KR101094163B1 - Apparatus and method for measuring blood pressure using proximity sensor - Google Patents

Abstract

PURPOSE: A blood pressure measurement apparatus which uses a proximity sensor and a method thereof are provided to use the proximity sensor generating a signal when a part of a human body of a measured person is touched, thereby automatically starting blood pressure measurement without the manipulation of a user. CONSTITUTION: A proximity sensor part(630) detects a body part of a measured person and outputs a signal. A blood pressure measurement part(610) measures the blood pressure of the measured person while being touched to a measurement part of the measured person. A control part(620) receives a signal outputted from the proximity sensor part. The control part controls the operation of the blood pressure measurement part. The control part processes a result of blood pressure measurement. A display part(650) outputs the result of the blood pressure measurement.

Description

Apparatus and method for measuring blood pressure using a proximity sensor {APPARATUS AND METHOD FOR MEASURING BLOOD PRESSURE USING PROXIMITY SENSOR}

The embodiments below relate to a method and apparatus for measuring blood pressure using a proximity sensor.

An apparatus and method are disclosed for recognizing a subject by a proximity sensor and initiating a blood pressure measurement.

Blood pressure is a measure of the pressure of blood on the walls of blood vessels.

The human heart repeats approximately 60 contractions and expansions per minute.

"Shrinkage blood pressure" refers to the pressure on the blood vessels as the heart contracts and pushes the blood. Constrictive blood pressure is the highest blood pressure. Thus, systolic blood pressure is called "highest blood pressure".

"Relaxation blood pressure" refers to the pressure maintained in the blood vessels as the image expands and receives blood. Relaxed blood pressure is the lowest blood pressure. Thus, relaxation blood pressure is called "lowest blood pressure".

Generally, for a normal person, the systolic blood pressure is 120 mmHg and the relaxation blood pressure is 80 mmHg.

Hypertension, on the other hand, can be a cause of other life-threatening complications such as eye disease, kidney disease, arterial disease, brain disease, and heart disease.

Therefore, continuous measurement and management of blood pressure should be performed on the patients who show symptoms of such complications.

In addition, even for a person without complications, regular blood pressure measurement and management need to be performed to confirm the physical condition.

A blood pressure measuring device (abbreviated as a blood pressure monitor) is used as a device for measuring such blood pressure.

The blood pressure measuring device first blocks the flow of blood by pressing the blood pressure measuring part of the subject. The blood pressure measuring device measures the pressure by detecting a pulse sound or a pulse vibration generated while the flow of blood flow starts to resume while gradually decreasing the degree of compression after the above blocking time.

In the past, the cuff was attached to the body of the subject, and the subject was pumped directly or by a subject such as a nurse, and the blood pressure was measured by reading the changed mercury scale.

Recently, an automatic blood pressure measuring device which automatically performs the above blood pressure measuring process is mainly used.

The automatic blood pressure measuring device inserts a body part into a cuff and presses a start button, and performs a blood pressure measuring process by itself and outputs the measured blood pressure through a display screen or voice.

One embodiment of the present invention may provide an apparatus and method for starting blood pressure measurement using a proximity sensor that generates a signal when a part of a body of a subject is in contact.

One embodiment of the present invention may provide an apparatus and method for enabling a subject to take a correct measurement posture by using a proximity sensor.

One embodiment of the present invention can provide an apparatus and method for supplying the driving power required for blood pressure measurement by using a proximity sensor.

According to one aspect of the present invention, in the blood pressure measuring device, the proximity sensor unit for recognizing the body part of the subject to output a signal, the blood pressure for measuring the blood pressure of the subject in contact with the measuring part of the body of the subject And a control unit for controlling an operation of the measuring unit and the blood pressure measuring unit and processing a result of the blood pressure measurement, wherein a position in the blood pressure measuring device of the proximity sensor unit allows the subject to contact the measuring unit with the blood pressure measuring unit. When the body part of the subject is in close contact when the posture is taken, the control unit is provided with a blood pressure measuring device for controlling the operation of the blood pressure measuring unit in response to receiving the signal output from the proximity sensor unit.

The blood pressure measuring device may further include a display unit configured to output a result of the blood pressure measurement.

