KR20200064049A - Virtual pulse apparatus and pulse measuring test apparatus for sensor of pulse measuring using the same - Google Patents

Abstract

The present invention relates to a simulated pulse wave generating apparatus and a test apparatus for a pulse wave measuring apparatus using the same. According to the present invention, a pulse wave generating unit that comes in contact with a pulse wave measuring sensor to be tested is linearly reciprocated by a linear movement device for generating pulse waves, and a predetermined simulated pulse wave is generated. Therefore, performance of the pulse wave measuring sensor can be accurately tested, thereby reducing a defect rate of the pulse wave measuring sensor. In addition, accuracy of the pulse wave measuring sensor is improved, and the accuracy of a diagnostic device and reliability of diagnosis results of the diagnostic device can be improved. The simulated pulse wave generating apparatus includes the pulse wave generating unit, the linear movement device for generating the pulse waves, and a movement device for horizontal position adjustment.

Description

VIRTUAL PULSE APPARATUS AND PULSE MEASURING TEST APPARATUS FOR SENSOR OF PULSE MEASURING USING THE SAME}

The present invention relates to a simulated pulse wave generating device, and more particularly, to a simulated pulse wave generating device capable of evaluating the performance of a pulse wave measuring sensor and a test device for a pulse wave measuring device using the simulated pulse wave generating device.

In general, arterial stiffness is an important index for evaluating cardiovascular function, and an existing method capable of non-invasively measuring vascular stiffness in the radial artery is eco-tracking that measures changes in the diameter of the radial arteries of the systolic and diastolic ( There are two methods: echotracking) and pulse wave measurement based on the tonometry principle.

The eco-tracking method has a resolution of 1 μm, which is about 1/100 of that of an ultrasonic imaging device, but it is very expensive and practically difficult to use in clinical practice, whereas equipment based on the principle of tonometry measurement is easy to measure and relatively Because it is cheap, it is widely used.

In addition, the development and commercialization of diagnostic devices based on the tonometry technique among technologies for cardiovascular diagnosis and blood pressure measurement have been actively conducted.

The tonometry pulse wave analysis device applies a pressure to the corresponding area after vertically touching a measurement sensor (usually using an array pressure sensor) to the blood vessel site at the blood vessel site to be measured, and then changing the internal pressure. It is a reading device.

To increase the accuracy of the tonometry pulse wave analysis device, the pulse wave measurement sensor must accurately locate the blood vessel to be measured and apply pressure accurately to the pulse wave signal.

Accordingly, the accuracy of the pulse wave measurement sensor in the tonometry pulse wave analysis device, that is, the signal quality of the measurement device is directly related to the diagnosis result, and thus the performance of the pulse wave measurement sensor in the tonometry pulse wave analysis device is evaluated. It is a situation that requires a test equipment.

Korean Registered Patent No. 1048292'Pressure sensor array for measuring pulse wave and its manufacturing method' (2011.07.05.registered)

An object of the present invention is to provide a simulated pulse wave generator capable of accurately testing the performance of a pulse wave measurement sensor and a test device for a pulse wave measuring device using the same.

Another object of the present invention is to provide a simulated pulse wave generator and a test apparatus for pulse wave measuring devices using the same, which can accurately test the performance of the pulse wave measuring sensor to improve the accuracy of the diagnostic device and reliability of the diagnostic device. .

In order to achieve the above object, an embodiment of the simulated pulse wave generator according to the present invention is a pulse wave generator to which the pulse wave measurement sensor under test is contacted, and a linear mobile device for pulse wave generation to linearly reciprocate the pulse wave generator forward and backward. And it characterized in that it comprises a mobile device for horizontal position adjustment that can move the position of the pulse wave generator in the left and right directions.

One embodiment of the simulated pulse wave generator according to the present invention may further include a vertical movement device that can move the position of the pulse wave generator up and down.

In order to achieve the above object, an embodiment of a test apparatus for a pulse wave measuring device according to the present invention is a pulse wave generating unit to which a pulse wave measuring sensor as a test object is contacted, and a straight line for pulse wave generating a linear reciprocating movement of the pulse wave generating unit forward and backward. A mobile device, a horizontal position adjusting mobile device capable of moving the position of the pulse wave generating unit in the left and right directions, and a pulse wave generating control unit controlling the operation of the linear mobile device for generating pulse waves to generate a predetermined simulated pulse wave signal, and And a main control unit connected to the pulse wave generation control unit and the simulated pulse wave generation device to receive a measured pulse wave signal and a simulated pulse wave signal measured from the pulse wave measurement sensor and output a measured pulse wave signal and a simulated pulse wave signal. The display may include a display panel unit capable of outputting the measured pulse wave signal and the simulated pulse wave signal to a screen.

