KR101593412B1 - Acceleration plethysmography analysis apparatus and method using wave form frequency distribution - Google Patents

Abstract

The present invention detects a periodic waveform and a minutia point in an acceleration pulse wave and compares the waveform with a waveform pattern of a previously stored acceleration pulse wave to increase the counter of the same waveform pattern when there is the same waveform pattern, The present invention relates to an apparatus and method for analyzing an acceleration pulse wave parameter using a waveform type frequency distribution in which the number of waveform patterns is largest and the case where the counter value is the largest among the waveform patterns is selected and analyzed as a representative waveform pattern.
A signal preprocessing unit amplifies a pulse wave signal detected by the signal detecting unit, removes noise, and converts the pulse wave signal into a digital signal. The signal detecting unit detects a pulse wave signal of arterial blood flow in the arterioles of a finger, And an arithmetic processing unit for detecting an acceleration pulse wave by secondary differentiating the pulse wave signal received from the signal preprocessing unit, wherein the arithmetic processing unit calculates a maximum value (a ), The minimum value (b), the maximum value (c), and the minimum value (d) of the contraction late wave are detected as characteristic points of the acceleration pulse wave, And comparing the feature points of the acceleration waveforms of the waveform patterns previously stored in the storage section with the feature points of the acceleration waveforms of the same frequency as the feature points of the acceleration waveform of the current cycle If there is no waveform pattern, the counter of the waveform pattern having the characteristic point of the acceleration pulse wave similar to the characteristic point of the acceleration pulse wave of the current cycle is incremented. If there is no waveform pattern having the characteristic point of the acceleration pulse wave same as the characteristic point of the acceleration pulse wave of the current cycle, A waveform pattern having a waveform pattern counter value having a maximum value among the stored waveform pattern counter values is selected as a representative waveform pattern, And outputs the waveform and the characteristic point of the acceleration pulse wave of the pattern to the output unit.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an acceleration pulse wave analyzing apparatus and method using frequency distribution,

The present invention detects a periodic waveform and a minutia point in an acceleration pulse wave and compares the waveform with a waveform pattern of a previously stored acceleration pulse wave to increase the counter of the same waveform pattern when there is the same waveform pattern, The present invention relates to an apparatus and method for analyzing an acceleration pulse wave parameter using a waveform type frequency distribution in which the number of waveform patterns is largest and the case where the counter value is the largest among the waveform patterns is selected and analyzed as a representative waveform pattern.

Pulse wave refers to the wavelength at which blood circulates in the heart and propagates. It varies slightly depending on the arteries and veins, but generally, the characteristics of the pulse and pulse wave depend on the motion of the heart, the characteristics of the blood vessel wall, and the pressure in the blood vessel.

Pulse wave and pulse wave are pulse waves. The pressure pulse wave records a change in arterial pressure accompanied by a heartbeat, but a recordable portion is limited to a portion capable of touching the arterial pulse from the skin. The volumetric pulse wave is a method for detecting a volume change of an arbitrary region of the limb, and includes photoplethysmography (PPG) (hereinafter referred to as pulse wave).

Acceleration plethysmography (APG) obtained by measuring a pulse wave (PPG) from a subject and secondly differentiating the pulse wave is used for diagnosing a health condition including a blood vessel state such as a peripheral circulation disorder and atherosclerosis.

A general method for analyzing data in an apparatus and a program for measuring a health condition using a pulse wave and an acceleration pulse wave obtained by second differentiating the pulse wave is to detect a characteristic point (crest value) of a pulse wave and an acceleration pulse wave obtained by measuring a pulse wave The human body index is calculated using the detected minutiae points, and the pattern is classified according to the position of the minutiae points and the waveform shape.

Recently, autonomic nervous system and stress evaluation method using heart rate variability (HRV) has been developed and a pulse wave which can be easily measured instead of an electrocardiogram signal is also used.

Although the parameters to be measured in the acceleration pulse wave have been known for a long time, the standard measurement time or the number of the measurement waveforms for reliable diagnosis are not known. In addition to the measurement time, there are various methods Do.

When the rate of change of heart rate is not displayed, the measurement is completed when the interval of 10 seconds to 1 minute and 30 seconds is measured for each product, or when the number of predetermined bits is satisfied. When diagnosing the acceleration pulse wave parameter and the heart rate change together, it is common to measure at least three minutes.

The measurement time is not only varied but also the method of processing the measured waveforms is as follows. First, when the parameters of all the individual waveforms are extracted and processed as an average or an intermediate value, the representative waveform among the plurality of waveforms is selected Third, when extracting a parameter of a waveform, or when generating an average waveform or an intermediate value waveform to process a parameter, various methods are used.

Pulse waves are very fluctuating due to the characteristics of the signals, and when the measurement is not very careful, there is a high possibility that the signal is distorted due to the inclusion of noise. Even if you pay attention to the measurement, the reproducibility of the signal decreases depending on the situation of the subject. In addition, when diagnosing heart rate variability together, it is difficult to maintain a stable state for a relatively long period of time. At this time, the signal of the acceleration pulse wave is inevitably changed, and distorted information may be mixed in the average and intermediate value waveforms, and even if a representative waveform is selected, the objectivity may be deteriorated. In addition, a program error for peak detection can not be ignored.

Therefore, there is a need for a pulse wave analysis method capable of performing objective analysis even when the signal is distorted and the reproducibility of the signal is high.

As such a method, the present invention proposes an apparatus and method for analyzing an acceleration pulse wave parameter using a frequency distribution of a waveform type.

As a prior art, there is a pulse analysis apparatus of Korean Patent No. 10-0368021.

Korean Patent No. 10-0368021 discloses a method of extracting a digital converted volumetric pulse wave according to a predetermined analytical model, extracting feature points of a first differential and a second differential, a volumetric pulse wave of a first differential wave and a second differential wave, And analyze the correlation between the shape change of the volumetric pulse wave and the medical diagnosis concept by using the characteristic elements of the extracted volumetric pulse wave. In other words, time-related factors such as a starting point, a rising angle, a shock wave, a gyration wave, a cusp, a double wave, a falling angle, a rise time, an aggravation time, a pulse cycle, And analyze the correlation between the shape change of the volumetric pulse wave and the medical diagnosis concept by using the pulse database.

In the case of performing accurate analysis of the volumetric pulse wave as disclosed in Korean Patent No. 10-0368021, the patient can not be observed and judged from the viewpoint of the whole, and the reproducibility of the signal is deteriorated depending on the situation of the subject.

Therefore, according to the present invention, the parameters of all the individual waveforms are extracted regardless of the measurement time, and all the individual waveforms are classified into N predetermined waveform patterns, and then the number of waveforms belonging to the pattern N group is displayed Provided is an apparatus and method for analyzing an acceleration pulse wave parameter using a waveform type frequency distribution showing a change in a waveform pattern during a period.

Particularly, the present invention determines a representative waveform from a pattern 1 to a pattern having the most frequently occurring mode among the pattern N groups, extracts a final diagnostic parameter from the representative waveform, Prevent errors.

According to an aspect of the present invention, there is provided a method of detecting pulse waveforms and feature points in an acceleration pulse wave, comparing the pulse waveforms and the characteristic points of the pulse waveform with the waveform patterns of previously stored acceleration pulse waves, The present invention provides an apparatus and method for analyzing an acceleration pulse wave parameter using a waveform type frequency distribution in which the number of identical waveform patterns is calculated and a case where the counter value is the largest among the waveform patterns is selected and analyzed as a representative waveform pattern .

According to another aspect of the present invention, there is provided a method of extracting parameters of all individual waveforms, regardless of measurement time, and classifying all individual waveforms into N predetermined waveform patterns, And an analysis method and apparatus for analyzing an acceleration pulse wave parameter using a waveform type frequency distribution showing a change in a waveform pattern during a measurement period.

According to another aspect of the present invention, there is provided an apparatus and method for determining a representative waveform from a pattern 1 to a pattern having a mode most frequently occurring among pattern N groups, extracting a final diagnostic parameter from the representative waveform, The present invention provides an apparatus and method for analyzing acceleration pulse wave parameters using a waveform type frequency distribution, which prevents various errors that may occur.

