JP5556915B2 - Communications system - Google Patents

Description

  The present invention relates to communication between a base station and a communication terminal via a satellite.

  Conventionally, as a satellite communication access method suitable for two-way communication, a plurality of terminal devices use CDMA (Code Division Multiple Access) to a base station via a non-geostationary satellite such as a quasi-zenith satellite. There is something to access (see, for example, Patent Document 1).

  In recent years, basic studies on bidirectional communication systems using quasi-zenith satellites have been made, and extremely short messages (short messages) such as safety information can be sent using quasi-zenith satellites or GPS (Global Positioning System) satellites. The technical idea of transmitting via a satellite (quasi-zenith satellite) is public (for example, see Non-Patent Document 1).

  In the conventional satellite communication access method disclosed in Patent Document 1, a base station notifies predetermined delay time information to each terminal device, and then each terminal device transmits each transmission data to the same spreading code. In addition, transmission data after spreading whose delay time is individually adjusted based on the delay time information is arranged and transmitted in a prescribed slot.

  An example of a spreading code sequence for performing code division multiple access (CDMA) is an orthogonal gold code sequence (for example, Non-Patent Document 2). Non-Patent Document 2 describes that the generated orthogonal Gold code sequences are orthogonal to each other with a shift of 0.

JP 2004-289717 A Taku Kameda, Kenji Suematsu, Fumihiro Yamagata, Hiroshi Oguma, Nao Takagi, Kazuo Tsubouchi "Fundamental study on wireless access method for location and short message bidirectional communication system using quasi-zenith satellite" IEICE Technical Report May 2012 35-40 Hiromasa Hana, “Series Constructed Based on M Series and Its Application to Communication” The Institute of Electronics, Information and Communication Engineers Fundamental / Boundary Society, Fundamentals Review, Vol. 3 No. 1, July 2009, P3B-42

  However, in the conventional satellite communication access method as disclosed in Patent Document 1, since the resources to be selected for performing random access are limited to the delay time of the same spreading code, the number of selectable resources is When there are few and the number of communication terminals accessed simultaneously at the time of a disaster etc. increases, the subject that the throughput fell by the collision of the data which each communication terminal transmits occurred.

  Further, when the DAMA (Demand Assignment Multiple Access) system is used as the satellite communication access method, there is no data collision in the communication line and the communication line throughput increases, but the communication line is connected to the base station. The number of CSC lines (Common Signaling Channels) to be allocated to each communication terminal is limited, and therefore, it can be accessed simultaneously from many communication terminals, such as rescue message communication in the event of a large-scale disaster. When a request occurs, there is a problem that communication becomes impossible due to a line congestion.

  In other words, in the conventional satellite communication access method, for example, when a large-scale disaster occurs, when a rescue message is transmitted almost simultaneously from a large number of victims, communication is avoided and communication is avoided. It is easily conceived that it is difficult to obtain a satellite communication access method that can increase the throughput of the network.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a communication system that can easily increase the throughput of communication between a base station and a communication terminal via a satellite.

The communication system according to claim 1 is a communication system in which a base station and a plurality of communication terminals communicate via a satellite, and the base station transmits a forward link signal to the plurality of communication terminals. Each of the plurality of terminals receives the forward link signal, and CDMA receives the generated transmission data triggered by reception of the forward link signal by the receiving unit. Obtained from the satellite or GPS satellite, a transmission unit that spreads, delays according to the time slot for transmitting the CDMA spread transmission data, converts the frequency of the delayed transmission data and transmits it to the base station, and the satellite or GPS satellite An orthogonal code start type generated from an information acquisition unit for acquiring GPS information and time information obtained from the GPS information and synchronized between the plurality of communication terminals. The transmission unit randomly selects and supplies an orthogonal code generation unit that generates an orthogonal code used for CDMA spreading and a spreading code channel used by the orthogonal code generation unit, and the transmission unit transmits transmission data. A random selection unit that randomly selects and supplies a time slot channel that is a basis of a delay time, and a transmission unit that randomly selects and supplies a frequency channel for frequency conversion, and the reception unit includes: Obtaining information of a predetermined region from the received forward link signal, the random selection unit, if there is a communication terminal having the random selection unit in the predetermined region, for the case of not, Increasing the probability that the transmission unit can select a time slot as a basis for delaying transmission data from an early time slot channel, and performing the random selection. When there is a communication terminal having the random selection unit outside the predetermined area, the unit sets an earlier time slot that is a basis of a time for the transmission unit to delay transmission data with respect to a communication terminal that does not The probability of selecting from the slot channel is lowered .

A communication system according to a second aspect of the present invention is a communication system in which a base station and a plurality of communication terminals communicate via a satellite, and the base station transmits a forward link signal to the plurality of communication terminals. Each of the plurality of terminals receives the forward link signal, and CDMA receives the generated transmission data triggered by reception of the forward link signal by the receiving unit. Obtained from the satellite or GPS satellite, a transmission unit that spreads, delays according to the time slot for transmitting the CDMA spread transmission data, converts the frequency of the delayed transmission data and transmits it to the base station, and the satellite or GPS satellite An orthogonal code start type generated from an information acquisition unit for acquiring GPS information and time information obtained from the GPS information and synchronized between the plurality of communication terminals. The transmission unit randomly selects and supplies an orthogonal code generation unit that generates an orthogonal code used for CDMA spreading and a spreading code channel used by the orthogonal code generation unit, and the transmission unit transmits transmission data. A random selection unit that randomly selects and supplies a time slot channel that is a basis of a delay time, and a transmission unit that randomly selects and supplies a frequency channel for frequency conversion, and the reception unit includes: Obtaining information of a predetermined region from the received forward link signal, the random selection unit, if there is a communication terminal having the random selection unit in the predetermined region, for the case of not, Of the time slot channels within the range in which the time slot on which the transmission unit delays transmission data can be selected, the one on the earlier time side When the communication terminal having the random selection unit is outside the predetermined area, the random selection unit delays transmission data with respect to the case where the communication terminal does not Is selected at random from the time slot channels within the selectable time slot channel .

A communication system according to a third aspect of the present invention is the communication system according to the first or second aspect , wherein the random selection unit determines the position of the communication terminal from position information obtained from the GPS information.

In the communication system according to a fourth aspect of the present invention, the reception unit sets, as the predetermined area, an area set based on a predetermined condition from one point of position information indicated by position information obtained from the forward link signal. It is a thing in any one of Claim 1, 2 , 3 .

In the communication system according to the fifth aspect of the present invention, the receiving unit sets an area set based on a predetermined condition from position information of two or more points indicated by position information obtained from the forward link signal. It is a thing in any one of Claim 1,2,3 .

As described above, according to the first to fifth aspects of the present invention, it is possible to suppress the collision of data simultaneously transmitted by a large number of communication terminals, increase the communication success probability, that is, the throughput, and the communication line is in a congested state. It is possible to obtain a communication system having an effect of preventing falling.

1 is a schematic diagram of a communication system (communication terminal, base station, satellite) according to Embodiment 1 of the present invention. 1 is a schematic diagram of a communication system (communication terminal, base station, satellite) according to Embodiment 1 of the present invention. It is a functional block diagram of the communication terminal which concerns on Embodiment 1 of this invention. It is a transmission timing chart of the communication terminal which concerns on Embodiment 1 of this invention. It is a flowchart which shows operation | movement of the communication terminal which concerns on Embodiment 1 of this invention. It is a flowchart which shows operation | movement of the communication terminal which concerns on Embodiment 1 of this invention. It is a functional block diagram of the communication terminal which concerns on Embodiment 1 of this invention. It is the table which the table memory | storage part of the communication terminal which concerns on Embodiment 1 and 5 of this invention memorize | stores. It is a table which the table memory | storage part of the communication terminal which concerns on Embodiment 1, 2, and 5 of this invention memorize | stores. It is a functional block diagram of the communication terminal which concerns on Embodiment 2 of this invention. It is a flowchart which shows operation | movement of the communication terminal which concerns on Embodiment 2 of this invention. It is a functional block diagram of the communication terminal which concerns on Embodiment 3 of this invention. It is a functional block diagram (schematic diagram of a communication system) of a base station according to Embodiment 3 of the present invention. It is a functional block diagram (schematic diagram of a communication system) of a base station according to Embodiment 3 of the present invention. It is a figure which shows the predetermined area | region obtained from the information of the position which the base station which concerns on Embodiment 3 of this invention transmitted. It is a figure which shows the predetermined area | region obtained from the information of the position which the base station which concerns on Embodiment 3 of this invention transmitted. It is a figure which shows the predetermined area | region obtained from the information of the position which the base station which concerns on Embodiment 3 of this invention transmitted. It is a figure which shows the predetermined area | region obtained from the information of the position which the base station which concerns on Embodiment 3 of this invention transmitted. It is a functional block diagram of the communication terminal which concerns on Embodiment 4 of this invention. It is a functional block diagram of the communication terminal which concerns on Embodiment 4 of this invention. It is a table which the table memory | storage part of the communication terminal which concerns on Embodiment 4 of this invention memorize | stores. It is a table which the table memory | storage part of the communication terminal which concerns on Embodiment 4 of this invention memorize | stores. It is a functional block diagram of the communication terminal which concerns on Embodiment 5 of this invention. It is a functional block diagram of the communication terminal which concerns on Embodiment 5 of this invention. It is a graph which shows the probability distribution which the probability setting part of the communication terminal which concerns on Embodiment 5 of this invention sets. It is a flowchart which shows operation | movement of the communication terminal which concerns on Embodiment 6 of this invention. It is a flowchart which shows operation | movement of the communication terminal which concerns on Embodiment 6 of this invention.

Embodiment 1 FIG.
In the normal slotted ALOHA random access method, the data transmission request in the communication terminal is randomly generated in time. For example, data is transmitted in the slot next to the slot in which the data transmission request is generated. However, the service assumed to be applied to the communication method, the communication terminal, the base station, and the communication system (satellite communication access method) according to the present application is that, as described above, the rescue service starts from the base station 2 when a major disaster occurs. The service is such that a rescue message transmission request is generated all at once from the time when the signal is received by the communication terminal 3. In this application, a random access by CDMA / FDMA / TDMA is proposed.

  Embodiment 1 of the present invention will be described below with reference to FIGS. 1 to 9, 1 is a satellite (non-stationary satellite (quasi-zenith satellite)), 2 is a base station provided on the ground, 3 is a communication terminal (short message communication terminal). A communication system in which the base station 2 and a plurality of communication terminals 3 communicate with each other via CDMA (Code Division Multiple Access) transmission data transmitted to the base station 2 via the satellite 1 Communication terminal 3 transmitting as a signal (return link signal) 3 Base station 2 communicating with a plurality of communication terminals 3 via satellite 1 Transmitting CDMA spread transmission data to base station 2 via satellite 1 This relates to a communication method used for the communication terminal 3 to be used. The base station 2 includes a satellite communication antenna 2s (base station side satellite communication antenna 2s). The satellite communication antenna 2s is illustrated in FIGS. 13 and 14 to be described later. Each of the plurality of communication terminals 3 (the plurality of communication terminals 3 may be referred to as “communication terminal 3A, communication terminal 3B, communication terminal 3C, communication terminal 3D. (Communication terminal side satellite communication antenna 3s) and GPS antenna 3g. 4 is a GPS (Global Positioning System) satellite (satellite 1 may have the function of GPS satellite 4), 5 is a base station 2 that is configured to transmit a forward link signal to a plurality of communication terminals 3. It is a station transmitter. The base station transmitter 5 is illustrated in FIGS. 13 and 14 to be described later. The forward link signal may include a service start signal (rescue service start signal) described later, and the communication terminal 3 transmits transmission data to the base station 2 using this as a trigger. In the drawings, the same reference numerals denote the same or corresponding parts, and detailed descriptions thereof are omitted.

  In FIG. 1 to FIG. 9, 6 is a receiving unit that receives a forward link signal, 7 is a CDMA spread of the generated transmission data triggered by the reception unit 6 receiving a forward link signal, and this CDMA spread transmission A transmission unit that delays data according to the time slot for transmitting data, converts the frequency of the delayed transmission data and transmits the data to the base station 2, and 8 acquires information for acquiring GPS information obtained from the satellite 1 or the GPS satellite 4 Part. The information acquisition unit 8 may acquire information by a method other than information obtained from the GPS satellite 4. For example, information may be acquired from an external device connected to the communication terminal 3, or information may be acquired by receiving an input from an input button (described later “input means”) of the communication terminal 3. 9 is generated from time information (GPS time information) obtained from GPS information and is used by the transmitter 7 for CDMA spreading by the orthogonal code start timing (spreading code start timing) synchronized between the plurality of communication terminals 3. An orthogonal code generator (spread code generator) that generates a code (spread code). In the present application, the spread code channel is described assuming that an orthogonal code channel is used, but the application range of the present application is not limited to the orthogonal code channel. If it is a spread code, this application can be implemented. In the drawings, the same reference numerals denote the same or corresponding parts, and detailed descriptions thereof are omitted.

  1 to 9, reference numeral 10 denotes a random code channel (spread code channel) used by the orthogonal code generator 9 (spread code generator 9), which is randomly selected and supplied, and the transmitter 7 delays transmission data. It is a random selection unit that randomly selects and supplies a time slot channel that is the basis of time, and randomly selects and supplies a frequency channel that the transmission unit 7 performs frequency conversion. That is, the random selection unit 10 randomly selects one orthogonal code from a plurality of set orthogonal code channels (spreading code channels), randomly selects one time slot from a plurality of set time slot channels, and is set a plurality. One frequency is selected from the selected frequency channels. Each of the plurality of communication terminals 3 includes a reception unit 6, a transmission unit 7, an information acquisition unit 8, an orthogonal code generation unit 9 (spreading code generation unit 9), and a random selection unit 10. In the drawings, the same reference numerals denote the same or corresponding parts, and detailed descriptions thereof are omitted.

