JP2009177294A - Cradle apparatus, server, control method, control program, and recording medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To limit the data amount to be stored in a server and to inform an abnormal state to a user or a third party in real time. <P>SOLUTION: A portable telephone 111 is mounted in a cradle apparatus 110. The cradle apparatus 110 includes an input section 1001, a determination section 1003, and a control section 1004. The input section 1001 inputs detection information from a predetermined sensor. The determination section 1003 determines whether the active state of a human body or an object is different from a normal state (hereinafter referred to "abnormal state") or not using the detection information input to the input section 1001. If a determination is made that the active state is abnormal at the determination section 1003, the control section 1004 controls the portable telephone 111 to transmit information indicating an abnormal state to a server 120. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a cradle device, a server, a control method, a control program, and a recording medium on which a mobile phone device is placed.

  In recent years, mobile phone devices capable of making calls and e-mails as mobile communication have become widespread. Such a cellular phone device can be carried by a user by charging a battery. The battery is charged by, for example, using a cradle that is a stand-type expansion device and placing a mobile phone on the cradle.

  Moreover, by placing a mobile phone on the cradle, not only charging the battery, but also transmitting / receiving data between the PC and the mobile phone by connecting a PC (Personal Computer) and the cradle using a USB cable, for example. It is also possible to perform.

  In addition to this, a technique has been proposed in which a function as a drive recorder is provided using a mobile phone and a cradle. For example, a teleconverter lens that adjusts the focal length is incorporated in the cradle device, and an image at the time of traveling taken by a camera built in a camera-equipped mobile phone is transmitted to the server, and the server records the image. A cradle has been proposed (see, for example, Patent Document 1 below).

JP 2004-235964 A

  However, the technique of Patent Document 1 described above is a configuration in which a captured image is simply recorded on a server, and the load on the server is unavoidable due to the enormous amount of data that is sequentially recorded. When verifying, there is a problem that the target data must be searched from the recorded data.

  Furthermore, the technique of Patent Document 1 merely captures and records a running image, and even when the moving body is in an emergency state such as an accident, a third party other than the witness can be in the emergency state. There was a problem that it was not possible to know in real time.

  In order to solve the above-described problems caused by the prior art, the present invention reduces the load on the server, and when a human body or an object is in a state different from a normal state, a third party or a user An object of the present invention is to provide a cradle device that can know the state in real time.

  In order to solve the above-described problems and achieve the object, a cradle device according to the present invention includes an input unit for inputting detection information from a predetermined detection sensor in the cradle device on which a mobile phone device is placed, and the input unit. Using the detection information input to the determination means for determining whether the operation state of the human body or the object is different from the normal state (hereinafter referred to as “abnormal state”); And a control unit that transmits information indicating the abnormal state from the mobile phone device to an external server when it is determined that the state is an abnormal state.

  The cradle device according to the present invention is the cradle device mounted on a moving body, further comprising a detecting means comprising an acceleration sensor for detecting the acceleration of the moving body, wherein the input means is detected by the detecting means. The acceleration information is input, the determination means determines whether or not the acceleration is within a predetermined range, and the control means transmits information indicating an abnormal state when the acceleration exceeds a predetermined range. It is characterized by transmitting from the telephone device to the server.

  The cradle device according to the present invention is the cradle device arranged in the vicinity of a detection sensor for detecting a human respiratory rate, heart rate or body movement, wherein the input means receives detection information from the detection sensor. The determination means determines whether or not the respiration rate or the heart rate is within a predetermined range using the detection information input to the input means, and the control means When the number or the heart rate exceeds a predetermined range, information indicating an abnormal state is transmitted from the mobile phone device to an external server.

  Further, a cradle device according to the present invention is the cradle device arranged in the vicinity of a security sensor installed indoors or outdoors, wherein the input means inputs detection information from the security sensor, The determination means determines whether or not the detection information input to the input means indicates an abnormality, and the control means determines that the detection information indicates an abnormality when the determination means determines that the detection information indicates an abnormality. Is transmitted from the mobile phone device to an external server.

  The cradle apparatus according to the present invention is characterized in that in the above-mentioned invention, the cradle device further comprises a storage means for storing the detection information input to the input means.

  In the cradle device according to the present invention, in the above-mentioned invention, the acquisition means for updating the information stored in the storage means and the peripheral imaging information imaged by the camera built in the mobile phone device is acquired. And the storage means stores the imaging information acquired by the acquisition means, and the update means updates the imaging information stored in the storage means at a predetermined interval. To do.

  The cradle apparatus according to the present invention is the cradle device according to the above invention, wherein the control means captures image information stored in the storage means when the determination means determines that the operating state of a human body or an object is abnormal. Is stored, and the stored imaging information is transmitted from the mobile phone device to the server as information indicating the abnormal state.

  The cradle device according to the present invention further comprises registration means for registering information of a user terminal device as a transfer destination of information indicating the abnormal state in the above invention, and the control means indicates the abnormal state. Information and user terminal device information registered in the registration means are transmitted from the mobile phone device to an external server.

  In the cradle apparatus according to the present invention as set forth in the invention described above, the storage means is a non-volatile storage medium.

  In the cradle device according to the present invention, in the above invention, a housing for accommodating the mobile phone device, buffer means provided in the housing and having an airbag, and presence / absence of the mobile phone device in the housing are determined. Detecting means for detecting, and when the mobile phone device is detected in the housing by the detecting means, the mobile phone device is sent to the air bag of the buffer means to send air to the buffer means And pressurizing means for applying a force for fixing.

  The cradle device according to the present invention is characterized in that, in the above-mentioned invention, the cradle device further comprises power supply means for supplying power to the mobile phone device in the housing.

  The server according to the present invention is a state in which the operating state of a human body or an object is different from a normal state (hereinafter referred to as “abnormal state”) from the cradle device on which the mobile phone device is placed via the mobile phone device. Receiving means for receiving the information indicating the abnormal state and the information of the user terminal device to which the information indicating the abnormal state is transferred, and transferring the information indicating the abnormal state received by the receiving means to the user terminal device And a transfer means.

  The server according to the present invention also provides information on a user terminal device that is a transfer destination of information indicating a state (hereinafter referred to as “abnormal state”) in which the operating state of a human body or an object is different from a normal state. Registration means for pre-registering each time, receiving means for receiving detection information detected by a predetermined detection sensor from the cradle device on which the mobile phone device is placed via the mobile phone device, and receiving by the receiving means Using the detected information, a determination unit that determines whether or not the operation state is an abnormal state, and when the determination unit determines that the operation state is an abnormal state, information indicating the abnormal state, Control means for transmitting to the user terminal device registered in the registration means.