In order to solve the above problems, the present invention provides a blood pressure measuring device comprising: a signal detecting unit for detecting a pulse wave signal of arterial blood flow in the arteriovenous artery of a finger, an earlobe, or a toe; a signal detecting unit for amplifying the pulse wave signal detected by the signal detecting unit, And an arithmetic processing unit for performing a second differentiation on the pulse wave signal received from the signal preprocessing unit to detect an acceleration pulse wave, wherein the arithmetic processing unit comprises: (A), the minimum value of the initial sound wave at the time of contraction (b), the maximum value (c) of the mid-contraction period and the minimum value (d) of the late contraction period are detected as characteristic points of the acceleration pulse wave. The feature point of the acceleration pulse wave is compared with the feature points of the acceleration pulse wave of the waveform patterns previously stored in the storage section, If there is a waveform pattern having characteristic points of the velocity pulse wave, a counter of a waveform pattern having characteristic points of the same acceleration pulse wave as the characteristic points of the acceleration pulse wave of the current cycle is incremented, and a waveform having characteristic points of the acceleration pulse wave, If there is no pattern, a waveform pattern having a waveform pattern counter value having the maximum value among the stored waveform pattern counter values is stored as a representative waveform pattern And outputs the waveform and the characteristic point of the acceleration pulse wave of the representative waveform pattern to the output unit.

The characteristic points of the acceleration pulse wave are the time value of the minimum point of the negative initial wave of contraction, the time value of the maximum point of the contraction mid-reentry wave based on the time value of the maximum point of the initial positive wave of contraction, Lt; / RTI >

The arithmetic processing unit estimates the degree of senescence of the blood vessel using the characteristic points of the acceleration pulse waves of the representative waveform pattern.

The calculation processing unit obtains the slope SL at the minimum point of the initial sound wave at the initial shrinkage and the minimum point of the descending wave at the late contraction period of the representative waveform and calculates the slope SL, the minimum value b of the initial sound wave at the initial shrinkage of the representative waveform, The degree of senescence of the blood vessel is estimated using the maximum value (c) of the contraction mid-reentry wave of the waveform and the minimum value (d) of the late-contraction late wave of the representative waveform.

The calculation processing section sets a value having a smaller value among the minimum value b of the initial sound wave at the contraction of the representative waveform and the minimum value d of the latter period of the contraction late period as the minimum sound wave value H3, ) Of the size of the voice wave minimum value (H3) is set as a 1/3 sound wave minimum value (H1), and a value that is 2/3 of the minimum sound wave minimum value (H3) do.

The arithmetic processing unit may be configured such that the inclination SL is greater than 0 and the maximum value c of the shrunken middle rising wave of the representative waveform is greater than or equal to 0 and the minimum value d of the shrunken lower- 3 sound wave minimum value (H2), it is determined that the representative waveform is the waveform of the first stage of blood vessel aging.

The computation processing unit may be configured such that the inclination SL is greater than 0 and the maximum value c of the contraction mid-wave reentrant wave of the representative waveform is greater than or equal to the 1/3 sound wave minimum value H1, Is greater than or equal to the 1/3 sound wave minimum value (H1), it is determined that the representative waveform is the waveform of the second stage of blood vessel aging.

The computation processing unit may be configured such that the inclination SL is greater than 0 and the maximum value c of the contraction mid-wave reentrant wave of the representative waveform is greater than or equal to the 1/3 sound wave minimum value H1, Is smaller than the 1/3 sound wave minimum value (H1) and equal to or greater than the sound wave minimum value (H3), the representative waveform is judged to be the waveform of the third stage of the blood vessel aging.

The computation processing unit may be configured such that the inclination SL is less than or equal to 0 and the maximum value c of the contraction mid-wave reentrant wave of the representative waveform is smaller than the 1/3 sound wave minimum value H1, If the minimum value d of the wave is smaller than or equal to the 2/3 sound wave minimum value H2, it is determined that the representative waveform is the waveform of the fourth stage of vascular aging.

The arithmetic processing unit may be configured such that the inclination SL is less than 0 and the minimum value b of the initial sound wave at the initial shrinkage of the representative waveform is less than or equal to the 2/3 sound wave minimum value H2, (C) is smaller than or equal to the 2/3 sound wave minimum value (H2), the representative waveform is judged to be the waveform of the fifth stage of the blood vessel aging.

If the inclination SL is less than 0 and the minimum value b of the initial sound wave at the contraction of the representative waveform is equal to or greater than the 1/3 sound wave minimum value H1, It is judged to be the waveform of 6 stages of aging of the blood vessel.

In the arithmetic processing unit, the arithmetic processing unit determines that the waveform is the seventh stage of blood vessel aging if the slope SL is less than 0 and is not one of the waveforms of the first stage of vascular aging to the sixth stage of vascular aging.

The arithmetic processing unit detects a sample having a maximum positive value larger than a predetermined a detection threshold value among the samples of the acceleration pulse wave and detects the sample as the maximum point of the initial positive wave of contraction and sets the maximum positive value larger than the a detection threshold value as the maximum Value, and the time value of the maximum point of the initial positive wave is detected.

The calculation processing unit detects inflection points having two minimum negative values smaller than a preset negative wave detection threshold among the samples of the acceleration pulse wave and extracts a sample having an inflection point close to the maximum point of the contraction initial positive wave among the inflection points, Wave and detects a sample having an inflection point far from the maximum point of the contraction initial positive wave among the inflection points as the minimum point of the late contraction late wave.

The calculation processing unit detects the minimum value (b) of the initial sound wave at the initial shrinkage, which is the minimum point of the initial sound wave at the initial shrinkage, and calculates the time interval of the minimum point of the initial sound wave at the initial shrinkage from the maximum point of the initial shunt wave, As the time value of the minimum point of the initial sound wave of contraction based on the maximum point of the wave.

The arithmetic processing unit detects the minimum value (d) of the late contraction late wave, which is the minimum point of the late contraction late wave, and calculates the time interval of the minimum point of the contraction late wave from the maximum point of the initial contraction positive wave, Is detected as the time value of the minimum point of the descending wave of the late contraction based on the maximum point of the wave.

The calculation processing section finds a sample having the maximum value among the samples of the acceleration pulse wave between the minimum point of the initial sound wave at the contraction and the minimum point of the late contraction late wave and detects it as the maximum point of the contraction mid wave re- The maximum point size is detected as the maximum value (c) of the mid-contraction reverberation wave, and the time interval of the maximum point of the contraction midterm reverberation wave from the maximum point of the contraction initial positive wave, , And is detected as the time value of the maximum point of the re-emergence wave in the middle of contraction.

The storage section stores the characteristic points of the acceleration pulse wave of the waveform of the first stage of the blood vessel aging to the waveform of the seventh stage of the blood vessel aging and the waveform of the first stage of the blood vessel aging to the seventh stage of the aging of the blood vessel.

According to another aspect of the present invention, there is provided a method of driving an acceleration pulse wave analyzing apparatus, comprising: an acceleration pulse wave detecting step of receiving a pulse wave signal detected at the arteriovenous artery of a finger, an earlobe, or a toe and secondarily differentiating the pulse wave signal to detect an acceleration pulse wave; (A), the minimum value of the negative initial wave of contraction (b), the maximum value of the contraction mid-reentry wave (c), the contraction late fall (c) An acceleration pulse wave feature point detecting step of detecting an acceleration pulse wave feature point including a minimum value (d) of a wave; Similar to the existing waveform pattern, which compares the acceleration pulse wave feature points detected in the acceleration pulse wave feature point detection step with the acceleration pulse wave feature points of the existing waveform pattern stored in the storage section to determine whether there is the same pattern as the current acceleration pulse wave waveform. A determination step; If there is the same waveform pattern at the step of determining similarity with the existing waveform pattern, the existing waveform pattern counter, which is the same waveform pattern, is incremented, and the arithmetic processing unit determines whether or not all analysis of the previously set detection data is completed, The previous waveform pattern counter incrementing step of returning to the acceleration pulse wave feature point detection step if all analysis of the waveform pattern counter has not been completed; If all of the analysis of the detection data of the predetermined pulse wave signal is completed, the arithmetic processing unit determines whether or not all of the analysis of the previously detected data has been completed. Then, the counter values of the waveform pattern are compared with each other, And a representative waveform pattern selection step of selecting the representative waveform pattern.

