JP2010093833A - Mobile communication system, wireless communication method, base station apparatus and mobile station apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent communication of a surrounding base station apparatus or mobile station apparatus from being interfered by causing the mobile station apparatus to perform communication in accordance with allocation channel information received while including error. <P>SOLUTION: A base station apparatus 10A adds an error detecting code to control information including allocation channel information designating information of a communication channel to be allocated to a mobile station apparatus 100A and transmits the control information and the mobile station apparatus 100A receives the control information transmitted by the base station apparatus 10A and detects error in the allocation channel information on the basis of the error detecting code added to the received control information. If any error is detected, the mobile station apparatus 100A controls not to transmit any signal using the communication channel designated by the allocation channel information. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a technique for preventing communication interference in a mobile communication system.

  In a mobile communication system, a base station apparatus and one or a plurality of mobile station apparatuses perform wireless communication. Each mobile station apparatus is assigned a communication channel used for communication with the base station apparatus. Which communication channel is assigned to which mobile station apparatus is determined by the base station apparatus. Each mobile station apparatus is notified of communication channel information (allocation channel information) determined to be allocated by the base station apparatus. Each mobile station apparatus sets a communication channel based on the notified allocation channel information and communicates with the base station apparatus (see, for example, Patent Document 1).

  In a conventional mobile communication system, by using a modulation scheme with low modulation efficiency in a data area including allocation channel information, it is possible to suppress occurrence of errors when decoding allocation channel information, and to allocate allocation channel information. There is something that prevents you from getting it by mistake.

JP-A-10-190621

  However, in the conventional technique, when the reception level of the signal received by the mobile station apparatus is lowered, the allocation channel information may be acquired with an error even if the modulation efficiency is lowered. If the acquired allocation channel information includes an error, the mobile station apparatus transmits a signal to the base station apparatus using an incorrect communication channel, and as a result, the transmitted signal is transmitted to the surrounding base station apparatus and In some cases, the mobile station apparatus interferes with communication.

  The present invention has been made in view of the above problems, and its purpose is to use the allocated channel information received by the mobile station apparatus including an error so that the surrounding base station apparatus and mobile station apparatus An object of the present invention is to provide a mobile communication system, a radio communication method, a base station apparatus, and a mobile station apparatus that prevent interference with communication.

  In order to solve the above problems, a mobile communication system according to the present invention communicates with a base station apparatus by assigning at least a part of a plurality of radio communication channels constituting a communication frame by the base station apparatus. A mobile communication system including a mobile station device, wherein the base station device includes control information including allocation channel information specifying information on a radio communication channel to be allocated to the mobile station device for transmitting and receiving communication data. An allocation unit that allocates a radio communication channel to be transmitted to the mobile station apparatus with an error detection code added from the communication frame, and the control information is transmitted for each communication frame using the radio communication channel allocated by the allocation unit. Control information transmitting means, wherein the mobile station apparatus transmits the control information transmitted by the control information transmitting means. Receiving means for receiving each communication frame; error detecting means for detecting an error in the allocated channel information for each communication frame based on an error detection code added to the control information received by the receiving means; and the error detection Transmission control means for controlling not to transmit a signal using the wireless communication channel specified by the assigned channel information of the communication frame in which the error is detected by the means.

  In the present invention, the base station apparatus determines at least some radio communication channels to be allocated to the mobile station apparatus among the plurality of communication channels. Then, the base station apparatus adds the error detection code to the control information including the assigned channel information specifying the determined wireless communication channel information, and transmits the control information. The mobile station apparatus receives the transmitted control information. Then, the mobile station apparatus performs error detection based on the error detection code included in the received control information. When an error is detected by error detection, the mobile station apparatus does not transmit a signal through the wireless communication channel specified by the received allocation channel information.

  According to the present invention, when an error is detected in the allocation channel information received from the base station apparatus, the mobile station apparatus does not perform communication using the radio communication channel specified by the allocation channel information. Therefore, it is possible to prevent the mobile station apparatus from interfering with the communication of surrounding base station apparatuses and mobile station apparatuses by transmitting signals using the allocation channel information received with errors.

