JP4789897B2 - Cordless telephone equipment - Google Patents

Description

The present invention relates to a cordless telephone apparatus that communicates by being connected to a wide area communication network, and more particularly to a cordless telephone apparatus that receives an emergency earthquake bulletin distributed by the Japan Meteorological Agency and issues an evacuation instruction.

  In recent years, with the development of communication infrastructure, various additional services related to communication have become widespread. For example, telephone devices that can connect to a wide-area communication network such as an IP telephone network or the Internet and receive various services such as a data communication service have become widespread.

  As one of the functions provided in such a communication device, there is a function for receiving an emergency earthquake bulletin distributed by the Japan Meteorological Agency when an earthquake occurs. Earthquake early warning is an information distribution service that will be implemented from October 1, 2007 AD. The user can use this service by purchasing a communication device corresponding to the earthquake early warning and making a contract with a distribution service company for the earthquake early warning.

  A communication device that has received an earthquake early warning when an earthquake occurs uses local information recorded in advance in the communication device, for example, latitude / longitude information of the location where the communication device is installed, etc. Of earthquake motion, the part most felt by the human body (usually the S wave) is calculated.

  The calculation result is notified to the user, for example, by displaying an image on a liquid crystal panel or outputting sound through a speaker. Thus, the user can take an evacuation action such as hiding under the desk or extinguishing the source of the fire before the main motion arrives from the epicenter.

  Patent Document 1 discloses an image processing apparatus that can suppress the possibility of a secondary disaster such as a fire due to an earthquake as compared with the conventional apparatus as an apparatus capable of receiving the emergency earthquake warning as described above. The image processing apparatus includes a communication control unit that performs communication with an external device, and a power source control unit that changes an energization state inside the apparatus.

  Then, when the communication control means receives the earthquake early warning from the external device, the power supply control means is controlled to change the energization state. By controlling the power supply based on external information in this way, it is possible to prevent erroneous detection of earthquakes due to vibrations other than earthquakes, such as when working nearby or accidentally colliding with equipment, without compromising convenience. Safety can be ensured.

  In relation to the above, Patent Document 2 discloses a portable early earthquake warning device capable of collecting early earthquake information and determining whether or not it is necessary to call attention before reaching the main motion of the earthquake motion. . This portable early earthquake warning device has a position information receiving means, an emergency earthquake warning receiving means, a position information received by both receiving means, and an earthquake early warning, before the arrival of the main motion of the earthquake motion. Is provided with means for determining whether or not attention is required.

According to this, since warnings can be issued before the main motion of the earthquake motion reaches the railroad vehicles and automobiles, it is possible to take measures to stop the railroad vehicles and automobiles quickly, and the occurrence of great damage. Can be prevented.
JP 2007-72917 A JP 2005-283491 A

  According to Patent Document 1 and Patent Document 2 described above, it is possible to prevent secondary disasters by receiving emergency earthquake warnings, and to perform alerts, vehicle stoppages, etc. before the main motion arrives. . However, for voice messages and text messages for calling attention, fixed messages previously set in the communication device are used as in the conventional case.

  However, there are various patterns in the place where the earthquake early warning receiver is installed and the age group and gender of the user who receives the evacuation instruction. For example, the installation location is assumed to be a kitchen, study room, bedroom, living room, etc. at home. In the case of an office, an office room, a reception room, a computer room, a hot water supply room, etc. are assumed. If the installation location is different, the content of the optimum evacuation behavior at each location will also be different.

  For example, it is desirable to evacuate under the study desk in the study room, and evacuate under the bed in the bedroom. In addition, it is desirable to extinguish the source of fire in a kitchen or hot water supply room, and it is desirable to turn off the computer in a computer room. However, in the conventional communication apparatus, since the standard message is used, the evacuation action instruction according to the installation location cannot be properly used as described above.

  Therefore, for example, a user who has lost his normal feeling may be confused without knowing where to evacuate. In addition, young children and elderly people often have poorer judgment than ordinary adults, and there is a possibility that appropriate evacuation behavior cannot be taken.

  The present invention has been made to solve the above-described problem, and when receiving an earthquake early warning due to the occurrence of an earthquake, instructs the installation location of the communication device and the user who is the target of evacuation for the optimum evacuation behavior. An object of the present invention is to provide a communication device that can perform the above-described operation.