The driving method of the acceleration pulse wave analyzing apparatus further includes a representative waveform pattern output step of outputting the representative waveform pattern and its acceleration pulse wave feature points selected in the representative waveform pattern selection step.

The driving method of the acceleration pulse-wave analyzing apparatus is characterized in that, in the step of judging whether the existing waveform pattern is similar to the existing waveform pattern, if there is no same waveform pattern, the current acceleration waveform waveform and the acceleration waveform waveform feature point are stored as a new waveform pattern, If all the analysis of the predetermined detection data has not been completed, the process returns to the acceleration pulse wave characteristic point detection step. If all the analysis of the previously set detection data is completed, And a new waveform pattern generation step to a pattern selection step.

The driving method of the acceleration pulse-wave analyzing apparatus further includes a step of estimating the degree of senescence of the blood vessel using the feature points of the acceleration pulse wave of the representative waveform pattern to estimate the degree of senescence of the blood vessel.

According to another aspect of the present invention, there is provided a method of driving an acceleration pulse wave analyzing apparatus, comprising: an acceleration pulse wave detecting step of receiving a pulse wave signal detected at the arteriovenous artery of a finger, an earlobe, or a toe and secondarily differentiating the pulse wave signal to detect an acceleration pulse wave; (A), the minimum value of the negative initial wave of contraction (b), the maximum value of the contraction mid-reentry wave (c), the contraction late fall (c) An acceleration pulse wave feature point detection step of detecting an acceleration pulse wave feature point including a slope (SL) obtained by finding a minimum value (d) of a wave, a minimum point of an initial negative wave of contraction, and a minimum point of a late contraction period;

The computation processing unit determines that the slope SL is greater than 0 and the maximum value c of the contraction mid-wave reentry wave is greater than or equal to 0 and the minimum value d of the late contraction period wave is less than the 2/3 sound wave minimum value H2, Determining whether the waveform of the acceleration pulse wave is equal to the waveform of the first stage of vascular aging and increasing the waveform counter of the first stage of vascular aging; The computation processing unit determines that the slope SL is greater than 0 and the maximum value c of the contraction mid-reentry wave is greater than or equal to the 1/3 sound wave minimum value H1 and the minimum value d of the late- Determining whether the waveform of the acceleration pulse wave is the same as the waveform of the second stage of the blood vessel aging and increasing the waveform counter of the second stage of the blood vessel aging if the pulse wave is greater than or equal to the minimum sound wave minimum value H1; The computation processing unit determines that the slope SL is greater than 0 and the maximum value c of the contraction mid-reentry wave is greater than or equal to the 1/3 sound wave minimum value H1 and the minimum value d of the late- / 3 sound wave minimum value H1 and is greater than or equal to the sound wave minimum value H3, it is determined that the waveform of the acceleration pulse wave is the same as the waveform of the third stage of the blood vessel aging, and the waveform counter of the third stage of the blood vessel aging is increased , A step of determining whether or not the blood vessel is aged in three stages; The computation processing unit determines that the slope SL is less than or equal to 0 and the maximum value c of the contraction mid-reentry wave is smaller than the 1/3 sound wave minimum value H1 and the minimum value d of the late- Determining whether the waveform of the acceleration pulse wave is equal to the waveform of the fourth stage of vascular aging and increasing the waveform counter of the fourth stage of vascular aging if the pulse wave is less than or equal to the 2/3 sound wave minimum value H2; If all of the analysis of the detection data of the predetermined pulse wave signal is completed, the arithmetic processing unit determines whether or not all of the analysis of the previously detected data has been completed. Then, the counter values of the waveform pattern are compared with each other, And a representative waveform pattern selection step of selecting the representative waveform pattern.

In the driving method of the acceleration pulse-wave analyzing apparatus, the arithmetic processing unit determines that the slope (SL) is smaller than 0 and the minimum value (b) of the initial sound wave of contraction is between If the maximum value (c) of the mid-contraction wave is equal to or greater than the 2/3 sound wave minimum value (H2) and the waveform of the acceleration pulse wave is greater than or equal to the 2/3 sound wave minimum value (H2) And a waveform counter of the fourth stage of vascular aging is increased; a step of determining whether the vascular aging is a fifth stage; If the slope SL is less than 0 and the minimum value b of the initial sound wave at the contraction is greater than or equal to the 1/3 sound wave minimum value H1, then the arithmetic processing unit determines that the waveform of the acceleration pulse wave is the waveform Determining whether the blood vessel aging 6 step is equal to the blood vessel aging 6 step; The arithmetic processing unit determines that the waveform of the acceleration pulse wave is the same as the waveform of the blood vessel aging 7 stage if the slope SL is less than 0 and is not the same as any one of the waveforms of the first stage of vascular aging to the waveform of the sixth stage of vascular aging, And a step of determining whether or not the blood vessel aging is a seventh step, wherein the waveform counter of the seventh step of the blood vessel aging is increased.

The driving method of the acceleration pulse-wave analyzing apparatus determines whether the maximum value (c) of the mid-contraction period re-uptake wave is smaller than the 1/3 sound wave minimum value (H1) , If it is small, it is judged to be four stages of blood vessel aging, and the counter of the four-stage waveform of aging of blood vessels is increased, if not small, it is judged to be three stages of blood vessel aging, And a determining step.

The present invention detects waveforms and minutiae by period in an acceleration pulse wave and compares them with waveform patterns of previously stored acceleration pulse waves to increase the counter of the same waveform pattern when there is the same waveform pattern, The present invention provides an apparatus and method for analyzing an acceleration pulse wave parameter using a waveform type frequency distribution in which the number of waveform patterns is largest and the case where the counter value is the largest among the waveform patterns is selected and analyzed as a representative waveform pattern.

The present invention extracts parameters of all individual waveforms irrespective of measurement time, classifies all individual waveforms into N predetermined waveform patterns, displays the number of waveforms belonging to the pattern N group from pattern 1, It shows the change of waveform pattern. Therefore, the present invention has high reproducibility of signals and allows objective analysis even when the signals are distorted.

Further, according to the present invention, a pattern having the most frequently occurring mode among pattern 1 to pattern N groups is determined as a representative waveform, and a final diagnosis parameter is extracted from the representative waveform. Thus, It is possible to prevent errors.

1 is a block diagram schematically illustrating a configuration of an apparatus for analyzing an acceleration pulse wave parameter using a waveform type frequency distribution.
2A is a basic waveform of an accelerating pulse wave for explaining acceleration pulse wave parameters.
FIG. 2B is an explanatory diagram for explaining the additional acceleration pulse wave parameters proposed in the present invention.
3 is an example of a waveform pattern stored in the storage section.
FIG. 4 is an explanatory view for explaining a method of determining the degree of blood vessel aging using the waveform pattern of FIG. 3;
5 is a flowchart schematically illustrating a method of analyzing an acceleration pulse wave parameter according to an embodiment of the present invention.
6 is a flowchart schematically illustrating a method of analyzing an acceleration pulse wave parameter according to another embodiment of the present invention.

Hereinafter, an apparatus and method for analyzing acceleration pulse wave parameters using the waveform type frequency distribution according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram schematically illustrating a configuration of an apparatus for analyzing an acceleration pulse wave parameter using a waveform type frequency distribution, a signal detecting unit 100, a signal preprocessing unit 200, an arithmetic processing unit 300, an output unit 410, A key input unit 430, and a storage unit 450.

The signal detecting unit 100 is a means for measuring the pulse wave of the arterial blood flow in the arterioles of the finger or toe and uses the characteristic that the arterial blood oxidized hemoglobin (HbO ₂ ) absorbs light in the infrared (IR) band, (100) includes a light emitting portion (110) and a light receiving portion (120).

The light emitting portion 110 is made of a light emitting diode and emits monochromatic light having a single wavelength within the band of 500 nm to 1000 nm on a finger or a toe.

