG.

Referring to FIG. 2, the received signal passes through the band limiting filter BPF 21 to extract only a desired channel signal and supplies it to the demodulator 23. The demodulator 23 multiplies the carrier restored by the carrier decompressor (CR) 22 with the output signal of the band limiting filter 21, and removes the harmonic components that may be generated from the low pass filter (LPF: 24). Create a baseband signal.

The baseband signal passes through the signal determination devices 25, 26, 27 and is decoded into the original data bit stream. The signal judging devices 25, 26, and 27 compare L-1 (i.e., 3 in 4-PAM) reference values to find the magnitude of the demodulated received signal, and finally determine the result by the logic circuit 29. do. For example, if the third code point (data bit 10) of FIG. 1 was transmitted and received without error, the magnitude of the received signal V _RX would be V _TH2 < V _RX < V _TH3 . The condition at this time is determined by the noisy circuit 29 as the third reference point and output.

The received signal does not always come to the exact position in the center of the reference values as in the transmission signal code points as in FIG. 1 under the influence of noise or the like, and the position of the received code point is irregularly positioned. It is well known that this phenomenon becomes more severe as the intensity of noise increases. Further, when incomplete carrier recovery and clock recovery are performed in the carrier recoverer 22 and the sampling click recoverer 28 of the receiver, the position change of the received signal code point is more severe.

In the conventional conventional digital receiver, regardless of the above fact, the received signal is determined only by whether the received signal is within a predetermined reference value V _TH . For example, as shown in FIG. 3, if the transmitted code point A moves to point A1 upon reception due to noise or the like, the conventional technique incorrectly determines that the signal of point B has been transmitted. In other cases, if a code point is received at the A2 position, it becomes very ambiguous to determine which of the signals A, B, C, and D is received from the signal. In the prior art, data is determined by forcibly approximating to the nearest point. Therefore, the probability of error is increased.

In order to solve this problem, conventional digital data transmission systems use error correction decoders to improve the performance of a system by correcting a large number of errors occurring in a transmission path. As a representative example, there are BCH code, Reed Solomon Code, and Convolution coding techniques by Viterbi decoding, which are a type of block coding.

On the other hand, in the prior art to solve the problem with the received signal in the ambiguous region described above, the soft decision (soft decision) technique is mainly used. This technique does not output whether the signal received by the decoder is larger or smaller than the reference value, as shown in FIG. 4, but the number of received voltage values is converted by analog / digital (A / D) conversion means or the like. It is usually represented by digital bits of 3 to 8 bits in one decision range, and then supplied to an error decoder to make it easier to determine ambiguous points.

However, this technique requires an A / D conversion means with a large number of bits because the number of decision ranges increases as the range to be determined becomes wider, that is, as the signal level increases, so that the receiving apparatus becomes exponentially complicated and uneconomical. do. In addition, when the received signal point is converted into a digital signal by the A / D conversion means, since all the ranges within the determination range are represented by a plurality of 3 to 8 bits, the resolution is limited when the signal point is represented digitally. .

Accordingly, an object of the present invention is to provide a digital signal reception system in order to solve the above-mentioned problems. In the digital signal receiving system, when a code point received by an interference signal such as a noise of a transmission channel is located in an ambiguous region, a decision is made, such as a soft decision technique for solving this problem. To provide a signal to help, but to provide a signal determination method and apparatus that simplified the complexity of the A / D conversion means, such as may occur in the conventional soft decision technique.

Another object of the present invention is to provide a signal determination method and apparatus for improving the determination performance by widening the resolution of the conventional technology in the soft decision.

In order to achieve the above objects, a signal determination method according to the present invention in a digital signal receiving system is

A steel sheet determination process of determining the baseband signal generated from the signal received through the transmission channel by comparing each of the baseband signals with predetermined reference voltages:

An ambiguity signal detection process for determining whether the received signal is located within a predetermined determination ambiguity range from the baseband signal, reference voltages, predetermined ambiguity region voltages, and steel sheet crystal data; and

A soft decision process of softly determining a difference voltage value between the baseband signal and an ambiguous region voltage corresponding to the steel sheet determination result data region when the received signal is determined to be within a determination ambiguity range in the obscuring signal detection process; It is characterized by.

