JP2004320355A - Channel-state adaptive communication system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a channel-state adaptive communication system by which a high-quality and high-efficiency radio communication channel is ensured by conducting effective communication timely taking measures against a quality change in a transmission line in radio communication, particularly, a variation in radio wave propagation in mobile radio communication. <P>SOLUTION: A channel-state adaptive radio communication system selects one of a plurality of communication systems having different modulation systems and communication speeds in accordance with a channel state in a communication area and conducts communication. Base station equipment receives position information from mobile station equipment to grasp the location of a mobile station, decides the communication system by referring to a radio wave propagation state table used for each location in the communication area and previously provided in the base station equipment, and transmits communication system information to the mobile station. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a line state adaptive packet communication, and more particularly to a system for improving the line quality with respect to the fluctuation of the radio wave propagation environment in mobile communication.
[0002]
[Prior art]
In data communication between a mobile wireless device (hereinafter, a mobile station) and a fixed wireless device (hereinafter, a base station), the line state generally fluctuates greatly. This is because the propagation environment fluctuates from time to time, such as multipath fading due to the moving speed of the mobile station and the surrounding environment.
[0003]
A conventional technique will be described with reference to FIG.
[0004]
When the base station 1-1 and the mobile station 1-2 moving in the areas A, B, and C perform wireless communication, if the mobile station 1-2 is moving in the area A or B, a building or the like is used. Radio wave propagation conditions are relatively good from the surrounding environment, and high quality communication is possible. However, if the mobile station 1-2 is moving within the area C, the S / N of the received signal is deteriorated due to the surrounding environment such as a building, the error rate is increased, and the radio wave propagation situation is deteriorated.
[0005]
In order to realize error-free communication even in such an environment where the radio wave propagation condition is poor, there is a technique such as adaptive modulation which lowers the transmission rate and reduces the error rate when the radio wave propagation condition is bad.
[0006]
Further, as another means in an environment where the radio wave propagation condition is poor, the transmitting side transmits at a high transmission rate, and if the error rate is high on the receiving side, the transmitting side retransmits to the transmitting side by an automatic repeat request (ARQ) signal. There is also a method in which a request is issued, and when the transmitting side receives the ARQ, the transmission rate is reduced and retransmitted.
[0007]
[Problems to be solved by the invention]
However, in the conventional method, there is no established method for determining the radio wave propagation path condition, and the procedure of retransmission by ARQ requires complicated processing and the error rate cannot be improved if the modulation method is the same.
[0008]
Therefore, an object of the present invention is to provide a communication control device in wireless communication that can solve the above-described problems.
[0009]
[Means for Solving the Problems]
In order to achieve the above object, the present invention provides a method of selecting one of a plurality of communication schemes comprising a base station apparatus and a mobile station apparatus and having different modulation schemes and communication speeds according to line conditions in a communication area for communication. The mobile station device, a means for grasping position information in a communication area, a means for transmitting the position information to the base station device, and a communication with the base station device. Means for receiving, from the base station apparatus, communication method information used for the base station, wherein the base station apparatus includes means for receiving the position information transmitted from the mobile station apparatus, and radio waves at a plurality of positions in a communication area. Means for storing the propagation status as a radio wave propagation status table, and referring to the radio wave propagation status table based on the position information, to obtain a radio wave propagation status at a position in the communication area of the mobile station apparatus. Means for selecting a communication method adapted, characterized in that a means for transmitting to said mobile station apparatus the communication mode selected as the communication method information.
[0010]
BEST MODE FOR CARRYING OUT THE INVENTION
Next, the present invention will be described with reference to the drawings.
FIG. 2 shows an operation system for performing communication between a base station and a mobile station as one embodiment of the present invention. The mobile station 2-2 receives position information (Global Position System) from a satellite via the GPS antenna 2-1. The mobile station 2-2 wirelessly transmits the voice data, the current position information, and the modulation method as transmission data from the antenna 2-3 to the base station 2-4. The base station 2-4 demodulates the received data, obtains the position information of the mobile station 2-2, determines the modulation method of the next frame, and returns it to the mobile station 2-2.
[0012]
FIG. 3 shows a configuration of transmission and reception of the mobile station 1-2 (FIG. 1) as one embodiment of the present invention. Position information from a satellite via the GPS antenna 3-2 is received by the GPS receiver 3-22, and digital data is generated by the position information input unit 3-23.
[0013]
The input unit 3-1 encodes audio input from a microphone or the like into digital data. Channel coding section 3-2 generates transmission data. FIG. 6 shows an embodiment of the transmission data format created by the channel coding unit 3-2. One block of transmission data includes communication method information 6-1, position information 6-2, control parameters 6-3, and audio data 6-4. Channel coding section 3-2 generates information on the position from position information input section 3-23 as transmission data to base station 1-1 (FIG. 1).
