CN109381190B - Exercise assisting device, electronic timepiece, exercise assisting method, and recording medium - Google Patents

Abstract

The invention provides a sports assistance device, an electronic timepiece, a sports assistance method, and a recording medium. The electronic timepiece (100) is provided with a CPU (120) which controls notification to a user. A CPU (120) acquires the user's amount of motion for each second unit time divided by a predetermined number into predetermined first unit times. Then, the CPU (120) determines a pause degree indicating the degree of no movement in the first unit time based on a second target movement amount obtained by dividing a predetermined first target movement amount to be moved every first unit time by a predetermined amount and the movement amount obtained in the second unit time. Then, the CPU (120) controls notification based on the decided stop degree and a predetermined threshold value corresponding to the first target motion amount.

Description

Exercise assisting device, electronic timepiece, exercise assisting method, and recording medium

Technical Field

The present application relates to a sports support device, an electronic timepiece, a sports support method, and a recording medium.

Background

Conventionally, there is a technique of issuing an alarm when a swing arm signal is not detected for a predetermined time by a pedometer attached to an arm of a user in order to prevent the user from sitting for a long time (see, for example, japanese patent application laid-open No. 2009-53911).

In the pedometer disclosed in patent document 1, if it is determined whether or not to notify the user based only on the amount of exercise per specific time, if there is an imbalance in the amount of exercise within the time, the user may not be notified at an appropriate timing.

Disclosure of Invention

An object of the present invention is to provide an exercise assisting device, an electronic timepiece, an exercise assisting method, and a recording medium, which can remind a user of exercise at an appropriate timing.

The present invention has been made to achieve the above object, and an exercise assisting device according to a first aspect of the present invention includes a control unit that controls notification to a user, the control unit executing: acquiring the amount of motion of the user for each second unit time obtained by dividing a predetermined first unit time by a predetermined number; determining a pause degree indicating a degree of no motion in the first unit time based on a second target motion amount obtained by dividing a predetermined first target motion amount to be moved in each of the first unit times by the predetermined number and the motion amount obtained in the second unit time; and controlling the notification based on the decided stop degree and a predetermined threshold corresponding to the first target motion amount.

Drawings

Fig. 1 is a block diagram showing a configuration example of an electronic timepiece of the embodiment.

Fig. 2 (a) to (q) are diagrams showing time transitions of the pause degrees.

Fig. 3 (a) to (c) are diagrams for explaining an example in which an image is displayed and notified on the display unit.

Fig. 4 is a flowchart of notification control processing executed by the CPU of the electronic timepiece according to the embodiment.

Fig. 5 is a flowchart of notification control processing executed by the CPU of the electronic timepiece according to the embodiment.

Description of the symbols

100: an electronic timepiece, 101: microcomputer, 102: ROM, 103: communication unit, 104: antenna, 105: power supply unit, 106: display unit, 107: display driver, 108: speech output unit, 109: operation receiving unit, 110: vibrator, 111: acceleration sensor, 112: tilt sensor, 120: CPU, 121: RAM, 122: oscillation circuit, 123: frequency dividing circuit, 124: timing circuit, 125: procedure, 131: motion amount acquisition unit, 132: pause degree determination unit, 133: and a notification control unit.

Detailed Description

The preferred embodiments are described below based on the drawings.

Fig. 1 is a block diagram showing a configuration example of an electronic timepiece 100 of the present embodiment. The electronic timepiece 100 has a function of notifying the user of walking (hereinafter referred to as a "step count reminder function") in addition to a function of counting the current time.

First, a hardware configuration of the electronic timepiece 100 according to the embodiment will be described. As shown in fig. 1, the electronic timepiece 100 includes a microcomputer 101, a ROM (Read Only Memory) 102, a communication unit 103, an antenna 104, a power supply unit 105, a display unit 106, a display driver 107, a voice output unit 108, an operation receiving unit 109, an oscillator 110, an acceleration sensor 111, and a tilt sensor 112.

The microcomputer 101 is an example of a motion assist device, and includes a CPU (Central Processing Unit) 120 as a control Unit, a RAM (Random Access Memory) 121 as a storage Unit, an oscillation circuit 122, a frequency dividing circuit 123, and a timer circuit 124. The RAM121, the oscillation circuit 122, the frequency dividing circuit 123, and the timer circuit 124 are not limited to being provided inside the microcomputer 101, and may be provided outside the microcomputer 101. The ROM102, the communication unit 103, the power supply unit 105, the display driver 107, the voice output unit 108, and the vibrator 110 are not limited to being provided outside the microcomputer 101, and may be provided inside the microcomputer 101.

The CPU120 is a processor that performs various arithmetic processes and centrally controls the overall operation of the electronic timepiece 100. The CPU120 reads out a control program from the ROM102, loads the control program into the RAM121, and performs various operation processes such as time display, arithmetic control and display related to various functions.

