JP5014023B2 - Pedometer - Google Patents

Description

  The present invention relates to a pedometer that is used by being worn on a human body and that measures the number of steps of the worn user, and particularly relates to a pedometer that is worn and used on the user's arm.

2. Description of the Related Art Conventionally, a pedometer has been developed that measures the number of steps of a user by wearing it on a user's arm or waist or by storing it in a bag or the like carried by the user.
In recent years, in addition to the function of measuring the number of steps, various functions have been incorporated into the pedometer, and the training function for improving the user's exercise ability is one of them.

For example, in Patent Document 1, in the exercise of shooting a runner with a camera and running, arm swing, stride, pitch, etc. Among the items of arm swing, wrist position change, arm angle change, Disclosed are a body feature point detection device and a body motion analysis device that give advice to users based on the results of physical motion analysis such as the timing of left and right arm swings while utilizing knowledge of physical motion of skilled workers. Yes.
However, since it is a system for taking a picture with a camera, it is not easy to use because the apparatus is large for an individual to use as training.

In Patent Document 2, the detection device attached to the abdomen is used to measure the translational acceleration and angular velocity of the runner in each axial direction, and when the measured value exceeds the target value, an alarm is notified to the runner step by step. A running method learning device for a track and field runner is disclosed.
However, since the three-axis translational acceleration and angular velocity are measured, the structure becomes complicated, miniaturization is difficult, and there is a limit to the reduction in consumption. Moreover, since it is necessary to attach a detection apparatus to an abdomen, there exists a problem that a runner's usability is bad.

In the motion identification method described in Patent Document 3, body motion and gesture are identified using only acceleration data detected by a three-axis acceleration sensor included in a device attached to the wrist. In addition, the average magnitude and average azimuth angles θ and φ of the position vector during one type of exercise are graphed, and the exercise pattern is identified from each value.
However, since the three-axis translational acceleration and angular velocity are measured, the configuration becomes complicated, miniaturization is difficult, and there is a limit to the reduction in consumption.

Japanese Patent Laid-Open No. 10-111940 JP 2006-110046 A JP 2003-93566 A

  It is an object of the present invention to detect and notify the degree of arm swing of a user during traveling with a simple configuration.

According to the present invention, the detecting means having a sensor for detecting running and arm swing and outputting a running signal corresponding to the running detected by the sensor and an arm swing signal corresponding to the arm swing; Step counting means for counting the number of steps based on the running signal; evaluation means for evaluating the arm swing based on the arm swing signal; and notification means for notifying the evaluation of the arm swing performed by the evaluation means. There is provided a pedometer characterized by comprising:
The detection means has a sensor for detecting running and arm swing, and outputs a running signal corresponding to the running detected by the sensor and an arm swing signal corresponding to the arm swing. The step count counting means counts the number of steps based on the running signal from the detection means. The evaluation means evaluates arm swing based on the arm swing signal. The notifying means notifies the arm swing evaluation performed by the evaluating means.

Here, the evaluation means may be configured to count the arm swing signal, count the arm swing number, and perform arm swing evaluation based on the relationship between the arm swing number and the step count.
The detection means outputs a signal exceeding a first threshold among the signals from the sensor as the running signal, and outputs a signal exceeding a second threshold larger than the first threshold as the arm swing signal. You may comprise.

Moreover, you may comprise so that a threshold value change means to change the said 2nd threshold value may be provided.
The threshold value changing means may be configured to change the second threshold value based on the relationship between the number of steps counted by the step number counting means and the arm swing number counted by the evaluation means.
The travel time measuring means for measuring the cumulative travel time may be provided, and the threshold value changing means may be configured to change the second threshold value based on the cumulative travel time measured by the travel time measuring means. Good.

Further, when the evaluation unit determines that the arm swing signal is not output continuously from the detection unit for a predetermined time, or the number of arm swing signals output from the detection unit is determined to be equal to or less than a predetermined value. In this case, a notification means for issuing an alarm may be provided.
Further, at least the sensor may be configured to be used by being worn on an arm.

  According to the present invention, it is possible to detect and notify the degree of user's arm swing during traveling with a simple configuration.

Hereinafter, a pedometer according to an embodiment of the present invention will be described with reference to the drawings.
First, the basic concept of a pedometer according to an embodiment of the present invention will be described. A pedometer (arm pedometer) to be used by wearing on a user's arm is worn on the arm (by the user's own foot). 9 is output from the acceleration sensor for running detection. In the case of performing exercise walking, racewalking, and walking).

