JP6840830B2 - Display system and wearable device - Google Patents

Description

The present invention relates to display systems, programs, mobile devices, and wearable devices.

As a conventional display system, for example, Patent Document 1 discloses a communication control system including an electronic clock and a computer. In this communication control system, the computer receives the balance information regarding the transition of the power generation amount or the charge balance of the secondary battery of the electronic clock from the electronic clock, and displays the transition of the balance information on the display unit.

WO2017 / 159761

By the way, the above-mentioned communication control system is further improved in that, for example, a physical quantity such as a power generation amount detected by a mobile device such as an electronic clock is displayed in an easy-to-understand manner in association with the activity of a user carrying the mobile device. There is room for improvement.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a display system, a program, a portable device, and a wearable device capable of appropriately displaying a detected physical quantity.

In order to achieve the above object, the display system according to the present invention controls a position detection unit for detecting a position, a physical quantity detection unit for detecting a physical quantity, a display unit for displaying an image, and the display unit for displaying an image. A movement including a portable device having a processing unit capable of executing the processing to be performed, the processing unit controls the display unit, and represents a movement route of the portable device determined according to a position detected by the position detection unit. It is characterized in that it is possible to execute an overlay display process in which a physical quantity image representing a physical quantity detected by the physical quantity detection unit is superimposed and displayed on the root image.

Further, in the display system, in the overlay display process, the processing unit transfers the physical quantity image representing the physical quantity detected by the physical quantity detection unit at the specific location of the movement route to the specific location of the movement route image. It can be superimposed and displayed at the corresponding position.

Further, in the display system, the mobile device includes a first mobile device and a second mobile device capable of communicating with each other, and the second mobile device has the physical quantity detecting unit and detects the physical quantity. The detected physical quantity information regarding the physical quantity detected by the unit is transmitted to the first mobile device, and the first mobile device has the position detection unit, the display unit, and the processing unit, and the processing unit has the processing unit. It is possible to control the display unit and execute the overlay display process based on the detected position information regarding the position detected by the position detection unit and the detected physical quantity information received from the second mobile device. it can.

Further, in the display system, the second portable device can be a wearable device that can be worn on a human body.

Further, in the display system, the second portable device is an electronic clock that displays the time by a pointer, and the physical quantity detected by the physical quantity detection unit is the amount of power generated by the second portable device. Can be assumed to be.

Further, in the display system, the processing unit may make the size of the physical quantity image variable according to the physical quantity represented by the physical quantity image in the superimposed display process.

Further, in the display system, when the physical quantity represented by the physical quantity image is a relatively small value in the overlay display processing, the processing unit determines the difference in size of the physical quantity image with respect to the difference in the value of the physical quantity. When the physical quantity is relatively large and the physical quantity represented by the physical quantity image is a relatively large value, the difference in size of the physical quantity image with respect to the difference in the value of the physical quantity can be relatively small.

Further, in the display system, in the overlay display process, the processing unit may make the display color or the transmittance of the physical quantity image variable according to the physical quantity represented by the physical quantity image.

Further, in the display system, the processing unit limits the maximum size and the minimum size of the physical quantity image within a predetermined ratio based on the size of the display area of the display unit in the superimposed display processing. Can be done.

Further, in the display system, the processing unit can superimpose and distinguish a plurality of the physical quantity images for each predetermined unit time in the superimposed display process.

Further, in the display system, in the overlay display process, the processing unit may sequentially display the physical quantities represented by the plurality of physical quantity images in response to an operation on the plurality of overlapping physical quantity images. ..

Further, in the display system, the processing unit may make the method of totaling the physical quantities to be displayed in the overlay display process variable based on the moving speed of the mobile device.

Further, in the display system, when the moving speed of the portable device is relatively slow, the processing unit aggregates the physical quantity according to the moving distance of the portable device, and the moving speed of the portable device is relative. If it is fast, the physical quantity can be aggregated according to the elapsed time.

Further, in the display system, when the processing unit detects that the first portable device and the second portable device are separated and relatively moved in the superimposed display process, the processing unit is separated and relatively moved. It is possible to execute the forget-holding handling process that makes the display of the physical quantity image different from the display of the physical quantity image outside the period.

Further, the display system may include a server capable of communicating with the mobile device and storing information transmitted / received to / from the mobile device.

Further, in the display system, the processing unit specifies the previously specified specific location while the moving distance of the mobile device from the specific location of the previously specified travel route exceeds a preset determination distance. The specific location this time is specified on condition that the elapsed time from the previous time exceeds the preset determination period, and the physical quantity detection unit detects the specific location from the specific location specified last time to the specific location specified this time. The integrated value of the physical quantity obtained may be the physical quantity at the specific location specified this time.

Further, in the display system, in the overlay display process, the processing unit detects the physical quantity at a plurality of specific points of the movement route within the merged display reference distance set in advance by the merged display reference distance. The physical quantities obtained can be merged and displayed as one physical quantity image.

Further, in the display system, the processing unit initially sets an intermediate position between the first specific location, which is the starting point within the merged display range, and the second specific location following the first specific location. A reference position is used, and a determination process is performed to determine whether or not the distance between the reference position and the specific location this time is equal to or greater than the merged display reference distance. When it is determined that the distance is not greater than or equal to the merged display reference distance, the specific location of this time is set as the specific location within the merged display range, and the intermediate position between the reference position and the specific location of this time is set. Is updated as the reference position in the next determination process, the determination process is repeated, and it is determined by the determination process that the distance between the reference position and the specific location this time is greater than or equal to the merged display reference distance. , The specific location of this time can be set as the first specific location which is the starting point within the next merged display range.

Further, in the display system, in the overlay display process, the processing unit displays the one physical quantity image obtained by merging the physical quantities detected by the physical quantity detection unit at the plurality of specific locations within the merged display range. In the moving route image, the image is superimposed on the position corresponding to the last reference position in the merged display range or the position corresponding to the centroid position of the plurality of specific points in the merged display range. can do.

In order to achieve the above object, the program according to the present invention controls a display unit of a computer and creates a travel route image representing a travel route of the mobile device determined according to a position detected by a position detection unit of the mobile device. The computer is characterized in that it performs an overlay display process of overlaying and displaying a physical quantity image representing a physical quantity detected by a physical quantity detection unit of the mobile device.

In order to achieve the above object, the portable device according to the present invention controls a position detection unit for detecting a position, a physical quantity detection unit for detecting a physical quantity, a display unit for displaying an image, and the display unit for displaying an image. The processing unit has a processing unit capable of executing a process to be displayed, and the processing unit controls the display unit and displays a moving route image representing a moving route determined according to a position detected by the position detecting unit. It is characterized in that it is possible to execute a superimposition display process of superimposing and displaying a physical quantity image representing a physical quantity detected by a physical quantity detection unit.

In order to achieve the above object, the wearable device according to the present invention can execute a position detecting unit for detecting a position, a display unit for displaying an image, and a process for controlling the display unit to display an image. The processing unit controls the display unit, and the physical quantity image representing the physical quantity is superimposed and displayed on the moving route image representing the moving route determined according to the position detected by the position detecting unit. It has a communication unit capable of communicating with a mobile device capable of executing processing and a physical quantity detection unit for detecting the physical quantity, and the communication unit obtains detected physical quantity information regarding the physical quantity detected by the physical quantity detection unit. It is characterized in that it is transmitted to the portable device.

The display system, program, portable device, and wearable device according to the present invention shall execute the overlay display process by the position detection unit, the physical quantity detection unit, the display unit, and the processing unit of the portable device having the processing unit. Can be done. As a result, the display system, the program, the portable device, and the wearable device display the physical quantity image representing the physical quantity detected by the physical quantity detection unit in the moving route image representing the moving route of the mobile device on the display unit of the mobile device. It can be displayed in layers. Therefore, the display system, the program, the portable device, and the wearable device can display the physical quantity detected by the physical quantity detection unit in an easy-to-understand manner in association with the activity of the user who carries the portable device. As a result, the display system, the program, the portable device, and the wearable device have the effect of being able to properly display the detected physical quantity.

FIG. 1 is a block diagram showing a schematic configuration of a display system according to an embodiment. FIG. 2 is a block diagram showing a schematic configuration of a first portable device included in the display system according to the embodiment. FIG. 3 is a block diagram showing a schematic configuration of a second portable device included in the display system according to the embodiment. FIG. 4 is a diagram showing an example of a display screen displayed on the display unit of the display system according to the embodiment. FIG. 5 is a flow chart showing an example of a series of processes executed when the superimposed display process is executed in the display system according to the embodiment. FIG. 6 is a diagram showing an example of the display color of the physical quantity image displayed on the display unit of the display system according to the embodiment. FIG. 7 is a diagram showing an example of superimposed display of physical quantity images displayed on the display unit of the display system according to the embodiment. FIG. 8 is a schematic diagram illustrating an example of a first aggregation method of physical quantities in the display system according to the embodiment. FIG. 9 is a schematic diagram illustrating an example of a physical quantity image of a physical quantity aggregated by the first aggregation method of the physical quantity in the display system according to the embodiment. FIG. 10 is a diagram showing an example of a display screen when the forget-holding handling process is executed in the display system according to the embodiment. FIG. 11 is a diagram showing an example of a display screen when the forget-holding handling process is executed in the display system according to the embodiment. FIG. 12 is a schematic diagram illustrating an example of a forget-holding handling process in the display system according to the embodiment. FIG. 13 is a diagram showing an example of a display screen when the forget-holding handling process is executed in the display system according to the embodiment. FIG. 14 is a diagram showing an example of a display screen when the forget-holding handling process is executed in the display system according to the embodiment. FIG. 15 is a schematic diagram illustrating an example of a method of totaling physical quantities in a display system according to a modified example. FIG. 16 is a schematic diagram illustrating an example of a method of totaling physical quantities in a display system according to a modified example. FIG. 17 is a schematic diagram illustrating an example of merged display in the display system according to the modified example. FIG. 18 is a schematic diagram illustrating an example of merged display in the display system according to the modified example. FIG. 19 is a diagram showing an example of a display screen when the display mode of the physical quantity image is variable according to a plurality of second portable devices in the display system according to the modified example.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the drawings. The present invention is not limited to this embodiment. In addition, the components in the following embodiments include those that can be easily replaced by those skilled in the art, or those that are substantially the same.

[Embodiment]
<Overview of display system>
The display system Sys1 of the present embodiment shown in FIG. 1 includes a portable device 10 that can be carried by a person. The display system Sys1 of the present embodiment detects on the display unit 25a of the mobile device 10 together with the movement route of the person (hereinafter, may be referred to as “user”) who possesses the mobile device 10 on the mobile device 10. It is a system that superimposes and displays physical quantities. As a result, the display system Sys1 realizes an easy-to-understand display in which the physical quantity detected by the mobile device 10 is associated with the activity of the user carrying the mobile device 10 on the display unit 25a.

As an example, the display system Sys1 of the present embodiment will be described as including a plurality of portable devices 10. Here, the mobile device 10 includes a first mobile device 20 and a second mobile device 30 that can communicate with each other. Further, the display system Sys1 of the present embodiment will be described as further including a server 40 capable of communicating with the mobile device 10 in addition to the mobile device 10 (first mobile device 20, second mobile device 30). .. The display system Sys1 of the present embodiment constitutes a cooperation system that realizes the above-mentioned easy-to-understand display by communicating with each other and cooperating with the first mobile device 20, the second mobile device 30, and the server 40. .. Further, in the present embodiment, the physical quantity detected by the portable device 10 will be described as, for example, the amount of power generated by the second portable device 30. Here, the server 40 will be described as forming a part of the display system Sys1, but the present invention is not limited to this, and for example, the server 40 may also be used by a server that constitutes a part of another system. Hereinafter, each configuration of the display system Sys1 will be described in detail with reference to each figure.

