JP2020036065A - Radio system - Google Patents

Abstract

To provide a relay method which allows frequency selection control for one multi frequency radio from multiple terminals.SOLUTION: In a radio system having multiple terminals, a sharing wave controller and a multi frequency radio, where the multi frequency radio is shared by the multiple terminals, the multiple terminals can transmit a frequency changeover request signal and a frequency selection signal. Upon receiving the frequency changeover request signal from any one of the multiple terminals, the sharing wave controller transmits the frequency selection signal, received from the first terminal, to the multi frequency radio. Upon receiving the frequency selection signal from the first terminal, the multi frequency radio changes over the use frequency on the basis of the frequency selection signal. The sharing wave controller relays communication between the first terminal and a radio communication apparatus, by using radiocommunication of the multi frequency radio and the radio communication apparatus using the use frequency after changeover.SELECTED DRAWING: Figure 2

Description

  The present invention relates to wireless systems.

  In recent years, various communication systems have been known. For example, a one-to-many communication system has been disclosed (for example, see Patent Document 1). In such a communication system, even if there are a large number of receiving devices, one transmitting device transmits an ID code and a strobe signal to transmit data to one specific receiving device to which an ID code is assigned. can do. Further, it is described that a control unit switches a wireless band of a multi-band wireless device to a wireless communication unit for each band using three types of signals of data, clock, and strobe (for example, Patent Document 2). reference.).

JP-A-04-189047 JP 2004-274097 A

  An air traffic control system is an example of a communication system. By the way, the operation mode of the air traffic control system has been changed, and it has become necessary to operate the air traffic control system installed in each of a plurality of government offices using one multi-frequency radio. However, in the conventional technology, since the connection between the air traffic control system and the multi-frequency radio is in a one-to-one relationship, it is possible to perform selection control of the frequency used by one multi-frequency radio from a plurality of government offices. Have difficulty.

  Therefore, it is desired to provide a technique that enables a plurality of terminals to perform frequency selection control on one multi-frequency wireless device.

  In order to solve the above problem, according to an aspect of the present invention, a radio including a plurality of terminals, a shared wave control device, and a multi-frequency radio, wherein the multi-frequency radio is shared by the plurality of terminals. In the system, each of the plurality of terminals can transmit a frequency switching request signal and a frequency selection signal, and the shared wave control device transmits a frequency switching request signal from a first terminal of any of the plurality of terminals. When receiving the frequency selection signal from the first terminal, the multi-frequency radio transmits the frequency selection signal received from the first terminal to the multi-frequency radio. And the shared wave control device performs wireless communication between the multi-frequency wireless device and the wireless communication device using the switched used frequency. Using, relays communication between the first terminal and the wireless communication device, a wireless system is provided.

  The frequency switching request signal is a pulse signal, the shared wave control device, at the timing when the pulse signal transitions from ON to OFF, a frequency selection signal to be transmitted to the multi-frequency radio from the first terminal The received frequency selection signal may be determined.

  The shared wave control device is input from a second terminal different from the first terminal among the plurality of terminals until a predetermined time elapses from the timing when the pulse signal transitions from ON to OFF. The frequency switching request signal may be invalidated.

  The shared wave control device, when receiving a frequency switching request signal from any one of the plurality of terminals, converts the number of bits of the frequency selection signal received from the first terminal, the number of bits The converted frequency selection signal may be transmitted to the multi-frequency radio.

  The multi-frequency wireless device, when receiving a voice from the wireless communication device using wireless communication using the used frequency after switching, outputs the voice as a received voice to the shared wave control device, the second When a voice is input from one terminal, the voice may be transmitted to the wireless communication device as transmission voice using wireless communication using the used frequency after switching.

  As described above, according to the present invention, a plurality of terminals can perform frequency selection control for one multi-frequency wireless device.