The RAM121 is a volatile Memory such as an SRAM (Static Random Access Memory) or a DRAM (Dynamic Random Access Memory), and stores various setting data while providing a Memory space for operation to the CPU120 to store temporary data.

Oscillator circuit 122 generates and outputs a predetermined frequency signal (clock signal) by oscillating oscillator 110. As the oscillation circuit 122, for example, a crystal oscillator is used.

The frequency dividing circuit 123 divides the frequency signal input from the oscillation circuit 122 into signals of frequencies used by the timer circuit 124 or the CPU120 and outputs the signals. The frequency of the output signal may be changed based on the setting performed by the CPU 120.

The timing circuit 124 counts the current time by counting the number of inputs of a predetermined timing signal input from the frequency dividing circuit 123 and adding to an initial value. The timer circuit 124 may be constituted by software for changing the value stored in the RAM121, or may be constituted by a dedicated counter circuit. The Time counted by the timer circuit 124 may be any of an accumulated Time from a predetermined timing, a Coordinated Universal Time (UTC), a preset local Time, or the like. In addition, the time measured by the timer circuit 124 does not necessarily have to be maintained in the form of year, month, day, hour, minute and second.

The oscillation circuit 122, the frequency dividing circuit 123, and the timer circuit 124 constitute a timer unit.

The ROM102 is a mask ROM, a rewritable nonvolatile memory, or the like, and stores a control program and initial setting data. The control program includes a program 125 related to notification control processing described later.

The communication unit 103 is configured by, for example, a Radio Frequency (RF) circuit, a Baseband (BB) circuit, and a memory circuit. The communication unit 103 demodulates and decodes a radio signal received via the antenna 104, and transmits the radio signal to the CPU 120. The communication unit 103 encodes, modulates, and the like a signal transmitted from the CPU120, and transmits the signal to the outside via the antenna 104. The communication unit 103 performs wireless communication with another wireless communication device based on, for example, Bluetooth (registered trademark) low power consumption (BLE). BLE is a standard (pattern) established for the purpose of low power consumption in a short-range wireless communication standard called Bluetooth (registered trademark).

The power supply unit 105 includes a battery, and supplies power related to the operation of the electronic timepiece 100 to each unit at its operating voltage. In the present embodiment, a secondary battery such as a lithium ion battery is used as the battery of the power supply unit 105.

The Display unit 106 includes a Display screen such as a Liquid Crystal Display (LCD) or an organic EL (Electroluminescence) Display. The display driver 107 outputs a drive signal corresponding to the type of the display screen to the display 106 based on a control signal from the CPU120, and performs display on the display screen.

The voice output unit 108 includes, for example, a speaker or an amplifier, and outputs a voice based on a control signal from the CPU 120.

The operation receiving unit 109 includes, for example, a key or a button, receives an input operation from a user, and outputs an electric signal corresponding to the input operation to the CPU120 as an input signal. For example, as the operation receiving unit 109, a touch sensor may be provided so as to overlap the display screen of the display unit 106, and a touch panel may be configured together with the display screen. In this case, the touch sensor detects a contact position or a contact pattern associated with a contact action of a user to the touch sensor, and outputs an operation signal corresponding to the detected contact position or contact pattern to the CPU 120.

The acceleration sensor 111 includes a three-axis acceleration sensor that detects acceleration in three axis directions and outputs an electric signal corresponding to the detected acceleration to the CPU 120.

The tilt sensor 112 detects the tilt of the electronic timepiece 100, and outputs an electric signal corresponding to the detected tilt to the CPU 120. For example, the tilt sensor 112 includes a switch that is turned on when the electronic timepiece 100 is tilted so that the time base 12 faces downward, and outputs an electric signal indicating on/off of the switch to the CPU 120.

Next, a functional configuration of the CPU120 of the electronic timepiece 100 according to the embodiment will be described. The CPU120 functions as a motion amount acquisition unit 131, a pause degree determination unit 132, and a notification control unit 133. The functions of the motion amount acquisition unit 131, the pause degree determination unit 132, and the notification control unit 133 may be realized by a single CPU or may be realized by separate CPUs. These functions may be realized by a processor other than the microcomputer 101, such as a CPU of the communication unit 103.

The CPU120 as the motion amount acquisition section 131 acquires the user's motion amount per second unit time divided by a predetermined number into predetermined first unit times. The first unit time is a time that is a reference for determining whether or not to give a user a motion, and is, for example, 1 hour. The second unit time is a time to be a reference for determining a pause degree described later, and is 10 minutes when the first unit time is 1 hour and the predetermined number is 6. The amount of user's motion represents the amount of user's motion, expressed in units of steps, kilocalories, etc. Next, an example in which the user's exercise amount is expressed by the number of steps will be described.

