JP2017098758A - Radio communication system and remote communication control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radio communication system that allows a mobile station radio device to keep transmittable and receivable frequencies in a radio communication area of a base station radio device and to automatically switches to a frequency which a movement destination base station radio device can receive if the mobile station radio device has moved into a radio communication area of another base station radio device.SOLUTION: A base station radio device 30 communicates signals with a mobile station radio device 40. A remote communication control device 10 includes a control unit 11 for controlling the base station radio device 30 to transmit a pilot signal PS with a prescribed frequency. The mobile station radio device 40 detects the pilot signal PS and keeps the prescribed frequency of the detected pilot signal PS as a reception frequency for a prescribed time. The control unit 11 controls the base station radio device 30 so that the base station radio device 30 will transmit the pilot signal PS at a shorter interval than a prescribed time.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a wireless communication system and a remote communication control device.

  The wireless communication system includes a base station wireless device and a mobile station wireless device. The base station radio apparatus and the mobile station radio apparatus transmit and receive signals including voice or data via radio waves.

  The base station radio apparatus has different frequencies (channels) that can be transmitted and received for each base station radio apparatus. Therefore, the mobile station radio device needs to be set to the frequency of the base station radio device in the radio communication area. However, it is difficult to easily determine which base station radio apparatus the mobile station radio apparatus is located in.

  Therefore, when a signal is transmitted from the mobile station radio device to the base station radio device, the mobile station radio device manually switches to a frequency that can be received by the base station radio device, or searches for the frequency. It is necessary to execute a scanning operation.

  Patent Literature 1 discloses a wireless communication system that performs a scan operation and searches for frequencies that can be received by a base station wireless device.

JP-A-9-121174

  However, in the wireless communication system as disclosed in Patent Document 1, no signal is detected even though the mobile station wireless device has not moved out of the wireless communication area of the base station wireless device. If the scan operation is re-executed in this state, the receivable frequency cannot be maintained.

  In addition, when the mobile station radio apparatus moves into the radio communication area of another base station radio apparatus, the mobile station radio apparatus manually performs a scan operation for searching for frequencies that can be received by the destination base station radio apparatus. It is necessary to execute with.

  In view of such a problem, the present invention maintains a frequency at which a mobile station radio apparatus can transmit and receive within a radio communication area of a base station radio apparatus and moves into a radio communication area of another base station radio apparatus. An object of the present invention is to provide a radio communication system and a remote communication control apparatus that can automatically switch to a frequency that can be received by a base station radio apparatus of a moving destination.

  The present invention includes a base station radio apparatus, a mobile station radio apparatus that transmits and receives signals between the base station radio apparatus, and a control unit that controls the base station radio apparatus to transmit a pilot signal having a predetermined frequency. The mobile station radio apparatus detects the pilot signal, maintains a predetermined frequency of the detected pilot signal as a reception frequency for a predetermined time, and the control unit includes the base station A radio communication system is provided that controls the base station radio apparatus so that a station radio apparatus transmits the pilot signal at an interval shorter than the predetermined time.

  The present invention further includes a control unit that controls the base station radio apparatus so that the base station radio apparatus that transmits and receives signals to and from the mobile station radio apparatus transmits a pilot signal having a predetermined frequency. The unit controls the base station radio apparatus to transmit the pilot signal at an interval shorter than a time during which the mobile station radio apparatus maintains the predetermined frequency at which the pilot signal is detected as a reception frequency. A remote communication control device is provided.

  According to the radio communication system and the remote communication control device of the present invention, the mobile station radio device maintains a frequency at which transmission and reception can be performed within the radio communication area of the base station radio device, and within the radio communication area of other base station radio devices. When moving, it is possible to automatically switch to a frequency that can be received by the destination base station radio apparatus.

It is a conceptual diagram which shows a radio | wireless communications system. It is a conceptual diagram which shows the radio | wireless communications system for demonstrating a remote communication control apparatus. It is a timing diagram for demonstrating the timing which a pilot signal is transmitted from a base station radio | wireless apparatus. It is a timing diagram for demonstrating the relationship between real call time and the timing which a pilot signal is transmitted from a base station radio | wireless apparatus. It is a conceptual diagram of the radio | wireless communications system for demonstrating the case where a remote communication control apparatus controls a some base station radio | wireless apparatus. It is a timing diagram for demonstrating the timing at which a pilot signal is transmitted from a some base station radio | wireless apparatus. It is a conceptual diagram for demonstrating the Example of a radio | wireless communications system.