The measurement site and the body part may be journals in the limbs of the subject.

The measurement site may be a specific area of the arm of the subject. The body part may be an elbow of the subject.

The controller may control the blood pressure measuring unit to perform the blood pressure measurement in response to receiving the signal output from the proximity sensor unit.

The controller may determine whether the subject takes the correct measurement posture based on the signal, and control the operation of the blood pressure measuring unit based on the determination.

The blood pressure measuring apparatus may further include a display unit configured to receive and output a message according to the determination from the controller.

The proximity sensor unit may include a plurality of proximity sensors.

Each of the plurality of proximity sensors may be located where the body part of the subject is in close contact with the subject when the subject is in a position to contact the measuring unit with the blood pressure measuring unit.

The blood pressure measuring unit detects a cuff wound around the measurement part of the subject, a pressure adjusting unit for raising or lowering the pressure inside the cuff, and a pressure inside the cuff, based on the detected pressure inside the cuff. It may include a pulse wave detection unit for detecting.

The cuff may wind a specific portion of the arm of the subject.

The proximity sensor may be mounted at a lower end of the position where the elbow of the subject in the cuff is placed.

The proximity sensor unit may detect whether the elbow has reached the correct position in the cuff and output the signal.

The blood pressure measuring apparatus may further include a power supply unit supplying power to the blood pressure measuring apparatus.

The controller may control the power supply unit to convert the power supplied by the power supply unit from standby power to operating power based on the signal.

According to another aspect of the present invention, in the operation method of the measuring device, the blood pressure measuring device is measured by the operation of recognizing the body part of the subject to output a signal and the proximity sensor outputs the signal; And measuring the blood pressure, wherein the proximity sensor is attached to a position at which the body part of the subject is in close contact when the subject of the blood pressure measuring apparatus is in a position to measure blood pressure through the blood pressure measuring apparatus. A blood pressure measurement method is provided.

The blood pressure measuring method may further include displaying the measured blood pressure of the measured subject.

The body part may be an elbow of the subject.

The proximity sensor may output the signal when the subject takes the correct measurement posture.

There may be a plurality of proximity sensors.

The measuring of the blood pressure of the subject may include adjusting a pressure inside the cuff wound around the measuring part of the subject, detecting a pressure inside the cuff, and detecting a pulse wave based on the detected pressure inside the cuff. It may include an operation to.

The cuff may wind a specific portion of the arm of the subject.

The proximity sensor may be mounted at a lower end of the position where the elbow of the subject in the cuff is placed.

The blood pressure measuring method may further include an operation of converting power supplied from the standby power into operating power as the proximity sensor outputs a signal.

According to another aspect of the present invention, in the biometric information measuring apparatus, the proximity sensor unit for recognizing a body part of the subject to output a signal, the biometric information of the subject by measuring in contact with the measurement site of the subject And a controller configured to control an operation of the biometric information measuring unit and the biometric information measuring unit, and to process a result of the biometric information measurement. Where the body part of the subject is in close contact when the posture for contacting the biometric unit, the control unit controls the operation of the biometric information measuring unit in response to receiving the signal output from the proximity sensor unit, A biometric information measuring apparatus is provided.

According to another aspect of the present invention, in the operation method of the biometric information measuring device, the proximity sensor recognizes the body part of the subject to output the signal and the proximity sensor outputs the signal as the proximity sensor outputs the signal A measuring device measures the biometric information of the subject, and the proximity sensor is configured to measure the biometric information when the subject is measured to perform biometric information through the biometric information measuring apparatus. Provided is a method of measuring biometric information attached to a location where the body part of the measurer is in close contact.

By providing an apparatus and method for starting blood pressure measurement using a proximity sensor that generates a signal when a part of the body of the subject is in contact, the blood pressure measurement can be automatically started without user intervention.

By providing an apparatus and a method for determining a measurement posture of a subject by an output signal of a proximity sensor, the subject can take a correct measurement posture.

By providing an apparatus and a method for automatically supplying the driving power required for blood pressure measurement by the output signal of the proximity sensor, blood pressure measurement can be automatically started without user's operation, and power consumption can be reduced.

