JP5478335B2 - Wireless communication system - Google Patents

Description

  The present invention relates to a wireless communication system in which the same transmission data is divided into a plurality of signals having different frequencies and transmitted in parallel from a transmitting station to a plurality of receiving stations, and in particular, one receiving station has an error packet having a single frequency. The present invention relates to a wireless communication system that returns a response signal to a transmitting station.

  Conventionally, many forms of wireless communication devices have been developed, manufactured, and used. In such wireless communication devices, a technique for improving communication efficiency by preparing and using a plurality of channels is known. ing. For this communication channel, for example, different channels can be set by changing the frequency, and even if different signals are transmitted at the same time, they can be separated and transmitted without interference.

  Patent Document 1 discloses a technique for transmitting the same transmission data to a plurality of receiving apparatuses via a plurality of channels by a wireless LAN (Local Area Network) technique.

JP-A-2005-252937

  However, Patent Document 1 discloses a technique for transmitting the same transmission data from a transmitting station to a plurality of receiving stations via a plurality of channels by a wireless LAN (Local Area Network) technique. There is no description about how it is efficient to send error packet information of the packet from the receiving station to the transmitting station.

  That is, in a wireless communication system, when performing broadcast communication from a transmitting station to a plurality of receiving stations, the transmission speed is improved if transmission data is further divided into a plurality of signals having different frequencies and transmitted simultaneously. However, at this time, if a plurality of receiving stations send packet information back to each transmitting station at a frequency at which packet information is received at a plurality of different frequencies for transmission, signal waiting occurs due to signal collision, so processing time Will be delayed.

  An object of the present invention is to provide a wireless communication system that allows a transmitting station to quickly receive error packet information from a receiving station when performing broadcast communication using a plurality of frequencies.

One embodiment to solve the problem is:
A wireless communication system comprising a plurality of receiving stations (1-2, 1-3, 1-4) and a transmitting station (1-1) that respectively transmits the same transmission data to the plurality of receiving stations,
The transmitting station divides the transmission data into a plurality of pieces, and transmits the divided transmission data in parallel to the plurality of receiving stations using different frequencies, respectively.
Each receiving station returns an error response packet for transmission data transmitted from the transmitting station,
The error response packet is a method of returning error packet response information for transmission data transmitted using the frequency for each of the plurality of different frequencies (F1, F2, F3,...) To the transmitting station in a time division manner; At least one of the methods of returning a plurality of error packet response information corresponding to a plurality of transmission data respectively transmitted using a plurality of different frequencies to the transmitting station using one of the plurality of different frequencies A wireless communication system characterized by being returned by the method.

  When a transmitting station performs broadcast communication (communication in which communication of the same contents is simultaneously performed by a plurality of receiving stations) divided into a plurality of receiving stations by a plurality of frequencies F1, F2, and F3, Even when receiving transmission signals at F1, F2, and F3, when transmitting error packet information from the receiving station to the transmitting station, the first receiving station has the first frequency F1, the second receiving station has the second frequency F2, The third receiving station returns error packet information at a dedicated frequency to the receiving station like the third frequency F3. As a result, the transmitting station can quickly receive error packet information from the receiving station.

Explanatory drawing which shows an example of the communication system which concerns on one Embodiment of this invention. The block diagram which shows an example of a structure of the radio | wireless communication apparatus contained in the said communication system. Explanatory drawing which shows the format of the frame signal handled with the said communication system. Explanatory drawing which shows an example of the operation | movement sequence for the simultaneous communication in the said communication system. Explanatory drawing which shows an example of the operation | movement sequence for the simultaneous communication which has the characteristic of the transmission frequency in the said communication system. Explanatory drawing which shows an example of the structure of the frame format of an error packet response channel in the said communication system. Explanatory drawing which shows an example of the operation | movement sequence for the simultaneous communication by the transmission frequency F1 in the said communication system. Explanatory drawing which shows an example of the operation | movement sequence for the simultaneous communication by the transmission frequency F2 in the said communication system. Explanatory drawing which shows an example of the other structure of the frame format of an error packet response channel in the said communication system.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
As shown in FIG. 1, the wireless communication device 1 according to an embodiment of the present invention functions as the transmitter 1-1 in the transmission mode while communicating with the spectrum management server 2, and the first receiver in the reception mode. The transmission data is transmitted by wireless communication to the other wireless communication devices 1 functioning as 1-2, the second receiver 1-3, the third receiver 1-4,.

  First, the configuration of the radios of the transmitting station 1-1 and the first to third receiving stations 1-2, 1-3, and 1-4 in FIG. 1 will be described with reference to FIG. Here, since the transmitting station 1-1 differs from each receiving station only in that it has a communication function with the spectrum management server 2, illustration and description of the communication function with the spectrum management server 2 are omitted in FIG. A description will be given of a configuration common to the transmitting station 1-1 and the first to third receiving stations 1-2, 1-3, and 1-4.