[Wireless communication system]
A wireless communication system will be described with reference to FIG. FIG. 1 is a conceptual diagram illustrating a wireless communication system according to an embodiment.

  The wireless communication system 1 includes a remote communication control device 10, a remote communication device 20, a base station wireless device 30, and a mobile station wireless device 40. The remote communication control device 10, the remote communication device 20, and the base station wireless device 30 are connected by a predetermined communication network 2. The communication network 2 is an arbitrary communication network such as an Internet line or a telephone line.

  The number of the remote communication control device 10, the remote communication device 20, the base station radio device 30, and the mobile station radio device 40 is not limited to that shown in FIG. 1, but can be set to any number. . In FIG. 1, three base station radio apparatuses 30 are shown as a base station radio apparatus 31, a base station radio apparatus 32, and a base station radio apparatus 33.

  The remote communication control device 10 monitors and controls the base station wireless device 30 (31 to 33) via the communication network 2. The remote communication control device 10 is, for example, a general-purpose control device such as a computer or a wireless communication control device.

  The remote communication device 20 controls transmission / reception of the base station radio device 30 via the communication network 2, and further transmits a signal including voice or data to the mobile station radio device 40 via the base station radio device 30. The base station radio apparatus 30 receives a signal including voice or data received. The remote communication device 20 is a desktop communication terminal such as a telephone type.

  The remote communication control device 10 and the remote communication device 20 may be configured as one device.

  The base station radio apparatus 30 and the mobile station radio apparatus 40 transmit or receive signals including voice or data via radio waves. The base station radio apparatus 30 and the mobile station radio apparatus 40 communicate with each other by, for example, a half-duplex communication method. In addition, the mobile station wireless devices 40 communicate with each other using a half-duplex communication method. The base station radio device 30 is, for example, a stationary radio device. The mobile station radio device 40 is, for example, a handy radio.

[Remote communication control device]
The remote communication control device 10 will be described with reference to FIGS.

  FIG. 2 is a conceptual diagram showing a wireless communication system for explaining the remote communication control device 10. In order to make the explanation easy to understand, the same components as those in FIG.

  The remote communication control device 10 includes a control unit 11 and a call determination unit 12. The control unit 11 and the call determination unit 12 may each be configured by software (computer program), or may be configured by hardware such as an integrated circuit.

  The control unit 11 controls the base station radio apparatus 30 via the communication network 2 so that a pilot signal PS having a predetermined frequency is transmitted from the base station radio apparatus 30.

  FIG. 3 is a timing diagram for explaining the timing at which the pilot signal PS is transmitted from the base station radio apparatus 30.

  The control unit 11 causes the base station radio apparatus 30 to transmit the pilot signal PS at a predetermined interval (transmission interval) T2 (T1 <T2) within a predetermined time (transmission time) T1. To control.

  FIG. 4 is a timing diagram for explaining the relationship between the actual call time and the timing at which the pilot signal is transmitted from the base station radio apparatus 30.

  The call determination unit 12 determines whether or not the base station radio device 30 is actually communicating via the communication network 2. The control unit 11 controls transmission of the pilot signal PS of the base station radio device 30 based on the determination result of the call determination unit 12.

  Specifically, when it is determined that the base station radio apparatus 30 is in an actual call, the control unit 11 performs base station so that the base station radio apparatus 30 does not transmit the pilot signal PS as shown in FIG. The station radio apparatus 30 is controlled. Further, the control unit 11 controls the base station radio apparatus 30 so that the base station radio apparatus 30 transmits the pilot signal PS when it is determined that the base station radio apparatus 30 is not actually talking.

  FIG. 5 is a conceptual diagram showing a radio communication system for explaining a case where the remote communication control device 10 controls a plurality of base station radio devices 31 to 33. In order to make the description easy to understand, the same components as those in FIGS. 1 and 2 are denoted by the same reference numerals. In FIG. 5, pilot signals PS transmitted from three base station radio apparatuses 31, 32, and 33 are shown as pilot signals PS31, PS32, and PS33.

  FIG. 6 is a timing chart for explaining the timing at which pilot signals PS31 to PS33 are transmitted from a plurality of base station radio apparatuses 31 to 33.