  1 to 9, reference numeral 11 denotes a CDMA spreading unit for CDMA spreading transmission data. That is, the orthogonal code generation unit 9 (spreading code generation unit 9) generates an orthogonal code (spreading code) used by the CDMA spreading unit 11 for CDMA spreading. Reference numeral 12 denotes a TDMA (Time Division Multiple Access) processing unit that delays transmission data that is CDMA spread by the CDMA spreading unit 11 according to a time slot for transmission, and 13 denotes transmission data delayed by the TDMA processing unit 12. FDMA (Frequency Division Multiple Access) processing unit for frequency-converting. That is, the random selection unit 10 randomly selects and supplies an orthogonal code channel (spreading code channel) used by the orthogonal code generation unit 9 (spreading code generation unit 9), and the TDMA processing unit 12 delays transmission data. The time slot channel on which the time is based is selected and supplied at random, and the frequency channel for frequency conversion by the FDMA processing unit 13 is selected at random and supplied. In the drawings, the same reference numerals denote the same or corresponding parts, and detailed descriptions thereof are omitted.

  In FIG. 1 to FIG. 9, 14 is a ground network, 15 is a satellite tracking control center that tracks the satellite 1 and sends satellite tracking information to the base station 2 via the ground network 14, and 16 is various types via the ground network 14. A service center for sending information to the base station 2, 17 a forward link communication line for the base station 2 to send a forward link signal from the satellite communication antenna 2s to the communication terminal 3 via the satellite 1, and 18 a plurality of communication terminals 3 for the satellite A return link communication line for sending a return link signal from the communication antenna 3s to the base station 2 via the satellite 1, 19 is GPS information (position) that the communication terminal 3 receives from the GPS satellite 4 or the satellite 1 via the GPS antenna 3g GPS signal carrying information and time information), 20 is a forward signal received by the satellite communication antenna 3s to the receiving unit 6 , A duplexer for sending transmission data (return link signal) sent from the transmission unit 7 to the antenna for satellite communication 3s (a circulator or a filter is assumed), 21 for reception received by the reception unit 6 separated from the forward link signal A data output terminal (received data) from which data is output, 22 is a transmission data unit for generating a transmission data signal to be sent to the transmission unit 7, and 23 is input of transmission data as a source of the transmission data signal generated by the transmission data unit 22 Data input terminal (transmission data). In the drawings, the same reference numerals denote the same or corresponding parts, and detailed descriptions thereof are omitted.

  Next, an explanation will be given of the configuration that has not been described and explained. In the present application, the case where the plurality of communication terminals 3 are the communication terminal 3A, the communication terminal 3B, and the communication terminal 3C, or the case where one representative communication terminal 3 is used will be described as an example. Absent. In the communication system according to Embodiment 1 shown in FIG. 1, the transmission signals (return link signals) transmitted by the communication terminals 3A, 3B, and 3C are transmitted to the non-stationary satellites by independent return link communication lines 9, respectively. 1 is integrated by the non-geostationary satellite 1 via 1 and transmits data to the base station 2.

  The base station 2 shown in FIGS. 1 and 2 distributes transmission data (forward link signal) to the communication terminal 3A, the communication terminal 3B, and the communication terminal 3C via the non-stationary satellite 1 via the forward link communication line 17. Further, the communication terminal 3A, the communication terminal 3B, and the communication terminal 3C receive the GPS signal 19 from the GPS satellite 4, and GPS information such as position information (GPS position information) and time information (GPS time information) of the own terminal To get.

  The satellite tracking control center 15 shown in FIGS. 1 and 2 is connected to the base station 2 via the terrestrial network 14, and the base station 2 monitors and controls the base station 2 for tracking the non-stationary satellite 1. Is what you do. The service center 16 is connected to the base station 2 via the terrestrial network 14, acquires data from the communication terminal 3A, the communication terminal 3B, and the communication terminal 3C received by the base station 2, as well as the communication terminal 3A and the communication terminal. Data to 3B and communication terminal 3C is transmitted to base station 2.

  The detailed configuration of the communication terminal 3 will be described with reference to FIG. First, the receiving side of the communication terminal 3 will be described. The signal of the forward link communication line 17 from the base station 2 is received by the satellite communication antenna 3s, separated from the transmission signal by the duplexer 20, and then subjected to low noise amplification by the radio receiving unit 24, and then the QPSK demodulating unit. At 25, the QPSK modulated wave is demodulated. The received data after QPSK demodulation is subjected to error correction decoding by the error correction decoding unit 26 and becomes original information data. The reception unit 6 includes a radio reception unit 24, a QPSK demodulation unit 25, an error correction decoding unit 26, and a TDM separation unit 27 described later.

  Here, information data (transmission data) of the forward link communication line 17 is transmitted by TDM (Time Division Multiplex), and communication data or control data addressed to each communication terminal 3 is time-division multiplexed. The TDM separation unit 27 separates the reception data addressed to its own device and outputs it to the reception data output terminal 21. On the other hand, the GPS signal 19 from the GPS satellite 4 is received by the GPS receiver 28 via the GPS antenna 3g, and is subjected to signal processing by the GPS signal processing unit 29 to obtain a GPS time signal and GPS position information.

Next, the transmission side of the communication terminal 3 will be described. Transmission data receiving unit 4 (The forward link signals, including receiving data from the forward link signal output to the reception data output terminal 21) the forward link signal transmit data section 22 sent to trigger the reception of the generated Send. The transmission data unit 22 includes a data generation unit 30 and an error correction coding unit 31. The transmission data input to the data input terminal 23 is converted into a predetermined burst format by adding a synchronization bit, a control bit, etc. to the transmission data in the data generation unit 30, and then an error correction code in the error correction encoding unit 31. It becomes. The transmission data that has been subjected to error correction coding in the error correction coding unit 31 is transmitted from the orthogonal code generated in the orthogonal code generation unit 9 in the CDMA spreading unit 11 corresponding to the spreading code channel input from the random selection unit 10. The sequence and modulo 2 are added and spread for CDMA.

  In order to obtain timing such as orthogonal code start timing synchronized among a plurality of communication terminals 3, the communication terminal 3 has a transmission timing generation unit 32. The transmission timing generation unit 32 generates a clock signal and a timing signal to each unit synchronized with the GPS time signal from the GPS signal processing unit 29. The data generation unit 30 and the error correction encoding unit 31 (transmission data unit 22) synchronize with the transmission data so as to synchronize between the plurality of communication terminals 3 from the clock signal and timing signal obtained from the transmission timing generation unit 32. Bits, control bits, etc. are added and converted into a predetermined burst format, and error correction coding is performed. Specifically, the transmission timing generation unit 32 sends a data clock to the data generation unit 30 and an error correction coding clock to the error correction coding unit 31.

  The transmission timing generator 32 obtains the orthogonal code start timing for synchronization between the plurality of communication terminals 3, so that the transmission timing generator 32 includes a chip clock for generating orthogonal codes, an orthogonal code A transmission timing signal such as a code start timing is generated (the error correction coding clock and the data clock may be included in the transmission timing signal). The orthogonal code generation unit 9 randomly selects one orthogonal code from among a plurality of orthogonal codes, and generates the selected orthogonal code based on the chip clock synchronized with the GPS time signal and the orthogonal code start timing. As a result, the chip clock and the orthogonal code start timing of the orthogonal code of the CDMA signal transmitted from the plurality of communication terminals 3 to the satellite 1 can be synchronized between the plurality of communication terminals 3, If the distance to 1 is almost the same, the orthogonal code chip clock and the orthogonal code start timing of the CDMA signal transmitted by each terminal on the transponder of satellite 1 are synchronized.

  In other words, the communication terminal 3 includes the information acquisition unit 8 that acquires GPS information obtained from the satellite 1 or the GPS satellite 4, and the orthogonal code start timing generated by the transmission timing generation unit 32 from the time information obtained from the GPS information. Thus, it can be said that the orthogonal code generator 9 generates an orthogonal code. The random selection unit 10 of the communication terminal 3 not only randomly selects and supplies the orthogonal code channel (spreading code channel) used by the orthogonal code generation unit 9, but also the TDMA processing unit 12 (transmission unit 7). A time slot channel that is a base of time for delaying transmission data is randomly selected and supplied, and a frequency channel for frequency conversion by the FDMA processing unit 13 (transmitting unit 7) is randomly selected and supplied.

  Therefore, the communication terminal 3 corresponds to the time slot channel input from the random selection unit 10 in the TDMA processing unit 12 in which the CDMA spread transmission data output from the CDMA spreading unit 11 corresponds to the time slot. After being delayed so as to be transmitted, the BPSK modulation unit 33 performs BPSK modulation, and the FDMA processing unit 13 performs frequency conversion to a frequency corresponding to the frequency channel input from the random selection unit 10 and then wireless transmission. In the unit 27, the power is amplified and transmitted to the non-stationary satellite 1 as a transmission burst signal (return link signal) of the return link communication line 9 from the satellite communication antenna 3 s via the duplexer 20.

  The communication system (communication terminal) according to Embodiment 1 includes a combination of orthogonal code channel (spreading code channel), time slot channel, and frequency channel set randomly by random selection unit 10 (random access by CDMA / FDMA / TDMA). The “combination of access methods”) is used for each communication terminal 3. FIG. 4 shows an example of combinations of access methods of communication terminal 3A, communication terminal 3B, and communication terminal 3C that transmit data in the communication system (communication terminal) according to the first embodiment.

  In FIG. 4, the communication terminal 3A selects the combination of spreading code A, frequency CH1, and time slot 1, the communication terminal 3B selects the combination of spreading code B, frequency CH3, and time slot 2, and the communication terminal 3C A case where a combination of C, frequency CH2, and time slot 2 is selected is shown. As shown in FIG. 4, the timing of the time slot and the phase of the chip clock of the spreading code are synchronized with the GPS time signal, and the communication terminal 3A, the communication terminal 3B, and the communication terminal 3C transmit data. As shown in FIG. 4, the communication terminal 3A, the communication terminal 3B, and the communication terminal 3C do not have a combination of access methods, so there is no collision of transmission data on the satellite.

  Therefore, the communication system (communication terminal) according to the first embodiment determines the channel for accessing the satellite by the combination of the access methods that are randomly determined by the random selection unit 10, so that the satellites can be simultaneously transmitted from a large number of communication terminals 3. Even if the access to 1 is performed, the possibility that throughput is reduced due to collision of data transmitted by each communication terminal can be reduced, and the possibility that communication with the base station 2 can be performed due to a line congestion state can be extremely reduced. There is an effect that can be done. The degree of this effect varies depending on the number of orthogonal code channels (spreading code channels), time slot channels, and frequency channels that can be selected by the random selector 10 and the number of communication terminals 3 that are accessed simultaneously. The number of orthogonal code channels (spreading code channels), time slot channels, and frequency channels may be set in accordance with the “probability of mismatching access schemes”.

  Since the communication system (communication terminal) according to the first embodiment has such characteristics, the communication terminal 3 uses personal quasi-zenith satellites and GPS satellites to identify personal identification information (ID information) and position information. It is suitable for the use of transmitting extremely short messages such as safety information including short messages (short messages, short messages, location short messages, hereinafter referred to as short messages) via the satellite 1 (quasi-zenith satellite 1). . As an example of a service using a short message using the communication terminal 3, the base station 2 sends a forward link signal to the user terminal of the victim in order for the service center 16 to obtain information from the communication terminal 3 in a disaster or the like. An instruction (request) is issued from the service center 16 to the base station 2 so as to transmit to the (mobile terminal 3).

  When the base station 2 receives the forward link signal transmitted using the forward link communication line 17 as a trigger, the user terminal (mobile terminal 3) of the disaster victim uses the return link communication line 18 to return the return link signal (transmission). By sending a rescue message, an emergency message, a rescue signal, etc. including the location information included in the signal) to the base station 2, the rescue message including the location information, emergency, is sent to the service center 16 via the satellite line. Disaster victim information such as messages and rescue signals can be transmitted. In addition, the information on the victims is transmitted to the service center 16, and the service center 16 transmits a reply message including an ACK signal to the user terminal (communication terminal 3) through the same satellite line in response to the received short message. A service that can be considered. The service center 16 and the base station 2 are connected via a terrestrial network.

  A communication method according to the first embodiment will be described with reference to FIGS. 5 and 6. FIG. 5 is a flowchart showing a transmission operation of the communication terminal according to the first embodiment. In other words, it can be said that this is a communication method used for the communication terminal 3 that transmits the transmission data spread by CDMA to the base station 2 via the satellite 1. S in FIG. 5 and FIG. 6 means a processing step, and represents the initial letter of STEP. Since S104 to S108 and S113 are processing steps in the following embodiments, they will not be described here.

  In FIG. 5, when the communication terminal 3 is turned on, the GPS signal 19 is received via the GPS antenna 3g in S101. Next, in S102, the reception system of the communication terminal 3 is started up and the base station 2 The forward link signal is received via the antenna 3s for satellite communication. Usually, the power supply of the communication terminal 3 is always turned on. However, if the communication terminal 3 is the short message communication terminal 3 that transmits the above-mentioned short message to the base station 2, that is, if the communication system is used for transmission / reception of a short message such as safety information, the communication terminal 3 is shorted as necessary. The operation may be such that the message communication terminal 3 is powered on. Hereinafter, the case of the short message communication terminal 3 is used for explanation.

  In S103, it is determined whether or not the short message communication terminal 3 transmits data. The determination of whether to transmit data is performed as follows, for example. When a disaster occurs, the service center 16 starts the rescue message service and notifies the control data (this is referred to as “rescue service start signal”. When the application is not the rescue message service) Or simply referred to as a “service start signal”) is transmitted to the base station 2 via the terrestrial network 14. The base station 2 broadcasts the rescue service start signal as control data on the forward link signal toward all the short message communication terminals 3.

