JPH0831819B2 - Data transmission equipment - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data transmission device used for digital mobile communication and the like.

2. Description of the Related Art FIG. 2 shows the configuration of a conventional data transmission device.

In the left side of FIG. 2, 21 is a modulator for modulating transmission data, 22 is a signal for amplifying the signal modulated by the modulator 21,
It is an amplifier for transmitting as a radio wave via the antenna 23, and these members 21 to 23 constitute a transmitting section.

In the right side of FIG. 2, 25 is an amplifier that amplifies a signal received through the antenna 24, 26 is a detector that converts the received signal amplified by the amplifier 25 into a baseband modulated signal, and 27 is This is a discriminator that discriminates the modulated signal detected by the detector 26 at the time when the eye is most opened and outputs the decoded data.

In the above configuration, the receiving-side discriminator 27 discriminates the modulated signal detected by the detector 26 at the time when the eye is most opened. Therefore, when a signal without distortion is received, the received data is decoded without error. be able to.

However, in the above-described conventional data transmission device, in general, in the transmission path of the wireless circuit, interference between codes occurs due to the influence of the delayed wave, so that the received signal is received at the time when the eye is most opened. There is a possibility that there is no distortion, and therefore there is a problem in that data cannot be accurately transmitted via a wireless line.

In view of the above-mentioned conventional problems, the present invention provides a data transmission device capable of reducing transmission errors due to the influence of a delayed wave generated in a transmission line of a wireless line and obtaining the likelihood of decoded data. The purpose is to

Means for Solving the Problem In order to achieve the above object, the present invention estimates a impulse response of a transmission path of a wireless line by a detector that converts a reception signal from a transmitter into a baseband signal, and the baseband signal. A line estimator, a matched filter that improves the S / N ratio of the baseband signal by the impulse response and outputs the signal, and predicts the output signal of the matched filter that corresponds to all patterns of the transmission signal by the impulse response. , A branch metric calculator that calculates the branch metric indicating the error between this predicted value and the output signal of the matched filter, and by adding this branch metric according to the trellis diagram, the expected path is selected and selected. Information that indicates the branch that determines the path, and the path metric that indicates the branch metric and path likelihood corresponding to that branch. ACS calculator that calculates licks and this path metric
The state that represents the received signal is determined by the storage that is stored for the next operation by the arithmetic unit and the information that indicates the branch that determines the path, and the received data is decoded according to that state, and the branch that leads to that state A trellis decoder that adds a likelihood to each bit of decoded data by a metric and outputs the result is provided in the receiving unit.

With the above-described configuration, the present invention configures a trellis diagram corresponding to a transmission signal using the impulse response of a reception signal, calculates errors corresponding to all input patterns, and determines and receives a path of the trellis diagram. Since the data is decoded, it is possible to reduce the transmission error due to the influence of the delay wave generated in the transmission path of the wireless line, and it is possible to obtain the likelihood of the decoded data.

Embodiments Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing an embodiment of a data transmission device according to the present invention.

In the left side of FIG. 1, 1 is a modulator that modulates transmission data, 2 is an amplifier that amplifies the signal modulated by the modulator 1,
It is an amplifier for transmitting as a radio wave via the antenna 3, and these members 1 to 3 compose a transmitter.

In the right side of FIG. 1, 5 is an amplifier for amplifying a signal received through the antenna 4, and 6 is a detector for converting the received signal amplified by the amplifier 5 into a modulated signal in the baseband.

Further, 7 is a channel estimator that estimates the impulse response of the transmission path of the wireless channel by the baseband modulation signal converted by the detector 6, and 8 is the impulse response estimated by the channel estimator 7. A matched filter that improves the S / N ratio of the baseband band modulated signal converted by the detector 6 and outputs it. 9 corresponds to all patterns of the transmission signal by the impulse response estimated by the line estimator 7. A branch metric calculator that predicts the output signal of the matched filter 8 and calculates the error (branch metric) between this predicted value and the signal actually output from the matched filter 8.

Reference numeral 10 corresponds to the information indicating the branch that selects the expected path by adding the branch metric calculated by the branch metric calculator 9 according to the trellis diagram and the branch that determines the selected path. ACS calculator 11 outputs a branch metric and a likelihood (path metric) indicating the likelihood of a path, 11 stores the path metric from ACS calculator 10, and ACS calculator 10 for the next calculation.
Output to the path metric storage, 12 is ACS calculator 10
Trellis that determines the state that represents the received signal by the information that indicates the branch that determines the path from, and decodes the received data according to that state, and adds the likelihood to each bit of the received data by the branch metric that reaches that state. It is a decoder, and the members 4 to 12 compose a receiving unit.