The light receiving unit 120 is formed of a light receiving sensor such as a photodiode, and light emitted from the light emitting unit 110 detects light transmitted through the finger, the toe, or the earlobe. The light detected by the light receiving unit 120 is a volumetric pulse wave (hereinafter, referred to as "pulse wave") signal, which is a signal indicating a change in the volume of oxidized hemoglobin (HbO ₂ ) due to the flow of blood in the arteriolar blood vessel.

The signal preprocessing unit 200 amplifies the pulse wave signal detected by the light receiving unit 120, removes noise, and converts it into a digital signal. The signal preprocessing unit 200 includes an amplification unit 210, a filter unit 220, and an A / D conversion unit 230.

The amplification unit 210 amplifies the pulse wave signal received by the signal preprocessing unit 200. The amplification unit 210 is composed of a differential amplifier.

The filter unit 220 is composed of a bandpass filter and removes noise from the amplified pulse wave signal from the amplification unit 210.

The A / D conversion unit 230 converts a pulse wave signal, which is an analog signal filtered by the filter unit 220, into a pulse wave signal that is a digital signal.

The operation processing unit 300 second-differentiates the pulse wave signal received from the A / D conversion unit 230 or the pulse wave signal received from the A / D conversion unit 230 and stored in the storage unit 450 to generate an acceleration pulse wave And detects all the minutiae points in each cycle of the acceleration pulse wave. (A), (b), (c), (c), and (d), respectively, of the contraction late waves. (SL) of the minimum value (d) of the late contraction late wave and the minimum sound wave value (H3).

As shown in FIG. 2A, the 1-cycle waveform of the acceleration pulse wave is composed of an initial contraction initial positive wave (a wave), an initial contraction negative wave (b wave), a contraction middle reflex wave (c wave), a contraction late falling wave (d wave) (A) (hereinafter referred to as a) and the minimum value of the initial negative wave of contraction (b in FIG. 2A) (hereinafter referred to as " b " (c) (hereinafter referred to as c), the minimum value of the late contraction late wave (d in FIG. 2a) (hereinafter referred to as d), the maximum value of the initial initial positive waves The value (e in FIG. 2A) (hereinafter referred to as e) is an important parameter of the acceleration pulse wave.

The maximum value (a) of the positive initial wave at the initial shrinkage is used as a reference value (base value) or a reference point for facilitating comparison at the time of wave observation, and the maximum value (a) of the positive wave at the initial shrinkage is one cycle of the acceleration pulse wave , And has the largest positive value in the second differential pulse wave of one cycle. The arithmetic processing unit 300 detects a maximum positive value larger than the a detection threshold value and detects the maximum positive value of the initial positive shaking wave as a maximum value of the initial positive shaking wave, (Amplitude value) is detected. a The detection threshold value can be a positive value of the preset natural number at the factory. In some cases, if the a detection threshold can not detect the maximum value of the initial positive shaking wave within a predetermined time (for example, 3 seconds), the current a detection threshold is decreased by a predetermined value (for example, 10% ) Can be set as a new detection threshold value so that the maximum value of the initial positive waves can be detected again.

The minimum value of the initial wave of contraction (b) represents the heart beat phase, which is the first negative wave after the maximum value (a) of the initial wave of contraction. The calculation processing unit 300 finds an inflection point having two minimum negative values smaller than the negative wave detection threshold and detects a point nearest to the maximum point of the initial contraction positive wave as the minimum value b of the initial contraction negative wave, The distance from the maximum point of the initial positive wave of contraction is detected as the minimum value (d) of the last wave of contraction. The time point of the minimum value (b) of the initial negative sound wave of contraction is detected as the minimum point of the initial negative wave of contraction, and the time point of the minimum value (d) of the late contraction late wave is detected as the minimum point of the late contraction late wave. Here, the minimum value (b) of the initial sound wave at the contraction is the b-size value (amplitude value), and the time interval between the maximum point (a time value) b Time value - a Time value. This is the time value representing the minimum point of the initial negative wave of contraction based on the maximum point of the initial positive wave.

The maximum value (c) of the mid-contraction reentry wave is the reanalysis wave which is located between the minimum value (b) of negative initial wave of contraction and the minimum value (d) of late contraction wave. The operation processing unit 300 detects the maximum value between the minimum value b of the initial sound wave at the shrinkage and the minimum value d of the late contraction period and detects the maximum value c as the maximum value c of the contraction mid- It is detected as the maximum point of positive waves at the initial shrinkage. Here, the maximum value (c) of the contraction mid-rewarming wave is the c-size value (amplitude value), the time of the maximum point (c time value) of the contraction mid- The interval is the c time value - a time value. This is the time value that represents the maximum point of the mid-contraction reentrant wave based on the maximum point of the initial positive wave.

The minimum value (d) of the last wave of contraction is the residual blood volume, which is the second most negative wave after the maximum value (a) of the initial positive wave of contraction. The minimum value (d) of the late contraction late wave is detected at the time of detection of the minimum value (b) of the negative sound wave at the initial shrinkage. That is, the calculation processing unit 300 finds an inflection point having two minimum negative values smaller than the negative wave detection threshold, and detects a point nearest to the maximum point of the initial contraction positive wave as the minimum value b of the initial negative wave of contraction, (D), and the minimum point (d) of the last wave of contraction is detected as the minimum point of the late contraction wave. The time interval between the maximum point (a time value) and the minimum point (d time value) of the late contraction period is the d-size value (amplitude value) d time value - a time value. This is the time value that represents the minimum point (d time value) of the last wave of contraction according to the maximum point (a time value) of the initial positive wave of contraction.

In particular, when the minimum value (b) of the initial negative shrinkage wave and the minimum value (d) of the late shrinkage wave are compared, the minimum value of the initial negative shrinkage wave (b) indicates self- The minimum value (d) represents functional vascularization.

As shown in FIG. 2B, the slope SL of the minimum contraction early sound wave b and the minimum contraction late wave d may also be used as acceleration pulse wave parameters (acceleration pulse wave characteristic points). That is, it can be obtained as follows.

SL = (d - b) / (d time value - b time value)

Here, instead of the d time value and the b time value, a d time value based on a time value and a b time value based on a time value can be used.

2B, a value having a minimum value (smaller value) among the minimum value b of the initial sound wave at the initial shrinkage and the minimum value d of the late contraction period is set as the sound wave minimum value H3, Which is a value that is one-third of the size of the minimum sound wave value H3, that is, a value that is 2/3 of the 1/3 sound wave minimum value H1 and the sound wave minimum value H3 in addition to the minimum value H3 , And the 2/3 sound wave minimum value (H2) can be used as the acceleration pulse wave parameter (acceleration pulse wave characteristic point).

The calculation processing unit 300 calculates the maximum value (a) of the initial positive shaking wave, the minimum value (b) of the initial negative shrinkage, the maximum value (c) of the contraction middle rising wave and the minimum value The slope (SL), the minimum value of the negative sound (H3), the minimum value of the negative wave at the beginning of the contraction (b) and the minimum value (d) , The 1/3 sound wave minimum value (H1), and the 2/3 sound wave minimum value (H2), it is determined whether or not there is a waveform of the same type among the existing waveforms stored in the storage unit 450 If there is the same waveform, the counter of the waveform is incremented and stored. If it is determined that there is no waveform of the same type, a new type of waveform is registered in the storage unit 450, and a counter of the new waveform is generated. When all of the pre-stored data is analyzed in this manner, or when the end signal is input from the key input unit 430, the waveforms stored in the storage unit 450 and the counter for each wave type (for each waveform, That is, the number of detected waves by each wave type) and outputs them to the output unit 410.

The arithmetic processing unit 300 selects a waveform having the largest counter value for each wave type, that is, a waveform having the largest number of detected waves by each wave type, and calculates a minimum value (b) of the initial sound wave at the initial shrinkage of the representative waveform, a maximum value ) And the minimum value (d) of the lowering wave in the late phase of contraction are used to analyze the cardiac output intensity, peripheral vascular elasticity, and residual blood volume to grasp the blood vessel condition. Depending on the representative waveform of the blood vessel aging waveform Estimate blood vessel senescence. Depending on the degree of aging of the blood vessels, blood circulation disturbance, arteriosclerosis, etc. can be estimated.