  In S102 described above, the short message communication terminal 3 receiving the forward link signal obtains from the TDM demultiplexing unit 27 in S103 whether or not the rescue message service start signal (service start signal) is included in the forward link signal. It is determined from the received data, and if included, it is determined whether or not a rescue message transmission button (input button) provided in the short message communication terminal 3 is pressed. If it has been pressed, the process proceeds to S109, and if it has not been pressed, the process returns to S101. The rescue message transmission button provided in the short message communication terminal 3 is not a physical button, but a touch panel type display unit of the short message communication terminal 3 or a touch panel type display unit connected to the short message communication terminal 3. The voice message indicating that a rescue message is to be transmitted is input to the voice input unit of the short message communication terminal 3 or the voice input unit connected to the short message communication terminal 3. It is good also as a substitute of. These are collectively referred to as “input means”.

If the short message communication terminal 3 receives the rescue message service start signal and the rescue message transmission button is pressed, it is determined in S103 that data is to be transmitted. Note that whether the rescue message service start signal is included in the received data output from the data output terminal 21 of the short message communication terminal 3 and separated by the TDM separation unit 27 is determined by the control of the short message communication terminal 3. (A control unit of the communication terminal 3). Illustration of the control unit is omitted. When detecting the rescue message service start signal, the control unit of the short message communication terminal 3 sends a short message such as safety information including personal identification information (ID information) and position information to the data input terminal 23. The short message input to the data input terminal 23 is subjected to the processing described above in the transmission data unit 22.

  In the processing as the communication system in S103, it is considered that the short message communication terminals 3 damaged by the occurrence of a large earthquake press the rescue message transmission button almost simultaneously, and requests for data transmission occur almost simultaneously at a large number of terminals. Therefore, in S103, if the data is automatically transmitted only by receiving the rescue message service start signal without determining whether or not the rescue message button transmission button is pressed, the control unit of the short message communication terminal 3 You may judge. Further, the specification may be such that the data is automatically transmitted by detecting the rescue message service start signal without preparing the rescue message button transmission button itself. That is, S103 may be omitted.

  Next, in S109, the random selection unit 10 randomly selects one of the plurality of spreading code channels. This can be said to be a spreading code channel selection step for randomly selecting a spreading code channel for CDMA spreading transmission data. In S110, the random selection unit 10 randomly selects one of the time slot channels. This can be said to be a time slot channel selection step of randomly selecting a time slot channel for transmitting CDMA spread transmission data. In S111, the random selection unit 10 randomly selects one of the frequency channels. This can be said to be a frequency channel selection step of randomly selecting a frequency channel for transmitting CDMA spread transmission data.

  In S112, the random selection unit 10 determines the selected one spread code channel, one time slot channel, and one frequency channel as one of the combinations of access methods.

  In S114, data is transmitted to the satellite 1 via the satellite communication antenna 3s as a CDMA / FDMA / TDMA signal by a combination of access methods selected and determined by the random selection unit 10. This is CDMA spread by the spreading code channel selected in the spreading code channel selection step at the frequency corresponding to the time slot channel selected in the time slot channel selection step and the frequency channel selected in the frequency channel selection step. This can be said to be a transmission step of transmitting the transmitted data. From the series of processes in the flowchart shown in FIG. 5, this transmission step uses transmission data as a trigger when the communication terminal 3 receives a forward link signal transmitted from the base station 2 to the communication terminal 3 via the satellite 1. It can be said that it is transmitted to the base station 2 as a return link signal.

The processing of S109 to S112 and S114 is performed by an operation in which the short message processed by the transmission data unit 22 is linked with the random selection unit 10 and the transmission unit 7. Details are as described above with reference to the random selection unit 10 and the transmission unit 7. In S114, the transmission timing generation unit 32 also performs a synchronization step for transmitting the transmission data subjected to CDMA spreading in synchronization between the plurality of communication terminals 3.

  When S109 to S112 and S114 are replaced with detailed processing steps, a CDMA spreading step (CDMA spreading unit 11) for spreading transmission data using the spreading code channel randomly selected in the spreading code channel selection step, a time slot channel A delay step (TDMA processing unit 12) that delays transmission of the CDMA spread transmission data by the CDMA spread step in the time slot channel randomly selected by the selection step, and the frequency randomly selected by the frequency channel selection step There are three processing steps: a frequency conversion step (FDMA processing unit 13) that converts the frequency of transmission data delayed in the delay step to a frequency corresponding to a channel. Finally, a transmission step (radio processing unit 34) that transmits transmission data that is delayed in the delay step and frequency-converted in the frequency conversion step, corresponding to S114, is performed.

  FIG. 6 is a flowchart showing preprocessing of transmission operation of the communication terminal according to Embodiment 1. In other words, “S” in FIG. 6 means a processing step and represents an initial of STEP. The flowchart shown in FIG. 6 is different from the flowchart shown in FIG. 5 in the relationship between the orthogonal code generation unit 9 (spreading code generation unit 9), the TDMA processing unit 12, the FDMA processing unit 13, and the random selection unit 10. It is specialized.

  S201 corresponds to S109 described in FIG. 5, and is a spreading code channel selection step for randomly selecting a spreading code channel for CDMA spreading transmission data. Step S202 corresponds to step S110 shown in FIG. 5, and is a time slot channel selection step for randomly selecting a time slot channel for transmitting CDMA spread transmission data. Step S203 corresponds to step S111 shown in FIG. 5, and is a frequency channel selection step for randomly selecting a frequency channel for transmitting CDMA spread transmission data. The order of the processing steps of the spreading code channel selection step (S201), the time slot channel selection step (S202), and the frequency channel selection step (S203) is not limited. This is because the process is performed within the random selection unit 10.

  S204 corresponds to S112 shown in FIG. 5, and is determined by the random selection unit 10 with one selected spread code channel, one time slot channel, and one frequency channel as one of the combinations of access methods. It is. In S205, one spread code channel is notified to the orthogonal code generation unit 9 (spread code generation unit 9), one time slot channel is notified to the TDMA processing unit 12, and one frequency channel is transmitted to the FDMA processing unit. 13 is notified.

  On the other hand, in the processing steps performed by the transmission unit 7 after S204, first, the spread code channel randomly selected in the spread code channel selection step for randomly selecting the spread code channel for CDMA spreading of transmission data is used. A CDMA spreading step for CDMA spreading the transmission data is performed. Next, the transmission data CDMA spread by the CDMA spreading step is transmitted in the time slot channel randomly selected in the time slot channel selection step for randomly selecting the time slot channel for transmitting the CDMA spread transmission data. A delay step for delaying is performed.

  Finally, the transmission channel delayed in the above-described delay step is frequency-converted to a frequency corresponding to the frequency channel randomly selected in the frequency channel selection step for randomly selecting a frequency channel for transmitting transmission data subjected to CDMA spreading. After performing the frequency conversion step, the transmission step is performed in which transmission data that is delayed in the delay step and frequency-converted in the frequency conversion step is transmitted.

  Here, S201, S202, and S203 will be described in more detail. In S201, one of the spread code channels is selected at random, which corresponds to, for example, selecting one of a plurality of orthogonal codes that can be generated by the orthogonal code generation unit 9 as an orthogonal code. For example, an orthogonal Gold code as shown in Non-Patent Document 2 can be considered, and 1024 is considered as an example of the number of mutually orthogonal codes that can be selected. The orthogonal code generated by the orthogonal code generator 9 is synchronized with the GPS time signal at the chip level, and is controlled so that the orthogonal codes transmitted from the respective communication terminals 3 are orthogonal to each other on the satellite transponder. The However, in the present application, the spreading code is not particularly limited to the orthogonal code, and needless to say, it may be a non-orthogonal code such as a Gold code or an M sequence. However, when the orthogonal code is used, the mutual interference between the codes is almost eliminated, but when the non-orthogonal code is used, the mutual interference between the codes is increased.

  In S202, one of a plurality of frequency channels is selected at random. For example, given that the information rate of communication data transmitted from the communication terminal on the return link line is 50 bps, error correction coding with a coding rate of 1/2 is performed, and spreading is performed 1024 times, the chip rate is 50 bps × 2 X1024 = 102.4 kcps. Therefore, the required bandwidth of the BPSK modulated wave after CDMA spreading is about 200 kHz. That is, since this is the bandwidth of one frequency channel, for example, if the total frequency band that can be used is about 5 MHz, the number of frequency channels that can be selected is 25. In S203, one is randomly selected from a plurality of time slots.

  A modification of the random selection unit 10 will be described with reference to FIGS. 7, 8, and 9. In the communication terminal 3 illustrated in FIG. 7, the random selection unit 10 includes a combination selection unit 35 and a combination setting unit (table storage unit) 36. In the communication terminal 3 shown in FIG. 3, the random selection unit 10 individually selects an orthogonal code channel (spreading code channel), a time slot channel, and a frequency channel from the set ones. In the communication terminal 3 described, the combination selection unit 35 randomly selects a combination of access methods based on the “table stored in the table storage unit 36 (combination setting unit 36)” shown in FIG. In the random selection unit 10, an operation is performed in which the combination setting unit 36 transmits table information (combination information) to the combination selection unit 35.

  Therefore, when based on the “table stored in the table storage unit 36 (combination setting unit 36)” shown in FIG. 8, the communication method according to the first embodiment uses the spreading code channel selection step, the frequency channel selection step, and the time slot channel. It can be said that the selection step is performed in advance and is randomly selected from a table including combinations of spreading code channels, frequency channels, and time slot channels.

  In the table shown in FIG. 8, three items of “spreading code channel (orthogonal code channel)”, “frequency channel”, and “time slot channel” that the random selection unit 10 needs to select at random are set in the row direction. ing. In the column direction, the channels that can be set are arranged by selecting combinations that do not overlap among the three items. Each combination is given a selection number. In FIG. 8, four of NNN, MMM, LLL, and KKK each indicate a positive integer. Also, these four positive integers may be different. Note that channel # 1, channel # 2,... Channel #KKK in the time slot channel are arranged in the order from the earliest time zone.

  The communication terminal 3 shown in FIG. 7 receives the forward link signal (rescue message service start signal), and the random selection unit 10 selects “spreading code channel (orthogonal code channel)”, “frequency channel”, and “time slot channel”. When it is necessary to select at random, the combination selection unit 35 selects one of the selection numbers set (stored) in the combination setting unit 36 (table storage unit 36) at random, thereby obtaining a result. Specifically, “spreading code channel (orthogonal code channel)”, “frequency channel”, and “time slot channel” can be selected at random.

  For example, when the communication terminal 3A shown in FIG. 1 selects the selection number 004, the communication terminal 3B selects the selection number 001, and the communication terminal CA selects the selection number 002, the “spread code channel (orthogonal code channel)” It is possible to select a combination of access methods in which all of the three items “frequency channel” and “time slot channel” do not match among the plurality of communication terminals 3. Needless to say, as the number of selection numbers NNN increases, the possibility of selecting a combination of access methods in which all three items do not match increases.

  That is, the communication terminal 3 described in FIG. 7 means that the three processing steps S109, S110, and S111 shown in FIG. 5 may be performed simultaneously. In other words, it also means that the three processing steps S201, S202, and S203 shown in FIG. 6 may be performed simultaneously. The tables set (stored) in the combination setting unit 36 (table storage unit 36) may have the same table among the plurality of communication terminals 3, or may be different tables for each communication terminal 3.

  For example, when it is desired to positively (as a whole communication system) to have a difference in communication time for each communication terminal 3, a time slot channel is randomly selected from picked up relatively early ones within a selectable range. A table may be prepared so that it is possible. This is the same even when the table is not used. That is, when the random selection unit 10 (shown in FIG. 3) selects a time slot channel, it may be selected at a relatively early rate. Conversely, a table may be prepared so that a time slot channel that is relatively slow in the selectable range is picked up randomly. This is the same even when the table is not used. That is, when the random selection unit 10 (shown in FIG. 3) selects the time slot channel, it may be selected randomly from the relatively slow ones.

  The table shown in FIG. 9 is an example in the case where it is desired to have a difference in communication time for each communication terminal 3. The table shown in FIG. 9A is the same as the table shown in FIG. Even if the combination selection unit 35 selects a selection number from this table, it does not cause a difference in the time of communication for each communication terminal 3 actively (as a whole communication system). However, for example, as shown in FIG. 9 (b), a communication terminal having this table is prepared by preparing a table so that only the channel # 1 and channel # 2 whose time slot channel is relatively fast can be selected. 3 can inevitably communicate relatively quickly. Similarly, for example, as shown in FIG. 9C, a communication terminal having this table is prepared by preparing a table so that the time slot channel can be selected only from channel # 3 and channel # 4, which are relatively slow. 3 can inevitably communicate relatively slowly. 9B and 9C, the number of time slots that can be selected is 4 (that is, when KKK = 4). In FIGS. 9B and 9C, two channel numbers for each time slot are selected. This is just an example.

  That is, in the communication terminal according to Embodiment 1, when the random selection unit 10 is the communication terminal 3 that is desired to communicate relatively quickly, the transmission unit 7 delays the transmission data with respect to the case where the random selection unit 10 does not. It can be said that the probability that the time slot on which the time is based can be selected from the early time slot channel is increased. Similarly, when the random selection unit 10 is the communication terminal 3 that is desired to communicate relatively slowly, the time slot that is the basis of the time for the transmission unit 7 to delay the transmission data is compared with the case where the random selection unit 10 is not. It can be said that the probability of selecting from the slot channel is increased. In other words, in the communication terminal according to Embodiment 1, when the random selection unit 10 is the communication terminal 3 that is desired to communicate relatively quickly, the transmission unit 7 delays the transmission data with respect to the case where the random selection unit 10 does not. It can be said that the time slot that is the basis of the time to be selected is randomly selected from the earlier time slots among the time slot channels within the selectable range. Similarly, when the random selection unit 10 is the communication terminal 3 that is desired to communicate relatively slowly, the time slot that is the basis of the time for the transmission unit 7 to delay the transmission data is selected for the case where the random selection unit 10 is not. It can be said that a time slot channel within a possible range is randomly selected from those on the slow time side.