  The wireless communication device 1 includes a control unit 11 connected to each component to control the overall operation, a display unit 12 for displaying images and characters, an operation unit 13 for operator operations, character information and photos A packet processing unit 14 that packetizes information and the like, converts the packet into character information, photo information, and the like; a division / assembly unit 15 that divides transmission data according to the number of channels and assembles the divided transmission data; A frame processing unit 16 that generates a channel from the divided transmission data, an error detection unit 17 that detects an error in the frame processing unit 16, an automatic retransmission control unit 18 that performs automatic retransmission processing based on error detection, and transmission data Are composed of a plurality of data transmission / reception units 19, 20, and 21. Each processing unit, which is a component in the data transmission / reception unit 19, operates based on control information from the control unit 11, and includes an error correction unit 22, a modem unit 23, and a radio unit 24. .

  The wireless communication device 1 of this embodiment is premised on half-duplex communication in the following description. Half-duplex communication is a communication method in which data cannot be transmitted or received from both at the same time in bidirectional communication, and transmission can only be performed from one direction at a time interval. In order to exchange data in both directions, the data transmission / reception unit 19 has a function of switching the communication direction by switching the processing to the transmission mode / reception mode in time division according to an instruction from the control unit 11. ing.

  In the transmission mode, the dividing / assembling unit 15 performs a process of dividing the data (a2) such as an electronic mail and an electronic file into n equal parts, and the divided data (d2-1) (d2-2) (d2- n) is output, and in the reception mode, the divided data (d2-1) (d2-2). Here, the number of divisions is indicated by control information from the control unit 11. In the description of this embodiment, it is assumed that the number of divisions is 3, and the transmission is performed in parallel using three frequencies.

  In the transmission mode, the frame processing unit 16 inputs the divided data (d2-1) (d2-2) (d2-3) and the control signal, and generates each channel having the frame format configuration shown in FIG. . Here, 5 shown in FIGS. 3A to 3E separately for each of the three divided data (d2-1), (d2-2), and (d2-3) according to an operation sequence described later in FIG. The types of channels are sequentially generated, and three channel strings (e2-1) (e2-2) (e2-3) are simultaneously output.

  The control signal from the operation unit 13 and the control unit 11 is information handled by an application such as e-mail located in a higher layer, such as a message number (number assigned to a communication unit such as e-mail), e-mail, etc. It includes a transmission data size, the number of broadcast destinations, a source IP address, and one or more destination IP addresses.

  Further, as described above, the control signals from the operation unit 13 and the control unit 11 are information for setting the specification (operation) of the data transmission / reception unit 19, and the transmission mode / reception mode switching control information and transmission data division are performed. Number, modulation / demodulation method type information, data block size, packet size, and usage frequency information (frequency and number) are included. Here, the divided data (d2-1), (d2-2), and (d2-3) such as e-mail and electronic file are divided in units of packets, and the error detection unit 17 inputs the packet and receives an error. The detection code is added and returned to the frame processing unit 16 as a packet with the error detection code added. The data block is composed of a plurality of packets, and automatic retransmission control (ARQ) is executed for each data block transmission. The data block size and the packet size are managed and stored in the control unit 11, and may be configured to be input and set from a control panel (not shown) or a control PC. Further, the use frequency information (frequency and number) is instructed from the spectrum management server 2 as described above, and is managed and stored by the control unit 11.

  Next, the frame format configuration of each channel shown in FIG. 3 will be described. First, the common channel portion of FIGS. 9A to 9E will be described. The synchronization information d11, d21, d31, d41, d51 is a synchronization pattern for detecting the start point of each channel. On the other hand, a synchronization pattern for demodulating the received signal is inserted by the modem unit 23. Setting information d12, d22, d32, d42, and d52 are control channel type information (line setting / initial transmission data / retransmission data / error packet billing / error packet response / line release identification information) and modulation / demodulation method type for data packet d24. Information (identification information such as BPSK / QPSK / 16QAM). For the control information other than the data packet d24, the modulation / demodulation method to be applied is fixed, and the control information is more important than the data packet. For example, BPSK having the strongest noise resistance is used. Also, control information other than the data packet d24 is added to the frame of each channel after an error detection code is added by the error detection unit 17.

  First, the line setting channel (FIG. 3A) includes synchronization information d11, setting information d12, transmission data size d13, transmission source IP address d14, number of destinations d15, first transmission destination IP address d16, and second transmission destination. It consists of an IP address d17 and a third destination IP address d18. Here, in this embodiment, the transmission source IP address d14, the first transmission destination IP address d16, the second transmission destination IP address d17, and the third transmission destination IP address d18 are respectively the transmission station 1-1 and the first transmission address in FIG. This corresponds to the addresses of one receiving station 1-2, second receiving station 1-3, and third receiving station 1-4. The destination number d15 is set to 3.

  Next, the data channel and the retransmission data channel (FIG. 3B) are composed of synchronization information d21, setting information d22, data block information d23, and data packet d24. The data block information d23 includes a data block size, final data block identification information, a packet size, a message number, a data block number, and the number of packets per data block. The data packet d24 is packed with the number of packets per data block.

Next, the error packet billing channel (FIG. 3C) includes synchronization information d31, setting information d32, and error packet billing information d33. The error packet billing information d33 includes receiving station designation information requesting a response, a data block number, and a message number.
Next, the error packet response channel (FIG. 3 (d)) includes synchronization information d41, setting information d42, and error packet response information d43. The error packet response information d43 includes a data block number, a message number, and error packet information (error presence / absence information of all packets in the data block specified by the data block number).