In order to achieve the above object, the cordless telephone device of the present invention is a cordless phone device comprising a parent device and a plurality of child devices that can be wirelessly connected to the parent device, and the parent device is connected to a communication network. Possible first communication means, a breaking news receiving section that receives the earthquake early warning from the communication network using the first communication means, and an earthquake detection notification to the slave unit when the breaking news receiving section receives the earthquake early warning An earthquake detection transmission unit, and the slave unit stores a plurality of earthquake detection reception units that receive an earthquake detection notification from the master unit, an installation location where the slave unit is installed, audio data, and image data in advance. The storage unit, the speaker that outputs the audio data stored in the storage unit, the evacuation instruction unit that controls the display unit that displays the image data stored in the storage unit, and the user selecting the installation location , The selected setting A registration unit that registers voice data and image data corresponding to a place in the storage unit as evacuation instruction data, and the slave unit receives the earthquake detection reception unit after registration of the evacuation instruction data. When the earthquake detection notification is received from the base unit, the evacuation instruction unit outputs voice data and image data, which are evacuation instruction data registered in the storage unit, from the speaker and the display unit, respectively. To do.

According to the configuration of the present invention, the evacuation instruction table that associates the location of the slave unit with the evacuation instruction image and the evacuation instruction voice is provided. For this reason, the user can set the evacuation instruction image and the evacuation instruction sound corresponding to each installation place only by specifying the installation place. For this reason, since the setting operation can be performed easily and in a short time, the convenience is improved.

  Moreover, according to the structure of this invention, the main | base station and the subunit | mobile_unit are equipped with the radio | wireless communication part, and evacuate instruction | indication via a radio | wireless communication network. For this reason, even when the user moves and uses the slave unit, it is possible to receive an evacuation instruction by the registered or selected evacuation instruction image or evacuation instruction voice. In addition, for example, when the child device is carried from the bedroom to the kitchen, the evacuation instruction for the kitchen can be reset. As described above, even when the location of the slave unit is changed, the contents of the evacuation instruction can be easily changed according to the situation.

Embodiments of the present invention will be described below with reference to the drawings. In addition, embodiment shown here is an example and this invention is not limited to embodiment shown here.
[Embodiment 1]
<1-1. About the configuration of the telephone system>
FIG. 1 is a block diagram showing a configuration of a telephone system including a cordless telephone apparatus (= communication apparatus) of the present invention. This system includes at least a master unit 1 (= main communication device), a slave unit 2 (= sub communication device), a wired LAN 41, a wireless communication network 42, an IP telephone router 51, a broadband router 52, a gateway 53, an IP telephone network 61, An Internet 62, a PSTN network 63 (= Public Switched Telephone Network), and a subscriber telephone device 71 are configured.

  The cordless telephone apparatus of the present invention is a cordless telephone apparatus that can be connected to an IP communication network, and corresponds to the parent device 1 and the plurality of child devices 2 (child devices A2a to C2c) in the figure. The base unit 1 is an IP telephone device capable of voice communication via a telephone network by being connected to the wired LAN 41. The base unit 1 has a relay function for relaying communication between the wired LAN 41 and the wireless communication network 42. Accordingly, the slave unit 2 described later can perform a call via the IP telephone network 61 or the PSTN network 63 by relaying the master unit 1. The base unit 1 also has a function of receiving an emergency self-breaking report distributed by the Japan Meteorological Agency via the Internet 62. The details of the internal structure of base unit 1 will be described later.

  The handset 2 is connected to a wireless communication network 42, which will be described later, and communicates with the base unit 1 so that the handset 2 can perform voice communication with other telephone devices via the IP telephone network 61 and the PSTN network 63. It is a communication device. The details of the internal configuration of the slave unit 2 will be described later.

  The wired LAN 41 is a local network in which the parent device 1, the IP telephone router 51, the broadband router 52, the gateway 53, and the like are connected by wire. Each of the above devices can communicate with each other by being connected to the wired LAN 41. Examples of physical means constituting the wired LAN 41 include 10BASE-T (standardized as IEEE802.3i) and 100BASE-TX (standardized as IEEE802.3u) using a twisted pair cable.

  The wireless communication network 42 is a small-scale communication network in which the parent device 1 and the plurality of child devices 2 are wirelessly connected. Specifically, for example, communication is performed using a communication system based on FHSS-WDCT (Frequency Hopping Spread Spectrum-Worldwide Digital Cordless Telephone) using radio waves in a frequency band of 2.4 GHz (gigahertz).

  The IP telephone router 51 and the broadband router 52 are network relay devices for interconnecting a plurality of IP networks. Specifically, the transfer is performed by analyzing a part of the protocol of the network layer (third layer) and the transport layer (fourth layer) in the OSI (Open Systems Interconnection) reference model. In the present embodiment, the IP telephone router 51 has a role of connecting two IP networks of the wired LAN 41 and the IP telephone network 61 to each other. The broadband router 52 has a role of connecting two IP networks of the wired LAN 41 and the Internet 62 to each other.

  The gateway 53 is a protocol converter for interconnecting networks having different protocol systems. For example, the gateway 53 connects the wired LAN 41 and the PSTN network 63 and performs signal conversion using a signaling protocol such as SIP, thereby enabling communication between both networks.