  According to another aspect of the present invention, there is provided a control method for a cradle device on which a mobile phone device is placed, wherein an input step for inputting detection information from a predetermined detection sensor, and a detection information input in the input step. And determining whether or not the operating state of the human body or the object is different from the normal state (hereinafter referred to as “abnormal state”), and the operating state is abnormal in the determining step. And a control step of transmitting information indicating an abnormal state from the mobile phone device to an external server.

  A control program according to the present invention causes a computer to execute the control method described above.

  A recording medium according to the present invention is characterized in that the control program described above is recorded in a computer-readable manner.

  According to the cradle device according to the present invention, when the operation state of the human body or the object is in an abnormal state, only the information indicating the abnormal state is transmitted to the server. In addition to being able to suppress, only the information in the abnormal state can be accurately stored in the server.

  Further, according to the server according to the present invention, since information indicating that the operating state of the human body or the object is in an abnormal state is transferred to another user terminal device, There is an effect that it is possible to notify in real time that there is an abnormal state.

  In addition, according to the server of the present invention, the detection information detected by the cradle device is received, and when it is determined that the operation state of the vehicle is an abnormal state using the received detection information, the abnormal state is indicated. Since the information is transmitted to the user terminal device registered in advance, a simple configuration in which imaging information is transmitted to the cradle device and the mobile phone device can be achieved. Furthermore, by performing various processes at the server and storing only the information indicating the abnormal state, it is possible to suppress the amount of data to be stored and transmit the abnormal state to the user terminal device accurately and in real time. be able to.

  Exemplary embodiments of a cradle device, a server, a control method, a control program, and a recording medium according to the present invention will be described below in detail with reference to the accompanying drawings.

(Embodiment 1)
(Outline of the information notification system 100)
First, an overview of the information notification system 100 according to the first embodiment will be described. FIG. 1 is an explanatory diagram of an overview of the information notification system 100 according to the first embodiment. In FIG. 1, the information notification system 100 includes a cradle device 110, a mobile phone device 111, a server 120, and a user terminal device 130.

  The mobile phone device 111, the server 120, and the user terminal device 130 are connected by a network 140 such as the Internet. In the following description, a case where the cradle device 110 and the mobile phone device 111 are used to function as a drive recorder will be described.

  The cradle device 110 is installed on a dashboard of a vehicle, for example. Although the cradle device 110 will be described in detail later, the cradle device 110 includes an acceleration sensor, detects acceleration generated in the vehicle, and determines whether the vehicle is in a state different from a normal state (hereinafter referred to as “abnormal state”). When the determination is made and it is determined that the state is abnormal, control is performed such as transmitting information indicating the abnormal state to the server 120 via the mobile phone device 111. The information indicating the abnormal state is information such as an image captured by a camera of the mobile phone device 111 described later, a notification alarm indicating that an abnormality has occurred, or the like.

  The mobile phone device 111 has a built-in image pickup unit 112 that picks up moving images and still images, and when set on the cradle device 110, for example, it is possible to pick up images of the situation in the front direction of the vehicle. The imaging information includes audio information, time information, position information, and the like. The captured imaging information is sequentially overwritten in, for example, a memory built in the cradle device 110. Note that the captured image information can be stored not only in the memory of the cradle device 110 but also in a memory built in the mobile phone device 111. The mobile phone device 111 can be connected to an external communication device via the network 140.

  The server 120 stores information sent from the mobile phone device 111 and transfers the information to the user terminal device 130. The user terminal device 130 includes another mobile phone device 131 and a PC (Personal Computer) 132. Note that each of the other mobile phone devices 131 and PCs 132 may be singular or plural. The user of the user terminal device 130 is a person who desires notification of the abnormal state when an abnormality occurs in the operation state of the owner of the mobile phone device 111. Specifically, for example, for example, the mobile phone device 111 owners' family members and employees in the workplace.

  In addition to the user's home, the PC 132 is installed in a workplace where the user works (for example, a transportation company such as a taxi company or a delivery company). The PC 132 will be described in detail later, but when the cradle device 110 is used for medical purposes or nursing care, it is installed in a family medical facility or nursing care facility, for example. Furthermore, when the cradle device 110 is used for crime prevention, the PC 132 is installed in a security company with which the user has a contract.

  Further, reference symbols A to D shown in FIG. 1 indicate the flow of information of the information notification system 100 according to the present invention. That is, when information indicating an abnormal state is transmitted from the mobile phone device 111 set in the cradle device 110 to the server 120 (reference characters A and B), the information indicating the abnormal state is transferred from the server 120 to the user terminal device 130. (References C and D).

(Configuration of cradle device)
Next, the configuration of the cradle device 110 will be described with reference to FIGS. FIG. 2 is a side view of the cradle device 110. FIG. 3 is a front view of the cradle device 110. FIG. 4 is a top view of the cradle device 110.

  2 and 3, the cradle device 110 includes a housing 201, a fixed plate 202, a rotation mechanism 203, a power cable 204, and a housing portion 205. The casing 201 is made of, for example, a synthetic resin, and is provided with a storage unit 205 that stores the mobile phone device 111. The fixed plate 202 is a part that becomes a base of the cradle device 110, and is fixed on the dashboard using, for example, a metal fitting, a suction cup, a double-sided tape, a screw, or the like.

  The rotation mechanism 203 connects the casing 201 and the fixed plate 202, and allows the casing 201 to rotate forward, backward, left and right. The turning mechanism 203 can be turned by an external force greater than or equal to a predetermined amount applied by a person, and may have a holding force that does not turn due to vibrations in the vehicle during traveling, or a lock mechanism provided with a locking mechanism. It is good also as what can be rotated only when canceling | releasing. The power cable 204 is a cable for supplying power to the sensor-equipped circuit unit (see FIG. 5) and the cellular phone device 111 described later. As shown in FIG. 3, the cradle device 110 is provided with an emergency switch 301 on the front surface of the housing 201, specifically at a position where the user can easily press it (side closer to the driver's seat). Yes.

  Further, as shown in FIG. 4, the cradle device 110 includes an airbag 401 in the housing portion 205. The airbag 401 is inflated when air is sent into the airbag 401 by a pump described later, and fixes the cellular phone device 111 by pressing the cellular phone device 111 from the four sides.

  Note that an elastic member, a damping member, or the like for reducing the transmission of vibration from the vehicle to the casing 201 may be provided in the vicinity of the connection portion between the casing 201 and the fixing plate 202 where the rotation mechanism 203 is provided. Is possible. It is also possible to provide a buffer member on the surface of the fixed plate 202 that contacts the dashboard. Furthermore, in order to widen the imaging area by the mobile phone device 111, for example, it is possible to have a structure in which the housing 201 is rotated left and right by a motor.