<Basic configuration of mobile devices>
The portable device 10 is an electronic terminal device configured to be portable by the user. Typically, the first mobile device 20 of the mobile devices 10 constitutes a main communication terminal that communicates with the server 40 via the network N. On the other hand, the second mobile device 30 of the mobile devices 10 constitutes a secondary communication terminal that communicates with the first mobile device 20 via short-range wireless communication. The network N is composed of an arbitrary communication network regardless of wireless communication using Wi-Fi (registered trademark), 4G, 5G, etc., or wired communication using a communication line, and connects the server 40 and the first mobile device 20. Connect so that you can communicate. The method of short-range wireless communication is, for example, Bluetooth (registered trademark), W-LAN, Wi-Fi (registered trademark), NFC (Near Field Communication), or the like. However, the second mobile device 30 is not limited to short-range wireless communication, and may be configured to be able to communicate with the server 40 and the first mobile device 20 via the network N.

The mobile device 10 can be composed of, for example, a smartphone, a tablet PC, a notebook PC, a PDA, a mobile game device, a wearable device that can be worn on a human body, and the like. Examples of wearable devices include wristband type, eyeglass type, ring type, shoe type, pendant type and the like. The first portable device 20 of the present embodiment will be described as an example of a smartphone. On the other hand, the second portable device 30 of the present embodiment will be described as, for example, a wristband-type wearable device worn on an wrist and an electronic watch (wrist watch) that displays the time.

<Basic configuration of the first mobile device>
The first mobile device 20 is an electronic terminal device capable of receiving various services from the server 40 by communicating with and cooperating with the server 40. Here, the first mobile device 20 is a smartphone as described above.

Specifically, as shown in FIG. 2, the first mobile device 20 processes the power supply unit 21, the communication unit 22, the input unit 23, the detection unit 24, the output unit 25, and the storage unit 26. It has a part 27 and.

The power supply unit 21 is a power source for the first mobile device 20. The power supply unit 21 includes a rechargeable secondary battery 21a or the like such as a lithium ion battery, and supplies electric power to each unit in the first portable device 20.

The communication unit 22 is a communication module capable of communicating with the outside of the first mobile device 20. The communication unit 22 is communicably connected to the network N regardless of wireless communication or wired communication, and communicates with the server 40 via the network N. The communication unit 22 also communicates with the second mobile device 30 via short-range wireless communication.

The input unit 23 is a portion that receives various inputs to the first mobile device 20. The input unit 23 includes, for example, a touch panel 23a for receiving an operation input for the first mobile device 20, a voice input device 23b for receiving a voice input for the first mobile device 20, and the like. The input unit 23 may also include an input device such as an operation button, a keyboard, and a mouse pointer.

The detection unit 24 is a unit that detects various information in the first portable device 20. The detection unit 24 includes a position detection unit 24a that detects a position in at least the first portable device 20. The position detection unit 24a is a positioning device that measures the current position of the first portable device 20. As the position detection unit 24a, for example, a GPS receiver or the like that receives radio waves transmitted from a GPS (Global Positioning System) satellite can be used. The position detection unit 24a receives radio waves transmitted from GPS satellites and acquires information (GPS information such as latitude / longitude coordinates) representing the current position of the first mobile device 20 to determine the position in the first mobile device 20. Can be detected. In addition to this, the detection unit 24 includes, for example, an acceleration sensor that detects the acceleration acting on the first mobile device 20, an illuminance sensor that detects the illuminance of the light emitted to the first mobile device 20, and a vicinity of the first mobile device 20. It may be configured to include a temperature sensor for detecting temperature, a voltage / current sensor for detecting power supply voltage, current, etc. of the power supply unit 21, and the like.

The output unit 25 is a unit that outputs various outputs in the first portable device 20. The output unit 25 includes at least a display unit 25a for displaying an image. The display unit 25a is composed of, for example, an image display device such as a liquid crystal display, a plasma display, or an organic EL display that displays an image. The touch panel 23a described above is provided so as to be superimposed on the surface of the display unit 25a (see FIG. 4). The output unit 25 may also include, for example, an indicator light, a speaker / alarm buzzer, a vibrator, and the like.

The storage unit 26 is a storage device for a ROM, RAM, semiconductor memory, etc. built in the first portable device 20. The storage unit 26 stores conditions and information necessary for various processes in the first mobile device 20, various application programs to be executed in the first mobile device 20, control data, and the like. Further, the storage unit 26 detects various information received by the communication unit 22, various information input by the input unit 23, and various information detected by the detection unit 24 (for example, detection of the position detected by the position detection unit 24a). (Including position information and the like), various information and the like output by the output unit 25 can be stored. In the storage unit 26, such information is read out as needed by the processing unit 27 and the like.

The processing unit 27 is electrically connected to each unit of the first mobile device 20 and controls each unit of the first mobile device 20 in an integrated manner. The processing unit 27 includes an electronic circuit mainly composed of a well-known microcomputer including a central processing unit such as a CPU. The processing unit 27 is communicably connected to each unit of the first portable device 20, and can exchange various signals with each other. The processing unit 27 executes various application programs stored in the storage unit 26, and when the program operates, operates each part of the first mobile device 20 to execute various processes for realizing various functions. .. The processing unit 27 can execute a process of controlling at least the display unit 25a to display an image. Further, the processing unit 27 can execute, for example, a process of acquiring various information from the second mobile device 30, the server 40, etc. via the communication unit 22 and storing the information in the storage unit 26. Further, the processing unit 27 executes various processes according to the operation contents performed by the user on the input unit 23 (touch panel 23a, voice input device 23b), for example.

<Basic configuration of the second mobile device>
The second mobile device 30 is an electronic terminal device that can receive various services together with the first mobile device 20 by communicating with and cooperating with the first mobile device 20. Here, the second portable device 30 is an electronic clock as described above. The second mobile device 30 of the present embodiment is paired with the first mobile device 20 so as to be communicable in response to various pairing operations. The second portable device 30 shown in FIG. 1 is an analog electronic clock (analog quartz clock) that displays the time by pointing to the index (scale) of the dial with physical pointers 3 (second hand 3a, minute hand 3b, hour hand 3c). Is. The second portable device 30 is not limited to this, and is a digital electronic clock (digital quartz clock) that digitally displays the time, a combination electronic clock (combination quartz clock) that partially includes a digital display together with an analog pointer display, and the like. You may.

Specifically, as shown in FIG. 3, the second portable device 30 includes a power supply unit 31, a communication unit 32, a timekeeping unit 33, a drive unit 34, an operation unit 35, a detection unit 36, and an output. It has a unit 37, a storage unit 38, and a processing unit 39.

The power supply unit 31 is a power source for the second mobile device 30. The power supply unit 31 includes a rechargeable secondary battery 31a such as a lithium ion battery and a power generation unit 31b capable of generating electric power, and supplies electric power to each part in the second portable device 30. The power generation unit 31b is composed of a power generation element such as a solar cell capable of generating electric power by converting optical energy into electric energy by utilizing the photovoltaic effect. The power generation unit 31b may also be composed of a piezoelectric element, a thermoelectric conversion element, a vibration power generation element, or the like.

The communication unit 32 is a communication module capable of communicating with the outside of the second mobile device 30. The communication unit 32 communicates with the first mobile device 20 via short-range wireless communication. The communication unit 22 may be configured to be communicably connected to the network N regardless of wireless communication or wired communication, and to communicate with the server 40 and the first mobile device 20 via the network N.

The time measuring unit 33 is a circuit for measuring the time (time inside the clock) displayed by the pointer 3. The timekeeping unit 33 includes, for example, an oscillator, an oscillation circuit, a compensation circuit, a frequency dividing circuit, and the like, and generates a clock signal having a predetermined frequency that serves as a reference for timekeeping inside the second portable device 30. Timekeeping is performed by counting the pulses included in the clock signal.

The drive unit 34 is a circuit that rotationally drives the pointer 3. The drive unit 34 operates the motor (for example, a stepping motor) 34a by the electric power supplied from the power supply unit 31. The rotational force generated by the motor 34a is transmitted to the pointer 3 via the train wheel or the like, and the pointer 3 is rotationally driven. The motor 34a may be individually provided for a plurality of pointers 3 (second hand 3a, minute hand 3b, hour hand 3c), or may be shared by some pointers 3.

The operation unit 35 is a part that accepts external operations as various inputs to the second mobile device 30. The operation unit 35 is composed of a crown 35a, push buttons 35b, 35c, etc., which are provided so as to project from the outer peripheral surface of the outer case (see also FIG. 1). The operation unit 35 receives various operations in conjunction with each part in the outer case in response to a pull-out / rotation operation on the crown 35a and a pressing operation on the push buttons 35b and 35c. The operation unit 35 may also include registering and the like.

The detection unit 36 is a part that detects various information in the second portable device 30. The detection unit 36 includes a physical quantity detection unit 36a that detects various physical quantities in at least the second portable device 30. In the present embodiment, the physical quantity detected by the physical quantity detecting unit 36a will be described as being the amount of power generated by the second portable device 30 as described above. Here, the physical quantity detection unit 36a generates power by detecting the power supply voltage and current of the secondary battery 31a, the presence or absence of power generation by the power generation unit 31b, the power generation voltage, the current, etc. as the physical quantity that can be detected by the second portable device 30. It is composed of a voltage / current sensor or the like that detects the amount of power generated by the unit 31b. The detection unit 36 also includes, for example, an acceleration sensor that detects the acceleration acting on the second mobile device 30, an illuminance sensor that detects the illuminance of the light emitted to the second mobile device 30, and the vicinity of the second mobile device 30. It may be configured to include a temperature sensor for detecting the temperature, a positioning device for measuring the current position of the second portable device 30, and the like.

The output unit 37 is a portion of the second mobile device 30 that outputs various outputs other than the time. The output unit 37 may include, for example, an indicator light, a speaker / alarm buzzer, a vibrator, and the like. When the second portable device 30 is a digital electronic clock or a combination electronic clock, the output unit 37 digitally displays an image including time and function selection instead of the physical pointer 3. It may be configured to include.

The storage unit 38 is a storage device for a ROM, RAM, semiconductor memory, etc. built in the second portable device 30. Typically, the storage unit 38 has a relatively small storage capacity as compared with the storage unit 26 of the first portable device 20 described above. The storage unit 38 stores conditions and information necessary for various processes in the second mobile device 30, various application programs to be executed in the first mobile device 20, control data, and the like. Further, the storage unit 38 detects various information received by the communication unit 32, timekeeping information measured by the timekeeping unit 33, and various information detected by the detection unit 36 (for example, detection of the physical quantity detected by the physical quantity detection unit 36a). (Including physical quantity information and the like), various information and the like output by the output unit 37 can be stored. In the storage unit 38, such information is read out as needed by the processing unit 39 and the like.

The processing unit 39 is electrically connected to each unit of the second mobile device 30 and controls each unit of the second mobile device 30 in an integrated manner. The processing unit 39 includes an electronic circuit mainly composed of a well-known microcomputer including a central processing unit such as a CPU. The processing unit 39 is communicably connected to each unit of the second portable device 30, and can exchange various signals with each other. The processing unit 39 executes various application programs stored in the storage unit 38, and when the program operates, operates each part of the second mobile device 30 to execute various processes for realizing various functions. .. For example, the processing unit 39 controls the motor 34a by the drive unit 34 based on the time measured by the time measuring unit 33, rotates the pointer 3 to move the hand, and displays the time measured on the pointer 3 as the current time. To execute. Further, the processing unit 39 executes various processes according to the operation contents performed by the user on the operation unit 35 (crown 35a, push button 35b, 35c), for example.

<Basic server configuration>
The server 40 constitutes a cloud service device (cloud server) mounted on the network N. The server 40 includes an electronic circuit mainly composed of a well-known microcomputer including a central processing unit such as a CPU, various storage devices such as a semiconductor memory, and the like. The server 40 can also be configured by installing a program that realizes various processes in a known computer system such as a PC or workstation. Further, the server 40 may be configured by a single device, or may be configured by combining a plurality of devices so as to be able to communicate with each other. The server 40 stores and manages information transmitted and received to and from the mobile device 10 (here, the first mobile device 20). The server 40 also stores and manages various information necessary for various services in the display system Sys1. The server 40 reads out this information as needed via the network N or the like.