FIG. 11 is a diagram illustrating a configuration example of a conventional system. FIG. 1 is a diagram illustrating a configuration example of a system according to an embodiment of the present invention. It is a block diagram showing the example of functional composition of the control console concerning the embodiment. FIG. 3 is a block diagram showing a functional configuration example of the shared wave control device according to the embodiment. FIG. 3 is a block diagram illustrating a functional configuration example of the multi-frequency wireless device according to the embodiment. FIG. 3 is a diagram illustrating a functional configuration example of a frequency selection processing unit according to the embodiment. It is a code conversion correspondence table of a 4-bit frequency selection signal and a 10-bit frequency selection signal. FIG. 7 is a diagram illustrating operation timings of a frequency selection processing unit.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the specification and the drawings, components having substantially the same function and configuration are denoted by the same reference numerals, and redundant description is omitted.

  In this specification and the drawings, a plurality of components having substantially the same or similar functional configuration are distinguished from each other by the same reference numerals followed by different numbers. Further, similar components in different embodiments are distinguished by adding different alphabets to the same reference numerals. However, when it is not necessary to particularly distinguish each of a plurality of components having substantially the same functional configuration, only the same reference numerals are given.

(0. Outline)
First, an outline of an embodiment of the present invention will be described. In the air traffic control system, a multi-frequency radio having one radio using a plurality of transmission / reception frequencies is used for emergency use when performing radio communication with an aircraft. The air traffic control system can perform radio communication with an aircraft by switching the frequency of a multi-frequency radio device by a frequency selection operation from a control console. An embodiment of the present invention relates to a control process for sharing one multi-frequency radio from a plurality of different government offices performing air traffic control.

  FIG. 1 shows a conventional system configuration. In a conventional air traffic control system 802, a voice exchange device 804 and a multi-frequency radio 807 installed in a public office A (800) are connected in a one-to-one relationship. The multi-frequency radio 807 can switch and use ten types of frequencies. In the air traffic control system 802, the voice exchange device 804 and the multi-frequency radio 807 include a transmission voice signal, a reception voice signal, a PTT signal (short for push-to-talk signal), a frequency selection signal (CH1 to CH10), It is connected by each signal line of the selection state signal (CH1 to CH10).

  The voice exchange device 804 selects one of ten frequencies assigned to the multi-frequency radio 807 by a frequency selection operation (by the controller 801) from the control console 803. Then, the voice exchange apparatus 804 turns on only one bit corresponding to the selected frequency in the 10-bit frequency selection signal transmitted to the multi-frequency radio 807. Thus, the multi-frequency wireless device 807 can switch the frequency used for wireless communication with the aircraft 150 to a frequency corresponding to the bit that has been turned ON.

  The multi-frequency radio 807 turns on one bit corresponding to the currently selected frequency in the 10-bit frequency selection status signal transmitted to the voice switching device 804. As a result, the multi-frequency wireless device 807 notifies the voice exchange device 804 of the result of switching the frequency (the currently selected frequency). The voice switching device 804 receives the frequency selection state signal from the multi-frequency wireless device 807 and notifies the control console 803 of the frequency selection information. Thereby, the control console 803 can recognize which frequency is currently used.

  The operation mode of the air traffic control system 802 has been changed, and it has become necessary to operate the air traffic control system installed at each of a plurality of government offices using one multi-frequency radio 807. However, in the related art, since the connection between the air traffic control system 802 and the multi-frequency radio 807 is in a one-to-one relationship, the selection control of the frequency used by one multi-frequency radio 807 from a plurality of government offices is performed. Difficult to do. Also, the multi-frequency radio 807 continues to use the radio currently being used. Therefore, it is necessary to inherit the alternative frequency selection method using 10 bits (a method of turning ON only one bit corresponding to the selected frequency in the 10-bit frequency selection signal) which is the conventional interface.

  Therefore, in the embodiment of the present invention, in the air traffic control system 802, a shared use that enables frequency selection control for one multi-frequency radio 807 from a plurality of government offices without changing the interface specification with the multi-frequency radio 807. We mainly propose the control method.

  The outline of the embodiment of the present invention has been described above.

(1-1. System Configuration)
Subsequently, a configuration example of a system (wireless system) according to the embodiment of the present invention will be described. FIG. 2 shows a configuration example of a system according to the embodiment of the present invention. Referring to FIG. 2, the public office A (100) includes an air traffic control system 102, a data transmission device 105, a shared wave control device 106, and a multi-frequency radio 107. The air traffic control system 102 includes a control console 103 (terminal) and a voice exchange device 104. On the other hand, the government office B (200) includes an air traffic control system 202 and a data transmission device 205. The air traffic control system 202 includes a control console 203 (second terminal) and a voice exchange device 204. Referring to FIG. 2, various signals used by the system according to the embodiment of the present invention are shown.