(Configuration of the sensor circuit)
Next, the configuration of the sensor-equipped circuit unit will be described with reference to FIG. FIG. 5 is a side view showing the configuration of the sensor-equipped circuit unit 501. In FIG. 5, a sensor-equipped circuit unit 501 is provided in a housing 201, and details thereof will be described later with reference to FIG. 9, but an acceleration sensor, a memory, a CPU, various circuits, and the like are incorporated therein. The sensor-equipped circuit unit 501 includes a pump 502 below. The pump 502 sends air to the airbag 401.

  The sensor-equipped circuit unit 501 detects that the cellular phone device 111 is accommodated in the accommodating unit 205 by being connected to the cellular phone device 111 by a connector 701 (see FIG. 7) described later. It should be noted that a sensor can also be used when detecting the presence or absence of the mobile phone device 111 in the housing unit 205.

(State when the mobile phone device is set in the cradle device)
Next, the state when the mobile phone device 111 is set in the cradle device 110 will be described with reference to FIGS. FIG. 6 is a side view when the mobile phone device 111 is set in the cradle device 110. FIG. 7 is a front view when the mobile phone device 111 is set in the cradle device 110. FIG. 8 is a top view when the cellular phone device 111 is set in the cradle device 110.

  6 to 8, a mobile phone device 111 is set in the cradle device 110. When the cellular phone device 111 is housed in the housing unit 205, the imaging unit 112 is placed in a direction facing the windshield (not shown). When the cellular phone device 111 is accommodated, the cellular phone device 111 is fixed by the airbag 401.

  In addition, as shown in FIG. 7, the cellular phone device 111 and the cradle device 110 are connected by a cable via a connector 701. When the cellular phone device 111 and the connector 701 are connected, the pump 502 is driven and air is sent into the airbag 401, so that the cellular phone device 111 is fixed by the airbag 401.

  In addition, the mobile phone device 111 and the cradle device 110 are connected to each other by a connector 701 so that the battery of the mobile phone device 111 can be charged. In addition to the wired connection, for example, a control signal such as a timing for transmitting information is transmitted from the cradle device 110 to the mobile phone device 111, and the mobile phone device 111 or the cradle device 110 images the mobile phone device 111. Imaging information is sent out.

  For example, a 3GPP (Third Generation Partnership Project) connector is used as the connector 701. Although details will be described later, the connection between the mobile phone device 111 and the cradle device 110 is not limited to a wired connection, and a communication connection by short-range wireless communication using Bluetooth or the like is also possible. Note that Bluetooth is a registered trademark.

(Outline of hardware configuration of cradle device)
Next, an outline of the hardware configuration of the cradle device 110 will be described with reference to FIG. FIG. 9 is a block diagram showing an outline of the hardware configuration of the cradle device 110. In FIG. 9, the cradle device 110 includes an acceleration sensor (G sensor) 901, an A / D converter 902, a CPU 903, a memory 904, a mobile phone interface (I / F) 905, a USB port 906, and an external sensor. An input terminal 907, a maintenance USB port 908, a power input terminal 909, and a DC / DC converter 910 are provided.

  The G sensor 901 detects acceleration generated in the vehicle. Specifically, a small sensor that detects acceleration in two axes is used. In addition, as a sensor, you may provide the detection sensor besides illustration which detects the presence or absence of the mobile telephone apparatus 111 in the accommodating part 205 (refer FIG. 2) of the cradle apparatus 110 other than this. The A / D converter 902 converts the analog signal detected by the G sensor 901 into a digital signal.

  The CPU 903 governs overall control of the cradle device 110 and executes various arithmetic processes based on a control program stored in a ROM (not shown). The RAM (not shown) functions as a data work area when the CPU 903 performs arithmetic processing. The control program determines whether or not the acceleration detected by the G sensor 901 is a value within a predetermined range, and if it is determined that the acceleration exceeds the predetermined range, information indicating an abnormal state is transmitted via the mobile phone device 111. A program to be transmitted to the server 120.

  The memory 904 uses a magnetic disk, an optical disk, a flash memory, or the like, and stores the detection result of the G sensor 901 and imaging information captured by the mobile phone device 111. The imaging information includes audio information, time information, position information, and the like. The stored information is updated as needed under the control of the CPU 903. It should be noted that at least a non-volatile storage medium such as a flash memory is used as a medium for storing the imaging information so that the imaging information is not erased even when the power supply is lost in the event of a collision such as an accident. It is desirable to use it.

  The mobile I / F 905 is connected to the mobile phone device 111 via the USB port 906 and the connector 701, and inputs / outputs information to / from the mobile phone device 111. The external sensor input terminal 907 is a terminal for inputting various sensors from the outside. The maintenance USB port 908 is a connector for performing USB connection of other devices from the outside.

  The power input terminal 909 has, for example, a cigar socket plug and is connected to a cigar socket in the vehicle. The DC / DC converter 910 is a converter that converts a voltage value of a direct current of 12 V or 24 V into a voltage value for operation of the cradle device 110 (for example, about 3 V). The converted power supply is branched into a power supply for the cradle device 110 (for circuit) and a power supply for charging the mobile phone device 111.

(Functional configuration of cradle device 110)
Next, the functional configuration of the cradle device 110 will be described with reference to FIG. FIG. 10 is a block diagram illustrating a functional configuration of the cradle device 110.

  10, the cradle device 110 includes an input unit 1001, a detection unit 1002, a determination unit 1003, a control unit 1004, an output unit 1005, an acquisition unit 1006, a storage unit 1007, an update unit 1008, and a registration. A unit 1009, a detection unit 1010, a pressure unit 1011, and an airbag 401 are configured.

  The input unit 1001 inputs detection information from the detection unit 1002. The input unit 1001 can realize its function by the A / D converter 902 shown in FIG. 9 as an interface converter. Further, the detection unit 1002 can realize its function by the G sensor 901 shown in FIG.

  The determination unit 1003 determines whether the acceleration input to the input unit 1001 is within a predetermined range. The acceleration within the predetermined range is an acceleration smaller than the acceleration generated at the time of a collision such as a traffic accident. In addition, when the determination unit 1003 determines that the acceleration exceeds a predetermined range, the control unit 1004 outputs information indicating an abnormal state to the output unit 1005. Specifically, the acceleration exceeding the predetermined range is an acceleration generated at the time of a collision.

  The information indicating the abnormal state is typically imaging information around the vehicle imaged within a predetermined time before and after the time when the collision occurred or the time when the emergency switch 301 (see FIG. 3) was pressed. In addition to this, information such as a notification alarm may be used, or acceleration information that is input to the input unit 1001 and stored in the storage unit 1007 may be used.