  A radio communication method according to the present invention is performed by a base station apparatus and a mobile station apparatus that performs communication by assigning at least a part of a plurality of radio communication channels constituting a communication frame by the base station apparatus. The base station apparatus adds an error detection code to control information including allocation channel information that specifies radio communication channel information allocated to the mobile station apparatus in order to transmit and receive communication data. An allocation step of allocating a radio communication channel to be transmitted to the mobile station device from the communication frame, and control information for transmitting the control information for each communication frame in the radio communication channel allocated by the base station device in the allocation step A transmission step, and the mobile station apparatus transmits the control information transmitted in the control information transmission step to a communication frame. A reception step for receiving each channel, and error detection for detecting an error in the allocated channel information for each communication frame based on an error detection code added to the control information received by the mobile station device in the reception step And a transmission control step for controlling the mobile station apparatus so as not to transmit a signal using a radio communication channel specified by allocation channel information of a communication frame in which an error is detected in the error detection step. It is characterized by that.

  A base station apparatus according to the present invention is a base station apparatus that performs communication by allocating at least a part of a plurality of radio communication channels constituting a communication frame to a mobile station apparatus, for transmitting and receiving communication data. An allocating unit for allocating a radio communication channel to be transmitted to the mobile station apparatus by adding an error detection code to control information including allocation channel information designating information of a radio communication channel to be allocated to the mobile station apparatus from the communication frame; Control information transmitting means for transmitting the control information for each communication frame on the wireless communication channel allocated by the allocating means, and the control information transmitted by the control information transmitting means for each communication frame Based on the error detection code received by the apparatus and added to the received control information, the mobile station apparatus An error in the allocated channel information is detected for each communication frame, so that a signal is not transmitted using a radio communication channel specified by the allocated channel information in the communication frame in which the error is detected by the mobile station device. The mobile station apparatus is controlled.

  Also, the mobile station apparatus according to the present invention performs communication by assigning at least a part of a plurality of radio communication channels constituting a communication frame to the mobile station apparatus, and assigning the mobile station apparatus to transmit / receive communication data An allocation unit that allocates a radio communication channel to be transmitted to the mobile station apparatus by adding an error detection code to control information including allocation channel information specifying radio communication channel information is allocated from the communication frame, and is allocated by the allocation unit. A mobile station apparatus that communicates with a base station apparatus including a control information transmission unit that transmits the control information for each communication frame on a wireless communication channel, the control information transmitted by the control information transmission unit A receiving means for receiving each communication frame, and an error detection code added to the control information received by the receiving means. Accordingly, an error detecting means for detecting an error of the allocated channel information for each communication frame, and a signal is transmitted using a radio communication channel designated by the allocated channel information of the communication frame in which the error is detected by the error detecting means. Transmission control means for controlling so as not to occur.

  The base station apparatus further includes encoding means for encoding the control information using shared information shared between the base station apparatus and the mobile station apparatus, and the control information transmitting means includes the control information transmitting means, The control information encoded by the encoding means is transmitted, and the mobile station apparatus further includes decoding means for decoding the encoded control information received by the receiving means using the shared information. But you can. In this way, allocation channel information transmitted from other base stations that do not have shared information and allocation channel information transmitted to other mobile station devices are not decoded, and erroneous allocation channel information is transmitted. The signal can be prevented from being transmitted according to the above.

  Further, the encoding may be scramble encoding using the shared information. By doing so, the encoding and decoding circuits can be simplified, and the processing required for them can be reduced.

  The shared information may be unique information of at least one of the base station apparatus and the mobile station apparatus. By doing so, it is possible to reliably identify the communication partner and prevent transmission of a signal according to incorrect allocation channel information.

It is a figure which shows an example of the system configuration | structure of a mobile communication system. It is a figure which shows an example of a structure of a communication frame. It is a figure which shows an example of the control information transmitted in ASCH. It is a functional block diagram of a base station apparatus. It is a functional block diagram of a mobile station apparatus. It is a flowchart of the production | generation process of fixed modulation data. It is an example of the shift register which produces | generates a scramble sequence. It is an example of an error correction coding circuit. It is a flowchart of the demodulation process of the received signal in a mobile station apparatus.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the invention (hereinafter referred to as embodiments) will be described in detail with reference to the drawings.

