JP2010258975A - Portable terminal and method of protecting data of the portable terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a portable terminal which suitably protects data according to a degree of shock or water immersion, and also to provide a method of protecting data on the portable terminal. <P>SOLUTION: A portable terminal 1 accurately determines a risk degree of a failure in an internal memory 3 caused by shock or water immersion by combining detection of an acceleration by an acceleration sensor 101 and detection of humidities by humidity sensors 102, 103. When the portable terminal 1 determines that the risk degree is "low", the terminal simply stores user data in the internal memory 3 into an external memory 4. When the terminal determines that the risk degree is "high", the terminal transmits the user data of the internal memory 3 to a storage server 20 in a network N for reliable data protection. In this manner, the terminal switches between the user data storage destinations according to the "low" or "high" of the risk degree, thus securing suitable data protection. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a portable terminal and a data protection method for the portable terminal.

  When the mobile terminal is in a fall state and may be submerged by impact or landing, it is necessary to protect the data in the mobile terminal from being lost. As such a data protection method, for example, there is a data protection method described in Patent Document 1. In this conventional data protection method, it is detected whether or not the mobile terminal is in a fall state by comparing the detection profile of the acceleration sensor provided in the mobile terminal with a preset drop profile, and the mobile terminal is dropped. Necessary data is stored in the non-volatile memory when it is detected to be in a state.

  Further, in this conventional data protection method, the acceleration measurement is continued even after the falling state is detected, and it is detected from the deceleration whether the mobile terminal has landed. When it is detected that the mobile terminal has landed, the storage of data in the nonvolatile memory is stopped to prevent the program from running away.

JP 2008-42495 A JP 2006-254207 A

  In the conventional data protection method described above, since the nonvolatile memory for storing data is built in the portable terminal, depending on the degree of impact or submergence, the nonvolatile memory itself may be defective, and reliable data protection cannot be realized. There is a fear. In view of the certainty of data protection, a method of transmitting data to a server on the network when an impact or submersion is detected is also conceivable.

  However, if data is transmitted to a server on the network every time regardless of the degree of impact or submergence, the transmission frequency increases, which may lead to waste of network resources. In this regard, since the conventional data protection method described above detects only the presence or absence of impact and the presence or absence of water landing based on the acceleration profile, it is difficult to determine the degree of impact or submersion.

  The present invention has been made to solve the above-described problems, and an object thereof is to provide a mobile terminal capable of performing appropriate data protection according to the degree of impact or submergence, and a data protection method for the mobile terminal. And

  In order to solve the above problems, a mobile terminal according to the present invention is a mobile terminal in which a fixedly mounted internal memory is built in a housing, and an external memory separate from the internal memory can be attached and detached. Risk determination to determine the degree of risk of failure in the internal memory based on the acceleration sensor and humidity sensor provided in the housing, and the acceleration detected by the acceleration sensor and the humidity detected by the humidity sensor And a storage control means for storing data stored in the internal memory in the external memory when the risk determination means determines that the risk of failure in the internal memory is small, and a risk determination When it is determined by the means that the risk of failure in the internal memory is large, the data stored in the internal memory is transmitted to the storage server on the network. It is characterized in that a chromatography data transmission means.

  In this portable terminal, by combining the detection of acceleration by the acceleration sensor and the detection of humidity by the humidity sensor, it is possible to accurately determine the risk of failure of the internal memory due to impact or submersion. Further, in this portable terminal, when it is determined that the risk level is low, the data in the internal memory is simply stored in the external memory, and when it is determined that the risk level is high, the internal memory Data is transmitted to a storage server on the network to ensure data protection. In this way, appropriate data protection can be performed by switching the data storage destination according to the determined degree of risk.

  Moreover, it is preferable that a humidity sensor is comprised by the 1st humidity sensor which detects the humidity of the surface of a housing | casing, and the 2nd humidity sensor which detects the humidity inside a housing | casing. In this case, since it becomes easy to grasp the situation where moisture enters the casing, it is possible to determine the degree of risk more accurately.

  In addition, the portable terminal data protection method according to the present invention is a portable terminal data protection method in which a fixedly mounted internal memory is built in the housing and an external memory separate from the internal memory can be attached and detached. And a step of determining the degree of risk that a failure occurs in the internal memory based on the acceleration and humidity detected by the acceleration sensor and humidity sensor provided in the housing, and storage control. Means for storing the data stored in the internal memory in the external memory when the risk determination means determines that the risk of failure in the internal memory is small; and the data transmission means, When the risk determination means determines that the risk of failure in the internal memory is high, the data stored in the internal memory is It is characterized by comprising a step of transmitting to the server.

  In this portable terminal data protection method, by combining the acceleration detection by the acceleration sensor and the humidity detection by the humidity sensor, it is possible to accurately determine the risk of failure of the internal memory due to impact or submersion. Also, with this method, when it is determined that the risk level is low, the data in the internal memory is simply stored in the external memory, and when it is determined that the risk level is high, the data in the internal memory is stored. Data is transmitted to a storage server on the network for reliable data protection. In this way, appropriate data protection can be performed by switching the data storage destination according to the determined degree of risk.