  The functions of the determination unit 1003 and the control unit 1004 can be realized by the CPU 903 shown in FIG. Information indicating the abnormal state output from the output unit 1005 is transmitted from the mobile phone device 111 to the server 120. The output unit 1005 can realize its function by the output interface of the portable I / F 905 shown in FIG.

  The acquisition unit 1006 acquires imaging information around the vehicle captured by a camera built in the mobile phone device 111. The acquisition unit 1006 can realize the function by an input interface of the portable I / F 905. The storage unit 1007 stores the detection information input to the input unit 1001 and the imaging information acquired by the acquisition unit 1006. The function of the storage unit 1007 can be realized by the memory 904 illustrated in FIG.

  The update unit 1008 cyclically updates (overwrites) information stored in the storage unit 1007, and particularly updates imaging information at a predetermined interval. Specifically, the update unit 1008 sequentially overwrites, for example, imaging information acquired at the current time with imaging information stored 20 seconds ago as a predetermined interval. Note that, depending on the memory capacity of the storage unit 1007, specifically, for example, the storage time can be appropriately changed according to the memory capacity of a removable memory card or the like. The update unit 1008 can realize its function by the CPU 903 shown in FIG. Note that the CPU 903 includes a timer for measuring time.

  The registration unit 1009 registers information of the user terminal device 130 that is a transfer destination. Specifically, the information of the user terminal device 130 serving as the transfer destination is information on an electronic mail address or a telephone number of the user terminal device 130. The number of user terminal devices 130 registered in the registration unit 1009 may be singular or plural. The registration unit 1009 can realize its function by the memory 904 shown in FIG.

  In addition, when the determination unit 1003 determines that the acceleration exceeds a predetermined range, the control unit 1004 stores the imaging information stored in the storage unit 1007 and also stores the imaging information as information indicating an abnormal state. And information of the user terminal device 130 registered in the registration unit 1009 is output to the output unit 1005. Specifically, the imaging information stored in the storage unit 1007 is information for a certain period of time before and after the time when the determination unit 1003 determines that the acceleration exceeds a predetermined range. In addition, the preservation | save here is prohibiting overwriting with respect to the stored imaging information.

  The detection unit 1010 detects the connection between the connector 701 (see FIG. 7) and the mobile phone device 111. The detection unit 1010 may be any device that can detect the presence / absence of the mobile phone device 111 in the housing unit 205 (see FIG. 2), and is not limited to one using a connection signal based on such an electrical connection. It may be by sensing. In this case, the detection unit 1010 can realize its function by a sensor that detects the presence or absence of the mobile phone device 111 in the storage unit 205.

  The pressurizing unit 1011 fixes the cellular phone device 111 to the airbag 401 by sending air to the airbag 401 when the detection unit 1010 detects the cellular phone device 111 in the housing unit 205. Force is applied. The pressurizing unit 1011 can realize its function by the pump 502 (see FIG. 5) based on the control of the CPU 903 shown in FIG.

(An example of information notification processing of the information notification system)
Next, an example of the information notification process of the information notification system 100 according to the first embodiment will be described with reference to FIG. FIG. 11 is a sequence diagram illustrating an example of information notification processing of the information notification system 100.

  In FIG. 11, first, the cradle device 110 determines whether or not the mobile phone device 111 is set in the accommodation unit 205 (step S <b> 1101). In step S1101, the mobile phone device 111 is in a standby state until it is set in the storage unit 205 (step S1101: No loop). When the mobile phone device 111 is set in the storage unit 205 (step S1101: Yes), The air bag is pressurized by the pump 502 based on the control of the CPU 903 (step S1102).

  The G sensor 901 detects acceleration (step S1103). Furthermore, imaging information is acquired from the mobile phone device 111 via the mobile I / F 905 (step S1104). The imaging information includes audio information, time information, position information, and the like. When the cellular phone device 111 is set in the housing unit 205, a request signal for requesting an activation command for the imaging unit 112 such as a camera built in the cellular phone device 111 or a sound collecting unit such as a microphone. The mobile phone device 111 may receive the request signal and activate the imaging unit 112 and the like.

  Then, the acquired imaging information is stored in the memory 904 (step S1105). Further, the imaging information that has been stored for a predetermined time is sequentially overwritten (step S1106). Specifically, the predetermined time is around 20 seconds, for example, 18 seconds. That is, the imaging information acquired at the current time is overwritten on the imaging information stored in the memory 904 18 seconds ago.

  Further, the CPU 903 determines whether or not the acceleration exceeds a predetermined range (step S1107). If it is determined in step S1107 that the acceleration does not exceed the predetermined range (step S1107: No), the process proceeds to step S1103. On the other hand, when it is determined in step S1107 that the acceleration exceeds the predetermined range (step S1107: Yes), the imaging information for a certain period of time is stored based on the time when the acceleration exceeds the predetermined range (step S1108).

  Specifically, an image for a total of 18 seconds from 12 seconds before to 6 seconds after is stored on the basis of when the acceleration exceeds a predetermined range. Then, the stored imaging information and the information of the transfer destination user terminal device 130 registered in the memory 904 are transmitted to the server 120 via the mobile phone device 111 (step S1109). Thereafter, it is determined whether or not the mobile phone device 111 has been removed from the storage unit 205 (step S1110).

  In step S1110, until the mobile phone device 111 is removed from the storage unit 205 (step S1110: No), the process proceeds to step S1103, and the above-described processing is repeated. On the other hand, when the cellular phone device 111 is removed from the storage unit 205 in step S1110 (step S1110: Yes), a series of processing ends.

  Next, processing of the server 120 will be described. The server 120 is in a standby state until it receives imaging information and information of the transfer destination user terminal device 130 from the mobile phone device 111 controlled by the cradle device 110 (step S1111: No loop). When the imaging information and the information of the transfer destination user terminal device 130 are received in step S1111 (step S1111: Yes), the imaging information is transferred to the transfer destination user terminal device 130 (step S1112). Terminate the process.

  Next, processing of the user terminal device 130 will be described. The user terminal device 130 is in a standby state until it receives imaging information from the server 120 (step S1113: No loop). In step S1113, when imaging information is received (step S1113: Yes), information indicating that the imaging information has been received is notified (step S1114), and a series of processing ends.

  The notification of the information indicating that the imaging information has been received is, for example, a display format that is different from the display when a normal e-mail is received, and is impulsive to the user using the user terminal device 130. The notification may be emphasized. In step S1114, the imaging information may be displayed together with information indicating that the imaging information has been received.

