JPH09122090A - Non-restrictive pulsimeter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a non-restrictive pulsimeter which is designed enhancing operability, mounting skill, visual recognizability and saving of power by providing the body of the pulsimeter with a pulse wave sensor which is arranged integrally to detect a pulse from a finger. SOLUTION: A pulsimeter 10 has a display section 11 to display a measured value of a pulse rate or the like and is provided with the body of the pulsimeter having a band 12 as mounting means for positioning the display 11 on the back of a hand and a pulse wave sensor 14 built integrally on the body 13 of the pulsimeter. The pulse wave sensor 14 is built integrally on the body 13 of the pulsimeter to be positioned at the root of an index finger in the mounting thereof. The pulse wave sensor 14 herein used is a type made up of a light emitting element and a photoreceptive element or with a strain gauge or the like. The mounting means may be either of a band 12 or glove but it is desired that the pulse wave sensor 14 should be pressed on to the foot of a finger by a moderate pressing force when the body 13 of the pulsimeter is mounted.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an unrestrained pulse meter for measuring a human pulse without restriction.

[0002]

2. Description of the Related Art A conventional unrestrained pulse rate meter measures a pulse rate by putting a finger on a pulse wave sensor attached to a wrist watch or a pedometer, for example. When measuring the pulse rate, stop and measure the pulse rate. ing. Further, as a device capable of measuring a pulse without stopping, there is a device in which a pulse wave sensor is attached to the ear.

[0003]

In a wristwatch or a pedometer equipped with a pulse wave sensor, it is necessary to touch the pulse wave sensor with a fingertip, and therefore, when measuring while exercising such as jogging, swing the arm. It is difficult to measure unless it stops because of the large movement caused by. Therefore, when measuring a pulse during exercise such as jogging, the exercise must be interrupted each time.

On the other hand, in the case where the pulse wave sensor is worn on the ear, a lead wire having a length from the main body to the pulse wave sensor is required, and it is not only complicated to handle the long lead wire, but also due to the lead wire. There is a problem that the movement of the body is restrained, and the pulse wave sensor comes off from the ear by, for example, catching a hand or the like on the lead wire during jogging. Moreover, in order to detect the pulse wave from the ear, the pulse wave sensor is generally a photoelectric sensor, and since an unrestrained pulse meter of this type needs to be used continuously for a long time, the photoelectric sensor has a battery life. It has the drawback of being short.

On the other hand, there is a wristwatch type pulse rate monitor in which a sack type photoelectric pulse wave sensor is attached to the fingertip for use, but the movement of the finger is obstructed by the lead wire, the handling is complicated, and the restraint is also required. strong. In addition, because the main body is a wristwatch type, it is not only necessary to remove the wristwatch and wear it,
It is necessary to incorporate a clock function into the pulse rate monitor. In addition, most wrist watches used for jogging have special functions such as a stopwatch function and a lap function. Therefore, in the case of a wristwatch type, if a watch function for such exercise management is built-in. However, the cost becomes higher.

It is also conceivable to wear a pulse rate monitor on the arm opposite to the wrist-watching arm, but the operation is complicated and the restraint is high. You cannot see the contents at the same time. As described above, the conventional unconstrained pulse rate monitor has many practical problems.
Therefore, the present invention has been made in view of such various problems, and an object thereof is to provide an unrestrained pulse meter in consideration of operability, wearability, visibility, power saving, and the like. .

[0007]

In order to achieve the above-mentioned object, the unconstrained pulse rate monitor of the present invention has a display section for displaying a measured value and a mounting means for positioning this display section in a hand. The present invention is characterized by including a pulse meter main body having the pulse wave sensor and a pulse wave sensor which is provided integrally with the pulse meter main body and detects a pulse from a finger.

This unconstrained pulse meter is worn on the hand by the wearing means. In the worn state, the display section of the pulse meter main body is positioned on the hand and the pulse wave sensor is positioned on the finger. Therefore, the pulse signal detected from the finger by the pulse wave sensor is input to the pulse meter main body without passing through the lead wire, the pulse rate etc. is calculated by the pulse meter main body, and the pulse rate etc. is displayed on the display section of the pulse meter main body. Is displayed in. According to this pulse meter, since the pulse wave sensor is integrally provided in the pulse meter main body, the pulse meter can be worn as it is on the arm of the wrist watch and can be used together with the wrist watch.

