JP2012212321A - Telephone - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a communication system capable of confirming safety of people and surely making notification of the safety in emergency situations.SOLUTION: A normal mode is a mode in a normal time, in which there is low possibility that earthquake will happen or happened. In S110, a master unit transmits a command for switching a slave unit to an earthquake mode. However, there is a possibility that the emergency earthquake advance report is an erroneous report. To deal with the situation, when it is determined that there is no big shake for five minutes in S140, the slave unit 200 is switched to a normal mode in S170 due to low possibility of earthquake that will happen or happened.

Description

  The present invention relates to a telephone that, when receiving a signal, confirms the safety of surrounding humans, transmits and receives the confirmed safety between telephones, and notifies them.

  2. Description of the Related Art In recent years, telephones have been provided that can be notified by an audio message or the like when an earthquake early warning is received from the Internet or the like that notifies of the occurrence of an earthquake.

  Also, in a system composed of a base unit and a handset of a telephone, if the base unit has an input from a device that outputs emergency information such as a fire alarm, the base unit notifies the handset by cordless communication. Things exist.

JP 2009-171281 A

  However, in such a system, if the emergency information is erroneously reported, there is a problem that the notification is made wastefully and is troublesome for the user.

  Including the above-described problems, an object of the present invention is to provide a communication system that can confirm the safety of a person in an emergency and reliably notify the safety.

  In order to achieve this object, the invention according to claim 1 is provided with a connection unit for connecting to a network, and a master unit that performs cordless telephone communication with a plurality of slave units, and a slave unit that performs cordless wireless communication with the master unit A first transmission unit that transmits a first signal to the slave unit when receiving the earthquake early warning from the network via a connection unit; and the emergency earthquake Upon receiving the breaking news, the measuring means for measuring the magnitude of the shaking, the second transmitting means for sending the shaking correlation signal that varies depending on the magnitude of the shaking to the slave unit, and the magnitude of the shaking measured by the measuring means A determination means for determining whether or not the first condition is satisfied, and a creation means for creating safety information indicating the safety of a person existing in the surroundings when the determination means determines that the first condition is satisfied; The judge Is determined to satisfy the first condition, the safety information receiving means for receiving the safety information of the slave unit from each of the slave units after the second transmission unit has transmitted the shake correlation signal, Safety information transmitting means for transmitting the safety information created by the creating means and the safety information received by the safety information to each of the slave units, safety information created by the creating means, and the safety information receiving means And a notification means for performing notification based on the safety information received by the mobile device, wherein the slave device receives the first signal from the master device and then receives a shaking correlation signal from the master device within a predetermined time. When the first determination means for determining whether or not the signal has been received and the first determination means have determined that the fluctuation correlation signal has been received, it is further determined whether or not the fluctuation correlation signal satisfies the second condition. A second determination means; 2 When the determination unit determines that the second condition is satisfied, a generation unit that generates the safety information, a safety information transmission unit that transmits the safety information generated by the generation unit to the parent device, 2 When the judging means judges that the second condition is satisfied, the safety information receiving means for receiving the safety information from the master unit, the safety information created by the creating means, and the safety information receiving means And a notification means for performing notification based on the safety information.

  The invention according to claim 2 is the communication system according to claim 1, wherein, in the base unit, when the determination unit determines that the first condition is not satisfied, the creation unit, The safety information transmission means, the safety information reception means, and the notification means do not perform the respective processes, and the slave unit determines that the second determination means does not satisfy the second condition, The creation unit, the safety information transmission unit, the safety information reception unit, and the notification unit do not perform respective processes.

  The invention according to claim 3 is the communication system according to claim 2, wherein, in the base unit, the second transmission means is configured to perform a first operation when the magnitude of the shaking is equal to or greater than a threshold value. 1 shake correlation signal is transmitted to the slave unit, and if it is not greater than or equal to a threshold value, a second shake correlation signal is transmitted to the slave unit, and the determination means has a magnitude of the swing greater than or equal to the threshold value. In the slave unit, the second determination means determines whether the shake correlation signal received from the master unit is the first shake correlation signal. A communication system is characterized.

  According to a fourth aspect of the present invention, in the communication system according to the first aspect, in the slave unit, the first determination unit determines that the fluctuation correlation signal is not received within the predetermined time. The creation means creates the safety information, the safety information transmission means sends the safety information created by the creation means to a slave device different from the own device, and the first determination means performs the predetermined time. The safety information receiving means receives the safety information of the slave unit different from the own unit from the slave unit different from the own unit, and the notification unit However, a communication system is characterized in that notification is performed based on the safety information created by the creating means and the safety information received by the safety information receiving means.

  According to the communication system of the first aspect, when the probability that a large earthquake has occurred is high, there is an effect that it is possible to reliably notify the safety information of the person to the surroundings.

  Further, the communication system according to claim 2 is a process that is not necessary when the earthquake early warning is received but it is determined to be false information in addition to the effect of the communication system according to claim 1. No effect is performed, and there is an effect that the surrounding people are not bothered.