1 illustrates a configuration of a general blood pressure measuring apparatus 100 according to an example of the present invention.
2 is a cross-sectional view illustrating an apparatus for measuring blood pressure using a proximity sensor according to an embodiment of the present invention.
3 is a cross-sectional view illustrating an apparatus for measuring blood pressure using a proximity sensor according to an embodiment of the present invention.
4 is a cross-sectional view illustrating an apparatus for measuring blood pressure using a plurality of proximity sensors according to an embodiment of the present invention.
5 is a cross-sectional view illustrating an apparatus for measuring blood pressure using a plurality of proximity sensors according to an embodiment of the present invention.
6 is a structural diagram of a blood pressure measuring device 600 according to an embodiment of the present invention.
7 is a flowchart illustrating a method of operating the blood pressure measuring apparatus 600 according to an embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited or limited by the embodiments. Like reference numerals in the drawings denote like elements.

1 illustrates a configuration of a general blood pressure measuring apparatus 100 according to an example of the present invention.

The main body 110, the cuff 120, the display 130, and the operation buttons 140 of the blood pressure measuring apparatus 100 are illustrated.

In addition, the blood pressure measuring apparatus 100 may include an air tube, a pumping unit, a pressure sensor, a controller, and the like. (Not shown)

Through-holes may be formed in the main body 110 in the front-rear direction. The through hole is formed to be large enough to accommodate a portion of the subject's body, such as an arm.

The main body 110 may have a display unit 130 that displays the measured blood pressure numerically. In addition, the main body 110 may be provided with a sound output unit (ie, a speaker) (not shown) in place of the display unit 130 or together with the display unit 130.

The cuff 120 is disposed in the through hole of the main body 110. Therefore, the cuff 120 may accommodate a part of the body of the subject.

An air tube may be provided inside the cuff 120. The air tube is pumped by the pumping part to press a part of the body of the subject.

The pumping part contracts and expands the air tube. The pumping part 140 is connected to the air tube 130 through a hose. The pumping unit may pressurize the air to the air tube, and may reduce the pressure by removing the air injected into the air tube. For this operation, the pumping unit may have a step valve and an exhaust valve. (Not shown)

The step valve allows the air tube to be retracted in stages.

The exhaust valve allows air to escape from the air tube, allowing the air tube to depressurize at a constant rate.

The pressure sensor measures the pressure of the air tube.

The pressure sensor may measure the vibration of the cuff 120 pressure generated by the pulsation of the artery of the subject.

The operation button unit 140 may be disposed on an outer surface of the main body 110.

The operation button unit 140 allows the subject to operate the blood pressure measuring apparatus 100 to perform a desired operation.

The operation button unit 140 may include two or more buttons 142 and 144.

Each of the buttons 142 and 144 may cause the blood pressure measuring apparatus 100 to perform a different operation.

For example, the upper button 144 may be a start button for causing the blood pressure measuring apparatus 100 to start a blood pressure measuring operation. In addition, the lower button 144 may allow the blood pressure measuring device 100 to emergency stop the blood pressure measuring operation.

The start button is a button for causing the blood pressure measuring apparatus 100 to start the blood pressure measuring process. When the subject inserts his arm into the cuff 120 and presses the start button, the controller recognizes that the start button is pressed and proceeds with the blood pressure measurement process.

The emergency stop button is a button for temporarily stopping the air tube from being pressurized by the pumping part or discharging air from the air tube. When the cuff 120 excessively presses a part of the body of the subject, the subject may press the emergency stop button. The controller may recognize that the emergency stop button has been pressed and block the supply of air to the air tube, or may discharge the air from the air tube.

The subject can operate the operation button unit 140 (eg, by pressing the buttons 142 and 144) to cause the blood pressure measuring apparatus 100 to start the blood pressure measuring operation.

The controller calculates the blood pressure from the pressure values input to the pressure sensor while controlling the pumping unit 140 in response to the operation signal from the operation button unit 140.

As an example of calculating the blood pressure, when the air tube is compressed, the controller may extract the pulse wave component of the artery through a filter and calculate the blood pressure using a predetermined algorithm.

Hereinafter, an example of a process of measuring a blood pressure in the blood pressure measuring apparatus 100 by a person to be measured will be described.