  According to the present invention, appropriate data protection according to the degree of impact or submergence can be performed.

It is a perspective view which shows one Embodiment of the portable terminal which concerns on this invention. It is a block diagram which shows the functional component of the portable terminal shown in FIG. It is a figure which shows an example of the determination table in a risk determination part. 3 is a flowchart showing a data protection method in the mobile terminal shown in FIG. 1.

  Hereinafter, preferred embodiments of a mobile terminal and a data protection method for a mobile terminal according to the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a perspective view showing an embodiment of a portable terminal according to the present invention. The mobile terminal 1 shown in FIG. 1 physically includes a CPU (Central Processing Unit), a storage device such as a memory, an input device such as a push button / microphone / camera, a display device such as a display, and the like. -Equipped with various functions such as mail transmission / reception function.

  The mobile terminal 1 attaches and detaches an external memory 4 such as a chip-type flash memory in addition to an internal memory 3 such as a RAM fixedly mounted on a mounting board (not shown) installed inside the housing 10. It is freely removable. In addition to the general functions described above, the mobile terminal 1 externally stores user data such as telephone directory data stored in the internal memory 3 in a situation where a failure such as data loss may occur in the internal memory 3. A data protection function for instantaneous storage in the memory 4 or the storage server 20 (see FIG. 2) on the network N is installed.

  FIG. 2 is a block diagram showing functional components of the mobile terminal 1 for realizing the data protection function. As shown in the figure, the mobile terminal 1 includes, as functional components, an acceleration sensor 101, a surface humidity sensor (first humidity sensor) 102, an internal humidity sensor (second humidity sensor) 103, A risk level determination unit (risk level determination unit) 104, a storage control unit (storage control unit) 105, and a data transmission unit (data transmission unit) 106 are provided.

  As shown in FIG. 1, the acceleration sensor 101 is provided, for example, below the push button. The acceleration sensor 101 detects acceleration generated in the housing 10 and outputs a detection signal to the risk determination unit 104. The surface humidity sensor 102 is provided above the cross key, for example. The surface humidity sensor 102 detects the humidity of the surface of the housing 10 and outputs a detection signal to the risk determination unit 104. Further, the internal humidity sensor 103 is provided in the vicinity of the internal memory 3 inside the housing 10, for example. The internal humidity sensor 103 detects the humidity inside the housing 10 and outputs a detection signal to the risk determination unit 104.

  The risk determination unit 104 determines the level of risk of failure in the internal memory 3 based on the acceleration detected by the acceleration sensor 101 and the humidity detected by the surface humidity sensor 102 and the internal humidity sensor 103. It is a part to do. Here, FIG. 3 is a diagram illustrating an example of a determination table in the risk determination unit 104. In this determination table, it is assumed that a failure occurs in the internal memory 3 and an impact due to a drop and moisture intrusion into the housing 10.

  In the example shown in the figure, for the acceleration, it is determined whether or not the acceleration detected by the acceleration sensor 101 exceeds a preset threshold value. If the acceleration exceeds the threshold value, “reaction: ○” is set. When the acceleration is less than the threshold value, “no response: x” is set.

  In addition to determining whether or not the humidity detected by the surface humidity sensor 102 and the internal humidity sensor 103 exceeds a preset threshold, the humidity changes when the humidity exceeds the threshold. It is also judged whether the rate exceeds a certain threshold. If the humidity exceeds the threshold at a certain rate of change, the response is “abruptly responded: ◯”, and if the humidity exceeds the threshold at a rate of change below a certain value, the response is “slowly responded: △”. It is said. When the humidity is less than the threshold, “no reaction: x” is set.

  As shown in FIG. 3A, when the acceleration sensor is “reactive: ◯”, the risk determination unit 104 determines that at least one of the surface humidity sensor 102 and the internal humidity sensor 103 is “reacting rapidly”. : “”, It is determined that the risk of failure in the internal memory 3 is “high”. In other cases, both the surface humidity sensor 102 and the internal humidity sensor 103 indicate “no response”. It is determined that the risk of failure in the internal memory 3 is “small”, including the case of “:”.

  On the other hand, as shown in FIG. 3B, when the acceleration sensor is “reactive: x”, the risk determination unit 104 indicates that the internal humidity sensor 103 has “reacted rapidly: ○”. In this case, it is determined that the risk of occurrence of a failure in the internal memory 3 is large. In other cases, the surface humidity sensor 102 indicates “suddenly responding: ○” or “slowly responding: Δ”. If it is, it is determined that the risk of failure in the internal memory 3 is “low”. Further, when both the surface humidity sensor 102 and the internal humidity sensor 103 are “no response: ×”, it is determined that the degree of risk is “none”.

  When it is determined that the degree of risk is “low”, the risk level determination unit 104 outputs instruction information for instructing execution of the process to the storage control unit 105 and determines that the level of risk is “high”. In this case, the instruction information is output to the data transmission unit 106. If the risk determination unit 104 determines that the risk is “none”, the process ends without outputting the instruction information.