<Overview of overlay processing>
In the display system Sys1 configured as described above, the processing unit 27 of the first mobile device 20 can control the display unit 25a to execute the overlay display processing. As shown in FIG. 4, the overlay display process is a process of controlling the display unit 25a to superimpose the physical quantity image I2 on the movement route image I1. The moving route image I1 displayed in the overlay processing is an image representing the moving route of the mobile device 10 determined according to the position of the mobile device 10 detected by the position detection unit 24a of the mobile device 10, for example, a map. It is displayed including images and the like. In other words, the movement route of the mobile device 10 corresponds to the movement route of the user who carries the mobile device 10. That is, the moving route image I1 corresponds to an image showing the moving route of the user who carries the mobile device 10. On the other hand, the physical quantity image I2 displayed by the overlay processing is an image showing the physical quantity detected by the physical quantity detection unit 36a of the portable device 10. Here, the physical quantity detected by the physical quantity detecting unit 36a is the amount of power generated by the second portable device 30 as described above. That is, the physical quantity image I2 corresponds to an image showing the amount of power generated by the second portable device 30 as the physical quantity detected by the physical quantity detecting unit 36a. In the display system Sys1, the processing unit 27 executes this superimposed display process, so that the physical quantity detected by the mobile device 10, here, the amount of power generated by the second mobile device 30, and the user carrying the mobile device 10 Realize an easy-to-understand display associated with activities.

Here, as described above, the position detection unit 24a, the display unit 25a, and the processing unit 27 that executes the overlay display processing are provided in the first mobile device 20 of the mobile device 10, and the physical quantity detection unit 36a is the mobile device. It is provided in the second portable device 30 out of 10. The second mobile device 30 transmits the detected physical quantity information regarding the physical quantity (power generation amount) detected by the physical quantity detection unit 36a to the first mobile device 20. Then, the first mobile device 20 controls the display unit 25a based on the detection position information regarding the position detected by the position detection unit 24a by the processing unit 27 and the detected physical quantity information received from the second mobile device 30. The above overlay processing is executed. Further, as an example, the processing unit 27 of the first portable device 20 of the present embodiment executes the overlapping display processing in cooperation with the server 40. Here, the processing unit 27 temporarily stores the detected physical quantity information received from the second mobile device 30 in the server 40, then appropriately reads out the necessary information together with the detected physical quantity information from the server 40 and performs the overlay display process. Execute.

<Example of processing flow>
The display system Sys1 of the present embodiment is, for example, as shown in FIG. 5, a physical quantity detection process (step S1), an information transmission process (step S2), an information storage process (step S3), an information read process (step S4), and the like. By executing the movement route identification process (step S5), the detection position identification process (step S6), the display image generation process (step S7), and the overlay display process (step S8), the display as illustrated in FIG. 4 is performed. To realize. The processing units 27 and 39 execute each of the above processes by executing the program stored in the storage units 26 and 38. The program is executed by the processing units 27 and 39 to cause the mobile device 10 (first mobile device 20, second mobile device 30) as a computer to execute each of the above processes.

<Physical quantity detection process>
First, the processing unit 39 of the second portable device 30 executes the physical quantity detection process (step S1). The physical quantity detection process is a process of detecting a physical quantity by the physical quantity detection unit 36a in a predetermined sampling cycle (for example, 5 minutes). Here, the physical quantity detection unit 36a detects the power generation amount of the electric power generated by the power generation unit 31b of the second portable device 30 as the physical quantity.

<Information transmission process>
Next, the processing unit 39 executes the information transmission process via the communication unit 32 (step S2). The information transmission process is a process of transmitting the detected physical quantity information regarding the physical quantity detected in the physical quantity detection process to the first mobile device 20 via the communication unit 32. The processing unit 39 processes information transmission of untransmitted detected physical quantity information at the timing when the first mobile device 20 and the second mobile device 30 can perform short-range wireless communication via the communication units 22 and 32, for example. To execute.

<Information storage processing>
Next, when the processing unit 27 of the first mobile device 20 receives the detected physical quantity information from the second mobile device 30 via the communication unit 22, the processing unit 27 executes the information storage process via the communication unit 22 (step S3). The information storage process is a process of transmitting the detected physical quantity information received from the second mobile device 30 to the server 40 together with other information via the communication unit 22. In the information storage process, the processing unit 27 transmits the detected physical quantity information received from the second mobile device 30 to the server 40 together with the detected position information regarding the position detected by the position detecting unit 24a. In this case, the processing unit 27 associates the detected physical quantity information with the detection time information indicating the time when the physical quantity of the detected physical quantity information is detected and the detection position information indicating the position where the physical quantity of the detected physical quantity information is detected. (Link), store in the server, and store.

<Information read processing>
Next, the processing unit 27 executes the information reading process via the communication unit 22 (step S4). The information reading process is a process of reading the detected physical quantity information, the detected time information, and the detected position information associated with each other from the server 40 via the communication unit 22. In this case, for example, the processing unit 27 reads out all the combinations of the detected physical quantity information, the detection time information, and the detection position information within the target period in which the overlay display processing is performed from the server 40. The target period for performing the overlay display processing may be predetermined, or may be arbitrarily set by the user via the input unit 23 or the like.

<Movement route identification process>
Next, the processing unit 27 executes the movement route specifying process (step S5). The movement route identification process is a movement route (movement locus) of the mobile device 10 (first mobile device 20, second mobile device 30) based on the detection time information and detection position information of the target period read from the server 40. It is a process to identify. In other words, the movement route of the mobile device 10 specified by the movement route identification process corresponds to the movement route of the user who carries the mobile device 10.

<Detection position identification process>
Next, the processing unit 27 executes the detection position specifying process (step S6). The detection position identification process is based on the detected physical quantity information, the detection time information, and the detected position information of the target period read from the server 40, and the physical quantity of each detected physical quantity information is detected in the travel route specified by the travel route identification process. It is a process to specify the position.

<Display image generation process>
Next, the processing unit 27 executes the display image generation process (step S7). The display image generation process is a display image to be displayed on the display unit 25a based on the movement route specified by the movement route identification process and the position where the physical quantity of each detected physical quantity information specified by the detection position identification process is detected. It is a process to generate. In the display image generation process, the processing unit 27 superimposes the physical quantity image I2 representing the physical quantity of each detected physical quantity information on the moving route image I1 representing the moving route specified in the moving route specifying process (see FIG. 4). To generate. In this case, the processing unit 27 superimposes the physical quantity image I2 representing the physical quantity of each detected physical quantity information on the position corresponding to the position where each physical quantity is detected in the moving route image I1. That is, the processing unit 27 generates a display image in which the physical quantity image I2 representing the physical quantity detected by the physical quantity detection unit 36a at the specific location of the movement route is superimposed on the position corresponding to the specific location of the movement route image I1. ..

<Overlapping display processing>
Then, the processing unit 27 controls the display unit 25a based on the display image generated in the display image generation process to execute the superimposed display process (step S8), and ends a series of processes. In the overlay display process, the processing unit 27 displays the display image generated in the display image generation process on the display unit 25a, so that each physical quantity image I2 is superimposed on the movement route image I1 as shown in FIG. Let me. More specifically, in the overlay display process, the processing unit 27 superimposes and displays the physical quantity image I2 representing the physical quantity detected at the specific location of the movement route at the position corresponding to the specific location of the movement route image I1.

<Variations of physical quantity images>
In the overlay display process as described above, the physical quantity image I2 can be displayed on the display unit 25a in various display modes. Typically, in the overlay display processing, the processing unit 27 can change the display mode of the physical quantity image I2 according to the magnitude of the physical quantity expressed by the physical quantity image I2.

<Variation 1; variable size>
In the overlay processing, the processing unit 27 can change the size of the physical quantity image I2 according to the magnitude of the physical quantity represented by the physical quantity image I2, for example, as shown in FIG. For example, when displaying the physical quantity image I2 in a circular shape as shown in FIG. 4, the processing unit 27 changes the size of the physical quantity image I2 by changing the diameter (in other words, the area) of the circle. Can be done. In this case, when the physical quantity represented by the physical quantity image I2 is a relatively small value, the processing unit 27 causes the display unit 25a to display the physical quantity image I2 in a relatively small size. On the other hand, when the physical quantity represented by the physical quantity image I2 is a relatively large value, the processing unit 27 causes the display unit 25a to display the physical quantity image I2 with a relatively large size. That is, in this case, the display system Sys1 makes the size of the physical quantity image I2 relatively small and displays it on the display unit 25a, so that the amount of power generated by the second portable device 30 at the position where the physical quantity image I2 is displayed ( It can be expressed that the physical quantity) was relatively small. On the other hand, the display system Sys1 increases the size of the physical quantity image I2 relatively and displays it on the display unit 25a, so that the amount of power generated (physical quantity) of the second portable device 30 at the position where the physical quantity image I2 is displayed. Can be expressed as being relatively large.

<Additional items regarding variable size 1: degree of change in size>
Further, in this case, in the overlay processing, when the physical quantity represented by the physical quantity image I2 is a relatively small value, the processing unit 27 makes a relatively large difference in the size of the physical quantity image I2 with respect to the difference in the value of the physical quantity. It may be displayed on the display unit 25a. Then, when the physical quantity represented by the physical quantity image I2 is a relatively large value, the processing unit 27 causes the display unit 25a to display the difference in size of the physical quantity image I2 relative to the difference in the value of the physical quantity. You may do so. As a result, the display system Sys1 can effectively express the magnitude difference of the physical quantity represented by the physical quantity image I2 by the size of the physical quantity image I2.

<Additional items regarding variable size 2: Size limitation>
Further, in the overlay display processing, the processing unit 27 limits the maximum size and the minimum size of the physical quantity image I2 within a predetermined ratio based on the size of the display area 25at (see FIG. 4) of the display unit 25a. You may try to do it. Here, the display area 25at of the display unit 25a is an area in which an image can be displayed on the display unit 25a, and is a substantially rectangular area in the example of FIG. The processing unit 27 has a size that fits the maximum size of the physical quantity image I2 within the display area 25at, for example, the diameter is half or less of the length L (see FIG. 4) in the short side direction of the display area 25at. You may try to limit it to size. In this case, the processing unit 27 displays the physical quantity image I2 with the maximum size limited as described above even if the physical quantity represented by the physical quantity image I2 is larger than the value corresponding to the maximum size. Become. Further, the processing unit 27 has a size that allows the user to easily see the minimum size of the physical quantity image I2, for example, one twentieth of the length L in the short side direction of the display area 25 at (see FIG. 4). It may be limited to the above size. In this case, the processing unit 27 displays the physical quantity image I2 with the minimum size limited as described above even if the physical quantity represented by the physical quantity image I2 is smaller than the value corresponding to the minimum size. Become. Further, as described above, the processing unit 27 also expands / reduces the entire display screen including the physical quantity image I2 in accordance with the user's enlargement / reduction operation (pinch-out / pinch-in operation) with respect to the touch panel 23a, for example. The maximum size and the minimum size of the physical quantity image I2 may be limited. As a result, the display system Sys1 can ensure proper visibility in the display on the display unit 25a by the overlay display process.

<Variation 2; variable color parameters>
In the overlay display processing, the processing unit 27 can change the display color or the transmittance of the physical quantity image I2 according to the magnitude of the physical quantity represented by the physical quantity image I2. The processing unit 27 can change the display color of the physical quantity image I2 by changing, for example, the hue, saturation, and lightness, which are the three attributes of the color. Here, the hue is an attribute representing the type of color, and represents the difference in the appearance of colors such as red, yellow, green, blue, and purple. Saturation represents the degree of vividness of a color. Brightness represents the degree of brightness of a color. The transmittance of the physical quantity image I2 is an index indicating the degree of transparency of the image behind the physical quantity image I2, and the lower the value, the less the image behind the physical quantity image I2 is transmitted, and the higher the value. It means that the image behind the physical quantity image I2 is transmitted to some extent.