The subject inserts his arm into the cuff 120 and presses the operation button 142 or 144.

The controller drives the pumping unit to gradually increase the pressure of the air tube, that is, the pressure of the cuff 120 (that is, the cuff pressure).

When the arm of the subject is pressed step by step, and the pressure of the cuff 120 reaches the size for blood pressure measurement, the controller stops pumping the pumping part and gradually discharges the air in the air tube to increase the pressure of the cuff 120. Gradually decrease.

Blood pressure is measured while the pressure of the cuff 120 is reduced.

The measured blood pressure may be output to the display unit 130 to be checked by the subject.

When using the blood pressure measuring device 100, the subject should take a measurement posture so that the measurement site is horizontal with the heart for accurate blood pressure measurement.

In addition, even while blood pressure measurement is performed by pressurizing and depressurizing the cuff attached to the arm, the subject must maintain the posture so that the measurement site and the heart are horizontal to each other. When the measurement posture of the subject is incorrect and the measurement region and the heart are not horizontal to each other, or when the subject moves, noise due to movement affects the measurement result, so that the blood pressure measuring apparatus 100 cannot obtain accurate measurement values. Because.

In order to induce the subject to take the correct measurement posture, an arm rest in a concave elbow portion may be used.

However, even when the arm holder is used, the measurement may be started while the elbow is not in close contact with the concave portion, and the arm may not be fixed while pressing the cuff.

For this reason, the measurement posture of the subject becomes unstable and the subject can move. Therefore, noise may be applied to the pulse wave detected in the blood pressure measurement process, so that the blood pressure measuring apparatus 100 may not detect the accurate pulse wave and the blood pressure.

Therefore, in order to solve the problem as described above, it is necessary to induce the subject's elbow to be in a predetermined position so that the subject can take an appropriate measurement posture.

In order to solve this problem, a method may be considered in which a load detection unit is placed at an elbow to guide the elbow to a predetermined position so that the subject can take an appropriate measurement posture.

In this method, the load detection unit can confirm the load within a predetermined range before the measurement, and the blood pressure measuring device may not start the blood pressure measurement until the load is confirmed within the prescribed range.

However, in this case, load cells and electronic devices for load detection must be added mechanically.

Therefore, this type of blood pressure measuring device is difficult to manufacture, causing a problem that the mass production cost for the production is increased.

In addition, since the measurer must consciously weigh the elbow, this type of blood pressure measuring device may cause the subject to take an uncomfortable posture and cause a problem that causes the subject's movement during the measurement. .

2 is a cross-sectional view illustrating an apparatus for measuring blood pressure using a proximity sensor according to an embodiment of the present invention.

Therefore, in the blood pressure measuring apparatus according to an exemplary embodiment of the present invention, the proximity sensor 210 is attached to the elbow portion of the cuff 200 so that the measurement is started by simply putting the arm lightly into the cuff 200. .

Thus, the measurement can be initiated when the proximity sensor 210 recognizes that the elbow of the subject is in the proper position.

This method has advantages in that it is easier to manufacture than the above-described load detection unit and the mass production cost for the production can be lowered.

Furthermore, since the proximity sensor 210 is located at the position where the elbow is closest to the structure when the arm is placed in the cuff 200, the blood pressure measuring device having such a structure allows the subject to consciously force the arm. There is no need for the subject to be naturally in an optimal position.

3 is a cross-sectional view illustrating an apparatus for measuring blood pressure using a proximity sensor according to an embodiment of the present invention.

The proximity sensor 210 may be mounted outside the cuff 200.

When the subject passes the arm into the cuff 200, the elbow of the subject is in close contact with the proximity sensor 210 attached to the cradle 300.

Thus, the blood pressure measuring device may start the blood pressure measuring process only by the subject inserting the arm into the cuff 200.

4 is a cross-sectional view illustrating an apparatus for measuring blood pressure using a plurality of proximity sensors according to an embodiment of the present invention.

A plurality of proximity sensors 410 and 420 may be mounted inside the cuff 200.

When the subject inserts the arm into the cuff 200, the elbow and the cuff of the subject are in close contact with the first proximity sensor 410 and the second proximity sensor 420 attached to the cuff, respectively.

