JP5243198B2 - Communications system - Google Patents

Description

  The present invention relates to a communication system.

In recent years, with the widespread use of mobile phones, it has become easy to obtain mobile communication means that are highly convenient even outdoors. Therefore, mobile phones are widely used as means for emergency communication in railway maintenance and inspection work, railway accidents, and the like.
Moreover, as an outside contact means, a wired telephone line was laid along the railway, and emergency contact telephones were installed at regular intervals (see, for example, FIG. 7 of Patent Document 1).

Further, in mountainous areas, tunnels are often formed at various places on the railway, and there is a situation that communication using a mobile phone cannot be performed in the tunnel section. In view of this, a plurality of base stations including a base station connected via a wired line from a switch provided outside the tunnel can be installed at predetermined intervals along the tunnel to communicate with the base station. A communication system in a tunnel has been devised in which a mobile station is placed at an arbitrary position in a tunnel and communicates with a mobile wireless telephone using a communication protocol (SIP) based on a wireless LAN standard. (For example, refer nonpatent literature 1).
In this communication system, communication is performed in a predetermined frequency band in which high-power communication is performed in order to perform long-distance communication between each base station and the mobile station, and between the mobile station and the portable wireless telephone. By performing communication conforming to the wireless LAN standard, a call from outside the tunnel to a portable wireless telephone is possible.
Japanese Patent No. 4127658 "Railway and Electrical Technology" Japan Railway Electrical Technology Association, September 2007, p.14

However, in the prior art of Patent Document 1, the emergency contact telephone provided along the railway is installed at a certain interval, so it must be moved to the telephone and used. There has been a problem that it cannot be used and the movement to the telephone is a burden.
Further, since the prior art of Non-Patent Document 1 can carry a portable wireless telephone, it can eliminate the burden of movement to a fixedly installed telephone. Since both low frequency wireless LAN standard frequency band communications are used in combination, communication equipment in each frequency band is required, and communication in one frequency band and communication in the other frequency band are required. There is a problem in that an interface for connecting to the base station and the mobile station is complicated and the cost is high.
Furthermore, because the base stations communicate with each other in a high-output frequency band, the distance between the base stations is increased, so that communication with a portable wireless telephone, which is a communication means with a short communication distance, is possible. In addition, a mobile station that relays between the base station and the portable wireless telephone is indispensable, which also complicates the configuration and increases the cost.

  An object of the present invention is to enable communication in an area where a mobile phone cannot be used while reducing costs.

The invention according to claim 1 is a communication system having a plurality of distribution base devices arranged side by side along a tunnel, and a portable wireless telephone that makes a call by wirelessly transmitting / receiving call information to / from the distribution base device. The portable wireless telephone has a telephone-side packet generating means for converting voice data into a plurality of packets having a header for specifying a transmission destination, demodulating the packetized voice digital data, and outputting the voice and calling. A telephone-side demodulating unit that modulates voice into digital data; and a wireless transmitting / receiving unit that transmits and receives a packet of voice call information. At least one of the distribution base devices is connected to an external railway line. , at least the external wayside telephone line connected to delivery site device, data of a predetermined size audio data Divided into knit, and outputs it to the wayside telephone line as a voice call signal and the base side packet generator for converting by applying a header including destination information in the packet, a voice call signal packetized demodulates reduction, the And a base-side demodulating means for modulating a voice call signal from a telephone line to digital data, and all the distribution base devices wirelessly transmit / receive the packet installed with the transmission / reception direction directed along the tunnel. And a wireless transmission / reception means for transmitting / receiving the received packet or the packet generated by the base-side packet generation means, and the wireless transmission / reception means of each distribution base device includes other distribution bases Radio transmission / reception with a device and radio transmission / reception with the portable wireless telephone perform communication in the same frequency band without distinction. Device, regardless of the packet received at its destination, all the includes a relay communication control unit for transmitting a radio transceiver unit, the outside of the base-side packet generator of the connected distributed base device wayside telephone line For the digital data generated by the base side demodulating means, a packet that does not include transmission destination information in the header is generated, and the portable wireless telephone sets the portable wireless telephone to the transmission destination of the received packet. Only when a telephone is included, the telephone-side demodulating means performs demodulation by the telephone-side demodulating means , and further comprises a communication control means for controlling so that a packet not including transmission destination information in the header is regarded as all designation .

“Stationary telephone line” means a telephone line provided along a railway line, and is a part of the security communication facility based on the Ministry of Land, Infrastructure and Transport Ordinance (Ministry Ordinance that establishes technical standards related to railways) The telephone line and terminals for connecting telephones or telephones to the telephone line are provided at intervals of about 500 m.
When the train stops in the middle of the station due to an accident, etc., the crew will be in contact with the adjacent station and related parts, and not only for accidents but also for communication with related parts of facilities and electrical employees. . When a terminal is provided, a telephone that is brought separately is connected for communication.
The “railway telephone line” refers to a telephone line provided for security communication as described above, but a wired telephone in a tunnel and a connection terminal of the telephone are not essential components of the present invention.