  Here, the operation of the random selection unit 10 in the case of using three combination information (table information) of “spreading code channel (orthogonal code channel)”, “frequency channel”, and “time slot channel” will be described. If there is nothing to be communicated between the plurality of communication terminals 3 relatively quickly, the combination setting unit 36 sends the table information (combination information) shown in FIG. 8 (FIG. 9A) to the combination selection unit 35. Good. Further, when there is something that is desired to be communicated relatively quickly between the plurality of communication terminals 3, the combination setting unit 36 of the communication terminal 3 uses the information (combination information) in the table shown in FIG. To send to. Further, when there is something that is desired to communicate relatively slowly between the plurality of communication terminals 3, the combination setting unit 36 of the communication terminal 3 uses the information (combination information) in the table shown in FIG. To send to. When the information in the table shown in FIG. 9B is sent to the combination selection unit 35, communication terminals 3 other than the communication terminal 3 (including a plurality of communication terminals 3) are shown in FIG. 9C. The table information shown may be sent to the combination selection unit 35, or the table information shown in FIG. 8 (FIG. 9A), which is a normal case, may be sent to the combination selection unit 35. Of course, when the information in the table shown in FIG. 9C is sent to the combination selection unit 35, communication terminals 3 other than the communication terminal 3 (including a case where there are a plurality of communication terminals 3) are shown in FIG. 9B. The table information shown may be sent to the combination selection unit 35, or the table information shown in FIG. 8 (FIG. 9A), which is a normal case, may be sent to the combination selection unit 35.

Embodiment 2. FIG.
A second embodiment of the present invention will be described with reference to FIGS. 9, 10, and 11. FIG. In the first embodiment, a specific example of the case where it is desired to positively (as the entire communication system) to have a difference in communication time for each communication terminal 3 is not given, but in the second embodiment, a specific example thereof is not given. Give up. Therefore, in the second embodiment, description regarding the same parts as in the first embodiment may be omitted.

  In FIG. 10, reference numeral 37 denotes a position information acquisition unit that acquires position information (own terminal position data) of its own terminal from the information acquisition unit 8 and sends it to the random selection unit 10. The position information acquisition unit 37 is connected to the information acquisition unit 8 (GPS signal processing unit 29). Specifically, the position information acquisition unit 37 acquires position information (GPS position information) processed by the GPS signal processing unit. Reference numeral 38 denotes a determination processing unit that determines from the position information acquired by the position information acquisition unit 37 whether the position is within a predetermined area and notifies the combination setting unit 36 (table storage unit 36). . That is, it can be said that the random selection unit 10 determines the position of the communication terminal 3 from position information (position information obtained from GPS information) acquired from the outside. In the drawings, the same reference numerals denote the same or corresponding parts, and detailed descriptions thereof are omitted.

  The random selection unit 10 according to the second embodiment includes a combination selection unit 35, a combination setting unit 36 (table storage unit 36), and a determination processing unit 38. Of course, the position information acquisition unit 37 may be incorporated in the random selection unit 10. Note that the position information acquisition unit 37 may acquire the position information of the terminal itself by a method other than the position information obtained from the GPS satellite 4. For example, the position information may be acquired from an external device connected to the communication terminal 3, or the position information may be acquired by receiving an input from an input button (the above-described “input unit”) of the communication terminal 3.

  In the communication terminal 3 illustrated in FIG. 10, the position information acquisition unit 37 acquires GPS position information from the GPS signal processing unit 29 and outputs the GPS position information to the determination processing unit 38 as the position information of the own terminal. The determination processing unit 38 generates local terminal inside / outside information that is information indicating whether the position of the terminal is within a specific range (predetermined region) or out of the range, and sends the information to the combination setting unit 36. The combination setting unit 36 performs random selection when the position of the own terminal is within a specific range (predetermined region) according to the own terminal range inside / outside information held in advance by the combination setting unit 36 (random selection unit 10). When the communication terminal 3 having the random selection unit 10 is present in the predetermined area, the unit 10 sets a time slot that is a basis of the time for the transmission unit 7 to delay the transmission data with respect to the case where the communication terminal 3 does not. For increasing the probability of being able to select from an early time slot channel, in other words, when the random selection unit 10 has the communication terminal 3 having the random selection unit 10 in a predetermined region, Randomly select the time slot on which the transmission unit 7 delays the transmission data from the earlier time slot channels within the selectable range. And it transmits the setting unit 36 is the combination selecting unit 35 combines the tables can Rukoto information (combination information). For example, it is like the table shown in FIG.

  In accordance with the own terminal range inside / outside information held in advance by the combination setting unit 36, the combination setting unit 36, when the position of the own terminal is outside a specific range (predetermined area), May be transmitted to the combination selection unit 35. For example, it is like the table shown in FIG. 9 (a) (FIG. 8). Of course, when the position of the terminal is out of a specific range (predetermined area), information of a table (combination information) that can be randomly selected from the time slot channels within the selectable range from the later time side channels. May be transmitted from the combination setting unit 36 to the combination selection unit 35. For example, it is like the table shown in FIG.

  That is, when the position of the own terminal is outside a specific range (predetermined area), the random selection unit 10 has the communication terminal 3 having the random selection unit 10 outside the predetermined area, or not To increase the probability that the transmission unit 7 can select the time slot from which the transmission data is delayed from the slow time slot channel, in other words, the random selection unit 10 is outside the predetermined area. When there is the communication terminal 3 having the random selection unit 10, the time slot of the time slot channel within a range in which the transmission unit 7 can select the time slot on which the transmission data is delayed is compared with the case where the communication terminal 3 is not. The combination setting unit 36 transmits information of a table that can be randomly selected from the later ones to the combination selection unit 35 (for example, FIG. 9). c), the possibility of early communication of the communication terminal 3 whose position of the own terminal is outside a specific range (predetermined area) is reduced, so that the position of the own terminal is specified The possibility of early communication of the communication terminal 3 within the range (predetermined area) can be increased.

  The own terminal range inside / outside information held in advance by the combination setting unit 36 is information on a predetermined area. This predetermined area refers to a communication terminal 3 that has a strong need for early communication when it exists within the predetermined area, even when it exists outside the predetermined area. In the communication terminal according to the second embodiment, a case is described in which the random selection unit 10 (combination setting unit 36) holds information on a predetermined area in advance. A case where the area information is acquired from the outside will be described.

  As described above, the combination setting unit 36 that has received the own terminal range inside / outside information from the determination processing unit 38 determines the combination selection unit from the table information (combination information) determined according to the own terminal range inside / outside information. 35 randomly selects one of the combinations of spreading code channel (orthogonal code channel), frequency channel, and time slot channel (selection number when using the table shown in FIG. 9). Then, the combination selection unit 35 transmits the selected spreading code channel (orthogonal code channel)) to the spreading code generation unit 9 (orthogonal code generation unit 9), transmits the selected time slot channel to the TDMA processing unit 12, The selected frequency channel is transmitted to the FDMA processing unit 13.

  A communication method according to Embodiment 2 will be described with reference to FIG. FIG. 11 is a flowchart showing a transmission operation of the communication terminal according to the second embodiment. In other words, it can be said that this is a communication method used for the communication terminal 3 that transmits the transmission data spread by CDMA to the base station 2 via the satellite 1. S in FIG. 11 means a processing step, and the initial letter of STEP is described. Note that S101, S102, S103, S109 to S112, and S114 are the same as those shown in FIG. Further, S004, S005, S007, and S113 are processing steps in the following embodiments, and will not be described here.

  After the process of S103 (after the process of S102 when S103 is not performed), in S106, the determination processing unit 38 and the local terminal position information from the position information acquisition unit 37 and the combination setting unit 36 (random selection unit 10). ) And the own terminal range inside / outside information held in advance, it is determined whether or not the position of the own terminal is within the range. When the position of the own terminal is within the range, in S108, the random selection unit 10 sets the probability that an early time is selected in the selection of the time slot channel. In S106, if the position of the terminal is out of range, S108 is skipped. Before S106, a communication terminal position acquisition step of acquiring the location of the communication terminal 3 by the position information acquisition unit 37 is performed.

  Next, S109 and S110 are performed, and in S111, the random selection unit 10 randomly selects one of the frequency channels set to increase the probability that an early time is selected. This can be said to be a frequency channel selection step in which a frequency channel for transmitting CDMA spread transmission data is randomly selected from those set so as to increase the probability that an early time is selected.

  That is, it can be said that the time slot channel selection step of S111 increases the probability that an early time slot channel can be selected when the location of the communication terminal 3 is within a predetermined area and when it is not. Further, the time slot channel selection step is performed in a random manner from the time slot channel within the selectable range from the earliest time side when the location of the communication terminal 3 is within a predetermined area, or not. It can be said that it is a choice.

  If the position of the terminal is out of the range, S108 is skipped, but in this case, “the time slot channel selection is set so as to increase the possibility (probability) of a late time”. The processing step opposite to S108 may be performed. In this case, by this processing step, the time slot channel selection step, which is S111, lowers the probability that an early time slot channel can be selected when the location of the communication terminal 3 is outside the predetermined area and when it is not. Is. Also, the time slot channel selection step is performed randomly from the time slot channel within the selectable range from the later time side when the location of the communication terminal 3 is out of the predetermined area and when it is not. It can be said that it is a choice.

  In S112, the random selection unit 10 determines the random selection unit 10 with one selected spread code channel, one time slot channel, and one frequency channel as one of the combinations of access methods, and S114 is executed. CDMA-spread transmission with the spreading code channel selected in the spreading code channel selection step at the frequency corresponding to the time slot channel selected in the time slot channel selection step and the frequency channel selected in the frequency channel selection step Send data.

The processing of S109 to S112 and S114 is performed by an operation in which the short message processed by the transmission data unit 22 is linked with the random selection unit 10, the position information acquisition unit 37, and the transmission unit 7. Details are as described in the description of the random selection unit 10, the position information acquisition unit 37, and the transmission unit 7.

  When S109 to S112 and S114 in the case where Yes is determined in S106 are replaced with detailed processing steps, a CDMA spreading step (in which CDMA spreading of transmission data is performed using the spreading code channel randomly selected in the spreading code channel selection step ( CDMA spreading unit 11), transmission data that is CDMA spread by a CDMA spreading step in a time slot channel selected at random from among those set to increase the probability that an early time is selected in the time slot channel selecting step A delay step (TDMA processing unit 12) that delays the transmission data to be transmitted, and a frequency conversion step that frequency-converts the transmission data delayed in the delay step to a frequency corresponding to the frequency channel randomly selected in the frequency channel selection step (FDM The three process steps of the processing unit 13). Finally, a transmission step (radio processing unit 34) that transmits transmission data that is delayed in the delay step and frequency-converted in the frequency conversion step, corresponding to S114, is performed.

Embodiment 3 FIG.
A third embodiment of the present invention will be described with reference to FIGS. The basic configuration of the base station (base station 2) according to Embodiment 3 is the same as the base station (base station 2) according to other embodiments. A black dot “●” shown in FIGS. 15 to 18 is a point (position) indicated by latitude and longitude. Also, the area indicated by diagonal lines is the predetermined area described above. In the figure, a predetermined area E, a predetermined area E1, and a predetermined area E2 are displayed. FIG. 15A is a diagram showing a predetermined circular area E given center (centroid) information, and FIG. 15B is a quadrangular prescribed area E given center (centroid) information. FIG. 15 (c) is a diagram showing a predetermined region E indicated by a plurality of circles given information of a plurality of centers (centers of gravity), and FIG. 16 (a) is a predetermined circle of information given vertex information. FIG. 16 (b) is a diagram showing a region E, FIG. 16 (b) is a diagram showing a rectangular predetermined region E given vertex information, and FIG. 16 (c) is a circle prescribed given information on three points on the circumference. FIG. 16D is a diagram showing the region E of FIG. 16A. FIG. 16 (d) shows a circle contained in the circle from information given at three points on the circumference (this circle is also given information on three points on the circumference). FIG. 17 (a) and FIG. 17 (b) are diagrams showing the predetermined region E surrounded by a plurality of given points.

  FIG. 18A shows a circular predetermined area E1 to which information on three points on the circumference is given and a circle included in the predetermined area E1 (this circle is also given information on three points on the circumference). FIG. 18B shows a predetermined area E1 surrounded by a plurality of given points and a quadrangle included in the predetermined area E1 (this square is a vertex). FIG. 18C is a diagram showing a predetermined area E2 from which a plurality of centers (centers of gravity) are given, and a predetermined area E2 and a center indicated by a plurality of circles. It is a figure which shows the predetermined | prescribed area | region E1 to which the information of (centroid) is given and which several circular shows.

  The third embodiment describes a case where the communication terminal according to the second embodiment describes the case where the random selection unit 10 (combination setting unit 36) holds information of a predetermined region in advance. In the case of acquiring the information of the area from the outside, in particular, the case of acquiring from the base station 2 will be described. In communication terminal 3 according to Embodiments 2 and 3, random selection unit 10 determines the position of communication terminal 3 from position information obtained from GPS information. Specifically, it is common that the communication terminal 3 includes an information acquisition unit 8 that acquires GPS information obtained from the satellite 1 or the GPS satellite 4, and the position information acquisition unit 8 acquires position information from the GPS information. doing. Of course, the communication terminal 3 is provided with the receiving part 6 which receives the forward link signal which the base station 2 transmits, and the transmission part 7 which transmits a return link signal.

  Therefore, in the third embodiment, description regarding the same parts as in the first and second embodiments may be omitted. In other words, Embodiment 3 can be said to describe the base station according to Embodiment 3. That is, in the third embodiment, the base station 2 communicates with a plurality of communication terminals 3 via the satellite 1, and the base station 2 transmits a return link signal from the plurality of communication terminals 3 to the base station 2. Start of orthogonal code (spreading code) generated from the base station transmitter 2t for transmitting the forward link signal to the plurality of communication terminals 3 and time information obtained from the satellite 1 or GPS information and synchronized between the plurality of communication terminals 3 And a base station receiving unit 2r that receives, from a plurality of communication terminals 3, a return link signal that is CDMA spread by an orthogonal code (spreading code) generated according to timing. Note that the basic operation of the base station 2 described in the third embodiment is the same as that of the base station 2 in the other embodiments.