The output unit 410 includes a monitor or a printer, and outputs a value received from the operation processing unit 300. That is, the output unit 410 outputs the number detected by the user according to the waveforms and the waveforms received by the operation processing unit 300. Further, the representative waveform received by the calculation processing unit 300 is output, and the minimum value (b), the maximum value (c), and the minimum value (d) of the late contraction period wave And outputs an analysis result of the estimated aging degree and the like.

The key input unit 430 includes a start key and an end key, and transmits the input key value to the arithmetic processing unit 300. In some cases, the detection time of the pulse wave detected through the key input unit 430 may be stored. Accordingly, the operation processing unit 300 determines the amount of data of the pulse wave temporarily stored in the storage unit 450 for waveform analysis, and determines whether the analysis of all the pulse wave data is completed based on the amount of the data.

The storage unit 450 stores data of each waveform pattern. (A), the minimum value of the negative initial wave of contraction (b), the maximum value of the contralateral re-emergence wave (c), and the minimum value of the descending wave of contraction (d ), And stores the time intervals of these together. At the time of factory shipment, seven waveforms that are basically classified into the storage unit 450 are stored.

In addition, the storage unit 450 temporarily stores the pulse wave signal detected by the signal detector 100 for waveform analysis. The pulse wave signal is detected by the signal detecting unit 100 and transmitted to the arithmetic processing unit 300 through the signal preprocessing unit 200. The arithmetic processing unit 300 temporarily stores the pulse wave signal in the storage unit 450. [

3 is an example of a waveform pattern stored in the storage section.

3 is an example of a waveform stored as a waveform that is basically classified into the storage unit 450 at the time of factory shipment.

3 (a) shows the slope SL between the minimum value b of the initial shrinkage negative sound wave and the minimum value d of the late contraction period is greater than 0, and the maximum value c of the shrinkage mid- And the minimum value (d) of the late contraction wave is equal to or greater than the 2/3 sound wave minimum value (H2). FIG. 3 (a) can be regarded as a blood vessel aging one-step waveform.

3B is a graph showing the relationship between the minimum value b of the initial sound wave at the initial stage of contraction and the slope SL of the minimum value d of the late contraction period and the maximum value c of the contraction mid- Is equal to or greater than the minimum sound wave amplitude value (H1), and the minimum value (d) of the late contraction period wave is greater than or equal to the 1/3 sound wave minimum value (H1). FIG. 3 (b) shows a two-stage waveform of blood vessel aging.

3 (c) shows the slope SL between the minimum value b of the initial sound wave at the initial shrinkage and the minimum value d of the late period of the late contraction is greater than 0, and the maximum value c of the contraction mid- Is equal to or greater than the minimum value H1 of the voice wave and the minimum value d of the late contraction wave is smaller than the 1/3 voice minimum value H1 and greater than or equal to the minimum voice wave value H3. FIG. 3 (c) can be referred to as a three-stage waveform of blood vessel aging.

3 (d) shows the slope SL between the minimum value b of the initial shrinkage negative sound wave and the minimum value d of the late contraction period is less than or equal to 0, and the maximum value c of the shrinkage mid- Is smaller than the 1/3 sound wave minimum value (H1), and the minimum value (d) of the late contraction late wave is smaller than or equal to the 2/3 sound wave minimum value (H2). Fig. 3 (d) can be regarded as a four-step waveform of blood vessel aging.

3 (e) shows the slope (SL) of the minimum value (b) and the minimum value (d) of the late contraction late wave when the shrinkage initial sound wave is less than 0 and the minimum value (b) Is greater than or equal to the minimum sound wave H2 and the maximum value c of the mid-contraction period reef wave is greater than or equal to the 2/3 sound wave minimum value H2. FIG. 3 (e) can be regarded as a five-step waveform of blood vessel aging.

(F) of FIG. 3 shows that the slope SL of the minimum contraction early sound wave b and the minimum contraction late wave d is less than 0 and the minimum value b of the initial contraction sound wave is 1/3 Is greater than or equal to the minimum value H1 of the voice wave. FIG. 3 (f) is a 6-stage waveform of blood vessel aging.

3 (g) shows the slope SL of the minimum value b of the initial sound wave at the initial shrinkage and the minimum value d of the late period of the contracting period is smaller than 0, f). FIG. 3 (g) can be referred to as a 7-stage waveform of blood vessel aging.

FIG. 4 is an explanatory view for explaining a method of determining the degree of blood vessel aging using the waveform pattern of FIG. 3;

The operation processing unit 300 compares the representative waveform with the waveform of the first stage of the blood vessel aging to the waveform of the seventh stage of the blood vessel aging to determine the degree of aging of the blood vessel.

In the determination step of the first stage of vascular aging, the calculation processing unit 300 compares the representative waveform with the waveform of the first stage of vascular aging shown in Fig. 3 (a), and if it is the same, it determines the first stage of vascular aging. That is, the calculation processing unit 300 determines whether the slope SL of the minimum value b of the initial sound wave at the initial contraction of the representative waveform and the minimum value d of the late-contraction late falling wave is greater than 0, (c) is greater than or equal to 0 and the minimum value (d) of the late contraction late wave of the representative waveform is greater than or equal to the 2/3 sound wave minimum value (H2), it is determined to be the first stage of the blood vessel aging.

Here, the minimum value H3 of sound wave, the minimum value H3 of 1/3 sound wave, and the minimum value H2 of 2/3 sound wave are the minimum value H3 of the sound wave in the first stage of the blood vessel aging, the minimum value H3 ) And a 2/3 sound wave minimum value (H2). The minimum value H3 of the sound wave, the minimum value H3 of the 1/3 sound wave and the minimum value H2 of the sound wave 2/3 are the minimum value H3 of the representative waveform and the minimum value H1 of the 1/3 sound wave, , And a 2/3 sound wave minimum value (H2).

If it is not the first stage of the aging of the blood vessels and the second stage of the aging of the blood vessels, the calculation processing unit 300 compares the representative waveform with the two-stage waveform of the aging of the blood vessels of FIG. 3 (b) , And blood vessel aging (2). That is, the calculation processing unit 300 determines whether the slope SL of the minimum value b of the initial sound wave at the initial contraction of the representative waveform and the minimum value d of the late-contraction late falling wave is greater than 0, (c) is greater than or equal to the 1/3 sound wave minimum value (H1) and the minimum value (d) of the late contraction late wave of the representative waveform is greater than or equal to the 1/3 sound wave minimum value (H1) Step.

If it is not the second stage of the aging of the blood vessels at the stage of determining whether the aging of the blood vessels is the second stage, the operation processing unit 300 compares the representative waveform with the three stages of the aging of the blood vessels of FIG. 3 (c) , And three stages of vascular aging. That is, the calculation processing unit 300 determines whether the slope SL of the minimum value b of the initial sound wave at the initial contraction of the representative waveform and the minimum value d of the late-contraction late falling wave is greater than 0, (c) is greater than or equal to the 1/3 sound wave minimum value (H1), the minimum value (d) of the late contraction late wave of the representative waveform is smaller than the 1/3 sound wave minimum value (H1) If it is greater than or equal to, it is judged to be the third stage of vascular aging.

The arithmetic processing unit 300 compares the representative waveform with the four-stage waveform of the vascular aging in (d) of Fig. 3, and if it is equal to , And 4 stages of vascular aging. That is, the calculation processing unit 300 determines whether the inclination SL of the minimum value b of the initial sound wave at the initial contraction of the representative waveform and the minimum value d of the latter period of the contraction late period is equal to or less than 0, Is smaller than the 1/3 sound wave minimum value (H1) and the minimum value (d) of the late contraction late wave of the representative waveform is smaller than or equal to the 2/3 sound wave minimum value (H2) It is judged as the fourth step.