The invention according to claim 2 has the same configuration as that of the invention according to claim 1, and at least one of the plurality of delivery base devices arranged side by side excludes those located at both ends of the tunnel. Are characterized by having two directional antennas respectively directed to both ends of the tunnel.
It should be noted that the distribution base devices located at both ends of the tunnel as shown as “at least” may have two directional antennas respectively directed to both ends of the tunnel, or inside the tunnel. It may have only one directed directional antenna.

Since the invention according to claim 1 is performed by transmitting and receiving data packets using the distribution base device to the portable wireless telephone, even in a tunnel where a normal cellular phone call is not possible, By installing a distribution base device, voice communication between portable wireless telephones or between the outside and portable wireless telephones via the telephone line is possible over the wireless coverage area. Calls such as contact are possible.
And the said communication system is installed in the tunnel, and is using the transmission / reception direction of the directional antenna of a distribution base apparatus toward the direction along a tunnel. For this reason, it is possible to suppress the spread of radio waves and prevent the influence of noise that is a disturbance from the outside. Therefore, it is possible to perform communication over a longer distance than when performing communication outdoors without a shielding object. For this reason, it is possible to perform a wide range of communication with a small number of equipment.
In addition, since the portable wireless telephone can be carried, it eliminates the inconvenience of having to move to a fixed telephone provided at regular intervals in an area that requires communication in the tunnel, without requiring the burden and time of movement. It becomes possible to communicate quickly and easily.

  According to the first aspect of the present invention, the wireless transmission / reception means of each distribution base device communicates in the same frequency band without distinction between wireless transmission / reception with other distribution base devices and wireless transmission / reception with the portable wireless telephone. Because the relay communication control means newly transmits all received packets regardless of their destinations, all packets are relayed by all distribution base devices, and are within the transmission / reception range of any distribution base device. Communication with a portable wireless telephone. When there are a plurality of portable wireless telephones, packets are transmitted to all the portable wireless telephones, but the communication control means demodulates only the packets destined for the portable wireless telephone. Therefore, it is possible to make a call with a scheduled portable wireless telephone.

  In the communication system, the wireless transmission / reception means of each distribution base device performs communication in the same frequency band without distinction between wireless transmission / reception with other distribution base devices and wireless transmission / reception with the portable wireless telephone. Unlike conventional technology that performs communication between devices and communication between a distribution base device and a portable wireless telephone in different frequency standby areas, wireless transmission / reception means for each frequency and wireless transmission / reception means that handle different frequencies Since it is not necessary to provide an interface provided between them and only a wireless transmission / reception means for performing communication at a single frequency is required, the configuration can be simplified and the cost can be reduced.

  Further, since the wireless transmission / reception means of each distribution base device performs communication in the same frequency band without distinction between wireless transmission / reception with other distribution base devices and wireless transmission / reception with a portable wireless telephone, the distribution base device as in the past Since each other is not arranged at an interval longer than the communicable distance of the portable wireless phone, there is no need for a movable relay means for relaying between the distribution base device and the portable wireless phone, and the configuration is simplified. As a result, the cost can be reduced.

  In the invention according to claim 2, since the distribution base device excluding at least those located at both ends of the tunnel has two directional antennas respectively directed to both ends of the tunnel, the distribution base devices are both It is possible to cover the communication range in the direction, and to reduce the number of distribution base devices installed.

(First embodiment)
Hereinafter, the communication system 10 which is 1st embodiment of this invention is demonstrated, referring FIGS. 1-3. FIG. 1 is an overall configuration diagram of a communication system 10.
In the present embodiment, the communication system 10 is provided in a tunnel section T along the railway (the tunnel may be provided with a shelter for wind protection or snow protection, but in such a case, the shelter is also a communication target). An example in which is provided will be described. Such a communication system 10 is suitable, for example, when communication is performed between workers for maintenance / maintenance management of railways or from a worker and an external remote location.

The communication system 10 includes a line telephone line 11 laid along the line, a line telephone 12 connected to the line telephone line 11, a plurality of distribution base devices 20A and 20B arranged along the line telephone line 11, There are provided IP telephones 30 as a plurality of portable wireless telephones that perform communication by telephone call via the distribution base devices 20A and 20B.
As described above, the railway line 11 is a telephone line provided along the railway line, and is connected to an analog telephone set installed at a railway management office (not shown) provided outside the tunnel. Further, the line-side telephone line 11 may be connected to an exchange and then connected to a subscriber telephone network which is a network of a communication carrier.
Each of the distribution base devices 20A is fixedly installed at both ends of the tunnel section, and the distribution base device 20B is fixedly installed in the middle of the tunnel section. Note that only one distribution base device 20B is shown in FIG. 1, but it may be installed more densely in the middle section in the tunnel. Each of the distribution base devices 20A and 20B includes a wireless transmission / reception circuit 202 (described later), and the adjacent distribution base devices are set as far as possible in a range where wireless transmission / reception with an allowable communication strength is possible. They are placed apart.