  FIG. 1 shows an example of a system configuration of a mobile communication system according to the present embodiment. In the mobile communication system 1, a plurality of cells are arranged in the communication area. Each cell is provided with a base station apparatus 10 (10A, 10B, 10C). The mobile station apparatus 100 (100A, 100B, 100C) performs radio communication with the base station apparatus 10 in a good communication state according to the location located in the communication area. For example, in the communication environment shown in FIG. 1, it is assumed that the mobile station devices 100A and 100B communicate with the base station device 10A, and the mobile station device 100C communicates with the base station device 10C.

  In the mobile communication system 1 according to the present embodiment, the mobile station device 100 transmits / receives data to / from the base station device 10 by the TDD method, and performs multiplex communication by the TDMA method and the OFDMA method.

  FIG. 2 shows an example of a time slot configuration (for one TDMA frame) by TDMA / TDD and a subchannel configuration by OFDMA. As shown in FIG. 2, the uplink (signal from the mobile station apparatus 100 to the base station apparatus 10) and the downlink (signal from the base station apparatus 10 to the mobile station apparatus 100) are both from four time slots. Composed. Each slot is composed of a plurality of subchannels. In the frame configuration shown in FIG. 2, ESCH indicates an extended subchannel, and ASCH indicates a subchannel assigned as an anchor subchannel.

  The ESCH is a communication channel mainly used for transmission / reception of communication data with the mobile station device 100. One or more ESCHs (enhanced subchannels) are assigned to the mobile station apparatus 100 as communication channels.

  ASCH is one subchannel specified from among a plurality of subchannels, and is a subchannel used mainly for transmitting and receiving control information related to communication between mobile station apparatus 100 and base station apparatus 10. .

  FIG. 3 shows an example of control information transmitted by ASCH. As shown in FIG. 3, the control information includes MAP, ACK, MI, CRC, and TAIL data.

  The MAP is allocation channel information that specifies a subchannel to be allocated to the mobile station device 100 among a plurality of subchannels that can be used by the base station device 10.

  The ACK is information for transmitting in the mobile station apparatus 100 or the base station apparatus 10 that the data transmitted from the data transmission side has been normally received on the data reception side.

  MI is identifier information that specifies a modulation scheme for the adaptive modulation region. The adaptive modulation area is a data area in which mainly communication data is carried. For the control information, a fixed modulation scheme with a suppressed modulation efficiency is used to suppress the occurrence of errors during decoding.

  The CRC is information that stores the value of a CRC (Cyclic Redundancy Check) code for detecting a data error. The CRC code is generated for a CRC calculation area including MAP, ACK, and MI. Note that the same CRC code is generated from the same data.

  TAIL is a bit added to initialize the value of the shift register constituting the encoding circuit to zero.

  Further, the scramble area in FIG. 3 is a data area obtained by adding CRC to the CRC calculation area, and this data area is scrambled. Details of the scramble coding will be described later.

  The ASCH is assigned when the mobile station device 100 requests the base station device 10 to establish a link. Then, control information including allocation channel information (MAP information) indicating a communication channel (ESCH) allocated to communication with the base station apparatus 10 is notified by the ASCH.

  In the mobile station apparatus 100 according to the present invention, error detection is performed based on an error detection code (CRC code) included in the received control information. Here, when a data error is detected, the uplink signal is not transmitted using the subchannel specified by the received MAP information. In addition, the control information to be transmitted is subjected to scramble coding so that only the intended mobile station apparatus 100 can normally decode the scramble area obtained by adding the CRC code to the CRC calculation area, and the mobile station apparatus 100 ( For example, 100A) receives the control information transmitted from another base station apparatus 10 (for example, 10B, 10C) or the control information transmitted to another mobile station apparatus 100 (for example, 100B, 100C), and MAP Do not set information.