Thus, the blood pressure measuring device may start the blood pressure measuring process only by the subject inserting the arm into the cuff 200.

In addition, by using the plurality of proximity sensors 410 and 420, it is possible to induce the user to take a more accurate posture, and the accuracy of the operation can be improved.

5 is a cross-sectional view illustrating an apparatus for measuring blood pressure using a plurality of proximity sensors according to an embodiment of the present invention.

Some of the plurality of proximity sensors 410 and 420 may be mounted outside the cuff 200.

When the subject passes the arm into the cuff 200, the elbow and the cuff of the subject are in close contact with the first proximity sensor 410 and the second proximity sensor 420 attached to the cradle 300, respectively.

6 is a structural diagram of a blood pressure measuring device 600 according to an embodiment of the present invention.

The blood pressure measuring apparatus 600 may include a blood pressure measuring unit 610, a control unit 620, a proximity sensor unit 630, a power supply unit 640, and a display unit 650.

The proximity sensor 630 outputs a signal when the object is in proximity.

The blood pressure measuring unit 610 contacts the measurement part of the body of the subject, and measures the blood pressure of the subject.

The position in the blood pressure measuring device 600 of the proximity sensor unit 630 is a place where the proximity part of the body of the subject approaches when the subject takes a posture for contacting the measurement site with the blood pressure measuring unit 610. to be.

For example, the measurement site and the proximal site may be journals in the limbs of the subject. Specifically, the measurement site may be the arm of the subject and the proximal site may be the elbow of the subject.

The measurement site is a site targeted for blood pressure measurement, and the proximity site is a site that comes close to (or contacts with) the proximity sensor unit 630 when the subject takes a correct posture for blood pressure measurement.

The controller 620 controls the operation of the blood pressure measuring unit 610 and processes the result of blood pressure measurement.

The display unit 650 outputs the result of blood pressure measurement.

The controller 620 may control the operation of the blood pressure measuring unit 610 according to the signal output from the proximity sensor unit 630.

That is, the controller 620 may control the blood pressure measuring unit 610 to perform (or start) blood pressure measurement in response to the signal output from the proximity sensor unit 630.

For example, the controller 620 may control the blood pressure measuring unit 610 to perform (or start) blood pressure measurement when the signal indicating that the body of the subject is close is received from the proximity sensor unit 630. . In addition, when the controller 620 receives a signal indicating that the subject's body is not in proximity from the proximity sensor unit 630, the controller 620 may control the blood pressure measuring unit 610 to end (or emergency stop) the blood pressure measurement. Can be.

The proximity sensor unit 630 may include information on whether the measured person has taken the correct measurement posture in the signal. Accordingly, the controller 620 may determine whether the subject takes the correct measurement posture based on the signal output from the proximity sensor unit 630, and control the operation of the blood pressure measuring unit 610 based on the determination. can do.

In this case, the display unit 650 may receive and output a message according to the determination from the control unit 620. Thus, information about whether the correct measurement posture is taken can be fed back to the subject.

The proximity sensor unit 630 may include a plurality of proximity sensors.

Each of the plurality of proximity sensors is a part of the body of the subject (eg, elbow or cuff) when the subject takes a posture for contacting the measurement site with the blood pressure measuring unit 610.

The controller 620 may control an operation of the blood pressure measuring unit 610 based on signals output from the plurality of proximity sensors. For example, the controller 620 may control the blood pressure measuring unit 610 to perform (or start) blood pressure measurement when all of the plurality of proximity sensors receive signals indicating that the subject's body is in proximity. .

The blood pressure measuring unit 610 may include a cuff 612, a pressure adjusting unit 614, and a pulse wave detecting unit 616.

The cuff 612 winds up the measurement site of the subject. Specifically, the cuff may wind the arm of the subject.

The pressure regulator 614 raises or lowers the pressure inside the cuff 612.

The pulse wave detector 616 detects a pressure inside the cuff 612 and detects a pulse wave based on the detected pressure inside the cuff 612.

The proximity sensor unit 630 may be mounted at the lower end of the position where the elbow of the subject in the cuff 200 is placed.

The proximity sensor 630 may detect whether the elbow of the subject reaches the correct position in the cuff 200 and output a signal.