The present invention is capable of accurately testing the performance of the pulse wave measuring sensor, thereby reducing the defect rate of the pulse wave measuring sensor and improving the accuracy of the pulse wave measuring device including the pulse wave measuring sensor.

There is an effect of accurately testing the performance of the pulse wave measuring device including the pulse wave measuring sensor of the present invention to improve the accuracy of the diagnostic device and reliability of the diagnostic device.

In the present invention, the pulse wave measurement sensor can test the accuracy of the pulse rate, the accuracy of the pressing force, the accuracy of the measurement pressure, the accuracy of the blood vessel position, and the accuracy of acquiring a three-dimensional pulse image of the measurement site. It has a beneficial effect.

1 is a perspective view showing a simulated pulse wave generator according to the present invention.
Figure 2 is a side view of a simulated pulse wave generator according to the present invention.
3 is a front view of a simulated pulse wave generator according to the present invention.
4 is a schematic diagram of a test apparatus for a pulse wave measuring instrument according to the present invention.

The present invention will be described in more detail.

If described in detail by the accompanying drawings, preferred embodiments of the present invention. Prior to the detailed description of the present invention, terms or words used in the present specification and claims described below should not be interpreted as being limited to a conventional or dictionary meaning. Therefore, the configuration shown in the embodiments and drawings described in this specification are only the most preferred embodiments of the present invention and do not represent all of the technical spirit of the present invention, and thus can replace them at the time of application. It should be understood that there may be equivalents and variations.

1 is a perspective view showing a simulated pulse wave generator according to the present invention, FIG. 2 is a side view of the simulated pulse wave generator according to the present invention, and FIG. 3 is a front view of the simulated pulse wave generator according to the present invention.

1 and 2, the simulated pulse wave generator according to the present invention includes a pulse wave generator 100 to which the pulse wave measurement sensor 10 to be tested is contacted.

The pulse wave generating unit 100 is linearly reciprocated by the linear moving device 200 for generating pulse waves to generate simulated pulse waves sensed by the pulse wave measuring sensor 10 to be tested.

The pulse wave generating linear moving device 200 allows a predetermined pulse wave similar to a human pulse wave to be generated by the pulse wave generator 100 while changing the linear reciprocating range.

The simulated pulse wave generation apparatus according to the present invention further includes a pulse wave generation control unit 300 for controlling the operation of the linear mobile device 200 for generating pulse waves to generate a preset simulated pulse wave signal to the pulse wave measurement sensor 10. can do.

The pulse wave generator 100 has an area in which the pulse wave measuring sensor 10, which is a test object, can be contacted, and the sensor support member 110 and the sensor support member 110 linearly reciprocated by the pulse wave generating linear moving device 200 ) Is located in front of the contact area detection sensor 120 for sensing the area in contact with the pulse wave measurement sensor 10, the elastic pad member located between the contact area detection sensor 120 and the sensor support member 110 ( 130).

The elastic pad member 130 is a silicone pad having a hardness similar to that of the human skin and maintains the same test environment as when it comes into contact with the skin, so that it can generate pulse waves similar to those detected by the human body.

In addition, the contact area detection sensor 120 detects the contact area with the pulse wave measurement sensor 10, which is a test target, and can measure an accurate pressure value applied to the pulse wave measurement sensor 10 to calculate the pressure value and the pressure and pulse pressure. can do.

That is, since the pressure is calculated by dividing the force by the contact area value, the pulse wave generation control unit () is transmitted by transmitting the contact area in which the pulse pressure generation unit contacts the pulse wave measurement sensor 10 through the contact area detection sensor 120 to the pulse wave generation control unit 300. 300) the pulse pressure value for generating a preset pulse wave, that is, the pulse pressure generating unit 100 so as to accurately control the pressure value that presses the pulse wave measuring sensor 10 to be tested as the pulse pressure generating unit so as to generate a predetermined pulse wave. It becomes possible to accurately control the linear reciprocating motion of.