Finally, the line release channel (FIG. 3 (e)) includes synchronization information d51 and setting information d52.
Next, in the reception mode, the frame processing unit 16 shown in FIG. 2 receives the data (d2) divided from the reception data (channel sequence) (e2-1) (e2-2) (e2-3) for each frequency. -1) Extract and output control information (d2-2) and (d2-3).

  The three channel strings (e2-1), (e2-2), and (e2-3) are processed by the separate data transmitting / receiving units 19, 20, and 21, respectively, and the wireless signals (h2-1) (h2-2) ( h2-3) is transmitted and received. Here, the carrier frequencies of the radio signals (h2-1), (h2-2), and (h2-3) are F1, F2, and F3, respectively. These utilization frequencies are instructed as one of the control information from the control unit 11 as described above.

The data transmission / reception units 19, 20, and 21 are configured by an error correction unit 22, a modem unit 23, and a radio unit 24, respectively. The following description will be limited to the internal processing of the data transmission / reception unit 19, but the same processing is performed in the data transmission / reception units 19, 20, and 21.
In the transmission mode, the error correction unit 22 receives the information of the channel sequence (e2-1), performs error correction encoding, and outputs the data sequence after error correction encoding to the modem unit 23. In the reception mode, the demodulated reception data sequence is received from the modem unit 23, error correction processing is performed, and the error-corrected reception data sequence (reception channel sequence) (e2-1) is output to the frame processing unit 16.

  In the transmission mode, the modulation / demodulation unit 23 uses the method specified by the modulation / demodulation method type information (identification information such as BPSK / QPSK / 16QAM) included in the control information from the control unit 11 to perform data after error correction coding. The data packet d24 in the column is modulated, and control information other than the data packet d24 is modulated by BPSK as described above, and the modulated signal is output to the radio unit 24. In the reception mode, the baseband reception signal output from the radio unit 24 is demodulated using the demodulation method designated by the control unit 11 and the demodulated signal is output to the error detection unit 17.

  Although the illustration of the internal configuration of the radio unit 24 is omitted, in the transmission mode, a transmission filter process, a carrier is performed on the modulation signal from the modulation / demodulation unit 23 based on the use frequency information included in the control information from the control unit 11. Orthogonal modulation processing for up-conversion to frequency is performed, and a transmission radio wave h2-1 is transmitted to the receiver 1-2 via the transmission / reception antenna 25. In the reception mode, an orthogonal demodulation process and a reception filter process for down-converting the radio wave h2-1 received from the transmitter 1-1 via the transmission / reception antenna 25 or the like to the baseband frequency based on the use frequency information from the control unit 11. The baseband received signal is output to the modem unit 23. Here, each of the above-described components in the wireless unit 24 is configured to be able to transmit / receive by switching the frequency based on the transmission / reception frequency specified by the control unit 11.

The automatic retransmission control unit 18 is a component that performs automatic retransmission control according to an operation sequence of FIG. 4 to be described later, and operates in cooperation with the frame processing unit 16. In the transmission mode, and stores and manages the error packet according channels (FIG. 3 (c)) the error packet billing information d 3 information included in 3 at (requested receiver specifying information response, data block number, message number) If there is an error in the result of the error packet response from the receiver, a retransmission data channel is generated and the corresponding packet is retransmitted to the receiver 1-2. In the reception mode, when an error packet request channel (FIG. 3 (c) ) is received from the transmitter 1-1, information included in the error packet request information d 3 3 (receiver designation information and data requested for a response) For the received packet corresponding to the block number and message number), the error detection unit 17 performs error detection, and the error detection result is input to the frame processing unit 16 as an automatic retransmission control signal.

  In the present embodiment, it is assumed that a packet error response is returned to all data blocks. The frame processing unit 16 creates error packet response information d43 in the error packet response channel (FIG. 3 (d)) based on the automatic retransmission control signal from the automatic retransmission control unit 18, and together with the synchronization information d41 and the setting information d42 ( The data is input to the data transmitting / receiving unit 19 as e2-1). The data block number and message number related to retransmission are also stored and managed. Since half-duplex communication is assumed, transmission / reception switching is required when returning an error packet response channel. The timing is shown in the description of the operation sequence shown in FIG. 4 below. .

-1st Embodiment 1st Embodiment performs the parallel transmission using a some frequency when performing broadcast communication from a transmitting station to several receiving stations, and is an error for automatic retransmission control from a receiving station to a transmitting station. A specific example of transmitting a packet response is specified, and a method is described in which each receiving station responds to the transmitting station with error packet response information in a time division manner for each use frequency. FIG. 4 is an explanatory diagram showing an example of an operation sequence for simultaneous communication in the communication system.

  FIG. 4 shows three operation sequences SK1, SK2, and SK3 in which communication is performed at three frequencies (F1, F2, and F3), respectively, which are radio signals h2-1, h2-2, and h2 in FIG. -3 communication. Since these three operation sequences SK1, SK2, and SK3 perform exactly the same operation, only the operation sequence SK1 at the frequency F1 will be described below.