Specifically, the CPU120 as the motion amount acquisition unit 131 determines whether or not the user is walking based on the electric signal from the acceleration sensor 111. For example, the CPU120 compares a waveform of an acceleration signal in a walking state stored in advance with a waveform of an electric signal from the acceleration sensor 111, determines that the walking state is present if the waveforms match, and adds the number of steps. The CPU120 counts the number of steps per second unit time and records the number of steps in the RAM121 or the like. When it is determined that the electronic timepiece 100 is not in the walking state, the CPU120 determines whether or not the electronic timepiece 100 is attached to the arm of the user based on the electric signal from the inclination sensor 112. For example, when an electric signal indicating on is received from the tilt sensor 112, that is, when the electronic timepiece 100 is tilted so that the time side of 12 is facing downward, the CPU120 determines that the electronic timepiece 100 is attached to the arm of the user. On the other hand, when receiving the electrical signal indicating disconnection from the tilt sensor 112, the CPU120 determines that the electronic timepiece 100 is not attached to the arm of the user. When the electronic timepiece 100 is determined not to be attached to the arm of the user for a predetermined time (for example, 3 minutes) or more, the CPU120 shifts the acceleration sensor 111 to the sleep mode.

The CPU120 as the pause degree determination unit 132 determines a pause degree indicating the degree of no motion in the first unit time based on a second target motion amount obtained by dividing a predetermined first target motion amount to be moved in each first unit time by a predetermined amount and the motion amount acquired in the second unit time. Specifically, for example, if the first unit time is 1 hour, the first target motion amount is 300 steps, and if the second unit time is 10 minutes (i.e., the predetermined number is 6), the second target motion amount is 50 steps. The pause degree is expressed by an integer of 0 to 6, for example. The CPU120 compares the number of steps acquired in the second unit time with the second target motion amount, and increases the current pause degree in the case where the number of steps acquired in the second unit time is smaller than the second target motion amount. When the number of steps acquired in the second unit time is equal to or greater than the second target motion amount, the CPU120 maintains the current stop level. Further, in the case where the number of steps acquired in the second unit time is equal to or greater than a predetermined third target motion amount that is larger than the second target motion amount, the CPU120 decreases the current stop degree. When the number of steps acquired in the second unit time is equal to or greater than the first target motion amount, the CPU120 clears (i.e., returns to the initial value of 0) the current pause degree.

Next, an example of a method of determining the stop level by the CPU120 as the stop level determining unit 132 will be described. In the following example, it is assumed that the first target motion amount is set in advance to 300 steps, the second motion target amount is set to 50 steps, and the third target motion amount is set to 100, 150, 200, and 250 steps.

The CPU120 performs the following processing:

(1) in the case where the number of steps acquired within 10 minutes as the second unit time is less than 50 steps, 1 is added to the stop count.

(2) The pause degree is maintained when the number of steps acquired within 10 minutes as the second unit time is 50 to 99 steps.

(3) When the number of steps acquired within 10 minutes as the second unit time is 100 to 149 steps, 1 is subtracted from the pause degree.

(4) When the number of steps acquired within 10 minutes as the second unit time is 150 to 199 steps, 2 is subtracted from the pause degree.

(5) When the number of steps acquired within 10 minutes as the second unit time is 200 to 249 steps, the pause degree is reduced by 3.

(6) When the number of steps acquired within 10 minutes as the second unit time is 250 to 299 steps, 4 is subtracted from the pause degree.

(7) When the number of steps acquired within 10 minutes as the second unit time is 300 steps or more, the pause degree is cleared.

The CPU120 changes the current degree of pause every second unit time according to the above rule, thereby determining the degree of pause.

The change of the specific pause degree in the above-described determination method will be described. Fig. 2 (a) to (q) are histograms showing temporal transitions of the pause degree represented by integers of 0 to 6. First, the time transition in which there is no pause at walking smaller than the second target amount periodically will be described with reference to (a) to (g) of fig. 2.

As shown in fig. 2 (a), the pause degree is 0 in the initial state. Thereafter, in the case where the second unit time, i.e., 10 minutes, has elapsed and the number of steps acquired in the 10 minutes is less than 50 steps, the CPU120 changes the degree of pause to 1 as shown in (b) of fig. 2 by adding 1 to the degree of pause 0 of the initial value. Further, after 10 minutes has elapsed and the number of steps acquired in 10 is less than 50 steps, the CPU120 changes the pause degree to 2 by adding 1 to the current pause degree 1 as shown in (c) of fig. 2. In this way, when the number of steps acquired in 10 minutes is less than 50 steps every 10 minutes, the CPU120 adds 1 to the current pause degree, and the pause degree is gradually increased by 1 every 10 minutes as shown in (d) to (g) of fig. 2. When 1 hour, which is the first unit time, has elapsed from the initial state shown in fig. 2 (a), the CPU120 determines that the pause degree is equal to or more than a predetermined threshold value described later and notifies the user when the pause degree becomes 6 as shown in fig. 2 (g).

