JP6481357B2 - Electronics - Google Patents

Description

  The present invention relates to an electronic device.

  Operation of electronic devices such as smartphones and tablets while walking is dangerous because it increases the possibility that nearby passersby, bicycles, cars, and obstacles will come into contact with the user operating the electronic device. There is a problem. In the following description, a user operating an electronic device while walking is also referred to as a “walking smartphone”.

  Therefore, in order to suppress the “walking smartphone” and avoid the danger of the user, measures are taken such as limiting functions provided by the electronic device when detecting that the user is walking.

  As another related technique, the imaging device of the mobile terminal is provided on the same surface as the display device. A mobile terminal is in a moving state when a predetermined reference value is satisfied using a moving state detection unit that detects any one or more of vibration, acceleration, or a voltage accompanying the mobile terminal and the detected information. A movement state determination unit. In addition, the portable terminal includes a camera activation instruction unit that transmits an activation instruction for the imaging device, and a dangerous state determination unit that determines a dangerous state of the owner by detecting a face from an image captured by the imaging device. . Further, a technology is known that includes a danger determination time processing unit that sends a control instruction for notifying the owner of a portable terminal when it is determined that the portable terminal is in a dangerous state.

  As another related technology, the wristwatch type information terminal includes an input unit that receives an input operation, a display unit that displays predetermined information, and a usage state detection that detects a usage state of the wristwatch type information terminal by the user U. A part. Further, the wristwatch type information terminal includes a usage mode setting unit that sets any one of a non-use mode, an information confirmation mode, and a complete operation mode according to the usage state of the user detected by the usage state detection unit. The technology to prepare is known. The non-use mode is a use mode that restricts display of information on the display unit and prohibits an input operation to the input unit. The information confirmation mode is a usage mode that permits display of information on the display unit and prohibits input operations on the input unit. The complete operation mode is a usage mode that permits display of information on the display unit and input operation on the input unit (for example, Patent Document 1 or Patent Document 2).

JP 2008-085510 A JP 2013-198107 A

  In the electronic device having the above-described danger avoidance technology, when the user detects that he / she is walking in order to avoid the danger of the user, the function of the electronic device is limited. However, this may limit the convenience and impair the convenience.

  In one aspect, the present invention provides a technique for avoiding a user's danger without impairing convenience.

  One electronic device disclosed in this specification is an electronic device including a detection unit, a measurement unit, a determination unit, and a restriction unit. The detection unit detects the movement state of the user. The measurement unit includes a first measurement that measures the distance between the electronic device and the user, a second measurement that measures the angle of the electronic device with respect to the horizontal plane, a third measurement that measures the volume of sound around the electronic device, Any two or more of these are measured. The determination unit determines any two or more of the first determination, the second determination, and the third determination, and determines the fourth risk level using a combination of the determined two or more risk levels. The first determination is a determination that when the distance between the electronic device and the user is equal to or greater than the first distance, the first risk is higher as the distance from the user is closer to the first distance. The second determination is a determination that the second risk is higher as the angle of the electronic device with respect to the horizontal plane is smaller. The third determination is a determination that the third risk is higher as the sound around the electronic device is larger. The restriction unit restricts the function of the electronic device according to the fourth degree of risk determined by the determination unit.

  According to one embodiment, the danger of the user can be avoided without impairing convenience.

It is a figure which shows an example of electronic device operation during movement. It is a figure explaining the difference in the visual field by the distance of an electronic device and a user. It is a functional block diagram which shows one Example of an electronic device. It is FIG. (1) which shows an example of a measurement of the distance of an electronic device and a user. It is FIG. (2) which shows an example of a measurement of the distance of an electronic device and a user. It is a figure which shows an example of distance information. It is a figure which shows an example of inclination information. It is a figure which shows an example of noise information. It is a figure which shows an example of the determination information. It is a figure which shows an example of the setting of a judgment value. It is a figure which shows an example of a risk handling process. It is a flowchart (the 1) which shows a danger avoidance process. It is a flowchart (the 2) which shows a danger avoidance process. It is a flowchart (the 1) which shows a risk determination process. It is a flowchart (the 2) which shows a risk determination process. It is a flowchart which shows a risk handling process. It is a block diagram which shows one Example of a computer apparatus.

[Embodiment]
The electronic device of the embodiment will be described.

  FIG. 1 is a diagram illustrating an example of an electronic device operation during movement. FIG. 2 is a diagram illustrating the difference in field of view depending on the distance between the electronic device and the user.

  With reference to FIG. 1, the degree of danger of the user estimated when the user operates the electronic device 1 while moving will be described based on how the user holds the electronic device 1. “Moving” includes walking, riding a bicycle, and the like. In the following description, the degree of danger is also called the degree of danger. In addition, a high degree of risk means that the user is highly likely to come into contact with a passerby and the like, and that there is a high possibility that the user will crawl at a step. As shown in FIG. 1, the electronic device 1 may include a rear camera 2. Moreover, the electronic device 1 may include a front camera 3 and a display device 4 as shown in FIG. The front camera 3 captures at least an image including an image in the normal direction of the display device 4.

  As shown in FIG. 1A, when the user 100 operates the electronic device 1 while moving, the user 100 and the electronic device 1 have a sufficient distance and the user 100 is looking forward. Is in a state where the surrounding situation in front is visible, the possibility that the user 100 will be in contact with a passerby around is low. Therefore, when the user is operating the electronic device 1 in the state shown in FIG. 1A, the risk of the user 100 is considered low. When the distance between the user 100 and the electronic device 1 is sufficient, the distance between the user and the electronic device 1 is, for example, the ratio of the electronic device 1 that enters the field of view 5 of the user 100 as shown in FIG. It may be a distance of 30% or less. In the following description, the user 100 is also simply referred to as a user.