  The transmission audio signal 110 is a signal in which a sound emitted by the controller 101 is input by a microphone or the like of the control console 103. The transmission voice signal 110 is input as a transmission voice signal 120 from the control console 103 to the shared wave control device 106 via the voice switching device 104. On the other hand, the PTT signal 111 is a signal in which ON (ON state) or OFF (OFF state) is input by the controller 101 using a button of the control console 103 or the like. The PTT signal 111 is input as a PTT signal 121 from the control console 103 to the shared wave control device 106 via the voice exchange device 104.

  When the PTT signal 121 is turned on before the PTT signal from another government office, the transmission sound signal 120 and the PTT signal 121 are converted to the transmission sound signal 140 and the PTT signal 141 by the shared wave control device 106. Output to multi-frequency radio 107. On the other hand, when the PTT signal 121 is turned on after the PTT signal from another government office, the transmission sound signal 120 and the PTT signal 121 are multiplexed as the transmission sound signal 140 and the PTT signal 141 by the shared wave control unit 106. It is not output to the frequency radio 107.

  When transmitted voice signal 140 and PTT signal 141 are output to multi-frequency radio 107, they are transmitted to aircraft 150 (wireless communication device of aircraft 150) by wireless communication, and received by aircraft 150 (wireless communication device of aircraft 150). Is done. The currently selected frequency is used for such wireless communication.

  The received audio signal 142 is an audio signal transmitted from the aircraft 150 (the wireless communication device of the aircraft 150) by wireless communication, received by the multi-frequency radio 107, and output from the multi-frequency radio 107. The currently selected frequency is used for such wireless communication. The received voice signal 142 is output from the multi-frequency wireless device 107 via the shared wave control device 106 to the voice switching device 104 of the air traffic control system 102 of the government office A (100) as the received voice signal 122. The voice exchange device 104 performs voice route control for outputting the received voice signal 122 from the control console 103 as the received voice signal 112. As a result, the received audio signal 112 is output from the headphones or speakers of the control console 103 according to the audio path control, and is supplied to the controller 101.

  The received audio signal 142 is also output from the multi-frequency radio 107 via the shared wave control device 106 to the data transmission device 105 as a received audio signal 132. Then, the received voice signal 132 is output as the received voice signal 222 to the voice exchange device 204 of the air traffic control system 202 of the government office B (200) via the data transmission device 105, the network, and the data transmission device 205. The voice exchange device 204 performs voice route control for outputting the received voice signal 222 from the control console 203 as the received voice signal 212. As a result, the received voice signal 212 is output from the headphone or speaker of the control console 203 according to the voice route control, and is supplied to the controller 201.

  The incoming call display 113 is a display for notifying the controller 101 that the received voice signal 122 has been input to the air traffic control system 102. Specifically, when the received voice signal 122 is input to the control console 103 from the voice exchange device 104 of the air traffic control system 102, the incoming call display 113 indicating that the received voice signal 122 has been input to the control console 103 is displayed. Output by The incoming call display 113 allows the controller 101 to recognize that a call from the aircraft 150 has been made.

  Note that the received voice signal 122 is input to the air traffic control system 102 and the received voice signal 222 is also input to the air traffic control system 202. When the received voice signal 222 is input from the voice exchange device 204 of the air traffic control system 202 to the control console 203, an incoming call display 213 indicating that the received voice signal 222 has been input to the control console 203 is output by the control console 203. . From the incoming call display 213, the controller 201 can recognize that there is a call from the aircraft 150.

  The other government office busy display 123 is a signal indicating that the transmission audio signal output from the other government office is being output from the shared wave control device 106 to the multi-frequency wireless device 107. For example, when the transmission audio signal 130 output from the public office B (200) is output as the transmission audio signal 140 from the shared wave control device 106 to the multi-frequency wireless device 107, the other public office busy display 123 is displayed. The signal is output from the wave control device 106 to the air traffic control system 102. When the other government office busy display 123 is input from the voice exchange device 104 to the control console 103, the control console 103 outputs another government office busy display 114.