Next, the time transition of the pause degree in the case where there is walking of the second target amount or more will be described with reference to (h) to (q) of fig. 2. First, as shown in fig. 2 (h), the pause degree is 0 in the initial state. Thereafter, in the case where 10 minutes as the second unit time elapses and the number of steps acquired in the 10 minutes is less than 50 steps, the CPU120 changes the stop count to 1 as shown in (i) of fig. 2 by adding 1 to the stop count 0 of the initial value. In the case where the number of steps acquired in the 10 minutes is less than 50 steps after another 10 minutes elapses, the CPU120 changes the stop count to 2 as shown in (j) of fig. 2 by adding 1 to the current stop count 1. When another 10 minutes has elapsed and the number of steps acquired in the 10 minutes is 50 steps to 99 steps, the CPU120 maintains the stop level 2 as shown in fig. 2 (k). In the case where the 10 minutes again passes and the number of steps acquired in the 10 minutes is less than 50 steps, the CPU120 changes the pause degree to 3 as shown in (l) of fig. 2 by adding 1 to the current pause degree 2. When the 10 minutes have elapsed again and the number of steps acquired in the 10 minutes is 100 to 149 steps, the CPU120 changes the pause degree to 2 as shown in fig. 2 (m) by subtracting 1 from the current pause degree 3. In the case where the 10 minutes again passes and the number of steps acquired in the 10 minutes is less than 50 steps, the CPU120 changes the stop count to 3 as shown in (n) of fig. 2 by adding 1 to the current stop count 2. When the number of steps acquired in 10 minutes is less than 50 steps, the CPU120 increments the current pause by 1, and the pause is incremented by 1 every 10 minutes as shown in (o) to (q) of fig. 2. When the stop degree becomes 6 as shown in fig. 2 (q), the CPU120 determines that the stop degree is equal to or higher than a predetermined threshold value described later, and notifies the user of the stop degree.

When the acceleration sensor 111 is in the sleep mode, the CPU120 maintains the stop until a predetermined time (for example, 1 hour) elapses since the shift to the sleep mode. Then, after 1 hour has elapsed since the sleep mode, the CPU120 clears the stop count. This is because the purpose is to detect human activity, not activity of the electronic timepiece 100. A predetermined time period from the transition to the sleep mode to the clear of the pause degree is set in advance as a time period to be a reference for distinguishing from a case where the user temporarily takes off the electronic timepiece 100. That is, in the sleep mode, the electronic timepiece 100 is highly likely to be in a state of not being worn on the arm of the user. In a state where the electronic timepiece 100 is not worn on the arm of the user, the electronic timepiece 100 cannot determine the movement of the user, and therefore the pause degree is maintained until the sleep mode is released. When the sleep mode is released within 1 hour from the time when the electronic timepiece 100 is turned into the sleep mode, the CPU120 determines that the user has worn the electronic timepiece 100 again, and restarts the determination of the walking state of the user by the acceleration sensor 111. When 1 hour has elapsed since the sleep mode was switched, without releasing the sleep mode, the CPU120 determines that the user has not worn the electronic timepiece 100 for a long time, not temporarily, and clears the pause degree. Further, by resetting the stop level after 1 hour has elapsed since the transition to the sleep mode by the CPU120, it is possible to prevent the start of the stop level every morning from halfway.

The CPU120 as the notification control unit 133 controls notification based on the determined stop degree and a predetermined threshold value corresponding to the first target motion amount. For example, when the upper limit value 6 of the pause degree is set in advance as the predetermined threshold value corresponding to the first target motion amount, the notification control unit 133 determines that the timing is the notification timing when the determined pause degree is the predetermined threshold value 6 corresponding to the first target motion amount, and causes the voice output unit 108 to output a predetermined voice and the display unit 106 to display a predetermined image to perform notification.

Fig. 3 (a) to (c) show an example of notification by the CPU120 as the notification control unit 133. Fig. 3 (a) is a diagram showing a screen of the display unit 106 of the electronic timepiece 100 in a state where notification is not performed. In the state shown in fig. 3 (a), an image I1 indicating the month, day, and week, such as "6/30, sunday" is displayed on the display unit 106. FIG. 3 (b) is a diagram showing the CPU120 by displaying "number of steps! | A "image I2 and icon image I3 marked with a circle are blinked to indicate a state of notification. In this state, the CPU120 outputs an alarm for a predetermined time (for example, about 0.5 to 1 second) through the voice output unit. Fig. 3 (c) is a diagram showing a screen of the display portion 106 of the electronic timepiece 100 in a state in which a predetermined time has elapsed from the state in fig. 3 (b). In the state shown in fig. 3 (c), the image I2 returns to the original image I1, but the icon image I3 continues to blink. Thus, while the user is prompted with information such as the month and date or the week, the fact that the number of steps has not reached the first target amount is notified to the user.

Fig. 4 and 5 are flowcharts showing an example of the report control process of the electronic timepiece 100 according to the present embodiment. The CPU120 of the electronic timepiece 100 starts the notification control process shown in fig. 4 and 5 when the step number reminder function is turned on by a user operation, for example. In the following flowchart, the first unit time is 1 hour, the second unit time is 10 minutes, the first target motion amount is 300 steps, and the second target motion amount is 50 steps.