  In the case of a person with a small arm swing, the arm swing motion does not significantly affect the detection of the acceleration sensor, so the acceleration sensor detects only the impact at the time of landing due to traveling, and the acceleration sensor corresponding to traveling The signal level of the output signal (running signal) is small and substantially constant. This is shown in FIG. In the figure, the travel signal has a signal level that exceeds a first threshold that is a criterion for determining whether or not the vehicle is traveling.

  On the other hand, in the case of a person with a large arm swing, the arm swing motion has a great influence on the detection of the acceleration sensor, so the acceleration sensor detects the sum of the landing landing impact and the acceleration by the arm swing. It becomes. The acceleration due to arm swing increases when the arm is swung forward or backward, and decreases when the arm is swung back.

  Therefore, as shown in FIG. 9B, the output signal of the acceleration sensor that is generated when the vehicle travels with a large arm swing is generated such that the travel signal and the sum signal of the travel signal and the arm swing signal are alternately generated. Signal. As shown in the figure, the running signal is a signal larger than the first threshold, and the sum signal of the running signal and the arm swing signal is a larger signal exceeding the second threshold.

FIG. 10 is a graph showing the relationship between the magnitude of arm swing and the running speed, and shows data of four runners F, K, Su, and M.
As shown in FIG. 10, the running speed of each runner F, K, Su, M and the magnitude of arm swing are different from each other. It can be seen that the travel speed increases as the speed increases, and the magnitude of arm swing and the travel speed are in a proportional relationship.

That is, when running using a wristwatch type pedometer (arm pedometer), a person who swings his arm well will have the characteristics shown in FIG. It appears alternately.
As is clear from the graph shown in FIG. 10, it is known that the greater the arm swing, the faster the traveling speed. The pedometer according to the present embodiment uses such a feature and evaluates and notifies whether or not the arm is swinging firmly during running.

FIG. 1 is a block diagram of a pedometer according to the first embodiment of the present invention.
In FIG. 1, a pedometer detects a running and an arm swing and outputs a corresponding running signal and an arm swing signal (for example, an acceleration sensor) 101, and amplifies and outputs the running signal and the arm swing signal from the sensor 101. From the amplifier circuit 102, the filter 103 that passes the running signal and the arm swing signal in the signal from the amplifier circuit 102, the amplifier circuit 104 that amplifies and outputs the running signal and the arm swing signal from the filter 103, and The running signal and the arm swing signal are compared with a predetermined first threshold value, a signal exceeding the first threshold value is converted into a binarized digital signal as a running signal, and output from the step detection comparator 105 and the amplification circuit 104 The signal and the arm swing signal are compared with a predetermined second threshold value that is larger than the first threshold value, and a signal exceeding the second threshold value is binarized as an arm swing signal. And a arm swing detection comparator 109 outputs is converted into the digital signal.

  The pedometer includes a central processing unit (CPU) 106, an oscillation circuit 107 that generates a signal having a predetermined frequency, and a frequency dividing circuit that divides the signal from the oscillation circuit 107 and outputs a clock signal that serves as a reference for time counting operation. 108, an operation unit 110 constituted by key switches, a read only memory (ROM) 111 for storing programs executed by the CPU 106, a random access memory (RAM) 112 for storing step count data, arm swing number data, and the like, an alarm Is provided with a sound report unit 113 that emits a sound, a display drive circuit 114 that drives the display unit 115 in response to a display control signal from the CPU 106, and a display unit 115 that displays the number of steps, arm swing evaluation, and the like.

In FIG. 1, a function realized when the CPU 106 executes a program stored in the ROM 111 is shown as a block diagram in the CPU 106.
The CPU 106 calculates the travel pitch Tr based on the travel signal from the step detection comparator 105 (for example, by taking a moving average of the travel pitch based on the latest predetermined number of travel signals), It is determined whether or not the running pitch is within a predetermined range, and among the running signals output from the step detection comparator 105, a signal having a pitch within the predetermined range is output to the step counting unit 118 as a running signal for one step. In addition, a period comparison unit 117 that instructs the arm swing evaluation unit 119 to count an arm swing signal, and a step count unit 118 that counts the cumulative number of steps by adding the number of steps obtained from the period comparison unit 117 to the current number of steps. In response to the arm swing signal count instruction from the period comparison unit 117, the arm swing signal count processing and evaluation from the arm swing detection comparator 109 are performed. To function as arm swing evaluation unit 119 to perform.