  The frequency selection state signal 144 is a 10-bit signal indicating the frequency (one type) currently used by the multi-frequency radio 107, and is input from the multi-frequency radio 107 to the shared wave control device 106. The frequency selection state signal 144 is converted from the 10-bit frequency selection state signal 144 into the 4-bit frequency selection state signal 126 by the shared wave control device 106. When the frequency selection state signal 126 is input from the shared wave control device 106 to the voice exchange device 104 of the air traffic control system 102 of the government office A (100), it is output to the control console 103, and is output as frequency selection information 116 by the control console 103. Is displayed. As a result, the controller 101 of the government office A (100) can recognize which frequency is currently selected among the ten types of frequencies allocated to the multi-frequency wireless device 107.

  The frequency selection status signal 126 is input from the shared wave control device 106 to the voice switching device 104, and the frequency selection status signal 136 (similar to the frequency selection signal 125) is transmitted to the air traffic control system of the government office B (200). The data is input to a voice exchange device 204 at 202. The frequency selection state signal 136 is output from the voice exchange device 204 to the control console 203 and displayed as frequency selection information 216 by the control console 203. Thereby, the controller 201 of the government office B (200) can recognize which frequency is currently selected from the ten types of frequencies allocated to the multi-frequency radio 107.

  The frequency selection operation 115 is information (including at least information indicating which frequency was selected) obtained by the controller 101 operating a switch or the like mounted on the control console 103. The controller 101 selects only one of the ten frequencies (CH1 to CH10) assigned to the multi-frequency wireless device 107 by the frequency selection operation 115. When the frequency selection operation 115 is performed by the controller 101, the frequency selection operation 115 is output from the control console 103 to the voice exchange device 104.

  The frequency switching request signal 124 and the 4-bit frequency selection signal 125 are generated by the voice switching device 104 based on the frequency selection operation 115 and output to the shared wave control device 106. These two signals are unique to the embodiment of the present invention because they are not generated by the conventional system. The frequency switching request signal 124 is a timing signal for determining the frequency selection signal 125 transmitted from the air traffic control system 102 to the shared wave control device 106, and is a one-second pulse signal. The frequency selection signal 125 is a 4-bit code signal corresponding to ten kinds of frequencies allocated to the multi-frequency wireless device 107.

  The control console 203 and the voice exchange device 204 of the government office B (200) have the same functions as the control console 103 and the voice exchange device 104 of the air traffic control system 102 of the government office A (100). FIG. 2 shows various signals input from the controller 201 to the control console 203 as a transmission audio signal 210, a PTT signal 211, and a frequency selection operation 215. Various signals output from the control console 203 to the controller 201 are shown as a received voice signal 212, an incoming call display 213, an in-use office display 214, and frequency selection information 216.

  Here, a functional configuration example of a main device will be described. Specifically, an example of a functional configuration of the control console 103 will be described with reference to FIG. 3, an example of a functional configuration of the shared wave control device 106 will be described with reference to FIG. A functional configuration example of the frequency wireless device 107 will be described.

  FIG. 3 is a block diagram illustrating a functional configuration example of the control console 103 according to the embodiment of the present invention. As shown in FIG. 3, the control console 103 according to the embodiment of the present invention includes an input unit 1031, a control unit 1032, a storage unit 1033, a signal input / output unit 1034, and an output unit 1035.

  The input unit 1031 receives various information input from the controller. Further, the input unit 1031 provides the control unit 1032 with various information input from the controller. In the embodiment of the present invention, the input unit 1031 includes a microphone to which a transmission audio signal is input, a switch or touch input display (TID) used for frequency selection operation, a button used for push-to-talk, and the like. It is comprised including. However, what kind of hardware the input unit 1031 is specifically implemented with is not particularly limited.

  The control unit 1032 has a function of controlling the entire operation of the control console 103. The control unit 1032 may be configured by dedicated hardware, or may be realized by a CPU built in the control console 103 expanding a program stored in the ROM into the RAM and executing the program. In addition to providing such a program, a storage medium storing such a program may also be provided.