According to a second aspect of the present invention, the pulse sensor main body is provided with an acceleration sensor for detecting the movement of the arm, so that the measurement and display of the pulse can be controlled according to the presence or absence of the movement (swing) of the arm. can do. According to claims 3 to 5, for example,
When the acceleration sensor detects a swing of the arm, the display unit does not display the measurement value, or when the acceleration sensor detects the stop of the arm swing, the display unit displays the measurement value, Alternatively, it becomes possible to thin out the measurement of the pulse while the swing of the arm is detected by the acceleration sensor. Further, according to the sixth aspect, by providing the pulse rate measurement interval setting means for setting the time interval for measuring the pulse rate, the subject can freely adjust the pulse measurement time interval.

[0010]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below based on embodiments. An unrestrained pulse meter according to the embodiment is shown in FIG. The pulse rate monitor 10 has a display section (for example, LCD) 11 for displaying a measured value such as a pulse rate, and a pulse rate meter main body 13 having a band 12 as a mounting means for positioning the display section 11 on the back of the hand, The pulse wave sensor 14 is provided integrally with the pulse meter main body 13.

The display unit 11 of the pulse rate monitor main body 13 is a band 1
It is positioned near the center of the back of the hand when it is attached to the hand by 2, so that the display on the display unit 11 is easy to see. A power switch 15 is provided on the display unit 11. The pulse meter main body 13 is preferably formed thin so that the back of the hand does not feel uncomfortable when worn.
Particularly, it is desirable that the display unit 11 be thin.

The pulse wave sensor 14 is provided integrally with the pulse meter main body 13 (that is, the band 12) so that it is positioned at the base of the index finger when it is worn. Pulse wave sensor 1
Reference numeral 4 represents a light emitting element and a light receiving element, a strain gauge, or the like. An unrestrained pulse meter according to another embodiment is shown in FIG. This pulse rate monitor 10 'has basically the same configuration as the pulse rate meter 10 shown in FIG.
The only difference is that it is 2 '.

Whether the wearing means is the band 12 or the glove 12 ', when the pulse meter main body 13 is worn, the pulse wave sensor 14 is pressed against the base of the finger (index finger) with an appropriate pressing force. It is desirable to do. That is, it is preferable that the length of the circumference of the main body portion provided with the pulse wave sensor 14 can be adjusted. The adjusting mechanism in this case is illustrated in FIG. In FIG. 3A, a notch is made in the main body portion where the pulse wave sensor 14 is provided, and one end of the notch is cut into the hook-and-loop fastener 2.
It is formed in a belt shape with 1, and the peripheral length of the portion is adjusted by the surface fastener 21. In FIG. 3B, a notch is made in the main body portion where the pulse wave sensor 14 is provided, and both ends of the notched portion are connected by elastic members 22 such as rubber and springs. In FIG. 3C, a stretchable member 23 such as a rubber band is attached to the pulse wave sensor 14, and the stretchable member 23 is integrally joined to the pulse meter main body 13. In any case, the pulse wave sensor 14 fits properly to the base of the finger regardless of the thickness of the finger (index finger) of the person to be measured, and the pulse is detected reliably.

Although only the power switch 15 is provided on the display unit 11, in addition to the power switch 15, in addition to the power switch 15 in FIG. 4, in order to add a function of setting the time interval for measuring the pulse rate, for example, in FIG. A set switch (pulse rate measurement interval setting means) 16 may be provided. In this case, the display unit 1
It is convenient to operate the switch 16 while watching 1 so that the time interval can be arbitrarily set.

FIG. 5 is a block diagram showing an example of the circuit of the unrestrained pulse rate monitor as described above. In this example, the pulse wave sensor 14
Besides, the acceleration sensor 17 for detecting the movement of the arm
And a power generation unit 18 that generates power by the movement of the arm. ON / OFF of the power switch 15 is input to the CPU 30 via the power circuit 31 to which the power source 32 is connected. Further, the electricity generated by the power generation unit 18 is supplied to the power supply circuit 31.

The output from the acceleration sensor 17 is converted into a digital signal by the A / D converter 34 through the amplifier circuit 33 and is taken into the CPU 30. Pulse wave sensor drive circuit 3
Reference numeral 5 drives the pulse wave sensor 14 according to a command from the CPU 30. For example, when the pulse wave sensor 14 is composed of a light emitting element and a light receiving element, the pulse wave sensor drive circuit 35 causes the light emitting element to emit light. The output from the pulse wave sensor 14 is filtered by a filter 36 to remove noise and drift, and then amplified.
Is converted into a digital signal by the A / D converter 38 and is taken into the CPU 30.