  Moreover, according to the communication system of Claim 3, in addition to the effect which the communication system of Claim 2 show | plays, there exists an effect that it can be judged reliably whether the big earthquake has occurred.

  According to the communication system of the fourth aspect, even if the parent device falls and breaks down due to the shaking of the earthquake, the safety information of the person can be performed only by the child device. Therefore, in addition to the effect which the communication system of Claim 3 shows, there exists an effect that the safety information of a person can be alert | reported with a higher probability.

3 is a block diagram showing an electrical configuration of base unit 100. FIG. It is a block diagram which shows the electric constitution of the subunit | mobile_unit 200. FIG. It is a schematic diagram of ID table 104a. It is a schematic diagram of the state table 104c. It is a schematic diagram of ID table 204a. It is a schematic diagram of the state table 204c. It is a schematic diagram of the state table 104c. 5 is a flowchart showing a mode switching process executed in the parent device 100. It is a flowchart which shows the mode switching process performed in the subunit | mobile_unit 200. It is a flowchart which shows the process of 1st mode. It is a flowchart which shows the detection process of S310. (A) is a flowchart showing information transmission / reception processing of S320 executed in base unit 100. (B) is a flowchart showing the information transmission / reception process of S320 executed in the slave unit 200. It is a flowchart which shows the alerting | reporting process of S330. It is a flowchart which shows the process of 2nd mode. It is a flowchart which shows the pseudo | simulation main | base station determination process of S830. (A) is the information transmission / reception process of S850. (B) is the information transmission / reception process of S860.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

  The telephone system of the present invention includes a parent device 100 and a plurality of child devices 200. Master device 100 performs digital cordless telephone communication with slave device 200. An example of the digital cordless standard is DECT (Digital Enhanced Cordless Communications). DECT is a standard that uses frequencies in the 1.9 GHz band, and has the advantage of not receiving radio wave interference from 2.4 GHz band wireless devices. Further, when DECT is used, the parent device 100 and the child device 200 can transmit and receive various data such as document data, image data, and moving image data as well as audio data.

  FIG. 1A is a block diagram showing an electrical configuration of base unit 100. The CPU 101, ROM 102, RAM 103, flash memory 104, display control unit 106, operation control unit 108, baseband unit 120, human sensor control unit 115, network control unit 117, and wireless communication control unit 120 are respectively connected via the bus 122. It is connected.

  A master program 102a is stored in a ROM 102, which is a non-rewritable nonvolatile memory. The CPU 101 controls each hardware according to the parent device program 102a. The master program 102a includes various fixed values and predetermined audio data.

  The RAM 103 which is a rewritable volatile memory stores temporarily used data and the like. In addition, the predetermined area of the RAM 103 is provided with an area 103a for storing an information command counter value N used in processing to be described later, and an area 103b for storing an information transmission counter value M.

  The flash memory 104, which is a rewritable nonvolatile memory, stores an ID table 104a, a status table 104c, and the number of slave units 104d. Details of the ID table 104a and the status table 104c will be described later with reference to FIG. The number of slave units 104d indicates the number of slave units 100 whose IDs are registered so as to perform digital cordless telephone communication with the master unit 200. In addition, a message recording area 104b, which is an area for storing voice data of the recorded voice, is provided.

  The display control unit 106 inputs and controls an electric signal to the LCD 105 in accordance with an instruction input from the CPU 101. The LCD 105 displays various icons, characters, and the like according to the electrical signal input from the display control unit 106. The operation button 107 inputs a corresponding electric signal to the operation control unit 108 when pressed by the user. The operation control unit 108 converts the electrical signal input from the operation button 107 into a digital signal and inputs the digital signal to the CPU 101. A microphone 109 and a speaker 110 are connected to the baseband unit 119, and audio input / output performed via the microphone 109 and the speaker 110 is controlled.

  Master device 100 is connected to a network (not shown) via network I / F 116, and can receive an earthquake early warning via network I / F 116 from a contracted provider or the like. The network control unit 117 mediates transmission / reception of signals between the CPU 101 and the network I / F 116.

  Master device 100 can transmit and receive a voice signal and facsimile data to and from an external device connected to a public line (not shown) via telephone line I / F 118 connected to baseband unit 119. .

  When an external line call is performed between the handset 200 and an external device (communication partner), a voice signal input from the public line via the telephone line I / F 118 is demodulated by the baseband unit 120 and wireless communication control is performed. Input to the unit 120. The audio signal input to the wireless communication control unit 120 is converted into digital audio data and transmitted from the antenna 121. On the other hand, the audio data transmitted from the slave unit 200 and received from the antenna 121 is converted into analog audio data by the wireless communication control unit 120 and input to the baseband unit 119. The input voice data is modulated by the baseband unit 119 and transmitted from the telephone line I / F 118 to the public line.

  The earthquake sensor 112 is hardware equipped with an accelerometer, measures the magnitude of shaking in accordance with an instruction input from the CPU 101, and outputs a Gal value (ie, a maximum acceleration value) or SI (Spectral Intensity) value. To do. The earthquake sensor control unit 113 converts the electrical signal input from the earthquake sensor 112 into a digital signal and inputs it to the CPU 101.