  12 to 18, reference numeral 39 denotes broadcast information that acquires range information (region information) that is information on a predetermined region from the base station 2 that has been separated from the received data by the TDM separation unit 27, and that is sent to the determination processing unit 38. It is an acquisition unit. Range information (region information) that is information on a predetermined region may be referred to as “broadcast information” because the same information is distributed from the base station 2 to a plurality of terminals 3. Reference numeral 40 denotes a range information unit that sends information serving as a source of range information (region information) that is information on a predetermined region transmitted from the base station 2 to the communication terminal 3 to the service center 16. The service center 16 sends information from the range information unit 40 to the base station 2 (a ground interface unit 41 described later) via the ground network 14. The black dot “●” indicates latitude and longitude as range information (region information) which is information of a predetermined region (predetermined region E (predetermined regions E1, E2)). If the information from the range information unit 40 is not usable as range information (region information) that is information on a predetermined region when the communication terminal 3 receives the information, the service center 16 sends a range information generation unit. The information from the range information unit 40 may be converted by 16e (range information conversion unit 16e) and then sent to the base station 2 (a ground interface unit 41 described later). A range information generation unit 16e (range information conversion unit 16e) may be provided on the base station 2 side. In the drawings, the same reference numerals denote the same or corresponding parts, and detailed descriptions thereof are omitted.

  12 to 18, reference numeral 41 denotes a ground interface unit of the base station 2 that receives data to be transmitted to each communication terminal 3 transmitted from the service center 16 to the base station 2 via the ground network 14. Note that data (mainly satellite orbit information) transmitted from the satellite tracking control center 15 to the base station 2 via the ground network 14 is similarly received by the ground interface unit 41 of the base station 2. 42 receives data to be transmitted for each communication terminal 3 from the terrestrial interface unit 41 and generates transmission data for each communication terminal 3, and 43 represents transmitted control data (such as satellite orbit information). In addition, a TDM multiplexing unit for TDM multiplexing transmission data, a control information transmitting unit for transmitting control data (satellite orbit information, etc.) to the TDM multiplexing unit 43, and a TDM multiplexing unit 43 for TDM multiplexing Is an error correction encoding unit that performs error correction encoding on the processed data, 46 is a QPSK modulation unit that performs QPSK modulation after processing in the error correction encoding unit 45, and 47 is transmission data that is QPSK modulated by the QPSK modulation unit 46 Is a radio transmission unit that amplifies a large amount of power after frequency conversion into an RF frequency. A duplexer through in order to transmit a forward link signal using an over drinks communication line 17. Reference numeral 2t denotes the above-described base station transmitter, which includes a TDM multiplexer 43, an error correction encoder 45, a QPSK modulator 46, and a radio transmitter (base station side transmitter) 47. In the drawings, the same reference numerals denote the same or corresponding parts, and detailed descriptions thereof are omitted.

  12 to 18, reference numeral 49 denotes a received signal transmitted from the non-stationary satellite 1 via the non-stationary satellite 1 (relay), received by the satellite communication antenna 2 s, and sent via the duplexer 48. A radio receiving unit 50 for amplifying the signal with low noise, and 50 receives the chip clock and the orthogonal code start timing from the received signal (received CDMA signal) converted into the IF frequency signal after the low noise amplification by the radio receiving unit 49. , A CDMA despreading unit for performing CDMA despreading, 51 a BPSK demodulating unit for BPSK demodulating a signal despread in the CDMA despreading unit 51 of the base station 2, and 52 for error correction after BPSK demodulation by the BPSK demodulating unit 52 An error correction decoding unit 53 that performs decoding, forms data to be output to the service center 16 after error correction decoding by the error correction decoding unit 52 A data processing unit for transmitting to the ground interface 41. Data processed from the data processing unit 53 is transmitted from the ground interface unit 41 to the service center 16 via the ground network 14. Reference numeral 2r denotes the above-described base station receiving unit, which includes a radio receiving unit (base station side receiving unit) 49, a CDMA despreading unit 50, a BPSK demodulating unit 51, and an error correction decoding unit 52. In the drawings, the same reference numerals denote the same or corresponding parts, and detailed descriptions thereof are omitted.

  The base station 2 (base station transmission unit 2t) illustrated in FIG. 13 and FIG. 14 transmits information on a predetermined area set based on a predetermined condition in addition to the forward link signal, and transmits the position information of the communication terminal 3. (Position information obtained by the position information acquisition unit 37, that is, the position (location) of the terminal itself) is compared with a predetermined area, and when the communication terminal 3 is in the predetermined area and when it is not Thus, the selection range of the time slot for transmitting the return link signal is changed between the plurality of communication terminals 3 in accordance with the position of the communication terminal 3. Range information (region information), which is information on a predetermined region, is processed as transmission data by the data generation unit 42 and the base station transmission unit 2t, and forward link from the satellite communication antenna 2s to the communication terminal 3 via the satellite 1. It is transmitted as a signal.

  The communication terminal 3 (reception unit 6) that has received the forward link signal acquires information on a predetermined region from the received forward link signal, and the random selection unit 10 of the communication terminal 3 selects the random region within the predetermined region. When the communication terminal 3 having the unit 10 is present, the probability that the transmission unit 7 can select the time slot that is the basis of the time for delaying the transmission data from the early time slot channel is increased as compared to the case where the communication terminal 3 is not. Note that the random selection unit 10 of the communication terminal 3 causes the transmission unit 7 to delay the transmission data when the communication terminal 3 having the random selection unit 10 is outside the predetermined area, and when the communication terminal 3 does not. The probability that the time slot on which the time is based can be selected from the early time slot channel may be lowered.

  Then, the return link signal is transmitted from the satellite communication antenna 3s by a combination of access methods (one spreading code channel, one time slot channel, one frequency channel) set (determined) by the random selection unit 10 of the communication terminal 3. It transmits to the base station 2 via the satellite 1. The return link signal is received by the satellite communication antenna 2s of the base station 2, processed by the base station receiving unit 2r and the data processing unit 53, and sent from the ground interface unit 41 to the service center 16 via the ground network. Therefore, the service center 16 can obtain information from the plurality of communication terminals 3. Application to the communication system (base station, communication terminal) according to Embodiment 3 for transmitting short messages such as safety information including personal identification information (ID information) and position information via satellite 1 (quasi-zenith satellite 1). In this case, the service center 16 can obtain safety information including personal identification information (ID information) and position information of the communication terminal 3 or the user thereof.

  Note that the communication system (base station, communication terminal) according to Embodiment 3 transmits a short message such as safety information including personal identification information (ID information) and position information via satellite 1 (quasi-zenith satellite 1). When applied to the above, the predetermined area refers to a disaster area such as a disaster. Therefore, the range information unit 40 transmits information on the affected area to the service center 16 as range information (region information) that is a predetermined region. However, when the information on the disaster area is not usable as range information (area information) that is information on a predetermined area when the communication terminal 3 receives the information, for example, when the area name is simply the name of the disaster area 14 converts the information from the range information unit 40 into the service center 16 shown in FIG. 14 by the range information generation unit 16e (range information conversion unit 16e), and then sends it to the base station 2 (terrestrial interface unit 41 described later). There is a need. Here, the information converted by the range information generation unit 16e (range information conversion unit 16e) is referred to as information on a predetermined region set based on a predetermined condition.

  The predetermined condition is, for example, “if the information sent from the range information unit 40 to the service center 16 (range information generation unit 16e) is a place name, a famous place such as a government office or a landmark existing in the area indicated by the place name is used. “The address and position of the building are converted into position information represented by one point indicated by latitude and longitude.”, “Information sent from the range information section 40 to the service center 16 (range information generation section 16e) is a place name. , The area indicated by the address of a well-known building such as a government office or landmark existing in the area indicated by the place name is converted into position information represented by a plurality of points indicated by latitude and longitude. Can be mentioned.

  In the former case, the “location information represented by one point” obtained by converting the address and position of a prominent building into position information represented by one point indicated by latitude and longitude is the ground interface unit 41. Is generated as transmission data including “position information represented by one point” by the data generation unit 42, and the base station transmission unit 2 t receives each piece of position information as a forward link signal as position information. Transmit to the communication terminal 3. Then, the communication terminal 3 that has received the forward link signal separates the position information by the TDM separation unit 27 and sends it to the broadcast information acquisition unit 39. And the predetermined area | region set based on the predetermined condition from the positional information on one point is calculated.

  In this calculation, that is, when a predetermined area set based on a predetermined condition is calculated from position information of one point, a predetermined area having one point as the center (center of gravity) of the circle as shown in FIG. E or a predetermined area E having a single point as a center of gravity (center) of a rectangle as shown in FIG. 15B (may be a predetermined area E having a single point as a center of gravity (center) of a polygon) or the like. The determination processing unit 38 or the broadcast information acquisition unit 39 calculates. The radius, vertex coordinates, or area information of the predetermined area E may be determined in advance and stored in the determination processing unit 38 or the broadcast information acquisition unit 39 of the communication terminal 3, or the predetermined area E The radius information, vertex coordinates, or area information of E may be set by the range information unit 40 or the range information generation unit 16e (range information conversion unit 16e), and transmitted together with the position information by a forward link signal.

  In the latter case, the “location information represented by a plurality of points” obtained by converting the area indicated by the address of a prominent building into location information represented by a plurality of points indicated by latitude and longitude is the ground interface unit. 41, the data generation unit 42 generates the transmission data including “position information represented by a plurality of points”, and the base station transmission unit 2t forwards the position information of the plurality of points as the position information. It transmits to each communication terminal 3 as a signal. Then, the communication terminal 3 that has received the forward link signal separates the position information by the TDM separation unit 27 and sends it to the broadcast information acquisition unit 39. And the predetermined area | region set based on the predetermined condition from the positional information on several points is calculated.

  In this calculation, that is, when a predetermined region set based on a predetermined condition is calculated from position information of a plurality of points, a plurality of points having one point as shown in FIG. A predetermined area E indicated by a circle, a predetermined area E having a plurality of points (three points) as shown in FIG. 16A as vertices of a triangle, and a plurality of points as shown in FIG. A predetermined area E having four vertices as quadrangular vertices (may be a predetermined area E having a polygonal shape having a given point as a vertex), and a plurality of points (three points) as shown in FIG. ) Is a circular predetermined region E passing through the circumference, and a plurality of points (three points) as shown in FIG. 16D are included in the circle from the circle passing through the circumference (this circle also has a circumference). A predetermined region E except for a plurality of points (three points are given), surrounded by a plurality of points as shown in FIGS. Determination processing unit 38 or the broadcast information acquisition unit 39, such as the communication terminal 3 a predetermined area E is calculated was. The radius and area information of the predetermined area E may be determined in advance and stored in the determination processing unit 38 or the broadcast information acquisition unit 39 of the communication terminal 3, or the radius or area of the predetermined area E may be stored. The area information may be set by the range information unit 40 or the range information generation unit 16e (range information conversion unit 16e) and transmitted together with the position information by a forward link signal.

  From the predetermined area thus determined (predetermined area E), the determination processing unit 38 determines the position of its own terminal in the communication terminal 3 according to the third embodiment as well as in the second embodiment. Local terminal internal / external information, which is information indicating whether it is within the range (predetermined region (predetermined region E)) or outside the range, is generated and sent to the combination setting unit 36. The combination setting unit 36 determines that the position of the own terminal is within a specific range (predetermined region (predetermined region E)) according to the own terminal range inside / outside information held in advance by the combination setting unit 36 (random selection unit 10). In some cases, when the random selection unit 10 has a communication terminal 3 having the random selection unit 10 in a predetermined region (predetermined region E), the transmission unit 7 transmits the communication terminal 3 for the communication terminal 3 that does not. What increases the probability that a time slot that is the basis of the data delay time can be selected from an early time slot channel, in other words, the random selection unit 10 places the random selection unit 10 in a predetermined region (predetermined region E). When there is a communication terminal 3 having, a time slot within a range in which a time slot based on which the transmission unit 7 delays transmission data can be selected. Transmitting from those early side of the panel to the selection unit 35 combination setting unit 36 combines the information of the table that can be selected randomly.

  In addition, when the position of the terminal is outside a specific range (predetermined region (predetermined region E)), the random selection unit 10 moves the random selection unit 10 outside the predetermined region (predetermined region E). If there is a communication terminal 3 having, if it is not so, the one that increases the probability that the transmission unit 7 can select a time slot as a base of time for delaying transmission data from a slow time slot channel, in other words, When the random selection unit 10 has the communication terminal 3 having the random selection unit 10 outside the predetermined region (predetermined region E), the transmission unit 7 delays the transmission data with respect to the case where it is not The combination setting unit 36 sets information of a table that can randomly select a time slot that is a base of time from among the time slot channels within the selectable range from the later time side channels. Since the possibility of early communication of the communication terminal 3 whose position is out of a specific range (predetermined region (predetermined region E)) is reduced by transmitting to the matching selection unit 35, the position of the own terminal Can increase the possibility of early communication of the communication terminal 3 within a specific range (predetermined region).

  Therefore, since the communication apparatus according to the third embodiment performs such an operation, the base station transmission unit 2t (base station 2) in the base station according to the third embodiment has a predetermined area (predetermined area E). It can be said that the selection range of the time slot for transmitting the return link signal is changed between the plurality of communication terminals 3 depending on whether the communication terminal 3 is present or not. In addition, the predetermined region E is “a region in which position information is transmitted by a forward link signal and is set based on a predetermined condition from one point of position information indicated by the position information” or “a position of a position by a forward link signal”. It can be said that it is an area | region set based on predetermined conditions from the positional information of two or more points | pieces which the information is transmitted and this positional information shows.

  In Embodiments 2 and 3 so far, a communication method, a communication terminal, and a base for changing a selectable range of a time slot depending on whether the communication terminal 3 is inside or outside a predetermined area (predetermined area E) Although the station and the communication system have been described, the selectable range of the time slot may be changed even within the predetermined area. For example, the predetermined area E is divided into a predetermined area E1 and a predetermined area E2.

