KR100480779B1 - Apparatus for measuring valuable PPG - Google Patents

Abstract

The present invention relates to a volumetric pulse wave measurement system for determining an effective volume pulse wave by determining whether a subject is stabilized. A volumetric pulse wave measuring system for determining an effective volume pulse wave by determining whether a subject is stabilized, comprising: temperature measuring means for measuring skin temperature; Heart rate measurement means for measuring a heart rate variation when it is determined that the skin temperature measured by the temperature measuring means is a stable value; And a data processing unit for determining whether the volume pulse wave is effective by measuring a DC drift from the volume pulse wave measured by the volume pulse wave measuring means when the heart rate variation is determined to be a stable value. A volumetric pulse wave measurement system for measuring effective volumetric pulse waves is provided. According to the present invention, the reliability of the data can be secured by removing the influence of the external environment on the subject, that is, the noise factor due to stress, and then measuring the volume pulse wave.

Description

Volumetric pulse wave measuring system for determining effective volume pulse wave by judging whether or not the subject is stabilized {Apparatus for measuring valuable PPG}

The present invention relates to a volumetric pulse wave measurement system for determining an effective volume pulse wave by determining whether a subject is stabilized.

A volume pulse wave (PPG: PhotoPlethysmoGraphy) is a light source of a light emitting unit and refers to a light quantity signal of light transmitted through a finger region after irradiating light of a specific wavelength to a finger region of a human body. Background Art Conventionally, various attempts have been made to determine the presence or absence of diseases of the cardiovascular system by using volumetric pulse waves, or to determine the extent of disease or the hardness of blood vessels. In recent years, development of a bloodless diagnostic technique for measuring hemoglobin concentration in blood using volumetric pulse waves has been attempted.

In general, there are various noise factors that need to be considered and prevented for accurate volumetric pulse wave measurement in various types of tasks in which a subject uses a volumetric pulse wave to detect a cardiovascular disease or the degree of cardiovascular disease.

Whether the noise component of the volumetric pulse wave waveform measured by a conventional volumetric pulse wave measuring device is caused by a pathology, a pure mechanism in the subject's body, an external thermal environment, an unstable posture of the subject, or a tension state of the subject. Could not be clearly distinguished.

When estimating the concentration of hemoglobin based on the volume pulse wave collected using light, the waveform change of the volume pulse wave has a great influence on the estimate. There are many factors that determine the volumetric pulse wave waveform. The pattern of the volumetric pulse wave varies depending on factors such as cardiovascular disease, the presence of stress, the subject's posture, and the external thermal environment such as extremely low and high temperatures. Form.

In particular, when the psychological state of tension is maintained due to stress, the amplitude of the volume pulse wave decreases, and thus, a pattern passing through the low pass filter is generally compared with that of the psychological relaxation state. This is easily observed even in the volume pulse wave pattern measured in the lying and sitting state of the same subject.

As such, the psychological tension or external thermal environment acts as a noise factor in estimating hemoglobin concentration based on volumetric pulse waves. Therefore, in order to accurately estimate the hemoglobin concentration by the volume pulse wave, such noise factor should be excluded as much as possible.

Changes that occur when the human body is exposed to a stressful environment can be variously listed. For example, when the human body is stressed, the heart rate increases, and the amplitude of the R-peak of the ECG and the amplitude of the breathing curve decrease. In addition, when exposed to low temperatures, the skin temperature of the finger corresponding to the distal end of the human body is rapidly reduced, such a decrease in the skin temperature will show a physiological change similar to the state exposed to the stress environment.

Human body temperature can be largely divided into skin temperature and core temperature. The skin temperature of each part of the human body varies from the maximum of about 2 degrees Celsius to the minimum of about 0.5 degrees Celsius based on the normal body temperature according to the region of the human body. Is known to be lower than average. Figure 1a shows the changes in the volumetric pulse wave waveform at normal skin temperature, Figure 1b shows the changes in the volumetric pulse wave waveform at a temperature lower than the normal skin temperature. And, when exposed to a stress environment or already under stress, the value is generally reduced. In other words, the skin temperature of the distal end of the human body is distributed in a temperature range of about 1 to 2 degrees lower than the normal body temperature of about 36.5 degrees Celsius, the skin temperature is reduced when the human body is stressed.

