JP2007209678A - Measuring device, and controlling method and controlling program of measuring device, - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To relate biological information to correct time by easily determining whether time information is corrected or not without increasing the number of parts. <P>SOLUTION: A measuring device 10, which measures biological information of a user and performs processing by relating the time information to the biological information, performs one of the processes of preventing a display of time, the storage of the biological information related to the time information, the measurement of the biological information, or the automatic measurement of the biological information when the time is not corrected at prescribed timing. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a measurement device, a control method for the measurement device, and a control program, and in particular, a measurement device that is worn on the user's body and measures biological information such as a pulse in the user's daily life, a control method for the measurement device, and a control program About.

In a biological information measuring device that measures biological information such as a pulse rate and oxygen saturation (SPO ₂ ), biological information changes with time. Therefore, when storing biological information, accurate time information is required. Saving is very important. As such a biological information measuring device, there exists a thing as described in patent document 1, for example.
In recent years, higher functionality of devices has progressed, and battery-driven products using primary batteries or secondary batteries are increasing even for devices with relatively large power consumption.
JP 2004-298320 A

The battery voltage may drop in a short time, especially in situations where measurement is performed frequently. In such a case, the time information is reset and the correct time is displayed if the time is not adjusted. Or there may be situations where it cannot be saved.
However, in the biological information measuring device described in Patent Document 1, if accurate time information cannot be stored when storing biological information, the reliability of the data decreases, and the usefulness of the stored biological information decreases, or In addition to the fact that biometric information does not make sense at all, there is a risk that wrong judgments and conclusions may be drawn.

Specifically, if the battery is changed at 11:00, the time information is reset. For example, if the time is 0 o'clock, the biological information data is acquired at 13:00, considering the actual time. However, on recording, the data was acquired at 2 o'clock in the middle of the night, and there is a possibility that the data becomes meaningless at all.
In addition, in a biological information measuring device that automatically measures biological information at a predetermined time, biological information at a time different from the time that was originally intended to be measured is also measured. For example, assuming a biological information measuring device that decides to eat at 8:00 am and automatically measures blood glucose levels at predetermined times before and after the meal, it would be meaningless if the measurement time is shifted. It would be tricky for biometric data.

In addition, if the time information is corrected after measuring several times, it will not be possible to know when the data is stored at the correct time when the data is analyzed later. However, there is a problem that it becomes impossible to use.
In order to solve these problems, even if the voltage of the battery used as the main power supply drops, the real time clock and spare battery can be installed in these devices so that the time information can be retained. A method of incorporating a so-called radio clock is also proposed.
However, the method with a built-in radio timepiece has a problem that it is not always used in a state in which the time is corrected because the radio wave cannot be received. In any of the methods, there are problems that the number of parts constituting the device increases and the control becomes complicated, resulting in an increase in cost and an increase in size of the device.

  Accordingly, an object of the present invention is to provide a measuring device and a measuring device that can easily determine whether or not time information is corrected without causing an increase in the number of parts, and associate biological information with the correct time. A control method and a control program are provided.

In order to solve the above problems, in a measurement device that measures a user's biological information and performs processing by associating time information with the biological information, a time display unit that displays time, and a time correction unit that performs time correction, A time correction determination unit that determines whether or not a time correction corresponding to the time information has been made at a predetermined timing, and the time display unit when the time correction corresponding to the time information has not been made at the predetermined timing And a display prohibition unit for prohibiting the time display in FIG.
According to the said structure, a time correction part makes a user perform time correction.
In parallel with this, the time correction determination unit determines whether or not the time correction corresponding to the time information has been performed at a predetermined timing, and the display prohibition unit performs the time correction corresponding to the time information at a predetermined timing. If not, the time display in the time display unit is prohibited.

Further, in the measurement device that measures the biometric information of the user and stores it in association with the time information, a time correction determination unit that determines whether or not the time correction corresponding to the time information has been performed at a predetermined timing; And a storage prohibiting unit for prohibiting the storage of the biometric information and the time information in association with each other when the time correction corresponding to the time information is not performed at the timing.
According to the above configuration, the time correction determination unit determines whether or not the time correction corresponding to the time information has been made at a predetermined timing.
Based on this determination, the storage prohibition unit prohibits the biometric information and the time information from being stored in association with each other when the time correction corresponding to the time information is not performed at a predetermined timing.