  FIG. 6A shows the timing at which the pilot signal PS31 is transmitted from the base station radio apparatus 31. FIG. 6B shows the timing at which the pilot signal PS 32 is transmitted from the base station radio apparatus 32. FIG. 6C shows the timing at which the pilot signal PS33 is transmitted from the base station radio apparatus 33. Pilot signals PS31 to PS33 have different frequencies.

  When the remote communication control apparatus 10 controls a plurality of base station radio apparatuses 31 to 33, the control unit 11 does not overlap pilot signals PS31 to PS33 of the base station radio apparatuses 31 to 33, for example, as shown in FIG. As described above, the base station radio apparatuses 31 to 33 are controlled so as to shift the transmission timing of the pilot signals PS31 to PS33.

[Mobile station radio equipment]
The mobile station radio apparatus 40 receives a signal including voice or data transmitted from the base station radio apparatus 30 or another mobile station radio apparatus 40. The mobile station radio device 40 stops the scan operation at the reception frequency at which the received signal is detected by the scan operation. Therefore, when the mobile station radio apparatus 40 detects the pilot signal PS during the scan operation, the mobile station radio apparatus 40 sets the frequency of the detected pilot signal PS as a reception frequency and stops the scan operation.

  After stopping the scanning operation, the mobile station radio device 40 maintains the reception frequency set for a predetermined time T4 after the signal cannot be received.

  The predetermined time T4 is a timer time set in the mobile station radio apparatus 40. After stopping the scanning operation, the mobile station radio device 40 starts counting the timer when no received signal is detected. When the mobile station radio apparatus 40 receives a signal again during the time T4 during which the reception frequency is maintained, the timer is reset. Further, the mobile station radio device 40 resumes scanning when the time T4 elapses without detection of the received signal. Therefore, the mobile station radio device 40 maintains the reception frequency while receiving the signal, and the scan is resumed when the time T4 elapses after the reception signal is interrupted.

[Relationship with time]
The base station radio device 30 needs to transmit the pilot signal PS for a time that the mobile station radio device 40 can detect during the scanning operation. Therefore, it is desirable that the time T1 for the base station radio apparatus 30 to transmit the pilot signal PS is equal to or longer than the time T3 (T1 ≧ T3) required for the mobile station radio apparatus 40 to complete a scan. The round of scanning of the mobile station radio apparatus 40 is to scan all the frequencies to be scanned set in the mobile station radio apparatus 40. For this reason, since the scan makes a round during the time T1 during which the pilot signal PS is transmitted, there is always a timing at which the pilot signal PS can be detected.

  The interval T2 at which the base station radio apparatus 30 transmits the pilot signal PS is set to be shorter (T2 <T4) than the time T4 during which the mobile station radio apparatus 40 maintains the set frequency. The time T4 may be set so that T2 <T4 on the mobile station radio device 40 side.

  By setting T2 <T4, the pilot signal PS is received within the time T4 during which the set frequency is maintained. For this reason, the mobile station radio apparatus 40 maintains the set frequency during the period in which the pilot signal PS is continuously received.

[Example]
An embodiment of the wireless communication system will be described with reference to FIG.

  FIG. 7 is a conceptual diagram for explaining an embodiment of the wireless communication system. In order to make the explanation easy to understand, the same components as those in FIG.

  The wireless communication system 101 according to the embodiment includes a remote communication control device 10, a remote communication device 20, a plurality of base station wireless devices 31, 32, and 33, and a plurality of mobile station wireless devices 40.

  In FIG. 7, the mobile station radio devices 40 located in the area AR31 capable of transmitting and receiving with the base station radio device (first base station radio device) 31 are shown as mobile station radio devices 41a, 41b, and 41c. Mobile station radio devices 40 located in an area AR32 capable of transmitting and receiving with the base station radio device (second base station radio device) 32 are shown as mobile station radio devices 42a, 42b and 42c. Mobile station radio devices 40 located in an area AR33 capable of transmitting and receiving with the base station radio device (third base station radio device) 33 are shown as mobile station radio devices 43a, 43b and 43c.

  The base station radio device 31 and the mobile station radio devices 41a, 41b, 41c transmit or receive signals including voice or data on the first channel CH31 set to the first frequency f31. Accordingly, the remote communication control device 10 controls the base station radio apparatus 31 so that the base station radio apparatus 31 transmits the pilot signal PS31 having the first frequency f31.