  The storage unit 1033 can store programs and data for operating the control unit 1032. Further, the storage unit 1033 can also temporarily store various data required during the operation of the control unit 1032.

  The signal input / output unit 1034 is an input / output interface for transmitting and receiving various signals to and from the voice exchange device 104 by wire or wirelessly. For example, the signal input / output unit 1034 can function as a signal input unit that inputs various signals from the voice exchange device 104. In addition, the signal input / output unit 1034 can function as a signal output unit that outputs various signals to the voice exchange device 104.

  The output unit 1035 has a function of outputting various types of information according to the control of the control unit 1032. Specifically, output unit 1035 includes a display that displays information according to control by control unit 1032. The display may be a CRT (Cathode Ray Tube) display device, a liquid crystal display (LCD) device, an OLED (Organic Light Emitting Diode) device, a lamp, or the like. The output unit 1035 includes a headphone or a speaker that outputs a received audio signal under the control of the control unit 1032.

  FIG. 4 is a block diagram illustrating a functional configuration example of the shared wave control device 106 according to the embodiment of the present invention. As shown in FIG. 4, the shared wave control device 106 according to the embodiment of the present invention includes a signal input / output unit 1061, a control unit 1062, and a storage unit 1063.

  The signal input / output unit 1061 is an input / output interface for transmitting and receiving various signals to and from the voice exchange device 104 and the multi-frequency wireless device 107 by wire or wirelessly. For example, the signal input / output unit 1061 can function as a signal input unit that inputs various signals from the voice exchange device 104 and the multi-frequency wireless device 107. Further, the signal input / output unit 1061 can function as a signal output unit that outputs various signals to the voice exchange device 104 and the multi-frequency wireless device 107.

  The control unit 1062 has a function of controlling the entire operation of the shared wave control device 106. The control unit 1062 may be configured by dedicated hardware, or may be realized by a CPU incorporated in the shared wave control device 106 expanding a program stored in the ROM into the RAM and executing the program. In addition to providing such a program, a storage medium storing such a program may also be provided.

  The storage unit 1063 can store programs and data for operating the control unit 1062. Further, the storage unit 1063 can also temporarily store various data required in the course of the operation of the control unit 1062.

  FIG. 5 is a block diagram illustrating a functional configuration example of the multi-frequency wireless device 107 according to the embodiment of the present invention. As shown in FIG. 5, the multi-frequency wireless device 107 according to the embodiment of the present invention includes a control unit 1071, a signal input / output unit 1072, a storage unit 1073, and a wireless communication unit 1074.

  The control unit 1071 has a function of controlling the entire operation of the multi-frequency wireless device 107. The control unit 1071 may be configured by dedicated hardware, or may be realized by a CPU incorporated in the multi-frequency wireless device 107 expanding a program stored in a ROM into a RAM and executing the program. In addition to providing such a program, a storage medium storing such a program may also be provided.

  The signal input / output unit 1072 is an input / output interface for transmitting / receiving various signals to / from the shared wave control device 106 by wire or wirelessly. For example, the signal input / output unit 1072 can function as a signal input unit that inputs various signals from the shared wave control device 106. The signal input / output unit 1072 can function as a signal output unit that outputs various signals to the shared wave control device 106.

  The storage unit 1073 can store programs and data for operating the control unit 1071. The storage unit 1073 can also temporarily store various data required in the course of the operation of the control unit 1071.

  The wireless communication unit 1074 has a function of performing wireless communication with the aircraft 150 (the wireless communication device of the aircraft 150). For example, the wireless communication unit 1074 includes a communication circuit and an antenna for performing wireless communication. The wireless communication unit 1074 performs wireless communication with the aircraft 150 (the wireless communication device of the aircraft 150) using the currently selected frequency.

  Returning to FIG. The data transmission device 105 performs data transmission (data transmission / reception) with the data transmission device 205 installed in the government office B (200). For example, when the data transmission apparatus 105 receives the transmission voice signal 220, the PTT signal 221, the frequency switching request signal 224, and the frequency selection signal 225 from the government office B (200) via a network or the like, the transmission voice signal 130, It outputs to the shared wave control device 106 as the PTT signal 131, the frequency switching request signal 134, and the frequency selection signal 135.