(IP phone)
FIG. 2 is a functional block diagram showing main functions of the IP telephone 30. The IP telephone 30 includes a main control unit 36 that performs main control necessary for communication, a modulation / demodulation processing unit 33 that converts the voice data of the call into voice data and voice of the received voice data, a destination and a call. Operation button 34 for inputting start and disconnection (on / off of hook) and transmission / reception as wireless transmission / reception means for transmitting voice data converted into packet F on a carrier wave and receiving packet F of data on the carrier wave from outside A circuit 37 and a whip antenna 38 having no directivity for transmission and reception are provided.

  The modulation / demodulation processing unit 33 is connected to the microphone 31, samples the call voice through the microphone 31, and modulates the call voice into digital data. Also, the modulation / demodulation processing unit 33 demodulates the audio digital data received from the transmission / reception circuit 37 to generate an audio signal and output the audio signal from the speaker 32. The modulation / demodulation processing unit 33 functions as “telephone side demodulation means”.

The main control unit 36 divides the audio data generated by the modulation / demodulation processing unit 33 into data units of a predetermined size, and adds a header including transmission destination information and transmission source information.
That is, the main control unit 36 and the modulation / demodulation processing unit 33 cooperate to function as “telephone side packet generation means”.
Then, the main control unit 36 performs data transmission processing by sending the packet F to the transmission / reception circuit 37 and transmitting it on the carrier wave.

In addition, the main control unit 36 reads the transmission destination information from the header of each packet F received by the transmission / reception circuit 37, and when the IP telephone 30 is the transmission destination or when all the IP telephones 30 are the transmission destination Alternatively, when there is no designation of the transmission destination (when there is no designation, all are designated), audio data is generated from the packet F and output to the modulation / demodulation processing unit 33. As a result, the modulation / demodulation processing unit 33 demodulates the audio data and outputs the audio from the speaker 32.
The main control unit 36 discards the packet F when the destination of the received packet F is another IP telephone 30.
As a result, the main control unit 36 functions as “communication control means”.

In addition, the main control unit 36 performs various processes based on an input operation by the operation button 34. That is, when a telephone number is input by the operation button 34, the packet F is generated by including the destination information and the source information based on the telephone number in the header. In the case of a call from the other party, a process is performed to attach to the packet F a header whose destination is the transmission source based on the transmission source information of the head attached to the empty packet F from the other party.
In addition, the main control unit 36 performs various controls in accordance with various commands related to the call from the operation buttons 34 (such as making a call, ending a call, or connecting a line when receiving a call).

(Distribution base equipment)
The distribution base devices 20A and 20B both have a built-in VoIP router 200. Since the distribution base device 20A is arranged at the end of the tunnel section T, it is sufficient if transmission / reception can be performed toward the inner side of the tunnel, and thus one directivity directed toward the inner side of the tunnel is sufficient. Only the antenna 21 and one VoIP router 200 connected thereto are provided.
On the other hand, since the distribution base device 20B is arranged in the middle of the tunnel section T, it is necessary to perform transmission and reception from both directions, and the two directional antennas 21 directed to both sides in the direction along the tunnel section, 21 and two VoIP routers 200 and 200 individually connected thereto. Here, as the directional antenna 21, a Yagi / Uda antenna is used. Note that these two VoIP routers 200 and 200 are connected to each other by a LAN cable 22, and the packet F is transmitted and received by wire.

FIG. 3 is a functional block diagram illustrating a schematic configuration of the distribution base device 20B. Since the distribution base device 20A has the same structure except that the directional antenna 21 and the VoIP router 200 are one and the VoIP router 200 is not connected to the WAN, only the distribution base device 20B will be described. Thus, the description of the distribution base device 20A is omitted.
As described above, the distribution base device 20B includes the directional antennas 21 and 21 directed to one and the other of the tunnel section T and the VoIP routers 200 and 200 connected to the directional antennas 21 and 21, respectively. It is configured.

  The VoIP router 200 functions as an access point of each IP telephone 30 by performing communication control such as packet distribution conforming to VoIP. The VoIP router 200 can perform communication in compliance with IEEE802.11b, IEEE802.11a, and IEEE802.11g, which are wireless LAN standards. For this reason, it is possible to access an information processing terminal including a wireless LAN client compliant with these standards.