  Then, the local terminal inside / outside information, which is information indicating whether the position of the own terminal is in the predetermined area E1 or the predetermined area E2, is generated and sent to the combination setting unit 36. When the position of the own terminal is within the predetermined area E1 according to the own terminal range inside / outside information held in advance by the combination setting unit 36 (random selection unit 10), the combination selection unit 36 When there is a communication terminal 3 having the random selection unit 10 in the predetermined area E1, a time slot that is a base of the time for which the transmission unit 7 delays transmission data with respect to the case where the communication terminal 3 is in the predetermined area E2. That increases the probability of selecting a channel from an early time slot channel, in other words, when the random selection unit 10 is in the predetermined region E1 when the communication terminal 3 has the random selection unit 10 in the predetermined region E1. The time slot on which the transmission unit 7 delays transmission data with respect to the time slot on the earlier time side of the time slot channels within the selectable range Setting unit 36 combines the information of the table may be randomly selected to transmit the combination selection unit 35 from the. Since the predetermined area E1 and the predetermined area E2 are obtained by dividing the predetermined area E, the predetermined area E1, the predetermined area E2, the predetermined area E1, and the predetermined area E are related to the random selection of the time slot channel. The relationship outside the region E2 is the same as the relationship outside the predetermined region E and the predetermined region E.

  Next, with reference to FIG. 18, the setting method of the predetermined area E1 and the predetermined area E2 is “the position information is transmitted by the forward link signal, and the predetermined position information is obtained from two or more points of position information indicated by the position information”. It will be described that the region is set based on the condition. In FIG. 18A, a circle in which a plurality of points (three points) pass through the circumference is excluded from a circle included in the circle (this circle is also given a plurality of points (three points) that pass through the circumference). In this example, the predetermined area E2 is an encircled circle as the predetermined area E1. FIG. 18B shows a predetermined circle as a predetermined area E2 excluding a square enclosed by a plurality of points from the area enclosed by the area (this square is also given a vertex (four points)). This is an example in the case of the region E1. FIG. 18C shows a predetermined region E1 among a plurality of predetermined regions indicated by a single point as the center (center of gravity) of the circle, and a predetermined region E2 that is indicated by the remaining circle. This is an example of the case. The radius and area information of the predetermined area E1 and the predetermined area E2 may be determined in advance and stored in the determination processing unit 38 or the broadcast information acquisition unit 39 of the communication terminal 3, Information on the radius and area of the region E1 and the predetermined region E2 may be set by the range information unit 40 or the range information generation unit 16e (range information conversion unit 16e), and transmitted together with the position information using a forward link signal. Good.

16 (c), (d), and FIG. 18 (a), if three points (coordinates defined as latitude and longitude) are known, a circle (circular shape) is known. The reason is as follows. Each of x and y in one of the equations of the circles represented by Equations 1 and 2 is three points (for example, (X ₁ , Y ₁ ) (X ₂ , Y ₂ ) (X ₃ , Y ₃ )) This is because the coordinates (a, b) and the radius r of the center of the circle can be easily obtained by solving the simultaneous equations formed by substituting).

  Therefore, in the communication terminal according to Embodiment 3, the reception unit 6 of communication terminal 3 that has received the forward link signal transmitted from the base station according to Embodiment 3 indicates the position information obtained from the forward link signal. It can be said that an area set based on a predetermined condition from one point of position information is a “predetermined area (predetermined area E (predetermined area E1, predetermined area E2))”. Of course, in the communication terminal according to the third embodiment, the reception unit 6 of the communication terminal 3 that has received the forward link signal transmitted from the base station according to the third embodiment indicates the position information obtained from the forward link signal. It can be said that an area set based on a predetermined condition from two or more points of position information is a “predetermined area (predetermined area E (predetermined area E1, predetermined area E2))”.

  FIGS. 15 to 18 are diagrams showing a position range designation method of “range information” distributed from the base station 2 to the communication terminal 3 through the forward link communication line 17. As shown in the figure, the range information is composed of one point (latitude and longitude) or a combination of two or more points (latitude and longitude). A black dot “●” indicates (latitude, longitude). The broadcast information acquisition unit 39 recognizes the enclosed range as range information. By using such a position range specifying method, it is possible to specify a fine range in accordance with the shape of the position range to be specified. Here, the location range to be designated is, for example, a location range where an actual disaster seems to have occurred, or an area where there are many terminals to which a short message is transmitted due to the disaster.

Embodiment 4 FIG.
Embodiment 4 of the present invention will be described with reference to FIGS. In the first to third embodiments, the combination selection unit 35 that randomly selects a combination of access schemes includes “spread code channel”, “frequency channel”, “time slot channel” stored in the combination setting unit 36 (table storage unit 36). "Random code channel", "Frequency channel", and "Time slot channel" are determined at random by selecting the aforementioned selection number from the table consisting of the selection numbers given in batches for each of the three combinations However, in the fourth embodiment, only “time slot channel” in a separate table will be described. Therefore, in Embodiment 4, the description regarding the same part as Embodiments 1-3 may be omitted.

  19 to 22, reference numeral 54 denotes a time slot setting unit (second table storage unit) that sets (stores) a table by which the combination selection unit 35 can randomly select “time slot channel”. Therefore, in the fourth embodiment, the combination setting unit 36 (table storage unit 36) sets (stores) a table that can randomly select “spread code channel (orthogonal code channel)” and “frequency channel”. It will be a thing. In the fourth embodiment, the own terminal position data (position information of the own terminal) from the position information acquisition unit 37 is sent to the time slot setting unit 54 (second table storage unit 54) of the random selection unit 10. In the first to third embodiments, the combination setting unit 36 (table storage unit 36) is a table that can randomly select “spreading code channel (orthogonal code channel)”, “frequency channel”, and “time slot channel”. It can be said that it is set (memorized). In the drawings, the same reference numerals denote the same or corresponding parts, and detailed descriptions thereof are omitted.

  A communication terminal 3 shown in FIG. 19 is obtained by adding a time slot setting unit 54 (second table storage unit 54) to the communication terminal according to the second embodiment, and the communication terminal 3 shown in FIG. These show what the time slot setting part 54 (2nd table memory | storage part 54) was added to the communication terminal which concerns on Embodiment 3. FIG. The table shown in FIGS. 21 and 22 includes three items of “spreading code channel (orthogonal code channel)”, “frequency channel”, and “time slot channel” that the random selection unit 10 needs to select at random in the row direction. Either one is set. In the column direction, the channels that can be set are arranged by selecting combinations that do not overlap among the three items. Each combination is given a selection number. In FIGS. 21 and 22, four of NNN, MMM, LLL, and KKK indicate positive integers, respectively. Also, these four positive integers may be different. Note that channel # 1, channel # 2,... Channel #KKK in the time slot channel are arranged in the order from the earliest time zone.

  21 (a) and 22 (a) are tables of selectable “spread code channels (orthogonal code channels)” and “frequency channels” stored in the combination setting unit 36 (table storage unit 36). It is. The table shown in FIG. 21B and FIG. 22B is a table of selectable “time slot channels” stored in the time slot setting unit 54 (second table storage unit 54). FIG. 21 (c) can be selected only from channel # 1 and channel # 2, which have a relatively fast time slot channel, from the table of “time slot channel” shown in FIG. 21 (b) (FIG. 22 (b)). It is a table. FIG. 21 (d) can be selected only from channel # 3 and channel # 4, in which the time slot channel is relatively slow, from the table of “time slot channel” shown in FIG. 21 (b) (FIG. 22 (b)). It is a table. FIG. 22C shows only the number of “time slot channels” that can be selected in the table shown in FIG. 21C. Similarly, FIG. 22D shows only the number of “time slot channels” that can be selected in the table shown in FIG. 21D.

  Therefore, when based on the “table stored by the table storage unit 36 (combination setting unit 36)” shown in FIGS. 21 and 22, the communication method according to the fourth embodiment includes the spreading code channel selection step and the frequency channel selection step: It can be said that it is set in advance and is randomly selected from a table comprising combinations of spreading code channels and frequency channels.

  The random selection unit 10 according to the fourth embodiment includes a combination selection unit 35, a combination setting unit 36 (table storage unit 36), a determination processing unit 38, and a time slot setting unit 54 (second table storage unit 54). . In the communication terminal 3 shown in FIG. 19, the position information acquisition unit 37 acquires GPS position information from the GPS signal processing unit 29 and outputs it to the determination processing unit 38 as the position information of the own terminal. Judgment processing unit 38 generates local terminal inside / outside information that is information indicating whether the position of the terminal is within a specific range (predetermined region) or out of the range, and sends the information to time slot setting unit 54. .

  When the time slot setting unit 54 is in a specific range (predetermined area) according to the own terminal range inside / outside information held in advance by the time slot setting unit 54 (random selection unit 10), When the random selection unit 10 has the communication terminal 3 having the random selection unit 10 in a predetermined area, the time when the transmission unit 7 delays transmission data with respect to the case where the random selection unit 10 does not To increase the probability that a slot can be selected from an early time slot channel, in other words, when the random selection unit 10 has a communication terminal 3 having the random selection unit 10 in a predetermined area, Thus, the time slot on which the transmission unit 7 delays transmission data is randomly selected from the time slot channels within the selectable range from the earlier time side. Transmitting the information of the table that can be-option time slot setting section 54 is the combination selecting unit 35. For example, it is like the table shown in FIG.

  The combination setting unit 36 transmits the combination of “spread code channel (orthogonal code channel)” and “frequency channel” to the combination selection unit 35. For example, it is like the table shown in FIG. When the position of the own terminal is outside a specific range (predetermined area) according to the own terminal range inside / outside information held in advance by the time slot setting unit 54, the time slot setting unit 54 normally uses a table. The time slot setting unit 54 may transmit this information to the combination selection unit 35. For example, it is like the table shown in FIG.

  Further, when the position of the own terminal is out of a specific range (predetermined area), the random selection unit 10 has the communication terminal 3 having the random selection unit 10 outside the predetermined area, or not To increase the probability that the transmission unit 7 can select the time slot from which the transmission data is delayed from the slow time slot channel, in other words, the random selection unit 10 is outside the predetermined area. When there is the communication terminal 3 having the random selection unit 10, the time slot of the time slot channel within a range in which the transmission unit 7 can select the time slot on which the transmission data is delayed is compared with the case where the communication terminal 3 is not. The time slot setting unit 54 transmits information of a table that can be randomly selected from the later ones to the combination selection unit 35 (for example, FIG. 2). (It is like the table shown in (d)), since the possibility of early communication of the communication terminal 3 whose position of the own terminal is outside a specific range (predetermined area) is reduced, the position of the own terminal is specified. The possibility of early communication of the communication terminal 3 within the range (predetermined area) can be increased.

  In this way, the time slot setting unit 54 that has received the own terminal range inside / outside information from the determination processing unit 38 selects the combination from the information (combination information) in the table as described above determined according to the own terminal range inside / outside information. The unit 35 randomly selects one time slot channel (a selection number when using the table shown in FIG. 21). Then, the combination selection unit 35 transmits the selected selected time slot channel to the TDM processing unit 12. In addition, the combination selection unit 35 uses one of the combinations of the spread code channel (orthogonal code channel) and the frequency channel based on the information obtained from the combination setting unit 36 regardless of the local terminal range information (see FIG. 21A). When the table shown is used, the selection number) is selected at random. Then, the combination selection unit 35 transmits the selected spreading code channel (orthogonal code channel)) to the spreading code generation unit 9 (orthogonal code generation unit 9), and transmits the selected frequency channel to the FDM processing unit 13.

  The own terminal range inside / outside information held in advance by the time slot setting unit 54 is information on a predetermined area. This predetermined area (predetermined area E (predetermined areas E1, E2)) is, as described above, when the communication terminal 3 exists outside the predetermined area when it exists within the predetermined area. In this case, it means that there is a strong need for early communication. In the communication terminal 3 described in FIG. 19, the case where the random selection unit 10 (combination setting unit 36) holds information in a predetermined area in advance is described. However, in the communication terminal 3 illustrated in FIG. 20, The case where the information of a predetermined area | region is acquired from the outside is shown. Note that the cooperation between the broadcast information acquisition unit 39, the broadcast information acquisition unit 39, and the determination processing unit 38 illustrated in FIG.

  Next, the table shown in FIG. 22 will be described. The table shown in FIG. 22 is a substitute for the table shown in FIG. FIG. 21A and FIG. 22A, which are tables held by the combination setting unit 36, are common. Further, FIG. 21B and FIG. 22B which are tables held by the time slot setting unit 54 are common.

  The difference is that in FIGS. 21C and 21D, the selection number is set to “NNN” in accordance with FIGS. 21A and 21B, and the combination selection unit 35 is randomly determined from “NNN”. However, if the number of time slots that can be selected is reduced in order to increase the probability that a time slot can be selected from an early time slot or a late time slot channel according to the determination of the determination processing unit 38, the number of selectable time slots and the selection number There is no problem even if the numbers are matched.

  For this reason, FIGS. 22 (c) and 22 (d) show a case where the number of selectable time slots and the number of selection numbers are matched. In FIGS. 22C and 22D, since the number of time slots that can be selected is two, only two selection numbers “001” and “002” are shown. It is not limited.

  In the fourth embodiment, the time slot setting unit 54 (second table storage unit 54) is provided as a configuration that can be changed only with respect to time slots in which the selection width changes depending on conditions. It is possible to set a “time slot channel” having a higher degree of freedom than creating three tables of “code channel)”, “frequency channel”, and “time slot channel” together. Of course, it becomes easy to create a table of “spreading code channel (orthogonal code channel)”, “frequency channel”, and “time slot channel”.