Here, the sensor 101, the amplifier circuits 102 and 104, the filter 103, the step count detection comparator 105, and the arm swing detection comparator 109 constitute a detection circuit as detection means. The CPU 106, the oscillation circuit 107, and the frequency dividing circuit 08 constitute time measuring means and travel time measuring means.
The CPU 106 constitutes step count counting means, evaluation means, and threshold value changing means. The operation unit 110 constitutes an operation unit, and the ROM 111 and the RAM 112 constitute a storage unit. The sound report unit 113 constitutes a notification means. The display drive circuit 113 and the display unit 114 constitute notification means.

The detection means has a sensor for detecting running and arm swing, and can output a running signal corresponding to the running detected by the sensor and an arm swing signal corresponding to the arm swing. The detection means outputs a signal exceeding a first threshold value among the signals from the sensor as the running signal, and outputs a signal exceeding a second threshold value larger than the first threshold value as the arm swing signal. be able to.
The step count counting means can count the number of steps based on the running signal from the detection means.

The evaluation means can evaluate the arm swing based on the arm swing signal. The evaluation means can count the arm swing signal to count the arm swing number, and perform arm swing evaluation based on the relationship between the arm swing number and the step number.
The notification means can notify the evaluation of the arm swing performed by the evaluation means.
The threshold value changing unit can change the second threshold value. Further, the threshold value changing means can change the second threshold value based on the relationship between the number of steps counted by the step number counting means and the number of arm swings counted by the evaluation means. Further, the threshold value changing means can change the second threshold value based on the accumulated travel time measured by the travel time measuring means.

The travel time measuring means can measure the accumulated travel time.
The notification means determines that the evaluation means determines that the arm swing signal is not output continuously from the detection means for a predetermined time or the number of arm swing signals output from the detection means is equal to or less than a predetermined value. In some cases, an alarm can be issued.
Further, at least the sensor can be used by being attached to an arm.

FIG. 2 is a flowchart showing processing of the pedometer according to the first embodiment of the present invention.
Hereinafter, the operation of the pedometer according to the first embodiment of the present invention will be described with reference to FIGS. 1 and 2.
When measuring the number of steps, first, by turning on the power, the detection circuit including the sensor 101, the amplification circuits 102 and 104, the filter 103, the step detection comparator 105, and the arm swing detection comparator 109 is turned on (step S201). ), The start of the step count measurement is instructed by starting the operation unit 110.

The cycle calculation unit 116 of the CPU 106 detects a start operation of the operation unit 110 and starts a step count measurement operation (step S202). Further, in response to the start operation, the period calculation unit 116 starts a time measuring operation based on a clock signal input from the frequency dividing circuit 108.
Next, when it is determined that the travel signal has been input from the step detection comparator 105 (step S203), the cycle calculation unit 116 calculates the travel pitch Tr (step S204).

  When the period comparison unit 117 determines that the traveling pitch Tr is larger than 120 rpm (steps / minute) and smaller than 240 rpm, that is, the traveling signal is a normal traveling signal because it is a normal traveling pitch of the user. If the determination is made, the period comparison unit 117 outputs a step count signal so as to add one step to the step count counting unit 118, and instructs the arm swing evaluation unit 119 to count the arm swing signal (step S205).

  The step counting unit 118 receives the step count signal from the cycle comparison unit 117, adds one step to the current step count value, and counts the cumulative number of steps (S206). The step counting unit 118 drives and controls the display driving circuit 114 so as to display the current accumulated number of steps on the display unit 115 (step S207). As a result, the current cumulative step count counted by the step count counting unit 118 is displayed on the display unit 115 by driving the display drive circuit 114. In addition, by the display switching operation of the operation unit 110, the accumulated travel time measured by the period calculation unit 116 is displayed on the display unit 115.

Next, when an arm swing signal is input from the arm swing detection comparator 109 (step S208), the arm swing evaluation unit 119 adds 1 to the current cumulative arm swing number and counts the cumulative arm swing number. Thereafter, the process returns to the processing step S203 (step S209).
If the arm swing signal is not input from the arm swing detection comparator 109 in processing step S208 (step S208), the arm swing evaluation unit 119 returns to processing step S203 without counting the arm swing signal.