  The base station radio device 32 and the mobile station radio devices 42a, 42b, and 42c transmit and receive signals including voice or data on the second channel CH32 set to the second frequency f32. Accordingly, the remote communication control device 10 controls the base station radio device 32 so that the base station radio device 32 transmits the pilot signal PS32 having the second frequency f32.

  The base station radio device 33 and the mobile station radio devices 43a, 43b, and 43c transmit or receive signals including voice or data on the third channel CH33 set to the third frequency f33. Accordingly, the remote communication control device 10 controls the base station radio device 33 so that the base station radio device 33 transmits the pilot signal PS33 of the third frequency f33.

  For example, the mobile station radio apparatus 41a receives the pilot signal PS31 from the base station radio apparatus 31 at a predetermined interval T2 in a state where the mobile station radio apparatus 41a is located in the area AR31 that can transmit and receive with the base station radio apparatus 31. The time T4 during which the mobile station radio apparatus 41a maintains the frequency is longer than the interval T2 at which the base station radio apparatus 31 transmits the pilot signal PS31. Therefore, the mobile station radio device 41a is maintained at the first frequency f31 (first channel CH31). The same applies to the mobile station radio devices 41b and 41c.

  When the mobile station radio apparatus 41a and the base station radio apparatus 31 are in actual communication, the pilot signal PS31 is not transmitted from the base station radio apparatus 31 as shown in FIG. For example, when the base station radio apparatus 31 is transmitting, the mobile station radio apparatuses 41 a, 41 b, 41 c receive a transmission wave during an actual call from the base station radio apparatus 31. Thereby, the mobile station wireless devices 41a, 41b, and 41c maintain the first frequency f31.

  Further, when the mobile station radio device 41a is transmitting, the mobile station radio devices 41b and 41c and the base station communication device 31 receive a transmission wave during an actual call from the mobile station radio device 41a. Thereby, the mobile station radio devices 41b and 41c maintain the first frequency f31, and the base station communication device 31 stops the transmission of the pilot signal PS31 during the actual call.

  The mobile station radio devices 42a, 42b, and 42c are located in the area AR32 that can transmit and receive with the base station radio device 32, and the mobile station radio devices 43a, 43b, and 43c can transmit and receive with the base station radio device 33. The same applies to the state of being located in the area AR33.

  For example, when the mobile station radio apparatus 41a moves from the area AR31 that can transmit and receive with the base station radio apparatus 31 to the area AR32 that can transmit and receive with the base station radio apparatus 32, first, the mobile station radio apparatus 41a has the first frequency f31. When the pilot signal PS31 (first channel CH31) or the actual call in the area AR31 cannot be received and the time T4 for maintaining the set reception frequency has elapsed, the scan is resumed.

  Next, when the mobile station radio device 41a detects the reception of the pilot signal PS32 of the base station radio device 32 or the actual call in the area AR32 during the scan, the frequency, that is, the second frequency f32 (second frequency Scanning stops at channel CH32). The mobile station radio apparatus 41a receives the pilot signal PS32 from the base station radio apparatus 32 at a predetermined interval T2 before T4 which is the scan resumption time. Accordingly, the mobile station radio device 41a maintains the second frequency f32 (second channel CH32) by receiving the pilot signal PS32 or receiving the actual call in the area AR32.

  With the above operation, the reception frequency can be automatically switched and maintained from the first frequency f31 (first channel CH31) to the second frequency f32 (second channel CH32).

  For example, as shown in FIG. 6, the remote communication control device 10 shifts the transmission timings of the pilot signals PS31 to PS33 so that the pilot signals PS31 to PS33 of the base station radio devices 31 to 33 do not overlap each other. Controls the base station radio devices 31-33.

  For example, the base station radio apparatus 32 transmits the pilot signal PS32 before the timing at which the base station radio apparatus 31 transmits the next pilot signal PS31. Thereby, when the mobile station radio apparatus 41a moves from the area AR31 to the area AR32, the mobile station radio apparatus 41a cannot receive the pilot signal PS31 and starts scanning, and before the timing at which the next pilot signal PS31 is transmitted. The pilot signal PS32 transmitted by the base station radio apparatus 32 in the area AR32 that is the destination is received. Therefore, the reception frequency can be switched from the first frequency f31 to the second frequency f32 in a short time.