The power supply unit 640 supplies power to the blood pressure measuring device 600. The power supply unit 640 may be divided into standby power or operating power to supply the blood pressure measuring device 600. Standby power is power supplied to the blood pressure measuring apparatus 600 when the blood pressure measuring apparatus 600 does not perform blood pressure measurement. The operating power is power supplied to the blood pressure measuring apparatus 600 when the blood pressure measuring apparatus 600 is performing blood pressure measurement.

The controller 630 may control the power supply unit 640 such that the power supplied by the power supply unit 640 is converted from standby power to operating power based on the signal output from the proximity sensor unit 630.

Technical contents according to an embodiment of the present invention described above with reference to FIGS. 1 to 5 may be applied to the present embodiment as it is. Therefore, more detailed description will be omitted below.

7 is a flowchart illustrating a method of operating the blood pressure measuring apparatus 600 according to an embodiment of the present invention.

In operation 710, the proximity sensor (ie, the proximity sensor unit) outputs a signal as the proximity portion of the subject is approached.

The proximity sensor may be attached to a position in which the proximity region of the subject comes close when the subject takes a posture to measure blood pressure through the blood pressure measurement apparatus.

The proximity sensor can only output a signal if the subject takes the correct measurement position.

There may be a plurality of proximity sensors.

The measurement site can be the elbow of the subject.

In operation 720, power supplied to the blood pressure measuring apparatus 600 is converted from standby power to operating power as the proximity sensor outputs a signal.

In operation 730, the blood pressure measuring apparatus 600 measures the blood pressure as the proximity sensor outputs a signal.

Operation 730 includes 1) adjusting the pressure inside the cuff 612 winding the measurement site of the subject, 2) detecting the pressure inside the cuff 612 and 3) inside the detected cuff 612. The operation may include detecting a pulse wave of the subject based on the pressure.

In operation 740, the measured blood pressure is displayed.

In operation 750, the measurement ends.

In operation 750, the power supplied to the blood pressure measuring apparatus 600 may be converted from operating power to standby power.

Technical contents according to an embodiment of the present invention described above with reference to FIGS. 1 to 6 may be applied to the present embodiment as it is. Therefore, more detailed description will be omitted below.

The technical idea described through the above-described examples and one embodiment of the present invention may be extended to a general biometric information measuring device, not a blood pressure measuring device.

That is, the blood pressure of the subject may be replaced by biometric information, the blood pressure measuring apparatus 600 and the method may be replaced by the biometric information measuring apparatus, and the blood pressure measuring unit 610 may be replaced by the biometric information measuring unit. have.

The biometric information measuring unit may refer to any device for measuring the body information of the subject by being attached, inserted or adhered to the body of the subject, such as an electrode or an invasive tool.

Method according to an embodiment of the present invention is implemented in the form of program instructions that can be executed by various computer means may be recorded on a computer readable medium. The computer readable medium may include program instructions, data files, data structures, etc. alone or in combination. Program instructions recorded on the media may be those specially designed and constructed for the purposes of the present invention, or they may be of the kind well-known and available to those having skill in the computer software arts. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks, and magnetic tape, optical media such as CD-ROMs, DVDs, and magnetic disks, such as floppy disks. Magneto-optical media, and hardware devices specifically configured to store and execute program instructions, such as ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine code generated by a compiler, but also high-level language code that can be executed by a computer using an interpreter or the like. The hardware device described above may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above embodiments, and those skilled in the art to which the present invention pertains various modifications and variations from such descriptions. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the claims below but also by the equivalents of the claims.

600: blood pressure measuring device
610: blood pressure measuring unit
620: control unit
630: proximity sensor

Claims (22)