First, the CPU120 determines whether the step number reminding function is on (step S101). When determining that the step number reminding function is not on, that is, when the step number reminding function is off (step S101: no), the CPU120 clears the pause degree (step S102), and ends the present process.

If it is determined that the step number reminding function is on (step S101: yes), CPU120 determines whether an error is output from acceleration sensor 111 (step S103). If it is determined that an error has been output from the acceleration sensor 111 (yes in step S103), the CPU120 executes sleep shift processing for putting the acceleration sensor 111 in the sleep mode (step S104). Then, the CPU120 proceeds to the process of step S107.

The CPU120 determines whether the acceleration sensor 111 is in the sleep mode (step S105). If it is determined that acceleration sensor 111 is not in sleep mode (no in step S105), CPU120 proceeds to the process of step S109. When it is determined that the acceleration sensor 111 is in the sleep mode (yes in step S105), the CPU120 determines whether or not an operation to cancel the sleep mode, such as an operation of any one of the keys provided in the electronic timepiece 100, is received (step S106). If it is determined that the operation to release the sleep state is not received (no in step S106), CPU120 determines whether or not 1 hour or more has elapsed since acceleration sensor 111 entered the sleep mode (step S107). When it is determined that 1 hour or more has elapsed since the acceleration sensor 111 has been in the sleep mode (yes in step S107), the CPU120 clears the stop time (step S102) and ends the present process. If it is determined that 1 hour or more has not elapsed since the acceleration sensor 111 has been in the sleep mode (no in step S107), the CPU120 returns to the process of step S103.

If it is determined that the operation of canceling the sleep mode is accepted (step S106: YES), the CPU120 executes a process of canceling the sleep mode (step S108). Then, the CPU120 executes walking determination processing for determining the walking state based on the output signal from the acceleration sensor 111 (step S109).

After the walking determination processing, the CPU120 determines whether the user is in a walking state (step S110). If it is determined that the user is not in the walking state (no in step S110), the CPU120 determines whether the state where the key of the electronic timepiece 100 is not pressed or the state where the tilt sensor 112 is not turned on continues for 3 minutes (step S111). If it is determined that the state in which any of the keys provided in the electronic timepiece 100 is not operated or the state in which the tilt sensor 112 is not turned on continues for 3 minutes (yes in step S111), the CPU120 proceeds to the process of step S107. If the state in which the key of the electronic timepiece 100 is not pressed or the state in which the tilt sensor 112 is not on does not continue for 3 minutes (no in step S111), the CPU120 proceeds to the process in step S113.

If it is determined that the user is in a walking state (step S110: YES), the CPU120 performs a walking addition process of measuring the cumulative number of steps by adding 1 step to the current number of steps of the first unit time (step S112).

Then, the CPU120 determines whether or not the timing to determine the stop degree, that is, whether or not the current second unit time is at the end (step S113). If it is determined that the timing is not the timing for determining the stop level (no in step S113), the CPU120 returns to the processing in step S101. If it is determined that the timing to determine the stop degree is "yes" (step S113:), CPU120 proceeds to the process of step S114 in fig. 5.

The CPU120 determines whether the cumulative number of steps in the last 10 minutes is less than 50 steps (step S114). If it is determined that the cumulative number of steps in the last 10 minutes is less than 50 steps (step S114: yes), the CPU120 adds 1 to the stop count (step S115) and proceeds to step S126.

If it is determined that the cumulative number of steps in the last 10 minutes is not less than 50 steps (step S114: NO), the CPU120 determines whether the cumulative number of steps in the last 10 minutes is less than 100 steps (step S116). If it is determined that the cumulative number of steps in the last 10 minutes is less than 100 steps (step S116: yes), the CPU120 proceeds to step S126 while maintaining the current pause.

If it is determined that the cumulative number of steps in the last 10 minutes is not less than 100 steps (step S116: no), the CPU120 determines whether the cumulative number of steps in the last 10 minutes is less than 150 steps (step S117). If it is determined that the cumulative number of steps in the last 10 minutes is less than 150 steps (step S117: yes), the CPU120 decrements the stop count by 1 (step S118), and proceeds to step S126.

If it is determined that the cumulative number of steps in the last 10 minutes is not less than 150 steps (step S117: no), the CPU120 determines whether the cumulative number of steps in the last 10 minutes is less than 200 steps (step S119). If it is determined that the cumulative number of steps in the last 10 minutes is less than 200 steps (step S119: yes), the CPU120 decrements the stop count by 2 (step S120) and proceeds to step S126.

If it is determined that the cumulative number of steps in the last 10 minutes is not less than 200 steps (step S119: NO), the CPU120 determines whether the cumulative number of steps in the last 10 minutes is less than 250 steps (step S121). If it is determined that the cumulative number of steps in the last 10 minutes is less than 250 steps (step S121: yes), the CPU120 decrements the stop count by 3 (step S122) and proceeds to step S126.