The transmitting station 1-1, the first receiving station 1-2, the second receiving station 1-3, and the third receiving station 1-4 are the transmitting station 1-1 and the first receiving station 1 in the configuration of the wireless communication network of FIG. This corresponds to the receiving station 1-2, the second receiving station 1-3, and the third receiving station 1-4.
At the start of communication, first, the control unit 11 and the data transmitting / receiving unit 19 of the transmitting station 1-1 transmit a channel setting channel to each receiving station (step S1). As described above, the line setting channel includes the source IP address, the number of destinations, and the destination IP address, and all the receiving stations in the wireless communication network receive the line setting channel, If the address is included, it is recognized that it is a transmission target and the subsequent communication is continued. If it is not included, the subsequent communication is ignored. In this example, the first receiving station 1-2, the second receiving station 1-3, and the third receiving station 1-4 are transmission targets (destination) from the transmitting station 1-1.

  Next, the data channel is transmitted from the transmitting station 1-1 to each receiving station (step S2). The data channel includes data packets for one data block. Each time transmission of a data packet for one data block is completed, the following automatic retransmission control operation sequence (step S3) to (step S7) is executed.

  The transmitting station 1-1 transmits an error packet request channel to each receiving station in order to confirm whether or not the transmitted data packet can be accurately transmitted with no transmission error (step S3). Since it is half-duplex communication (the transmitting station and the receiving station transmit using the same frequency F1), when each receiving station receives an error packet request channel, it switches to a transmission state to return an error packet response channel. However, the reception mode state is maintained.

At the time of the error packet response, the first receiving station 1-2, the second receiving station 1-3, and the third receiving station 1-4 have the same frequency (the same frequency as the data channel corresponding to the error packet response or the error packet requesting channel). In order to use a certain F1), it is necessary to transmit the error packet response channel to the transmitting station in a time division manner. The timing will be described below.
The first receiving station 1-2 transmits a packet response channel to the transmitting station at the transmission frequency F1 T1 after the reception of the error packet request channel in step S3 is completed (step S4). T1 is the time from the completion of reception of the error packet solicitation channel until the receiving station 1 starts transmitting an error packet response, and is the time required for the above-described switching from reception to transmission state and data processing for packet response channel generation. is there. When the transmission of the packet response channel ends, the first receiving station 1-2 returns to the reception state again.

  When the transmitting station 1-1 receives an error packet response between T1 and T1 + T2 (between time A and time B in FIG. 4) after completion of transmission of the error packet billing channel in step S3 (step S4), the first reception It is recognized as a response from the station 1-2. T2 is the time required for transmission of the error packet response, and in addition to the data transmission time (T2t) from the receiving station, it absorbs the difference in the delay time in the propagation path due to the difference in the location of each receiving station. A margin (T2m) is included.

The second receiving station 1-3 transmits a packet response channel to the transmitting station 1-1 after T1 + T2 from completion of reception of the error packet request channel in step S3 (step S5). When the transmission of the packet response channel ends, the second receiving station 1-3 returns to the reception state again.
When the transmitting station 1-1 receives an error packet response between T1 + T2 and T1 + T2 × 2 (between time B and time C in FIG. 4) after completion of transmission of the error packet billing channel in step S3, the second receiving station 1 It is recognized as a response from -3 (step S5).

The third receiving station 1-4 transmits a packet response channel to the transmitting station T1 + T2 × 2 after the reception of the error packet request channel in step S3 is completed (step S6). When the transmission of the packet response channel is completed, the third receiving station 1-4 returns to the reception state again.
When the transmitting station 1-1 receives an error packet response between T1 + T × 2 and T1 + T2 × 3 (between time C and time D in FIG. 4) after completion of transmission of the error packet request channel (step S3) in step S3 It is recognized as a response from the third receiving station 1-4 (step S6).

  Next, when the error packet response from each receiving station indicates that there is a packet error, the transmitting station 1-1 retransmits the corresponding data block through the retransmission data channel (step S7). Here, the transmitting station 1-1 retransmits the data to all the receiving stations, and each receiving station validates the received data only when a packet for which retransmission is requested (responses that there is an error) is sent, and is retransmitted. Received data not requested is ignored.

After retransmitting the data block, the transmitting station 1-1 transmits the error packet request channel to all the receiving stations (step S8), and the subsequent operation sequence is the same as that shown in steps S4 to S6. For this reason, illustration is omitted.
Although not shown, when there is no packet error in the error packet response reception in steps S4, S5, and S6, the transmitting station 1-1 transmits a data channel having the next data block information, and then Then, step S3 to step S6, which is an operation sequence of automatic retransmission control, are executed.

  The data channel transmission in step S2 or the retransmission data channel transmission in step S7 and the automatic retransmission control operation sequence in steps S3 to S6 are repeated until transmission of all data blocks is completed. 1 transmits a channel release channel to all receiving stations and ends communication (step S9).

Thus, as shown in the operation sequence at each frequency in FIG. 4, the transmission time T_ARQ required for automatic retransmission control (ARQ) per data block transmission (excluding retransmission) is:
T_ARQ = T1 + T2 × number of receiving stations
= T1 + (T2t + T2m) × number of receiving stations
= T1 + (T2t + T2m) × 3 (Formula 1)
In (Expression 1), as described above, T2 includes a margin T2m for absorbing the difference between the transmission time T2t of the error packet response and the delay time in the propagation path due to the difference in the location of the receiving station. .