For example, the processing unit 27 changes the display color of the physical quantity image I2 according to the magnitude of the physical quantity represented by the physical quantity image I2 based on the color palette data P (stored in the storage unit 26) as illustrated in FIG. can do. The palette data P is data relating to a plurality of display colors of the physical quantity image I2, and is stored in the storage unit 26. In this case, for example, when the physical quantity represented by the physical quantity image I2 is a relatively small value, the processing unit 27 causes the display unit 25a to display the physical quantity image I2 in a cold color. On the other hand, when the physical quantity represented by the physical quantity image I2 is a relatively large value, the processing unit 27 causes the display unit 25a to display the physical quantity image I2 in a warm color display color. That is, in this case, the display system Sys1 causes the display unit 25a to display the physical quantity image I2 in a cold color, so that the amount of power generated (physical quantity) of the second portable device 30 at the position where the physical quantity image I2 is displayed is increased. It can be expressed that it was relatively small. On the other hand, in the display system Sys1, the physical quantity image I2 is displayed on the display unit 25a in warm colors, so that the amount of power generated (physical quantity) of the second portable device 30 at the position where the physical quantity image I2 is displayed is relative. It can be expressed that it was great. Similarly, when the physical quantity represented by the physical quantity image I2 is a relatively small value, the processing unit 27 may cause the display unit 25a to display the transmittance of the physical quantity image I2 as a high value. On the other hand, when the physical quantity represented by the physical quantity image I2 is a relatively large value, the processing unit 27 may display the transmittance of the physical quantity image I2 as a low value on the display unit 25a.

<Overlapping display of physical quantity images>
In the overlay display process, the processing unit 27 can superimpose and distinguish a plurality of physical quantity images I2 for each predetermined unit time (see the physical quantity images I2A in FIGS. 4 and 7). Here, the predetermined unit time may be predetermined according to the sampling cycle of the physical quantity by the physical quantity detection unit 36a, or may be arbitrarily set by the user via the input unit 23 or the like. When displaying the plurality of physical quantity images I2 in an overlapping manner, the processing unit 27 distinguishes the plurality of physical quantity images I2 by changing the display color and the transmittance between the plurality of physical quantity images I2, for example, and displays the display unit 25a. It may be displayed in. In this case, for example, as illustrated in FIG. 7, the processing unit 27 causes the display unit 25a to display the latest physical quantity image I2 in a relatively dark color, and the physical quantity image I2 is displayed in a relatively light color as far back as the present time. May be displayed on the display unit 25a. Further, as illustrated in FIG. 7, the processing unit 27 displays a balloon in response to a selection operation (tap operation) via the input unit 23 or the like for a plurality of overlapping physical quantity images I2 in the overlapping display processing. The details of the physical quantity represented by the plurality of physical quantity images I2 may be displayed on the display unit 25a. Further, for example, in the overlay display processing, the processing unit 27 sequentially selects the physical quantities represented by the plurality of physical quantity images I2 in response to a selection operation (tap operation) for the overlapping physical quantity images I2 via the input unit 23 or the like. , May be displayed on the display unit 25a.

<Aggregation method of physical quantity>
For example, in the above-mentioned detection position specifying process (step S6), the processing unit 27 makes the method of totaling the physical quantities to be displayed in the subsequent overlapping display process (step S8) variable based on the moving speed of the mobile device 10. Can be done. As a result, the display system Sys1 can realize more appropriate physical quantity aggregation according to the situation. Here, the processing unit 27 uses, for example, the first aggregation method described below and the second aggregation method properly based on the movement speed of the mobile device 10, and each point (each identification of the above-mentioned movement route). It is possible to aggregate physical quantities at (corresponding to a location).

<First tabulation method>
The first counting method is a counting method based on the moving distance of the mobile device 10. In the first aggregation method, the processing unit 27 aggregates physical quantities according to the moving distance of the mobile device 10. In the first aggregation method, the processing unit 27 corresponds to, for example, a movement point (corresponding to each specific point of the above-mentioned movement route) for each predetermined movement distance (for example, 300 m) based on the position detected by the position detection unit 24a. ) Is specified. In other words, this process corresponds to dividing each specific point of the movement route by a predetermined distance (for example, 300 m). Then, the processing unit 27 aggregates and integrates the physical quantities (power generation amount) detected by the physical quantity detection unit 36a during the period of movement to each movement point, and sets this as the physical quantity at each movement point. For example, the processing unit 27 identifies that the user carrying the mobile device 10 has moved from the point A to the point B when the user moves to a position 300 m away from the point A. Then, while moving from the point A to the point B, the processing unit 27 aggregates and integrates the power generation amount (physical quantity) detected by the physical quantity detection unit 36a, and uses the integrated result as the power generation amount at the point A. Next, the processing unit 27 identifies that the user carrying the mobile device 10 has moved from the point B to the point C when the user moves to a position 300 m away from the point B. Then, while moving from the point B to the point C, the processing unit 27 aggregates and integrates the power generation amount (physical quantity) detected by the physical quantity detection unit 36a, and uses the integrated result as the power generation amount at the point B. The same applies hereinafter.

FIG. 8 shows an example of the first aggregation method when the sampling period of the physical quantity is 5 minutes, and here, it is represented as a point value of the power generation amount. For example, when the user carrying the mobile device 10 moves to the point B 300 m away from the point A between 10:00 and 10:15, the processing unit 27 moves from the point A to the point B at the time 10 :. The integrated value of the amount of power generation detected between 00 and 10:15 is calculated. Then, the processing unit 27 sets the integrated value = 15 of the power generation amount detected between 10:00 and 10:15 as the power generation amount at the point A. If the user moves from time 10:15 to point C, which is 300 m away from point B, before the next sampling cycle (10:20), the processing unit 27 generates electricity during the period when the user moves from point B to point C. Since there was no detection of, the amount of power generated at point B is set to 0. After that, when the user moves to the point D 300 m away from the point C before the time is 10:25, the processing unit 27 is before the time when the user moves from the point C to the point D at 10:25. Calculate the integrated value of the detected power generation amount. Then, the processing unit 27 sets the integrated value = 64 of the power generation amount detected before the time of 10:25 as the power generation amount of the power generation amount at the point C. As a result, the physical quantity image I2 displayed on the display unit 25a in the overlay display process has a magnitude relationship as illustrated in FIG. 9, for example. In this case, the physical quantity image I2 at the point C is displayed larger than the physical quantity image I2 at the point A, and the physical quantity image I2 is not displayed at the point B where the amount of power generation is 0.

<Second tabulation method>
The second aggregation method is an aggregation method based on the elapsed time. In the second aggregation method, the processing unit 27 aggregates physical quantities according to the elapsed time. In the second aggregation method, the processing unit 27 aggregates the physical quantity at predetermined elapsed time, for example. In this case, the processing unit 27 determines, for example, a point at which a predetermined elapsed time has elapsed based on the position detected by the position detection unit 24a, and a point at which physical quantities are aggregated (each identification of the above-mentioned movement route). Specify as (corresponding to the location). In other words, this process corresponds to dividing each specific part of the movement route by a predetermined elapsed time. Then, the processing unit 27 aggregates and integrates the physical quantities (power generation amount) detected by the physical quantity detection unit 36a within the predetermined elapsed time, and sets this as the physical quantity at each point.

<Example of proper use of aggregation method>
As an example of proper use of the aggregation method, the processing unit 27 aggregates physical quantities by the first aggregation method when the moving speed of the mobile device 10 is relatively slow, and the moving speed of the mobile device 10 is relatively slow. If it is fast, the physical quantity may be aggregated by the second aggregation method. That is, when the moving speed of the mobile device 10 is relatively slow, the processing unit 27 aggregates the physical quantities according to the moving distance of the mobile device 10, and when the moving speed of the mobile device 10 is relatively fast, the elapsed time. The physical quantity may be aggregated according to the above. In this case, the display system Sys1 applies the first aggregation method when the moving speed of the mobile device 10 is slow, so that, for example, when the user is staying at almost the same point, the aggregation point is at the same point. It is possible to prevent the identification and the aggregation of physical quantities from being continuously performed. On the other hand, the display system Sys1 applies the second aggregation method when the moving speed of the mobile device 10 is high, so that, for example, when the user is moving at high speed, the aggregation point is specified and the physical quantity is aggregated. Can be prevented from being continuously performed in a short time.

<Processing for forgetting to carry>
When the processing unit 27 detects that the first mobile device 20 and the second mobile device 30 have separated and moved relative to each other in the overlay display processing, the processing unit 27 can execute the forget-holding handling process. The forget-holding processing is a process of making the display of the physical quantity image I2 different from the display of the physical quantity image I2 during the period when the first mobile device 20 and the second mobile device 30 are separated and relatively moved. is there. In the display system Sys1, for example, when the user forgets to possess one of the first mobile device 20 or the second mobile device 30 and carries only the other, the physical quantity totaling point and the user's movement route are used. May not be consistent. In such a case, the processing unit 27 suppresses the display of the physical quantity image I2 without the consistency between the physical quantity totaling point and the user's movement route by performing the possession forgetting processing. can do.

In the processing unit 27, for example, the first mobile device 20 and the second mobile device 30 are separated based on various detection results by the detection unit 24 and various detection results by the detection unit 36 received from the second mobile device 30. It is possible to detect that the relative movement has occurred.

<Example of forgetting to carry the second mobile device 30>
For example, the processing unit 39 transmits the detected physical quantity information as well as other information detected by the detection unit 36 in the information transmission process (step S2) to the first mobile device 20, and the processing unit 27 is based on the received information. It is detected that the second portable device 30 is not attached to the user. For example, when the signal of the acceleration sensor constituting the detection unit 36 is not detected, the processing unit 27 can detect that the second portable device 30 is not attached to the user. Further, for example, when the detection unit 36 is further configured to include the tilt sensor, the processing unit 27 is said to be the first when the tilt sensor is ON (actuated) and the acceleration sensor is OFF (non-operated). 2 It is possible to detect that the portable device 30 is not worn by the user. Further, for example, when the detection unit 36 includes a temperature sensor, the processing unit 27 sets a temperature threshold in advance based on the temperature difference between when the second portable device 30 is attached and when it is not attached. However, when the actually detected temperature is equal to or lower than the temperature threshold value, it can be detected that the second portable device 30 is not attached to the user. Further, for example, when the detection unit 36 includes a heart rate sensor, the processing unit 27 detects that the second portable device 30 is not worn by the user when the heart rate is not measured. can do. The processing unit 27 can also detect that the second mobile device 30 is not attached to the user based on various activity meters mounted on the second mobile device 30 as the detection unit 36. Further, the processing unit 39 may make the same determination as described above on the second mobile device 30 side, and transmit information indicating the detection result of the presence / absence of wearing to the first mobile device 20.

The processing unit 27 detects that the second mobile device 30 is not attached to the user as described above, in other words, the user forgets to carry the second mobile device 30 and carries only the first mobile device 20. When it is detected that the mobile phone has moved, a display screen as shown in FIG. 10 may be displayed as a process for dealing with forgetting to carry. That is, in this case, as illustrated in FIG. 10, the processing unit 27 calculates the total physical quantity detected during the period when the first mobile device 20 and the second mobile device 30 are separated and relatively moved, with respect to the second mobile device. The physical quantity image I2 is displayed as a physical quantity detected at a place where the 30 is forgotten. In this case, the processing unit 27 further displays the physical quantity image I2 with respect to the physical quantity image I2 in the normal period in which the user carries both the first mobile device 20 and the second mobile device 30 and moves. Or the shape may be changed to display. Further, in this case, as a modification, the processing unit 27 may stop the overlay display process and display only the physical quantity image I2 without displaying the movement route image I1.

In addition, the processing unit 27 misplaces the second mobile device 30 at any point from the state in which the user carries and moves both the first mobile device 20 and the second mobile device 30, and the first mobile device 20 When it is detected that the user has moved by carrying only the mobile phone, for example, a display screen as shown in FIG. 11 may be displayed as a process for dealing with forgetting to carry. That is, in this case, as illustrated in FIG. 11, the processing unit 27 displays the physical quantity image I2 as usual during the normal period in which the user carries both the first mobile device 20 and the second mobile device 30 and moves. (See the physical quantity image I2B in FIG. 11). From that state, when the processing unit 27 detects that the user has moved by carrying only the first mobile device 20 and forgetting to hold the second mobile device 30, the first mobile device 20 and the second mobile device 30 move. The physical quantity image I2 is displayed as the total physical quantity detected during the period of separation and relative movement as the physical quantity detected at the place where the second mobile device 30 is forgotten (see the physical quantity image I2C in FIG. 11). .. In this case, the processing unit 27 displays the physical quantity image I2C on the physical quantity image I2B with different display colors and shapes. For example, in the case of the example shown in FIG. 12, the integrated value of the physical quantity detected in the period from 10:00 to 10:15 is displayed as the physical quantity image I2B, and is displayed in the period from 10:20 to 12:00. All the integrated values of the detected physical quantities are displayed as the physical quantity image I2C. As a result, the display system Sys1 can emphasize and display the point where the second portable device 30 is misplaced. Also in this case, as a modification, the processing unit 27 stops the overlay display process, does not display the moving route image I1, and displays only the physical quantity image I2 (physical quantity image I2B, physical quantity image I2C). You can also.