Display data from the CPU 30 (pulse rate, etc.)
Is displayed on the LCD 11 via the LCD drive circuit 39. It should be noted that the CPU 30 is executed according to the program of the flowchart described later. Further, when the measurement interval set switch 16 for setting the time interval for measuring the pulse rate is provided, the signal is taken into the CPU 30. Next, an operation example of the unrestrained pulse rate monitor configured as described above will be described. There are various possible operations of the above pulse rate monitor.
Explain the street. When measuring and displaying the pulse rate only when the arm is stopped (there is no movement of the arm) This process is shown in the flowchart of FIG. When the power switch 15 is turned on, it is first determined from the output of the acceleration sensor 17 whether or not the arm wearing the pulse rate monitor is stopped.
Here, for example, as shown in FIG.
When the output A is smaller than a threshold (absolute value) Th, the arm is stopped, and when the output A is equal to or larger than the threshold Th, it is determined that the arm is being shaken (moving) [step (hereinafter,
(Abbreviated as ST) 11]. ST until it is determined that the arm has stopped
Wait at 11.

When it is determined that the arm has stopped, the CPU 30 sends a command to the pulse wave sensor drive circuit 35, and the pulse wave sensor 14
Drive. With respect to the pulse wave signal obtained from the pulse wave sensor 14, the peak of the pulse wave is detected in FIG. 10 and the time interval Δt between the peaks is measured (ST12). And
The reciprocal of the measured peak interval Δt is multiplied by 60 to calculate the pulse rate for one minute (ST13). However, in order to improve the accuracy of the pulse rate, the pulse rate for one minute is calculated by actually waiting until the peak interval is measured multiple times and multiplying the reciprocal of the average value of the multiple peak intervals by 60. . For example, in the example shown in FIG. 10, pulse rate = [1 / {(Δt ₁ + Δt ₂ + Δt ₃ ) / 3}]
It becomes x60.

The calculated pulse rate is displayed on the LCD 11 (ST14), the pulse wave sensor drive circuit 35 is stopped to stop the pulse wave measurement (ST15), and the process returns to ST11 again. Then, by turning off the power switch 15, the operation ends. By this operation, the pulse can be measured and displayed only when the movement of the arm is stopped. When the pulse rate is constantly measured and the pulse rate is displayed only when the arm does not move This process is shown in the flowchart of FIG. When the power switch 15 is turned on, the CPU 30 sends a command to the pulse wave sensor drive circuit 35 to drive the pulse wave sensor 14, as described above.
Then, the peak of the pulse wave is detected and the time interval Δ
The t is measured (ST21). The reciprocal of the obtained peak interval is multiplied by 60 to calculate the pulse rate for one minute (S
T22). In practice, it is preferable to obtain a plurality of peak intervals and multiply the reciprocal of their average value by 60 in order to improve the accuracy of the pulse rate as described above.

Next, check the output of the acceleration sensor 17,
If the output A is smaller than a certain threshold Th, it means that the arm is stopped. If the output A is equal to or larger than the threshold Th, it is judged that the arm is being shaken (ST23). If it is determined in ST23 that the arm is being swung, the process returns to ST21, and if it is determined that the arm is stopped, the pulse rate is displayed (ST24), and S is displayed.
Return to T21. Here again, the operation ends when the power switch 15 is turned off.

By this operation, the pulse rate can be displayed only when the movement of the arm is stopped. When setting the time interval for measuring the pulse rate, that is, when setting the time interval for measuring the pulse rate arbitrarily, calculating the pulse rate for each time interval, and displaying the pulse rate only when the arm stops The process is shown in the flowchart of FIG. First, the power switch 15 is turned on, and the time interval T (s) for measuring the pulse rate is set (ST31). At next ST32, the timer is reset (t = 0), and the CPU 30
Sends a command to the pulse wave sensor drive circuit 35, and the pulse wave sensor 1
4 is driven, the peak of the pulse wave is detected, and the time interval Δt between the peaks is measured (ST33).

A pulse rate for 1 minute is calculated based on the obtained interval between peaks (ST34). Of course, similarly to the above, the average value of a plurality of peak intervals is used to improve the accuracy of the pulse rate. After calculating the pulse rate, the pulse wave sensor drive circuit 35
Is stopped (ST35). Next, the acceleration sensor 17
It is determined whether or not the output A is smaller than a certain threshold Th (ST36). When the output A is smaller than the threshold Th, that is, when it is determined that the arm is stopped, the pulse rate is displayed (ST37), and the process proceeds to ST38. When the output A is equal to or greater than the threshold Th, that is, when it is determined that the arm is swung, the pulse rate is not displayed and the process proceeds to ST38.