  As shown in FIG. 1B, when the user operates the electronic device 1 while moving, there is a sufficient distance between the user and the electronic device 1, but when the user is looking downward, the user Since the surrounding situation is invisible, there is a high possibility that the user will come in contact with a passerby. Therefore, when the user operates the electronic device 1 in the state shown in FIG. 1B, the user's risk is considered high. When the distance between the user and the electronic device 1 is sufficient, the distance between the user and the electronic device 1 is, for example, as shown in FIG. The distance which becomes below may be sufficient.

  As shown in FIG. 1C, when the user operates the electronic device 1 while moving, the user is looking forward. If the distance between the user and the electronic device 1 is short, the user Since the situation is invisible, there is a high possibility that the user will contact a passerby around. Therefore, when the user is operating the electronic device 1 in the state shown in FIG. 1C, the user's risk is considered high. When the distance between the user and the electronic device 1 is short, the distance between the user and the electronic device 1 is 30% or more, for example, as shown in FIG. There may be a distance at which the electronic device 1 substantially blocks the user's field of view.

  In order to avoid dangers caused by operating the electronic device 1 by the moving user, by restricting the functions of the electronic device 1 when the user is moving, the operation of the electronic device 1 by the user is suppressed, and the user There is a technology to reduce the risk level. When this technique is used, when the user is moving, functions used during walking such as a navigation application are also limited, which may impair user convenience. Therefore, the electronic device 1 according to the embodiment determines the risk level of the user when the user is moving, and performs risk avoidance processing that does not limit the functions of the electronic device 1 even when the user is moving when the user risk level is low. To do. Thereby, the electronic device 1 of the embodiment avoids the danger of the user without impairing the convenience.

FIG. 3 is a functional block diagram showing an embodiment of the electronic device.
With reference to FIG. 3, the electronic apparatus 1 of the embodiment will be described.

  The electronic device 1 includes a control unit 10, a measurement unit 20, a storage unit 30, a display unit 40, a sound generation unit 50, an input / output unit 60, and a transmission / reception unit 70. The electronic device 1 is, for example, a computer device 500 described later.

  The control unit 10 includes a detection unit 11, a determination unit 12, a restriction unit 13, a switching unit 14, and a notification unit 15. The measurement unit 20 includes a first measurement unit 21, a second measurement unit 22, and a third measurement unit 23. The storage unit 30 stores distance information 31, inclination information 32, noise information 33, determination information 34, and setting information 35.

  The display unit 40 displays information input from the control unit 10. The sound generator 50 generates a sound according to the sound data input from the controller 10. The input / output unit 60 receives input of information from a user or a connected device. Further, the input / output unit 60 outputs information output from the control unit 10 to a connected device. The transmission / reception unit 70 receives information from communication-connected devices. Furthermore, the transmission / reception unit 70 transmits information to the devices connected for communication.

The first measurement unit 21 measures the distance between the electronic device 1 and the user.
For example, the first measurement unit 21 may include a camera that captures an image on the display unit 40 side of the electronic device 1 and may acquire a user image as illustrated in FIG. 4. The camera has an image sensor 301 shown in FIG. The camera may be, for example, the front camera 3 shown in FIG.

  When the first measurement unit 21 acquires the images shown in FIGS. 4A and 4B, the first measurement unit 21 detects the eyes of the user by image processing, and the distance a between the eyes of the user on the image sensor 301 is calculated. The focal length b of the camera lens 302 and the actual distance c between the eyes of the user are acquired. As shown in FIG. 5, the first measuring unit 21 obtains the distance x by using the ratio of the distance a and the distance b and the ratio of the distance c and the distance x to obtain the distance b + the distance x. The distance between the image sensor and the user may be measured as the distance between the electronic device 1 and the user. For example, values stored in the setting information 35 in advance may be used as the focal length b of the lens 302 of the camera and the actual distance c between the eyes of the user.

  When the first measurement unit 21 acquires the image shown in FIG. 4C, the first measurement unit 21 detects the user's shoulders by image processing, the distance a between the user's shoulders on the image sensor 301, and the camera The focal length b of the lens 302 and the actual distance c between the user's shoulders are acquired. As shown in FIG. 5, the first measuring unit 21 obtains the distance x by using the ratio of the distance a and the distance b and the ratio of the distance c and the distance x to obtain the distance b + the distance x. The distance between the image sensor and the user may be measured as the distance between the electronic device 1 and the user. The focal length b of the camera lens 302 and the actual distance c between the user's shoulders may be values stored in the setting information 35 in advance, for example.

  As described above, the first measurement unit 21 detects a feature portion by processing an image obtained from the camera, and the distance of the feature portion on the image sensor, the focal length, and the actual size of the detected feature portion. Is used to determine the distance between the electronic device 1 and the user.

  Further, the first measurement unit 21 may be a distance sensor of a triangular measurement method and a time-of-write method. At this time, the first measurement unit 21 may obtain the distance between the electronic device 1 and the user using a triangular measurement method and a time-of-write method.

  As described above, the first measurement unit 21 detects the distance between the electronic device 1 and the object in the normal direction of the display unit 40. In the following description, the distance from the user in the normal direction of the display unit 40 is also simply referred to as the distance between the electronic device 1 and the user. The first measuring unit 21 is not limited to the distance between the electronic device 1 and the target object in the normal direction of the display unit 40, and is applied as the distance between the electronic device 1 used for risk determination described later and the user. You may detect the distance of the possible direction suitably.