In this case, if the time corresponding to the time information is not corrected at the predetermined timing, an information storage unit that stores the biological information and the elapsed time from the measurement start time in association with each other may be provided. Good.
In addition, when the time corresponding to the time information is not corrected at the predetermined timing, a biometric information storage prohibiting unit that prohibits the storage of the biometric information may be provided.

Further, in the measurement device that measures the biometric information of the user and stores it in association with the time information, a time correction determination unit that determines whether or not the time correction corresponding to the time information has been performed at a predetermined timing; And a measurement prohibition unit that prohibits measurement of the biological information when the time correction corresponding to the time information is not performed at the timing.
According to the above configuration, the time correction determination unit determines whether or not the time correction corresponding to the time information has been performed at a predetermined timing, and the measurement prohibition unit performs the time correction corresponding to the time information at a predetermined timing. When there is not, measurement of biological information is prohibited.

Further, in a measurement device that measures biological information of a user and performs processing by associating time information with the biological information, an automatic measurement unit that measures biological information at a predetermined automatic measurement timing, and a time corresponding to the time information A time correction determination unit that determines whether or not the correction is made at a predetermined timing; and an automatic that prohibits the automatic measurement operation in the automatic measurement unit when the time correction corresponding to the time information is not made at the predetermined timing And a measurement prohibition unit.
According to the above configuration, the time correction determination unit determines whether or not the time correction corresponding to the time information has been performed at a predetermined timing, and the automatic measurement prohibition unit performs the time correction corresponding to the time information at a predetermined timing. If not done, automatic measurement operation in the automatic measurement unit is prohibited.

Moreover, the control method of the measuring device which has the time display part which displays time, and the time adjustment part for performing time correction, measures a user's biometric information, and associates time information with the said biometric information, and performs a process The time correction determining process for determining whether or not the time correction corresponding to the time information has been made at a predetermined timing, and the time display when the time correction corresponding to the time information has not been made at the predetermined timing And a display prohibiting process for prohibiting time display in the section.
In addition, in the control method of the measuring device that measures the user's biological information and stores it in association with the time information, a time correction determination process for determining whether or not the time correction corresponding to the time information has been made at a predetermined timing; A storage prohibiting step for prohibiting the storage of the biometric information and the time information in association with each other when the time correction corresponding to the time information is not made at the predetermined timing. .
In addition, in a measurement device that measures biological information of a user and associates time information with the biological information and performs processing, an automatic measurement process of measuring biological information at a predetermined automatic measurement timing, and the time information at a predetermined timing Automatic correction for prohibiting automatic measurement operation in the automatic measurement process when the time correction corresponding to the time information is not performed at the predetermined timing And a measurement prohibition process.

Further, a computer includes a time display unit that displays time and a time correction unit for performing time correction, and measures a user's biological information and performs processing by associating the time information with the biological information. In the control program for controlling, it is determined whether or not the time correction corresponding to the time information is made at a predetermined timing, and the time is corrected when the time correction corresponding to the time information is not made at the predetermined timing. It is characterized by prohibiting time display on the display unit.
Further, in a control program for measuring a user's biological information and controlling the measurement device stored in association with the time information by a computer, it is determined whether or not the time correction corresponding to the time information has been made at a predetermined timing. The biometric information and the time information are prohibited from being stored in association with each other when the time corresponding to the time information is not corrected at the predetermined timing.
In a control program for measuring a user's biological information and controlling a measurement device that performs processing by associating time information with the biological information by a computer, the biological information is measured at a predetermined automatic measurement timing. It is determined whether or not the time correction corresponding to the time information has been made at the timing, and if the time correction corresponding to the time information has not been made at the predetermined timing, the automatic measurement operation in the automatic measurement process is prohibited. It is characterized by that.

  According to the present invention, it is possible to easily determine whether or not the time information is corrected without causing an increase in the number of parts, and to associate the biological information with the correct time.

Next, preferred embodiments of the present invention will be described with reference to the drawings.
(1) Principle Description First, the principle of the present invention will be described with reference to the drawings.
FIG. 1 is a schematic configuration block diagram for explaining the principle of the present invention.
The measuring device 10 can be broadly divided into a control unit 11 that controls the entire measuring device 10 and manages time information, a biological information detection unit 12 that detects biological information and outputs a detection signal, and a detection signal. A calculation unit 13 that calculates a parameter to be measured and performs calculation processing, a display unit 14 that displays time information and biological information, a storage unit 15 that stores biological information together with time information, and a time correction performed to the user. A time setting unit 16 for adjusting the time and a time correction determination unit 17 for determining whether or not the time correction has been performed at a predetermined timing.