  The human sensor 114 includes a plurality of elements that generate a potential difference by infrared energy. Therefore, the temperature distribution can be measured within the predetermined region. When the temperature of the element in the region where the temperature is higher than the surroundings changes, a corresponding electric signal is input to the human sensor control unit 115. The human sensor control unit 115 converts the electrical signal input from the human sensor 114 into a digital signal and inputs the digital signal to the CPU 101.

  Next, the ID table 104a and the state table 104c will be described with reference to FIG. The ID table 104a shown in FIG. 2A stores a unique ID for each of the parent device 100 and all the child devices 200 that perform digital cordless telephone communication with the parent device 100. This ID is used when the parent device 100 performs digital cordless telephone communication with the child device 200. When the parent device 100 transmits a packet including data and commands to the child device 200, the parent device ID is included in the packet as transmission source information. On the other hand, when the base unit 100 receives a packet including data or a command, the base unit 100 confirms whether the received packet includes the ID of the base unit 200, so that the packet is transmitted from the base unit 200. It can be judged. Usually, the ID consists of a 10-digit number, but here it is simply expressed as ID1, ID2, etc. for the sake of simplicity. The status table 104a also stores a slave unit number, which is the number of the slave unit 200.

  The status table 104c shown in FIG. 2B shows that the emergency flag is turned on or off for the parent device 100 and all the child devices 200 that perform digital cordless telephone communication with the parent device 100, and the parent device 100 or the child device. An area for storing the installation location, which is the location where 200 is installed, is provided. The emergency flags are all turned off before the processing of this embodiment is performed. In the process described later, the danger flag corresponding to the telephone set that is determined to have a person who cannot move is set to ON. Only the installation location corresponding to the parent device 100 is stored as the installation location before the processing of the present embodiment is performed. The installation location of parent device 100 is stored, for example, when the user inputs from operation button 107. When the processing of this embodiment is performed, the installation location information of the slave unit 200 is also stored in the state table 104c. The status table 104c also stores a slave unit number, which is the number of the slave unit 200.

  Next, the subunit | mobile_unit 200 is demonstrated using FIG.1 (b). The slave device 200 includes a CPU 201, a ROM 202, a RAM 203, a flash memory 204, a display control unit 206, an operation control unit 208, a baseband unit 219, a human sensor control unit 215, and a wireless communication control unit 220 via a bus 222. It is connected. The detailed description of the points common to the parent device for each hardware is omitted.

  The ROM 202 stores a handset program 202a. CPU201 controls each hardware according to cordless handset program 202a. The slave program 202a includes various fixed values and predetermined audio data.

  The RAM 203 is provided with an area 203c for storing the value L of the pseudo master unit counter in addition to an area 203a for storing the value N of the information command counter and an area 203b for storing the value M of the information transmission counter.

  The flash memory 204 stores an ID table 204a, a status table 204c, and the number of slave units 204d. Details of the ID table 204a and the status table 204c will be described later with reference to FIG. In addition, a message recording area 204b for storing voice data of the recorded voice is provided.

  The slave unit 200 transmits and receives packets including data and commands to and from the master unit 100 and other slave units 200 via the wireless communication control unit 220 and the antenna 221.

  The ID table 204a and the state table 204c will be described with reference to FIG. FIG. 2C is an example of the ID table 204a. About the subunit | mobile_unit number and ID, the same thing as ID table 104a is memorize | stored. When the slave device 200 transmits a packet including data and commands to the master device 100, the packet includes the ID of its own device as transmission source information. On the other hand, when the slave device 200 receives a packet including data or a command, the slave device 200 confirms whether the received packet includes the ID of the master device 100, thereby transmitting the packet from the master device 100. It can be judged. Further, when the child device 200 transmits a packet including data and a command to another child device 200, the packet includes the ID of the own device and the ID of the parent device as transmission source information. On the other hand, when the slave unit 200 receives a packet including data or a command, the slave unit 200 checks whether the received packet includes the ID of the master unit 100 and the ID of another slave unit 200, so that the packet is sent to another child unit. It can be determined that the data has been transmitted from the device 200.

  Further, the ID table 204a is different from the ID table 104a in that an area for storing ON or OFF of the pseudo parent machine flag is provided. The pseudo master unit refers to a slave unit 200 that communicates with another slave unit 200 in place of the master unit when communication becomes impossible due to damage to the master unit. Before the processing of this embodiment is performed, the pseudo master unit flags of all the slave units 200 are off. The pseudo master unit flag of the slave unit 200 determined as the pseudo master unit is set to ON by the processing described later.

  FIG. 2D is an example of the state table 204c. The status table 204c is the same as the status table 104c stored in the parent device 100. However, regarding the installation location, not the installation location of the parent device 100 but the installation location of the child device 200 is stored. For example, since the status table 204c shown in FIG. 2D is stored in the slave unit 200 having the slave unit number 1, only the installation location of the slave unit 200 having the slave unit number 1 is stored. Yes. The method for storing the installation location is the same as in the case of the parent device 100, and thus the description thereof is omitted.