In order to achieve the above objects, a signal determination apparatus according to the present invention in a digital signal receiving system is

A steel plate unit for determining the baseband signal generated from the signal received through the transmission channel by comparing each of the baseband signals with predetermined reference voltages and then outputting decoded data;

Receiving the baseband signal, reference voltages, predetermined ambiguity region voltages, and steel sheet crystal data as inputs, evaluating whether the received signal is located within a predetermined determination ambiguity range from them, and outputting an evaluation result as a signal. Ambiguous signal detector:

A subtractor configured to receive the baseband signal, the steel sheet determination result data and the ambiguous region voltages as inputs, and calculate a difference voltage value between the baseband signal and the ambiguous region voltage corresponding to the steel sheet determination result data region;

A switching unit which selects and outputs an output of the subtractor when the received signal is in an ambiguous region under control of the signal output from the obscure signal detector, and selects and outputs a reference potential; And

After receiving the output of the switching unit and the soft decision, characterized in that it comprises a soft decision unit for outputting the soft decision data.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

5 is a block diagram of a signal determination apparatus according to the present invention in a digital signal receiving system, in which a received quadrature amplitude modulation (QAM) signal is converted into a baseband signal through a carrier recovery, a clock recovery, and a demodulation process. steel determined by a conventional technique as compared to the respective pre-specified reference voltage in the baseband signal received from the digital demodulator _{(V TH1, V TH2 ...,} V TH (L-1) , etc.) in addition to the (hard After the decision, the base plate 51 for outputting the decoded data, the baseband signal, reference voltages, ambiguous region voltages (V _d1 , V _d2 .., V _di ) and the steel plate _crystal data are received as inputs. From these, an ambiguous signal detector 52 for evaluating whether the received signal is located within a predetermined decision ambiguity range set by a user or a designer and outputting the result as a signal, the received baseband signal, the steel plate crystal result data and The specified ambiguous region voltages (V _d1 , V _d2 ..., V _di : where i is an arbitrary integer that can be set by the user and the designer) are input to the received baseband signal and the steel sheet result data region. A subtractor 53 that calculates a difference voltage value between corresponding ambiguous region voltages, and the subtractor 53 when the received signal is in an ambiguous region under control of a signal output from the ambiguity signal detector 52. ) Is selected and outputted; otherwise, a switching section 54 for selecting a value having a reference potential OV, and a soft decision section 55 for outputting soft decision data after receiving the output of the switching section 54 and making a soft decision. It is composed of

Referring to the operation of the present invention in detail on the basis of the above configuration as follows. First, for convenience of explanation, i of the ambiguity region voltage V _di will be described only when 1, i.e., only one identical ambiguity region voltage is set for each determination region range.

The received digital modulated signal is converted into a baseband signal through carrier recovery, click recovery, and demodulation and input into the present invention. At this time, after the respective predetermined reference voltage, the signal flowing to the present invention in the steel sheet state _{(51) (V TH1, V} TH2, ..., river determined compared to the _{V TH (L-1) (} hard decision) decoding Print the data.

If the result of evaluating the received signal point by the ambiguity signal detection unit 52 is that the received signal is located outside the predetermined determination ambiguity region, this means that the reliability of the grated data is very high. Decoding can be done. Therefore, at this time, the control signal of this determination is output from the obscure signal detection unit 52, so that the switching unit 54 selects the reference voltage 0V. Therefore, the input provided to the soft decision unit 55 becomes OV, and the output of the association unit 55 becomes invalid data.

If the result of evaluating the received signal point by the ambiguity signal detection unit 52 is that the received signal is located within the predetermined determination ambiguity area, since the reliability of the grated data is very low, only the grated crystal result data is used for data decoding. This is the case that the probability of error is high. Therefore, at this time, the control signal of this determination is output from the obfuscation signal detecting unit 52, and the switching unit 4 is a subtracting unit for calculating the difference voltage value (absolute difference value) between the received baseband signal V _RX and the ambiguous region V _d ( Select the output voltage of 53).

The soft decision unit 55 converts the provided input voltage into a multi-bit digital form using an A / D conversion means or the like and outputs the converted input voltage. The steel plate determination and soft determination signals are simultaneously provided to an error correction decoder (not shown) together with the ambiguity determination signal to be used for error detection and correction.