The control unit 11 includes a time information determination unit 18 that determines whether to display, store, or automatically measure time information.
FIG. 2 is a schematic configuration block diagram of the time information determination unit.
The time information determination unit 18 includes a time display determination unit 18A that determines whether or not the time display should be performed based on whether or not the time correction is performed normally, and a time based on whether or not the time correction is performed normally. A time information storage determination unit 18B that determines whether or not information should be stored in association with biometric information, and an automatic measurement determination unit that determines whether or not to perform automatic measurement based on whether or not the time correction has been performed normally 18C.

In this case, when the measuring apparatus 10 is started after the power is restored by performing battery replacement or charging from a state where the battery voltage is lowered, the measuring apparatus 10 is activated. Since the time information may not be correct while the power is not turned on, the control unit 11 resets the time information.
After that, the time correction determination unit 17 always monitors the operation state of the time setting unit 16 after the time information is reset, and notifies the control unit 11 when an instruction for rewriting the time information is input. It will be.
Thereby, the time information determination unit 18 of the control unit 11 can always grasp the determination result of the time correction determination unit 17.
On the other hand, once the time information has been rewritten, it is considered that the time information has been set correctly, so the time correction determination unit 17 stops monitoring.
First, the time display operation will be described.
In this case, when the measuring device 10 is activated (powered on), the time correction determination unit 17 monitors the operation state of the time setting unit 16 to determine whether the time correction has been performed, The determination result is notified to the control unit 11.
The display unit 14 displays time information when the measurement is not started, and displays the measured biological information and time information when the measurement is started.

  In the time information determination unit 18 of the control unit 11, the time display determination unit 18 </ b> A determines that the time display should not be performed when the time correction is not performed based on the determination result of the time correction determination unit 17. As a result, the control unit 11 does not display the time on the display unit 14. Therefore, the user recognizes that the time is not displayed on the display unit 14, so that the time has not been corrected yet, so that the user can be surely prompted to correct the time.

Next, the time information storage operation will be described.
In this case, when the measuring device 10 is activated (powered on), the time correction determination unit 17 monitors the operation state of the time setting unit 16 to determine whether the time correction has been performed, The determination result is notified to the control unit 11.
When measurement is started, the biological information is detected and a detection signal is output to the calculation unit 13, and the calculation unit 13 calculates a parameter to be measured from the input detection signal, performs calculation processing, and performs control. To the unit 11.
In parallel with this, in the time information determination unit 18 of the control unit 11, the time information storage determination unit 18 </ b> B determines the measured biological information when the time correction is normally performed based on the determination result of the time correction determination unit 17. It is determined that the time information should be stored in the storage unit 15 in association with the information, and as a result, the control unit 11 stores the biological information together with the time information in the storage unit 15. Therefore, biological information can be stored together with accurate time information.

In the time information determination unit 18 of the control unit 11, the time information storage determination unit 18 </ b> B associates the time information with the measured biological information when the time correction is not performed based on the determination result of the time correction determination unit 17. Is not to be stored in the storage unit 15, and as a result, the control unit 11 stores the biological information in the storage unit 15 without associating it with the time information.
Next, the automatic measurement operation will be described.
In this case, when the measuring device 10 is activated (powered on), the time correction determination unit 17 monitors the operation state of the time setting unit 16 to determine whether the time correction has been performed, The determination result is notified to the control unit 11.

In the time information determination unit 18 of the control unit 11, the automatic measurement determination unit 18 </ b> C, when the time correction is normally performed based on the determination result of the time correction determination unit 17, the biological information at the time corresponding to the predetermined time information. The detection unit detects biological information and outputs a detection signal to the calculation unit 13, calculates a parameter to be measured from the detection signal input to the calculation unit 13, performs calculation processing, and outputs it to the control unit 11, Display or storage is performed. Therefore, it is possible to acquire biological information by performing automatic measurement at an accurate time.
In the time information determination unit 18 of the control unit 11, the automatic measurement determination unit 18 </ b> C ends the process without performing automatic measurement when the time is not corrected based on the determination result of the time correction determination unit 17. .
As described above, according to the present invention, the time display, time information storage, or automatic measurement is performed only when the time is corrected normally after the power is turned on, which increases the number of parts. Therefore, it is possible to easily determine whether or not the time information is corrected, and to associate the biological information with the correct time.