<Example of forgetting to carry the first mobile device 20>
The processing unit 27 can detect that the first mobile device 20 is not carried by the user, for example, based on the position detected by the position detection unit 24a constituting the detection unit 24. For example, the processing unit 27 forgets to hold the first mobile device 20 during the period during which it is detected that the first mobile device 20 does not move and the second mobile device 30 is attached to the user. 2 It is detected that it is a period during which the user has moved by carrying only the mobile device 30. When the processing unit 27 detects that it is a period in which the user has forgotten to carry the first mobile device 20 and carried only the second mobile device 30 and the user has moved, as a process for dealing with forgetting to carry, for example, as shown in FIG. The display screen may be displayed. That is, in this case, as illustrated in FIG. 13, the processing unit 27 calculates the total physical quantity detected during the period when the first mobile device 20 and the second mobile device 30 are separated and relatively moved. The physical quantity image I2 is displayed as a physical quantity detected at a place where the 20 is forgotten. In this case, the processing unit 27 moves the physical quantity image I2 with both the first mobile device 20 and the second mobile device 30 in the normal period, as in the case illustrated in FIG. The display color and shape of the image I2 may be changed to display the image I2. Further, in this case, as a modification, the processing unit 27 may stop the overlay display process and prevent the physical quantity image I2 itself from being displayed.

In addition, the processing unit 27 misplaces the first mobile device 20 at some point from the state in which the user carries and moves both the first mobile device 20 and the second mobile device 30, and the second mobile device 30. When it is detected that the user has moved by carrying only the mobile phone, for example, a display screen as shown in FIG. 14 may be displayed as a process for dealing with forgetting to carry. That is, in this case, as illustrated in FIG. 14, the processing unit 27 displays the physical quantity image I2 as usual during the normal period in which the user carries both the first mobile device 20 and the second mobile device 30 and moves. (See the physical quantity image I2D in FIG. 14). From that state, when the processing unit 27 detects that the user has moved by carrying only the second mobile device 30 and forgetting to hold the first mobile device 20, the first mobile device 20 and the second mobile device 30 move. The physical quantity image I2 is displayed as the total physical quantity detected during the period of separation and relative movement as the physical quantity detected at the place where the first portable device 20 is forgotten (see the physical quantity image I2E in FIG. 14). .. In this case, the processing unit 27 displays the physical quantity image I2E on the physical quantity image I2D with different display colors and shapes, as in the case illustrated in FIG. As a result, the display system Sys1 can emphasize and display the point where the first portable device 20 is misplaced. Also in this case, as a modification, the processing unit 27 stops the overlay display process, does not display the moving route image I1, and displays only the physical quantity image I2 (physical quantity image I2D, physical quantity image I2E). You can also.

<Action and effect of the embodiment>
The display system Sys1 and the program described above execute the overlay display process by the position detection unit 24a, the physical quantity detection unit 36a, the display unit 25a, and the processing unit 27 of the portable device 10 having the processing unit 27. be able to. As a result, the display system Sys1 and the program display the display unit 25a of the mobile device 10 with the moving route image I1 representing the moving route of the mobile device 10 and the physical quantity image I2 representing the physical quantity detected by the mobile device 10. It can be displayed in layers. Therefore, the display system Sys1 and the program can display the physical quantity detected by the mobile device 10 in an easy-to-understand manner in association with the activity of the user who carries the mobile device 10. Thereby, the display system Sys1 and the program can easily grasp the causal relationship between the detected physical quantity and the user's action range, for example. As a result, the display system Sys1, the program, the portable device 10, and the second portable device 30 as a wearable device can appropriately display the detected physical quantity.

More specifically, the display system Sys1 and the program described above correspond the physical quantity image I2 representing the physical quantity detected at the specific location of the movement route to the specific location of the movement route image I1 in the overlay display processing. It can be displayed overlaid on the position. Therefore, the display system Sys1, the program, the portable device 10, and the second portable device 30 as a wearable device can appropriately express the physical quantity detected at a specific location of the movement route by the physical quantity image I2, and can be specified. It is possible to make it easier to grasp the physical quantity at the location.

Further, the display system Sys1 and the program described above move the physical quantity image I2 representing the physical quantity detected by the physical quantity detection unit 36a of the second mobile device 30 on the display unit 25a of the first mobile device 20 as a moving route. It can be superimposed on the image I1 and displayed. As a result, the display system Sys1, the program, the mobile device 10, and the second mobile device 30 as a wearable device are detected by linking the first mobile device 20 and the second mobile device 30 constituting the mobile device 10. It is possible to properly display the physical quantity.

Here, the display system Sys1 and the program described above are wearable devices that can be worn on a human body by the second portable device 30 that detects a physical quantity among the mobile devices 10. Therefore, the display system Sys1, the program, the portable device 10, and the second portable device 30 as a wearable device can be attached to the user and can appropriately display the physical quantity detected in a situation closer to the user.

As an example, the display system Sys1 and the program described above display a physical quantity image I2 representing the power generation amount of the electric power generated by the second portable device 30 which is an electronic clock as the physical quantity detected by the physical quantity detection unit 36a. , The moving route image I1 can be superimposed and displayed. Thereby, the display system Sys1 and the program can easily grasp the causal relationship between the amount of power generated by the second mobile device 30 and the user's action range, for example. As a result, the display system Sys1, the program, the mobile device 10, and the second mobile device 30 as a wearable device make it easier for the user to, for example, know where in the travel route the amount of power generation is large. be able to. As a result, the display system Sys1, the program, the mobile device 10, and the second mobile device 30 as a wearable device can select, for example, a movement route that is conscious of a place where power generation is easy for the user and a place where the staying time is long. It is possible to encourage users to devise efficient power generation in Japan, and to make users aware of power generation and actively generate power.

Further, the display system Sys1 and the program described above can change the size of the physical quantity image I2 according to the physical quantity represented by the physical quantity image I2 in the overlay display processing. In this case, the display system Sys1, the program, the portable device 10, and the second portable device 30 as a wearable device can recognize the magnitude of the physical quantity (power generation amount) depending on the magnitude of the physical quantity image I2.

Further, in this case, in the display system Sys1 and the program described above, when the physical quantity represented by the physical quantity image I2 is a small value in the overlay display processing, the difference in the size of the physical quantity image I2 with respect to the difference in the value of the physical quantity. Is relatively large, and when the value is large, the difference in size of the physical quantity image I2 with respect to the difference in the value of the physical quantity can be relatively small. As a result, the display system Sys1, the program, the portable device 10, and the second portable device 30 as a wearable device effectively represent the magnitude difference of the physical quantity represented by the physical quantity image I2 by the size of the physical quantity image I2. Can be done. That is, the display system Sys1 can easily recognize the difference in the physical quantity even if the difference is small at the stage where the physical quantity represented by the physical quantity image I2 is relatively small. On the other hand, the display system Sys1 can recognize the difference in the physical quantity only when a large difference occurs at the stage where the physical quantity represented by the physical quantity image I2 is relatively large.

Further, in the overlay display processing, the display system Sys1 and the program described above can change the display color or the transmittance of the physical quantity image I2 according to the physical quantity represented by the physical quantity image I2. In this case, the display system Sys1, the program, the portable device 10, and the second portable device 30 as a wearable device can recognize the magnitude of the physical quantity (power generation amount) by the display color of the physical quantity image I2 or the transmittance. it can.

Further, in the display system Sys1 and the program described above, in the overlay display processing, the maximum size and the minimum size of the physical quantity image I2 are set to a predetermined ratio based on the size of the display area 25at of the display unit 25a. Can be restricted within. As a result, the display system Sys1, the program, the portable device 10, and the second portable device 30 as a wearable device can ensure proper visibility in the display on the display unit 25a by the overlay display process. That is, the display system Sys1 and the program can, for example, set the maximum size of the physical quantity image I2 to a size that fits within the display area 25at so that the physical quantity image I2 is not cut off. Further, the display system Sys1 and the program can, for example, make the minimum size of the physical quantity image I2 easily visible to the user.

Further, the display system Sys1 and the program described above can display a plurality of physical quantity images I2 for each predetermined unit time in a superimposed manner and separately in the superimposed display process. As a result, the display system Sys1, the program, the portable device 10, and the second portable device 30 as a wearable device can realize more diverse displays with respect to the detected physical quantity.

Further, the display system Sys1 and the program described above can sequentially display the physical quantities represented by the plurality of physical quantity image 2 images in response to the operation on the plurality of physical quantity images I2 that are adjacent to each other in the superimposed display process. .. In this respect as well, the display system Sys1, the program, the portable device 10, and the second portable device 30 as a wearable device can realize more diverse displays with respect to the detected physical quantity.

Further, the display system Sys1 and the program described above can make the method of totaling the physical quantities to be displayed by the overlay display process variable based on the moving speed of the mobile device 10. As a result, the display system Sys1, the program, the portable device 10, and the second portable device 30 as a wearable device can realize more appropriate physical quantity aggregation according to the situation, and the movement pattern of the user with respect to the detected physical quantity. It is possible to realize a more appropriate display according to the above.

For example, the display system Sys1 and the program described above aggregate physical quantities according to the moving distance of the mobile device 10 when the moving speed of the mobile device 10 is relatively slow, and the moving speed of the mobile device 10 is increased. If it is relatively fast, the physical quantity is aggregated according to the elapsed time. In this case, the display system Sys1 and the program can prevent the identification of the aggregation point and the aggregation of physical quantities from being unnecessarily continuously performed. As a result, the display system Sys1, the program, the portable device 10, and the second portable device 30 as a wearable device can suppress, for example, the display of too many physical quantity images I2 from deteriorating visibility. In addition, the amount of calculation can be suppressed and the power consumption can be suppressed.

Further, when the display system Sys1 and the program described above detect that the first mobile device 20 and the second mobile device 30 have separated and moved relative to each other in the superimposed display process, the physical quantity image during the period is detected. Performs a forget-me-not handling process that makes the display of the physical quantity image different from the display of the physical quantity image outside the relevant period. As a result, the display system Sys1, the program, the mobile device 10, and the second mobile device 30 as a wearable device forget to possess one of the first mobile device 20 or the second mobile device 30 and carry only the other. When the user moves, it is possible to suppress the display of the physical quantity image I2 without the consistency between the aggregation point of the physical quantity and the movement route of the user. Further, in this case, the display system Sys1, the program, the mobile device 10, and the second mobile device 30 as a wearable device emphasize and display, for example, the points where the first mobile device 20 and the second mobile device 30 are misplaced. Therefore, it is possible to make it easier for the user to confirm the position where the first mobile device 20 and the second mobile device 30 are misplaced.

Further, in the display system Sys1, the program, the mobile device 10, and the second mobile device 30 as the wearable device described above, the first mobile device 20, the second mobile device 30, and the server 40 communicate with each other. By linking, it is possible to configure a linking system that realizes the above-mentioned easy-to-understand display.

The display system, program, portable device, and wearable device according to the above-described embodiment of the present invention are not limited to the above-described embodiment, and various changes can be made within the scope of the claims. is there. The display system, the program, the portable device, and the wearable device according to the present embodiment may be configured by appropriately combining the components of the embodiments and modifications described above.

In the above description, the first mobile device 20 is a smartphone, and the second mobile device 30 is an electronic watch (wristband type wearable device), but the present invention is not limited to this. The first mobile device 20 and the second mobile device 30 may be any electronic device that can be carried by the user.