The pulse wave generation control unit 300 receives the contact area with the pulse wave measurement sensor 10 from the contact area detection sensor 120 and confirms an accurate pressure value applied to the pulse wave measurement sensor 10 by the sensor support member 110. , It is possible to press the pulse wave measurement sensor 10 to the correct pressure value by the sensor support member 110 so as to accurately transmit a preset simulated pulse wave signal to the pulse wave measurement sensor 10.

Meanwhile, the linear mobile device 200 for generating pulse waves is an example of a linear motor, and an example of a linear motor equipped with a hall sensor.

The linear motor includes a stator with permanent magnets with alternating polarity, and a mover with a mover coil wound on the mover core. Magnetic force and permanent magnets generated by the mover coil as current is applied to the mover coil Since the structure can be linearly reciprocated by the interaction between the magnetic forces of the well-known configuration, a detailed description thereof will be omitted.

The linear motor is equipped with a hall sensor to accurately detect the position of the mover, so that the pulse wave generator 100 can be reciprocated in a straight line to an accurate position capable of generating a predetermined pulse wave.

The Hall sensor is installed on the mover side to detect the phase of the mover using a Hall sensor that measures the magnetic flux of the stator permanent magnet, and a sensor head that detects the linear scale installed on the stator side and the linear scale installed on the mover side. It is possible to detect the moving position (movement amount) of the mover using.

In addition, it is revealed that the linear movement device 200 for pulse wave generation may be a ball screw type linear actuator in addition to a linear motor, or may be implemented by applying a linear actuator having various well-known structures capable of linear reciprocation.

When the linear moving device 200 for generating pulse waves is a ball screw type linear moving device 200 for generating pulse waves, a magnetic field generator such as a coil is positioned in the pulse wave generating unit 100, and the moving of the pulse wave generating unit 100 is performed. It is revealed that the position of the pulse wave generator 100 can be accurately controlled by detecting a change in the magnetic field according to the Hall sensor and transmitting the pulse wave to the pulse wave generator controller 300.

That is, the pulse wave generation control unit 300 generates an accurate position that the pulse wave generation unit 100 can generate a predetermined pulse wave, that is, a predetermined pulse pressure through the position of the pulse wave generation unit 100 detected by the hall sensor. The operation of the linear mobile device 200 for pulse wave generation is controlled so as to be able to reciprocate linearly to the correct position.

When the position of the pulse wave generator 100 is not detected by the hall sensor, the zero position of the pulse wave generator 100 is caused by the mechanical coupling structure tolerance and backlash when driving the motor of the linear mobile device 200 for pulse wave generation. It is difficult to generate a predetermined pulse wave due to a phenomenon caused by distortion, and it is difficult to generate a predetermined pulse pressure, and a predetermined pulse pressure and pulse pressure are generated by the pulse wave measurement sensor 10, which is a test object, so that the accurate pulse wave measurement sensor 10 is generated. The test becomes impossible.

On the other hand, the simulated pulse wave generator according to the present invention is located in front of the pulse wave generator 100 and the sensor holder 400 that can be positioned to face the pulse wave measurement sensor 10 to be tested facing the pulse wave generator 100 It may further include.

The sensor holder 400 may be positioned to be spaced apart from the pulse wave generator 100 on the front side in the moving direction of the pulse wave generator 100, and may be placed on the base support 220.

In addition, the simulated pulse wave generator according to the present invention can move the pulse wave generator 100 and the linear moving device 200 for pulse wave forward and backward to adjust the pulse wave position of the pulse wave generator 100, that is, the zero point position. It may further include a linear moving device 500 for initial position adjustment.

The linear moving device 500 for initial position adjustment is assumed to be a linear motor as an example, and an linear motor equipped with a hall sensor is taken as an example.

The linear motor includes a stator with permanent magnets with alternating polarity, and a mover with a mover coil wound on the mover core. Magnetic force and permanent magnets generated by the mover coil as current is applied to the mover coil Since the structure can be linearly reciprocated by the interaction between the magnetic forces of the well-known configuration, a detailed description thereof will be omitted.

The linear motor is equipped with a hall sensor to accurately detect the position of the mover, so that the pulse wave generator 100 can be reciprocated in a straight line to an accurate position capable of generating a predetermined pulse wave.