  The IP telephone network 61 is a communication network using VoIP (Voice over Internet Protocol) technology for part or all of the telephone network, and FTTH (Fiber To The Home) and ADSL (Asymmetric Digital Subscriber) are used as communication lines. A so-called broadband line is used. Note that VoIP is a technique in which voice is compressed by various encoding methods, converted into packets, and transmitted in real time over an IP network. As a result, the IP telephone network 61 can provide a videophone service for transmitting and receiving images in addition to a voice call service.

  The Internet 62 is a wide area communication network constructed by interconnecting networks based on communication protocols. An international communication network is constructed by interconnecting large and small computer networks. As a communication protocol, TCP / IP is mainly adopted as a standard protocol.

The PSTN network 63 is a general subscriber telephone line network. It is used to make a voice call by connecting a telephone device to the end and connecting to a communication partner by a circuit switching method. The subscriber telephone device 71 is a telephone device that allows a telephone subscriber to make a voice call with another subscriber telephone device or an IP telephone device using the PSTN network 63.
<1-2. About the internal structure of the main unit>
FIG. 2 is a block diagram showing the inside of the base unit 1 according to the first embodiment of the present invention. The base unit 1 includes at least a control unit 11, a memory 12, a display unit 13, an input unit 14, a communication control unit 15 (= first communication means), an antenna device 16 (= wireless communication unit), an audio signal processing unit 17, and a speaker. 18 (= sound output unit), microphone 19, and flash memory 20 (= recording unit).

  The control unit 11 is a central processing unit for performing overall control of communication control processing (voice data transmission / reception, outgoing call execution, incoming call detection, etc.) by controlling each unit of the base unit 1. In addition, the control unit 11 is a functional unit realized by executing a program on the arithmetic processing device included in the control unit 11, and includes a breaking news receiving unit 11 a (= breaking news receiving unit), an earthquake detection transmission unit 11 b (= earthquake detection transmission). Means), an evacuation instruction section 11c (= evacuation instruction means), and an evacuation instruction registration section 11d (= evacuation instruction registration means).

  The breaking news receiving unit 11a determines that an earthquake has been detected by receiving an emergency earthquake breaking news from the Internet 62 using the communication control unit 15. When the occurrence of an earthquake is detected, an earthquake detection notification is given to the next earthquake detection transmission unit 11b and the evacuation instruction unit 11c.

  The earthquake detection transmission unit 11b transmits the earthquake detection notification to the child device 2 using the communication control unit 15 when the earthquake detection notification is given from the breaking news reception unit 11a. The evacuation instruction unit 11c reads an evacuation instruction image and an evacuation instruction sound (hereinafter referred to as “evacuation instruction data”) recorded in the flash memory 20 when an earthquake detection notification is given. Then, the evacuation instruction is performed by outputting the read evacuation instruction data using the display unit 13 and the speaker 18.

  The evacuation instruction registration unit 11d receives an instruction to select data to be used as evacuation instruction data by the evacuation instruction unit 11c from the image data and audio data recorded in the flash memory 20. The selection result is recorded in the flash memory 20. The evacuation instruction unit 11c determines the evacuation instruction data to be output by referring to the selection result. The evacuation instruction registration unit 11d also has a function of inputting image data and audio data from the outside and recording them in the flash memory 20. For example, the voice input from the microphone 19 is recorded as the evacuation instruction voice.

  The memory 12 is a medium for temporarily recording various data held by the parent device 1, and is configured by, for example, a writable RAM (Random Access Memory). The memory 12 serves as a buffer memory for temporarily recording processing data when various control processes are performed by the control unit 11, instruction commands received from the user, and the like.

  The display unit 13 displays various information (for example, a caller telephone number at the time of incoming call) held by the parent device 1 to the user. The display unit 13 uses, for example, a small display device that consumes less power, such as a liquid crystal panel. The input unit 14 is for a user to perform various operations (for example, input of a telephone number of a partner with whom a call is made) for performing communication using the parent device 1. The input unit 14 is generally composed of a plurality of operation buttons such as numeric buttons and redial buttons.

  The communication control unit 15 is a communication interface for connecting the parent device 1 to the wired LAN 41. The communication control unit 15 can perform incoming call processing, outgoing call processing, and the like in the IP telephone system by communicating with a call control server (not shown) connected to the wired LAN 41. In addition, the communication control unit 15 controls wireless communication via the wireless communication network 42 by the antenna device 16.

  The antenna device 16 is a wireless communication device for transmitting and receiving wireless communication radio waves to and from the handset 2. The antenna device 16 performs wireless communication in accordance with a predetermined communication standard, for example, a communication system conforming to FHSS-WDCT (Frequency Hopping Spread Spectrum-Worldwide Digital Cordless Telephone). Thereby, voice communication, data communication, etc. can be performed with the subunit | mobile_unit 2. FIG.