  The second measuring unit 22 measures the angle of the electronic device 1 with respect to the horizontal plane. The second measurement unit 22 may be a triaxial acceleration sensor, for example. The second measuring unit 22 may include a pedometer. In the following description, the second measuring unit 22 has a function of measuring triaxial acceleration. The angle of the electronic device 1 with respect to the horizontal plane is 0 degrees when the ground surface and the surface of the display unit 40 have the same normal vector. In the following description, the angle of the electronic device 1 with respect to the horizontal plane is also referred to as the inclination of the electronic device 1.

  The third measuring unit 23 measures the volume of sound around the electronic device 1. The 3rd measurement part 23 has a microphone, for example, and calculates | requires the magnitude | size of the sound collected with the microphone. In the following description, the volume of sound around the electronic device 1 is also referred to as noise volume and noise level.

  The detection unit 11 detects the movement state of the user. For example, the detection unit 11 acquires the triaxial acceleration from the second measurement unit 22, synthesizes the XYZ components of the acceleration, and extracts a waveform component obtained by removing noise from the synthesized value of the acceleration using a digital filter. good. Then, when the amplitude of peaks and troughs greater than or equal to a predetermined value appears in the extracted waveform component within a predetermined time, the detection unit 11 is walking (moving) while the user carrying the electronic device 1 is walking. May be detected.

  Further, the detection unit 11 detects that the user is moving on the bicycle when the feature value of the extracted waveform component is similar to the feature value of the user's waveform component when the user is riding the bicycle. You may do it. The characteristic value of the waveform component of the user when the user is riding a bicycle may be stored in the setting information 35 in advance. When the second measurement unit 22 includes a pedometer, the detection unit 11 may detect that the user is walking (moving) while the second measurement unit 22 is counting the number of steps.

  When the distance between the electronic device 1 and the user is equal to or greater than the first distance, the determination unit 12 determines that the first degree of risk is higher as the distance from the user approaches the first distance. The first distance is a distance measured by the user or the first measurement unit 21 by the display unit 40 of the electronic device 1, such as placing the electronic device 1 on the ear for a call or placing the electronic device 1 in a bag. This distance is close to the object and is considered not to be a state in which the user operates the electronic device 1.

FIG. 6 is a diagram illustrating an example of the distance information.
The distance information 31 will be described with reference to FIG.

  The distance information 31 stores the distance risk (first risk) and the distance between the electronic device 1 and the user in association with each other. The distance information 31 indicates that the distance risk is 0 when the first distance is 5 cm and the distance between the electronic device 1 and the user is less than 5 cm. And the distance information 31 has shown that distance danger is so high that the distance with a user approaches 1st distance in the distance beyond 1st distance. The distance risk is a value that is appropriately set according to the influence of the distance between the electronic device 1 and the user on the risk of the user, and indicates that the risk increases as the value increases.

  The determination unit 12 refers to the distance information 31 and determines the distance risk. In the following description, the first risk is also referred to as a distance risk.

This will be described with reference to FIG.
The determination unit 12 determines that the second risk is higher as the angle of the electronic device 1 with respect to the horizontal plane is smaller. That is, the determination unit 12 is more likely to cause the user to face down and operate the electronic device 1 as the angle with respect to the horizontal plane of the electronic device 1 becomes smaller, and the user cannot see the surroundings. Judge as high.

FIG. 7 is a diagram illustrating an example of the tilt information.
The tilt information 32 will be described with reference to FIG.

  The tilt information 32 stores the tilt risk (second risk) and the tilt of the electronic device 1 in association with each other. The inclination information 32 indicates that the distance risk is higher as the inclination of the electronic device 1 is smaller. The inclination risk is a value that is appropriately set according to the influence of the inclination of the electronic device 1 on the risk of the user, and indicates that the risk increases as the value increases.

  Then, the determination unit 12 refers to the inclination information 32 and determines the degree of inclination risk. In the following description, the second risk level is also referred to as a tilt risk level.

This will be described with reference to FIG.
The determination unit 12 determines that the third risk is higher as the sound around the electronic device 1 is larger. That is, as the sound around the electronic device 1 becomes louder, the determination unit 12 becomes harder for the user to hear sounds from passersby, and the user can determine the surrounding situation from the sound and avoid contact. Since it becomes difficult, it is determined that the risk level of the user is high.

FIG. 8 is a diagram illustrating an example of noise information.
The noise information 33 stores the noise risk level (third risk level) and the surrounding sound volume (noise level) in association with each other. The noise information 33 indicates that the greater the sound around the electronic device 1, the higher the distance risk. The noise risk level is a value that is appropriately set according to the influence of the surrounding sound level on the risk level of the user, and indicates that the higher the value, the higher the risk level.

  The determination unit 12 refers to the noise information 33 to determine the noise risk level. In the following description, the third risk level is also referred to as noise risk level.

  The determination unit 12 determines the fourth risk level by using a combination of two or more risk levels of the distance risk level, the tilt risk level, and the noise risk level. In the following description, the fourth risk level is also referred to as union risk level.

FIG. 9 is a diagram illustrating an example of the determination information.
The determination information 34 stores a determination value determined by a combination of the distance risk, the inclination risk, and the distance risk and the inclination risk in association with each other. The determination value is a value that is appropriately set according to the influence of the distance risk and the inclination risk on the user's risk, and indicates that the greater the value, the higher the user's risk. The determination unit 12 refers to the determination information 34 and determines a determination value.

FIG. 10 is a diagram illustrating an example of determination value settings.
The determination value will be described with reference to the determination value setting 300 in FIG. 10 is a diagram showing the state of the user corresponding to the determination value determined by the determination information 34 shown in FIG. The numbers attached to the upper left of each state diagram of the determination value setting 300 in FIG. 10 are the determination values in the state shown in each diagram. And the higher the determination value, the higher the risk level of the user.