Embodiment 5 FIG.
A fifth embodiment of the present invention will be described with reference to FIGS. 23, 24, and 25. FIG. In the fifth embodiment, a configuration will be described in which the judgment processing unit 38 using the own terminal position data described in the second to fourth embodiments is considered from the viewpoint of probability distribution characteristics. The communication terminal according to Embodiment 5 is different from the communication terminals according to other embodiments in that the time slot channel is randomly selected under the probability distribution characteristic. Therefore, even when the communication terminal according to Embodiment 5 needs to change the selection range of the time slot, the random selection unit 10 needs to maintain a table as shown in FIG. 9 and switch the reference table. There is no. Regarding the selection of the spread code channel (orthogonal code channel) and the frequency channel, the communication terminal according to the fifth embodiment and the communication terminal according to the first to fourth embodiments have the same basic operation. That is, the spread code channel (orthogonal code channel) and the frequency channel are randomly selected by the random selection unit 10 (combination selection unit 35).

  23, 24, and 25, 55 is a probability distribution storage unit that sends information of probability distribution characteristics (for example, those described in FIG. 25) to the combination selection unit 35, and 56 is the own terminal range from the determination processing unit 38. This is a probability setting unit that transmits probability distribution selection information to the probability distribution storage unit 55 based on the inside / outside information. The random selection unit 10 according to the fifth embodiment includes a combination selection unit 35, a combination setting unit 36 (table storage unit 36), a determination processing unit 38, a probability distribution storage unit 55, and a probability setting unit 56. In the drawings, the same reference numerals denote the same or corresponding parts, and detailed descriptions thereof are omitted.

  The communication terminal 3 described in FIG. 23 corresponds to the communication terminal according to the second embodiment (only the communication terminal 3 determines whether or not the own terminal is within the range), and is illustrated in FIG. The communication terminal 3 corresponds to the communication terminal according to Embodiment 3 (the communication terminal 3 receives information from the base station 2 to determine whether or not the own terminal is within the range). FIG. 25 is a characteristic diagram of the probability distribution for the time slot channel stored in the probability distribution storage unit 55. The characteristic of FIG. 25A is a distribution in which the probability is higher as the time slot channel is relatively faster, and the characteristic of FIG. 25B is a distribution in which the probability is uniform regardless of the time slot channel. The characteristic of FIG. 25C is a distribution in which the probability increases as the time slot channel is relatively slow.

  As described above, the slot selection method in which data is transmitted in the slot next to the slot in which the transmission request has occurred cannot be used in the present application, as in the case of the random access method based on the normal Slotted ALOHA. For this reason, a method for selecting different slots in CDMA / FDMA / TDMA random access capable of handling a service in which a rescue message (short message) transmission request is simultaneously generated in the communication terminals 3 will be described below.

  For example, a slot for transmitting data is selected as follows. That is, each communication terminal 3 randomly selects one slot from a number of slots from the time when the transmission request is generated until T time elapses. Each communication terminal 3 synchronizes the slot timing with the chip clock and the orthogonal code start timing (spread code start timing) generated by the transmission timing generation unit 32 using the absolute time obtained from the GPS time signal. Therefore, the slots between the communication terminals 3 are synchronized.

  Now, let the data burst length of the short message be 125 information bits. Since the minimum information necessary for the short message is the ID and position information of the victim (the communication terminal 3 holder), the message can be configured with such a small number of bits. Therefore, the time length of one burst is 125 bits / 50 bps = 2.5 seconds. If T = 30 minutes, the number of slots is 720.

  Next, in random access by CDMA / FDMA / TDMA, “the number of accessing communication terminals 3 is N, and one of the N communication terminals 3 is randomly assigned to one spreading code channel. And a combination of frequency channel and slot channel is selected to determine the probability of successful message transmission Ps ”.

  The probability Ps is “when a certain communication terminal 3 randomly selects a combination of one spreading code channel, a frequency channel, and a slot channel, and there are a total of N communication terminals 3 (N is a positive value). The probability that the other N−1 communication terminals 3 do not select the same combination as that of one communication terminal 3 described above ”. This probability is equal to the case of k = 0 in the “probability that the number of successes when performing N independent trials is k” in the binomial distribution. Therefore, the binomial distribution is obtained when n is large. If the Poisson distribution is followed, this probability is equal to the case of the Poisson distribution with k = 0. That is, N: number of terminals, Nc: number of spreading code channels, Nf: number of frequency channels, Nt: number of slot channels,

Then, the transmission message success probability Ps is

It becomes. Here, assuming that Nc = 1024, Nf = 25, Nt = 720, and assuming that the number of communication terminals simultaneously accessing N = 1 million, substituting into the above equation, λ = 0.1356, Ps = 0.947, and about 95 % Of terminals are expected to succeed in sending a short message once without collision.

  Next, when the communication terminal 3 transmits a short message, the communication terminal 3 waits for a time considering the round-trip delay time (about 0.5 seconds) in the satellite line and the processing time in the base station 2. Consider a case where a short message is retransmitted in the nearest next slot when an ACK signal is not returned from the station 2 through the forward link communication line 17 (that is, when a time-out occurs in the communication terminal 3). In the following, re-transmission is further considered until re-transmission. Now, let Pc be the probability that a message will collide.

So

Holds. However, when there is retransmission and re-transmission, it must be considered that the number N (that is, the total number of traffics) of the communication terminals 3 that simultaneously access increases. That is, in the first transmission of the message, the total traffic number of N increases to N / (1-Pc) due to the first collision, and when there is a retransmission, the total traffic number is further increased to N / [(1- Pc) (1-Pc ^ 2)], and when there is a re-transmission, the total traffic number further increases to N / [(1-Pc) (1-Pc ^ 2) (1-Pc ^ 3)] It is thought to increase. Therefore, if there is a resend or resend,

Can be considered to hold. Rewriting equation 7

This is an equation for obtaining λ = N / (Nc * Nf * Nt) necessary for setting the probability of collision in one message transmission to Pc when retransmission and re-transmission are performed. Conceivable. In Equation 8, if Pc = 0.2, for example, λ = 0.152. Therefore, if λ = 0.152, the probability that a message will collide even if one communication terminal resends the message is Pc ^ 3. Therefore, Pc ^ 3 = 0.2 ^ 3 = 0.008 Therefore, it is considered that the communication terminal can send a message by random access with a message loss rate of 0.8%.

  At this time, the number N of terminals that can be accessed simultaneously is calculated by substituting the above-described specific parameters Nc = 1024, Nf = 25, and Nt = 720 into the above equation, N = 0.152 * (1024 * 25 * 720) = 2801,664, and approximately 2.8 million communication terminals 3 can be accessed simultaneously with a message loss rate of 0.8%. Next, a specific method in which the random selection unit 10 of the communication terminal 3 randomly selects a combination of one spreading code channel, one frequency channel, and one time slot channel will be described.

  First, a uniform random number Rnd between 0 and 1 is generated. When the total number of spreading code channels is Nc, [Nc * Rnd + 1] is calculated, and the integer part is taken as one spreading code channel selected at random. The same applies to the frequency channel and the time slot channel.

  Similar to the other embodiments, the probability setting unit 56 determines whether the position of the own terminal is within a specific range (predetermined region) according to the own terminal range inside / outside information obtained from the determination processing unit 38. The setting information (probability distribution selection information) for increasing the selection probability of the early time slot channel is transmitted to the combination selection unit 35 as the probability distribution characteristic via the probability distribution storage unit 55. At that time, the combination selection unit 35 (randomly) The selection unit 10) can use, for example, an inverse transformation method as a random number generation method for selecting a time slot channel. The inverse transformation method is a method of obtaining random numbers according to a desired probability distribution by further transforming the obtained random numbers (for example, the above-mentioned uniform random number Rnd) with a function, and is well known in the world. Here, when a variable whose probability of taking the value is determined by the result of the trial is a random variable, the one showing the correspondence between the random variable and the probability of taking the value is called a probability distribution.

  As an example of a probability distribution that increases the selection probability of a relatively early time slot channel, among the all time slot channels, for example, the probability is uniform in the first half slot channel from the earliest time, and the remaining second half The probability distribution may be such that the probability is 0 in the slot channels. In such a case, the time slot channel is selected at random only from among the early time slot channels in the first half.

  8 and 9, the combination setting unit 36 in the access scheme from the communication terminal 3 randomly selects one or more combinations of spreading code channels, frequency channels, and time slot channels. In the system, differences and similarities between the random selection unit 10 of the communication terminal according to the fifth embodiment and the random selection unit 10 of the communication terminal according to the first to fourth embodiments will be described. Note that the number n of channel combinations equal to or greater than 2 (n is a positive integer) will be described in detail later in Embodiment 6. The table shown in FIG. 8 stores (sets) all combinations of spreading code channels, frequency channels, and time slot channels, and a selection number is assigned to each combination. FIG. 9 shows the contents of the table storage unit 36, and the table of FIG. 9A stores all combinations of spreading code channels, frequency channels, and time slot channels. , A selection number is attached. Further, in the table of FIG. 9B, the spread code channel and the frequency channel are the same as those of FIG. 9A, but the time slot channel is the table of only channel # 1 and channel # 2 having relatively early times. However, channel # 3 and channel # 4 which are late in time are not included in the table. In the table of FIG. 9 (c), the spread code channel and the frequency channel are the same as in FIG. 9 (a), but the time slot channel includes only channel # 3 and channel # 4 which are relatively slow in time. However, channel # 1 and channel # 2 whose time is early are not included in the table.

  In the communication terminals according to Embodiments 1 to 4, the random selection unit 10 refers to the table storage unit 36 and selects a selection number at random from the table storage unit 36, thereby selecting a combination of channels at random. By using this method, each channel can be selected at random. When it is necessary to set a time difference between time slots that can be selected for each communication terminal 3, the combination setting unit 36 uses information (combination information) in a table as shown in FIGS. 9B and 9C set in advance. What is necessary is just to send to the combination selection part 35. That is, since the random selection method of the access method of the communication terminal 3 using FIG. 9 (b) and FIG. 9 (c) described above switches the table set in advance, the random selection unit 10 itself has a fast time slot in the time slot. It is not a direct judgment of sheath delay. On the other hand, in the communication terminal according to Embodiment 5, according to the setting method for increasing the selection probability of the relatively early time slot channel according to the own terminal range inside / outside information in the probability distribution storage unit 55 and the probability setting unit 56, Alternatively, the present embodiment is different in that it relates to a setting method for increasing the selection probability of a relatively slow time slot channel according to the own terminal range inside / outside information in the probability distribution storage unit 55 and the probability setting unit 56. Therefore, it can be said that the communication terminals according to Embodiments 1 to 4 are randomly selected for the time slot channel. In the case of using a table, it can be said that the channel is randomly selected from the channels described in the table. On the other hand, it can be said that the communication terminal according to Embodiment 5 selects at random while being limited in the selection range of the time slot by the probability distribution characteristic. Note that, regarding the spread code channel (orthogonal code channel) and the frequency channel, both the communication terminals according to Embodiments 1 to 4 and Embodiment 5 are randomly selected. In the case of using a table, it can be said that the channel is randomly selected from the channels described in the table.

  In the communication terminal according to Embodiment 5 (communication terminal 3 described in FIG. 23 or FIG. 24), the table storage unit 36 (combination setting unit 36) receives information on the table shown in FIG. Combination information) is sent to the combination selection unit 35. The combination selection unit 35 randomly selects a time slot from the table information (combination information) based on the probability distribution characteristic information (the one described in FIG. 25) sent from the probability distribution storage unit 55. The communication terminal according to the fifth embodiment is the same as the communication terminal according to the first to fourth embodiments having the random selection unit 10 in which the table storage unit 36 stores the table shown in FIGS. 9A and 9B as table information. The function of can be obtained. On the other hand, the communication terminal according to the fifth embodiment randomly selects a time slot channel) than the other embodiments that switch the tables of FIG. 9 (a), FIG. 9 (b), and (c). The degree of freedom to change the range is high. The reason is that the slope of the straight line indicating the probability distribution shown in FIG. 25 can be easily changed by calculation. Therefore, in the fifth embodiment, unlike the combination setting unit 36 in the first to fourth embodiments, it is not necessary to prepare a table other than the basic table, which leads to a significant reduction in the memory of the communication terminal 3. . Of course, the communication terminal according to the fifth embodiment can also be applied to the random selection of the time slot channel in the predetermined area E1 and the predetermined area E2 described in the third embodiment.

  The probability setting unit 56, based on the information outside the own terminal range from the determination processing unit 38, when the own terminal is within the range, sets the time slot on the earlier time side among the time slot channels within the selectable range. Probability distribution selection information for selecting a probability distribution for enabling random selection from the one is sent to the probability distribution storage unit 55. The probability distribution storage unit 55 selects the characteristic probability distribution characteristic of FIG. 25A and sends it to the combination selection unit 35. Probability distribution selection for selecting a probability distribution for allowing a time slot to be randomly selected from the time slot channels within the selectable range from the later time side when the terminal is out of range Information is sent to the probability distribution storage unit 55. The probability distribution storage unit 55 selects the characteristic probability distribution characteristic of FIG. 25C and sends it to the combination selection unit 35. When the own terminal is out of the range, a probability distribution for randomly selecting a time slot from time slot channels within the selectable range (random from the table shown in FIG. 8 or FIG. 9A). Probability distribution selection information for selecting (equivalent to selecting) may be sent to the probability distribution storage unit 55. In this case, the probability distribution storage unit 55 selects the characteristic probability distribution characteristic in FIG. 25B and sends it to the combination selection unit 35.

  As described above, the probability distribution storage unit 55 sends probability distribution characteristic information to the combination selection unit 35 from the probability distribution selection information sent from the probability setting unit 56. Since such an operation is performed, the combination selection unit 35 uses a table (FIG. 8 or FIG. 9A) to select a range for randomly selecting a channel (time slot channel) based on the probability distribution characteristic information from the probability setting unit 56. ) Can be changed. By using this method, when the communication terminal 3 that is its own terminal is present in a predetermined area (for example, in a disaster area), a slot channel with a relatively early time slot is preferentially selected, It is apparent from the probability distribution characteristic shown in FIG. 25 that a short message can be transmitted. That is, the function of the combination setting unit 36 (table storage unit 36) alone (including the function of the time slot setting unit 54 (second table storage unit 54)) in other embodiments is the probability distribution storage in the fifth embodiment. Unit 55 and probability setting unit 56 and the table storage unit 36 in the fifth embodiment (that is, the stored table itself is the table storage unit 36 only shown in FIG. 8 or FIG. 9A). It can be interpreted as an even higher function.