If it is determined that the blood vessel aging is not the fourth stage, the arithmetic processing unit 300 compares the representative waveform with the blood vessel aging 5-stage waveform of FIG. 3 (e) , And 5 stages of vascular aging. That is, the calculation processing unit 300 determines that the inclination SL of the minimum value b of the initial sound wave at the initial contraction of the representative waveform and the minimum value d of the late contraction late wave is less than 0, (b) is greater than or equal to the 2/3 sound wave minimum value (H2), and the maximum value (c) of the shrunken midterm reentrant wave of the representative waveform is greater than or equal to the 2/3 sound wave minimum value (H2) It is judged to be the fifth step.

If it is determined that the blood vessel aging is at the sixth stage, and if the blood vessel aging at the fifth stage is not at the fifth stage, the arithmetic processing unit 300 compares the representative waveform with the blood vessel aging 6th stage waveform at (f) , And 6 stages of vascular aging. That is, the calculation processing unit 300 determines that the inclination SL of the minimum value b of the initial sound wave at the initial contraction of the representative waveform and the minimum value d of the late contraction late wave is less than 0, (b) is greater than or equal to the 1/3 sound wave minimum value (H1), it is determined that the waveform is a 6-stage blood vessel aging.

If the blood vessel aging is not the sixth step in the determination step of the blood vessel aging 6 step, the calculation processing part 300 compares the representative waveform with the seventh step waveform of FIG. 3 (g) , And 7 stages of vascular aging. That is, the calculation processing unit 300 determines that the inclination SL of the minimum value b of the initial sound wave at the initial contraction of the representative waveform and the minimum value d of the late-contraction late falling wave is less than 0, , It is judged that the blood vessel is aging 7 stage.

(C) is smaller than the 1/3 sound wave minimum value (H1) in the step of determining whether or not the blood vessel aging is at step 7, If it is small, it is judged to be the fourth stage of vascular aging, and if not, it is judged to be the third stage of vascular aging.

5 is a flowchart schematically illustrating a method of analyzing an acceleration pulse wave parameter according to an embodiment of the present invention. That is, FIG. 5 is an example of a method of driving the arithmetic processing unit of the apparatus for analyzing an acceleration pulse wave parameter of FIG.

In the pulse wave signal receiving step, the operation processing unit 300 receives the pulse wave signal from the A / D converting unit 230 (S110).

In the pulse wave signal second differentiation step, the pulse wave signal received in the pulse wave signal receiving step is second-differentiated to detect the acceleration pulse wave (S120).

(A), the minimum value of the initial negative shrink wave (b), and the shrinkage mid-wave reentrant wave in a period of one cycle from the acceleration pulse wave detected in the second-order differential phase of the pulse wave signal, A maximum value (c), a minimum value (d) of the late contraction period, and a time interval therebetween are detected (S130).

The similarity to the existing waveform pattern is compared with the acceleration pulse wave feature points detected in the acceleration pulse wave feature point detection step and the acceleration pulse wave feature points of the existing waveform pattern stored in the storage unit 450, (S140).

In a new waveform pattern generation step, if there is no similar waveform pattern in the similarity determination step, the current acceleration waveform waveform and the acceleration waveform waveform characteristic point are stored as a new waveform pattern, and a new waveform pattern counter is generated (S150) .

If there is the same waveform pattern in the step of increasing the existing waveform pattern counter and judging whether the existing waveform pattern is similar to the existing waveform pattern, the existing waveform pattern counter is incremented (S160).

If the end key is turned on from the key input unit 430 or the pulse wave signal is no longer received from the A / D conversion unit 230, or if all the data for the predetermined detection time are analyzed If it is determined that the waveform detection should not be terminated, the process proceeds to step S 130 for detecting the characteristic of the accelerogram pulse, and detects the characteristic point of the accelerogram pulse of the next cycle at step S 170.

In the representative waveform pattern selection step, if it is determined in the waveform waveform end determination step that the waveform detection should be terminated, the counter value of the waveform pattern is compared and the waveform pattern having the maximum value is selected as the representative waveform pattern (S180).

In step S185, the degree of vascular aging is determined by comparing the waveform of the first stage of the aging of the blood vessels or the seventh stage of the aging of the blood vessels stored in the storage unit 450 with the representative waveform selected in the representative waveform pattern selection step.

In the representative waveform pattern output step, the representative waveform pattern selected in the representative waveform pattern selection step, the acceleration pulse wave feature points thereof, and the blood vessel aging step determined in the blood vessel senility determination step are output (S190).

6 is a flowchart schematically illustrating a method of analyzing an acceleration pulse wave parameter according to another embodiment of the present invention.

In the pulse wave signal receiving step, the operation processing unit 300 receives the pulse wave signal from the A / D converting unit 230 (S110).

In the pulse wave signal second differentiation step, the pulse wave signal received in the pulse wave signal receiving step is second-differentiated to detect the acceleration pulse wave (S120).

(A), the minimum value of the initial negative shrink wave (b), and the shrinkage mid-wave re-enhancement wave The maximum value c, the minimum value d of the descending wave in the late period of contraction, and the characteristic point of the acceleration pulse wave in the time interval between them.

The inclination SL of the minimum value b of the negative sound wave at the initial stage of contraction and the minimum value d of the lagging wave of the late contraction period is detected at step S137.

In the determination step of the first stage of the blood vessel aging, the arithmetic processing unit 300 compares the waveform of the acceleration pulse wave with the waveform of the first stage of the blood vessel aging (S138). The counter of the first stage waveform of the blood vessel aging is increased (S139), and the process goes to the waveform determination completion step (S170). That is, the calculation processing unit 300 determines whether the slope SL of the minimum value b of the initial sound wave at the initial contraction of the waveform of the acceleration pulse wave and the minimum value d of the late-contraction late wave is greater than 0, If the maximum value c of the wave is greater than or equal to 0 and the minimum value d of the late contraction late wave of the waveform of the acceleration pulse wave is equal to or greater than the 2/3 sound wave minimum value H2, do.

If it is determined that the blood vessel aging is not the first stage, the arithmetic processing unit 300 compares the waveform of the acceleration pulse wave with the waveform of the second stage of the blood vessel aging (S141) It is judged to be two stages of aging. The counter of the two-stage waveform of the aging of blood vessels is increased (S142), and the process goes to the waveform detection end determination step S170. That is, the calculation processing unit 300 determines whether the slope SL of the minimum value b of the initial sound wave at the initial contraction of the representative waveform and the minimum value d of the late-contraction late falling wave is greater than 0, (c) is greater than or equal to the 1/3 sound wave minimum value (H1) and the minimum value (d) of the late contraction late wave of the representative waveform is greater than or equal to the 1/3 sound wave minimum value (H1) Step.

If it is determined that the blood vessel aging is not the second stage, the arithmetic processing unit 300 compares the waveform of the acceleration pulse wave with the waveform of the third stage of the blood vessel aging (S143) Three stages of aging are judged. The counter of the three-stage waveform of the aging of the blood vessel is increased (S144), and the process goes to the waveform detection end determination step S170. That is, the calculation processing unit 300 determines whether the slope SL of the minimum value b of the initial sound wave at the initial contraction of the representative waveform and the minimum value d of the late-contraction late falling wave is greater than 0, (c) is greater than or equal to the 1/3 sound wave minimum value (H1), the minimum value (d) of the late contraction late wave of the representative waveform is smaller than the 1/3 sound wave minimum value (H1) If it is greater than or equal to, it is judged to be the third stage of vascular aging.

If it is determined that the blood vessel aging is not the third stage, the arithmetic processing unit 300 compares the waveform of the acceleration pulse wave with the waveform of the blood vessel aging 4 stage (S145) It is judged to be four stages of aging. The counter of the four-stage waveform of the blood vessel aging is increased (S146), and the process goes to the waveform detection end determination step S170. That is, the calculation processing unit 300 determines whether the inclination SL of the minimum value b of the initial sound wave at the initial contraction of the representative waveform and the minimum value d of the latter period of the contraction late period is equal to or less than 0, Is smaller than the 1/3 sound wave minimum value (H1) and the minimum value (d) of the late contraction late wave of the representative waveform is smaller than or equal to the 2/3 sound wave minimum value (H2) It is judged as the fourth step.