(2) Embodiment Next, a specific embodiment will be described.
FIG. 3 is an explanatory diagram of a mounting state of a pulse measuring device as an example of a measuring device that measures biological information according to the embodiment.
The pulse measuring device 10 is used by being mounted on a user's arm 11, and includes a device main body (watch case) 10A and a wristband 10B for mounting the device main body 10A on the arm.
FIG. 4 is a cross-sectional view of the pulse measuring device according to the embodiment.
When the wristband 10B is wrapped around the wrist and the pulse measuring device 10 is mounted, the back side of the device main body 10A is in close contact with the back of the wrist.
Therefore, a body motion sensor 22 and a pulse wave sensor 23 configured as a triaxial (X axis, Y axis, Z axis) acceleration sensor are provided on the back side of the apparatus main body 10A.
As shown in FIG. 4, the pulse wave sensor 23 protects the LED 23A that emits pulse wave detection light, the PD (Photo Detector) 23B that receives the detection light reflected by the human body, and the LEDs 23A and PD 23B. A transparent glass 23C for transmitting the incident light of the LED 23A and the reflected light obtained through the living body to be incident on the PD 23B is also provided. Here, the transparent glass 23C is fixed by a back cover 24 constituting the apparatus main body 10A.
According to the configuration of the pulse wave sensor 23, the light from the LED 23A is applied to the back of the wrist through the transparent glass 23C, and the reflected light is received by the photodiode 23B.

A liquid crystal display device 25 that displays biological information such as a pulse rate HR based on the detection result of the pulse wave sensor 23 in addition to the current time and date is provided on the surface side of the apparatus main body 10A.
Further, various IC circuits such as a CPU are provided on the upper side of the main substrate 26 inside the apparatus main body 10A, and thereby a data processing circuit 27 is configured.
Further, a battery 28 is provided on the back side of the main board 26, and power is supplied from the battery 28 to the body motion sensor 22, the pulse wave sensor 23, the liquid crystal display device 25, and the main board 26. .
The body motion sensor 22, the pulse wave sensor 23 and the main board 26 are connected by a heat seal 29. Thereby, power is supplied from the main board 26 to the body motion sensor 22 and the pulse wave sensor 23 by the wiring formed by the heat seal 29.
As a result, an acceleration detection signal is supplied from the body motion sensor 22 to the main board 26. Further, a pulse wave detection signal is supplied from the pulse wave sensor 23 to the main board 26.
The data processing circuit 27 calculates the pulse rate HR by performing FFT processing on the acceleration detection signal and the pulse wave detection signal and analyzing the processing results. As shown in FIG. 3, button switches 20A, 20B, 20C, 20D, and 20E for time adjustment and display mode switching are provided on the outer surface of the apparatus main body 10A.

FIG. 5 is a schematic configuration block diagram of the pulse measuring device according to the embodiment.
The pulse measuring device 10 includes a CPU 130, which controls various operations such as a pulse rate calculation process based on a biological detection signal from the pulse wave sensor 23 in addition to controlling the operation of each part of the pulse wave meter 1. Functions as control / calculation means for executing
The EEPROM 132 is a nonvolatile and rewritable memory, and stores a control program executed by the CPU 130 and various data.
The RAM 134 is used as a work area for the CPU 130, and temporarily stores calculation results and various data by the CPU 130.

The clock circuit 136 includes an oscillation circuit 1360 that outputs a clock signal having a predetermined frequency (for example, 32.768 kHz), and a frequency dividing circuit 1361 that divides the clock signal from the oscillation circuit 1360 and outputs a 1 Hz clock signal to the CPU 130. The CPU 130 performs a time measurement process based on a 1 Hz clock signal.
The input unit 138 corresponds to the button switches 20A, 20B, 20C, 20D, and 20E described above, and outputs a signal corresponding to each button operation of the user to the CPU 130.
Multiplier 140 performs multiplication processing at high speed in hardware among the arithmetic processing required by CPU 130.
The liquid crystal display unit 108 displays a screen according to the control of the CPU 130.