If it is determined that the cumulative number of steps in the last 10 minutes is not less than 250 steps (step S121: NO), the CPU120 determines whether the cumulative number of steps in the last 10 minutes is less than 300 steps (step S123). If it is determined that the cumulative number of steps in the last 10 minutes is less than 300 steps (step S123: yes), the CPU120 decrements the stop count by 4 (step S124), and proceeds to step S126.

If it is determined that the cumulative number of steps in the last 10 minutes is not less than 300 steps (step S123: NO), the CPU120 clears the current pause level (step S125).

Then, the CPU120 determines whether or not the cumulative number of steps for the latest 1 hour is 300 steps or more (step S126). If it is determined that the cumulative number of steps in the last 1 hour is not 300 steps or more (step S126: NO), the CPU120 proceeds to the process of step S130.

If it is determined that the cumulative number of steps in the last 1 hour is 300 or more (step S126: YES), the CPU120 clears the current pause degree (step S127). Then, the CPU120 determines whether or not a notification is being made on the screen of the current display unit 106, for example, whether or not the icon image I3 shown in fig. 3 (c) is blinking (step S128). If it is determined that the notification is being made on the current screen (yes in step S128), CPU120 cancels the notification on the screen (step S129) and proceeds to the process of step S130.

If it is determined that the notification is not being made on the current screen (step S128: no), CPU120 determines whether the current pause degree is 6 (step S130). If it is determined that the current stop level is not 6 (step S130: no), the CPU120 returns to the process of step S101 in fig. 2.

If it is determined that the current pause degree is 6 (yes in step S130), CPU120 performs a notification process based on the voice and the display by voice output unit 108 and display unit 106 (step S131). Then, the CPU120 clears the current stop count (step S132), and returns to the processing of step S101 in fig. 4.

The CPU120, for example, repeatedly executes the above processing until the step number reminding function is turned off.

As described above, the CPU120 of the electronic timepiece 100 according to the present embodiment acquires the user's motion amount for each second unit time obtained by dividing a predetermined number into predetermined first unit times, and determines the degree of pause indicating the degree of no motion in the first unit time based on the second target motion amount obtained by dividing the predetermined first target motion amount to be moved for each first unit time by the predetermined number and the motion amount acquired in the second unit time. Then, the CPU120 controls notification based on the decided stop degree and a predetermined threshold value corresponding to the first target amount of motion. Therefore, since the amount of exercise of the user is determined for each second unit time shorter than the first unit time, the user can be notified at a more appropriate timing than when the determination is performed for each first unit time.

When the amount of motion acquired in the second unit time is smaller than the second target amount of motion, the CPU120 of the electronic timepiece 100 according to the present embodiment increases the degree of pause, and when the degree of pause is equal to or greater than the threshold value, the CPU120 performs notification. Therefore, the longer the time during which the motion amount acquired in the second unit time does not satisfy the second target motion amount, the longer the CPU120 increases the pause degree, and the user can be notified of the time at which the pause degree becomes equal to or greater than the threshold value.

When the amount of motion acquired in the second unit time is equal to or greater than the second target amount of motion, the CPU120 of the electronic timepiece 100 of the present embodiment maintains the pause degree. Accordingly, when the user performs the exercise of the target amount or more in the second unit time, the CPU120 can perform the adjustment by delaying the timing notified to the user while maintaining the stop degree.

When the motion amount acquired in the second unit time is equal to or greater than the predetermined third target motion amount larger than the second target motion amount, the CPU120 of the electronic timepiece 100 according to the present embodiment reduces the degree of pause. Thus, when the user performs a motion of a motion amount larger than the target amount within the second unit time, the CPU120 can perform adjustment by reducing the degree of pause and further delaying the timing of notification to the user.

When the accumulated value of the motion amounts acquired in the first unit time is equal to or greater than the first target motion amount, the CPU120 of the electronic timepiece 100 according to the present embodiment returns the pause degree to the initial value. Thus, when the user performs a motion equal to or greater than the first target motion amount within the first unit time, the user can be notified at an appropriate timing by clearing the pause degree and restarting the count of the pause degree.

The CPU120 of the electronic timepiece 100 according to the present embodiment further includes a voice output unit 108 that outputs a voice, and the CPU120 causes the voice output unit 108 to output a predetermined voice to perform notification. Therefore, notification of a motion to the user by voice can be performed.

The CPU120 of the electronic timepiece 100 according to the present embodiment further includes a display unit 106 that displays an image, and the CPU120 displays a predetermined image on the display unit 106 to perform notification. Therefore, notification that the user is reminded of the motion by the image can be performed.

The present invention is not limited to the above embodiment, and various modifications may be made.

For example, in the above-described embodiment, an example in which the CPU120 notifies the user by voice or image is described. However, the notification method to the user is not limited thereto. For example, the CPU120 may notify the user by either voice or image. The CPU120 may notify the user by vibration, or lighting or blinking of an LED (Light Emitting Diode).