Each VoIP router 200 employs SIP as a communication protocol, and transmits a main control unit 201 that performs communication control such as packet distribution and a packet F of call voice data with a predetermined header on a carrier wave. In addition, a transmission / reception circuit 202 as a wireless transmission / reception means for receiving a packet F riding on a carrier wave from the outside, a SIP server 212 storing information required for communication control, a TEL input port 204 to which the railway line 11 is connected, A TEL output port 205 to which a telephone 12 that is an analog telephone is connected, a WAN connection port 206 that can be connected to a WAN (Wide Area Network), connection ports 207 and 208 to a LAN (Local Area Network), The interfaces 209 of the ports 206 to 208 and the interfaces of the TEL input / output ports 204 and 205 The interface 210, and a modulation and demodulation processing unit 211 for performing the voice of the voice data received and digital data of the call voice.
In the distribution base device 20B having two VoIP routers 200, the line-side telephone line 11 is connected to the TEL input port 204 and the line-line telephone 12 is connected to the TEL output port 205 only for one VoIP router 200. The WAN connection port 206 is connected to the WAN, and the LAN connection port 207 is connected to the IP telephone 13.

  The transmission / reception circuit 202 performs packet transmission on a carrier wave having the same frequency as the IP telephone 30. All the VoIP routers 200 are transmission / reception circuits having the same frequency, and the VoIP routers 200 communicate with each other at the same frequency. That is, the VoIP router 200 can communicate with any of the other VoIP routers 200 and the IP telephones 30 within the transmission / reception range.

The modulation / demodulation processing unit 211 is connected to each of the TEL input / output ports 204 and 205 via the interface 210. When a call voice signal is input through the interface 210, the call voice signal is converted into digital data. Modulate and output to the main control unit 201.
Further, the modulation / demodulation processing unit 211 demodulates the digital voice data from the main control unit 201 to generate a voice signal, and the TEL input port 204 or the TEL via the interface 210. Output to the output port 205.
That is, the modulation / demodulation processing unit 211 functions as a base-side demodulation unit.

The main control unit 201 divides the audio data generated by the modulation / demodulation processing unit 211 into data units of a predetermined size, adds a header including transmission destination information, and generates a packet F. That is, the main control unit 201 and the modulation / demodulation processing unit 211 function as a “base-side packet generation unit” in cooperation.
The voice data generated by the modulation / demodulation processing unit 211 is voice data based on a call voice signal from an external analog telephone connected via the line telephone 12 or the line telephone line 11. Since the telephone 12 or the external analog telephone does not have a function of generating the packet F having the header indicating the transmission destination in the telephone unlike the IP telephone 30, the voice generated by the modulation / demodulation processing unit 211 When packet generation is performed from data, a packet F that does not include transmission destination information in the header is generated. As described above, the main control unit 36 of each IP telephone 30 processes the packet F for which the transmission destination is not designated in the same manner as for all designations, so that it is connected via the line telephone 12 or the line telephone line 11. The voice data from the external analog telephone is voiced by all the IP telephones 30, and the railway telephone 12 and the external analog telephone can make a call for all the IP telephones 30.
When the audio data is input from the modulation / demodulation processing unit 211, the main control unit 201 performs a process of generating a packet F having a header in which all the audio data is designated as a transmission destination. May be set.

The main control unit 201 receives the packet F received by the transmission / reception circuit 202 and the packet F from the WAN connection port 206 and the LAN connection ports 207 and 208 via the interface 209. At this time, when the destination information written in the header of the packet F is the telephone number input by the operation button 34 of the IP telephone 30, the SIP server 212 is referred to read out the correspondence between the telephone number and the destination. Then, the process of rewriting the contents of the header to the destination information according to the communication protocol is executed.
Then, the main control unit 201 wirelessly outputs all the input packets F on all the output destinations, that is, on the carrier wave from the transmission / reception circuit 202, and via the interface 209, the WAN connection port 206, the LAN connection port 207, External output to 208, external output to the TEL output port 205 and the TEL input port 204 through the interface 210 and the modulation / demodulation processing unit 211 are performed.
As described above, the packet F is output from the VoIP router 200 through any route, but there is no problem because the transmission destination information of the packet F is determined at the transmission destination.
Through the above processing, the main control unit 201 functions as “relay communication control means”.

With the above configuration, the VoIP router 200 is connected via an external analog telephone connected via the telephone line 11 connected to the TEL input port 204, a telephone 12 connected to the TEL output port 205, the WAN connection port 206, and the WAN. It is possible to make a call with the external IP telephone, the wired IP telephone 13 connected to the LAN connection port 207, and the IP telephone 30 within the communicable range for wireless LAN communication.
The packet F is transmitted in any direction along the tunnel by the directional antenna 21 connected to the transmission / reception circuit 202 or the directional antenna 21 connected to the transmission / reception circuit 202 of the VoIP router 200 connected to the LAN connection port 208. Since the packet F can be transmitted / received, communication can be performed with any of the adjacent distribution base devices 20A and 20B, and IP within a range covered by all the distribution base devices 20A or 20B arranged along the tunnel. It is possible to make a call between the telephone 30 and other telephones connected to the distribution base devices 20A and 20B.