  According to the above-described processing, when the acceleration detected by the G sensor 901 exceeds a predetermined range, information indicating an abnormal state is transmitted from the mobile phone device 111 to the server 120, so that it functions as a drive recorder. In addition to being able to reduce the amount of data stored in the server 120, the abnormal state can be transmitted to the server accurately and in real time. In addition, a family member or a work-related person who has acquired the fact that the user terminal device 130 is in an abnormal state can make an emergency vehicle dispatch request or an initial action. Therefore, it is not only effective for lifesaving in a moment, but can also be used to investigate the cause of an incident or accident.

  In addition, since the cradle device 110 according to the first embodiment includes the memory 904 that stores the acceleration detection information input from the G sensor 901, the detection is performed regardless of the capacity of the memory built in the mobile phone device 111. Information, imaging information, and the like can be stored.

  In addition, since the cradle device 110 according to the first embodiment updates the imaging information stored in the memory 904 at a predetermined interval, only necessary information can be stored in the memory 904. It can be prevented that the capacity reaches an allowable amount and cannot be stored.

  Further, the cradle device 110 according to the first embodiment saves the imaging information stored in the memory 904 and stores the saved imaging information in the mobile phone when the CPU 903 determines that the moving body is in an abnormal state. Since information is transmitted from the device 111 to the server 120, only information indicating an abnormal state can be transmitted to the server 120.

  Also, the cradle device 110 according to the first embodiment transmits, from the mobile phone device 111, information registered in advance on the user terminal device 130 that is a transfer destination of information indicating an abnormal state and information indicating the abnormal state. Therefore, information indicating an abnormal state can be quickly transferred to the user terminal device 130.

  In addition, since the cradle device 110 according to the first embodiment uses a non-volatile storage medium for the memory 904, it is possible to store imaging information even when there is no power input due to an accident or the like. become.

  In addition, since the cradle device 110 according to the first embodiment fixes the mobile phone device 111 by sending air to the airbag 401, the imaging region is fluctuated due to vibration or impact. Can be prevented.

  In addition, since the cradle device 110 according to the first embodiment supplies power to the mobile phone device 111, the battery of the mobile phone device 111 can be charged and the battery remaining in the mobile phone device 111 can be charged. Even in a state where the amount is small, it is possible to cause the imaging unit of the mobile phone device 111 to perform imaging by supplying power.

  Further, the server 120 according to the first embodiment receives the information indicating the abnormal state and the information of the user terminal device 130 that is the transfer destination of the information indicating the abnormal state, and receives the information indicating the received abnormal state. Since the data is transferred to the user terminal device 130, it is possible to notify the user or third party using the user terminal device 130 that the abnormal state is present in real time.

  In the first embodiment, the cradle device 110 or the mobile phone device 111 performs various processes and transmits them to the server 120. However, the server 120 can also perform various processes. That is, when the server 120 receives detection information detected by the G sensor 901 from the cradle device 110 and uses the received detection information to determine that the operation state of the vehicle is an abnormal state, it indicates an abnormal state. It is also possible to transmit information to the user terminal device 130 registered in advance.

  According to such a configuration, the cradle device 110 and the mobile phone device 111 can be simply configured to simply acquire and transmit imaging information and detection information. In addition, by performing various processes in the server 120, only information indicating an abnormal state can be stored, the amount of data to be stored can be suppressed, and the abnormal state can be transmitted to the user terminal device 130 accurately and in real time. be able to. Even if it is such a structure, the effect similar to the structure mentioned above can be acquired.

(Embodiment 2)
Next, a second embodiment according to the present invention will be described. In the second embodiment, the configuration and the like of the information notification system 100 are substantially the same as those in the first embodiment, but the imaging information is stored in the memory built in the mobile phone device 111. And different. In the following description, since the configuration and the like of the information notification system 100 are substantially the same as those in the first embodiment, only control processing will be described.

(Example of control processing of cradle device and mobile phone device)
An example of control processing of the cradle device 110 and the mobile phone device 111 according to the second embodiment will be described with reference to FIG. FIG. 12 is a sequence diagram illustrating an example of control processing of the cradle device 110 and the mobile phone device 111 according to the second embodiment. Note that the process shown in FIG. 12 will be described in more detail than the first embodiment (the process shown in FIG. 11) as appropriate.

  In FIG. 12, first, the cradle device 110 is in a standby state until the power is turned on (step S1201: No loop). When the power is turned on (step S1201: Yes), the initial setting of the cradle device 110 is performed. Perform (step S1202). Then, an initial setting request is made to the mobile phone device 111 (step S1203).

  Upon receiving this initial setting request, the mobile phone device 111 activates the application software of the drive recorder (step S1204). It is assumed that the application software is installed in the mobile phone device 111. Thereafter, the cellular phone device 111 performs initial setting (step S1205). The initial setting includes activation of the imaging unit 112, activation of the sound collection unit, and the like.

  When the initial setting is completed, an initial setting completion notification is transmitted to the cradle device 110. The cradle device 110 is in a standby state after receiving the initial setting completion notification after making the initial setting request in step S1203 (step S1206: No loop). In step S1206, when an initial setting completion notification is received (step S1206: Yes), it is determined whether an event has occurred (step S1207).

  An event occurs when an acceleration exceeding a predetermined range is detected by the G sensor 901, when the user presses the emergency switch when it is desired to memorize a dangerous state just before the accident, or other external storage request Such as when you accept.

  In step S1207, it is in a standby state until it is determined that an event has occurred (step S1207: No loop). When it is determined that an event has occurred (step S1207: Yes), an event has occurred to the mobile phone device 111. Information to that effect is transmitted (step S1208).

  On the other hand, the mobile phone device 111 acquires imaging information after performing the initial setting in step S1205 (step S1209). Also, voice information is acquired (step S1210). Further, time information is acquired (step S1211). Further, position information (vehicle position information) is acquired by the GPS function of the mobile phone device 111 (step S1212). Then, each acquired information is written in a memory built in the mobile phone device 111 (step S1213). The process proceeds to step S1209 until information indicating that an event has occurred is received (step S1214: NO).

  In step S1214, when information indicating that an event has occurred is received (step S1214: Yes), various types of information before and after reception are stored in the memory (step S1215). Specifically, the information for a certain period of time before and after reception is, for example, an image for a total of 18 seconds from 12 seconds before to 6 seconds after receiving information indicating that an event has occurred.