The linear moving device for initial position adjustment 500 is before the pulse wave is generated by the operation of the linear moving device 200 for generating pulse waves, that is, before the pulse wave generator 100 is operated to generate pulse waves, the pulse wave generator 100 and The distance between the pulse wave generator 100 and the pulse wave measurement sensor 10 mounted on the sensor holder 400 is adjusted by moving the straight line moving device 200 for pulse wave generation before and after.

This is because the pulse vibration of each person is different, that is, there is a person with a large pulse vibration and a person with a small pulse vibration, so the pulse wave generator 100 and the sensor are mounted before the pulse wave generator 100 generates a pulse wave. By variously adjusting the space between the portions 400, it is possible to test the performance of the pulse wave measurement sensor 10 in various situations in which pulse vibration is different.

The pulse wave measurement sensor 10 may be manufactured in various forms, each of which is different in size and shape depending on the model name in the manufacturing company and the manufacturing company, and thus the linear moving device 500 for initial position adjustment is the pulse wave measurement sensor 10 that is the test target. The position of the pulse wave generator 100 can be adjusted according to the size and shape of the to enable performance testing of the pulse wave measurement sensor 10 of various models of various manufacturers.

The linear moving device 500 for initial position adjustment may be positioned such that the pulse wave generator 100 is in contact with or separated from the pulse wave measurement sensor 10 located in the sensor holder 400, and the pulse wave measurement sensor 10 is a human body. The pulse wave generator 100 is positioned to the extent that it contacts the skin.

The pulse wave generating linear moving device 200 is operated after the pulse wave generating unit 100 is moved to the initial position for testing by the operation of the linear moving device 500 for initial position adjustment to generate a simulated pulse wave signal, thereby generating a pulse wave measuring sensor. (10).

In addition, the simulated pulse wave generator according to the present invention is located on the base support 220, the linear movement of the pulse wave generator 100 and the pulse wave generator linear movement device 200 by the linear movement device 500 for initial position adjustment It may further include a guide rail member 210 for guiding.

The guide rail member 210 is positioned long in the front and rear directions of the pulse wave generator 100 and the pulse wave generator 100 is a movement guide member 140 movably coupled to the guide rail member 210 on the lower side. It includes.

The guide rail member 210 guides the linear movement of the pulse wave generating unit 100 and the pulse wave generating unit 200 for pulse wave generation by the linear moving device 500 for initial position adjustment, and thus for the pulse wave generating unit 100 and pulse wave generation The linear moving device 200 can be stably positioned.

The linear moving device 500 for initial position adjustment can be used to simulate the operation of pressing to evaluate the pressing force, which is a main function of the pulse wave measuring device.

That is, during pulse wave measurement, the pulse wave measurement sensor 10 is placed on the radial artery to apply pressure (pressurization) while simultaneously measuring the arterial pressure in the pulse wave measurement sensor 10, precisely adjusting the pressure, and this pressure is applied to the sensor. It is also one of the test items that are accurately transmitted to.

Therefore, the two z-axis, that is, the linear movement device 500 for initial position adjustment can simulate the pressure control, and the linear movement device 200 for pulse wave generation simulates the pulsation, thereby measuring the arterial pressure in the pulse wave measurement sensor 10. Measurements can be made, and the pressure can be precisely adjusted and tested to see if this pressure is accurately transmitted to the sensor.

In addition, the simulated pulse wave generating apparatus according to the present invention is a position adjusting mobile device 600 capable of adjusting the position of the pulse wave generating portion 100 by linearly reciprocating the pulse wave generating portion 100 in an arbitrary direction different from the pulse wave generating direction. It may further include.

The position-adjusting mobile device 600 may include a horizontal position-adjusting mobile device 610 capable of horizontally moving the position of the pulse wave generator 100 in the left and right directions.

In addition, the mobile device 600 for position adjustment may further include a vertical movement device 620 that can move the position of the pulse wave generator 100 up and down.

The horizontal position adjusting mobile device 610 may finely adjust the position of the pulse wave generator 100 by linearly reciprocating the position of the pulse wave generator 100 in the horizontal direction.

In addition, the elevating/moving device 620 may finely adjust the position of the pulse wave generator 100 by linearly reciprocating the position of the pulse wave generator 100 in the up and down directions.

For example, the mobile device 610 for horizontal position adjustment or the mobile device for vertical movement is a linear motor, and an example is a linear motor equipped with a hall sensor.

The linear motor includes a stator with permanent magnets with alternating polarity, and a mover with a mover coil wound on the mover core. Magnetic force and permanent magnets generated by the mover coil as current is applied to the mover coil Since the structure can be linearly reciprocated by the interaction between the magnetic forces of the well-known configuration, a detailed description thereof will be omitted.