  In addition, when the data transmission device 105 receives the received voice signal 132, the display 133 indicating that another government office is being used, and the frequency selection state signal 136 from the shared wave control device 106, the data transmission device 105 receives the received voice signal 222, the display 223 that indicates that another government office is being used, and The status signal 226 is transmitted to the data transmission device 205 of the government office B (200) via a network or the like.

  The data transmission device 205 performs data transmission (data transmission / reception) with the data transmission device 105 installed in the government office A (100). For example, when the data transmission device 205 receives the transmission voice signal 220, the PTT signal 221, the frequency switching request signal 224, and the frequency selection signal 225 from the voice switching device 204, the data transmission device 205 transmits the signal to the government office A (100) via a network or the like. I do.

  Further, when the data transmission apparatus 205 receives the received voice signal 132, the in-use display 133 and the frequency selection status signal 136 from the government office A (100) via a network or the like, the data transmission apparatus 205 receives the received voice signal 222 and the other government office. It outputs to the voice exchange device 204 as the busy display 223 and the frequency selection status signal 226.

  The shared wave control device 106 is used for the air traffic control system 102 installed in the public office A (100) and the air traffic control system 202 installed in the public office B (200) to share one multi-frequency radio 107. Perform control. Further, the shared wave control device 106 performs frequency switching control based on a frequency switching request signal 124 from the air traffic control system 102 and a frequency switching request signal 134 from the air traffic control system 202.

  Specifically, when the shared wave control device 106 receives the frequency switching request signal 124 from the air traffic control system 102 under predetermined conditions, the shared wave control device 106 The frequency selection signal 125 is determined. The predetermined condition will be described later in detail. The shared wave control device 106 converts the 4-bit frequency selection signal 125 into a 10-bit frequency selection signal, which is the same interface as the conventional one, and sends the 10-bit frequency selection signal to the multi-frequency radio 107. 143 is output.

  In the embodiment of the present invention, the shared wave control device 106 receives the frequency switching request signal 124 and the frequency selection signal 125 from the government office A (100), and receives the frequency switching request signal 224 and the frequency from the government office B (200). The selection signal 225 is received via the data transmission device 105. Then, the shared wave control device 106 gives the priority of frequency control to the one of the two government offices that outputs the frequency switching request signal first, and validates the frequency selection signal from the government office to which the priority has been given. As a result, even when frequency selection signals are output from a plurality of government offices, it is possible to control the frequency used by the multi-frequency wireless device 107.

  The configuration example of the system (wireless system) according to the embodiment of the present invention has been described above. Control of the frequency used by the multi-frequency wireless device 107 can be mainly realized by the frequency selection processing unit 300 (FIG. 6). For example, the frequency selection processing unit 300 can be incorporated in the control unit 1062 of the shared wave control device 106. Hereinafter, details of frequency control by the frequency selection processing unit 300 will be mainly described.

(1-3. Operation of Frequency Selection Processing Unit)
Subsequently, frequency control by the frequency selection processing unit 300 according to the embodiment of the present invention will be described. FIG. 6 shows a functional configuration example of the frequency selection processing unit 300. As shown in FIG. 6, the frequency selection processing unit 300 includes a switching request competition processing unit 301, a selector unit 302, a 4-bit to 10-bit code conversion unit 303, and a 10-bit to 4-bit code conversion unit 304.

  The switching request competition processing unit 301 constantly monitors the frequency switching request signal 124 from the government office A and the frequency switching request signal 134 from the government office B, and generates a frequency selection signal of either the government office A or the government office B by the alternative competition control. Decide whether to enable it. These frequency switching request signals are pulse signals generated by the voice exchange device 104 so as to be turned on for one second and then turned off when a frequency selection operation (frequency switching selection operation) is performed. On the other hand, the frequency selection signal is a signal controlled by the voice exchange device 104 so as to indicate a frequency corresponding to the frequency selection operation.

  The switching request conflict processing unit 301 determines whether there is a frequency switching request signal that has transitioned from ON to OFF among the frequency switching request signal 124 input from the government office A and the frequency switching request signal 134 input from the office B. Then, the selector unit 302 selects the frequency selection signal input from the government office that transmitted the frequency switching request signal at the falling timing of the frequency switching request signal that has transitioned from ON to OFF. As a result, the selector 302 determines the 4-bit frequency selection signal.