In processing step S205, when the period comparison unit 117 determines that the travel pitch Tr is 120 rpm or less or 240 rpm or more, that is, when the travel signal is not a normal travel signal because it is not the normal travel pitch of the user. Then, it is determined that the traveling signal is not obtained, and the process returns to the processing step S203.
When it is determined that the travel signal is not input from the step detection comparator 105 in the processing step S203, the cycle calculation unit 116 determines that the operation unit 110 is stopped to stop the step measurement operation (step S210). The arm swing evaluation unit 119 performs arm swing evaluation (step S211).

As an arm swing evaluation method of the arm swing evaluation unit 119, arm swing evaluation can be performed based on the relationship between the number of arm swing signals detected (arm swing number) and the number of running steps. For example, the ratio of the number of arm swings to the number of steps taken (arm swing rate: for example, the ratio of the number of arm swings to half of the number of steps taken) is calculated. Passing, 70-80% is good (Fair), 80% -90% is good (Good), 90% -100% is excellent (Excellent) Five-level evaluation is performed, and the evaluation is displayed on the display unit 115 (step S212). Note that various evaluation methods can be used for the evaluation, such as a two-step evaluation of whether the arm swing is large or small, or whether the arm swing is good or not.
In processing step S210, when it is determined that the operation unit 110 has not been stopped, the period calculation unit 116 returns to processing step S203 if the predetermined time has not elapsed, and determines that a timeout has occurred if the predetermined time has elapsed. The process is terminated (step S213).

  According to the first embodiment, the arm swing detection comparator 109 detects an arm swing signal, the arm swing evaluation unit 119 evaluates the degree of arm swing of the user, and displays the result on the display unit 115. Output. Therefore, it is possible to detect and notify the degree of the user's arm swing during traveling. Therefore, it becomes a travel form in which the arm is firmly shaken during the travel, and there is an effect that the training for increasing the travel speed can be performed efficiently. In addition, since only one sensor is required, the configuration is simplified.

FIG. 3 is a block diagram of a pedometer according to the second embodiment of the present invention. FIG. 4 is a flowchart showing processing of the pedometer according to the second embodiment of the present invention. 3 and 4, the same parts as those in FIGS. 1 and 2 are denoted by the same reference numerals.
In the second embodiment, the arm swing detection adjustment unit 301 and the reference voltage circuit 302 of FIG. 3 are provided, so that the threshold value of the arm swing detection comparator 109 is changed. Accordingly, the processing steps S401 to S406 of FIG. 4 are provided.

Hereinafter, the operation of portions different from those of the first embodiment will be described with reference to FIGS. 3 and 4.
After the detection circuit is turned on by turning on the power (step S201), the arm swing detection adjustment unit 301 controls the reference voltage circuit 302 to initialize the threshold value (second threshold value) of the arm swing detection comparator 109 (step S401). ). In response to the control of the arm swing detection adjustment unit 301, the reference voltage circuit 302 initializes the threshold value of the arm swing detection comparator 109 to a predetermined value.

  In processing step S208, when the arm swing evaluation unit 119 determines that the arm swing signal is not input from the arm swing detection comparator 109, the arm swing evaluation unit 119 is not detected a predetermined number of times (the third time in the present embodiment) (that is, When the travel signal is detected but the arm swing signal is not detected three times in succession (step S402), the arm swing detection adjustment unit 301 sets the threshold value of the arm swing detection comparator 109. After controlling the reference voltage circuit 302 so as to decrease by a predetermined value, the process returns to the processing step S203 (step S403).

The reference voltage circuit 302 controls the arm swing detection comparator 109 to decrease the threshold value by a predetermined value in response to the control of the arm swing detection adjustment unit 301. As a result, the threshold value of the arm swing detection comparator 109 is lowered by a predetermined value, making it easier to detect the arm swing signal.
In processing step S402, when the arm swing evaluation unit 119 determines that the number of times that the arm swing signal detection by the arm swing detection comparator 109 has not been continuously performed is not three, the process returns to processing step S203. .