In the above description, as an example, the display system Sys1 has been described as having a first mobile device 20 and a second mobile device 30 as a plurality of mobile devices 10, but the present invention is not limited to this. Further, in the above description, it has been described that the server 40 is further provided in addition to the portable device 10, but the present invention is not limited to this. In the display system Sys1, for example, each process including the superimposed display process may be completed by one mobile device. In this case, in the mobile device, the position detection unit, the physical quantity detection unit, the display unit, and the processing unit that executes the overlay display process are all provided in one mobile device. Further, the display system Sys1 may be configured to include three or more mobile devices as the mobile device 10.

In the above description, the physical quantity detected by the mobile device 10 and displayed in the overlay display process is assumed to be the power generation amount of the electric power generated by the second mobile device 30, but is not limited to this. The physical quantity may be, for example, the temperature detected by the physical quantity detection unit, the amount of ultraviolet rays, or the like, or may be another detected amount. Further, the physical quantity may be, for example, a calorie consumption basal metabolic rate based on the physical quantity detected by the physical quantity detection unit. In this case, for example, the first mobile device 20 or the second mobile device 30 stores user information (height, weight, etc.) in advance, and the physical quantity such as acceleration detected by the physical quantity detection unit and the user information. The calorie consumption and the basal metabolic rate may be calculated based on the above. Further, in the overlay display process, the portable device 10 may display a plurality of types of physical quantity images representing a plurality of types of physical quantities in an superimposed manner.

In the portable device 10 described above, in addition to the display by the above-mentioned overlay display processing, a time-series physical quantity (power generation amount) may be displayed on another display screen in time units or days.

In the above description, the processing unit 27 has been described as, for example, making the method of totaling the physical quantities to be displayed by the overlay display process variable based on the moving speed of the mobile device 10, but the present invention is not limited to this. The method for aggregating physical quantities may be a single method regardless of the situation.

In the above description, when the processing unit 27 detects that the first mobile device 20 and the second mobile device 30 have separated and moved relative to each other, the processing unit 27 has been described as executing the forget-holding handling process, but the present invention is limited to this. Absent.

In the above description, the mobile device 10 and the server 40 have been described as being configured as a single device, but the present invention is not limited to this. The form of functional distribution of the mobile device 10 and the server 40 is not limited to the above, and can be functionally or physically distributed / integrated in any unit within the range in which the same effects and functions can be obtained. Further, the programs, various data, etc. described above may be updated as appropriate, or may be stored in another server connected to the mobile device 10 and the server 40 via an arbitrary network N. Good. The programs, various data, etc. described above are recorded on a computer-readable recording medium such as a hard disk, flexible disk (FD), CD-ROM, MO, or DVD, and executed by being read from the recording medium by the computer. You can also do it. Further, for example, with respect to each processing function provided in the processing units 27, 39 and the server 40, all or any part thereof may be realized by, for example, a CPU or a program interpreted and executed by the CPU or the like. It may be realized as hardware by wired logic or the like.

<Modification example of aggregation method>
In the above description, the processing unit 27 uses the first totaling method based on the moving distance of the mobile device 10, the second totaling method based on the elapsed time, or the moving speed of the mobile device 10 as the totaling method of the physical quantity. The method of using these properly has been described as an example, but the present invention is not limited to this. The processing unit 27, for example, aggregates physical quantities at each point (corresponding to each specific point of the above-mentioned movement route) on the condition that both the moving distance and the elapsed time of the mobile device 10 satisfy a predetermined threshold value. May be done.

Specifically, the processing unit 27, for example, has an elapsed time since the movement distance of the mobile device 10 from the previously specified specific location exceeds a preset determination distance and the previous specific location is specified. The specific location of this time is specified on condition that the preset judgment period has been exceeded. Here, the determination distance is a threshold value preset with respect to the moving distance of the portable device 10 from the specific location specified last time, and may be arbitrarily set. Similarly, the determination period is a threshold value preset with respect to the elapsed time since the last specific location was specified, and may be arbitrarily set. That is, the processing unit 27 specifies a moving point (corresponding to each specific point of the above-mentioned moving route) every time both the moving distance and the elapsed time of the mobile device 10 satisfy the above conditions. Then, the processing unit 27 sets the integrated value of the physical quantities detected by the physical quantity detection unit 36a from the specific location specified last time to the specific location specified this time as the physical quantity at the specific location specified this time.

Conversely, when the moving distance of the mobile device 10 from the previously specified specific location does not exceed the preset determination distance, or the elapsed time since the last specific location was specified, the processing unit 27 If does not exceed the preset judgment period, the integration is continued without specifying the specific location this time, and the aggregation is not performed at the next specific location. That is, even if the moving distance of the mobile device 10 from the previously specified specific location exceeds the preset determination distance, the processing unit 27 presets the elapsed time since the last specific location was specified. If the judgment period to be determined is not exceeded, the accumulation will be continued without specifying the specific location this time, and the next aggregation will not be performed. Similarly, in the processing unit 27, even if the elapsed time from the previous identification of the specific location exceeds the preset determination period, the moving distance of the portable device 10 from the previously specified specific location is in advance. If the set judgment distance is not exceeded, the integration is continued without specifying the specific location this time, and the next aggregation is not performed.

An example of a method of totaling physical quantities according to a modified example will be described with reference to FIGS. 15 and 16. 15 and 16 show an example in which the preset determination distance is set to 300 m and the preset determination period is set to 5 minutes as the sampling cycle. In addition, in FIG. 15 and FIG. 16, the physical quantity detected at each point is schematically represented by a circular motif.

In the example of FIG. 15, the processing unit 27 moves the distance of the user carrying the mobile device 10 even after the elapsed time of 5 minutes (determination period) has elapsed since the point A, which is the previous specific location, is specified. Until the condition is satisfied, the specific points of this time are not specified, and the physical quantities detected at the point b1 30 m away from the point A, the point b2 50 m away from the point b1 and the like are integrated. Then, the processing unit 27 identifies the specific location this time when the user carrying the mobile device 10 moves beyond the point B 300 m (determined distance) away from the point A, and integrates the physical quantities at the next specific location. Move to. In this case, as described above, the processing unit 27 integrates the physical quantities detected at the points b1, b2, and the like, and totals them as if they were the physical quantities at the point B, which is the specific location this time.

On the other hand, in the example of FIG. 16, the processing unit 27 has an elapsed time even if the user carrying the mobile device 10 moves beyond the point b1 300 m (determined distance) away from the previous specific point A. Until the condition is satisfied, the physical quantity detected at the point b1 or the like is integrated without specifying the specific place this time. Then, the processing unit 27 identifies the specific point this time at the point B where the elapsed time from specifying the point A, which is the previous specific point, elapses 5 minutes (determination period), and the physical quantity at the next specific point. Shift to the integration of. In this case, as described above, the processing unit 27 integrates the physical quantities detected at the point b1 and the like, and totals the physical quantities as if they were the physical quantities at the point B, which is the specific location this time.

By aggregating the physical quantities as described above, the display system Sys1 works at a company, for example, when the moving speed of the mobile device 10 is slower than that of specifying a specific location only on the condition of elapsed time. When the user's action range per unit time is relatively narrow, such as when the user is doing so, it is possible to prevent the specific location from being repeatedly specified at substantially the same location. On the other hand, in the display system Sys1, for example, when the moving speed of the mobile device 10 is faster than in the case of specifying a specific location only on the condition of the moving distance, for example, the user is moving at high speed along a train or the like. In this case, it is possible to prevent the part where the physical quantity cannot be detected from being unnecessarily specified as a specific part. As a result, the display system Sys1, the program, and the portable device 10 can suppress unnecessary identification of specific locations, unnecessary calculations, and the like, and can suppress unnecessary power consumption. On top of that, the display system Sys1, the program, and the mobile device 10 can realize a more appropriate physical quantity aggregation according to the situation, and realize a more appropriate display of the detected physical quantity according to the movement pattern of the user. be able to.

<Merge display of physical quantity images>
The processing unit 27 described above can merge physical quantities detected at a plurality of specific locations and display them as one physical quantity image I2. Specifically, in the overlay display process, the processing unit 27 merges the physical quantities detected by the physical quantity detection unit 36a at a plurality of specific locations within the merged display range determined according to the merged display reference distance set in advance. It can be displayed on the display unit 25a as one physical quantity image I2. Here, the merged display range defines a range in which physical quantities detected at a plurality of specific locations are merged and displayed as one physical quantity image I2, and is determined according to the merged display reference distance. The merged display reference distance is a distance arbitrarily set in advance, and is set according to a range in which the detected physical quantities are merged and displayed as one physical quantity image I2.

<Variation 1 of merged display>
An example of the merged display of the physical quantity image I2 will be described with reference to FIG. FIG. 17 shows an example in which the preset merged display reference distance THD is set to 900 m. In the example shown in FIG. 17, the processing unit 27 determines the merged display range based on the reference position that is sequentially updated according to the position of the specified specific location. Note that FIG. 17 shows the actual movement locus between specific locations specified with the movement of the user carrying the mobile device 10 with a dotted line, while the virtual movement locus passing through the reference position is shown with a solid line. ing.

First, for example, as shown in FIG. 17, the processing unit 27 has a first specific location P1 as a starting point within the first merged display range R1 and a second specific location following the first specific location P1. The intermediate position with P2 is set as the initial reference position C1. Then, when the third specific location P3 following the second specific location P2 is set as the specific location this time, the processing unit 27 determines that the distance between the reference position C1 and the specific location P3 this time is equal to or greater than the merged display reference distance THD. Performs a determination process to determine whether or not they are separated.

When the processing unit 27 determines by the determination process that the distance between the reference position C1 and the specific location P3 this time is not more than the merged display reference distance THD, the specific location P3 this time is set as the specific location within the merged display range R1. After that, the intermediate position between the reference position C1 and the specific location P3 this time is updated as the reference position C2 in the next determination process, and the determination process is repeated. In the example of FIG. 17, the processing unit 27 uses the reference position as a reference as the specific location moves from the third specific location P3 to the specific location P4, the specific location P5, the specific location P6, and the specific location P7. The determination process is repeated by updating to the position C3, the reference position C4, the reference position C5, and the reference position C6.

Then, when the processing unit 27 determines by the determination process that the distance between the reference position C6 and the specific location P8 following the specific location P7 is at least the merged display reference distance THD, the specific location P8 is next. This is the first specific location that is the starting point within the merged display range R2.

That is, in the example of FIG. 17, the processing unit 27 processes the specific locations P1 to P7 as specific locations within the first merged display range R1, and separates the specific locations P8 from the merged display range R1 for the second merge. It is processed as a specific part in the display range R2.

Then, in the overlay display process, the processing unit 27 merges (merges) the physical quantities detected by the physical quantity detection units 36a at the plurality of specific locations P1 to P7 in the merged display range R1 specified as described above. The physical quantity image I2 is superimposed on the moving route image I1 and displayed on the display unit 25a (see FIG. 4 and the like). In this case, the processing unit 27 integrates the physical quantities detected at a plurality of specific locations P1 to P7 in the merged display range R1, and causes the display unit 25a to display one physical quantity image I2 corresponding to the integrated physical quantity.

Further, in this case, for example, in the moving route image I1, the processing unit 27 is a position corresponding to the last reference position C6 in the merged display range R1, or a plurality of specific points P1 to P7 in the merged display range R1. The physical quantity image I2 is superimposed on the position corresponding to the centroid position PC and displayed on the display unit 25a. Here, the centroid position PCs of the plurality of specific points P1 to P7 in the merged display range R1 typically visualize the movement loci between all the specific points P1 to P7 in the merged display range R1. Corresponds to the position of the center of gravity (center of gravity position) of the case.

The display system Sys1, the program, and the portable device 10 combine the physical quantities of a plurality of specific locations as described above and display them as one physical quantity image I2, so that the display on the display unit 25a by the overlay display process can be performed. Appropriate visibility can be ensured.

In this case, the display system Sys1 determines the merged display range based on the reference position that is sequentially updated according to the position of the specified specific location, so that the amount of data stored and the calculation required for determining the merged display range are calculated. The amount can be suppressed. As a result, the display system Sys1, the program, and the portable device 10 can suppress power consumption.

Further, the display system Sys1 sets the moving route image I1 at a position corresponding to the last reference position in the merged display range or a position corresponding to the centroid position of a plurality of specific points in the merged display range. By displaying the merged physical quantity images I2 in an overlapping manner, it is possible to realize an appropriate display according to the movement pattern of the user while ensuring an appropriate visibility as described above.