  A mode switching process executed in base unit 100 will be described. This process is started when an emergency earthquake bulletin is received via the network I / F 116 in the normal mode and an emergency earthquake bulletin reception signal is input from the network control unit 117 to the CPU 101. When the magnitude of the shaking is large, the base unit that has received the earthquake early warning checks whether the base unit 100 and all the slave units 200 cannot move around. And when there is a person who cannot move, the process which alert | reports with an audio | voice is performed in cooperation with the subunit | mobile_unit 200. FIG. On the other hand, when the magnitude of the shake is small, the normal state, that is, the state before receiving the earthquake early warning is returned. Hereinafter, specific processing will be described with reference to FIG.

  In S110, the CPU 101 reads out the ID of the parent device and the ID of the child device from the ID table 104a. Then, the CPU 101 controls the wireless communication control unit 120 to transmit a command for switching to the earthquake mode in which each of the child device IDs is a reception destination and the parent device ID is a transmission source to all the child devices 200 (S110). . Further, the CPU 101 starts timing. Then, the process proceeds to S120.

  In S120, the CPU 101 controls the earthquake sensor control unit 113 to cause the earthquake sensor 112 to measure the magnitude of the shake. And CPU101 judges whether a shake is more than a threshold value based on the signal inputted from earthquake sensor control part 113 (S130). If it is determined that the value is equal to or less than the threshold value (S130 / No), the process proceeds to S160, and if it is determined that the value is equal to or greater than the threshold value (S130 / Yes), the process proceeds to S140. The threshold value is included in the parent device program 102a.

  In S140, the CPU 101 controls the wireless communication control unit 120 to transmit a command for switching to the first mode to all the slave units 200 (S140). Then, the process of the first mode of S150 is executed (S160), and the process of the master unit is terminated. Note that S160 is a subroutine, and details thereof will be described with reference to FIG.

  In S160, the CPU 101 determines whether 5 minutes have elapsed since the transmission of the command for switching to the earthquake mode in S110. If it is determined that 5 minutes have passed (S160 / Yes), the process proceeds to S170. On the other hand, if it is determined that 5 minutes have not yet elapsed, the process proceeds to S120.

  In S <b> 170, the CPU 101 controls the wireless communication control unit 120 to cause the antenna 121 to transmit a command for switching to the normal mode to all the slave units 200. Then, the process of the master unit is terminated. Details of the normal mode will be described later.

  Next, the mode switching process performed in the subunit | mobile_unit 200 is demonstrated. This process is started when the slave device 200 receives a command for switching from the master device 100 to the first mode in the normal mode. Hereinafter, specific processing will be described with reference to FIG.

  In S210, during a period of 6 minutes after the start of the mode switching process (S210, No), the wireless communication control unit 220 receives a command including the parent machine ID as the transmission source and the own machine ID as the reception source. (S220). When the CPU 201 determines that a command has been received (S220 / Yes), the CPU 201 proceeds to S230. On the other hand, if it is determined that 6 minutes have passed without receiving the command (S220 / No) (S210 / Yes), the process proceeds to S260, and the earthquake mode process is executed (S260). Note that S260 is a subroutine, the details of which will be described later.

  In S230, the CPU 201 determines whether the mode indicated by the received command is the normal mode or the first mode (S230). When the normal mode is instructed (S230, normal mode), the CPU 201 ends this process. On the other hand, when the first mode is instructed (S230 / first mode), the process proceeds to S240 to execute the process of the first mode. Note that the process of S240 is a subroutine, and details thereof will be described later.

  Here, each of the normal mode and the earthquake mode will be described. The normal mode is a mode at normal time, that is, when an earthquake occurs or is unlikely. In S110 of FIG. 3, the parent device 100 transmits a command for switching the child device 200 to the earthquake mode. However, there is a possibility that the earthquake early warning is a false alarm. For this reason, when it is determined in S140 that there has been no significant shaking for 5 minutes, since the earthquake has occurred or is unlikely to have occurred, the handset 200 is switched to the normal mode in S170.

  The earthquake mode is a mode in which the parent device 100 transmits the fact that an emergency earthquake warning has been announced to the child device 200 and determines the subsequent high risk level. That is, when it is determined that the shake is large and dangerous, it is determined that the processing in the first mode is performed. And the subunit | mobile_unit also switches to 1st mode. On the other hand, if it is determined that the shaking is small and not dangerous, the slave device 200 is switched to the normal mode, and the device itself returns to the normal mode.

  On the other hand, in handset 200, earthquake mode is a mode for determining a mode to be taken thereafter. The fact that an earthquake early warning has been received means that there is a high probability that a large earthquake will occur. For this reason, there is a possibility that the parent device breaks down and communication with the parent device cannot be performed thereafter. Therefore, in S220, it is determined whether a command is transmitted from the parent device 100. If no command is received from the parent device 100, it is highly possible that the parent device is out of order, so the mode is switched to the second mode in which the child devices 200 cooperate with each other without using the parent device. When a command is received from the parent device, the mode is switched to the normal mode or the first mode according to the command.