  The audio signal processing unit 17 performs a decoding process on the audio data input by the communication control unit 15 and provides the audio signal to the speaker 18. The audio signal processing unit 17 performs predetermined encoding processing on the audio signal input from the microphone 19 to generate audio data, and supplies the audio data to the communication control unit 15. As a result, the audio data is transmitted to another telephone device connected through the wired LAN 41, the wireless communication network 42, the IP telephone network 61, or the like.

The flash memory 20 is a non-volatile semiconductor memory that can be rewritten and does not lose data even when the power is turned off. The flash memory 20 is a kind of EEPROM, but unlike the EEPROM, it cannot be rewritten in units of 1 byte, and is written after being erased in units of blocks in advance. In the present invention, it is used for recording the evacuation instruction data used by the evacuation instruction unit 11c.
<1-3. About the internal structure of the slave unit>
FIG. 3 is a block diagram showing the inside of the handset 2 according to the first embodiment of the present invention. The subunit | mobile_unit 2 is the control part 21, the memory 22, the display part 23, the input part 24, the communication control part 25 (= 2nd communication means), the antenna apparatus 26 (= wireless communication part), the audio | voice signal processing part 27, a speaker. 28 (= sound output unit), microphone 29, flash memory 30 (= recording unit), battery unit 31, CCD (Charge Coupled Devices) camera 32, and SD card slot 33.

  The control unit 21 is a central processing unit for performing overall control of communication control processing (voice data transmission / reception, outgoing call execution, incoming call detection, etc.) by controlling each unit of the slave unit 2. In addition, the control unit 21 includes, as function units realized by executing a program on the arithmetic processing device included in the control unit 21, an earthquake detection reception unit 21a (= earthquake detection reception unit) and an evacuation instruction unit 21b (= evacuation instruction). Means) and an evacuation instruction registration unit 21c (= evacuation instruction registration means).

  The earthquake detection reception unit 21a determines whether or not an earthquake detection notification is included in various information received from the parent device 1. And when it determines with the earthquake detection notification being included, the message which shows an earthquake detection is given to the evacuation instruction | indication part 21b.

  The evacuation instruction unit 21b reads the evacuation instruction data recorded in the flash memory 30 when a telegram indicating earthquake detection is given from the earthquake detection reception unit 21a. Then, the evacuation instruction is performed by outputting the read evacuation instruction data using the display unit 23 and the speaker 28.

  The evacuation instruction registration unit 21c receives an instruction to select data to be used as evacuation instruction data by the evacuation instruction unit 21b from the image data and audio data recorded in the flash memory 30. The selection result is recorded in the flash memory 30. The evacuation instruction unit 21b refers to the selection result to determine the evacuation instruction data to be output. The evacuation instruction registration unit 21 c also has a function of receiving image data and audio data from the outside and recording them in the flash memory 30.

  The memory 22 is a medium for temporarily recording various data held by the child device 2, and is configured by, for example, a writable RAM (Random Access Memory). The memory 22 serves as a buffer memory for temporarily recording processing data when various control processes are performed by the control unit 21, instruction commands received from the user, and the like.

  The display unit 23 displays various kinds of information (for example, a caller telephone number at the time of incoming call) held by the handset 2 to the user. As the display unit 23, for example, a small and low power consumption display device such as a liquid crystal panel is used. The input unit 24 is for a user to perform various operations (for example, input of a telephone number of a partner with whom a call is made) for performing communication using the handset 2. The input unit 24 is usually composed of a plurality of operation buttons such as numeric buttons and redial buttons.

  The communication control unit 25 controls wireless communication by the antenna device 26. Thereby, the subunit | mobile_unit 2 can communicate with the main | base station 1 connected to the wireless communication network 42. FIG. Further, it is possible to perform incoming processing, outgoing processing, etc. via the PSTN network 63 by relaying the base unit 1.

  Since the antenna device 26 to the flash memory 30 have the same configuration as the antenna device 16 to the flash memory 20 of the parent device 1, description thereof is omitted here. The battery unit 31 is supplied with electric power from an external power source (not shown) and temporarily stores the electric power. For example, a rechargeable alkaline battery or a lithium ion battery is used.

  The CCD camera 32 is a photographing unit using a CCD as an image pickup device. The CCD photoelectrically converts a light image (optical information) of a subject formed by a photographing lens unit (not shown) into image data of R (red), G (green), and B (blue) color components and outputs the image data. . The CCD is driven by a timing generator (not shown) to control, for example, the aperture and exposure time. Image data obtained by the CCD camera 32 is recorded in the flash memory 30.