  When the mobile station wireless device 41a moves from the area AR31 that can be transmitted / received to / from the base station wireless device 31 to the area AR33 that can be transmitted / received to / from the base station wireless device 33, The same applies to the case of moving to the area AR33 capable of transmitting and receiving with the device 33. The same applies to the case where the mobile station radio devices 41b, 41c, 42a, 42b, 42c, 43a, 43b, 43c move into an area where they can transmit and receive with other base station radio devices 30.

  According to the radio communication system 1 and the remote communication control device 10 of the present embodiment, the pilot signal PS from the base station radio device 30 is at an interval T2 shorter than the time T4 during which the mobile station radio device 40 maintains the set frequency. Sent. Thereby, the mobile station radio | wireless apparatus 40 can maintain the set frequency during the period when pilot signal PS is received continuously in the area.

  Further, according to the wireless communication system 1 and the remote communication control device 10 of the present embodiment, pilot signals PS31 to PS33 having different frequencies f31 to f33 are transmitted from the plurality of base station wireless devices 31 to 33. The mobile station radio device 40 receives the pilot signal PS transmitted from the other base station radio device 30 when moving into the area of the other base station radio device 30. Thereby, the frequency of the mobile station radio | wireless apparatus 40 can be automatically switched to the frequency of the base station radio | wireless apparatus 30 of a movement destination.

  The embodiment according to the present invention is not limited to the above-described configuration, and various modifications can be made without departing from the gist of the present invention.

DESCRIPTION OF SYMBOLS 1 Wireless communication system 2 Communication network 10 Remote communication control apparatus 11 Control part 12 Call determination part 30-33 Base station radio | wireless apparatus 40 Mobile station radio | wireless apparatus PS Pilot signal

Claims (7)

A base station radio device;
A mobile station radio device that transmits and receives signals to and from the base station radio device;
A remote communication control device having a control unit for controlling the base station wireless device to transmit a pilot signal of a predetermined frequency;
With
The mobile station radio device detects the pilot signal, maintains a predetermined frequency of the detected pilot signal as a reception frequency for a predetermined time,
The radio communication system, wherein the control unit controls the base station radio apparatus so that the base station radio apparatus transmits the pilot signal at an interval shorter than the predetermined time. The remote communication control device further includes a call determination unit that determines whether or not the base station wireless device is in an actual call,
The control unit controls the base station radio apparatus so that the base station radio apparatus does not transmit the pilot signal when the call judgment unit determines that the base station radio apparatus is in an actual call. The base station radio apparatus controls the base station radio apparatus so that the base station radio apparatus transmits the pilot signal when it is determined that the base station radio apparatus is not in an actual call. The wireless communication system described. Comprising a plurality of base station radio devices,
The control unit controls the plurality of base station radio apparatuses so as to shift pilot signal transmission timings so that pilot signal timings transmitted by the plurality of base station radio apparatuses do not overlap each other. The wireless communication system according to claim 1 or 2.   The transmission time of the pilot signal transmitted by each of the plurality of base station wireless devices by the control unit is equal to or longer than the time required for the mobile station wireless device to scan all the frequencies transmitted by the plurality of base station wireless devices. The wireless communication system according to claim 3, wherein: A control unit that controls the base station radio apparatus so that a base station radio apparatus that transmits and receives signals to and from the mobile station radio apparatus transmits a pilot signal of a predetermined frequency;
The control unit controls the base station radio apparatus to transmit the pilot signal at an interval shorter than a time during which the mobile station radio apparatus maintains the predetermined frequency at which the pilot signal is detected as a reception frequency. A telecommunications control device characterized by the above. A call determination unit for determining whether or not the base station wireless device is in an actual call;
The control unit controls the base station radio apparatus so that the base station radio apparatus does not transmit the pilot signal when the call judgment unit determines that the base station radio apparatus is in an actual call. The base station radio apparatus controls the base station radio apparatus so that the base station radio apparatus transmits the pilot signal when it is determined that the base station radio apparatus is not in an actual call. The telecommunications control device described. When the remote communication control device controls a plurality of base station radio devices,
The control unit controls the plurality of base station radio apparatuses so as to shift pilot signal transmission timings so that pilot signal timings transmitted by the plurality of base station radio apparatuses do not overlap each other. The telecommunications control apparatus according to claim 5 or 6.

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