  With reference to FIG. 5, processing in the first mode executed in the parent device 100 and the child device 200 will be described. In both the parent device 100 and the child device 200, a detection process in S310, an information transmission / reception process in S320, and a notification process in S330 are performed. The detection process of S310 is a process of confirming safety when there is a person around, and the same process is performed in the parent device 100 and the child device 200. Details thereof will be described with reference to FIG.

  In the information transmission / reception process of S320, the parent device 100 acquires the safety information acquired by each of the parent device 100 and the child device 200 in the processing of S310, and transmits the acquired safety information of all telephones to the child device 200. It is processing. Details will be described with reference to FIG.

  The notification process in S330 is a process in which each of the parent device 100 and the child device 200 notifies the safety information of all the telephones. The same processing is performed in the parent device 100 and the child device 200. Details thereof will be described with reference to FIG.

  The detection process in S310 will be described. As described above, the detection process illustrated in FIG. 6 is performed in each of the parent device 100 and the child device 200. Here, description will be given by taking the base unit 100 as an example. First, the CPU 101 inputs an instruction to control the human sensor 114 to the human sensor control unit 115. Then, the human sensor control unit 115 controls the human sensor 114 and an electric signal corresponding to the detection result of the human sensor 114 is input to the human sensor control unit 115. The CPU 101 determines whether there is a person around the device based on the signal input from the human sensor control unit 115 (S410). If it is determined that there is a person (S410: Yes), the process proceeds to S420. On the other hand, if it is determined that there is no person (No in S410), the detection process is terminated.

  In S420, the CPU 101 starts measuring time, and until the five minutes have passed (S420, No), a message prompting the user around the telephone to input cancellation from the operation unit 106 is sent to the voice control unit 111. The process of controlling and emitting sound from the speaker 109 (S430) and the process of determining whether or not cancel has been input from the operation unit 106 (S440) are repeated. The following can be considered as an example of the message. “There was a big earthquake. Confirm the safety of the customer. If it is safe, press the cancel button.” Such a message is included in the main unit program 102a from the time of factory shipment. When the CPU 101 determines that an electrical signal corresponding to the cancel button provided on the operation button 107 is input from the operation control unit 108 (S440: Yes), the detection process is terminated. On the other hand, if the CPU 101 determines that five minutes have elapsed without receiving an electrical signal corresponding to the cancel button (S440 · No), the process proceeds to S450.

  In S450, the CPU 101 performs a sound recording process (S450). More specifically, first, the CPU 101 controls the voice control unit 111 to emit a message from the speaker 109 explaining that voice recording is to be performed. For example, the message is as follows. After that, the CPU 101 controls the voice control unit 111 to store the voice data collected from the microphone 109 in the recording area 104b for a predetermined time. Then, the process proceeds to S460.

  In S460, the CPU 101 turns on the emergency flag corresponding to the own device in the state table 104c. Then, the detection process ends. As described above, this detection process is also performed in the slave unit 200. For the details, in the description of FIG. 6, the hardware included in the parent device 100 may be replaced with the hardware included in the child device.

  An information transmission / reception process performed in the parent device will be described with reference to FIG. The CPU 101 sets the value N of the information request counter 103a to 1 (S510), and proceeds to S520.

  In S520, the CPU 101 controls the wireless communication control unit 120 to request a reply from the status table 204c using the ID of the slave device 200 whose slave device number is N as the reception destination and the ID of the slave device as the transmission source. Are transmitted (S520). In this case, for example, if the value N of the information request counter 103a is 1, the ID of the slave unit having the slave unit number 1 is designated as the receiving destination.

  In step S530, the CPU 101 determines whether the wireless communication control unit 120 has received a reply to the command transmitted in step S520 (step S530). If the CPU 101 determines that a reply has been received (S530, Yes), the CPU 101 proceeds to S540, and from the status table 204c included in the reply, the transmission source ID (that is, the slave device 200 set as the command reception destination in S520). ID), location of the slave unit, and on / off of the emergency flag. Then, the read source ID, location of the slave unit, and ON / OFF of the danger flag are stored in the corresponding area of the status table 104c (S540). On the other hand, if the CPU 101 determines that no reply has been received within the predetermined time (S530, No), it skips S540 and proceeds to S550.

  In S550, the CPU 101 adds 1 to the value N of the information request counter 103a (S550), and proceeds to S560.

  In S560, the CPU 101 determines whether the value N of the information request counter 103a exceeds the value of the number of slave units 104d (S560: Yes), proceeds to S570, and determines that it has not exceeded (S560. No), go to S520.

  In S570, the CPU 101 sets the value M of the information transmission counter 103b to 1. Then, the process proceeds to S580.

  In S580, the CPU 101 controls the wireless communication control unit 120 to transmit the status table 104c with the ID of the slave device 200 whose slave device number is M as the reception destination and the ID of the own device as the transmission source ( S580). Then, the process proceeds to S590, 1 is added to the value M of the information transmission counter 103b, and the process proceeds to S5100.

  In S5100, the CPU 101 determines whether or not the value M of the information transmission counter 103b has exceeded the value of the number of slave units 104d. If the CPU 101 determines that the value M has exceeded (Yes in S5100), the CPU 101 terminates the information transmission / reception process and determines that it has not exceeded (S5100). -No), it progresses to S580.