Therefore, in order to proceed with a series of tasks for measuring the physiological phenomena or blood components of the body using the volumetric pulse wave, it is required that the human body of the subject should be a clear measurement of the volumetric pulse wave in a normal state.

However, in the conventional volumetric pulse wave measuring apparatus, a volume pulse wave is accurately measured by measuring a volume pulse wave without taking into consideration the temperature of the subject's skin and the physiological stability of the subject while measuring the finger of the distal end of the human body. There is a problem that shows limitations.

In order to solve the above problems, an object of the present invention is to provide a volumetric pulse wave measuring system for measuring effective volumetric pulse wave by determining whether or not the subject is stabilized so that the subject's human body can show the volumetric pulse wave result in a normal state. do.

In the present invention, in order to achieve the above object, in the volumetric pulse wave measuring system for measuring the effective volume pulse wave by determining whether or not to stabilize the subject, a temperature measuring means for measuring the skin temperature; the skin temperature measured by the temperature measuring means If heart rate is determined to be a stable value, heart rate measurement means for measuring the heart rate variation; And a data processing unit for determining whether the volume pulse wave is effective by measuring DC drift from the volume pulse wave measured by the volume pulse wave measuring means when the heart rate variation is determined to be a stable value. Provided is a volumetric pulse wave measuring system for measuring an effective volumetric pulse wave. In the present invention, the volumetric pulse wave measuring means is formed to be open and close, a probe on which a subject is seated, and a light emitting part formed at one end of the probe to irradiate light. And a light receiving unit formed at the other end of the probe to receive the light irradiated from the light emitting unit, wherein the temperature measuring unit includes an infrared temperature measuring unit formed at one end of the probe, a thermocoupler or a thermometer formed at the bottom of the probe. It is characterized in that one. In the present invention, the skin temperature is If more than about 34.5 is also characterized by measuring the heart rate with the heart rate measuring means it is judged as being stable. In the present invention, the heart rate variation is measured by the heart rate measuring means after at least 10 seconds after the determination of the stabilization of the skin temperature, characterized in that the effective volume pulse wave is measured by determining whether the subject is stabilized.

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Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

2 is a view showing a simplified structural diagram of a volume pulse wave measuring apparatus according to the present invention. A typical volumetric pulse wave measuring device is a probe (11, 12) consisting of the upper and lower ends, a stopper (not shown) for fixing the position of the subject finger and the upper and lower ends (11, 12) of the probe to irradiate light to the finger portion of the subject And a light receiving portion 14 for receiving light passing through the subject's finger.

In the volume pulse wave measuring apparatus according to the present invention, the probes 11 and 12 further include infrared temperature sensor units 15 and 16 to measure the temperature of the subject's finger, that is, the skin temperature. The infrared temperature sensor unit 15, 16 is composed of an infrared temperature sensor 15 and a filter 16. The filter is for filtering a wavelength region of the irradiation light of the light emitting unit 13 so that light emitted from the light emitting unit 13 of the upper end portion 11 of the probe cannot pass. This filtering is to prevent the light emitted from the light emitting part 13 to the subject nail part of the subject is detected by the infrared temperature sensor 15 may cause an unexpected signal disturbance. The infrared temperature sensor 15 may use a general infrared sensor, and also may be used by mounting a thermocoupler, thermometer, etc. for direct temperature measurement in the area where the subject's finger touches the bottom of the probe 12.

In addition, the volumetric pulse wave measuring apparatus according to the present invention further includes a data processing unit for processing a temperature signal measured by the infrared temperature sensor units 15 and 16, and a display unit for monitoring such data. do.

The data processing and control process through the volumetric pulse wave measuring system for determining the effective volume pulse wave by determining whether the subject is stabilized according to the present invention configured as described above will be described in more detail with reference to FIG. 3.

First, the finger portion of the subject is fixed between the upper and lower ends 11 and 12 of the probe of the volumetric pulse wave measuring apparatus according to the present invention, and the temperature of the finger skin is measured. At this time, the skin temperature is less than about 34.5 degrees Celsius, the subject is unstable due to psychological stress, the measured volume pulse wave is less reliable. Therefore, when the skin temperature of the subject is measured at about 34.5 degrees Celsius or more, it is regarded as a stable state and proceeds to the next step.