  According to the operation shown in the first embodiment, as shown in (Equation 1), an amount of margin (T2m × the number of receiving stations) proportional to the number of receiving stations in broadcast communication is required, and one data block is transmitted. Since the transmission time T_ARQ required for per-ARQ is increased and the transmission time is affected in proportion to the number of data blocks, the total data transmission time is increased. This is because an error packet response signal transmitted from one receiving station is transmitted to the transmitting station as signals of a plurality of different frequencies F1, F2, and F3.

Second Embodiment In the second embodiment, broadcast communication in which a transmitting station divides a plurality of receiving stations into a plurality of frequencies (F1, F2, F3,...) (Communication with the same contents is performed simultaneously on a plurality of receiving stations) When performing transmission), even if each receiving station receives a transmission signal at a plurality of frequencies (F1, F2, F3,...), When transmitting error packet information from the receiving station to the transmitting station, the first The receiving station 1-2 has the first frequency F1, the second receiving station 1-2 has the second frequency F2, and the third receiving station 1-4 has the third frequency F3. Specific to reply. Thereby, since the transmission time T_ARQ required for ARQ per one data block transmission can be shortened, the transmitting station can promptly receive error packet information from the receiving station. FIG. 5 is an explanatory diagram showing an example of an operation sequence for simultaneous communication having the characteristics of the transmission frequency in the communication system.

  FIG. 5 shows the operation sequences of the frequency F1, the frequency F2, and the frequency F3 simultaneously, and these three sequences are executed simultaneously in parallel. At the start of communication, the control unit 11 and the data transmission / reception unit 19 of the transmitting station 1-1 use the signals of frequency F1, frequency F2, and frequency F3 to the receiving stations 1-2, 1-3, and 1-4. At the same time, the line setting channel is transmitted (step S11). As described above, the line setting channel includes the source IP address, the number of destinations, and the destination IP address, and all the receiving stations in the wireless communication network receive the line setting channel, If the address is included, it is recognized that it is a transmission target and the subsequent communication is continued. If it is not included, the subsequent communication is ignored. Next, the data channel is simultaneously transmitted from the transmitting station 1-1 to the receiving stations 1-2, 1-3, and 1-4 by signals of frequency F1, frequency F2, and frequency F3 (step S12). The data channel includes data packets for one data block. Each time transmission of a data packet for one data block ends, the following automatic retransmission control operation sequence (step S13) to (step S17) is executed. Further, the transmitting station 1-1 simultaneously transmits the error packet request channel to the receiving stations 1-2, 1-3, and 1-4 by the signals of the frequency F1, the frequency F2, and the frequency F3 (step S13). ).

  On the other hand, the first receiving station 1-2 transmits a packet response channel at the transmission frequency F1 to the transmitting station 1-1 after T1 from completion of reception of the error packet request channel in step S13 (step S14). Further, the second receiving station 1-3 transmits a packet response channel with the transmission frequency F2 to the transmitting station 1-1 after T1 from completion of reception of the error packet request channel in step S13 (step S14). Further, the third receiving station 1-4 transmits a packet response channel with the transmission frequency F3 to the transmitting station 1-1 after T1 from the completion of reception of the error packet request channel in step S13 (step S14).

  Thus, it should be noted in the present embodiment that the first receiving station 1-2 is only an error packet response channel using the frequency F1, and the second receiving station 1-3 is only an error packet response channel using the frequency F2. The third receiving station 1-4 transmits only an error packet response channel using the frequency F3. Thereby, as will be described later, the transmitter 1-1 is configured such that the first receiving station 1-2 has only the frequency F1, the second receiving station 1-3 has only the frequency F2, and the third receiving station 1-4 has only the frequency F3. Thus, since the error packet response channel is received, the reception time is shortened as will be described later.

  Here, each error packet response channel in the second embodiment has a frame format of the first receiving station 1-2, the second receiving station 1-3, the third receiving station 1-, as shown in FIG. 4 is a form in which error packet information d61, d62, and d63 of data channels (received packets) at all frequencies (F1, F2, and F3) received are aggregated.

  Similarly to the first embodiment, T1 is the time from the completion of reception of the error packet billing channel in step S13 until the first receiving station starts transmitting an error packet response, switching from reception to transmission state, and This is the time required for data processing for generating a packet response channel. When the transmission of the packet response channel (step S14) ends, the first receiving station 1-2, the second receiving station 1-3, and the third receiving station 1-4 return to the receiving state again.

  The transmitting station 1-1 receives the first receiving station 1-2 and the second receiving station 1-between T 1 and T 1 + T 2 ′ (between time G and time H in FIG. 5) from the completion of transmission of the error packet billing channel in step S 13. 3. Receives error packet responses from the third receiving stations 1-4. T2 ′ is a transmission time required for an error packet response, and a margin for absorbing a difference in delay time in a propagation path due to a difference in location of each receiving station in addition to a data transmission time T2t ′ from the receiving station T2m is included.