For example, in the above embodiment, an example was described in which the CPU120 displays the image I2 and the icon image I3 shown in fig. 3 (b) and 3 (c) on the display unit 106. The CPU120 may also display the pause degree on the display unit 106. For example, the CPU120 may display the pause degree on the display unit 106 in the manner shown in (a) to (q) of fig. 2. Thus, the user can easily recognize to what degree the lack of motion is currently relative to the first target amount of motion.

For example, in the above-described embodiment, an example has been described in which the CPU120 determines whether the electronic timepiece 100 is attached to the arm of the user based on the electric signal from the tilt sensor 112. However, the method of determining whether the electronic timepiece 100 is worn on the arm of the user is not limited to this. For example, the CPU120 may detect the tilt of the electronic timepiece 100 based on the electric signal from the acceleration sensor 111, and determine that the electronic timepiece 100 is attached to the arm of the user when determining that the electronic timepiece 100 is tilted so that the 12-hour side faces downward.

In the above embodiment, an example in which the CPU120 performs various control operations such as notification control processing has been described. However, the control operation is not limited to software control by the CPU. A part or all of the control operation may be performed by a hardware configuration such as a dedicated logic circuit.

In the above description, the ROM102 configured by a nonvolatile memory such as a flash memory is described as an example of a computer-readable medium storing a program related to data communication processing and a program related to notification control processing according to the present invention. However, the medium that can be Read by the computer is not limited to this, and a portable recording medium such as hdd (hard Disk drive), CD-rom (compact Disk Read Only memory), or dvd (digital Versatile Disk) may be applied. In addition, as a medium for supplying data of the program of the present invention via a communication line, a carrier wave is also applicable to the present invention.

In addition, the specific details of the structure, control procedure, display example, and the like shown in the above embodiments may be appropriately modified within the scope not departing from the gist of the present invention.

Although the embodiments of the present invention have been described, the scope of the present invention is not limited to the above embodiments, but includes the scope of the invention described in the claims and the equivalent scope thereof. Hereinafter, inventions described in the scope of patent protection originally attached to the present application are additionally described. The appended numbers are as if originally filed in the application for which protection was granted.

(attached note 1)

An exercise assisting device is characterized in that the exercise assisting device is provided with a control unit for controlling notification to a user,

the control section performs the following processing:

acquiring the amount of motion of the user for each second unit time obtained by dividing a predetermined first unit time by a predetermined number;

determining a pause degree indicating a degree of no motion in the first unit time based on a second target motion amount obtained by dividing a predetermined first target motion amount to be moved in each of the first unit times by the predetermined number and the motion amount obtained in the second unit time; and

controlling the notification based on the decided stop degree and a predetermined threshold corresponding to the first target amount of motion.

(attached note 2)

The exercise assisting device according to supplementary note 1, wherein,

the control section executes the following processing:

increasing the degree of pause in the case where the amount of motion acquired in the second unit time is smaller than the second target amount of motion; and

and when the pause degree is above the threshold value, executing the notification.

(attached note 3)

The exercise assisting device according to supplementary note 2, wherein,

the control unit maintains the pause degree when the motion amount acquired in the second unit time is equal to or greater than the second target motion amount.

(attached note 4)

The exercise assisting device according to supplementary note 2 or 3, characterized in that,

the control unit may decrease the pause degree when the motion amount acquired in the second unit time is equal to or greater than a predetermined third target motion amount that is larger than the second target motion amount.

(attached note 5)

The exercise assisting device according to any one of supplementary notes 2 to 4, wherein,

the control unit returns the pause degree to an initial value when the accumulated value of the motion amounts acquired in the first unit time is equal to or greater than the first target motion amount.

(attached note 6)

The exercise assisting device according to any one of supplementary notes 1 to 5, wherein,

the exercise assisting device further comprises a voice output unit for outputting voice,

the control unit causes the voice output unit to output a predetermined voice to thereby execute the notification.

(attached note 7)

The exercise assisting device according to any one of supplementary notes 1 to 6, wherein,

the exercise assisting device further includes a display unit for displaying an image,

the control unit causes the display unit to display a predetermined image to thereby execute the notification.

(attached note 8)

An electronic timepiece is characterized by comprising:

the exercise assisting device described in any one of supplementary notes 1 to 7;

a timing unit for timing a current time; and

and a time display unit that displays the current time measured by the time measuring unit.

(attached note 9)

An exercise assisting method executed by an exercise assisting device, comprising:

a motion amount acquisition step of acquiring a user's motion amount per second unit time obtained by dividing a predetermined first unit time by a predetermined number;

a pause degree determination step of determining a pause degree indicating a degree of no motion in the first unit time based on a second target motion amount obtained by dividing a predetermined first target motion amount to be moved in each of the first unit times by the predetermined number and the motion amount obtained in the second unit time; and

and a notification control step of controlling, based on the determined pause degree and a predetermined threshold value corresponding to the first target amount of motion, notification to the user indicating that the first target amount of motion is not achieved.