The linear motor is equipped with a hall sensor to accurately detect the position of the mover, thereby finely adjusting the position of the pulse wave generator 100 and accurately checking the adjusted position.

In addition, the horizontal position adjustment moving device 610 or the vertical moving device may be a ball screw type linear actuator in addition to a linear motor, or by applying a hydraulic actuator and a linear actuator having various well-known structures capable of linear reciprocation. It is revealed that it can be carried out.

When the forward and backward movements of the pulse wave generator 100 are in the Z-axis direction, the horizontal position adjustment moving device 610 linearly reciprocates the pulse wave generator 100 in the X-axis direction, and moves up and down. For example, the pulse wave generator 100 is linearly reciprocated in the Y-axis direction.

For example, the mobile device 600 for position adjustment is configured to be moved together with the pulse wave generating unit 100 by the linear wave moving device 200 for generating pulse waves.

In addition, one of the mobile device 610 for horizontal position adjustment and the vertical movement device 620 is located, the pulse wave generating unit 100 is located, and the other is a mobile device for horizontal position adjustment along with the pulse wave generating unit 100 (610) ) And the lifting device 620 is configured to move any one as an example.

That is, as an example, the horizontal position adjustment mobile device 610 is located on the upper side of the elevating mobile device 620 and the elevating mobile device 620 connected to the pulse wave generator 100 is located, the elevating mobile device 620 The pulse wave generator 100 and the pulse wave generator 100 may be linearly reciprocated in the horizontal direction.

In addition, although not shown, on the contrary, the elevating and moving device 620 has a pulse wave generator 100 connected to the mobile device 610 for horizontal position adjustment and the mobile device 610 for horizontal position adjustment on the upper side, and the horizontal position It is revealed that the reciprocating mobile device 610 and the pulse wave generator 100 may be reciprocated in a straight line in the up and down directions together.

The mobile device 610 for position adjustment enables testing of the array sensor of the pulse wave measurement sensor 10.

That is, in the tonometry (tonometry) pulse wave analysis device, the pulse wave measurement sensor 10 uses an array sensor to search for the location of the measurement vessel into which the largest and clearest signal is input when pressing the skin on the measurement site, thereby vascularizing the measurement vessel. It is configured to adjust the position of the pressing portion to pressurize.

Accordingly, the mobile device 600 for position adjustment, that is, the mobile device 610 for horizontal position adjustment, finely adjusts the position of the pulse wave generator 100 to test the accuracy of the array sensor and the skin of the measurement site when the pulse wave measurement sensor 10 is tested. When pressurizing, the position of the measurement vessel where the largest and clearest signal is inputted is searched to test whether the function to pressurize the pressurizing part operates normally.

In addition, the pulse wave measurement sensor 10 may be manufactured in various forms, each of which is different in size and shape, depending on the model name in the manufacturing company and the corresponding manufacturing company. It is located differently.

Accordingly, the mobile device for adjusting the horizontal position 610 or the vertically moving device 620 can adjust the position of the pulse wave generator 100 according to the size and shape of the pulse wave measuring sensor 10 to be tested, so that various models of various manufacturing companies It is possible to perform a performance test on the pulse wave measurement sensor 10.

On the other hand, Figure 4 is a schematic diagram of a test apparatus for a pulse wave measuring sensor 10 according to the present invention. Referring to Figure 4, a test apparatus for a pulse wave measuring device according to the present invention generates a simulated pulse wave generating device and a simulated pulse wave according to the present invention. It is connected to the pulse wave generation control unit 300 of the device and the pulse wave measurement sensor 10 to be tested to receive the measured pulse wave signal and the simulated pulse wave signal measured from the pulse wave measurement sensor 10 to output the measured pulse wave signal and the simulated pulse wave signal. The main control unit 700 is further included.

The main control unit 700 may include a display panel unit 710 connected to a display panel unit 710 capable of outputting a measured pulse wave signal and a simulated pulse wave signal to a screen.

The display panel unit 710 may input a test condition through a screen touch with a touch screen panel, and may switch the output result screen mode for the test result.

In addition, the main control unit 700 inputs test conditions through a known input unit such as a keyboard and a mouse to a terminal such as a PC, and reveals that the output result screen mode for the test result can be switched.