Further, subsequent processing such as transmission of a retransmission data channel (steps S15 to S17) and the like are the same as those in the first embodiment.
As described above, in the second embodiment, one frequency is assigned to each of the receiving stations 1-2, 1-3, and 1-4 for transmission of an error packet response channel, and error packet response information for received data at all frequencies is assigned. As a result, the transmission time T_ARQ ′ required for ARQ per one data block transmission is expressed by (Equation 2).

T_ARQ '= T1 + T2'
= T1 + (T2t '+ T2m) (Formula 2)
Here, as described above, T2 ′ is a communication time required for an error packet response, and is a transmission time from the receiving station (T2t ′) and a delay time in the propagation path due to a difference in location of each receiving station. A margin (T2m) for absorbing the difference is included.

  When (Equation 2) representing the transmission time required for ARQ per data block transmission is compared with (Equation 1) in the first embodiment, in (Equation 1), the amount is proportional to the number of receiving stations in broadcast communication. A margin (T2m × the number of receiving stations = T2m × 3) is required, whereas in (Equation 2), the margin is constant (T2m) regardless of the number of receiving stations.

  In addition, as for T2t ′ in (Equation 2), as shown in the frame format configuration of FIG. 6, only one synchronization and setting information is required, so in the first embodiment (T2t × number of receiving stations = T2t × 3) ) It will be a shorter time. Therefore, the transmission time required for ARQ per data block transmission in the second embodiment can be shortened as T_ARQ ′ (second embodiment) <T_ARQ (first embodiment).

  As described above, in the second embodiment, the frequency of the transmission signal from the transmission station 1-1 to the reception stations 1-2, 1-3, and 1-4 uses a plurality of frequencies such as the frequencies F1, F2, and F3. On the other hand, the error packet response signal from each receiving station 1-2, 1-3, 1-4 to the transmitting station 1-1 is that the first receiving station 1-2 has only the frequency F1, and the second receiving station 1 Since −3 is only the frequency F2 and the third receiving station 1-4 is only the frequency F3, the signal waiting time in the first embodiment is eliminated, so that rapid reception processing is possible.

  In the description of the second embodiment, it is assumed that the number of used frequencies is the same as the number of receiving stations. However, the number of used frequencies is less than the number of receiving stations as in the following third embodiment. Even when the number of frequencies used is 2 or more and error packet response information for received data at a plurality of frequencies can be aggregated and transmitted simultaneously at two or more receiving stations, the time to the margin (T2m) Since the distribution can be reduced, the transmission time required for ARQ can be shortened as compared with the first embodiment.

Third Embodiment In the third embodiment, a dedicated frequency for error packet response is not allocated to all of the plurality of receiving stations 1-2, 1-3, and 1-4. 2, 1-3, specify a case where dedicated frequencies F1 and F2 are allocated only to some receiving stations, for example, the first receiving station 1-2 and the second receiving station 1-3 . That is, here, an example in which the number of used frequencies is two (frequency is F1 and F2) and the number of receiving stations is three will be described below.

FIG. 7 shows an operation sequence at the frequency F1, and FIG. 8 shows an operation sequence at the frequency F2. These two sequences are executed in parallel at the same time. Here, the operation sequence of only the automatic retransmission control part will be described.
In the operation sequence of the frequency F1 shown in FIG. 7, at the start of communication, the control unit 11 and the data transmission / reception unit 19 of the transmission station 1-1 send the frequency to the reception stations 1-2, 1-3, and 1-4. At the same time, the line setting channel is transmitted by the F1 signal (step S21). Next, the data channel is simultaneously transmitted from the transmitting station 1-1 to each of the receiving stations 1-2, 1-3, and 1-4 by a signal of the frequency F1 (step S22). Next, an error packet request channel is transmitted from the transmitting station 1-1 to each receiving station 1-2, 1-3, 1-4 using a signal of frequency F1 (step S23).

  The first receiving station 1-2 transmits a packet response channel to the transmitting station T1 after completion of reception of the error packet request channel in step S23 (step S24). The error packet response channel here has the frame format shown in FIG. 9, and the error packet information d71, d72 of the data channel (received packet) at all frequencies F1, F2 received by the first receiving station 1-2. It is a form that aggregates.

  Similarly to the first embodiment and the second embodiment, T1 is the time from the completion of reception of the error packet request channel in step S23 until each receiving station starts transmitting an error packet response, from reception to transmission state. Switching and data processing for packet response channel generation. When the transmission of the packet response channel in step S24 ends, the first receiving station 1-2 returns to the reception state again.

  The transmitting station 1-1 receives the error packet response from the second receiving station 1-3 between T1 and T1 + T2 ″ (between time J and time K in FIG. 7) from the completion of transmission of the error packet billing channel in step S23. (Step S24) T2 ″ is a transmission time required for an error packet response, and in addition to the data transmission time (T2t ″) from the receiving station, the delay time in the propagation path due to the difference in the location of each receiving station A margin (T2m) for absorbing the difference is included.

  Next, the third receiving station 1-4 transmits the packet response channel to the transmitting station T1 + T2 ″ after the reception of the error packet request channel in step S23 is completed (step S25). The frame of the error packet response channel here The format is the same as that shown in Fig. 3 (d) and includes error packet information of the data channel (received packet) at the frequency F1 received by the third receiving station 1-4. When the transmission of is completed, the third receiving station 1-4 returns to the reception state again.