The SD card slot 33 is an interface for connecting an SD card memory 99 as an external recording medium and transmitting information. In the SD card memory 99, for example, still images and moving images taken with a digital camera are recorded. The SD card slot 33 copies these data to the flash memory 30 in accordance with an instruction from the evacuation instruction registration unit 21c. As a result, the evacuation instruction registration unit 21c can register images and sounds input from the outside as evacuation instruction data.
<1-4. External structure of slave unit>
FIG. 7 is an external view showing the external structure of the handset 2 according to the first embodiment of the present invention. 7A is an external view of the handset 2 viewed from the side, FIG. 7B is an external view of the handset 2 viewed from the front, and FIG. 7C is a view of the handset 2 viewed from the bottom. FIG.

  As shown in FIG. 7, the subunit | mobile_unit 2 is provided with the display part 23, the input part 24, the antenna device 26, the speaker 28, and the microphone 29 in the front. Moreover, the battery part 31 which can be charged is provided in the bottom face part. An input unit 24 including a plurality of operation button groups is present below the display unit 23 including the liquid crystal panel.

In addition, the handset 2 includes a CCD camera 32 and an SD card slot 33 on its side surface. As a result, it is possible to capture an evacuation instruction image or to input evacuation instruction data from the outside.
<1-5. About the data selection screen for evacuation instructions>
Here, an example of the evacuation instruction data selection screen according to the first embodiment of the present invention will be described with reference to the screen diagram of FIG.

  FIG. 8 is an example of the evacuation instruction data selection screen 80 displayed on the display unit 13 included in the parent device 1 or the display unit 23 included in the child device 2. This screen can be displayed at an arbitrary timing, for example, when a setting button included in the input unit 14 or the input unit 24 is pressed. As shown in FIG. 8, the evacuation instruction data selection screen 80 is configured to include sound and images that can be selected as evacuation instruction data, a solid line cursor 81, and a broken line cursor 82.

  The solid line cursor 81 is a cursor that is being operated by the user with a cross button or the like. The solid line cursor 81 can be moved up and down. In the example shown in FIG. 8, the evacuation instruction voice is selected using this. After selection, a predetermined button, for example, a decision button or the like is pressed, and the selected voice is registered as evacuation instruction data.

The broken line cursor 82 is a cursor that is not being operated by the user. The broken line cursor 82 is replaced with the solid line cursor 81 when a predetermined button, for example, a left / right button included in a cross button is pressed. Thereby, in the example shown in FIG. 8, it is possible to select and register an evacuation instruction image. When the size of the display unit is small, only a part of the evacuation instruction data selection screen 80, for example, only the voice selection unit (= left side of the screen) is displayed, and the image selection unit (= right side of the screen) is displayed by pressing a predetermined button. ) Display may be switched.
<1-6. About evacuation instruction data registration process>
Here, regarding the evacuation instruction data registration process using the master unit 1 and the slave unit 2 in the first embodiment of the present invention, the block diagram of FIGS. 1 to 3, the flowchart of FIG. This will be described with reference to FIG. Since the base unit 1 and the handset 2 have the same processing flow except that the processing subjects are different, the processing flow will be described below using the handset 2 as an example.

  The processing flow shown in FIG. 4 is started when the setting button or the like provided in the input unit 24 is pressed and the mode is shifted to the evacuation instruction data setting mode. After the start of this process, in step S110, the evacuation instruction registration unit 21c determines whether “selection mode” or “recording mode” is selected as the registration method. The “selection mode” is a mode for selecting evacuation instruction data from image data and audio data recorded in the flash memory 30 in advance. The “recording mode” is a mode for newly recording and registering evacuation instruction data from the outside.

  When “selection mode” is selected in step S110, the evacuation instruction registration unit 21c displays the evacuation instruction data selection screen 80 on the display unit 23. In step S120, selection of audio data is accepted. In step S130, selection of image data is accepted.

  Next, in step S140, the evacuation instruction registration unit 21c registers the selected audio data and image data in the flash memory 30 as evacuation instruction data, and then ends this process.

  Returning to step S110, when “recording mode” is selected in step S110, the evacuation instruction registration unit 21c shifts to a state of waiting for input of voice data for evacuation instruction in step S150. For example, when voice data is input using the microphone 29, a character image “please input voice” is displayed on the display unit 23, and the apparatus waits for input. Alternatively, when acquiring from the outside using the SD card slot 33 or the communication control unit 25, the display unit 23 displays the sound data that can be acquired, thereby waiting for designation of the acquired data.

  Next, in step S160, the evacuation instruction registration unit 21c shifts to a state of waiting for input of evacuation instruction image data. For example, when taking an evacuation instruction image using the CCD camera 32, a character image “Please shoot an image” is displayed on the display unit 23, and the camera enters a shooting standby state. Further, like audio data, it may be in a form of waiting for designation of a still image or a moving image that can be acquired from the outside.