On the other hand, the operation of the ambiguity signal detector 52 is as follows. In the case of 4-PAM, the ambiguity signal detector 52 determines whether a received signal exists in the ambiguity region D-D ', which is previously determined as shown in Fig. 6 by way of example.

In FIG. 6, the voltage (ie, position) of the original transmission code point P _org can be found as P _org = (V _TH2 -V _TH1 ) / 2. From this, and, when the distance to the original determination reference value D at La P _org, DD 'of the distance D to the pre-determined ambiguity region reference voltage value V _d is defined as the area between the ambiguous region. There are two ambiguities in one decision region 2D.

On the other hand, the multi-value digital modulation (Multi-Level Digital Modulation) in is a signal mapping point is located on the outer side to the fact of it easy to move inwardly receiving an external interrupt known, but not a constant V _TH cross-reference the particular system every code It may arrange | position nonlinearly for every point determination area | region. In this case, since it is reasonable to change the ambiguity region, the present invention employs a plurality of ambiguity region voltage values.

The ambiguity signal detecting unit 52 checks whether the distance from the corresponding steel sheet data of the received signal point is greater than D 'for each determination region 2D by using a comparison means or the like. Print this information. If the position of the received signal is within 2D 'range from P _org of FIG. 6, it is judged that reliable data decoding is possible only by the result of the steel plate determination of the signal.If the received signal is larger than 2D' from P _org , it is determined to be ambiguous. By calculating the absolute value of V _d -V _RX in the subtractor 53, it is determined by the soft decision unit 55 through the switching unit 54.

As described above, in the conventional soft decision, the values of all the determination areas of the received signal are converted to the A / D conversion means. In the present invention, the A / D conversion is performed only when the received signal is input to the ambiguous area. It has the effect of solving the complexity problem of technology.

In addition, the output value of the A / D conversion means, which is the soft decision output of the present invention, is not the entire value of the received signal, but only A / D conversion of the difference between the vague region and the apparent point. That is, since the area to be A / D conversion is smaller than the prior art, the soft decision result according to the present invention provides more resolution when using the same A / D converter. Therefore, the overall error correction capability of the digital data transmission system to which the present invention is applied is improved over the prior art.

1 shows a 4-PAM signal spatial diagram.

2 shows a hard decision type L-level PAM demodulator.

3 shows an example of error reception in 16-QAM.

4 shows a soft decision type M-ary QAM demodulator.

5 is a block diagram of a signal judging device according to the present invention in a digital receiving system.

6 shows an ambiguous region of a 4-PAM signal spatial diagram.

Claims (2)

A steel sheet determination process of comparing the baseband signal generated from the signal received through the transmission channel with predetermined reference voltages respectively; An ambiguity signal detection process for determining whether the received signal is located within a predetermined determination ambiguity range from the baseband signal, reference voltages, predetermined ambiguity region voltages, and steel sheet crystal data; and A soft decision process of softly determining a difference voltage value between the baseband signal and an ambiguous region voltage corresponding to the steel sheet determination result data region when the received signal is determined to be within a determination ambiguity range in the obscuring signal detection process; A signal determination method in a digital signal receiving system, characterized in that. A steel plate part for outputting decoded data after determining the baseband signal generated from the signal received through the transmission channel by comparing with the predetermined reference voltages, respectively: Receiving the baseband signal, reference voltages, predetermined ambiguity region voltages, and steel sheet crystal data as inputs, evaluating whether the received signal is located within a predetermined determination ambiguity range from them, and outputting an evaluation result as a signal. Ambiguous signal detector: A subtractor configured to receive the baseband signal, the steel sheet determination result data and the ambiguous region voltages as inputs, and calculate a difference voltage value between the baseband signal and the ambiguous region voltage corresponding to the steel sheet determination result data region; Under control of the signal output from the ambiguity signal detector, when the received signal is in the area of the ambiguity of determination, the switching unit for selecting and outputting the output of the subtractor, and otherwise select and output the reference potential: And And a soft decision unit for outputting soft decision data after the soft decision is made upon reception of the output of the switching unit.