  The determination value setting 300 indicates that when the distance between the electronic device 1 and the user is 5 cm or more, the closer the distance between the electronic device 1 and the user is, the more the user's field of view is blocked by the electronic device 1 and the higher the risk of the user. It shows that it becomes. The determination value setting 300 is, for example, when the distance between the electronic device 1 and the user is less than 5 cm, for example, when the user holds the electronic device 1 without operating it, or when the electronic device 1 is in the bag. , And the user presses the electronic device 1 against his / her ear to make a call. The determination value setting 300 indicates that the user is not in a dangerous state when the distance between the electronic device 1 and the user is less than 5 cm. The dangerous state is, for example, a state in which the user is highly likely to come into contact with a passerby or the like, and a state in which there is a high possibility of being hit by a step.

  The determination value setting 300 indicates that as the inclination of the electronic device 1 becomes smaller, the user faces downward and the front does not enter the field of view, so that the danger state of the user increases.

This will be described with reference to FIG.
When determining the combination risk using the distance risk and the inclination risk, the determination unit 12 may use the determination value determined using the determination information 34 as the combination risk. Further, when determining the combination risk using the distance risk, the inclination risk, and the noise risk, the determination unit 12 sets the noise risk value to the determination value determined using the determination information 34. The added value may be used as the association risk.

  When determining the union risk using the distance risk and the noise risk, the determination unit 12 may use a value obtained by adding the noise risk value to the distance risk value as the union risk. Further, when determining the union risk using the inclination risk and the noise risk, the determination unit 12 may use a value obtained by adding the noise risk value to the inclination risk value as the union risk.

  When the value of the union risk becomes larger than the maximum value of the determination value stored in the determination information 34, the determination unit 12 uses the determined union risk value as the determination value stored in the determination information 34. The maximum value may be adjusted.

  In the following description, the determination unit 12 stores the determined union risk value in the determination information 34 when the union risk level is greater than the maximum value of the determination value stored in the determination information 34. The maximum judgment value is adjusted.

  When the user is moving and the display unit 40 is on, the determination unit 12 performs two or more determinations of distance risk determination, inclination risk determination, and noise risk determination. To do. At this time, the determination unit 12 may determine only the risk level set by the user for use in determining the union risk level. The type of risk used for determining the union risk may be stored in the setting information 35, for example.

  The determination unit 12 may determine the fourth degree of risk when the detection unit 11 detects that the user is walking. And the determination part 12 may stop determination of a 4th risk, when it is detected by the detection part 11 that it is states other than a user walking.

  The restricting unit 13 restricts the function of the electronic device 1 according to the fourth degree of risk determined by the determining unit 12.

  The switching unit 14 switches each measurement unit to the on state when the user is moving and the display unit 40 is in the on state. Moreover, the switch part 14 switches each measurement part to an OFF state, when the distance with a user is less than 1st distance. When the distance to the user is less than the first distance, the switching unit 14 switches the display unit 40 to the off state.

  Further, the notification unit 15 notifies the user that it is dangerous according to the fourth degree of risk determined by the determination unit 12. In the following description, notifying the user that it is dangerous is also called a warning to the user.

FIG. 11 is a diagram illustrating an example of the risk handling process.
With reference to FIG. 11, the limitation of the function according to the union risk by the electronic device 1 and the warning to the user will be described. The function limitation and warning to the user described below are examples, and are set according to the situation as appropriate and stored in the setting information 35. Then, when the risk handling process is executed, the control unit 10 refers to the setting stored in the setting information 35 and executes a function restriction according to the union risk and a warning to the user.

  When the union risk is 4, the restriction unit 13 stops the operation of the electronic device 1 by the user. For example, when the input / output unit 60 has a touch panel function, the limiting unit 13 may stop accepting touch input from the user. When the union risk is 4, the notification unit 15 displays a large warning display on the display unit 40. At this time, for example, the notification unit 15 may cause the display unit 40 to display a message such as “Please be aware of the surrounding situation” as a warning display. Further, the notification unit 15 may input sound data to the sound generation unit 50 to sound an alarm for warning. The large warning display may be a warning display large enough to cover the display unit 40. In addition, sound data for generating an alarm may be stored in the setting information 35.

  When the union risk is 3, the restriction unit 13 restricts the operation of the electronic device 1 by the user. For example, when the input / output unit 60 has a touch panel function, the restriction unit 13 may restrict the acceptance of touch input from the user, such as accepting only screen switching. When the union risk is 3, the notification unit 15 causes the display unit 40 to display a medium warning display. At this time, for example, the notification unit 15 may cause the display unit 40 to display a message such as “Please be aware of the surrounding situation” as a warning display. Further, the notification unit 15 may input sound data to the sound generation unit 50 to sound an alarm for warning. The medium warning display may be a warning display large enough to cover about 30% of the display unit 40.

  When the union risk is 2, the restriction unit 13 does not restrict the operation of the electronic device 1 by the user. For example, when the input / output unit 60 has a touch panel function, the limiting unit 13 receives a touch input from the user. When the union risk is 2, the notification unit 15 causes the display unit 40 to flash a medium warning display. At this time, for example, the notification unit 15 may cause the display unit 40 to display a message such as “Please be aware of the surrounding situation” as a warning display.

  When the union risk is 1, the restriction unit 13 does not restrict the operation of the electronic device 1 by the user. For example, when the input / output unit 60 has a touch panel function, the limiting unit 13 receives a touch input from the user. When the union risk is 1, the notification unit 15 causes a small warning display to blink on the display unit 40. At this time, for example, the notification unit 15 may display a message such as “Be careful about the surroundings” on the upper side of the display unit 40 as a warning display. The small warning display may be a warning display large enough to cover about 10% of the display unit 40.