<Variation 2 of merged display>
Another example of the merged display of the physical quantity image I2 will be described with reference to FIG. Similar to FIG. 17, FIG. 18 also shows an example in which the preset merged display reference distance THD is set to 900 m. In the example shown in FIG. 18, the processing unit 27 determines the merged display range based on a specific location that is the starting point within the merged display range without using the reference position. Note that FIG. 18 is a solid line showing an actual movement locus between specific locations specified as the user carrying the mobile device 10 moves.

In this case, the processing unit 27 performs a determination process for determining whether or not the distance between the specific location that is the starting point in the first merged display range R1 and the specific location this time is separated by the merged display reference distance THD or more. Then, when the processing unit 27 determines by the determination process that the distance between the specific location as the starting point and the specific location this time is not more than the merged display reference distance THD, the specific location this time is set to the first merged display range. After making it a specific location in R1, the next determination process for the specific location is repeated. On the other hand, when the processing unit 27 determines by the determination process that the distance between the specific location as the starting point and the specific location this time is more than the merged display reference distance THD, the specific location of this time is set to the next merged display range. It is a specific location that is the starting point in R2.

For example, in the example of FIG. 18, the processing unit 27 has a first specific location P1 as a starting point in the first merged display range R1 and a second specific location P2 following the first specific location P1. Judgment processing for determining whether or not the distance is separated by the merged display reference distance THD or more is performed.

When the processing unit 27 determines by the determination process that the distance between the specific location P1 as the starting point and the specific location P2 this time is not more than the merged display reference distance THD, the specific location P2 this time is within the merged display range R1. After setting the specific location of the above, the determination process after the specific location P3 specified next is repeated. In the example of FIG. 18, the processing unit 27 has a specific location P4, a specific location P5, a specific location P6, a specific location P7, a specific location P8, a specific location P9, and a specific location P10, following the third specific location P3. , The determination process is repeated as it moves to the specific location P11 and the specific location P12.

Then, when the processing unit 27 determines by the determination process that the distance between the specific location P1 as the starting point and the specific location P13 following the specific location P12 is the merged display reference distance THD or more, the current identification The location P13 is set as the first specific location that serves as the starting point within the next merged display range R2.

That is, in the example of FIG. 18, the processing unit 27 processes the specific locations P1 to P12 as specific locations within the first merged display range R1, and separates the specific locations P13 from the merged display range R1 for the second merge. It is processed as a specific part in the display range R2.

Then, in the overlay display process, the processing unit 27 merges (merges) the physical quantities detected by the physical quantity detection units 36a at the plurality of specific locations P1 to P12 in the merged display range R1 specified as described above. The physical quantity image I2 is superimposed on the moving route image I1 and displayed on the display unit 25a (see FIG. 4 and the like). In this case, the processing unit 27 integrates the physical quantities detected at the plurality of specific locations P1 to P12 in the merged display range R1, and causes the display unit 25a to display one physical quantity image I2 corresponding to the integrated physical quantity.

Further, in this case, the processing unit 27 may, for example, in the moving route image I1, a position corresponding to the last specific location P12 in the merged display range R1, or a plurality of specific locations P1 to P12 in the merged display range R1. The physical quantity image I2 is superimposed on the position corresponding to the centroid position PC and displayed on the display unit 25a.

Even in this case, the display system Sys1, the program, and the portable device 10 merge the physical quantities of a plurality of specific locations and display them as one physical quantity image I2 as described above, so that the display is performed by overlay processing. Appropriate visibility can be ensured in the display on the part 25a.

<Merge display according to display magnification>
In the overlapping display processing, the processing unit 27 may change the size of the merged display reference distance and the merged display range determined accordingly according to the display magnification of the display area 25at of the display unit 25a. For example, the processing unit 27 sets the merged display reference distance relatively short as the display magnification of the display area 25at of the display unit 25a is relatively high (that is, the larger the display is), and sets the merged display range relative to each other. Make it smaller. On the other hand, the processing unit 27 sets the merged display reference distance relatively longer as the display magnification of the display area 25at of the display unit 25a is relatively lower (that is, the reduced display is used), and the merged display range is set. Is relatively large. As a result, the display system Sys1, the program, and the portable device 10 can ensure more appropriate visibility according to the display magnification in the display on the display unit 25a by the overlay display process.

<Variation example of physical quantity image variation: Display of physical quantity detected by multiple mobile devices>
In the overlay display process described above, the physical quantity image I2 has been described as being able to be displayed on the display unit 25a in various display modes, but the above-mentioned <variation 1; variable size> and <variation 2; variable color parameter have been described. > Etc. are not limited. In the overlay processing, the processing unit 27 performs physical quantities according to a plurality of different second mobile devices 30 for which a physical quantity is detected, for example, when one user owns a plurality of second mobile devices 30. The display mode of the image I2 can also be changed.

For example, in the overlay display process, the processing unit 27 can change the display mode of the physical quantity image I2 according to the second portable device 30 that has detected the physical quantity, as shown in FIG. In this case, the processing unit 27 distinguishes and displays the color, hatch, and the like of the physical quantity image I2 for each of the plurality of different second portable devices 30. In the example shown in FIG. 19, the processing unit 27 displays, for example, the physical quantity detected by the first second mobile device 30 by the physical quantity image I2F, while the physical quantity detected by the second second mobile device 30 is a physical quantity. It is displayed by a physical quantity image I2G different from the image I2F. As a result, when one user owns a plurality of second mobile devices 30, the display system Sys1 changes the display mode of the physical quantity image I2 for each of the plurality of second mobile devices 30 and displays the physical quantity image I2. Therefore, the physical quantities detected by each of the second portable devices 30 can be represented separately.

<Selective display in overlay processing>
Further, the processing unit 27 can arbitrarily select the physical quantity image I2 to be displayed on the display unit 25a in the overlay display processing.

For example, in the overlay display process, the processing unit 27 selects a day when the activity amount of the user carrying the mobile device 10 is high, and displays the physical quantity detected on the day when the activity amount is high as the physical quantity image I2. Can be displayed in. In this case, for example, the processing unit 27 sets the day when the amount of activity detected by various activity meters mounted as the detection unit 36 in the second mobile device 30 exceeds a preset threshold value as “a day with a large amount of activity”. Is extracted as. Then, the processing unit 27 lists the extracted “days with a large amount of activity” and displays them on the display unit 25a as a selection screen. Then, the processing unit 27 causes the user to arbitrarily select a desired "day with a large amount of activity" in accordance with the user's selection operation on the touch panel 23a on the selection screen, and the selected "activity amount is determined". The physical quantity detected on "many days" is displayed on the display unit 25a as a physical quantity image I2.

Further, in the overlay processing, the processing unit 27 switches, for example, the physical quantity detected on the same day arbitrarily selected by the user (for example, the physical quantity detected on January 1) for each year and the physical quantity. It can also be displayed on the display unit 25a as the image I2.

As described above, in the display system Sys1, the program, and the portable device 10, in the overlay display process, the physical quantity arbitrarily selected by the user is selectively displayed on the display unit 25a as the physical quantity image I2, so that the user can be more user-oriented. It is possible to make the display easy to understand according to the needs of.

<Sharing of detected physical quantity information>
The display system Sys1 described above can also be transmitted from the first mobile device 20 to the server 40, and the detected physical quantity information stored and stored in the server 40 can be shared with other users. In this case, the display system Sys1 can be shared by the user who presents the detected physical quantity information via the touch panel 23a of the first mobile device 20, for example, the target user, the target period, the target area, the target physical quantity, and the like. Set the filter information that specifies. Then, the display system Sys1 limits the detected physical quantity information shared with the first mobile device 20 or the like of another user based on the set filter information, and displays the physical quantity image I2 within the limited content. It can be displayed on 25a or the like. As a result, the display system Sys1, the program, and the portable device 10 can more effectively utilize the detected physical quantity.

<Variable regular communication interval>
In the display system Sys1 described above, the interval of periodic mutual communication between the first mobile device 20 and the second mobile device 30 can be made variable depending on the situation.

For example, since the storage capacity of the storage unit 38 tends to be relatively small in the second mobile device 30, the detected physical quantity information and the like are continuously stored in the storage unit 38 as they are without communicating with the first mobile device 20. If this is the case, the storage capacity of the storage unit 38 may be insufficient at a relatively early stage. In this case, the second mobile device 30 communicates with the first mobile device 20, transmits data such as detected physical quantity information to the first mobile device 20, and deletes the transmitted data from the storage unit 38. In the storage unit 38, the storage capacity for the transmitted data can be opened.

In addition, the second mobile device 30 is used for automatic mutual communication with the first mobile device 20 (for example, automatic advertisement accompanied by time adjustment), which is performed regularly in one day, between the first mobile device 20 and the second mobile device. If the 30 is not in a communicable positional relationship, the automatic communication is not performed, and as a result, the data is not completely swept to the first mobile device 20 side, and the storage capacity of the storage unit 38 may be sufficiently increased. It may not be possible.

Therefore, when the storage amount of the storage unit 38 exceeds a preset predetermined amount, the second mobile device 30 increases the number of trials of periodic automatic mutual communication with the first mobile device 20 in one day. You may. For example, in a normal state where the storage amount of the storage unit 38 is less than a preset predetermined amount, the second portable device 30 is periodically automatically reciprocated with the first portable device 20 once a day at 3:00 am. In the case of the specification for trying communication, when the storage amount of the storage unit 38 exceeds a preset predetermined amount and the capacity is insufficient, the number of times is increased (for example, 3 o'clock, 6 o'clock, 9 o'clock, 12 o'clock, 15 o'clock). 8 times, such as hour, 18:00, 21:00, 24:00).

As a result, when the storage capacity of the storage unit 38 becomes relatively small, the second mobile device 30 actively seeks automatic mutual communication with the first mobile device 20 and sweeps data to the first mobile device 20 side. be able to. As a result, the display system Sys1, the program, the mobile device 10, and the second mobile device 30 as a wearable device suppress that the detected physical quantity information once acquired by the second mobile device 30 is overwritten. It is possible to make the best use of the detected physical quantity.

3 Guideline 10 Portable device 20 First portable device 21, 31 Power supply unit 21a, 31a Secondary battery 22, 32 Communication unit 23 Input unit 23a Touch panel 23b Voice input device 24, 36 Detection unit 24a Position detection unit 25, 37 Output unit 25a Display 25at Display area 26, 38 Storage 27, 39 Processing unit 30 Second mobile device 31b Power generation unit 33 Timing unit 34 Drive unit 34a Motor 35 Operation unit 35a Crown 35b Push button 36a Physical quantity detection unit 40 Servers C1 to C6 Reference position I1 Travel route image I2, I2A, I2B, I2C, I2D, I2E, I2F, I2G Physical quantity image P1 to P13 Specific location PC Center position R1, R2 Merged display range Sys1 Display system THD Merged display reference distance

Claims (20)