  An information transmission / reception process performed in the slave unit will be described with reference to FIG. In S610, the CPU 201 determines whether or not the wireless communication control unit 220 has received a command having the ID of its own device as the reception destination and the ID device of the parent device as the transmission source (S610). Note that this command is the command transmitted by the parent device 100 in S520 of FIG. If the CPU 201 determines that a command has not yet been received (No at S610), the determination is repeated (S610). If the determination is affirmed while the determination is repeated (Yes in S610), the process proceeds to S620.

  In S620, the CPU 201 controls the wireless communication control unit 220 to transmit the status table 204c as a reply to the command received in S610.

  In step S630, the CPU 201 determines whether the wireless communication control unit 220 has received 104c from the parent device 100 (step S630). If it is determined that it has not been received yet (S630, No), the determination is repeated (S630), and if it is determined that it has been received (S630, Yes), the process proceeds to S640.

  In S640, the CPU 201 reads on / off of the danger flag of the parent device 100 and the other child devices 200 and the installation location from the state table 104c received in S630, and stores them in the state table 204c (S640). Then, the information transmission / reception process ends.

  The notification process in S330 will be described with reference to FIG. As described above, the notification process illustrated in FIG. 8 is performed in each of the parent device 100 and the child device 200. This process is a process for notifying the safety information of users around the device detected in S310 and the safety information of other telephones obtained by the information transmission / reception process in S320 by voice. Here, description will be given by taking the base unit 100 as an example. First, the CPU 101 controls the voice control unit 111 to cause the microphone 109 to collect sound (S710). Then, the process proceeds to S720.

  In S720, the CPU 101 determines whether the collected sound is equal to or higher than the threshold value (S720). If it is determined that the collected voice is equal to or higher than the threshold value, the CPU 101 waits for 10 minutes (S770) and proceeds to S710. On the other hand, if it is determined that the value is equal to or less than the threshold value (S720 / No), the process proceeds to S730. The threshold value is included in the parent device program 102a.

  In S730, the CPU 101 controls the audio control unit 111 to emit the content of the state table 104c from the speaker 109. For example, when the status table is as shown in FIG. 2 (e), the contents are as follows. “There are people who can't move in the kitchen. There are people who can't move in the children's room.” Then, the CPU 101 starts timing and proceeds to S740.

  In S740, after starting the processing of S740, the CPU 101 determines whether three days have elapsed since the start of timing (S740), and determines that it has not elapsed (S740 No), proceeds to S750. move on. On the other hand, if it is determined that three days have elapsed since the start of timing (S740 / Yes), the notification process is terminated.

  In S750, the CPU 101 determines whether or not cancel is input from the operation unit 106 (S750). If it is determined that the cancel is not input yet, the CPU 101 proceeds to S710. On the other hand, if it is determined that the cancel is input (S750 / Yes), the process proceeds to S760.

  In S760, the CPU 101 reads out the voice message from the message recording area 104b and controls the voice control unit 107 to emit the voice message from the speaker 109. Then, this process ends.

  It should be noted that the voice message is emitted only when S720 · No, that is, when the surrounding volume is equal to or lower than the threshold value, for the following reason. Generally, when a house collapses due to an earthquake and there is a person who lay down, a silent time, which is a time zone in which heavy machinery or the like is stopped, is provided in order to avoid hearing a rescue voice. Therefore, while sound is generated by a heavy machine or the like, the sound emission process is not performed, and the sound emission process is performed only during the silent time, so that notification can be performed efficiently. In addition, the battery depletion can be delayed.

  As described above, in the first mode, the parent device 100 and the child device 200 cooperate with each other, and when there is a person who cannot move around, the fact can be notified efficiently.

  Next, the process in the second mode of S260 will be described. As described above, in the second mode, when there is a high possibility that the master unit is out of order, in cooperation with other slave units 200, if there is a person who cannot move around, the fact is effectively notified. Mode. Hereinafter, specific processing performed in the slave unit 200 will be described with reference to FIG.

  First, in S810, the CPU 106 starts measuring time (S810). Hereinafter, for the convenience of explanation, the measured time is referred to as a synchronous timer measurement time. In the process of FIG. 10 to be described later, all the slave units 200 need to start the process of S920 at the same time. However, in the detection process of S820, there is a possibility that the timing at which the process ends in each slave device 200 is shifted. Therefore, when all the slave units 200 start the process of S920 in FIG. 10 after a predetermined time has elapsed from S810, the processes can be started at the same time.

  In S820, a detection process is performed. This process is a subroutine, the details of which are the same as in FIG. Therefore, detailed description is omitted. Then, the process proceeds to S830.

  In S830, a pseudo master unit determination process is performed. This process is a subroutine, and details thereof will be described later with reference to FIG. S830 is a process of determining a pseudo master unit among a plurality of slave units. The pseudo master device in the present embodiment refers to the slave device 200 that performs the same processing as the processing performed by the master device 100 in the first mode. When the pseudo master unit determination process is completed, in the ID tables 204a of all the slave units 200, the pseudo master unit flag of the slave unit 200 determined as the pseudo master unit is set to ON.