  The storage control unit 105 is a part that controls the storage destination of user data stored in the internal memory 3. When the storage control unit 105 receives the instruction information from the risk determination unit 104, the storage control unit 105 reads the user data stored in the internal memory 3 and outputs the read user data to the external memory 4.

  The data transmitting unit 106 is a part that transmits user data stored in the internal memory 3 to the outside. When the data transmission unit 106 receives the instruction information from the risk determination unit 104, the data transmission unit 106 reads the user data stored in the internal memory 3 and transmits the read user data to the storage server 20 on the network N.

  Subsequently, the operation of the mobile terminal 1 having the above-described configuration will be described. FIG. 4 is a flowchart showing a data protection method in the mobile terminal 1.

  As shown in FIG. 4, in the mobile terminal 1, first, acceleration detection by the acceleration sensor 101 and humidity detection by the surface humidity sensor 102 and the internal humidity sensor 103 are performed (step S01). Next, the determination table is referred to based on the detected acceleration and humidity, and the degree of risk of failure in the internal memory 3 is determined (step S02).

  If it is determined in step S02 that the degree of risk is “none”, the process ends without performing any special processing. On the other hand, when it is determined that the degree of risk is “low”, the user data stored in the internal memory 3 is read and stored in the external memory 4 (step S03). If it is determined that the degree of risk is “high”, the user data stored in the internal memory 3 is transmitted to the storage server 20 via the network N (step S04).

  As described above, in the mobile terminal 1, the detection of acceleration by the acceleration sensor 101 and the detection of humidity by the humidity sensors 102 and 103 are combined to accurately determine the risk of failure of the internal memory 3 due to impact or submersion. Can be judged well. Further, in the mobile terminal 1, when it is determined that the risk level is “low”, the user data in the internal memory 3 is simply stored in the external memory 4, and it is determined that the risk level is “high”. If it is, user data in the internal memory 3 is transmitted to the storage server 20 on the network N to ensure reliable data protection. Thus, appropriate data protection can be performed by switching the storage destination of the user data according to the determined degree of risk.

  Moreover, in the portable terminal 1, the surface layer humidity sensor 102 which detects the humidity of the surface of the housing | casing 10, and the internal humidity sensor 103 which detects the humidity inside the housing | casing 10 are provided as a humidity sensor, When the humidity detected by the surface humidity sensor 102 and the internal humidity sensor 103 exceeds a threshold value, it is determined whether or not the rate of change exceeds a certain threshold value. Judgment is made step by step. By such a process, for example, rapid water ingress such as when the mobile terminal 1 is submerged, and gentle water infiltration such as when sweat or the like is attached to the mobile terminal 1 placed in a pocket of clothing or the like. Therefore, it is possible to determine the degree of risk more accurately.

  The present invention is not limited to the above embodiment. For example, the installation positions of the acceleration sensor 101, the surface humidity sensor 102, and the internal humidity sensor may be changed as appropriate according to the shape and weight of the mobile terminal. Further, the external memory 4 is not limited to the flash memory, and may be another nonvolatile memory. Further, user data is transmitted to the storage server at regular intervals regardless of whether or not the risk determination is performed, and only the difference data is transmitted to the storage server when the risk is determined to be “high”. You may do it. In this case, when it is determined that the degree of risk is “high”, it is possible to perform quick data protection.

  DESCRIPTION OF SYMBOLS 1 ... Portable terminal, 3 ... Internal memory, 4 ... External memory, 10 ... Case, 20 ... Storage server, 101 ... Acceleration sensor, 102 ... Surface humidity sensor (first humidity sensor), 103 ... Internal humidity sensor (first) (2 humidity sensors), 104... Risk determination unit (risk level determination unit), 105... Storage control unit (storage control unit), 106... Data transmission unit (data transmission unit), N.

Claims (3)

A portable terminal having a built-in internal memory fixedly mounted in a housing and a removable external memory separate from the internal memory,
An acceleration sensor and a humidity sensor provided in the housing;
A risk determination means for determining the degree of risk of failure of the internal memory based on the acceleration detected by the acceleration sensor and the humidity detected by the humidity sensor;
Storage control means for storing data stored in the internal memory in the external memory when the risk determination means determines that the risk of failure in the internal memory is small;
Data transmitting means for transmitting data stored in the internal memory to a storage server on a network when the risk determining means determines that the risk of failure in the internal memory is large; A portable terminal characterized by comprising:   The said humidity sensor is comprised by the 1st humidity sensor which detects the humidity of the surface of the said housing | casing, and the 2nd humidity sensor which detects the humidity inside the said housing | casing. 1. The mobile terminal according to 1. A data protection method for a portable terminal in which a fixedly mounted internal memory is built in a housing, and an external memory separate from the internal memory can be attached and detached.
A step of determining a degree of risk that a failure occurs in the internal memory based on acceleration and humidity detected by an acceleration sensor and a humidity sensor provided in the housing;
The storage control means stores the data stored in the internal memory in the external memory when the risk determination means determines that the risk of failure in the internal memory is small. When,
Data transmission means transmits data stored in the internal memory to a storage server on the network when the risk determination means determines that the risk of failure in the internal memory is large. And a data protection method for a portable terminal.

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