  When the union risk is 0, the switching unit 14 has a low possibility that the user looks at the display unit 40 of the electronic device 1 and operates the electronic device 1. Switch to the off state.

12 and 13 are flowcharts showing the danger avoidance process.
With reference to FIG. 12, FIG. 13, the danger avoidance process for the electronic device 1 to make a user avoid a danger is demonstrated. In the following description, the determination unit 12 determines the combination risk using the distance risk, the inclination risk, and the noise risk. The first measuring unit 21 includes the front camera 3 and measures the distance between the electronic device 1 and the user using an image captured by the front camera 3. The 2nd measurement part 22 shall be an acceleration sensor. The 3rd measurement part 23 shall have a microphone and shall measure the magnitude | size of the noise around the electronic device 1 using the sound collected with the microphone.

  The control unit 10 determines whether or not the user is walking (S101). When the user is not walking (No in S101), control unit 10 repeatedly executes the process of S101.

  When the user is walking (Yes in S101), control unit 10 determines whether or not the screen is on (S102). When the screen is not on (No in S102), control unit 10 executes the process of S101.

  When the screen is on (Yes in S102), control unit 10 determines whether the camera is being activated. When the camera is being activated (Yes in S103), the control unit 10 executes the process of S105. When the camera is not activated (No in S103), the controller 10 activates the camera (S104) and determines whether the microphone is activated (S105).

  When the microphone is being activated (Yes in S105), control unit 10 executes the process of S107. When the microphone is not activated (No in S105), control unit 10 activates the microphone (S106) and executes the process of S107.

This will be described with reference to FIG.
When the camera is activated, the first measurement unit 21 measures the distance (S107). The second measuring unit 22 measures the inclination of the electronic device 1 (S108). When the microphone is activated, the third measurement unit 23 measures the noise level (S109). In addition, when using the measurement of the acceleration by the 2nd measurement part 22 at the time of a danger avoidance process, the control part 10 may make the 2nd measurement part 22 into an ON state, when it determines with Yes in S102. . And the control part 10 may make the 2nd measurement part 22 an OFF state at the time of completion | finish of a danger avoidance process, when using the measurement of the acceleration by the 2nd measurement part 22 at the time of a danger avoidance process.

  The control part 10 performs the risk determination process mentioned later using the measurement result by each measurement part 20, and determines a combination risk (S110). And the control part 10 performs the risk handling process for avoiding the danger of the user mentioned later according to the union risk determined by the risk determination process (S111).

  The control unit 10 determines whether or not the user has requested to stop the danger avoidance process (S112). When there is no request for stopping the danger avoidance process from the user (No in S112), the control unit 10 executes the process of S101. When there is a request for stopping the danger avoidance process from the user (Yes in S112), the control unit 10 stops the first measurement part 21 and the third measurement part 23 and ends the danger avoidance process. The request for stopping the danger avoidance process may be input by the user via the input / output unit 60, for example. The stop request for the danger avoidance process may be automatically input, for example, when the display unit 40 is switched to the off state, or when the user's moving state is in a stopped state for a predetermined time or more. Note that the control unit 10 is not limited to S112, and if a stop request is input from the user during the execution of the risk avoidance process, the control unit 10 stops the first measurement unit 21 and the third measurement unit 23 to avoid danger. Processing may be terminated.

14 and 15 are flowcharts showing the risk determination process.
With reference to FIG. 14, FIG. 15, the risk determination process shown to S110 of FIG. 13 which determines a user's union risk is demonstrated. In the following description, the determination of the distance risk is made with reference to the distance information 31 shown in FIG. The inclination risk is determined with reference to the inclination information 32 shown in FIG. The noise risk level is determined with reference to the noise information 33 shown in FIG. The determination value is determined with reference to the determination information 34 shown in FIG.

  The control unit 10 determines whether or not the distance between the electronic device 1 measured by the first measurement unit 21 and the user is less than 5 cm (S201). When the distance between the electronic device 1 measured by the first measurement unit 21 and the user is less than 5 cm (Yes in S201), the control unit 10 refers to the distance information 31 and the distance risk is zero. (S202). And the control part 10 performs the process of S210.

  When the distance between the electronic device 1 measured by the first measurement unit 21 and the user is not less than 5 cm (No in S201), the control unit 10 determines whether the electronic device 1 measured by the first measurement unit 21 and the user are It is determined whether or not the distance is between 5 cm and less than 20 cm (S203). When the distance between the electronic device 1 measured by the first measurement unit 21 and the user is between 5 cm and less than 20 cm (Yes in S203), the control unit 10 refers to the distance information 31 and the distance risk degree Is determined to be 4 (S204). And the control part 10 performs the process of S210.

  When the distance between the electronic device 1 measured by the first measurement unit 21 and the user is not between 5 cm and less than 20 cm (No in S203), the control unit 10 measures the electronic device 1 measured by the first measurement unit 21. It is determined whether the distance between the user and the user is between 20 cm and less than 40 cm (S205). When the distance between the electronic device 1 measured by the first measurement unit 21 and the user is between 20 cm and less than 40 cm (Yes in S205), the control unit 10 refers to the distance information 31 and the distance risk degree Is determined to be 3 (S206). And the control part 10 performs the process of S210.