For example, the WAN connection port 206 is connected to the WAN (Internet) via a telephone line along the line via an ADSL modem (not shown).
The wired IP telephone 13 connected to the LAN connection port 207 is a telephone having substantially the same function as the IP telephone 30 except for the transmission / reception circuit 37 of the wireless IP telephone 30 described above.
Note that it is sufficient that at least one of all the VoIP routers 200 in the communication system 10 is connected to the external WAN and the line telephone line 11. However, more or all of the VoIP routers 200 are connected to the WAN and the line telephone line 11. The connection may be made to.

(Call processing by communication system)
Processing during a call in the communication system 10 will be described.
First, when a call is made from an external telephone through the railway line 11, the VoIP router 200 of the distribution base device 20B converts the audio signal from the external telephone into digital data by the modulation / demodulation processing unit 211, and performs main control. The unit 201 generates a packet F that does not specify a transmission destination, and distributes the packet F to the outside from the transmission / reception circuit 202, the WAN connection port 206, and the LAN connection ports 20 and 208. In addition, transmission is also performed to the line telephone 12 connected to the TEL output port 205.
As a result, the packet F is wirelessly distributed to one side along the tunnel by the directional antenna 21 connected to the transmission / reception circuit 202 of one VoIP router 200, and the other VoIP connected via the LAN connection port 208. The packet F is wirelessly distributed to the other side along the tunnel by the router 200.
Since the VoIP router 200 of all the distribution base devices 20A and 20B newly distributes the packet F received from the outside by radio, it relays the distribution base devices 20A and 20B to all the distribution base devices 20A and 20B. Packet F is transmitted. Then, the packet F is transmitted to all the IP telephones 30 within the communicable range of all the distribution base devices 20A and 20B. Also, the packet F is transmitted to the wired IP telephone set 13 connected to all the VoIP routers 200. Further, the VoIP router 200 of all the distribution base devices 20A and 20B demodulates the voice data of the packet F by the modulation / demodulation processing unit 211 and transmits the signal to the along-line telephone 12 instead of the voice signal.
As a result, it is possible to make a call to all the telephones 30, 12, 13 from an external telephone through the railway line 11.

Further, when a call is made from the IP telephone 30, a packet F with a header indicating a transmission destination designated by the number by the button 34 is wirelessly transmitted and received by any one of the distribution base devices 20A or 20B. Then, the main control unit 201 of the VoIP router 200 reads out the transmission destination corresponding to the designated number in the header by the SIP server 212 and rewrites the transmission destination information according to the communication protocol. And the packet F is transmitted to all the routes similarly to the above-mentioned case. As a result, the packet F is transmitted to all the distribution base devices 20A and 20B, and the packet F is transmitted to all the IP telephones 30 within the communicable range of all the distribution base devices 20A and 20B. Also, for all wired IP telephones 13 (including external IP telephones via WAN) connected to all the distribution base devices 20A and 20B and external telephones via the telephone 12 and the telephone line 11 along the line. Packet F or a voice signal is transmitted.
Thereby, it is possible to make a call from the IP telephone 30 to all the telephones.
When a call is made from a wired IP phone 13 or an external IP phone via a WAN, the same processing as that performed by the IP phone 30 is performed. The same processing is performed by an external telephone through the line 11.

As a result, the packet F of the voice call data is transmitted to all VoIP routers 200 (all distribution base devices 20), and further, the packet F is transmitted to all wireless transmission possible ranges of each VoIP router 200. As long as the IP telephone 30 as the transmission destination exists in any wireless transmission possible range, the voice call data packet F is properly received.
Therefore, a call between an external IP phone and the IP phone 30 in the communication system 10 and a call between the IP phones 30 in the communication system 10 are smoothly performed through the WAN.

(Effect of the first embodiment)
Since the communication system 10 performs voice communication with a plurality of IP telephones 30 by transmitting and receiving data packetized using the distribution base devices 20A and 20B, the distribution base device 20 can be used even in a non-call area of a mobile phone. By installing, voice communication between the IP telephones 30 is possible over the wireless range. In addition, since the distribution base device 20B is connected to the WAN, which is an information transmission line, a call to an external IP phone or a call device that functions in the same manner is performed not only within the network of the communication system 10 but also through an external network. It is also possible to do this.
In addition, since the distribution base device 20B is connected to the telephone line 11 along the line, the telephone set installed in the railway management office outside the tunnel and all the telephones 12, 13, 30 used in the tunnel are connected. It is also possible.
In addition, since the IP telephone 30 can be carried, it eliminates the inconvenience of having to walk to a fixed telephone sparsely provided in an area where communication is required, and can communicate quickly and easily without the burden and time of movement. Can be done.