  The 4-bit to 10-bit code conversion unit 303 converts the 4-bit frequency selection signal determined by the selector unit 302 into a frequency number corresponding to the 4-bit. Then, the 4-bit to 10-bit code conversion section 303 outputs a 10-bit frequency selection signal in which only one bit corresponding to the frequency number is turned ON, as a frequency selection signal to the multi-frequency wireless device 107. FIG. 7 shows a code conversion correspondence table between the 4-bit frequency selection signal and the 10-bit frequency selection signal.

  On the other hand, in the frequency selection state signal 144 input from the multi-frequency wireless device 107, only one bit corresponding to the currently selected frequency number in the 10-bit frequency selection state signal is ON. Therefore, the 10-bit to 4-bit code conversion unit 304 converts the 10-bit frequency selection state signal into a frequency number corresponding to one bit that is ON. Then, 10-bit → 4-bit code conversion section 304 outputs a 4-bit frequency selection state signal corresponding to the frequency number to air traffic control system 102 of public office A (100) and air traffic control system 202 of public office B (200). I do.

  In the embodiment of the present invention, the frequency switching request signal is set to a one-second pulse signal system, and one frequency switching is performed for one frequency selection operation. This makes it possible to perform frequency switching control in response to frequency selection operations from a plurality of government offices.

  Further, in the embodiment of the present invention, the switching request conflict processing unit 301 detects the frequency switching request signal and determines the frequency selection signal, and then transits to a state in which the frequency switching request signal from another government office is not accepted for one second. I do. By this processing, even when a frequency selection operation (frequency switching selection operation) is performed at the same time in different government offices, the priority of frequency control is given to the office where the frequency switching request signal is detected first. As a result, it is possible to avoid collision of a frequency selection operation (frequency switching selection operation) from a plurality of government offices, and control the sharing of the multi-frequency wireless device 107 from a plurality of government offices.

  At the office that lost the priority, the display on the control console is switched to the frequency specified by the office that obtained the priority (specifically, the frequency selection that indicates a frequency different from the frequency specified by the office that lost the priority) Information is displayed). Therefore, the controller of the government office that lost the priority can recognize from the display that the frequency selection operation (frequency switching selection operation) performed by the controller has not been effective, and if necessary, re-enter the frequency again. By performing a selection operation (frequency switching selection operation), the frequency can be switched.

  FIG. 8 shows the operation timing of the frequency selection processing unit 300. As shown in FIG. 8, when the frequency switching request signal input from the government office A is turned on first, the four-bit frequency selection signal input from the government office A is changed to the falling timing of the frequency switching request signal. Based on this, a 10-bit frequency selection signal is output. Similarly, when the frequency switching request signal input from the government office B is turned on first, the four bits input from the government office B at the falling timing of the frequency switching request signal (the timing of transition from ON to OFF). , A 10-bit frequency selection signal is output. For one second from the falling timing of the frequency switching request signal, the frequency switching request signal input from another government office is invalidated.

(2. Summary)
According to the present embodiment, a wireless system including the control console 103 and the control console 203, the shared wave control device 106, and the multi-frequency wireless device 107, wherein the control console 103 and the control console 203 share the multi-frequency wireless device 107 Is provided. Here, each of the control console 103 and the control console 203 can transmit a frequency switching request signal and a frequency selection signal. When receiving the frequency switching request signal from one of the terminals (first terminal) of control console 103 and control console 203, shared wave control device 106 multiplies the frequency selection signal received from the terminal (first terminal). The signal is transmitted to the frequency radio device 107.

  Further, when receiving the frequency selection signal from the terminal (first terminal), the multi-frequency wireless device 107 switches the used frequency based on the frequency selection signal. Then, shared wave control device 106 uses a wireless communication between multi-frequency wireless device 107 using the used frequency after switching and aircraft 150 (wireless communication device of aircraft 150) to communicate with a terminal (first terminal). It relays communication with the aircraft 150 (the wireless communication device of the aircraft 150).