[0014]
The 16QAM modulator 3-3 performs baseband 16QAM modulation on the transmission data from the channel coding unit 3-2. QPSK modulator 3-4 performs baseband QPSK modulation on transmission data from channel coding. The BPSK modulation section 3-5 performs BPSK modulation of a baseband on transmission data from the channel coding.
[0015]
The analog modulation unit 3-6 performs a modulation process such as AM on the baseband modulation wave and outputs an analog modulation wave to the transmission unit 3-7. The transmitting unit 3-7 performs a process of converting the analog modulated wave (intermediate frequency band) to a radio frequency band. The power amplifier 3-8 amplifies the signal in the radio frequency band to a radio output level. The diplexer 3-9 prevents the transmission signal from sneaking into the receiver, and conversely, the reception signal from the antenna from sneaking into the transmission side to prevent interference. The mobile station 1-2 transmits the power-amplified radio frequency band signal from the antenna 3-20 to the base station 1-1.
[0016]
The antenna 3-20 is a common antenna for transmission and reception. The receiving unit 3-10 performs a process of converting a received signal (radio frequency band) from the base station 1-1 into an intermediate frequency. The analog demodulation unit 3-11 performs analog demodulation of the intermediate frequency.
[0017]
The 16QAM demodulation unit 3-13 performs 16QAM demodulation of a baseband. The QPSK demodulation unit 3-14 performs baseband QPSK demodulation. The BPSK demodulation unit 3-15 performs BPSK demodulation in a baseband.
[0018]
The channel decoding unit 3-18 receives the audio data 6-4, the position information 6-2, and the communication system information from the demodulated data from the 16QAM demodulation unit 3-13, the QPSK demodulation unit 3-14, or the BPSK demodulation unit 3-15. 6-1 is separated. The output unit 3-19 outputs the audio data separated by the channel decoding unit 3-18 from a speaker or the like.
[0019]
The communication method determining unit 3-16 determines the communication method information 6-1 separated by the channel decoding unit 3-18, and determines a communication method for transmitting the next frame. The communication method determination unit 3-16 outputs information on the communication method to the SW switching control unit 3-17.
[0020]
The SW switching control unit 3-17 switches and selects a modulation method and a demodulation method using the SW 3-12. That is, the mobile station 1-2 selects a with SW3-12 when selecting the 16QAM modulation / demodulation method, selects b with SW3-12 when selecting the QPSK modulation / demodulation method, and selects the BPSK modulation / demodulation method. In this case, c is selected by SW3-12.
[0021]
FIG. 4 shows a configuration of transmission and reception of the base station 1-1 (FIG. 1) as one embodiment of the present invention. The input unit 4-1 encodes audio input from a microphone or the like into digital data. Channel coding section 4-2 generates transmission data. Referring to FIG. 6, the channel coding unit 4-2 generates the communication scheme information 6-1 determined by the position information determination unit 4-16 as transmission data to the mobile station 1-2 (FIG. 1). I do.
[0022]
The 16QAM modulator 4-3 performs baseband 16QAM modulation on the transmission data from the channel coding unit 4-2. The QPSK modulator 4-4 performs baseband QPSK modulation on transmission data from channel coding. The BPSK modulation section 4-5 performs BPSK modulation of a baseband on transmission data from channel coding.
[0023]
The analog modulator 4-6 performs a modulation process such as AM on the baseband modulated wave and outputs an analog modulated wave to the transmitter 4-7. The transmitting unit 4-7 performs a process of converting the analog modulated wave (intermediate frequency band) to a radio frequency band. The power amplifier 4-8 amplifies the signal in the radio frequency band to a radio output level. The diplexer 4-9 prevents the transmission signal from sneaking into the receiver side, and conversely, the reception signal from the antenna from sneaking into the transmission side to interfere. The base station 1-1 transmits the power-amplified radio frequency band signal from the antenna 3-20 to the mobile station 1-2.
[0024]
The antenna 4-20 is a common antenna for transmission and reception. The receiving unit 4-10 performs a process of converting a received signal (radio frequency band) from the mobile station 1-2 into an intermediate frequency. The analog demodulation unit 3-11 performs analog demodulation of the intermediate frequency.
[0025]
The 16QAM demodulation unit 4-13 performs 16QAM demodulation of a baseband. QPSK demodulation section 4-14 performs QPSK demodulation in a baseband. The BPSK demodulation unit 4-15 performs BPSK demodulation in a baseband.
[0026]
The channel decoding unit 4-18 outputs audio data 6-4, position information 6-2, and communication system information from demodulated data from the 16QAM demodulation unit 4-13, the QPSK demodulation unit 4-14, or the BPSK demodulation unit 4-15. 6-1 is separated. The output unit 4-19 outputs the audio data separated by the channel decoding unit 4-18 from a speaker or the like.
[0027]
The position information determining unit 4-16 determines the position information 6-2 separated by the channel decoding unit 4-18, and determines a communication system for transmitting the next frame. The position information determining unit 4-16 outputs information on the communication scheme to the channel decoding unit 4-18 and the SW switching control unit 4-17.