If it is not the fourth stage of the aging of the blood vessels, the arithmetic processing unit 300 compares the waveform of the acceleration pulse wave with the waveform of the fifth stage of the aging of blood vessels (S147) It is judged to be five stages of aging. The counter of the 5-stage waveform of the blood vessel aging is increased (S148), and the process goes to the waveform determination completion step (S170). That is, the calculation processing unit 300 determines that the inclination SL of the minimum value b of the initial sound wave at the initial contraction of the representative waveform and the minimum value d of the late contraction late wave is less than 0, (b) is greater than or equal to the 2/3 sound wave minimum value (H2), and the maximum value (c) of the shrunken midterm reentrant wave of the representative waveform is greater than or equal to the 2/3 sound wave minimum value (H2) It is judged to be the fifth step.

If it is determined that the blood vessel aging is not the fifth stage, the arithmetic processing unit 300 compares the waveform of the acceleration pulse wave with the waveform of the sixth stage of the blood vessel aging (S151) It is judged to be six stages of aging. The counter of the 6-stage waveform of the blood vessel aging is increased (S152), and the process goes to the waveform determination end step (S170). That is, the calculation processing unit 300 determines that the inclination SL of the minimum value b of the initial sound wave at the initial contraction of the representative waveform and the minimum value d of the late contraction late wave is less than 0, (b) is greater than or equal to the 1/3 sound wave minimum value (H1), it is determined that the waveform is a 6-stage blood vessel aging.

If it is determined that the blood vessel aging is not the sixth stage, the arithmetic processing unit 300 compares the waveform of the acceleration pulse wave with the waveform of the seventh stage of the blood vessel aging (S153) It is judged to be 7 stages of aging. The counter of the seventh-stage waveform of the blood vessel aging is incremented (S154), and the process goes to the waveform detection end determination step S170. That is, the calculation processing unit 300 determines that the inclination SL of the minimum value b of the initial sound wave at the initial contraction of the representative waveform and the minimum value d of the late-contraction late falling wave is less than 0, , It is judged that the blood vessel is aging 7 stage.

(The other blood vessel aging step determination step) to determine the blood vessel aging step to be a more similar blood vessel aging step, and if the blood vessel aging step is not the seventh step, the maximum value (c) of the contraction mid- (Step S155). If it is smaller, it is determined to be the fourth stage of vascular aging. Then, the counter of the fourth stage of vascular aging is increased (S156) If it is not small, it is determined to be three stages of blood vessel aging, and the counter of the three stages of blood vessel aging is increased (S157).

In step S 170, it is determined whether or not the number of times counter is equal to the number set in the beginning. If not, the number of times of data analysis The sequence number counter is incremented (S175), and the process proceeds to the acceleration pulse wave parameter detection step (S130) to detect the acceleration pulse wave parameter of the next cycle.

The method according to claim 1, wherein, in the step of selecting a representative waveform pattern, when it is determined in the step of determining whether or not waveform detection should be ended, a waveform pattern having a maximum value is selected as a representative waveform pattern by comparing waveform pattern counter values, If there are waveform patterns having the same counter value as the waveform pattern, a waveform pattern having a high degree of senescence step is selected as the representative waveform pattern (S182).

In the representative waveform pattern generation step, the representative waveform pattern selected in the representative waveform pattern selection step is read from the storage unit 450 and outputted to the output unit 410 (S184).

In the representative waveform pattern characteristic point output step, characteristic points of the representative waveform selected in the representative waveform pattern selection step are read from the storage unit 450 and outputted to the output unit 410 (S186).

In step of outputting the degree of aging of blood vessels, a number of steps of the blood vessel aging step are output according to the representative waveform selected in the representative waveform pattern selection step (S192).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, Modification is possible. Accordingly, it is intended that the scope of the invention be defined by the claims appended hereto, and that all equivalent or equivalent variations thereof fall within the scope of the present invention.

100: Signal detection unit 110:
120: light receiving unit 200: signal preprocessing unit
300: operation processing unit 410:
430: key input unit 450:

Claims (26)