  Hereinafter, in order to implement | achieve said process, the detail with which the structure with which the mobile communication system 1 which concerns on this embodiment is provided, and the process performed by each structure is demonstrated.

  Functional block diagrams of the base station apparatus 10 and the mobile station apparatus 100 according to the present embodiment are shown in FIGS. 4 and 5, respectively.

  As illustrated in FIG. 4, the base station apparatus 10 includes a communication unit 20, a signal processing unit 30, and a control unit 50 as functional configurations. The signal processing unit 30 includes a symbol synchronization unit 32, a Fourier transform unit 34, a timing estimation unit 36, a frequency / channel estimation unit 38, a demodulation unit 40, a fixed modulation data generation unit 42, an adaptive modulation data generation unit 44, and a modulation unit. 46 and an inverse Fourier transform unit 48.

  Also, as illustrated in FIG. 5, the mobile station device 100 includes a communication unit 120, a signal processing unit 130, and a control unit 150 as functional configurations. The signal processing unit 130 includes a symbol synchronization unit 132, a Fourier transform unit 134, a timing estimation unit 136, a frequency / channel estimation unit 138, a demodulation unit 140, a fixed modulation data demodulation unit 140A, an adaptive modulation data demodulation unit 140B, and fixed modulation data generation. Unit 142, adaptive modulation data generation unit 144, modulation unit 146, and inverse Fourier transform unit 148.

Hereinafter, details of processing performed in the functional blocks provided in the base station apparatus 10 and the mobile station apparatus 100 will be described.
[Processing of base station apparatus 10]
First, uplink signal reception processing in the base station apparatus 10 will be described.

  The communication unit 20 receives a signal in the carrier band transmitted from the mobile station apparatus 100 via the antenna 22. The received signal is amplified, converted to an intermediate frequency, and A / D converted, and then converted to an OFDM baseband signal.

  The symbol synchronization unit 32 performs symbol synchronization using a guard interval included in the OFDM symbol of the OFDM baseband signal output from the communication unit 20. Since the guard interval part has a correlation with the latter half part of the OFDM symbol, the start position of the OFDM symbol is detected by detecting the correlation. Then, symbol synchronization is performed based on the detected leading position of the OFDM symbol.

  In the Fourier transform unit 34, when the effective period length of the transmission symbol determined by the interval between the symbol head positions detected by the symbol synchronization unit 32 is Ts and the number of OFDM carriers is N, the output is performed by the communication unit 20. The OFDM baseband signal is sampled over the effective period length at a sampling interval of Ts / N. The sampled data is output after being serial-parallel converted as N signals. From the output N sampling data, a complex symbol sequence for modulating each carrier is extracted by a discrete Fourier transform (DFT). If the sampling interval of Ts / N is constant, the discrete Fourier transform (DFT) can be replaced with a fast Fourier transform (FFT). The extracted symbol is subjected to parallel-serial conversion and then output as a frequency-domain OFDM demodulated signal.

  The timing estimator 36 and the frequency / channel estimator 38 perform processing for correcting the influence of the transmission path characteristics on the OFDM demodulated signal output from the Fourier transform unit 34. The characteristics of the transmission path are estimated using pilot symbols in the OFDM demodulated signal. Then, the timing estimation unit 36 performs interpolation in the time direction on the OFDM demodulated signal, and then the frequency / channel estimation unit 38 performs interpolation in the frequency direction of the OFDM demodulated signal.

  In the demodulator 40, the data bit string is restored based on the OFDM demodulated signal in which the influence of the characteristics of the transmission path is corrected in the timing estimator 36 and the frequency / channel estimator 38. The data bit string is restored by symbol determination according to the modulation scheme of the OFDM demodulated signal. The data bit string demodulated by the demodulator 40 is output to the controller 50.

  Next, downlink signal transmission processing in the base station apparatus 10 will be described.

  In the control unit 50, the communication quality of each subchannel is determined based on the received uplink signal. Then, based on the determined communication quality, a communication subchannel to be allocated to the mobile station device 100, a modulation scheme of adaptive modulation data (communication data), and the like are determined. Then, the control unit 50 generates control information (MAP, ACK, MI) based on the determined information.