  In S840, the CPU 201 refers to the ID table 204a and determines whether the own device is a pseudo master device (S840). If it is determined that the own device is a pseudo master device (S840 / Yes), the process proceeds to S850, and if it is determined not to be a pseudo master device (S840 / No), the process proceeds to S860.

  In S850, information transmission / reception processing as a pseudo master device is performed, and in S860, information transmission / reception processing of slave devices other than the pseudo slave device is performed. These processes are subroutines, the details of which will be described later with reference to FIGS. 11 (a) and 11 (b). Then, when the process of S850 or S860 is performed, the process proceeds to S870. This process is a subroutine, and the details thereof are the same as those described with reference to FIG.

  Details of the pseudo parent device determination process in S830 will be described with reference to FIG. In step S910, the CPU 201 determines whether the measurement time of the synchronization timer has passed 10 minutes. If it is determined that the synchronization timer has not yet elapsed (No in step S910), the CPU 201 repeats the determination until it determines that 10 minutes have elapsed. . If it is determined that 10 minutes have passed (S910 / Yes), the process proceeds to S920.

  In S920, the CPU 201 sets the value L of the pseudo master device counter 203c to 1 (S920). Then, the process proceeds to S930.

  In S930, the CPU 201 determines whether or not the value of the pseudo master device counter 203c is equal to the own device number. If it is determined that they are equal (S930 / Yes), the process proceeds to S940. On the other hand, when it is determined that they are not equal (No in S930), time measurement is started and the process proceeds to S960.

  In S940, the CPU 201 turns on the pseudo parent machine flag of the own machine in the ID table 204a (S940). Then, the process proceeds to S950.

  In S950, the CPU 201 controls the wireless communication control unit 220 to transmit a command indicating that the own device is a pseudo master device to the other slave devices 200. Then, the pseudo master unit determination process ends. At this time, the transmission source ID is added to the transmitted command together with the ID of the own device read from the ID table 204a. Then, the child device that has received the command transmitted in S950 determines that the received command is transmitted from the child device 200 corresponding to the same parent device 100, based on the added parent device ID. Therefore, even if there is a child device 200 connected to the same model and a different parent device 100 in the vicinity, there is no possibility that digital cordless telephone communication is erroneously performed between such child devices 200.

  In S960, the CPU 201 determines whether 5 minutes have elapsed since the start of timing, and if it has not yet elapsed (No in S960), the CPU 201 proceeds to S970.

  In S970, it is determined whether the wireless communication control unit 220 has received a command transmitted from the child device 200 having the same parent device and indicating the pseudo parent device. At this time, whether the command indicating that it is a pseudo master device is transmitted from the slave device 200 having the same master device is determined by the master device stored in the ID table 204a as the command source ID. Judgment is made based on whether the ID and the ID of the slave unit are included. Note that the command received in S970 is a command transmitted from another child device 200 in S950. If the determination in S970 is affirmative (S970, Yes), the process proceeds to S980. On the other hand, if the determination in S970 is negative (S970, No), the process proceeds to S960.

  In S980, the CPU 201 reads from the packet the child device ID that is the transmission source of the packet received in S970, and turns on the pseudo parent device flag of the child device corresponding to the read ID in the ID table 204a (S980). Then, the pseudo master unit determination process ends.

  In S990, the CPU 201 adds 1 to the value L of the pseudo master device 203c (S990), and proceeds to S930.

  Details of the processing in S850 will be described with reference to FIG. This process is similar to the process performed in the parent device 100 described with reference to FIG. For this reason, similar steps are denoted by the same reference numerals. However, the part designated as the master unit 100 in FIG. 7A is read as a pseudo master unit. In addition, the numbers of the respective hardware are also read as the numbers of the hardware included in the slave unit 200.

  Hereinafter, the process which attached | subjected the different code | symbol is demonstrated. In S1010, the CPU 201 sets the value N of the information request counter 203a to a value obtained by adding 1 to the slave unit number of its own device. This is due to the following reason. In the process of FIG. 10, a process is performed in which the slave unit 200 with the younger slave unit number is preferentially a pseudo master unit. Therefore, in FIG. 10, the child device 200 having a younger child device number is more likely not to be operating due to a failure or the like than the child device 200 that has become the pseudo parent device. For this reason, in the process of FIG. 7A, no command or transmission of the status table 204c (S520, S580) is performed to the child device 200 having a child device number younger than the child device 200 that is the pseudo parent device. .

  In S1020, the CPU 201 sets the value M of the information transmission counter 203b to a value obtained by adding 1 to the slave unit number of its own device. The reason for this is the same as that of S1010 described above, and a detailed description thereof will be omitted.

  Details of the processing in S860 will be described with reference to FIG. This process is similar to the process performed in the slave device 200 described with reference to FIG. The only difference is that a place where the master unit 100 is located becomes a pseudo master unit. Therefore, detailed description is omitted.