In the blood pressure measuring device,
A proximity sensor unit configured to recognize a body part of the subject and output a signal;
A blood pressure measuring unit measuring the blood pressure of the subject by contacting the measurement site of the subject; And
Control unit for controlling the operation of the blood pressure measuring unit and processing the result of the blood pressure measurement
And a position in the blood pressure measuring device of the proximity sensor unit is a place where the body part of the subject is in close contact when the subject takes a posture for contacting the measuring unit with the blood pressure measuring unit. Is controlling the operation of the blood pressure measuring unit in response to receiving the signal output from the proximity sensor. The method of claim 1,
Display unit for outputting the result of the blood pressure measurement
Further comprising a blood pressure measuring device. The method of claim 1,
And said measuring part and said body part are diaries in the extremities of said subject. The method of claim 3,
And the measuring part is a specific part of the arm of the subject and the body part is an elbow of the subject. The method of claim 1,
The control unit controls the blood pressure measuring unit to perform the blood pressure measurement in response to receiving the signal output from the proximity sensor unit. The method of claim 1,
The controller determines whether the measured person has taken the correct measurement posture based on the signal, and controls the operation of the blood pressure measuring unit based on the determination. The method of claim 6,
A display unit for receiving and outputting a message according to the determination from the control unit
Further comprising a blood pressure measuring device. The method of claim 1,
The proximity sensor unit includes a plurality of proximity sensors,
And said plurality of proximity sensors are each located where the body part of the subject is in close contact when the subject is in a position to contact the measurement site with the blood pressure measuring unit. The method of claim 1,
The blood pressure measuring unit,
A cuff wound around the measurement site of the subject;
A pressure adjusting unit which raises or lowers the pressure inside the cuff; And
Pulse wave detection unit for detecting the pressure inside the cuff, and detects the pulse wave based on the detected pressure inside the cuff
Comprising a blood pressure measuring device. 10. The method of claim 9,
The cuff is wound around a specific part of the arm of the subject,
And the proximity sensor unit is mounted at a lower end of the position where the elbow of the subject in the cuff is placed. The method of claim 10,
And the proximity sensor unit outputs the signal by detecting whether the elbow has reached a correct position in the cuff. The method of claim 1,
Power supply unit for supplying power to the blood pressure measuring device
Further comprising:
The controller controls the power supply unit to convert the power supplied by the power supply unit from standby power to operating power based on the signal. In the operation method of the blood pressure measuring device,
Recognizing a body part of the subject and outputting a signal by the proximity sensor; And
The blood pressure measuring device measures the blood pressure of the subject as the proximity sensor outputs the signal
Including,
And the proximity sensor is attached to a position at which the body part of the subject is in close contact with the subject when the subject is in a position to measure blood pressure through the blood pressure measuring apparatus. The method of claim 13,
Displaying the blood pressure of the measured subject
Further comprising, blood pressure measurement method. The method of claim 13,
And said body part is the elbow of said subject. The method of claim 13,
And the proximity sensor outputs the signal when the subject takes the correct measurement posture. The method of claim 13,
The proximity sensor is a plurality of individuals, blood pressure measuring method. The method of claim 13,
The operation of measuring the blood pressure of the subject,
Adjusting the pressure inside the cuff that winds the measurement site of the subject;
Detecting a pressure inside the cuff; And
Detecting a pulse wave based on the pressure inside the detected cuff
Including, blood pressure measurement method. The method of claim 18,
The cuff is wound around a specific part of the arm of the subject,
And the proximity sensor is mounted at a lower end of the position where the subject's elbow is placed in the cuff. The method of claim 13,
As the proximity sensor outputs a signal, the power supplied to the blood pressure measuring device is converted from standby power to operating power
Further comprising, blood pressure measurement method. In the biometric information measuring apparatus,
A proximity sensor unit configured to recognize a body part of the subject and output a signal;
A biometric information measuring unit measuring biometric information of the subject by contacting a measurement site of the subject; And
Control unit for controlling the operation of the biometric information measuring unit and processing the results of the biometric information measurement
Wherein the position in the biometric information measuring device of the proximity sensor unit is where the body part of the subject is in close contact when the subject takes a posture for contacting the measuring unit with the biometric unit, The control unit controls the operation of the biometric information measuring unit in response to receiving the signal output from the proximity sensor unit. In the operation method of the biometric information measuring device,
Recognizing a body part of the subject and outputting a signal by the proximity sensor; And
The biometric information measuring device measuring the biometric information of the subject as the proximity sensor outputs the signal
Including,
The proximity sensor is attached to a position at which the body part of the subject is in close contact when the subject of the biometric information measuring apparatus takes a posture for measuring biometric information through the biometric information measuring apparatus. .

Images