  The fixed modulation data generating unit 42 generates fixed modulation data based on the control information generated by the control unit 50. Details of the fixed modulation data generation processing in the fixed modulation data generation unit 42 will be described with reference to the flowchart shown in FIG.

  As shown in FIG. 6, the fixed modulation data generation unit 42 receives control information (MAP, ACK, MI) from the control unit 50 (S101). Then, a CRC code is calculated for a CRC calculation area (see FIG. 3) composed of MAP, ACK, and MI (S102). The calculated CRC code is added to the rear of the CRC calculation area (S102).

  Next, a scramble sequence having the same data length as a scramble area (see FIG. 3) formed by adding a CRC code to the CRC calculation area is generated (S103). The scramble sequence is generated, for example, by inputting CS-ID that is an identifier of the base station apparatus 10 as an initial value to the shift registers S0 to S15 illustrated in FIG. The information used as the initial value may be determined by negotiation in advance by the base station device 10 and the mobile station device 100.

  Then, scramble coding is performed on the data in the scramble area by performing an EXOR between the scramble area data and the generated scramble sequence (S104).

  The data in the scrambled area subjected to the scramble coding is subjected to error correction coding by, for example, an 8PSK trellis code circuit shown in FIG. 8 (S105). 0 is added as the TAIL bit to the end of the data in the scrambled area subjected to error correction coding (S105). As described above, the TAIL bit is added to set the value of the shift register of the encoding circuit to zero.

  As described above, the fixed modulation data generation unit 42 generates fixed modulation data (including control information) that fixes the modulation method.

  Next, the adaptive modulation data generation unit 44 generates adaptive modulation data. Adaptive modulation data is mainly communication data carried by ESCH. The adaptive modulation data is generated by applying predetermined coding such as symbol interleaving, scrambling coding, CRC code addition, error correction coding, etc. to the data bit string transmitted to the mobile station apparatus 100.

  In the modulation unit 46, the fixed modulation data formed in the fixed modulation data generation unit 42 is converted into a complex symbol sequence according to a fixed modulation method. In addition, the adaptive modulation data formed in the adaptive modulation data generation unit 44 is converted into a complex symbol string in accordance with the modulation scheme specified by the MI included in the control information.

  In the inverse Fourier transform unit 48, the complex symbol sequence generated by the modulation code unit is serial-parallel converted as N symbol sequences and output. The output N symbol strings are collectively converted in the inverse Fourier transform unit 48 to generate sample values of N OFDM symbols. The obtained sample values are subjected to parallel-serial conversion and then output as a continuous time domain complex OFDM baseband signal.

In the communication unit 20, a guard interval (GI) having a length of Tg in the latter half of each symbol of the complex OFDM baseband signal output from the inverse Fourier transform unit 48 is added to the head of each symbol. The real part of the complex OFDM baseband signal to which the GI is added is multiplied by the carrier frequency, and an OFDM signal in the carrier band is output. The output OFDM signal is amplified by the communication unit 20 and then transmitted toward the mobile station apparatus 100 via the antenna 22.
[Processing of Mobile Station Device 100]
Next, downlink signal reception processing in mobile station apparatus 100 will be described.

  The communication unit 120 receives a signal transmitted from the base station apparatus 10 via an antenna. The received signal is amplified, converted to an intermediate frequency, and A / D converted, and then converted to an OFDM baseband signal.

  The symbol synchronization unit 132 performs symbol synchronization using a guard interval included in the OFDM baseband signal output from the communication unit 120.

  In the Fourier transform unit 134, a complex symbol sequence that modulates each carrier wave is extracted by performing a Fourier transform on the OFDM baseband signal. The extracted symbol is subjected to parallel-serial conversion and then output as a frequency-domain OFDM demodulated signal.

  The timing estimation unit 136 performs time direction interpolation on the OFDM demodulated signal, and then the frequency / channel estimation unit 138 performs frequency direction interpolation of the OFDM demodulated signal. Thus, the influence of the characteristics of the transmission path on the OFDM demodulated signal output from the Fourier transform unit 134 is corrected.