(attached note 10)

A recording medium having a computer-readable program recorded thereon,

the program causes a computer to function as:

a motion amount acquisition unit that acquires user's motion amounts for each second unit time divided by a predetermined number into predetermined first unit times;

a pause degree determination unit configured to determine a pause degree indicating a degree of no motion in the first unit time, based on a second target motion amount obtained by dividing a predetermined first target motion amount to be moved in each of the first unit times by the predetermined number, and the motion amount obtained in the second unit time; and

and a notification control unit that controls notification to the user indicating that the first target amount of motion is not achieved, based on the determined pause degree and a predetermined threshold value corresponding to the first target amount of motion.

Claims (10)

1. An exercise assisting device, characterized in that,

the exercise assisting device is provided with a control unit for controlling notification to a user,

the control section executes the following processing:

acquiring the amount of motion of the user for each second unit time obtained by dividing a predetermined first unit time by a predetermined number;

determining a degree of pause indicating a degree of no movement in the first unit time based on a second target movement amount obtained by dividing a predetermined first target movement amount to be moved in each of the first unit times by the predetermined number and the movement amount acquired in the second unit time, and maintaining the degree of pause until a predetermined time elapses since the sleep mode is entered, and clearing the degree of pause after a predetermined time elapses since the sleep mode; and

controlling the notification based on the decided stop degree and a predetermined threshold value corresponding to the first target amount of motion,

the first unit time is a time that becomes a reference for determining whether or not to give a user a motion, and the second unit time is a time that becomes a reference for determining the pause degree.

2. An exercise assisting device in accordance with claim 1,

the control section executes the following processing:

increasing the degree of pause in the case where the amount of motion acquired in the second unit time is smaller than the second target amount of motion; and

and when the pause degree is above the threshold value, executing the notification.

3. An exercise assisting device in accordance with claim 2,

the control unit maintains the pause degree when the motion amount acquired in the second unit time is equal to or greater than the second target motion amount.

4. An exercise assisting device in accordance with claim 2,

the control unit may decrease the pause degree when the motion amount acquired in the second unit time is equal to or greater than a predetermined third target motion amount that is larger than the second target motion amount.

5. An exercise assisting device in accordance with claim 2,

the control unit returns the pause degree to an initial value when the accumulated value of the motion amounts acquired in the first unit time is equal to or greater than the first target motion amount.

6. An exercise assisting device in accordance with claim 1,

the exercise assisting device further comprises a voice output unit for outputting voice,

the control unit causes the voice output unit to output a predetermined voice to thereby execute the notification.

7. An exercise assisting device in accordance with claim 1,

the exercise assisting device further includes a display unit for displaying an image,

the control unit causes the display unit to display a predetermined image to thereby execute the notification.

8. An electronic timepiece is characterized by comprising:

the exercise assisting device of any one of claims 1 to 7;

a timing unit for timing a current time; and

and a time display unit that displays the current time measured by the time measuring unit.

9. An exercise assisting method executed by an exercise assisting device, comprising:

a motion amount acquisition step of acquiring a user's motion amount per second unit time obtained by dividing a predetermined first unit time by a predetermined number;

a pause degree determination step of determining a pause degree indicating a degree of no movement in the first unit time based on a second target movement amount obtained by dividing a predetermined first target movement amount to be moved in each of the first unit times by the predetermined amount and the movement amount acquired in the second unit time, maintaining the pause degree until a predetermined time elapses since the transition to the sleep mode, and clearing the pause degree to zero after a predetermined time elapses since the sleep mode; and

a notification control step of controlling a notification to the user indicating that the first target amount of motion is not achieved, based on the determined pause degree and a predetermined threshold value corresponding to the first target amount of motion,

the first unit time is a time that becomes a reference for determining whether or not to give a user a motion, and the second unit time is a time that becomes a reference for determining the pause degree.

10. A recording medium having a computer-readable program recorded thereon,

the program causes a computer to function as:

a motion amount acquisition unit that acquires user's motion amounts for each second unit time divided by a predetermined number into predetermined first unit times;

a pause degree determination means for determining a pause degree indicating a degree of no motion in the first unit time based on a second target motion amount obtained by dividing a predetermined first target motion amount to be moved in each of the first unit times by the predetermined amount and the motion amount acquired in the second unit time, and for maintaining the pause degree until a predetermined time elapses since the transition to the sleep mode and clearing the pause degree to zero after a predetermined time elapses since the sleep mode; and

a notification control means for controlling a notification to the user indicating that the first target amount of motion is not achieved, based on the determined pause degree and a predetermined threshold corresponding to the first target amount of motion,

the first unit time is a time that becomes a reference for determining whether or not to give a user a motion, and the second unit time is a time that becomes a reference for determining the pause degree.

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