  As described above, the slave unit 200 can perform digital cordless telephone communication between the slave units 200 without passing through the master unit 100 when the instruction from the master unit 100 is not transmitted in the earthquake mode. And the safety of surrounding users is transmitted / received using the cordless telephone communication between the subunit | mobile_unit 200. FIG. And the safety information of the user who transmitted / received can be alert | reported. Therefore, even if the parent device 100 is damaged due to an earthquake or the like, it is possible to inform the surroundings of the safety of the user.

  Moreover, the subunit | mobile_unit 200 performs an alerting | reporting process when the surrounding sound volume is below a threshold value. Therefore, the notification process can be efficiently performed in accordance with the silent time.

  The cordless telephone communication may not be DECT. For example, spSHS (super personal handy-phone system) may be used.

  In S410 of FIG. 6, the CPU 101 may determine that a person exists even if an electric signal corresponding to a region where the temperature is higher than the surroundings is simply input from the human sensor 114. That is, even if the person does not move, the human sensor 114 inputs an electric signal to the human sensor control unit 115. In addition, the human sensor 114 may detect a person with ultrasonic waves.

  In the mode switching process of FIGS. 3 and 4, the following may be performed. In S140 and S170 of FIG. 3, the CPU 101 controls the wireless communication control unit 120 to transmit the detected magnitude of shaking to all the slave units 200. Furthermore, in S230 of FIG. 4, the CPU 201 determines whether or not the magnitude of the vibration transmitted from the parent device is greater than or equal to a threshold value. If it is determined that the value is equal to or less than the threshold value (No in S230), the mode switching process is terminated. However, in this case, the slave program 202a includes a threshold value of the magnitude of shaking.

100 Base unit 101 CPU
102 ROM
103 RAM
104 Flash memory 105 LCD
107 operation buttons 115 human sensor 117 network control unit 119 baseband unit 120 wireless communication unit 200 slave unit 201 CPU
202 ROM
203 RAM
204 Flash memory 205 LCD
207 Operation buttons 215 Human sensor 219 Baseband unit 220 Wireless communication unit

Claims (4)

A communication system comprising a connection means for connecting to a network, including a master unit that performs cordless telephone communication with a plurality of slave units, and a slave unit that performs cordless wireless communication with the master unit,
The base unit is
A first transmission means for transmitting a first signal to the slave unit upon receiving an earthquake early warning from the network via a connection means;
Upon receiving the earthquake early warning, measuring means for measuring the magnitude of shaking;
A second transmission means for transmitting a fluctuation correlation signal that varies depending on the magnitude of the fluctuation to the slave unit;
Determination means for determining whether or not the magnitude of the shake measured by the measurement means satisfies the first condition;
When the determination means determines that the first condition is satisfied, a creation means for creating safety information indicating the safety of a person existing in the surroundings;
When the determination means determines that the first condition is satisfied, the safety information reception for receiving the safety information of the slave unit from each of the slave units after the second transmission unit transmits the shake correlation signal. Means,
Safety information transmitting means for transmitting the safety information created by the creating means and the safety information received by the safety information to each of the slave units,
Informing means for informing based on the safety information created by the creating means and the safety information received by the safety information receiving means,
The slave is
First determination means for determining whether or not a shaking correlation signal is received from the parent device within a predetermined time after receiving the first signal from the parent device;
When the first determination means determines that the fluctuation correlation signal has been received, second determination means further determines whether the fluctuation correlation signal satisfies the second condition;
Creating means for creating the safety information when the second judging means judges that the second condition is satisfied;
Safety information transmitting means for transmitting the safety information created by the creating means to the master unit;
Safety information receiving means for receiving the safety information from the master unit when the second determination means determines that the second condition is satisfied;
A communication system comprising: safety information created by the creation means; and notification means for performing notification based on the safety information received by the safety information reception means. The communication system according to claim 1,
In the base unit,
When the determination unit determines that the first condition is not satisfied, the creation unit, the safety information transmission unit, the safety information reception unit, and the notification unit do not perform the respective processes.
The slave is
When the second determination means determines that the second condition is not satisfied,
The creation unit, the safety information transmission unit, the safety information reception unit, and the notification unit do not perform respective processes. A communication system according to claim 2,
In the base unit,
The second transmission means transmits a first fluctuation correlation signal to the slave unit when the magnitude of the fluctuation is equal to or greater than a threshold value, and outputs a second fluctuation correlation signal when the magnitude of the fluctuation is not equal to or greater than the threshold value. Send to the slave unit,
The determination means determines whether or not the magnitude of the shake is equal to or greater than the threshold value.
In the slave unit, the second determination unit determines whether or not the shake correlation signal received from the master unit is the first swing correlation signal. The communication system according to claim 1,
In the slave unit,
When the first determining means determines that the fluctuation correlation signal has not been received within the predetermined time, the creating means creates the safety information,
The safety information transmitting means transmits the safety information created by the creating means to a slave device different from the own device,
If the first determining means determines that the fluctuation correlation signal has not been received within the predetermined time, the safety information receiving means indicates the safety information of the slave unit different from the own device as the own device. Received from a different handset,
A communication system, wherein the notification means performs notification based on safety information created by the creation means and safety information received by the safety information receiving means.

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