  Note that details of the processing in the communication unit 120, symbol synchronization unit 132, Fourier transform unit 134, timing estimation unit 136, and frequency / channel estimation unit 138 overlap with the signal reception processing described in the base station apparatus 10. This is omitted here.

  The demodulator 140 demodulates the data bit string from the OFDM demodulated signal output from the timing estimator 136. The demodulator 140 includes a fixed modulation data demodulator 140A and an adaptive modulation data demodulator 140B, which perform demodulation of fixed modulation data and demodulation of adaptive modulation data, respectively. The demodulation processing performed in the demodulation unit 140 will be described with reference to the flowchart of FIG.

  An OFDM demodulated signal is input to fixed modulation data demodulator 140A (S201). Then, error correction processing is performed on the input OFDM demodulated signal (S202). After error correction is performed, scramble-encoded scrambled area data is acquired from the fixed modulation data included in the OFDM demodulated signal (S202).

  Then, fixed modulation data demodulation section 140A generates a scramble sequence having the same data length as that of the scramble area (S203). This scramble sequence is generated by inputting the CS-ID of the base station apparatus 10 as an initial value into a shift register circuit as shown in FIG. 7 in the same manner as the processing in the base station apparatus 10. Then, fixed modulation data demodulation section 140A performs decoding (descrambling) by taking an EXOR between the generated scramble sequence and the received scrambled area data (S204).

  Fixed modulation data demodulation section 140A performs error detection based on the CRC code for the decoded scrambled area data (S205). Error detection is performed by dividing the data in the scramble area by the bit string indicated by the generator polynomial, and determining that the data is correct if there is no remainder, and determining that the data has an error if there is a remainder. Is called.

  When an error is detected in the decoded fixed modulation data (control information including MAP information) in fixed modulation data demodulation section 140A (S206: Y), control section 150 has not assigned a communication channel. It is set as a thing (S207). This prevents the signal from being transmitted according to the MAP information including an error. If no error is detected in the decoded fixed modulation data in fixed modulation data demodulation section 140A (S206: N), control section 150 uses communication channel (ASCH) to be used according to the received MAP information. , ESCH) is set (S208).

  In adaptive modulation data demodulation section 140B, adaptive modulation data is demodulated into a data bit string by symbol determination according to the modulation method indicated by MI of the control information. The demodulated data bit string is output to the control unit 150.

  Regarding the signal transmission processing by the mobile station apparatus 100, if no error is detected in the fixed modulation data (control information including MAP information) received by the ASCH, the communication channel set based on the MAP information is used. Communication is performed. On the other hand, when an error is detected in the fixed modulation data, since a communication channel is not assigned, the signal is not transmitted based on the MAP information in which the error is detected.

  According to the mobile communication system according to the embodiment of the present invention described above, when an error is detected in the received control information based on the error detection code added to the control information including the allocated channel information. The communication channel is not set according to the allocated channel information. Thus, by transmitting a signal based on incorrect allocation channel information, it is possible to prevent interference with communication of surrounding base station devices and mobile station devices. Further, control information including allocation channel information is scrambled using information shared between the base station apparatus and the mobile station apparatus, so that erroneous allocation channel information cannot be decoded. By doing so, it is possible to prevent a signal from being transmitted based on incorrect allocation channel information.

  In addition, this invention is not limited to said embodiment.

  For example, in the above embodiment, when generating a scramble sequence for scramble coding, the CS-ID of the base station device is used, but this may be the PS-ID of the mobile station device, Other identification information may be used.

  In the above embodiment, the present invention is applied to an OFDMA mobile communication system. However, the present invention can also be applied to a mobile communication system employing other multi-channel communication systems.