[0028]
FIG. 5 shows the correspondence between the position information and the communication method as one embodiment of the present invention. The selection of a communication method using the position information of the mobile station 1-2 in communication areas having different radio wave propagation conditions will be described with reference to FIG. The base station 1-1 (FIG. 1) obtains the location information 6-2 of the mobile station 1-2 (FIG. 1) by the channel decoding unit 4-18. When the mobile station 1-2 is in the area A where propagation conditions are good, a high-speed 16QAM modulation scheme is selected. When the mobile station 1-2 is in the area B, the propagation condition is inferior to that in the area A. Therefore, the medium-speed QPSK modulation method is selected. Since the situation is inferior to area B, a low-speed BPSK modulation scheme is selected to avoid an increase in the error rate.
[0029]
The table shown in FIG. 5 is prepared in advance by using statistical data to determine whether the propagation status is good or bad for each area. Further, it is desirable that the table is changed or updated as needed.
[0030]
The SW switching control unit 4-17 switches and selects the modulation method and the demodulation method using the SW 4-12. That is, the base station 1-1 selects a with SW4-12 when selecting the 16QAM modulation / demodulation method, selects b with SW4-12 when selecting the QPSK modulation / demodulation method, and selects the BPSK modulation / demodulation method. In this case, c is selected by SW4-12.
[0031]
As described above, according to the packet control device of the present embodiment, efficient communication can be performed in a timely manner in response to a change in the quality of a transmission path due to a radio wave state or congestion.
[0032]
As described above, the present invention has been described using the embodiments, but the technical scope of the present invention is not limited to the scope described in the above embodiments. Various changes or improvements can be added to the above embodiment. It is apparent from the description of the appended claims that embodiments with such changes or improvements can be included in the technical scope of the present invention.
[0033]
As is evident from the above description, by providing a propagation condition determined in advance from surrounding conditions, etc., when the propagation condition is poor, the data transmission speed is reduced to realize error-free communication. If the communication is good, the transmission speed is increased to enable high quality and effective communication. In addition, the error rate can be reduced at a transmission rate that is optimal for the propagation situation without complicated control such as ARQ, and efficient communication can be performed in a timely manner in response to a change in the quality of a transmission path in wireless communication.
[Brief description of the drawings]
FIG. 1 shows a propagation situation in a communication area.
FIG. 2 shows an operation implementation configuration according to an embodiment of the present invention.
FIG. 3 shows a configuration of a mobile station according to an embodiment of the present invention.
FIG. 4 shows a configuration of base station transmission and reception according to an embodiment of the present invention.
FIG. 5 shows correspondence between position information and a modulation method according to an embodiment of the present invention.
FIG. 6 shows a configuration of transmission data according to an embodiment of the present invention.
[Explanation of symbols]
1-1: base station, 1-2: mobile station,
2-1, 2-3, 2-5: antenna, 2-2: mobile station, 2-4: base station 3-1: input section, 3-2, 3-18: channel coding section, 3-3: 16QAM modulator, 3-4: QPSK modulator, 3-5: BPSK modulator, 3-6: analog modulator, 3-7: transmitter, 3-9: duplexer, 3-10: receiver, 3- 11: analog demodulation unit, 3-12: switch, 3-13: 16QAM demodulation unit, 3-14: QPSK demodulation unit, 3-15: BPSK demodulation unit, 3-16: communication system determination unit, 3-17: switch Switching control unit, 3-19: output unit, 3-20: antenna, 3-22: GPS receiver, 3-23: position information input unit, 3-24: GPS antenna 4-1: input unit, 4-2 , 3-18: channel coding section, 4-3: 16QAM modulation section, 4-4: QP K modulator, 4-5: BPSK modulator, 4-6: analog modulator, 4-7: transmitter, 4-9: duplexer, 4-10: receiver, 4-11: analog demodulator, 4- 12: switch, 4-13: 16 QAM demodulation unit, 4-14: QPSK demodulation unit, 4-15: BPSK demodulation unit, 4-16: system determination unit, 4-17: switch switching control unit, 4-19: output Unit, 4-20: antenna 6-1: method information, 6-2: position information, 6-3: control parameter, 6-4: audio data

Claims (1)

A line state adaptive communication system configured by a base station apparatus and a mobile station apparatus and performing communication by selecting one from a plurality of communication systems having different modulation schemes and communication speeds according to a line state in a communication area,
The mobile station device,
Means for grasping position information in the communication area;
Means for transmitting the location information to the base station device,
Means for receiving communication method information used for communication with the base station device from the base station device,
The base station device,
Means for receiving the position information transmitted from the mobile station device,
Means for storing a radio wave propagation situation at a plurality of positions in the communication area as a radio wave propagation situation table;
Means for referring to the radio wave propagation situation table based on the position information, and selecting a communication method adapted to a radio wave propagation situation at a position in the communication area of the mobile station device,
Means for transmitting the selected communication method as communication method information to the mobile station apparatus.

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