  Thereafter, the stored information is transmitted to the server 120 (step S1216), and the event processing is completed (step S1217). At this time, an event processing completion notification is transmitted to the cradle device 110. Then, it is determined whether or not the mobile phone device 111 has been removed from the cradle device 110 (step S1218). In step S1218, the process proceeds to step S1209 until the cellular phone device 111 is removed from the cradle device 110 (step S1218: No). On the other hand, when the cellular phone device 111 is removed from the cradle device 110 in step S1218 (step S1218: Yes), a series of processing ends.

  The cradle device 110 is in a standby state until it receives information indicating completion of event processing after transmitting information indicating that an event has occurred in step S1208 (step S1219: No loop), and notification of completion of event processing. Is received (step S1219: Yes), it is determined whether or not the connection with the mobile phone device 111 is disconnected (step S1220).

  In step S1220, the process proceeds to step S1207 until the connection with the mobile phone device 111 is disconnected (step S1220: No). On the other hand, in step S1220, when the connection with the mobile phone device 111 is disconnected (step S1220: Yes), a series of processing ends.

  According to the processing described above, since the imaging information and the like are stored in the memory built in the mobile phone device 111, the cradle device 110 does not include the imaging information memory 904, and is the same as in the first embodiment. An effect can be obtained.

  As described above, according to the cradle device 110 according to the second embodiment, as in the first embodiment, when the acceleration detected by the G sensor 901 exceeds a predetermined range, information indicating an abnormal state is transmitted to the mobile phone. Since it is made to transmit to the server 120 from the apparatus 111, it not only can be made to function as a drive recorder, but the amount of data stored in the server 120 can be suppressed, and an abnormal state can be transmitted to the server accurately and in real time. be able to. In addition, a family member or a person involved in the workplace who has acquired the fact that the user terminal device 130 is in an abnormal state can perform an emergency vehicle dispatch request or an initial action. Therefore, it is effective not only for lifesaving for a moment but also for investigating the cause of an incident or accident.

(Embodiment 3)
Embodiment 3 according to the present invention will be described below in detail with reference to the accompanying drawings. In the third embodiment, the configuration of the information notification system 100 is the same as that of the first embodiment, and the cradle device 1300 and the mobile phone device 111 are used for notifying a user of an abnormality for medical use or nursing care. This is different from the first embodiment in that this function is provided. Specifically, the cradle device 1300 is disposed around the bed of the user. In the following description, the same components as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

(Outline of hardware configuration of cradle device)
First, the outline of the hardware configuration of the cradle device 1300 according to the third embodiment will be described with reference to FIG. FIG. 13 is a block diagram of an outline of a hardware configuration of the cradle device 1300 according to the third embodiment. In FIG. 13, a cradle device 1300 includes a wireless sensor receiving circuit 1301, an A / D converter 902, a CPU 903, a memory 904, a portable I / F 905, a short-range wireless communication circuit 1302, and an external sensor input terminal 907. A maintenance USB port 908, a power input terminal 1303, and an AC / DC converter 1304.

  The wireless sensor receiving circuit 1301 is connected in communication with the pocket-type ultra-low frequency sensor 1305. As the pocket type ultra-low frequency sensor 1305, for example, a pressure sensor capable of detecting an ultra-low frequency signal peculiar to a biological signal is used. More specifically, the pocket type ultra-low frequency sensor 1305 outputs a heart rate or a respiratory rate by processing the detected signal. The pocket-type ultra-low frequency sensor 1305 can output a signal related to other body movement states such as snoring, not limited to the heart rate and the respiratory rate. The wireless sensor receiving circuit 1301 receives the heart rate or respiratory rate output from the pocket-type ultra-low frequency sensor 1305.

  The short-range wireless communication circuit 1302 is configured by, for example, Bluetooth. Note that Bluetooth is a registered trademark. The short-range wireless communication circuit 1302 authenticates the mobile phone device 111 registered in advance, and connects to the mobile phone device 111 that has been successfully authenticated.

  The power input terminal 1303 has a plug, for example, and is connected to a household plug receptacle (power outlet). The AC / DC converter 1304 is a converter that converts a voltage value of an AC current of 100 V into a DC power source. The converted power supply is branched into a power supply for the cradle device 1300 (for circuit) and a power supply for charging the mobile phone device 111.

  The functional configuration of the cradle device 1300 according to the third embodiment will be described using the functional configuration of the cradle device 110 illustrated in FIG. 10. The input unit 1001 is a wireless sensor reception circuit 1301 or an interface converter. The function can be realized by the A / D converter 902. The detection unit 1002 is a function external to the cradle device 1300, and the function can be realized by the pocket-type ultra-low frequency sensor 1305.

  The determination unit 1003 determines whether the heart rate or the respiratory rate input to the input unit 1001 is within a predetermined range. A heart rate or respiration rate within a predetermined range is a value indicating a normal state for the person. Further, the control unit 1004 outputs information indicating an abnormal state to the output unit 1005 when the determination unit 1003 determines that the heart rate or the respiration rate exceeds a predetermined range. A heart rate or respiratory rate exceeding a predetermined range is a value that is not normal for the person.

  Specifically, the information indicating the abnormal state may be information such as a notification alarm, may be imaging information indicating the situation of the user who has been imaged, or may be information on a heart rate or a respiratory rate. There may be. The output unit 1005 can realize its function by the output interface of the portable I / F 905 shown in FIG. 9 or the communication I / F by Bluetooth.

  The acquisition unit 1006 acquires imaging information of a person on the bed using a camera built in the mobile phone device 111. The acquisition unit 1006 can realize the function by an input interface of the portable I / F 905 or a communication I / F by Bluetooth. The storage unit 1007 stores the heart rate or respiration rate information input to the input unit 1001 and the imaging information acquired by the acquisition unit 1006.

  The update unit 1008 updates information stored in the storage unit 1007, and updates information such as heart rate or respiration rate and imaging information at predetermined intervals. The registration unit 1009 registers information of the user terminal device 130 that is a transfer destination.

  In addition, the control unit 1004 saves the imaging information stored in the storage unit 1007 and the heart rate or respiration rate information when the determination unit 1003 determines that the heart rate or respiration rate exceeds a predetermined range. The stored information as information indicating the abnormal state and the information of the user terminal device 130 registered in the registration unit 1009 are output to the output unit 1005. Also in the third embodiment, it is possible to stably perform imaging by fixing the cellular phone device 111 by the airbag 401 or the pressurizing unit 1011.

(An example of information notification processing of the information notification system)
Next, an example of the information notification process of the information notification system 100 according to the third embodiment will be described with reference to FIG. FIG. 14 is a sequence diagram illustrating an example of the information notification process of the information notification system 100 according to the third embodiment. In the following description, simple processing will be described. Specifically, processing for storing imaging information captured by the imaging unit 112 of the mobile phone device 111 and pressurizing the airbag 401 is omitted. Will be described.