1 mobile communication system 10, 10A, 10B, 10C base station apparatus, 20 communication unit, 22 antenna, 30 signal processing unit, 32 symbol synchronization unit, 34 Fourier transform unit, 36 timing estimation unit, 38 frequency / channel estimation unit , 40 demodulator, 42 fixed tone data generator, 44 adaptive modulation data generator, 46 modulator, 48 inverse Fourier transform, 50 controller, 100, 100A, 100B, 100C mobile station apparatus, 120 communication unit, 122 antenna , 130 signal processing unit, 132 symbol synchronization unit, 134 Fourier transform unit, 136 timing estimation unit, 138 frequency / channel estimation unit, 140 demodulation unit, 140A fixed modulation data demodulation unit, 140B adaptive modulation data demodulation unit, 142 fixed modulation data Generation unit, 144 Adaptive modulation data generation unit, 146 Modulation unit, 148 Fourier transform unit, 150 controller.

Claims (4)

A mobile communication system comprising: a base station device; and a mobile station device that performs communication by being assigned at least a part of a plurality of wireless communication channels constituting a communication frame by the base station device,
The base station device
A wireless communication channel for transmitting to the mobile station device by adding an error detection code to control information including assigned channel information designating information of a wireless communication channel assigned to the mobile station device for transmitting / receiving communication data, Assigning means assigned from the frame;
Control information transmitting means for transmitting the control information for each communication frame in the wireless communication channel assigned by the assigning means,
The mobile station device
Receiving means for receiving the control information transmitted by the control information transmitting means for each communication frame;
An error detecting means for detecting an error of the allocated channel information for each communication frame based on an error detecting code added to the control information received by the receiving means;
Transmission control means for controlling not to transmit a signal using a radio communication channel specified by the allocation channel information of a communication frame in which an error is detected by the error detection means,
A mobile communication system. A wireless communication method performed by a base station device and a mobile station device that performs communication by being assigned at least a part of a plurality of wireless communication channels constituting a communication frame by the base station device,
Radio transmitted from the base station apparatus by adding an error detection code to control information including allocated channel information that designates information of a radio communication channel to be allocated to the mobile station apparatus in order to transmit / receive communication data to the mobile station apparatus Assigning a communication channel from the communication frame;
A control information transmission step in which the base station apparatus transmits the control information for each communication frame in the radio communication channel allocated in the allocation step;
A receiving step in which the mobile station apparatus receives the control information transmitted in the control information transmitting step for each communication frame;
An error detection step in which the mobile station apparatus detects an error in the allocated channel information for each communication frame based on an error detection code added to the control information received in the reception step;
A transmission control step for controlling the mobile station apparatus so as not to transmit a signal using a radio communication channel specified by allocation channel information of a communication frame in which an error is detected in the error detection step;
A wireless communication method. A base station apparatus that performs communication by allocating at least a part of a plurality of wireless communication channels that constitute a communication frame to a mobile station apparatus,
A wireless communication channel for transmitting to the mobile station device by adding an error detection code to control information including assigned channel information designating information of a wireless communication channel assigned to the mobile station device for transmitting / receiving communication data, Assigning means assigned from the frame;
Control information transmitting means for transmitting the control information for each communication frame in the wireless communication channel assigned by the assigning means,
The control information transmitted by the control information transmitting means is received by the mobile station device for each communication frame,
Based on the error detection code added to the received control information, the mobile station apparatus detects an error in the allocated channel information for each communication frame,
The mobile station apparatus is controlled so that a signal is not transmitted using a radio communication channel specified by allocation channel information of a communication frame in which an error is detected by the mobile station apparatus;
A base station apparatus. Allocation channel information that specifies information of a radio communication channel to be allocated to the mobile station apparatus in order to perform communication by allocating at least a part of a plurality of radio communication channels constituting a communication frame to the mobile station apparatus and transmitting / receiving communication data Allocating a radio communication channel to be transmitted to the mobile station apparatus by adding an error detection code to control information including the communication information from the communication frame, and communicating the control information using the radio communication channel allocated by the allocating means A mobile station apparatus that communicates with a base station apparatus including a control information transmission unit that transmits each frame,
Receiving means for receiving the control information transmitted by the control information transmitting means for each communication frame;
An error detecting means for detecting an error of the allocated channel information for each communication frame based on an error detecting code added to the control information received by the receiving means;
Transmission control means for controlling not to transmit a signal using a radio communication channel specified by the allocation channel information of a communication frame in which an error is detected by the error detection means,
A mobile station apparatus.

Images