Further, since the communication system 10 uses a wireless IP telephone as a call device and the distribution base devices 20A and 20B include the VoIP router 200, a communication system is configured by applying a commercially available wireless LAN system. Therefore, it is possible to easily and inexpensively install and remove the communication system.
In particular, wireless IP phones are excellent in portability, and commercially available VoIP routers are excellent in portability due to progress in units and miniaturization, so if power can be secured, they can be easily installed outdoors. It is possible to reduce the installation work cost and work load.

Further, in the communication system 10, each of the distribution base devices 20 </ b> A and 20 </ b> B transmits and receives radio waves using the directional antenna 21, and therefore, the distance between the distribution base devices is arranged farther than when a normal antenna is used. Therefore, it is possible to reduce the number of devices used and increase the communication range.
In particular, the communication system 10 is used as an intra-tunnel communication system, and the transmission / reception direction of the directional antenna 21 is directed in the direction along the tunnel. On the other hand, each of the distribution base devices 20A and 20B and the IP telephone 30 of the communication system 10 has a frequency band of 2412 to 2472 [MHz] or 5180 to 5320 [MHz] compliant with IEEE802.11b, IEEE802.11a, and IEEE802.11g. I ’m doing wireless communication,
In the tunnel, it is possible to suppress the spread of radio waves and to prevent the influence of noise that is a disturbance from the outside. Therefore, it is possible to perform communication over a longer distance than when performing communication outdoors without a shielding object. For this reason, each of the distribution base devices 20A and 20B can perform a wider range of communication.
Furthermore, the distribution base devices 20A and 20B are arranged side by side along the tunnel, and the intermediate distribution base device 20B has two directional antennas 21 and 21 respectively directed to both ends of the tunnel. Therefore, the distribution base device 20B can cover the communication range in both directions, and the number of distribution base devices can be reduced.

  The transmission / reception circuit 202 of each distribution base device 20A, 20B of the communication system 10 performs communication in the same frequency band without distinction between wireless transmission / reception with other distribution base devices 20A, 20B and wireless transmission / reception with the IP telephone 30. The main control unit 201 functioning as a relay communication control unit newly transmits all the received packets F regardless of their transmission destinations, so that all the packets F are relayed by all the distribution base devices 20A and 20B. , Communication to the IP telephone 30 existing in the transmission / reception range of any of the distribution base devices 20A and 20B is enabled. When there are a plurality of IP telephones 30 in the tunnel, the packet F is transmitted to all the IP telephones 30, but the main control unit 36 uses the portable wireless telephone as a transmission destination packet. Since only F is demodulated, it is possible to make a call with a scheduled portable wireless telephone.

  In the communication system 10, the transmission / reception circuit 202 of each distribution base device 20A, 20B communicates in the same frequency band without distinction between wireless transmission / reception with the other distribution base devices 20A, 20B and wireless transmission / reception with the IP telephone 30. Unlike the prior art in which communication between the distribution base devices 20A and 20B and communication between the distribution base devices 20A and 20B and the IP telephone 30 are performed in different frequency bands, a transmission / reception circuit for each frequency. In addition, it is not necessary to provide an interface provided between transmission / reception circuits that handle different frequencies, and it is sufficient to provide only the transmission / reception circuit 202 that performs communication at a single frequency. Therefore, the configuration can be simplified and the cost can be reduced. It becomes possible.

  Further, the transmission / reception circuit 202 of each distribution base device 20A, 20B performs communication in the same frequency band without distinction between wireless transmission / reception with the other distribution base devices 20A, 20B and wireless transmission / reception with the IP telephone 30. As described above, since the distribution base devices are not arranged at intervals longer than the communicable distance of the IP telephone, a movable relay means for relaying the distribution base apparatus and the IP telephone is not required, and the configuration is simple. And cost reduction can be achieved.

  In addition, the distribution base device 20B connected to the telephone line 11 in the communication system 10 uses all the telephones 12, 13,. Since 30 is transmitted as a transmission destination, it becomes possible to simultaneously contact all the telephones 12, 13, 30 used in the tunnel from the outside of the tunnel, and all the telephones 12, When there is a need for urgent contact with 13,30, for example, it is possible to promptly contact even in the case of, for example, bear drop information or tunnel icicle dropping work in the severe winter season.