  According to this configuration, in air traffic control, it is possible to share one multi-frequency wireless device from a plurality of government offices, which was difficult with the conventional system. More specifically, according to such a configuration, in air traffic control, it becomes possible to control switching of the frequency used by the multi-frequency radio in response to a request from each of a plurality of government offices.

(3. Modification)
As described above, the preferred embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited to such examples. It is obvious that those skilled in the art to which the present invention pertains can conceive various changes or modifications within the scope of the technical idea described in the claims. It is understood that these also belong to the technical scope of the present invention.

  For example, in the above, an example in which one multi-frequency wireless device 107 is shared by two public offices has been described. However, the number of government offices is not particularly limited as long as it is plural. For example, one multi-frequency radio may be shared by three or more government offices. In this case, in addition to the above-mentioned public offices A and B, a public office equivalent to the public office B is newly added, and the public office A has a function of transmitting and receiving data to and from the newly added public office. Should just be added.

  The specific numerical values described above are not particularly limited. For example, in the above description, an example has been described in which ten frequencies are used for wireless communication by the multi-frequency wireless device 107. However, the frequencies used for wireless communication by the multi-frequency wireless device 107 are not limited to ten types. Further, in the above, an example has been described in which the frequency switching request signal is a one-second pulse signal. However, the shape of the frequency switching request signal is not limited to such an example. For example, the pulse width of the pulse signal may be a time other than 1 second.

  In the above description, an example has been described in which a frequency switching request signal from another government office is not received for one second from the start of frequency switching (falling of the frequency switching request signal that has been turned ON first). However, the time during which a frequency switching request signal from another government office is not received is not limited to such an example. For example, the time during which a frequency switching request signal from another government office is not accepted may be a time other than 1 second from the start of frequency switching (falling of the frequency switching request signal that was previously turned ON).

  Further, in the above description, an example is shown in which the frequency selection signal output from the air traffic control system is 4 bits, and the frequency selection signal input to the multi-frequency wireless device 107 is 10 bits. However, the number of bits of each frequency selection signal is not limited. Similarly, an example has been described above in which the frequency selection state signal output from the multi-frequency wireless device 107 is 10 bits, and the frequency selection state signal input to the air traffic control system is 4 bits. However, the number of bits of each frequency selection state signal is not limited.

Reference Signs List 102 air traffic control system 103 control console 104 voice exchange device 105 data transmission device 106 shared wave control device 107 multi-frequency radio 150 aircraft 202 air traffic control system 203 control console 204 voice exchange device 205 data transmission device

Claims (5)

A wireless system having a plurality of terminals, a shared wave control device and a multi-frequency radio, wherein the multi-frequency radio is shared by the plurality of terminals,
Each of the plurality of terminals can transmit a frequency switching request signal and a frequency selection signal,
The shared wave control device, when receiving a frequency switching request signal from a first terminal of any of the plurality of terminals, transmits a frequency selection signal received from the first terminal to the multi-frequency radio,
The multi-frequency radio, when receiving the frequency selection signal from the first terminal, switching the frequency used based on the frequency selection signal,
The shared wave control device communicates between the first terminal and the wireless communication device using wireless communication between the multi-frequency wireless device and a wireless communication device using the used frequency after switching. Relay,
Wireless system. The frequency switching request signal is a pulse signal,
The shared wave control device determines a frequency selection signal to be transmitted to the multi-frequency wireless device to a frequency selection signal received from the first terminal at a timing when the pulse signal transitions from ON to OFF,
The wireless system according to claim 1. The shared wave control device is input from a second terminal different from the first terminal among the plurality of terminals until a predetermined time elapses from the timing when the pulse signal transitions from ON to OFF. Invalidate the frequency switching request signal,
The wireless system according to claim 2. The shared wave control device, when receiving a frequency switching request signal from any one of the plurality of terminals, converts the number of bits of the frequency selection signal received from the first terminal, the number of bits Transmitting the converted frequency selection signal to the multi-frequency radio,
The wireless system according to claim 1. The multi-frequency wireless device, when receiving a voice from the wireless communication device using wireless communication using the used frequency after switching, outputs the voice as a received voice to the shared wave control device, the second When a voice is input from one terminal, the voice is transmitted to the wireless communication device as a transmission voice using wireless communication using the used frequency after switching,
The wireless system according to claim 1.

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