A signal detection unit for detecting a pulse wave signal of an arterial blood flow in the arterioles of a finger, an earlobe, or a toe, a signal preprocessing unit for amplifying the pulse wave signal detected by the signal detection unit, removing noise and converting the pulse wave into a digital signal, And an arithmetic processing unit for performing second differentiation on the received pulse wave signal to detect an acceleration pulse wave, the arithmetic processing unit comprising:
(A), the minimum value of the negative initial wave of contraction (b), the maximum value of the contralateral reentry wave (c), and the minimum value of the contraction late wave (d) As a feature point of the image,
If there is a waveform pattern having the characteristic points of the acceleration pulse wave that is the same as the characteristic point of the acceleration pulse wave of the current cycle by comparing the characteristic points of the acceleration pulse wave of the current cycle with the characteristic points of the acceleration pulse wave of the waveform patterns previously stored in the storage section, If there is no waveform pattern having the characteristic point of the acceleration pulse wave such as the characteristic point of the acceleration pulse wave of the present cycle, the waveform and the characteristic point of the acceleration pulse wave of the current cycle are updated to a new value Stores it as a waveform pattern, generates a new waveform pattern counter,
A waveform pattern having a waveform pattern counter value having a maximum value among the stored waveform pattern counter values is selected as a representative waveform pattern, and waveforms and minutiae points of an acceleration pulse wave of a representative waveform pattern are output to an output section,
The arithmetic processing unit estimates the degree of senescence of blood vessels using the characteristic points of the acceleration pulse wave of the representative waveform pattern, obtains the slope (SL) from the minimum point of the initial sound wave at the initial shrinkage of the representative waveform and the minimum point of the descending wave of the late contraction, SL), the minimum value (b) of the initial sound wave at the initial shrinkage of the representative waveform, the maximum value (c) of the shrinkage middle reentrant wave of the representative waveform, and the minimum value (d) Wherein the pulse wave analyzer comprises: The method according to claim 1,
The characteristic points of the acceleration pulse wave are the time value of the minimum point of the negative initial wave of contraction, the time value of the maximum point of the contraction mid-reentry wave based on the time value of the maximum point of the initial positive wave of contraction, And a time value of the pulse wave of the pulse wave. delete delete The method according to claim 1,
The calculation processing section sets a value having a smaller value among the minimum value b of the initial sound wave at the initial contraction of the representative waveform and the minimum value d of the late contraction late wave as the sound wave minimum value H3,
A value that is 1/3 of the minimum value of the sound wave minimum value (H3) is set as a 1/3 sound wave minimum value (H1)
Wherein a value that is 2/3 of the magnitude of the minimum sound wave amplitude value (H3) is set as a 2/3 sound wave minimum value (H2). 6. The method of claim 5,
The arithmetic processing unit may be configured such that the inclination SL is greater than 0 and the maximum value c of the shrunken middle rising wave of the representative waveform is greater than or equal to 0 and the minimum value d of the shrunken lower- 3 > sound wave minimum value (H2), the determination means determines that the representative waveform is a waveform of the first stage of blood vessel aging. The method according to claim 6,
The computation processing unit may be configured such that the inclination SL is greater than 0 and the maximum value c of the contraction mid-wave reentrant wave of the representative waveform is greater than or equal to the 1/3 sound wave minimum value H1, Wherein the representative waveform is a waveform of the second stage of the blood vessel aging if the minimum value d of the first pulse wave is greater than or equal to the 1/3 sound wave minimum value H1. 8. The method of claim 7,
The computation processing unit may be configured such that the inclination SL is greater than 0 and the maximum value c of the contraction mid-wave reentrant wave of the representative waveform is greater than or equal to the 1/3 sound wave minimum value H1, Is smaller than or equal to the minimum sound wave minimum value (H3) and smaller than or equal to the minimum sound wave maximum value (H3), while the minimum value (d) Accelerometer pulse wave analyzer. 9. The method of claim 8,
The computation processing unit may be configured such that the inclination SL is less than or equal to 0 and the maximum value c of the contraction mid-wave reentrant wave of the representative waveform is smaller than the 1/3 sound wave minimum value H1, Wherein when the minimum value d of the wave is smaller than or equal to the 2/3 sound wave minimum value H2, the representative waveform is judged to be a waveform of four stages of blood vessel aging. 10. The method of claim 9,
The arithmetic processing unit may be configured such that the inclination SL is less than 0 and the minimum value b of the initial sound wave at the initial shrinkage of the representative waveform is less than or equal to the 2/3 sound wave minimum value H2, Wherein the representative waveform is determined as a waveform of five stages of blood vessel aging if the maximum value c of the first and second waveforms is smaller than or equal to the minimum value H2 of the 2/3 sound wave. 11. The method of claim 10,
If the inclination SL is less than 0 and the minimum value b of the initial sound wave at the contraction of the representative waveform is equal to or greater than the 1/3 sound wave minimum value H1, Is judged to be a waveform of 6 stages of blood vessel aging. 12. The method of claim 11,
In the arithmetic processing unit, the arithmetic processing unit determines that the waveform is of the seventh stage of vascular aging, unless the inclination SL is smaller than 0 and is not one of the waveforms of the first stage of vascular aging to the sixth stage of vascular aging An acceleration pulse wave analyzer. The apparatus according to claim 1, wherein the arithmetic processing unit
A sample having a maximum positive value greater than a predetermined a detection threshold value among the samples of the acceleration pulse wave is detected as the maximum point of the initial positive wave of contraction and a maximum positive value larger than a detection threshold is detected as the maximum value of the positive initial wave of contraction And detects a time value of the maximum point of positive waves at the initial shrinkage. 14. The apparatus of claim 13, wherein the arithmetic processing unit
The method includes detecting inflection points having two minimum negative values smaller than a preset negative wave detection threshold among samples of an acceleration pulse wave and comparing a sample having an inflection point close to a maximum point of a contraction initial positive wave among the inflection points to a minimum And detects a sample having an inflection point far from a maximum point of a contraction initial positive wave among the inflection points as a minimum point of a late contraction period falling wave. 15. The image processing apparatus according to claim 14,
(B) of the initial sound wave at the initial contraction, which is the size of the minimum point of the initial sound wave at the time of contraction,
As the time value of the minimum point of the initial negative wave of contraction on the basis of the maximum point of the positive initial wave of contraction at the time point of the minimum point of the initial negative wave of contraction from the maximum point of the initial positive wave of contraction, Accelerometer pulse wave analyzer. 16. The image processing apparatus according to claim 15,
The minimum value (d) of the last wave of the late contraction, which is the magnitude of the minimum point of the last wave of contraction,
Characterized in that the time interval between the maximum point of the initial contraction early positive wave and the minimum point of the late contraction late wave is detected as the time value of the minimum point of the late contraction late wave, Accelerometer pulse wave analyzer. 17. The apparatus according to claim 16, wherein the arithmetic processing unit
A sample having a maximum value is searched among the samples of the acceleration pulse wave between the minimum point of the initial negative wave of contraction and the minimum point of the late contraction period and detected as the maximum point of the contraction middle reentry wave, The magnitude is detected as the maximum value (c) of the mid-contraction re-
As the time value of the maximum point of the contraction mid-reentry wave based on the maximum point of the initial positive bending wave as the time interval of the maximum point of the contraction mid-reentry wave from the maximum point of the initial bending wave of contraction, Accelerometer pulse wave analyzer. 13. The method of claim 12,
Wherein the storage unit stores the characteristic points of the acceleration pulse wave of the waveform of the first stage of the blood vessel aging to the waveform of the seventh stage of the blood vessel aging and the waveform of the first stage of the blood vessel aging to the seventh stage of the aging of the blood vessel. delete delete delete delete An arithmetic processing part for receiving a pulse wave signal detected from the arteriovenous artery of a finger or an earlobe or a toe and detecting an acceleration pulse wave by secondary differentiation;
(A), the minimum value of the negative initial wave of contraction (b), the maximum value of the contraction mid-reentry wave (c), the contraction late fall (c) An acceleration pulse wave feature point detection step of detecting an acceleration pulse wave feature point including a slope (SL) obtained by finding a minimum value (d) of a wave, a minimum point of an initial negative wave of contraction, and a minimum point of a late contraction period;
The computation processing unit determines that the slope SL is greater than 0 and the maximum value c of the contraction mid-wave reentry wave is greater than or equal to 0 and the minimum value d of the late contraction period wave is less than the 2/3 sound wave minimum value H2, Determining whether the waveform of the acceleration pulse wave is equal to the waveform of the first stage of vascular aging and increasing the waveform counter of the first stage of vascular aging;
The computation processing unit determines that the slope SL is greater than 0 and the maximum value c of the contraction mid-reentry wave is greater than or equal to the 1/3 sound wave minimum value H1 and the minimum value d of the late- Determining whether the waveform of the acceleration pulse wave is the same as the waveform of the second stage of the blood vessel aging and increasing the waveform counter of the second stage of the blood vessel aging if the pulse wave is greater than or equal to the minimum sound wave minimum value H1;
The computation processing unit determines that the slope SL is greater than 0 and the maximum value c of the contraction mid-reentry wave is greater than or equal to the 1/3 sound wave minimum value H1 and the minimum value d of the late- / 3 sound wave minimum value H1 and is greater than or equal to the sound wave minimum value H3, it is determined that the waveform of the acceleration pulse wave is the same as the waveform of the third stage of the blood vessel aging, and the waveform counter of the third stage of the blood vessel aging is increased , A step of determining whether or not the blood vessel is aged in three stages;
The computation processing unit determines that the slope SL is less than or equal to 0 and the maximum value c of the contraction mid-reentry wave is smaller than the 1/3 sound wave minimum value H1 and the minimum value d of the late- Determining whether the waveform of the acceleration pulse wave is equal to the waveform of the fourth stage of vascular aging and increasing the waveform counter of the fourth stage of vascular aging if the pulse wave is less than or equal to the 2/3 sound wave minimum value H2;
If all of the analysis of the detection data of the predetermined pulse wave signal is completed, the arithmetic processing unit determines whether or not all of the analysis of the previously detected data has been completed. Then, the counter values of the waveform pattern are compared with each other, A representative waveform pattern selection step of selecting a representative waveform pattern;
Wherein the pulse wave analyzing apparatus comprises: 24. The method of claim 23,
Between the step of determining whether the blood vessel aging is the third stage and the representative waveform pattern selection step,
The computation processing unit may be configured such that the slope SL is less than 0 and the minimum value b of the initial sound wave of contraction is greater than or equal to the 2/3 sound wave minimum value H2 and the maximum value c of the contraction mid- Determining whether the waveform of the acceleration pulse wave is the same as the waveform of the fifth stage of the vascular aging and increasing the waveform counter of the fourth stage of vascular aging if the difference is greater than or equal to the 2/3 sound wave minimum value (H2);
If the slope SL is less than 0 and the minimum value b of the initial sound wave at the contraction is greater than or equal to the 1/3 sound wave minimum value H1, then the arithmetic processing unit determines that the waveform of the acceleration pulse wave is the waveform Determining whether the blood vessel aging 6 step is equal to the blood vessel aging 6 step;
The arithmetic processing unit determines that the waveform of the acceleration pulse wave is the same as the waveform of the blood vessel aging 7 stage if the slope SL is less than 0 and is not the same as any one of the waveforms of the first stage of vascular aging to the waveform of the sixth stage of vascular aging, A seventh stage determination step of increasing the waveform counter of the seventh stage of vascular aging;
Further comprising the step of: detecting a pulse wave from the pulse wave. 25. The method of claim 24,
If it is not the seventh stage of the aging of the blood vessels, it is judged whether the maximum value (c) of the contraction middle reentry wave is smaller than the 1/3 sound wave minimum value (H1), and if so, Determining an aging phase of the blood vessel aging; increasing the counter of the four-stage waveform of the aging of the blood vessels;
Further comprising the step of: detecting a pulse wave from the pulse wave. 26. The method of claim 25,
A representative waveform pattern output step of outputting the representative waveform pattern and its acceleration pulse wave characteristic points selected in the representative waveform pattern selection step;
Further comprising the steps of: detecting a pulse wave of the pulse wave from the pulse wave;

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