  The transmitting station 1-1 transmits an error packet response from the third receiving station 1-4 between T1 + T2 ″ and T1 + T2 ″ + T2 (between time J and time K in FIG. 7) after completion of transmission of the error packet request channel in step S23. Is received (step S25). T2 is a transmission time required for an error packet response, and a margin for absorbing a difference in delay time in a propagation path due to a difference in location of each receiving station in addition to a data transmission time (T2t) from the receiving station (T2m) is included.

Further, subsequent processing such as retransmission data channel transmission (step S26 to step S28) and the like are the same as those in the first and second embodiments.
Similarly, in the operation sequence of the frequency F2 shown in FIG. 8, at the start of communication, the control unit 11 and the data transmission / reception unit 19 of the transmission station 1-1 are connected to the reception stations 1-2, 1-3, and 1-4. On the other hand, the line setting channel is simultaneously transmitted by the signal of the frequency F2 (step S31). Next, the data channel is simultaneously transmitted from the transmitting station 1-1 to each of the receiving stations 1-2, 1-3, and 1-4 by a signal of the frequency F1 (step S32). Next, an error packet request channel is transmitted from the transmitting station 1-1 to each receiving station 1-2, 1-3, 1-4 using the frequency F2 signal to each receiving station (step S33).

  The second receiving station 1-3 transmits a packet response channel to the transmitting station T1 after completion of reception of the error packet request channel in step S33 (step S34). The error packet response channel here has the frame format shown in FIG. 9, and the error packet information d71, d72 of the data channel (received packet) at all frequencies F1, F2 received by the second receiving station 1-3. It is a form that aggregates.

  Similarly to the first embodiment and the second embodiment, T1 is the time from the completion of reception of the error packet request channel in step S33 until each receiving station starts transmitting an error packet response, from reception to transmission state. Switching and data processing for packet response channel generation. When the transmission of the packet response channel in step S34 is completed, the second receiving station 1-3 returns to the reception state again.

The transmitting station 1-1 receives the error packet response from the second receiving station 1-3 between T1 and T1 + T2 ″ (between time J and time K in FIG. 8) after completion of transmission of the error packet request channel in step S33. (Step S34).
Next, the third receiving station 1-4 transmits the packet response channel to the transmitting station T1 + T2 ″ after the reception of the error packet request channel in step S34 is completed (step S35). The frame of the error packet response channel here The format is the same as that shown in Fig. 3 (d) and includes error packet information of the data channel (received packet) at the frequency F2 received by the third receiving station 1-4. When the transmission is completed, the third receiving station 1-4 returns to the reception state again.

  The transmitting station 1-1 transmits an error packet response from the third receiving station 1-4 between T1 + T2 ″ and T1 + T2 ″ + T2 (between time J and time K in FIG. 8) after completion of transmission of the error packet request channel in step S37. Is received (step S35). T2 is a transmission time required for an error packet response, and a margin for absorbing a difference in delay time in a propagation path due to a difference in location of each receiving station in addition to a data transmission time (T2t) from the receiving station (T2m) is included.

Further, subsequent processing such as retransmission data channel transmission (step S26 to step S28) and the like are the same as those in the first and second embodiments.
As described above, in the third embodiment, for the first receiving station 1-2 and the second receiving station 1-3, one frequency is used for transmitting an error packet response channel for each receiving station, the frequency F1, the frequency The method of the second embodiment in which error packet response information for received data at all frequencies is aggregated and transmitted by assigning as in F2 is applied to the third receiving station 1-4. The method of the first embodiment in which each receiving station responds to the transmitting station with error packet response information in a time division manner is applied every time. As a result, the transmission time T_ARQ "required for ARQ per one data block transmission is expressed by (Equation 3).

T_ARQ "= T1 + T2" + T2
= T1 + (T2t ″ + T2m) + (T2t + T2m) (Formula 3)
When (Equation 3) representing transmission time required for ARQ per one data block transmission is compared with (Equation 1) in the first embodiment, the margin in (Equation 1) is (T2m × the number of receiving stations = T2m ×). 3), whereas in (Equation 3), (T2m × 2) is obtained, which indicates that the time is shortened.

In addition, as shown in the frame format configuration of FIG. 9, T2t ″ in (Equation 3) requires only one synchronization and setting information, and therefore when transmitted in a time division manner as in the first embodiment (T2t × 2) The time is shorter.
Therefore, the transmission time required for ARQ per data block transmission in the third embodiment can be shortened as T_ARQ "(third embodiment) <T_ARQ (first embodiment).
Here, the case where the number of used frequencies is 2 and the number of receiving stations is 3 has been described as an example, but the same configuration is used when there are a plurality of used frequencies and the number of receiving stations is larger than the number of used frequencies. Similar effects can be obtained.

  Next, when the number of used frequencies is larger than the number of receiving stations, depending on the combination of the number of used frequencies and the number of receiving stations, reception at a plurality of frequencies is possible at the receiving station as in the description of the second embodiment. There are cases where error packet response information for data is aggregated and simultaneously transmitted to shorten the data compared to the first embodiment.