 Next, the operation of the above embodiment will be described.

In FIG. 1, the signal is modulated and transmitted by the transmitter,
The baseband signal received and detected by the receiving unit includes a transmission error due to the influence of a delayed wave generated in the transmission path of the wireless line.

Therefore, the line estimator 7 estimates the impulse response of the transmission line of the wireless line from the baseband modulated signal, and the matched filter 8 uses this impulse response to determine the S / N ratio of the baseband modulated signal. Improve.

Next, the branch metric calculator 9 predicts the output signal of the matched filter 8 corresponding to all the patterns of the transmission signal based on the impulse response estimated by the line estimator 7, and predicts all of the predicted values and the matched filter 8. The squared error from the actual output value is calculated, and the branch metric representing the error at the sample point of the output signal of the matched filter 8 is output.

In this case, the branch metric calculator 9 first assumes a trellis diagram corresponding to the modulated signal from time “0”,
The branch metric obtained by the sample value at time n + 1 is output for the path considered up to time n in the trellis diagram.

Then, the ACS calculator 10 adds the branch metric at the time n + 1 to the sum (path metric) of the branch metrics corresponding to the paths up to the time n calculated by the branch metric calculator 9 to obtain the time n + 1 in the trellis diagram. Find the path metric of the candidate paths up to.

Here, since multiple paths are assumed for each state at time n + 1, the most probable path is selected for each state by comparing the path metrics.
In addition, the path metric of the path selected at this time is saved in the saver.
It is output to 11 to be used in the calculation at time n + 2, and the trellis information indicating the branch that determines the selected path, the branch metric corresponding to the branch, and the likelihood (path metric) indicating the certainty of the path. Output to the decoder 12.

Trellis decoder 12, information indicating which path was selected, determines the path of the trellis diagram at each time, in this case, since each state on the determined path corresponds to the predicted value of the received signal, The received data is decoded based on that state, and the branch metric leading to that state is then normalized by the sum of squares of the impulse response of the transmission path and output as the likelihood of the received data.

Therefore, according to the above-described embodiment, the impulse response of the received signal is used to form the trellis diagram corresponding to the transmitted signal, the errors corresponding to all the input patterns are calculated, and the path of the trellis diagram is determined. Since the received data is decoded, it is possible to reduce the transmission error due to the influence of the delay wave generated in the transmission path of the wireless line, and it is possible to obtain the likelihood of the decoded data.

As described above, according to the present invention, the impulse response of the received signal is used to construct the trellis diagram corresponding to the transmission signal, the errors corresponding to all the input patterns are calculated, and the path of the trellis diagram is calculated. Since the received data is decoded by fixing the above, it is possible to reduce the transmission error due to the influence of the delay wave generated in the transmission path of the wireless line, and it is possible to obtain the likelihood of the decoded data.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of a data transmission device according to the present invention, and FIG. 2 is a block diagram showing a conventional data transmission device. 1 ... Modulator, 2,5 ... Amplifier, 3,4 ... Antenna, 6 ...
… Detector, 7 …… Line estimator, 8 …… Matched filter, 9
...... Branch metric calculator, 10 …… ACS calculator, 11
...... Path metric saver, 12 …… Trellis decoder.

Front page continuation (72) Inventor Koichi Honma 4-3-1, Tsunashima-higashi, Kohoku-ku, Yokohama-shi, Kanagawa Matsushita Communication Industrial Co., Ltd. (56) Reference JP-A-60-200654 (JP, A) JP-A 2-241249 (JP, A) Proceedings of the 1989 IEICE Spring National Convention [Part 2] (1989-3.) P. 309

Claims (1)

[Claims] 1. A transmission section that modulates transmission data and wirelessly transmits it, a wave detector that converts a reception signal from the transmission section into a baseband signal, and a baseband signal from the wave detector for a wireless line. A line estimator that estimates the impulse response of the transmission path, and a matched filter that improves and outputs the S / N ratio of the baseband signal by the impulse response,
A branch metric calculator that predicts the output signal of the matched filter corresponding to all patterns of the transmission signal by the impulse response, and calculates a branch metric indicating an error between the predicted value and the output signal of the matched filter, and Information that indicates the branch that selects the expected path and determines the selected path by adding the branch metrics according to the trellis diagram, and the branch metric corresponding to that branch and the path metric that indicates the likelihood of the path. And an ACS calculator for calculating the path metric
The state representing the received signal is determined by the saver to be saved for the next operation by the arithmetic unit and the information indicating the branch that determines the path, and the received data is decoded according to the state and the state is reached. Branch metric
And a trellis decoder for adding a likelihood to each bit of the decoded data and outputting the result.