  In processing step S208, when the arm swing evaluation unit 119 determines that the arm swing signal is input from the arm swing detection comparator 109, the arm swing evaluation unit 119 continuously outputs the arm swing signal a predetermined number of times (this embodiment). (5th), when it is determined that the arm swing signal has been detected five times in succession (step S404), it is determined that the arm swing signal has been detected stably. Then, the display drive circuit 114 is controlled to display on the display unit 115 that the adjustment of the threshold value of the arm swing detection comparator 109 has been completed (step S405). As a result, the display unit 115 displays that the adjustment of the threshold value of the arm swing detection comparator 109 has been completed.

In process step S404, when it is determined that the arm swing evaluation unit 119 has not detected the arm swing signal continuously for the predetermined number of times, the process returns to process step S203.
In addition, when it is determined that the period calculation unit 116 has been stopped by the operation unit 110 in the processing step S210 or when the period calculation unit 116 determines that a time-out has occurred in the processing step 213, the period calculation unit 116 displays the display unit 115 The display drive circuit 114 is controlled to display that the adjustment of the threshold value has been stopped (step S406). As a result, the display unit 115 displays that the adjustment of the threshold value of the arm swing detection comparator 109 has been stopped.
According to the second embodiment, not only the same effects as in the first embodiment can be obtained, but also the threshold value of the arm swing detection comparator 109 can be changed and set to an appropriate threshold value. There is an effect that becomes possible.

FIG. 5 is a flowchart showing processing of the pedometer according to the third embodiment of the present invention, and the same parts as those in FIG.
Since the block diagram of the third embodiment is the same as that of FIG. 1, parts unique to the third embodiment will be described with reference to FIGS. 1 and 5.

  In processing step S208, when the arm swing evaluation unit 119 determines that no arm swing signal is input from the arm swing detection comparator 109, the arm swing evaluation unit 119 continuously outputs the arm swing signal a predetermined number of times (this embodiment). If it is determined that no detection has been made (that is, detection of the arm swing signal has not been performed five times in succession) (step S501), the sound reporting unit 113 is controlled to sound an alarm. (Step S502). Thereby, when the arm swing signal cannot be detected a predetermined number of times or for a predetermined time, a warning is notified from the sound report unit 113.

As described above, while the runner is running, the arm swing may be reduced in the middle due to fatigue. According to the third embodiment, the same effect as the first embodiment can be obtained. In addition, if the state of small swing of the arm continues for a predetermined time, a warning is sounded and the swing of the arm can be promoted.
As a condition for issuing an alarm, when the arm swing evaluation unit 119 determines that the arm swing signal is not output continuously from the arm swing detection comparator 109 for a predetermined time, or a unit output from the arm swing detection comparator 109. When it is determined that the number of arm swing signals per hour is equal to or less than a predetermined value, an alarm can be generated.

FIG. 6 is a flowchart showing processing of the pedometer according to the fourth embodiment of the present invention. FIG. 8 is an explanatory diagram of the fourth embodiment.
Since the block diagram of the fourth embodiment is the same as that of FIG. 3, parts unique to the fourth embodiment will be described with reference to FIGS. 3, 6, and 8.
In response to the start operation of the operation unit 110, the cycle calculation unit 116 of the CPU 106 starts a time counting operation based on a clock signal input from the frequency dividing circuit 108, and measures the accumulated traveling time T.

  As shown in FIG. 8, the arm swing detection adjustment unit 301 is configured such that when the relationship between the accumulated travel time T and the threshold time T1 is T <T1, T1 <T <T2, T2 <T <T3, T3 <T, Then, the reference voltage circuit 302 is controlled so that the threshold value (second threshold value) of the arm swing detection comparator 109 is set to Level1, Level2, Level3, and Level4 (Level1 <Level2 <Level3 <Level4) (steps S601 to 605).

After setting the threshold value of the arm swing detection comparator 109 as described above, the travel detection process of FIG. 2, FIG. 4 or FIG. 5 is performed (step S606), and the cumulative travel time is calculated (step S607). ).
As described above, since the arm swing cannot be increased from the beginning of the run, the threshold value of the arm swing detection comparator 109 is initially set to a small value so that the threshold value is gradually increased as the training time becomes shorter. Thereby, it becomes possible to set an appropriate threshold according to the amount of training.