  In FIG. 14, the cradle device 1300 first determines whether or not the mobile phone device 111 is set in the storage unit 205 (step S1401). In step S1401, the mobile phone device 111 is in a standby state until it is set in the storage unit 205 (step S1401: No loop), and when the mobile phone device 111 is set in the storage unit 205 (step S1401: Yes), Detection information is input from the pocket-type ultra-low frequency sensor 1305 (step S1402). The detection information is information on heart rate or respiration rate.

  Then, the detection information is stored in the memory 904 (step S1403). Further, the CPU 903 determines whether or not the heart rate or the respiratory rate exceeds a predetermined range (step S1404). In step S1404, when it is determined that the heart rate or the respiratory rate does not exceed the predetermined range (step S1404: No), the process proceeds to step S1402.

  On the other hand, if it is determined in step S1404 that the heart rate or respiratory rate has exceeded the predetermined range (step S1404: Yes), information indicating the abnormal state and the transfer destination registered in the memory 904 via the mobile phone device 111. The information on the user terminal device 130 to be transmitted is transmitted to the server 120 (step S1405). Note that the information indicating the abnormal state includes information on heart rate or respiratory rate. Thereafter, it is determined whether or not the cellular phone device 111 has been removed from the storage unit 205 (step S1406).

  In step S1406, until the mobile phone device 111 is removed from the storage unit 205 (step S1406: No), the process proceeds to step S1402, and the above-described processing is repeated. On the other hand, when the cellular phone device 111 is removed from the storage unit 205 in step S1406 (step S1406: Yes), a series of processing ends.

  Next, processing of the server 120 will be described. The server 120 is in a standby state until it receives information indicating an abnormal state and information of the transfer destination user terminal device 130 from the mobile phone device 111 controlled by the cradle device 1300 (step S1407: No loop). . In step S1407, when the information indicating the abnormal state and the information of the transfer destination user terminal device 130 are received (step S1407: Yes), the information indicating the abnormal state is transferred to the transfer destination user terminal device 130. (Step S1408), a series of processing ends.

  Next, processing of the user terminal device 130 will be described. The user terminal device 130 is in a standby state until it receives information indicating an abnormal state from the server 120 (step S1409: No loop). In step S1409, when information indicating an abnormal state is received (step S1409: Yes), information indicating that the information indicating the abnormal state has been received is notified (step S1410), and the series of processing ends.

  As described above, according to the cradle device 110 according to the third embodiment, when the detection information is input from the detection sensor and the respiration rate or the heart rate exceeds the predetermined range using the input detection information, the abnormal state Is transmitted from the mobile phone device 111 to the server 120, so that it can be used not only as a medical or nursing care notification device but also in an accurate and real-time transmission to the server 120. . As a result, an immediate medical system can be set up, which is effective in saving lives for the moment.

  In the third embodiment, simple processing omitted for storing imaging information captured by the imaging unit 112 of the mobile phone device 111 and pressurizing the airbag 401 has been described. However, the imaging information is stored. Of course, a process of pressurizing the air bag 401 may be added. That is, by pressing the airbag 401, it is possible to hold and fix an appropriate imaging area in the mobile phone device 111, store the imaging information, and transmit the imaging information to the server 120.

  In this case, the server 120 may transfer the imaging information to the user terminal device 130. With such processing, more detailed information can be obtained from the imaging information. In this case, the time for updating the imaging information may be set to a time that can be referred to for medical practice or the like. do it.

  In the third embodiment, various processes are performed by the cradle device 110 or the mobile phone device 111 and transmitted to the server 120. However, as supplemented in the first embodiment, the server 120 performs various processes. It is also possible to perform processing. That is, when the server 120 receives detection information detected by the pocket-type ultra-low frequency sensor 1305 from the cradle device 110 and uses the received detection information to determine an abnormal state, information indicating the abnormal state Can be transmitted to the user terminal device 130 registered in advance.

  According to such a configuration, the cradle device 110 and the mobile phone device 111 can be simply configured to simply acquire and transmit detection information. Further, the server 120 can transmit the abnormal state to the user terminal device 130 accurately and in real time by performing various processes. Even if it is such a structure, the effect similar to the structure mentioned above can be acquired.

(Embodiment 4)
Next, a fourth embodiment according to the present invention will be described. The fourth embodiment has the same configuration as that of the third embodiment, but differs from the third embodiment in that a function for notifying a crime prevention abnormality is provided. Since each configuration, processing, and the like are substantially the same as those in the first and third embodiments, a brief description will be given using the drawings described in the first and third embodiments as appropriate.

  In the fourth embodiment, instead of the pocket type ultra-low frequency sensor 1305 shown in FIG. 14, a security sensor installed indoors or outdoors is used. The indoor is specifically a residence or office which is a living space. The outdoor is below the living space, and is, for example, a veranda of a building, a vehicle, a warehouse, or the like. The reason why an unspecified number of people such as verandas are not allowed to enter and leave the outdoors is that the mobile phone device 111 needs to be arranged in the vicinity of the security sensor.

  In the following description, a case will be described in which a security sensor arranged around an opening / closing part such as a door or door is used. As the security sensor, for example, a magnet sensor attached to the opening / closing part, a vibration sensor for glass, an intrusion prevention sensor such as an infrared sensor is used. When described using the functional configuration of the cradle device 110 illustrated in FIG. 10, the determination unit 1003 determines whether the detection information of the sensor input to the input unit 1001 indicates abnormality. The control unit 1004 outputs information indicating an abnormal state to the output unit 1005 when the determination unit 1003 determines that the sensor detection signal indicates an abnormality.

  Specifically, the information indicating the abnormal state may be information such as a notification alarm, or may be captured image information. The acquisition unit 1006 acquires imaging information around the opening / closing unit using a camera built in the mobile phone device 111. The storage unit 1007 stores the detection information input to the input unit 1001 and the imaging information acquired by the acquisition unit 1006.

  According to the fourth embodiment described above, when detection information is input from the security sensor and it is determined that the input detection information indicates an abnormality, information indicating the abnormal state is transmitted from the mobile phone device 111 to the server 120. Since it was made to transmit, not only can it be used as an alarm device for crime prevention, but also an abnormal state can be transmitted to the server 120 accurately and in real time. Thereby, while being able to take a quick initial action, the evidence at the time of a crime occurring can be obtained.

  As described above, according to the cradle device, the server, the control method, the control program, and the recording medium according to the present invention, only the information in the abnormal state can be accurately stored in the server, and the data stored in the server Not only can the amount be reduced, but it can also notify the user or third party in real time that there is an abnormal condition.