  When the distance between the electronic device 1 measured by the first measurement unit 21 and the user is not between 20 cm and less than 40 cm (No in S205), the control unit 10 measures the electronic device 1 measured by the first measurement unit 21. It is determined whether or not the distance between the user and the user is between 40 cm and less than 60 cm (S207). When the distance between the electronic device 1 measured by the first measurement unit 21 and the user is between 40 cm and less than 60 cm (Yes in S207), the control unit 10 refers to the distance information 31 and the distance risk degree Is determined to be 2 (S208). And the control part 10 performs the process of S210.

  When the distance between the electronic device 1 measured by the first measuring unit 21 and the user is not between 40 cm and less than 60 cm (No in S207), the control unit 10 determines that the distance between the electronic device 1 and the user is 60 cm or more. It is determined that there is, and it is determined that the distance risk is 1 with reference to the distance information 31 (S209). And the control part 10 performs the process of S210.

This will be described with reference to FIG.
The control unit 10 determines whether or not the inclination of the electronic device 1 measured by the second measurement unit 22 is between 0 degrees and less than 20 degrees (S210). When the inclination of the electronic device 1 measured by the second measurement unit 22 is between 0 degree and less than 20 degrees (Yes in S210), the control unit 10 refers to the inclination information 32 and the inclination risk is determined. 3 is determined (S211). And the control part 10 performs the process of S215.

  When the inclination of the electronic device 1 measured by the second measurement unit 22 is not between 0 degree and less than 20 degrees (No in S210), the control unit 10 determines the electronic device 1 measured by the second measurement unit 22 It is determined whether or not the inclination is between 20 degrees and less than 45 degrees (S212). When the inclination of the electronic device 1 measured by the second measurement unit 22 is between 20 degrees and less than 45 degrees (Yes in S212), the control unit 10 refers to the inclination information 32 and the distance risk is 2 is determined (S213). And the control part 10 performs the process of S215.

  When the tilt of the electronic device 1 measured by the second measuring unit 22 is not between 20 degrees and less than 45 degrees (No in S212), the control unit 10 determines that the tilt of the electronic device 1 is 45 degrees or more. Then, it is determined that the distance risk is 1 with reference to the inclination information 32 (S213). And the control part 10 performs the process of S215.

  The control unit 10 determines the determination value by referring to the determination information 34 using the determined distance risk and the inclination risk, and acquiring values associated with the distance risk and the inclination risk. (S215).

  Then, the control unit 10 determines whether or not the volume of sound around the electronic device 1 measured by the third measurement unit 23 is less than 60 db (S216). When the noise level around the electronic device 1 measured by the third measuring unit 23 is less than 60 db (Yes in S216), the control unit 10 determines the determination value determined in S215 as the value of the union risk. Determination is made (S217).

  When the magnitude of noise around the electronic device 1 measured by the third measurement unit 23 is not less than 60 db (No in S216), the control unit 10 determines the electronic device 1 measured by the third measurement unit 23. It is determined whether or not the volume of the surrounding sound is between 60 db and less than 100 db (S218). When the volume of the sound around the electronic device 1 measured by the third measurement unit 23 is between 60 db and less than 100 db (Yes in S218), the control unit 10 sets 1 to the determination value determined in S215. It is determined that the value obtained by adding is the value of the union risk (S219).

  When the magnitude of noise around the electronic device 1 measured by the third measurement unit 23 is not between 60 db and less than 100 db (No in S218), the control unit 10 is measured by the third measurement unit 23. The noise level around the electronic device 1 is determined to be 100 db or more. And the control part 10 determines with the value which added 2 to the determination value determined by S215 being a value of union risk (S220). And the control part 10 complete | finishes a risk determination process.

FIG. 16 is a flowchart showing the risk handling process.
The risk handling process will be described with reference to FIG.

  With reference to FIG. 16, the risk handling process shown in S <b> 111 of FIG. 13 for executing the process for causing the user to avoid the risk according to the union risk will be described. In the following description, the value determined in the risk determination process shown in S110 is used as the value of the union risk. Then, it is assumed that the setting information 35 stores the setting of the risk handling process 400 described with reference to FIG.

  The control unit 10 determines whether or not the value of the association risk determined in the risk determination process is 4 or more (S301). When the value of the union risk is 4 or more (Yes in S301), the control unit 10 refers to the setting information 35 to display a large warning display on the display unit 40 (S302), and the electronic device 1 by the user is displayed. The operation is restricted (S303). Then, the control unit 10 ends the risk handling process. The control unit 10 adjusts the union risk to 4 when the union risk is 4 or more. Then, the control unit 10 may refer to the risk handling process 400 stored in the setting information 35 and execute the process set in the record to which the risk 4 belongs.

  When the value of union risk is not 4 (No in S301), control unit 10 determines whether or not the value of union risk determined in the risk determination process is 3 (S304). When the value of the association risk is 3 (Yes in S304), the control unit 10 refers to the setting information 35 to display a medium warning display on the display unit 40 (S305), and the electronic device 1 by the user is displayed. Are limited (S306). Then, the control unit 10 ends the risk handling process. When the union risk is 3, the control unit 10 may refer to the risk handling process 400 stored in the setting information 35 and execute the process set for the record to which the risk 3 belongs.

  When the value of union risk is not 3 (No in S304), control unit 10 determines whether or not the value of union risk determined in the risk determination process is 2 (S307). When the value of the union risk is 2 (Yes in S307), the control unit 10 refers to the setting information 35 and causes the display unit 40 to flash a middle warning display (S308), and the electronic device by the user The operation of 1 is not limited (S309). Then, the control unit 10 ends the risk handling process. Note that when the union risk is 2, the control unit 10 may refer to the risk handling process 400 stored in the setting information 35 and execute the process set in the record to which the risk 2 belongs.