Next, the subject's heart rate variation is measured. Variation of the heart rate of the subject may use a separate instrument, and if the heart rate change is measured before the volume pulse wave measurement to indicate a stabilized heart rate, the procedure may be immediately moved to the next step. Heart rate refers to a heart rate for 1 minute. When the subject is unstable, the heart rate is severely changed, making accurate volumetric pulse wave measurement difficult. The subject's heart rate is not based on any absolute value and is considered to be satisfied when the heart rate is stabilized after a predetermined time (about 10 seconds or more). This process is a procedure for determining whether or not the subject stabilizes at the actual pre-volume pulse wave measurement step.

When it is determined that the subject's heart rate has reached the stabilization stage, the actual volumetric pulse wave is measured. At this time, the volumetric pulse wave is measured on the nail part of the subject and the DC drift is measured. In the case of the volumetric pulse wave measurement, when the volume pulse wave baseline, that is, the volume pulse wave baseline variation due to respiration, noise, etc. as shown in FIGS. 4A and 4B occurs largely up and down (DC component variation), accurate volumetric pulse wave measurement is difficult. This is caused by psychological instability, stress, etc. of the subject. When DC drift occurs, it is preferable to measure the subject after stabilizing the subject. In addition, the amplitude of one volume pulse wave is compared with the amplitude of the first volume pulse wave 1 period, and when it is smaller than that, it may be determined that it is stabilized.

The temperature measurement, the heart rate measurement, and the DC drift measurement of the skin part of the subject are required for the desirable volumetric pulse wave measurement, and the normal volumetric pulse wave is measured through the above process.

According to the present invention, there is an advantage in that the reliability of the data can be secured by removing the influence of the external environment on the subject, that is, the noise factor due to stress, and then measuring the volume pulse wave.

Prior to volumetric pulse wave measurement, noise factors due to skin temperature and heart rate of the subject may be removed, and DC drift components may be directly removed from the measured volumetric pulse wave to directly determine whether the psychology of the subject is stable or unstable.

Figure 1a is a diagram showing the change in volumetric pulse wave waveform at normal skin temperature, Figure 1b is a view showing the change in volume pulse wave waveform at a temperature lower than the normal skin temperature.

2 is a view showing a volume pulse wave measuring apparatus according to the present invention including a temperature measuring means.

3 is a flowchart illustrating a data processing and control process through a volumetric pulse wave measuring system for determining an effective volume pulse wave by determining whether a subject stabilizes according to the present invention.

4A and 4B are volumetric pulse wave waveforms showing an example of changing the base point of the volumetric pulse wave waveform during volume pulse wave measurement.

<Description of Symbols for Main Parts of Drawings>

11 ... top of the probe 12 ... bottom of the probe

13 ... light emitter 14 ... light receiver

15 ... infrared temperature sensor 16 ... filter

Claims (5)

In the volume pulse wave measurement system for determining the effective volume pulse wave by determining whether the subject stabilized, Temperature measuring means for measuring skin temperature; Heart rate measurement means for measuring a heart rate variation when it is determined that the skin temperature measured by the temperature measuring means is a stable value; And When the heart rate variation is determined to be a stable value, the data processing unit for determining the validity of the volumetric pulse wave by measuring the DC drift from the volumetric pulse wave measured by the volumetric pulse wave measuring means; A volumetric pulse wave measuring system for determining an effective volumetric pulse wave by determining. The method of claim 1, The volumetric pulse wave measuring means is formed to be open and close, the probe on which the subject is seated, a light emitting part formed at one end of the probe to irradiate light, and formed at the other end of the probe to receive light irradiated from the light emitting part. Including a light receiver, The temperature measuring means is a volume pulse wave measuring system for measuring the effective volume pulse wave by determining whether the stabilization of the subject, characterized in that any one of the infrared temperature measuring unit formed on one end of the probe, a thermocoupler or a thermometer formed on the lower end of the probe. The method of claim 1, The skin temperature is determined to be stabilized when the skin temperature is more than about 34.5 degrees Celsius volumetric pulse wave measurement system for determining the effective volumetric pulse wave by determining whether the subject stabilized, characterized in that measuring the heart rate by the heart rate measuring means. The method according to any one of claims 1 to 3, A volumetric pulse wave measuring system for measuring an effective volumetric pulse wave by determining whether the subject stabilizes, characterized in that the heart rate variation is measured by the heart rate measuring means after at least 10 seconds after the stabilization of the skin temperature. delete