The pulse wave signal amplification circuit 120 amplifies the output signal of the pulse wave sensor 23 and outputs the amplified signal to the A / D conversion circuit 122 and the pulse wave waveform shaping circuit 123.
The body motion signal amplification circuit 121 amplifies the output signal of the body motion sensor 22 and outputs the amplified signal to the A / D conversion circuit 122 and the body motion waveform shaping circuit 124.
Under the control of the CPU 130, the A / D conversion circuit 122 performs analog / digital conversion on the output signal of the pulse wave sensor 23 or the body motion sensor 22 and outputs it to the digital input terminal of the CPU 130.
The pulse waveform shaping circuit 123 shapes the waveform of the output signal of the pulse wave sensor 23 and outputs it to the analog input terminal of the CPU 130.
The body motion waveform shaping circuit 124 shapes the output signal of the body motion sensor 22 and outputs it to the analog input terminal of the CPU 130.
The CPU 130 performs FFT (Fast Fourier Transform) processing on the biological detection data (pulse wave data and body motion data) input via the A / D conversion circuit 122, thereby generating the pulse wave signal and the body motion signal. The frequency component is calculated, the harmonic component of the pulse wave is extracted, and the pulse rate is calculated from the frequency. In addition, since the specific calculation method of this pulse rate is the same as that of the past, detailed description is abbreviate | omitted.

Next, the operation of the embodiment will be described.
FIG. 6 is a process flowchart of the time correction flag setting process.
This time correction flag setting process starts when the power is turned on and continues until the time is corrected by the user's manual process or automatic process.
When the power is turned on, the CPU 130 resets the time information (step S11). Subsequently, the CPU 130 defeats (turns off) the time correction flag (step S12).

Next, the CPU 130 determines whether or not the time information has been rewritten, that is, whether or not the time has been corrected by the user's manual processing or automatic processing (step S13).
In this case, the actual rewriting of the time information is generally performed by the CPU 130. In this case, the determination is easy, but when the time information is not managed by the CPU 130, a real time clock IC or the like is used. Therefore, the determination is made based on whether or not an interrupt signal is input.
If it is determined in step S13 that the time information has not been rewritten, that is, if the time has not yet been corrected by the user's manual processing or automatic processing (step S13; No), the CPU 130 enters a standby state.
On the other hand, when the time information is rewritten in the determination of step S13, that is, when the time is corrected by the user's manual processing or automatic processing, the CPU 130 does not need to monitor the time correction, so the time correction flag Is set (turned on) (step S14), and the time correction flag setting process is terminated.

Next, processing at the time of actual biological information measurement will be described.
FIG. 7 is a processing flowchart when measuring biological information.
First, the CPU 130 determines whether measurement of biological information has been started (step S21).
If the measurement of the biological information has not yet started in the determination of step S21 (step S21; No), it enters a standby state.
If the measurement of the biological information is started in the determination in step S21 (step S21; Yes), the CPU 130 determines whether or not the time correction flag is in an on state (step S22). That is, in the time correction flag setting process (see FIG. 6), it is determined whether or not it is determined that the time has been corrected by the user's manual process or automatic process.
If it is determined in step S22 that the time correction flag is on, that is, if the time is corrected by the user's manual processing or automatic processing after the power is turned on (step S22; Yes), the obtained time information is accurate. Therefore, biological information such as pitch and pulse rate is associated with time information and stored (step S23).

FIG. 8 is an explanatory diagram of an example in which the pitch and the pulse rate are stored in association with the time information.
As shown in FIG. = 1 biometric information is
Measurement time = 12:06:50 Pitch = 120 Pulse rate 70
Saved as In this example, the absolute time is stored as the measurement time. However, when the measurement time interval is constant, only the start time can be stored. is there.
Next, the CPU 130 determines whether or not the measurement has ended (step S25). If the measurement has not ended (step S25; No), the process proceeds to step S22 again. Process.

In the determination of step S25, when the measurement is finished, the process is finished.
On the other hand, if it is determined in step S22 that the time correction flag is off, that is, if the time has not been corrected by the user's manual processing or automatic processing after the power is turned on (step S22; No), it is obtained. Since the time information may not be accurate, biological information such as pitch and pulse rate is not associated with the time information but is stored in association with the elapsed time from the start of measurement (step S24).
Next, the CPU 130 determines whether or not the measurement has ended (step S25). If the measurement has not ended (step S25; No), the process proceeds to step S22 again. Process.
In the determination of step S25, when the measurement is finished, the process is finished.
Accordingly, the biological information is not stored in association with the inaccurate time information, and the information can be effectively used without erroneous information being used in the determination of the biological information.