Although not shown in the figure, for example, the number of used frequencies is 6 (frequency is F1, F2, F3, F4, F5, F6), and the number of receiving stations is 3 (first receiving station, second receiving station, third Receiver station)
The frequency F1 is used to transmit an error packet response for the received packets at the frequencies F1, F2, and F3 at the first receiving station.
The frequency F2 is used to transmit an error packet response for the received packet at the frequency F4, F5, F6 at the first receiving station,
The frequency F3 is used to transmit an error packet response for the received packet at the frequencies F1, F2, and F3 at the second receiving station.
The frequency F4 is used to transmit an error packet response for the received packet at the frequencies F4, F5, and F6 at the second receiving station,
The frequency F5 is used to transmit an error packet response for the received packet at the frequencies F1, F2, and F3 at the third receiving station.
By transmitting the error packet response for the received packet at the frequency F4, F5, F6 at the third receiving station by the frequency F6,
A transmission time T_ARQ3 required for ARQ per one data block transmission is expressed by (Equation 4).

T_ARQ3 = T1 + T2 ′
= T1 + (T2t '+ T2m) (Formula 4)
Here, T2 ′ is a communication time required for the error packet response, and is used to absorb the difference between the transmission time T2t ′ from the receiving station and the delay time in the propagation path due to the difference in the location of each receiving station. A margin (T2m) is included.

  The above (Equation 4) is the same as (Equation 2) in the second embodiment, and the frame format of the error packet response channel is the error information of received packets at three frequencies as in the second embodiment. In other words, since T2 ′ is the same value as in the second embodiment and T2m is also the same, as in the second embodiment, the transmission time required for ARQ per one data block transmission is the first. The embodiment can be shortened.

As described above, according to the number of used frequencies and the number of receiving stations, by appropriately selecting the transmission method of the error packet response channel shown in the first embodiment, the second embodiment, and the third embodiment, ARQ can be achieved. The required transmission time can be shortened. Also, under the control of the control unit 11, two or three of the first embodiment, the second embodiment, and the third embodiment may be appropriately combined so that the response packet processing time is minimized. Is possible.
A plurality of the various embodiments described above can be implemented at the same time. With these descriptions, those skilled in the art can realize the present invention, but various modifications of these embodiments can be conceived. It is easy for a person skilled in the art and can be applied to various embodiments without inventive ability. Therefore, the present invention covers a wide range consistent with the disclosed principle and novel features, and is not limited to the above-described embodiments.

  DESCRIPTION OF SYMBOLS 1 ... Wireless communication device, 1-1 ... Transmitter, 1-2 ... Receiver, 11 ... Control part, 12 ... Display part, 13 ... Operation part, 14 ... Packet processing part, 15 ... Dividing / assembling part, 16 ... Frame processing unit, 17 ... error detection unit, 18 ... automatic retransmission control unit, 19, 20, 21 ... data transmission / reception unit, 22 ... error correction unit, 23 ... modulation / demodulation unit, 24 ... radio unit.

Claims (1)

A wireless communication system comprising a plurality of receiving stations and transmitting stations that respectively transmit the same transmission data to the plurality of receiving stations,
The transmitting station divides the transmission data into a plurality of transmission data divided into packet units and attached with an error detection code, and a plurality of packets constitute a data block , and each of the divided transmission data is different. Transmitting in parallel to each of the plurality of receiving stations using a frequency, the frequency instructed from the spectrum management server as the plurality of different frequencies, the transmission data to be received prior to transmission of the transmission data A line setting signal including an enumeration of addresses of a plurality of receiving stations is transmitted at each of the plurality of different frequencies, and an error response is sent to the receiving station each time transmission of one packet of the data block is completed at each frequency. Means for further transmitting an error packet request to request,
Each receiving station comprises means for receiving the plurality of different frequencies in parallel and assembling the divided transmission data and returning an error response to the transmission data received at the plurality of different frequencies,
The wireless communication system includes:
As the error response method, when the plurality of receiving stations receive an error packet request transmitted from the transmitting station at each frequency, errors of all packets included in one data block of the received transmission data are received. Means for performing a first method of returning the error response including presence / absence information in a time division manner in an order corresponding to the enumeration of addresses at the same frequency as the frequency at which the transmission data is received;
The transmitting station associates the plurality of receiving stations requesting an error response with the plurality of different frequencies, and transmits the error packet request to each receiving station at the associated frequency. Means for implementing the second method of returning the error response in which error presence / absence information of all packets included in the plurality of data blocks respectively received at the plurality of frequencies is received at the frequency at which the error packet request is received;
An error method selection means for selecting or combining the first method and the second method according to the number of used frequencies and the number of receiving stations instructed from the spectrum management server;
With
The method selection means includes:
If the number of instructed used frequencies is equal to or greater than the number of receiving stations, the instructed plurality of used frequencies are individually allocated to the plurality of receiving stations, and an error response according to the second method is performed.
If the number of instructed utilization frequencies is less than the number of receiving stations, the instructed plurality of utilization frequencies are individually assigned to some of the plurality of receiving stations, and the second An error response according to the first method is performed, and the other plurality of receiving stations among the plurality of receiving stations are commonly assigned the instructed plurality of use frequencies to perform the error response according to the first method. A wireless communication system.

Images