  When the value of union risk is not 2 (No in S307), control unit 10 determines whether or not the value of union risk determined in the risk determination process is 1 (S310). When the value of the union risk is 1 (Yes in S310), the control unit 10 refers to the setting information 35 and causes a small warning display to blink on the display unit 40 (S311). The operation is not limited (S312). Then, the control unit 10 ends the risk handling process. When the union risk is 1, the control unit 10 may refer to the risk handling process 400 stored in the setting information 35 and execute the process set for the record to which the risk 1 belongs.

  When the value of union risk is not 1 (No in S310), control unit 10 determines that the value of union risk determined in the risk determination process is 0, and turns display 40 off ( S313), the first measurement unit 21 and the third measurement unit 23 are stopped (S314). Then, the control unit 10 ends the risk handling process. At this time, the control unit 10 may also stop the second measurement unit 22 when the second measurement unit 22 is not used for the risk avoidance process. Note that when the union risk is 0, the control unit 10 may refer to the risk handling process 400 stored in the setting information 35 and execute the process set in the record to which the risk 0 belongs.

FIG. 17 is a block diagram illustrating an example of a computer apparatus.
The configuration of the computer apparatus 500 will be described with reference to FIG.

  In FIG. 17, a computer device 500 includes a control circuit 501, a storage device 502, a reading device 503, a recording medium 504, a communication interface 505, an input / output interface 506, a display device 507, an input device 508, A touch panel 509, a camera 510, an acceleration sensor 511, a microphone 512, and a distance sensor 513 are included. The communication interface 505 is connected to the network 514. Each component is connected by a bus 515.

  The control circuit 501 controls the entire computer device 500. The control circuit 501 is a processor such as a CPU, a multi-core CPU, an FPGA (Field Programmable Gate Array), and a PLD (Programmable Logic Device). The control circuit 501 functions as the control unit 10 in FIG. In FIG. 3, the distance information 31, the inclination information 32, the noise information 33, the determination information 34, and the setting information 35 stored in the storage unit 30 are stored in, for example, CPU, FPGA, and PLD caches. May be remembered.

  The storage device 502 stores various data. The storage device 502 is, for example, a memory such as a ROM (Read Only Memory) and a RAM (Random Access Memory), or an HD. For example, the storage device 502 functions as the storage unit 30 in FIG.

  The ROM stores a program such as a boot program. The RAM is used as a work area for the control circuit 501. The HD stores an OS, an application program, a program such as firmware, and various data.

  The storage device 502 stores, for example, a risk avoidance program that causes the control circuit 501 to function as the control unit 10.

  When the electronic device 1 controls the storage device, it reads out the danger avoidance program stored in the storage device 502 into the RAM. By executing the danger avoidance program read into the RAM by the control circuit 501, the electronic device 1 includes one or more of a detection process, a determination process, a restriction process, a switching process, and a notification process. Execute risk avoidance processing.

  Note that the danger avoidance program may be stored in a storage device included in a server on the network 514 as long as the control circuit 501 is accessible via the communication interface 505.

  The reading device 503 is controlled by the control circuit 501 and reads / writes data on the removable recording medium 504. The reading device 503 includes, for example, an FDD (Floppy Disk Drive), a CDD (Compact Disc Drive), a DVDD (Digital Versatile Disk Drive), a BDD (Blu-ray (registered trademark) U USB Ver. Etc.

  The recording medium 504 stores various data. The recording medium 504 stores, for example, a danger avoidance program. Further, the recording medium 504 may store the distance information 31, the inclination information 32, the noise information 33, the determination information 34, and the setting information 35 illustrated in FIG.

  The recording medium 504 is connected to the bus 515 via the reading device 503, and the control circuit 501 controls the reading device 503 so that data is read / written. The recording medium 504 includes, for example, an SD memory card (SD Memory Card), an FD (Floppy Disk), a CD (Compact Disc), a DVD (Digital Versatile Disk), a BD (Blu-ray (registered trademark) Disk), and the like. A non-temporary recording medium such as a flash memory.

  The communication interface 505 connects the computer device 500 and other devices via a network 514 so that they can communicate with each other. The communication interface 505 functions as the transmission / reception unit 70 in FIG. 3, for example.

  The communication interface 505 may include an interface having a wireless LAN function and an interface having a short-range wireless communication function. The wireless LAN interface may support Wi-Fi (registered trademark) as a wireless LAN standard, for example. For example, the short-range wireless interface may support Bluetooth (registered trademark) as a short-range wireless communication standard. LAN is an abbreviation for Local Area Network.

  The input / output interface 506 is connected to, for example, an input device 508 such as a keyboard and a mouse, and a touch panel 509. When signals indicating various information are input from the connected input device 508, the input / output interface 506 is input via the bus 515. The signal is output to the control circuit 501. Further, when a signal indicating various information output from the control circuit 501 is input via the bus 512, the input / output interface 506 outputs the signal to various connected devices. The input / output interface 506 functions as, for example, the input / output unit 60 in FIG.

  The display device 507 displays various information. The display device may display information for receiving input from the touch panel 509. For example, the display device 507 functions as the display device 4 in FIG. The display device 507 functions as the display unit 40 in FIG. Note that the touch panel 509 is preferably disposed so as to overlap with the display device 507 as a transmissive input unit. The touch panel may employ various coordinate detection methods such as a pressure-sensitive method, an electrostatic method, and an optical method, and the disclosed technique is not limited to any one of these detection methods.

  The camera 510 takes an image. The camera 510 functions as, for example, the front camera 3 in FIG. Moreover, the camera 510 functions as a camera which the 1st measurement part 21 has in FIG. 3, for example.