Next, processing at the time display will be described.
FIG. 9 is a processing flowchart when displaying time.
First, the CPU 130 determines whether or not the time correction flag is on (step S31).
If it is determined in step S31 that the time correction flag is on, that is, if the time is corrected after the power is turned on (step S31; Yes), the obtained time information is considered to be accurate. Displays the time on the liquid crystal display unit 108 (step S32), and ends the process.

If it is determined in step S31 that the time correction flag is off, that is, if the time has not been corrected after power-on (step S31; No), the obtained time information may not be accurate. Therefore, the CPU 130 ends the process without displaying the time on the liquid crystal display unit 108 (step S33).
As a result, since the time (time information) is not displayed on the liquid crystal display unit 10, the user can easily grasp that the time has not been corrected yet, and prompt the user to correct the time. it can.

FIG. 10 is a process flowchart for automatic measurement.
First, the CPU 130 determines whether or not the time for automatic measurement of biological information has been reached (step S41).
If the time for automatic measurement of biological information has not been reached in the determination in step S41 (step S41; No), a standby state is entered.
If it is determined in step S41 that the time for automatic measurement of biological information has been reached (step S41; Yes), the CPU 130 determines whether or not the time correction flag is on (step S42).

In the determination of step S42, if the time correction flag is on, that is, if the time is corrected after power-on (step S42; Yes), the obtained time information is considered to be accurate. Measurement is started, measurement of predetermined biological information (for example, pitch, pulse rate, SPO2, etc.) is started, and time information corresponding to the biological information is stored in association with each other if necessary (step S43). ).
On the other hand, if it is determined in step S42 that the time correction flag is off, that is, if the time has not been corrected after power-on (step 42; No), the obtained time information may not be accurate. Therefore, the process ends without starting the automatic measurement of biological information.
Therefore, automatic measurement is not started based on inaccurate time information, meaningless biological information is not collected, and information can be effectively used for collected biological information. .

  As described above, according to the present embodiment, by not displaying the time, it is possible to make the user recognize that the time has not been corrected, to prompt the user to correct the time, and when the time is corrected. Since the biological information is collected in association with the time information or the measurement of the biological information is automatically started, the reliability of the collected biological information can be improved.

  In the above description, for information that becomes less important if the time is not known, such as changes in the amount of exercise as biological information, if the time is not corrected, the mode is shifted to the measurement mode. It is also possible to configure so that it is not possible or not notified.

  In the above description, when the time adjustment has not yet been performed, the time display is prohibited and the time display is not performed so that the user is prompted to correct the time. In addition, it is possible to notify the user that the time has not been corrected by sound, light, or the like.

  In the above description, the case where the control program is stored in advance in the ROM has been described. However, the control program is recorded in advance on recording media such as various magnetic disks, optical discs, memory cards, and the like. It can also be configured to read and install. It is also possible to provide a communication interface and download the control program via a network such as the Internet or LAN, and install and execute the program.

1 is a schematic configuration block diagram for explaining the principle of the present invention. It is a general | schematic block diagram of a time information determination part. It is a figure which shows the external appearance structure of the pulse measuring device as an example of the measuring device which measures the biometric information which concerns on embodiment with the aspect of the use. It is sectional drawing of the pulse measuring device of embodiment. It is a block diagram which shows the functional structure of a pulse measuring device. It is a process flowchart of a time correction flag setting process. It is a process flowchart at the time of biometric information measurement. It is explanatory drawing of the example in the case of preserve | storing a pitch and a pulse rate in association with time information. It is a process flowchart at the time of time display. It is a processing flowchart at the time of automatic measurement.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Measuring device (pulse measuring device), 11 ... Control part, 12 ... Biological information detection part, 13 ... Calculation part, 14 ... Display part, 15 ... Memory | storage part, 16 ... Time setting part, 17 ... Time correction determination part, DESCRIPTION OF SYMBOLS 18 ... Time information determination part, 18A ... Time display determination part, 18B ... Time information storage determination part, 18C ... Automatic measurement determination part, 22 ... Body motion sensor, 23 ... Pulse wave sensor, 108 ... Liquid crystal display part, 120 ... Pulse Wave signal amplifier circuit 121 ... Body motion signal amplifier circuit 122 ... A / D converter circuit 123 ... Pulse wave shaping circuit 124 ... Body motion shaping circuit 130 ... CPU 132 132 ROM 134 134 RAM 136 Clock Circuit, 138... Input unit, 140... Multiplier, 142.