  In brief, the communication terminal according to Embodiment 5 includes a probability distribution storage unit 55 in addition to the probability setting unit 56. The probability setting unit 56 transmits the probability distribution selection information to the probability distribution storage unit 55 based on the own terminal range inside / outside information from the determination processing unit 38. For example, the probability setting unit 56 selects the characteristics shown in FIG. 25A when the own terminal is within the range, and selects FIG. 25B when it is unclear whether the own terminal exists inside or outside the range. If the terminal does not exist within the range, FIG. 25 (c) is selected. The probability distribution storage unit 55 transmits the probability distribution characteristic for the time slot channel according to the probability distribution selection information from the probability setting unit 56. The combination selection unit 35 selects a time slot channel according to the characteristics of the probability distribution from the probability distribution storage unit 55. Thereby, for example, when the own terminal exists in the range, the selection probability of the relatively early time slot channel can be increased.

  When a time slot is selected under the probability distribution characteristic using FIG. 8 (FIG. 9A) for the basic table, the selection number is selected because the time slot is selected. Naturally, a spread code channel (orthogonal code channel) and a frequency channel are determined. That is, the combination selection unit 35 randomly selects one of the combinations of the spread code channel, the frequency channel, and the time slot channel. Further, the combination selection unit 35 transmits the selected spreading code channel to the orthogonal code generation unit 9, transmits the selected frequency channel to the FDM processing unit 13, and transmits the selected time slot channel to the TDM processing unit 12. On the other hand, when a time slot is selected based on the probability distribution characteristics using FIG. 21B (FIG. 22B) as a basic table, the spread code channel (orthogonal code channel) and the frequency channel are stored in the table. In addition, since it is separated from the time slot, the spreading code channel (orthogonal code channel) and the frequency channel may be selected at random from FIG. 21 (a) (FIG. 22 (a)).

  In the communication terminal according to the fifth embodiment (particularly, the communication terminal 3 described in FIG. 24), the reception unit 6 acquires information on a predetermined area from the received forward link signal, and the random selection unit 10 When there is a communication terminal 3 having the random selection unit 10 in the area, a time slot that is a basis of a time for which the transmission unit 7 delays transmission data is compared with a case where the communication terminal 3 is not. Random selection unit 10 selects a time slot channel from those on the earlier time side, and random selection unit 10 has a communication terminal 3 having random selection unit 10 outside a predetermined area, and a case where it is not Thus, the transmission unit 7 randomly selects a time slot as a basis for delaying transmission data from among the time slot channels within the selectable range from those on the slow time side. It can be said that.

Embodiment 6 FIG.
Embodiment 6 of the present invention will be described with reference to FIG. In the first to fifth embodiments, the communication terminal 3 (communication system) is based on the premise that the return link signal is transmitted only once when there is no need for retransmission or re-transmission. in the communication terminal 3 (a communication system), over the first plurality of times, explaining what to send return link signal. Therefore, in the sixth embodiment, description regarding the same parts as in the first to fifth embodiments may be omitted. For this reason, since it demonstrates using the flowchart of FIG.26 and FIG.27 as a communication method which concerns on Embodiment 6, description of the structure of the communication terminal which concerns on Embodiment 6, a base station, and a communication system is abbreviate | omitted.

  Since the configurations of the communication terminal, base station, and communication system according to Embodiment 6 are the same as the configurations of the communication terminal, base station, and communication system according to Embodiments 1 to 5, as described above, Embodiment 6 The communication method according to the above will be mainly described. Specifically, in the communication methods according to the first to fifth embodiments, the processing steps of S101, S102, S103, S109 to S112, and S114 described with reference to FIGS. 5 and 11 have been described. Such a communication method further includes processing steps of S107, S108, and S113. The operation of the communication terminal 3 is basically the operation of the random selection unit 10. In FIG. 26 and FIG. 27, “S” means a processing step, and the initial of STEP is described.

  In S104 shown in FIG. 26, the determination processing unit 38 determines whether the position of the own terminal is within the range from the own terminal position information from the position information obtaining unit 37, or the own terminal position from the position information obtaining unit 37. From the information and range information from the broadcast information acquisition unit 39, it is determined whether or not the position of the own terminal is within the range. Next, in S105, the number of combinations of time slot channel, spreading code channel, and frequency channel for transmitting short message data, that is, the number n of channel combinations (n is a positive integer) is set to 1 by random access. . This is because the position of the own terminal is not within the range, that is, the communication terminal 3 that is in the predetermined area, the possibility of successful communication is within the range, that is, within the predetermined area. It is because it is not necessary to make it higher than the communication terminal 3 in which it is contained. Note that the number of channel combinations means the number of combinations of access methods (one spreading code channel, one time slot channel, and one frequency channel). For example, when the table shown in FIG. 8 is used in the random selection unit 10, if the number of channel combinations is n, n selection numbers shown in FIG. 8 are selected.

  In S106, when the position of the own terminal is within the range, in order to increase the possibility of successful communication, the number of channel combinations n is set to a plurality in S107, and in S108, the time slot channel is selected in an earlier time. Set to increase the probability of becoming. In S106, if the position of the terminal is out of range, S107 and S108 are skipped.

  Next, after passing through the processing steps of S109 to S112, in S113, it is determined whether the channel combination of the spread code channel, the frequency channel, and the time slot channel has been selected by the number n of channel combinations. If not, the process returns to S109. . If it is selected, the process proceeds to S114.

  In S114, the data is transmitted to the satellite 1 via the satellite communication antenna 3s as a CDMA / FDMA / TDMA signal by n combinations of the access methods selected and determined by the random selection unit 10. The number of transmissions is n times, which is the number of combinations. This is CDMA spread by the spreading code channel selected in the spreading code channel selection step at the frequency corresponding to the time slot channel selected in the time slot channel selection step and the frequency channel selected in the frequency channel selection step. It can be said that the transmission step of transmitting the transmitted data is performed n times.

  As described above, in the sixth embodiment, the combination setting unit 36 sets the number of combinations to a plurality when the position of the own terminal is within a specific range (predetermined area) in accordance with the own terminal range inside / outside information. Is transmitted to the combination selection unit 35. If the terminal exists in a disaster area or the like, the same message is transmitted a plurality of times by a combination of a plurality of channels so that the short message can surely reach the service center. It is to make it. In addition, the combination selection unit 35 (probability setting unit 56 in the fifth embodiment) determines a relatively early time when the position of the own terminal is within a specific range (predetermined region) according to the own terminal range inside / outside information. The setting information for increasing the selection probability of the slot channel is transmitted to the combination selection unit 35. This is because the probability that a relatively early time slot can be selected is increased as soon as possible when the own terminal exists in a disaster area or the like. This is so that the short message can reach the service center.

  FIG. 27 shows a method of randomly selecting one of the combinations of the spread code channel, the frequency channel, and the time slot channel or the number n of channel combinations set by the combination setting unit 36 in the random selection unit 10 of the communication terminal 3. FIG. S201, S202, and S203 are the same as those in FIG. In S201 shown in FIG. 27, the random selection unit 10 randomly selects one from a plurality of spreading code channels. In S202, one of a plurality of frequency channels is randomly selected. In step S203, one of a plurality of time slot channels is randomly selected.

  In S304 shown in FIG. 27, the random selection unit 10 stores one set of the selected spreading code channel, frequency channel, and time slot channel in a memory (not shown) as one combination of access methods. In S <b> 305, the random selection unit 10 repeats S <b> 201 to S <b> 203 and S <b> 304 n times for the number of channel combinations set from the combination setting unit 36. Here, n is the same as that described in FIG. In S306, the random selection unit 10 notifies each unit of one or a plurality of combinations of access methods stored in the memory. Specifically, the spread code channel is notified to the orthogonal code generation unit 9, the frequency channel is notified to the FDM processing unit 13, and the time slot channel is notified to the TDM processing unit 12.

  As described above, the communication terminal 3 randomly selects a combination of a spread code channel, a frequency channel, and a time slot channel, and transmits transmission data to the satellite 1 as a CDMA / FDMA / TDMA signal. It is possible to suppress collision of data transmitted simultaneously by the communication terminals 3 and to increase the communication success probability, that is, the throughput. In addition, it is possible to obtain a communication method, a communication terminal, a base station, and a communication system that can prevent a communication line from falling into a congestion state.

1. Satellite (non-stationary satellite (quasi-zenith satellite)) 2. Base station 2s Satellite communication antenna (base station satellite communication antenna) 2t Base station transmitter 2r Base Station receiver, 3 .... Communication terminal (short message communication terminal), 3s ... Satellite communication antenna (communication terminal side satellite communication antenna), 3g ... GPS antenna, 4 .... GPS satellite, 5 .... Base Station transmitting unit, 6 ·· Receiving unit, 7 ·· Transmitting unit, 8 ·· Information acquiring unit, 9 ·· Orthogonal code generating unit (spreading code generating unit), 10 ·· Random selecting unit, 11 ·· CDMA spreading unit ... TDMA processing unit 13.. FDMA processing unit 14.. Terrestrial network 15 Satellite tracking control center 16 Service center 16 e Range information generation unit (range information conversion unit) 17 ..Forward link communication lines 18..Return link communication line, 19..GPS signal, 20..Duplexer, 21..Data output terminal (reception data), 22..Transmission data section, 23..Data input terminal (transmission data), 24. -Wireless receiver, 25-QPSK demodulator, 26-Error correction decoder, 27-TDM demultiplexer, 28-GPS receiver, 29-GPS signal processor, 30-Data generator, 31 ..Error correction encoding unit, 32 ..Transmission timing generation unit, 33 ..BPSK modulation unit, 34 ..Radio transmission unit, 35 ..Combination selection unit, 36 ..Combination setting unit (table storage unit), 37 ..Position information acquisition unit 38..Judgment processing unit 39..Broadcast information acquisition unit 40..Range information unit 41..Terrestrial interface unit 42..Data generation unit 43..TDM multiplexing , 44 .. Control information transmission unit, 45 .. Error correction coding unit, 46 .. QPSK modulation unit, 47 .. Wireless transmission unit (base station side transmission unit), 48 .. Duplexer (base station), 49. -Wireless receiver (base station side receiver), 50-CDMA despreader, 51-BPSK demodulator, 52-Error correction decoder, 53-Data processor, 54-Time slot setter ( (Second table storage unit), 55... Probability distribution storage unit, 56 .. probability setting unit.

Claims (5)

A communication system in which a base station and a plurality of communication terminals communicate via a satellite,
The base station has a base station transmitter that transmits a forward link signal to the plurality of communication terminals,
Wherein the plurality of terminals, a receiver for receiving a their respective, the forward link signal, as a trigger that the receiver receives the forward link signal, generated transmission data to CDMA spread, the CDMA spreading Information to obtain GPS information obtained from the satellite or the GPS satellite, and a transmission unit that delays the transmission data according to a time slot for transmitting the transmission data, converts the frequency of the delayed transmission data and transmits the data to the base station An orthogonal code generation unit that generates an orthogonal code used for CDMA spreading by the transmission unit based on an orthogonal code start timing generated from time information obtained from the GPS information and synchronized between the plurality of communication terminals A random code channel to be used by the orthogonal code generation unit is supplied and the transmission unit delays transmission data. That supplies to select a time slot channel underlying time randomly, the transmission unit have a random selection unit for supplying randomly select a frequency channel to frequency conversion,
The receiving unit obtains information of a predetermined area from the received forward link signal, and the random selection unit, if there is a communication terminal having the random selection unit in the predetermined area, if not In contrast, the probability that the transmission unit can select a time slot as a basis for delaying transmission data from an early time slot channel is increased, and the random selection unit places the random selection unit outside the predetermined region. A communication system that reduces the probability that a time slot on which the transmission unit delays transmission data can be selected from an early time slot channel when there is a communication terminal having the communication terminal and when the communication terminal is not . A communication system in which a base station and a plurality of communication terminals communicate via a satellite,
The base station has a base station transmitter that transmits a forward link signal to the plurality of communication terminals,
Each of the plurality of terminals CDMA spreads the generated transmission data triggered by the reception unit receiving the forward link signal and the reception unit receiving the forward link signal, and the CDMA spread transmission A transmission unit that delays data according to a time slot for transmitting data, frequency-converts the delayed transmission data and transmits the data to the base station, and an information acquisition unit that acquires GPS information obtained from the satellite or GPS satellite; An orthogonal code generation unit that generates an orthogonal code that is used for CDMA spreading by the transmission unit according to an orthogonal code start timing that is generated from time information obtained from the GPS information and synchronized between the plurality of communication terminals; The spreading code channel used by the orthogonal code generator is randomly selected and supplied, and the transmitter delays the transmission data. That supplies to select a time slot channel underlying time randomly, the transmission section and a random selection unit for supplying randomly select a frequency channel to frequency conversion,
The receiving unit obtains information of a predetermined area from the received forward link signal, and the random selection unit, if there is a communication terminal having the random selection unit in the predetermined area, if not In contrast, a time slot based on which the transmission unit delays transmission data is randomly selected from the earlier time slots among time slot channels within a selectable range, and the random selection unit When the communication terminal having the random selection unit is outside the predetermined area, the range in which the transmission unit can select the time slot on which the transmission unit delays transmission data with respect to the case where it is not A communication system that randomly selects one of the time slot channels in the time slot on the later time side . The communication system according to claim 1, wherein the random selection unit determines a position of the communication terminal from position information obtained from the GPS information . The receiver according to any one of claims 1, 2, and 3, wherein the receiving unit sets an area set based on a predetermined condition from position information indicated by one point indicated by position information obtained from the forward link signal as the predetermined area. The communication system in any one . The said receiving part makes the area | region set based on predetermined conditions from the positional information of two or more points which the information of the position obtained from the said forward link signal shows as the said predetermined area | region. 4. The communication system according to any one of 3 .

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