(Second embodiment)
Next, as a second embodiment of the present invention, a more specific example of actual use is shown in FIG.
The communication system 10 is an example in which the communication system 10 is applied to a section including a second additional tunnel T connected from the first additional tunnel T along the Ishikatsu Line in Hokkaido via a light section L (a section that is not a tunnel). .
The first distribution base device 20B (only this distribution base device 20B is connected to the telephone line 11 along the line) is installed on one end side of the first additional tunnel T, and the second distribution base device 20B is connected to the first additional tunnel. Installed on the other end side of T, the third distribution base device 20B was installed in the middle of the second Oiwake tunnel T. Then, a good call is made in a state where the distance between the IP telephone 30 on the first distribution base device 20B side and the IP telephone 30 on the third distribution base device 20B side is about 3500 [m]. I was able to. Thereby, the communication covering the light section between the first additional tunnel T and the entire section including the entire length of the second additional tunnel T was possible. Further, it was proved by the test of this example that the communication system 10 can perform good communication even if the communication system 10 is not entirely in the tunnel section but a light section is interposed in the middle.

(Third embodiment)
Next, as a third embodiment of the present invention, a more specific example of actual use is shown in FIG.
The communication system 10 is an example in which the communication system 10 is applied to a section including a Kamui tunnel T, an Ino first tunnel T, an Ino second tunnel T, and a light section interposed therebetween along the Hakodate main line in Hokkaido.
The first distribution base device 20B (only this distribution base device 20B is connected to the telephone line 11 along the line) is installed on one end side of the Kamii tunnel T, and the second distribution base device 20B is installed in the Ino first tunnel T. The third distribution base device 20B was installed in the Ino second tunnel T. A good call could be made with the distance from the first distribution base device 20B to the IP telephone 30 on the third distribution base device 20B side being about 8000 [m]. Thereby, the communication which covers the area including all the full length of the Kami tunnel T, the Ino 1 tunnel T, and the Ino 2 tunnel T was possible.

(Reference Example 1)
Next, a communication system 10C as a reference example will be described with reference to FIG. In the communication system 10C, the same components as those of the communication system 10 described above are denoted by the same reference numerals, and redundant description is omitted.
FIG. 6 is an overall configuration diagram of the communication system 10C. As shown in the figure, the communication system 10C includes an IP telephone 30 and a distribution base device 20B, and shows an example in which the communication system 10C is implemented outdoors in a releasable manner without a shielding object such as a tunnel. In the communication system 10 </ b> C, the directional antennas 21 and 21 of the distribution base device 20 </ b> B are installed so as to be directed in both directions along the telephone line 11. Needless to say, a plurality of distribution base devices 20A or 20B may be installed side by side.
Since this communication system 10C is not an environment that can prevent the influence of radio wave diffusion and disturbance noise as in the tunnel space T, the communicable distance is shortened. However, except for this point, the communication system 10C is the same as the communication system 10 It is possible to produce an effect.
In actual use results, in such a communication system 10C, stable telephone conversation was possible even when the IP telephone 30 was 340 [m] away from the distribution base unit 20B along the line. Further, in the above-described communication system 10 in the tunnel, a stable call can be made even at a distance of 2500 [m] along the telephone line of the IP telephone 30 with respect to the distribution base device 20B. Based on this result, the installation intervals of the distribution base devices 20A and 20B can be separated to at least 340 × 2 = 680 [m] without a shield, and can be separated to 2500 × 2 = 5000 [m] in the tunnel section. it can.

(Reference Example 2)
Next, communication systems 10D and 10E as Reference Example 2 will be described with reference to FIGS. 7 (A) and 7 (B). In the communication systems 10D and 10E, the same components as those of the communication system 10 described above are denoted by the same reference numerals, and redundant description is omitted.
As shown in FIG. 7A, the communication system 10D includes a battery 14 as a power source of the distribution base device 20B in addition to the IP telephone 30 and the distribution base device 20B, and the distribution base device 20B and the battery 14 are transportable. Are stored in case 15.
In addition, the directional antennas 21 and 21 are configured not to be integrated with the distribution base device 20B but to be supported by the tripod 40.
With such a configuration, the communication system 10D has the same effect as the communication system 10, and the case 15 can carry the communication system 10D to any destination. It is also possible to start communication. Moreover, since the directional antennas 21 and 21 are separate from the case 15, the portability can be improved without interfering with the transportation of the case 15. Furthermore, since the directional antenna 21 is supported by the tripod 40, the directional antenna 21 can be easily installed and removed and transported alone.

As shown in FIG. 7B, the communication system 10E includes an IP telephone 30 and a distribution base device 20B, and the distribution base device 20B is used as a transport vehicle 16 (a light truck, a railroad vehicle, a private vehicle, and other vehicle types are not selected). It is mounted on. In addition, a dedicated battery as a power source for the distribution base device may be prepared, or the battery of the transport vehicle 16 may be used. A generator (generator) may be prepared and installed together with the distribution base device 20B.
With such a configuration, the communication system 10D has the same effects as the communication system 10, and the transport vehicle 16 can quickly and easily transport the communication system 10D to any destination, enabling communication at any place and transporting. It is possible to start communication as soon as possible.

  In addition, although the example which uses the distribution base apparatus 20B was shown about the communication systems 10C-10E, you may use 10 A of distribution base apparatuses.