The simulated pulse wave generating apparatus according to the present invention generates pulse waves to generate a predetermined pulse wave signal identified by a sensor mounted on the sensor holder 400 by moving the pulse wave generator 100 back and forth by operating a pulse wave generating linear moving device. The linear mobile device is operated to transmit a preset simulated pulse wave signal to the pulse wave measurement sensor 10 to be tested to the pulse wave generator 100.

Then, the pulse wave measurement sensor 10 receives the measurement pulse wave signal from the pulse wave generator 100 and transmits the measured pulse wave signal to the main control unit 700, and the main control unit 700 outputs the received measurement pulse wave signal to a screen.

The main control unit 700 may simultaneously output the simulated pulse wave signal and the measured pulse wave signal through the display panel unit 710 or separately, respectively, and through the display panel unit 710, the examiner may use the pulse wave generator 100 The performance of the pulse wave measuring sensor 10 can be confirmed by comparing the simulated pulse wave signal generated with the measured pulse wave signal measured by the pulse wave measuring sensor 10 to be tested.

In addition, the simulated pulse wave generator according to the present invention is the position of the first pulse wave generator 100 as the linear moving device 500 for initial position adjustment, that is, the distance between the pulse wave measurement sensor 10 and the pulse wave generator 100 that are the test targets. By adjusting to enable more various tests on the measurement performance of the pulse wave measurement sensor 10 according to the individual pulsation.

The simulated pulse wave generator according to the present invention is a mobile device 610 for horizontal position adjustment or a vertical movement device 620, which can adjust the position of the pulse wave generator 100, so that the pulse wave measurement sensor 10 has various sizes and shapes Not only can be tested, but also the performance of the array sensor of the pulse wave measurement sensor 10 can be tested together.

The present invention has the effect of accurately testing the performance of the pulse wave measuring sensor 10 to reduce the defect rate of the pulse wave measuring sensor 10 and improving the accuracy of the pulse wave measuring device including the pulse wave measuring sensor 10.

There is an effect of accurately testing the performance of the pulse wave measuring device including the pulse wave measuring sensor 10 of the present invention to improve the accuracy of the diagnostic device and reliability of the diagnostic device.

In the present invention, the pulse wave measurement sensor 10 can test the accuracy of the pulse rate, the accuracy of the pressing force, the accuracy of the measurement pressure, the accuracy of the blood vessel position, and the accuracy of acquiring a stereoscopic pulse image of the measurement region, and thus the pulse wave including the pulse wave measurement sensor 10 It has the effect of helping the product development of measuring instruments.

The present invention is not limited to the above-described embodiments, but can be implemented by variously changing within a range not departing from the gist of the present invention, and it is revealed that it is included in the configuration of the present invention.

10: pulse wave measurement sensor 100: pulse wave generation unit
110: sensor support member 120: contact area detection sensor
130: elastic pad member 140: moving guide member
200: linear movement device for pulse wave generation 210: guide rail member
220: base support 300: pulse wave generation control unit
400: sensor mounting portion
500: linear moving device for initial position adjustment
600: mobile device for position adjustment 610: mobile device for horizontal position adjustment
620: moving devices up and down 700: main control
710: display panel unit

Claims (3)

A pulse wave generator to which the pulse wave measurement sensor to be tested is contacted;
A straight line moving device for generating a pulse wave that linearly reciprocates the pulse wave generating unit back and forth; And
And a moving device for horizontal position adjustment capable of moving the position of the pulse wave generator in the left and right directions.
The method according to claim 1,
And a moving device for moving up and down the position of the pulse wave generator.
A pulse wave generator to which the pulse wave measurement sensor to be tested is contacted;
A straight line moving device for generating a pulse wave that linearly reciprocates the pulse wave generating unit back and forth;
A mobile device for horizontal position adjustment capable of moving the position of the pulse wave generator in the left and right directions;
A pulse wave generation control unit controlling the operation of the linear mobile device for generating pulse waves to generate a predetermined simulated pulse wave signal; And
It is connected to the pulse wave generation control unit and the simulated pulse wave generation device and includes a main control unit capable of receiving the measured pulse wave signal and the simulated pulse wave signal measured from the pulse wave measurement sensor and outputting the measured pulse wave signal and the simulated pulse wave signal,
The main control unit comprises a display panel unit capable of outputting a measured pulse wave signal and a simulated pulse wave signal to a screen.

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