Next, in step S170, the evacuation instruction registration unit 21c registers the recorded audio data and image data in the flash memory 30 as evacuation instruction data, and then ends this process.
<1-7. About Evacuation Instruction Processing>
Here, with respect to the evacuation instruction processing at the time of receiving the earthquake early warning using the master unit 1 and the slave unit 2 in the first embodiment of the present invention, the block diagrams of FIGS. 1 to 3 and FIGS. This will be described with reference to a flow diagram.

  FIG. 5 is a processing flow of the base unit 1 that is waiting to receive the earthquake early warning. The processing flow shown in FIG. 5 can be started at an arbitrary timing in a state where the power source of the base unit 1 is activated and communication with the Internet 62 is possible. After the start of this processing, in step S210, the breaking news receiving unit 11a determines whether or not the emergency earthquake breaking news has been received from the Internet 62 by the communication control unit 15.

  When it is determined that the emergency earthquake bulletin has not been received, the process proceeds to step S210 again, and monitoring is continued until the emergency earthquake bulletin is detected. When the reception of the earthquake early warning is detected, the bulletin receiving unit 11a performs a process of analyzing the message included in the earthquake early warning in step S220. Thereby, the predicted seismic intensity, the predicted arrival time of the main motion, and the like are calculated from various parameters included in the message.

  Next, in step S230, the earthquake detection transmission unit 11b transmits an earthquake detection notification indicating that an emergency earthquake warning has been detected to one or a plurality of slave units 2 using the communication control unit 15 and the antenna device 16.

  Next, in step S240, the evacuation instruction unit 11c reads the evacuation instruction data registered in advance by the evacuation instruction registration unit 11d from the flash memory 20. Then, the display unit 13 and the speaker 18 are used to output sound and images based on the evacuation instruction data.

  Next, the processing flow in the subunit | mobile_unit 2 is demonstrated using the flowchart of FIG. The processing flow shown in FIG. 6 can be started at an arbitrary timing when the handset 2 is in a standby state and wireless communication with the base unit 1 is possible. After the start of this process, the earthquake detection reception unit 21a determines whether or not the earthquake detection notification is received from the parent device 1 by the antenna device 26 in step S310.

  If it is determined that the earthquake detection notification has not been received, the process proceeds to step S310 again, and monitoring is continued until the earthquake detection notification is detected. When the reception of the earthquake detection notification is detected, the evacuation instruction unit 21b reads the evacuation instruction data registered in advance by the evacuation instruction registration unit 21c from the flash memory 30 in step S320. Then, the display unit 23 and the speaker 28 are used to output sound and images based on the evacuation instruction data.

Next, a second embodiment of the present invention will be described with reference to the drawings.
[Embodiment 2]
<2-1. About the configuration of the telephone system>
Since it is the same content as Embodiment 1, description is abbreviate | omitted here.
<2-2. About the internal structure of the main unit>
The components are the same as those in the first embodiment, but the functions of the evacuation instruction unit 11c and the evacuation instruction registration unit 11d are partially different from those in the first embodiment. The evacuation instruction unit 11c according to the present embodiment determines evacuation instruction data to be used, using an evacuation instruction table in which the installation location of the parent device 1 and evacuation instruction data corresponding to the installation location are associated with each other. Similarly, the evacuation instruction registration unit 11d receives an evacuation instruction data selection instruction using the evacuation instruction table and performs registration. Details of the evacuation instruction table will be described later.
<2-3. About the internal structure of the slave unit>
The components are the same as those in the first embodiment, but the functions of the evacuation instruction unit 21b and the evacuation instruction registration unit 21c are partially different from those in the first embodiment. In addition, since the evacuation instruction | indication part 21b and the evacuation instruction | indication registration part 21c have the same function as said evacuation instruction | indication part 11c and the evacuation instruction registration part 11d, description is abbreviate | omitted here.
<2-4. External structure of slave unit>
Since it is the same content as Embodiment 1, description is abbreviate | omitted here.
<2-5. About the data selection screen for evacuation instructions>
Here, an example of the evacuation instruction data selection screen according to the second embodiment of the present invention will be described with reference to the screen diagram of FIG.

  FIG. 12 is an example of the evacuation instruction data selection screen 90 displayed on the display unit 13 included in the parent device 1 or the display unit 23 included in the child device 2 of the present invention. This screen can be displayed at an arbitrary timing, for example, when a setting button included in the input unit 14 or the input unit 24 is pressed. As shown in FIG. 12, the evacuation instruction data selection screen 90 includes voice data and image data prepared for each installation location of the communication device (= master device 1 or slave device 2), and a cursor 91. It is configured.