FIG. 7 is a flowchart showing processing of the pedometer according to the fifth embodiment of the present invention.
Since the block diagram of the fifth embodiment is the same as that of FIG. 3, parts unique to the fifth embodiment will be described with reference to FIGS. 3 and 7.
The arm swing evaluation unit 119 of the CPU 106 calculates a ratio between the arm swing number and the running step number (arm swing rate R: for example, a ratio between the arm swing number and half of the running step number) (step S701). When R <50%, 50% <R <70%, 70% <R <80%, and 80% <R, the threshold values of the arm swing detection comparator 109 are set to Level1, Level2, Level3, Level4 (Level1 < The reference voltage circuit 302 is controlled so as to set Level2 <Level3 <Level4) (steps S702 to S705).

After setting the threshold value of the arm swing detection comparator 109 as described above, the travel detection process of FIG. 2, FIG. 4 or FIG. 5 is performed (step S606), and the arm swing rate R is calculated (step S606). S706).
In this way, the threshold value of the arm swing detection comparator 109 is increased when the arm swing rate R can run exceeding the predetermined value instead of the training time. It is possible to set a different threshold value.
In each of the above-described embodiments, an example of an arm pedometer using at least a sensor attached to an arm has been described. However, the present invention can be applied to various pedometers having an arm swing detection function.

  The present invention is applicable to a pedometer having an arm swing detection function, such as an arm pedometer that is used with at least a sensor attached to the arm.

It is a block diagram of the pedometer which concerns on the 1st Embodiment of this invention. It is a flowchart of the pedometer which concerns on the 1st Embodiment of this invention. It is a block diagram of the pedometer which concerns on the 2nd Embodiment of this invention. It is a flowchart of the pedometer which concerns on the 2nd Embodiment of this invention. It is a flowchart of the pedometer which concerns on the 3rd Embodiment of this invention. It is a flowchart of the pedometer which concerns on the 4th Embodiment of this invention. It is a flowchart of the pedometer which concerns on the 5th Embodiment of this invention. It is explanatory drawing of the pedometer which concerns on the 4th Embodiment of this invention. It is explanatory drawing of the pedometer which concerns on embodiment of this invention. It is explanatory drawing of the pedometer which concerns on embodiment of this invention.

Explanation of symbols

101 ... sensors 102, 104 ... amplifier circuit 103 ... filter 105 ... step detection comparator 106 ... CPU
107... Oscillation circuit 108... Dividing circuit 109... Arm swing detection comparator 110.
112 ... RAM
113 ... Report sound part 114 ... Display drive circuit 115 ... Display part 116 ... Period calculation part 117 ... Period comparison part 118 ... Step count counting part 119 ... Arm swing evaluation part 301 ... Arm swing detection adjustment unit 302 ... Reference voltage circuit

Claims (7)

A detecting means that has a sensor for detecting running and arm swing and outputs a running signal corresponding to the running detected by the sensor and an arm swing signal corresponding to the arm swing;
Step counting means for counting the number of steps based on a running signal from the detection means;
Evaluation means for evaluating arm swing based on the arm swing signal;
Notification means for notifying the evaluation of arm swing performed by the evaluation means ,
The evaluation means is a pedometer that counts the arm swing signal and counts the arm swing number, and performs arm swing evaluation based on the relationship between the arm swing number and the step number,
A pedometer that performs arm swing evaluation based on a ratio between the number of arm swings and the number of steps.   The detection means outputs a signal exceeding a first threshold among the signals from the sensor as the running signal, and outputs a signal exceeding a second threshold larger than the first threshold as the arm swing signal. The pedometer according to claim 1.   The pedometer according to claim 2, further comprising threshold changing means for changing the second threshold.   4. The pedometer according to claim 3, wherein the threshold value changing unit changes the second threshold value based on a relationship between the number of steps counted by the step number counting unit and the number of arm swings counted by the evaluation unit. It comprises a travel time measuring means for measuring the cumulative travel time,
5. The pedometer according to claim 3, wherein the threshold value changing unit changes the second threshold value based on the accumulated travel time measured by the travel time measuring unit.   When the evaluation unit determines that the arm swing signal is not output continuously from the detection unit for a predetermined time or when the number of arm swing signals output from the detection unit is equal to or less than a predetermined value The pedometer according to any one of claims 1 to 5, further comprising notification means for issuing an alarm.   The pedometer according to any one of claims 1 to 6, wherein at least the sensor is used while being worn on an arm.

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