A mobile device including a position detecting unit for detecting a position, a physical quantity detecting unit for detecting a physical quantity, a display unit for displaying an image, and a processing unit capable of executing a process of controlling the display unit and displaying an image.
Wherein the processing unit,
The physical quantity image representing the physical quantity detected by the physical quantity detecting unit is superimposed on the moving route image representing the moving route of the mobile device determined according to the position detected by the position detecting unit by controlling the display unit. Ri executable der lap display processing for,
In the overlay display process, the size of the physical quantity image is made variable according to the physical quantity represented by the physical quantity image, and when the physical quantity represented by the physical quantity image is a relatively small value, the physical quantity with respect to the difference between the values of the physical quantity When the difference in the size of the image is relatively large and the physical quantity represented by the physical quantity image is a relatively large value, the difference in the size of the physical quantity image with respect to the difference in the value of the physical quantity is relatively small. Characterized by,
Display system. A mobile device including a position detecting unit for detecting a position, a physical quantity detecting unit for detecting a physical quantity, a display unit for displaying an image, and a processing unit capable of executing a process of controlling the display unit and displaying an image.
The processing unit
The physical quantity image representing the physical quantity detected by the physical quantity detecting unit is superimposed on the moving route image representing the moving route of the mobile device determined according to the position detected by the position detecting unit by controlling the display unit. It is possible to execute the overlay processing to make it
In the superimposed display process, a plurality of the physical quantity images for each predetermined unit time can be superimposed and displayed separately, and the plurality of the physical quantity images are represented according to operations on the plurality of overlapping physical quantity images. The feature is that physical quantities are displayed in sequence.
Viewing system. A mobile device including a position detecting unit for detecting a position, a physical quantity detecting unit for detecting a physical quantity, a display unit for displaying an image, and a processing unit capable of executing a process of controlling the display unit and displaying an image.
The processing unit
The physical quantity image representing the physical quantity detected by the physical quantity detecting unit is superimposed on the moving route image representing the moving route of the mobile device determined according to the position detected by the position detecting unit by controlling the display unit. It is possible to execute the overlay processing to make it
It is characterized in that the method of totaling the physical quantity to be displayed by the overlay display process is variable based on the moving speed of the portable device.
Viewing system. When the moving speed of the portable device is relatively slow, the processing unit aggregates the physical quantity according to the moving distance of the portable device, and when the moving speed of the portable device is relatively fast, the elapsed time is calculated. The physical quantities are aggregated accordingly.
The display system according to claim 3. A mobile device including a position detecting unit for detecting a position, a physical quantity detecting unit for detecting a physical quantity, a display unit for displaying an image, and a processing unit capable of executing a process of controlling the display unit and displaying an image.
The processing unit controls the display unit, and the physical quantity representing the physical quantity detected by the physical quantity detecting unit is displayed on the moving route image representing the moving route of the portable device determined according to the position detected by the position detecting unit. It is possible to execute a overlay display process that overlays images and displays them.
The mobile device includes a first mobile device and a second mobile device capable of communicating with each other.
The second portable device has the physical quantity detecting unit, and transmits detected physical quantity information regarding the physical quantity detected by the physical quantity detecting unit to the first portable device.
The first portable device has the position detection unit, the display unit, and the processing unit, and the detection position information regarding the position detected by the processing unit by the position detection unit, and the second portable device. Based on the detected physical quantity information received from, the display unit is controlled, and the superimposed display process is executed.
When the processing unit detects that the first mobile device and the second mobile device have separated and moved relative to each other in the superimposed display process, the processing unit displays the physical quantity image during the separated and relative movement period. Is executed, which is different from the display of the physical quantity image outside the relevant period.
Viewing system. A mobile device including a position detecting unit for detecting a position, a physical quantity detecting unit for detecting a physical quantity, a display unit for displaying an image, and a processing unit capable of executing a process of controlling the display unit and displaying an image.
The processing unit
The physical quantity image representing the physical quantity detected by the physical quantity detecting unit is superimposed on the moving route image representing the moving route of the mobile device determined according to the position detected by the position detecting unit by controlling the display unit. It is possible to execute the overlay processing to make it
A determination period in which the travel distance of the mobile device from the specific location of the previously specified travel route exceeds the preset determination distance and the elapsed time since the previous identification of the specific location is preset. The specific location this time was specified on the condition that it exceeded, and the integrated value of the physical quantity detected by the physical quantity detection unit from the specific location specified last time to the specific location specified this time was specified this time. It is characterized in that it is the physical quantity at the specific location.
Viewing system. A mobile device including a position detecting unit for detecting a position, a physical quantity detecting unit for detecting a physical quantity, a display unit for displaying an image, and a processing unit capable of executing a process of controlling the display unit and displaying an image.
The processing unit
The physical quantity image representing the physical quantity detected by the physical quantity detecting unit is superimposed on the moving route image representing the moving route of the mobile device determined according to the position detected by the position detecting unit by controlling the display unit. It is possible to execute the overlay processing to make it
In the superimposed display process, the physical quantities detected by the physical quantity detection unit are merged at a plurality of specific points of the moving route within the merged display range determined according to the merged display reference distance set in advance, and one physical quantity is obtained. Display as an image
The intermediate position between the first specific location, which is the starting point within the merged display range, and the second specific location following the first specific location is set as the initial reference position, and the reference position and the current specification are specified. Judgment processing is performed to determine whether or not the distance to the location is greater than or equal to the merged display reference distance.
When it is determined by the determination process that the distance between the reference position and the specific location this time is not more than the merged display reference distance, the specific location this time is set as the specific location within the merged display range. , The intermediate position between the reference position and the specific location this time is updated as the reference position in the next determination process, and the determination process is repeated.
When it is determined by the determination process that the distance between the reference position and the specific location this time is equal to or greater than the merged display reference distance, the first specific location becomes the starting point within the next merged display range. It is characterized by being a specific part of
Viewing system. In the overlay display process, the processing unit displays the one physical quantity image obtained by merging the physical quantities detected by the physical quantity detection unit at the plurality of specific locations within the merged display range in the moving route image. The display is superimposed on the position corresponding to the last reference position in the merged display range or the position corresponding to the centroid position of the plurality of specific points in the merged display range.
Display system according to請Motomeko 7. In the overlay display process, the processing unit superimposes and displays the physical quantity image representing the physical quantity detected by the physical quantity detection unit at the specific location of the movement route at a position corresponding to the specific location of the movement route image. Let,
The display system according to any one of claims 1 to 8. In the overlay display process, the processing unit changes the display color or transmittance of the physical quantity image according to the physical quantity represented by the physical quantity image.
The display system according to any one of claims 1 to 8. In the overlay display process, the processing unit limits the maximum size and the minimum size of the physical quantity image within a predetermined ratio based on the size of the display area of the display unit.
The display system according to any one of claims 1 to 8. It has a position detection unit for detecting a position, a display unit for displaying an image, and a processing unit capable of executing a process of controlling the display unit and displaying an image, and the processing unit controls the display unit. A communication unit capable of communicating with a mobile device capable of executing an overlay display process of superimposing a physical quantity image representing a physical quantity on a movement route image representing a movement route determined according to a position detected by the position detection unit. ,
It has a physical quantity detection unit that detects the physical quantity, and has a physical quantity detection unit.
The communication unit transmits the detected physical quantity information regarding the physical quantity detected by the physical quantity detecting unit to the mobile device.
In the overlay processing, the processing unit makes the size of the physical quantity image variable according to the physical quantity represented by the physical quantity image, and when the physical quantity represented by the physical quantity image is a relatively small value, the value of the physical quantity. When the difference in the size of the physical quantity image with respect to the difference is relatively large and the physical quantity represented by the physical quantity image is a relatively large value, the difference in the size of the physical quantity image with respect to the difference in the value of the physical quantity is calculated. Characterized by making it relatively small,
Wearable device. It has a position detection unit for detecting a position, a display unit for displaying an image, and a processing unit capable of executing a process of controlling the display unit and displaying an image, and the processing unit controls the display unit. A communication unit capable of communicating with a mobile device capable of executing an overlay display process of superimposing a physical quantity image representing a physical quantity on a movement route image representing a movement route determined according to a position detected by the position detection unit. ,
It has a physical quantity detection unit that detects the physical quantity, and has a physical quantity detection unit.
The communication unit transmits the detected physical quantity information regarding the physical quantity detected by the physical quantity detecting unit to the mobile device.
In the overlay display process, the processing unit can superimpose and distinguish a plurality of the physical quantity images for each predetermined unit time, and in the overlay display process, the operation for the plurality of overlapping physical quantity images can be performed. The physical quantity represented by each of the plurality of physical quantity images is sequentially displayed accordingly.
Wearable device. It has a position detection unit for detecting a position, a display unit for displaying an image, and a processing unit capable of executing a process of controlling the display unit and displaying an image, and the processing unit controls the display unit. A communication unit capable of communicating with a mobile device capable of executing an overlay display process of superimposing a physical quantity image representing a physical quantity on a movement route image representing a movement route determined according to a position detected by the position detection unit. ,
It has a physical quantity detection unit that detects the physical quantity, and has a physical quantity detection unit.
The communication unit transmits the detected physical quantity information regarding the physical quantity detected by the physical quantity detecting unit to the mobile device.
The processing unit is characterized in that the method of totaling the physical quantity to be displayed in the overlay processing is variable based on the moving speed of the mobile device.
Wearable device. When the moving speed of the portable device is relatively slow, the processing unit aggregates the physical quantity according to the moving distance of the portable device, and when the moving speed of the portable device is relatively fast, the elapsed time is calculated. The physical quantities are aggregated accordingly.
The wearable device according to claim 14. It has a position detection unit for detecting a position, a display unit for displaying an image, and a processing unit capable of executing a process of controlling the display unit and displaying an image, and the processing unit controls the display unit. A communication unit capable of communicating with a mobile device capable of executing an overlay display process of superimposing a physical quantity image representing a physical quantity on a movement route image representing a movement route determined according to a position detected by the position detection unit. ,
It has a physical quantity detection unit that detects the physical quantity, and has a physical quantity detection unit.
The communication unit is a wearable device that transmits detected physical quantity information regarding the physical quantity detected by the physical quantity detecting unit to the mobile device.
When the processing unit detects that the mobile device and the wearable device have separated and moved relative to each other in the superimposed display process, the processing unit displays the physical quantity image in the separated and relative movement period during the period. It is characterized by executing a forget-me-not handling process that is different from the display of the physical quantity image outside.
Wearable device. It has a position detection unit for detecting a position, a display unit for displaying an image, and a processing unit capable of executing a process of controlling the display unit and displaying an image, and the processing unit controls the display unit. A communication unit capable of communicating with a mobile device capable of executing an overlay display process of superimposing a physical quantity image representing a physical quantity on a movement route image representing a movement route determined according to a position detected by the position detection unit. ,
It has a physical quantity detection unit that detects the physical quantity, and has a physical quantity detection unit.
The communication unit transmits the detected physical quantity information regarding the physical quantity detected by the physical quantity detecting unit to the mobile device.
In the processing unit, the moving distance of the mobile device from the specific location of the previously specified movement route exceeds the preset determination distance, and the elapsed time since the previous identification of the specific location is preset. The specific location is specified this time on condition that the determination period is exceeded, and the integrated value of the physical quantity detected by the physical quantity detection unit from the specific location specified last time to the specific location specified this time is calculated. , The physical quantity at the specific location specified this time.
Wearable device. It has a position detection unit for detecting a position, a display unit for displaying an image, and a processing unit capable of executing a process of controlling the display unit and displaying an image, and the processing unit controls the display unit. A communication unit capable of communicating with a mobile device capable of executing an overlay display process of superimposing a physical quantity image representing a physical quantity on a movement route image representing a movement route determined according to a position detected by the position detection unit. ,
It has a physical quantity detection unit that detects the physical quantity, and has a physical quantity detection unit.
The communication unit transmits the detected physical quantity information regarding the physical quantity detected by the physical quantity detecting unit to the mobile device.
The processing unit
In the superimposed display process, the physical quantities detected by the physical quantity detection unit are merged at a plurality of specific points of the moving route within the merged display range determined according to the merged display reference distance set in advance, and one physical quantity is obtained. Display as an image
A first said specific position of the starting point of the previous SL merged display range, the initial reference position of the intermediate position between the second of the specific locations subsequent to the first specific position, the reference position and the current the Judgment processing is performed to determine whether or not the distance to the specific location is greater than or equal to the merged display reference distance.
When it is determined by the determination process that the distance between the reference position and the specific location this time is not more than the merged display reference distance, the specific location this time is set as the specific location within the merged display range. , The intermediate position between the reference position and the specific location this time is updated as the reference position in the next determination process, and the determination process is repeated.
When it is determined by the determination process that the distance between the reference position and the specific location this time is equal to or greater than the merged display reference distance, the first specific location becomes the starting point within the next merged display range. It is characterized by being a specific part of
Wearable device. In the overlay display process, the processing unit displays the one physical quantity image obtained by merging the physical quantities detected by the physical quantity detection unit at the plurality of specific locations within the merged display range in the moving route image. The display is superimposed on the position corresponding to the last reference position in the merged display range or the position corresponding to the centroid position of the plurality of specific points in the merged display range.
The wearable device according to claim 18. It is an electronic clock that displays the time with a pointer.
The physical quantity detected by the physical quantity detection unit is the amount of power generated by the electric clock.
The wearable device according to any one of claims 12 to 19.

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