(Other)
About each said communication system 10, 10C-10E, it is good also as a structure which attaches a heater to each delivery base apparatus 20A, 20B, or wraps the exterior with a heat insulating sheet so that it may be suitable also for use in a cold district.
Moreover, since humidity may be high in the submarine tunnel, a dehumidifying device may be attached to each of the distribution base devices 20A and 20B.

Further, in each of the communication systems 10, 10C to 10E, the case where the IP telephone 30 which is a dedicated machine as an IP telephone is used as the portable wireless telephone is exemplified. However, a hybrid telephone of a mobile telephone and an IP telephone is used. Needless to say. In that case, when the hybrid phone is used in a mobile phone call area outside the tunnel, it can be used in the same manner as a normal mobile phone, and the use area can be expanded as a means of communication. .
Similarly, as another example of a portable wireless phone, a portable information terminal such as a smartphone equipped with an IP phone function, or an information processing terminal installed with a so-called soft phone that realizes the IP phone function by software (Including a personal computer) may be used.

  As shown in FIG. 8, a wall-mounted broadcast system cooperation unit 50 may be used in the communication system 10 instead of the IP telephone 30 or in combination with the IP telephone 30. The broadcast system cooperation unit 50 has exactly the same function as the IP telephone 30 except for the installation type, and has the same internal configuration as the IP telephone 30 (see FIG. 2). In other words, it is equipped with a speaker and a microphone and can talk.

It is a schematic block diagram of the communication system which is 1st embodiment of this invention. It is a functional block diagram of the IP telephone of a communication system. It is a functional block diagram of the distribution base apparatus of a communication system. It is a schematic block diagram of the communication system which is 2nd embodiment of this invention. It is a schematic block diagram of the communication system which is 3rd embodiment of this invention. 2 is an overall configuration diagram of Reference Example 1. FIG. It is a whole block diagram of the reference example 2, FIG. 7 (A) shows the example which stored the distribution base apparatus in the case, FIG.7 (B) shows the example which mounted the distribution base apparatus in the conveyance vehicle. It is a schematic block diagram which shows the example which applied the broadcast system cooperation unit to the communication system.

Explanation of symbols

10, 10C, 10D, 10E Communication system 11 Line telephone lines 20A, 20B Distribution base unit 21 Directional antenna 30 IP telephone (portable wireless telephone)
33 Modulation / demodulation processing unit (phone-side demodulation means)
36 Main control unit (telephone side packet generation means, communication control means)
37 Transmission / reception circuit (wireless transmission / reception means)
200 VoIP router 201 main control unit (site side packet generation means, relay communication control means)
202 Transmission / reception circuit (wireless transmission / reception means)
211 Modulation / demodulation processing unit (base-side demodulation means)
F packet

Claims (2)

In a communication system having a plurality of distribution base devices arranged side by side along a tunnel and a portable wireless telephone that performs a call by transmitting and receiving call information wirelessly with the distribution base device,
The portable wireless telephone is
Telephone-side packet generation means for converting voice data into a plurality of packets having a header for specifying a transmission destination;
A telephone-side demodulating means for demodulating packetized voice digital data and outputting the voice and modulating the voice of the call into digital data ;
Wireless transmission and reception means for transmitting and receiving voice call information packets;
At least one of the distribution base devices is connected to an external railway line,
At least the distribution base device connected to the external telephone line,
Base-side packet generation means for dividing voice data into data units of a predetermined size, adding a header including transmission destination information, and converting the packet into packets;
A base-side demodulating means for demodulating a packetized voice call signal and outputting the voice call signal to the telephone line as a voice call signal, and modulating the voice call signal from the telephone line to digital data ;
All the distribution base devices
A directional antenna for wireless transmission / reception of the packet installed with its transmission / reception direction oriented along the tunnel;
Wireless transmission and reception means for transmitting and receiving the received packet or the packet generated by the base side packet generation means,
The wireless transmission / reception means of each distribution base device performs communication in the same frequency band without distinction between wireless transmission / reception with other distribution base devices and wireless transmission / reception with the portable wireless telephone,
Each of the distribution base devices includes a relay communication control unit that transmits all of the received packets regardless of the transmission destination by the wireless transmission / reception unit,
The base-side packet generation means of the distribution base device connected to the external railway line generates a packet that does not include transmission destination information in the header for the digital data generated by the base-side demodulation means. ,
The portable wireless telephone performs demodulation by the telephone-side demodulating means only when the portable wireless telephone is included in the destination of the received packet, and a packet that does not include transmission destination information in the header is A communication system comprising communication control means for performing control so that all are designated .   A distribution base device excluding at least both ends of the tunnel among the plurality of distribution base devices arranged side by side has two directional antennas respectively directed to both ends of the tunnel. The communication system according to claim 1.

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