The cursor 91 is a cursor that the user can move up and down with a cross button or the like. The user uses this to select the installation location of the communication device, that is, the location where the evacuation instruction is given. After the selection, a predetermined button, for example, a decision button or the like is pressed, so that audio data and image data associated with the selected installation location are registered as evacuation instruction data. For example, in the example shown in FIG. 12, when living is selected as the installation location, voice data “Please hide under the table” and image data indicating that it is hidden under the desk are registered as evacuation instruction data. Is done.
<2-6. About evacuation instruction data registration process>
Registration of the evacuation instruction data of this embodiment is performed using an evacuation instruction table. FIG. 11 is a table showing an example of the evacuation instruction table. As shown in FIG. 11, the evacuation instruction table of the present embodiment is composed of three columns of “installation location” column, “voice data” column and “image data” column in order from the left.

  The “installation place” column indicates a place where the communication device is assumed to be installed, and there are a child room, a kitchen, a living room, and the like. The “voice data” column indicates the file name of voice data used according to the installation location. In the example shown in FIG. 12, an audio file in the WAV format is registered. The “image data” column indicates the file name of image data used according to the installation location. In the example shown in FIG. 12, a JPG still image file or a MOV moving image file is registered.

  The evacuation instruction registration unit 11d and the evacuation instruction registration unit 21c display the evacuation instruction data selection screen 90 described above by referring to the evacuation instruction table. Further, the evacuation instruction unit 11c and the evacuation instruction unit 21b determine the file name of the evacuation instruction data to be used by collating the installation location received from the user on the evacuation instruction data selection screen 90 with the evacuation instruction table. To do.

The file names shown in the “audio data” field and the “image data” field may be appropriately changed by the user. Moreover, the form which can add / delete the kind of installation place may be sufficient. However, the file name data to be registered in the table needs to be recorded in advance in the flash memory 20 (flash memory 30 in the case of the slave unit 2).
<2-7. About Evacuation Instruction Processing>
Here, with respect to the evacuation instruction processing at the time of receiving the earthquake early warning using the master unit 1 and the slave unit 2 in the second embodiment of the present invention, the block diagrams of FIGS. 1 to 3 and FIGS. This will be described with reference to a flow diagram. In addition, about the process of the same content as Embodiment 1, description is abbreviate | omitted by adding the same step number.

  FIG. 9 is a processing flow of the base unit 1 prepared for the earthquake early warning. The processing flow shown in FIG. 9 can be started at an arbitrary timing in a state where the power source of the base unit 1 is activated and communication with the Internet 62 is possible. Steps S210 to S230 have the same contents as those in the first embodiment, and thus description thereof is omitted.

  After step S230, the evacuation instruction unit 11c reads the evacuation instruction table from the flash memory 20 in step S250. In step S260, the evacuation instruction data to be used is determined by comparing the installation location previously received from the user by the evacuation instruction registration unit 11d with the evacuation instruction table. The display unit 13 and the speaker 18 are used to output sound and images according to the evacuation instruction data.

  Next, the processing flow in the subunit | mobile_unit 2 is demonstrated, using the flowchart of FIG. The processing flow shown in FIG. 10 can be started at an arbitrary timing in a state where the slave unit 2 is in a standby state and wireless communication with the master unit 1 is possible. Note that step S310 has the same contents as in the first embodiment, and a description thereof will be omitted.

After step S310, the evacuation instruction unit 21b reads the evacuation instruction table from the flash memory 30 in step S330. In step S340, the evacuation instruction data to be used is determined by comparing the installation location received in advance by the evacuation instruction registration unit 21c with the evacuation instruction table. The display unit 23 and the speaker 28 are used to output sound and images according to the evacuation instruction data.
[Other embodiments]
The present invention has been described with reference to the preferred embodiments and examples. However, the present invention is not necessarily limited to the above-described embodiments, and various modifications can be made within the scope of the technical idea. be able to.

  Therefore, the present invention can also be applied to the following embodiments.

  (A) In this embodiment, the wired LAN 41 and the Internet 62 are used as communication lines for the base unit 1 to receive the earthquake early warning. However, other communication networks such as a dedicated line and a cable TV line are used. The form which receives emergency earthquake early warning from may be sufficient. Moreover, the form which acquires an earthquake early warning from a broadcast wave like terrestrial digital broadcasting and BS digital broadcasting may be sufficient.

  (B) In the present embodiment, the configuration in which each functional unit related to the evacuation instruction process is provided in the master unit 1 and the slave unit 2 has been described as an example. However, a part of these functional units is a telephone network, a LAN, or the like. It may be realized by an external device connected via the network. For example, the form which the evacuation instruction | indication table which the evacuation instruction | indication part 11c refers to is recorded on the information processing apparatus (network server etc.) which exists on a network may be sufficient. Thereby, for example, when it is desired to change the contents of the evacuation instruction table, it is possible to collectively change the evacuation instruction tables used by a plurality of communication devices. Therefore, the trouble of changing the contents of the evacuation instruction table for each vehicle can be saved.