  The acceleration sensor 511 is a triaxial acceleration sensor, for example, and measures the acceleration of the XYZ axes. For example, the acceleration sensor 511 functions as the second measuring unit 22 in FIG. 3.

  The microphone 512 collects sound. The microphone 512 may input the collected sound into a sound DSP (not shown). DSP is an abbreviation for Digital Signal Processor. And the microphone 512 functions as the 3rd measurement part 23 in FIG. 3, for example.

  The distance sensor 513 is, for example, a sensor using a triangulation measurement method, a time-of-write method, or the like that detects a distance from an object in the normal direction of the display unit 40. The distance sensor 513 functions as, for example, the first measurement unit 21 in FIG.

  As described above, in the electronic device 1 according to the embodiment, when the distance between the electronic device 1 and the user approaches, the inclination of the electronic device 1 decreases, and the sound around the electronic device 1 increases, the risk of the user increases. Judge as high. And the electronic device 1 will restrict | limit the function which the electronic device 1 provides, when the determined risk degree becomes high. Moreover, the electronic device 1 does not restrict the functions provided by the electronic device 1 when the risk level of the user is low. Therefore, the electronic device 1 can avoid a user's danger without impairing convenience.

  The electronic device 1 according to the embodiment determines the degree of risk when the user is moving and the display unit 40 is on. As a result, the electronic device 1 can automatically determine the degree of danger and avoid the danger of the user.

  When the distance between the electronic device 1 and the user is less than a first distance that is assumed that the user is not operating the electronic device 1, the electronic device 1 according to the embodiment switches each measurement unit to the off state. Thereby, when the electronic device 1 is not used, the measurement unit is automatically turned off, so that it is possible to suppress consumption of power used for the danger avoidance process.

  The electronic device 1 according to the embodiment switches each measurement unit to the on state when the user is moving and the display unit 40 is in the on state. That is, when the electronic device 1 does not use the measurement unit, the measurement unit is turned off, and when the measurement unit is used, the measurement unit is automatically turned on. Can be suppressed.

  The electronic device 1 according to the embodiment switches the display unit 40 to the off state when the distance between the electronic device 1 and the user is less than a first distance assumed that the user is not operating the electronic device 1. Thereby, when the electronic device 1 is not used, the display unit 40 is automatically turned off, so that it is possible to suppress power consumption used for the danger avoidance process.

  The electronic device 1 according to the embodiment detects that the user is walking, and determines the union risk when the user is walking. Thereby, when the electronic device 1 is moving in a public organization such as a train and the user is not in a dangerous state, the electronic device 1 does not execute the risk avoidance process, so that it is possible to suppress power consumption used for the risk avoidance process.

  The electronic device 1 of the embodiment notifies the user that it is dangerous according to the union risk. Thereby, when the user is in a dangerous state, the electronic device 1 can cause the user to recognize the degree of danger and prompt the user to avoid the danger.

  In addition, this embodiment is not limited to embodiment described above, A various structure or embodiment can be taken in the range which does not deviate from the summary of this embodiment.

DESCRIPTION OF SYMBOLS 1 Electronic device 2, 3 Camera 4 Display apparatus 10 Control part 20 Measurement part 30 Storage part 40 Display part 50 Sounding part 60 Input / output part 70 Transmission / reception part 301 Imaging element 302 Lens 500 Computer apparatus 501 Control circuit 502 Storage apparatus 503 Reading apparatus 504 Recording medium 505 Communication interface 506 Input / output interface 507 Display device 508 Input device 509 Touch panel 510 Camera 511 Acceleration sensor 512 Microphone 513 Distance sensor 514 Network 515 Bus

Claims (8)

A detection unit for detecting a movement state of the user;
A first measurement for measuring a distance between the electronic device and the user;
A second measurement for measuring an angle of the electronic device with respect to a horizontal plane;
A third measurement for measuring the volume of sound around the electronic device;
A measuring unit for measuring any two or more of
While the user is moving,
When the distance between the electronic device and the user is equal to or greater than the first distance, a first determination that determines that the first risk is higher as the distance from the user is closer to the first distance;
A second determination that determines that the second risk is higher as the angle of the electronic device with respect to the horizontal plane is smaller;
A third determination that determines that the third risk is higher as the sound around the electronic device increases,
Make a decision of 2 or more of either
A determination unit for determining a fourth risk level using a combination of the two or more determined risk levels;
A limiting unit that limits the function of the electronic device in accordance with the fourth degree of risk determined by the determination unit;
An electronic device comprising: The electronic device further includes:
A display unit for displaying information;
The determination unit
When the user is moving and the display unit is in an on state, the determination is any two or more of the first determination, the second determination, and the third determination. 1. The electronic device according to 1. The electronic device further includes:
When the distance between the user is less than the first distance, the electronic device according to claim 2, characterized in that it comprises a switching unit for switching the pre Kihaka tough off. The switching unit is
The user is moving, and when the display unit is turned on, the electronic device according to claim 3, characterized in that switching the pre Kihaka tough ON state. The electronic device further includes:
The electronic device according to claim 2, further comprising: a switching unit that switches the display unit to an off state when the distance to the user is less than the first distance. The determination unit
Determining the fourth risk level using the first risk level and the second risk level;
The restriction unit is
The electronic device according to any one of claims 1 to 5, wherein the function of the electronic device is limited according to a fourth degree of risk determined by the determination unit. The detector is
Detect that the user is walking,
The determination unit
The electronic device according to any one of claims 1 to 6, wherein the fourth risk is determined when the user is walking. The electronic device further includes:
The electronic device according to claim 1, further comprising: a notification unit that notifies the user of the danger according to the fourth degree of risk determined by the determination unit. .

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