At ST38, the timer time t (s) and S
The measurement time interval T (s) set at T31 is compared, and when the time t of the timer is smaller than the measurement time interval T, ST3
When it is longer than the measurement time interval T, the process returns to ST32. By the processing of this ST38, after the pulse rate is calculated, the pulse rate is displayed until the measurement time interval T elapses. If the arm does not stop within the time interval T, the process proceeds to the calculation of the next pulse rate and the time interval is calculated. If the arm stops within T, the calculated pulse rate is displayed. Of course, the operation ends when the power switch 15 is turned off.

By this operation, the measurement time can be freely thinned according to the taste of the person to be measured, and further power saving can be realized.

[0025]

Since the unrestrained pulse rate monitor of the present invention is constructed as described above, it has the following effects. (1) According to claim 1, since the pulse wave sensor is integrally provided in the pulse meter main body having the display unit and the mounting means, if the pulse meter main body is mounted on the hand by the mounting means, the pulse wave sensor will be automatically operated. Since the pulse wave sensor is positioned on the measurement site and the pulse wave sensor can be easily positioned on the measurement site, anyone can measure the pulse easily and reliably. (2) Since the pulse rate monitor main body is attached to the hand by the attaching means, the pulse rate meter can be attached to the arm of the wristwatch without removing the wristwatch, and the wristwatch and pulse rate meter can be used together. It is easy to handle and easy to install. Further, it is easy to integrate the pulse meter and the wrist watch. Furthermore, by using a wrist watch and pulse meter together, the clock and pulse rate can be viewed at the same time. (3) According to claim 2, an acceleration sensor for detecting the movement of the arm is provided on the main body of the pulse meter to control the measurement and display of the pulse according to the presence or absence of the movement (swing) of the arm. You can According to claims 3 and 4, for example, when the swing of the arm is stopped in order to check the pulse during exercise such as jogging, the stop of the swing of the arm is detected by the acceleration sensor, and the pulse rate is detected only at the time of detection. Can be displayed. Therefore, since the pulse rate is not displayed when unnecessary, the battery life can be greatly extended. (4) According to the sixth aspect, by providing the pulse rate measurement interval setting means for setting the time interval for measuring the pulse rate, the subject can freely adjust the pulse measurement time interval. (5) According to claim 7, by incorporating the power generation means,
The life of the battery can be further extended.

[Brief description of the drawings]

FIG. 1 is a diagram showing a state in which an unrestrained pulse meter according to an embodiment is worn on a hand.

FIG. 2 is a view showing a state in which an unrestrained pulse meter according to another embodiment is worn on a hand.

FIG. 3 is a diagram showing a mechanism for adjusting the peripheral length of a portion in which a pulse wave sensor is integrally provided on a pulse meter main body.

FIG. 4 is a diagram showing an example of the form of a display unit of the pulse meter main body.

FIG. 5 is a block diagram showing an example of a circuit of an unrestrained pulse meter.

FIG. 6 is a flowchart showing an example of the operation of the unrestrained pulse rate monitor.

FIG. 7 is a flowchart showing another example of the operation of the unrestrained pulse rate monitor.

FIG. 8 is a flowchart showing still another example of the operation of the unrestrained pulse rate monitor.

FIG. 9 is a diagram illustrating a case where the presence or absence of arm movement is detected using an acceleration sensor.

FIG. 10 is a diagram illustrating a case where a time interval between peaks is measured from a pulse wave signal of a pulse wave sensor.

[Explanation of symbols]

10, 10 'Unrestrained pulse meter 11 Display section 12, 12' Band, glove (wearing means) 13 Pulse meter main body 14 Pulse wave sensor 16 Measurement interval set switch (pulse rate measurement interval setting means) 17 Acceleration sensor

Claims (7)

[Claims] 1. A display unit for displaying measured values,
An unrestrained pulse meter characterized by comprising a pulse meter main body having a mounting means for positioning the display part in a hand, and a pulse wave sensor integrally provided on the pulse meter main body to detect a pulse from a finger. . 2. The unrestrained pulse meter according to claim 1, wherein the pulse meter main body has an acceleration sensor for detecting a movement of an arm. 3. The unconstrained pulse meter according to claim 2, wherein the display section does not display the measured value when the motion of the arm is detected by the acceleration sensor. 4. The unrestrained pulse meter according to claim 2, wherein the display section displays a measurement value when the movement of the arm is detected to be stopped by the acceleration sensor. 5. The unrestrained pulse meter according to claim 2, wherein the measurement of the pulse is thinned while the movement of the arm is detected by the acceleration sensor. 6. The apparatus according to claim 1, further comprising pulse rate measurement interval setting means for setting a time interval for measuring the pulse rate.
Alternatively, the unrestrained pulse rate monitor according to claim 2. 7. The unrestrained pulse rate monitor according to claim 1, further comprising a power generation means.