  (C) In the present embodiment, a cordless telephone including the master unit 1 and the slave unit 2 is taken as an example of the communication device having the emergency earthquake warning notification function of the present invention. As long as it is a communication device capable of receiving the earthquake early warning, the present invention may be implemented in other devices. For example, it is an embodiment implemented in a facsimile machine, a mobile phone with a wireless LAN connection function, an Internet phone, an IP phone having a slave unit capable of IP communication, a navigation device, an application executed on a PDA or a notebook computer, etc. Also good.

  (D) In this embodiment, the various functional units of the master unit 1 and the slave unit 2 related to the evacuation instruction process of the present invention are realized by executing a program on an arithmetic processing unit such as a microprocessor. Various functional units may be realized by a plurality of circuits.

  (E) In the present embodiment, the slave unit 2 having a wireless communication function is described as an example of the slave unit involved in the evacuation instruction process of the present invention. However, the form which performs the evacuation instruction | indication process of this invention may be sufficient.

  (F) In the present embodiment, the microphone 29, the CCD camera 32, and the SD card slot 33 are described as examples of means for acquiring evacuation instruction data from the outside, but means other than the above, for example, a USB connection terminal The evacuation instruction data may be acquired from an infrared input terminal, an external device connected to a communication network, the Internet, or the like.

These are block diagrams which show the structure of the telephone system of this invention. These are block diagrams which show the structure of the main | base station of the communication apparatus of this invention. These are block diagrams which show the structure of the subunit | mobile_unit of the communication apparatus of this invention. These are flowcharts which show the processing flow of the evacuation instruction data registration process which concerns on 1st embodiment of this invention. These are the flowcharts which show the processing flow of the evacuation instruction | indication process by the side of the main | base station which concerns on 1st embodiment of this invention. These are the flowcharts which show the processing flow of the evacuation instruction | indication process by the side of the subunit | mobile_unit which concerns on 1st embodiment of this invention. These are the external views which show the external appearance of the subunit | mobile_unit of the communication apparatus of this invention. These are screen figures which show the data selection screen for evacuation instructions which concerns on 1st embodiment of this invention. These are the flowcharts which show the processing flow of the evacuation instruction | indication process by the side of the main | base station which concerns on 2nd embodiment of this invention. These are flowcharts which show the processing flow of the evacuation instruction process by the side of the subunit | mobile_unit which concerns on 2nd embodiment of this invention. These are table figures which show the evacuation instruction | indication table which concerns on 2nd embodiment of this invention. These are screen figures which show the data selection screen for evacuation instructions which concerns on 2nd embodiment of this invention.

Explanation of symbols

1 Master unit (main communication device)
11a Breaking news receiver (breaking news receiving means)
11b Earthquake detection and transmission part (earthquake detection and transmission means)
11c Evacuation instruction section (evacuation instruction means)
11d Evacuation instruction registration unit (evacuation instruction registration means)
13 Display Unit 15 Communication Control Unit (First Communication Unit)
16 Antenna device (wireless communication unit)
18 Speaker (voice output unit)
20 Flash memory (recording unit)
2 Slave unit (sub communication device)
21a Earthquake detection receiver (earthquake detection receiver)
21b Evacuation instruction section (evacuation instruction means)
21c Evacuation instruction registration unit (evacuation instruction registration means)
23 display unit 25 communication control unit (second communication means)
26 Antenna device (wireless communication unit)
28 Speaker (voice output unit)
30 Flash memory (recording unit)

Claims (1)

A cordless telephone device comprising a parent device and a plurality of child devices wirelessly connectable to the parent device,
The base unit is a first communication means connectable to a communication network, a breaking news receiving unit that receives an earthquake early warning from the communication network using the first communication means, and the breaking news receiving unit receives an earthquake early warning An earthquake detection transmitter that transmits an earthquake detection notification to the slave unit, and
The slave unit includes an earthquake detection receiving unit that receives an earthquake detection notification from the master unit, a storage unit that preinstalls the slave unit, a storage unit that associates a plurality of audio data and image data, and stores in the storage unit. A speaker that outputs the sound data that is output, an evacuation instruction unit that controls a display unit that displays the image data stored in the storage unit, and a sound corresponding to the selected installation location by the user selecting the installation location A registration unit that registers data and image data as evacuation instruction data in the storage unit,
After the registration of the evacuation instruction data, the slave unit receives the earthquake detection notification from the master unit, and then the evacuation instruction unit uses the evacuation instruction data registered in the storage unit. A cordless telephone device, wherein certain audio data and image data are output from the speaker and the display unit, respectively.

Images