  INDUSTRIAL APPLICABILITY The cradle device according to the present invention is useful for a cradle device capable of charging a battery of a mobile phone device, and in particular, a cradle device having a function as a drive recorder together with the mobile phone device, a medical notification device. It is suitable for a cradle device having a function as a cradle device having a function as an alarm device for crime prevention.

1 is an explanatory diagram illustrating an overview of an information notification system according to a first exemplary embodiment; It is a side view of a cradle apparatus. It is a front view of a cradle apparatus. It is a top view of a cradle apparatus. It is a side view which shows the structure of a circuit part with a sensor. It is a side view at the time of setting a mobile telephone apparatus to a cradle apparatus. It is a front view at the time of setting a mobile telephone apparatus to a cradle apparatus. It is a top view at the time of setting a mobile telephone apparatus to a cradle apparatus. It is a block diagram which shows the outline | summary of the hardware constitutions of a cradle apparatus. It is a block diagram which shows the functional structure of a cradle apparatus. It is a sequence diagram which shows an example of the information notification process of an information notification system. FIG. 10 is a sequence diagram illustrating an example of control processing of the cradle device and the mobile phone device according to the second exemplary embodiment; FIG. 6 is a block diagram illustrating an outline of a hardware configuration of a cradle device according to a third embodiment; FIG. 10 is a sequence diagram illustrating an example of information notification processing of the information notification system according to the third exemplary embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Information notification system 110 Cradle apparatus 111 Mobile phone apparatus 112 Imaging part 120 Server 130 User terminal device 401 Air bag 502 Pump 901 G sensor 903 CPU
904 Memory 905 Mobile I / F
DESCRIPTION OF SYMBOLS 1001 Input part 1002 Detection part 1003 Judgment part 1004 Control part 1005 Output part 1006 Acquisition part 1007 Memory | storage part 1008 Update part 1009 Registration part 1010 Detection part 1011 Pressurization part 1300 Cradle apparatus 1301 Wireless sensor receiving circuit 1302 Near field communication circuit 1305 Pocket type ultra-low frequency sensor

Claims (16)

In the cradle device on which the mobile phone device is placed,
An input means for inputting detection information from a predetermined detection sensor;
Using the detection information input to the input means, a determination means for determining whether the operating state of a human body or an object is a state different from a normal state (hereinafter referred to as “abnormal state”);
Control means for transmitting information indicating the abnormal state from the mobile phone device to an external server when the operation state is determined to be an abnormal state by the determination unit;
A cradle device comprising: The cradle device according to claim 1, which is mounted on a moving body,
It further comprises a detection means comprising an acceleration sensor for detecting the acceleration of the moving body,
The input means inputs information on acceleration detected by the detection means,
The determining means determines whether the acceleration is within a predetermined range;
The control unit causes the mobile phone device to transmit information indicating an abnormal state to the server when the acceleration exceeds a predetermined range. The cradle device according to claim 1, wherein the cradle device is disposed in the vicinity of a detection sensor for detecting a human respiratory rate, heart rate, or body movement.
The input means inputs detection information from the detection sensor,
The determination unit determines whether the respiration rate or the heart rate is within a predetermined range using the detection information input to the input unit;
The control means causes the mobile phone device to transmit information indicating an abnormal state to an external server when the respiratory rate or the heart rate exceeds a predetermined range. The cradle device according to claim 1, which is disposed in the vicinity of a security sensor installed indoors or outdoors,
The input means inputs detection information from the security sensor,
The determination means determines whether or not the detection information input to the input means indicates abnormality,
The control unit causes the mobile phone device to transmit information indicating an abnormal state to an external server when the determination unit determines that the detection information indicates an abnormality.   The cradle apparatus according to claim 1, further comprising a storage unit that stores the detection information input to the input unit. Updating means for updating information stored in the storage means;
Acquisition means for acquiring peripheral imaging information imaged by a camera built in the mobile phone device;
Further comprising
The storage means stores the imaging information acquired by the acquisition means,
The cradle apparatus according to claim 5, wherein the updating unit updates imaging information stored in the storage unit at a predetermined interval.   The control means saves the imaging information stored in the storage means when the determination means determines that the operating state of the human body or the object is an abnormal state, and as the information indicating the abnormal state, The cradle device according to claim 5 or 6, wherein the stored imaging information is transmitted from the mobile phone device to the server. A registration means for registering information of a user terminal device that is a transfer destination of information indicating the abnormal state;
8. The control unit according to claim 1, wherein the control unit causes the mobile phone device to transmit information indicating the abnormal state and information on the user terminal device registered in the registration unit to an external server. The cradle device according to any one of the above.   The cradle apparatus according to claim 5, wherein the storage unit includes a nonvolatile storage medium. A housing for accommodating the mobile phone device;
A buffer means provided in the housing and having an airbag;
Detecting means for detecting the presence or absence of the mobile phone device in the housing;
When the mobile phone device is detected in the housing by the detection means, a force for fixing the mobile phone device to the buffer means by sending air to the airbag of the buffer means Pressurizing means for applying,
The cradle device according to claim 1, further comprising:   The cradle device according to claim 10, further comprising power supply means for supplying power to the mobile phone device in the housing. Information indicating a state (hereinafter referred to as “abnormal state”) in which the operating state of a human body or an object is different from a normal state from the cradle device on which the mobile phone device is placed via the mobile phone device, and the abnormal state Receiving means for receiving information of a user terminal device that is a transfer destination of the information to be shown;
Transfer means for transferring information indicating the abnormal state received by the receiving means to the user terminal device;
A server comprising: Registration means for registering in advance, for each mobile phone device, information of a user terminal device that is a transfer destination of information indicating a state (hereinafter referred to as “abnormal state”) in which the operation state of the human body or the object is different from the normal state;
Receiving means for receiving detection information detected by a predetermined detection sensor from the cradle device on which the mobile phone device is placed via the mobile phone device;
Using the detection information received by the receiving means, determining means for determining whether the operating state is an abnormal state;
Control means for transmitting information indicating the abnormal state to the user terminal device registered in the registration means when the operation state is determined to be abnormal by the determination means;
A server comprising: In the control method of the cradle device on which the mobile phone device is placed,
An input process for inputting detection information from a predetermined detection sensor;
Using the detection information input in the input step, a determination step of determining whether the operation state of the human body or the object is different from a normal state (hereinafter referred to as “abnormal state”);
A control step of transmitting information indicating an abnormal state from the mobile phone device to an external server when the operation state is determined to be an abnormal state in the determination step;
A control method for a cradle device comprising:   A control program for causing a computer to execute the control method according to claim 14.   A computer-readable recording medium on which the control program according to claim 15 is recorded.

Images