Claims (12)

In a measurement device that measures biological information of a user and performs processing by associating time information with the biological information,
A time display section for displaying the time;
A time correction unit for correcting the time;
A time correction determination unit for determining whether or not a time correction corresponding to the time information has been made at a predetermined timing;
A display prohibition unit for prohibiting the time display in the time display unit when the time correction corresponding to the time information is not made at the predetermined timing;
A measuring device comprising: In a measuring device that measures user biometric information and stores it in association with time information,
A time correction determination unit for determining whether or not a time correction corresponding to the time information has been made at a predetermined timing;
A storage prohibiting unit that prohibits the biometric information and the time information from being associated and stored when the time correction corresponding to the time information is not performed at the predetermined timing;
A measuring device comprising: In the measuring device according to claim 2,
A measuring device comprising: an information storage unit that stores the biological information and the elapsed time from the measurement start time in association with each other when the time correction corresponding to the time information is not performed at the predetermined timing . In the measuring device according to claim 2,
A measuring apparatus comprising: a biometric information storage prohibiting unit that prohibits storage of the biometric information when the time corresponding to the time information is not corrected at the predetermined timing. In a measuring device that measures user biometric information and stores it in association with time information,
A time correction determination unit that determines whether or not a time correction corresponding to the time information has been made at a predetermined timing;
A measurement prohibition unit that prohibits measurement of the biological information when time correction corresponding to the time information is not made at the predetermined timing;
A measuring device comprising: In a measurement device that measures biological information of a user and performs processing by associating time information with the biological information,
An automatic measurement unit that measures biological information at an automatic measurement timing specified in advance;
A time correction determination unit for determining whether or not a time correction corresponding to the time information has been made at a predetermined timing;
An automatic measurement prohibition unit that prohibits an automatic measurement operation in the automatic measurement unit when the time correction corresponding to the time information is not made at the predetermined timing;
A measuring device comprising: In a control method of a measurement apparatus, comprising a time display unit for displaying time and a time correction unit for performing time correction, measuring biological information of a user, and performing processing by associating time information with the biological information.
A time correction determination process for determining whether or not a time correction corresponding to the time information has been made at a predetermined timing;
A display prohibiting process for prohibiting time display in the time display unit when time correction corresponding to the time information is not performed at the predetermined timing;
A control method for a measuring apparatus, comprising: In a control method of a measurement device that measures a user's biological information and stores it in association with time information,
A time correction determination process for determining whether or not a time correction corresponding to the time information has been made at a predetermined timing;
A storage prohibiting step for prohibiting the biometric information and the time information from being associated and stored when the time correction corresponding to the time information is not made at the predetermined timing;
A control method for a measuring apparatus, comprising: In a measurement device that measures biological information of a user and performs processing by associating time information with the biological information,
An automatic measurement process for measuring biological information at an automatic measurement timing specified in advance;
A time correction determination process for determining whether or not a time correction corresponding to the time information has been made at a predetermined timing;
An automatic measurement prohibiting process for prohibiting an automatic measurement operation in the automatic measurement process when the time correction corresponding to the time information is not made at the predetermined timing;
A control method for a measuring apparatus, comprising: A time display unit that displays time and a time correction unit for performing time correction, and measures a user's biological information and controls a measurement device that performs processing by associating the biological information with time information. Control program for
It is determined whether or not the time correction corresponding to the time information has been made at a predetermined timing,
Prohibiting time display in the time display unit when time correction corresponding to the time information is not made at the predetermined timing,
A control program characterized by that. In a control program for measuring a user's biological information and controlling the measurement device that is stored in association with time information by a computer,
It is determined whether or not the time correction corresponding to the time information has been made at a predetermined timing,
When the time corresponding to the time information is not corrected at the predetermined timing, it is prohibited to store the biometric information and the time information in association with each other.
Control program characterized by comprising In a control program for measuring a user's biological information and controlling a measurement device that performs processing by associating time information with the biological information by a computer,
When measuring biological information at a pre-specified automatic measurement timing, it is determined whether or not a time correction corresponding to the time information has been made at a predetermined timing,
When the time correction corresponding to the time information is not made at the predetermined timing, the automatic measurement operation in the automatic measurement process is prohibited.
A control program characterized by that.

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