KR20150082965A - Portable diagnosis apparatus for stress - Google Patents

Abstract

The present invention relates to a portable apparatus for diagnosing stress which detects a movement of a human body by using an acceleration sensor, error-processes a pulse wave value and a skin resistance value measured at this time, and enables determining a relaxation degree (stress) of the human body by using heart rate variability and the skin resistance value at the same time when the human body is fixed without moving, thereby improving effectiveness and efficiency on determining the degree of stress of the human body.

Description

{Portable diagnosis apparatus for stress}

The present invention relates to a stress diagnostic technique, and more particularly to a portable stress diagnostic device.

In normal life, the body works under the control of the autonomic nervous system. However, when the human body is placed in an abnormal environment, the autonomic nervous system that dominates the human body activates the sympathetic nervous system in order to protect the human body, thereby reducing parasympathetic activity. When this phenomenon occurs, observing the state of change of the human body, the heart rate is accelerated when the activity of the sympathetic nerve is strengthened, or the skin resistance value becomes lower as the sweat gland activity becomes strong.

Korean Utility Model Registration No. 20-0023205 (1983. 01. 10) uses this phenomenon to indirectly measure brain activity according to the skin resistance value, and Korean Patent Registration No. 10-0954817 (2010. 04. 19 ), Heart rate variability (HRV) is used to determine the activity of LF and HF to measure the stress level of the human body.

There are a number of ways to measure when a person is stressed, but there are simple measures of non-invasive methods such as pulse wave measurement and skin resistance. However, as a simple method of measuring pulse waves, a volume pulse wave is obtained by measuring the degree to which blood flowing through blood vessels hinders the transmission of light according to the heartbeat by reflecting the light at the distal end portion of the capillaries of the human body In order to obtain the pulse wave data, the light receiving part of the light emitting part is mainly mounted on the finger or the ear ball. The volumetric pulse wave data obtained in this way has a disadvantage that it is difficult to acquire normal data by reacting sensitively when moving (moving) the human body.

In addition, the skin resistance value, which changes according to the relaxation state of the human body, is mainly measured by the finger because the capillary blood vessel is intensively changed in a concentrated manner. However, the skin resistance value measured by the finger shows a large difference in each measurement person, and the deviation varies greatly depending on the environment in which the human body is located. Therefore, it is difficult to use the skin resistance value as an absolute index value.

However, since the pulse wave value changes very sensitively according to the human's emotions, it is difficult to judge the degree of stress of the human body, that is, the degree of relaxation, but the skin resistance value changes slowly compared to the pulse wave. There is an advantage.

Korea Utility Model Registration No. 20-0023205 (1983. 01. 10) Korea Patent Registration No. 10-0954817 (Apr. 19, 2010)

The present invention detects a motion of a human body by using an acceleration sensor, error-processes a pulse wave value and a skin resistance value measured at this time, and when the human body is fixed without movement, The present invention has been made in view of the above problems, and it is an object of the present invention to provide a portable stress diagnostic apparatus which can improve the efficiency of judging the degree of stress of a human body.

Another object of the present invention is to provide a skin resistance value of the human body ranging from about 100 K to several MΩ. However, since the measurement resistance varies greatly depending on the environment, the measurement range is widened to about 100 K to 10 MΩ, To calculate a variation value and to use it to improve a different reference value for each measurement, thereby providing a portable stress diagnostic device.

It is still another object of the present invention to provide a portable stress diagnostic device capable of training the self-relaxation of the human body according to the self-relaxation guide by feeding back the voice relaxation guide prepared according to the measured pulse wave value and the skin resistance value, .

According to one aspect of the present invention, there is provided a portable stress diagnostic apparatus comprising a photocoupler for measuring a change amount of light reflected when a blood flow is changed according to a heartbeat of a heart, , The photocoupler is fixed to the ring type so that the pulse wave of the volume can be measured. When the finger is moved, the error caused by the sensor itself shaking is minimized. When the motion of the human body is detected using the acceleration sensor, The pulse wave and the skin resistance value are error-processed to improve the measurement efficiency.

The present invention detects a motion of a human body by using an acceleration sensor, error-processes a pulse wave value and a skin resistance value measured at this time, and when the human body is fixed without movement, (Stress) of the human body can be judged so that the efficiency of judging the degree of stress of the human body can be improved.

Since the skin resistance value of the human body reaches about 100K to several MΩ, the measurement range is widened to about 100K to 10MΩ and the initial measurement value is used as a reference value By using the value by calculating the variation amount, it is possible to improve another reference value every measurement.

According to the present invention, the voice relaxation guide prepared according to the measured pulse wave value and the skin resistance value is fed back to the measurer so that the self-relaxation guide can be used to relax the tension of the human body itself.

There are self training mode and expert guide training mode. In the self-training mode, the voice guidance according to the relaxed state of the trainee is stored so that the breathing control and the consciousness control that can most effectively control the autonomic nervous system of the human body can be performed in the smartphone, So that a sound can be generated.

For example, the trainer relaxes state using a 30-Hz to 0.1 Hz frequency beat. When the relaxation state is very low, it generates a sound with a beat close to 30 Hz to indicate a state of low relaxation. When entering a very deep relaxation state, a slow beat sound near 0.1 Hz is generated, thereby allowing the trainee himself to hear a beat sound, Trainees themselves are guided to learn how to relax their bodies by trying to pull themselves out of the nervous body while slowing the breathing and allowing the trainer to identify and lower the beat.

Expert Guide training mode is a mode in which a measurer accesses a professional server with a smartphone app program and selects a waiting expert, and when the expert enters the training mode, the expert monitors the relaxation state of the trainer directly, After selecting the relaxation guidance items prepared and sending them to the smartphone, the trainee can listen to the relaxation guidance of the experts on the smartphone by voice and train them according to the instruction, so that the professional training can be performed. Expert guide training mode is advantageous to relax training in cyber space without restriction of time and space by using internet means.

1 is a view showing an application example of a portable stress diagnostic apparatus according to the present invention.
2 is a network diagram of a portable stress diagnostic apparatus according to the present invention.
3 is a view showing a sensor module of the portable stress diagnostic apparatus according to the present invention.
4 is a block diagram showing the configuration of an embodiment of a portable stress diagnostic device according to the present invention.
5 is a diagram showing an example of a pulse wave and skin resistance sensor.
6 is a schematic view of a volume pulse wave measurement.
FIG. 7 is a diagram showing skin resistance, LF and HF in human relaxation.
8 is a diagram showing various index changes before and after human relaxation.
9 is a diagram for estimating the stress index.
Figure 10 is a plot of the autonomic nervous system index (LF / HF).
11 is a diagram showing the skin resistance.
Fig. 12 is a diagram relating to the average pulse rate. Fig.
FIG. 13 is a diagram illustrating a beats per minute heart rate histogram according to stress.
Figure 14 is the standard deviation of the heart rate change with stress.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

The terms used throughout the specification of the present invention have been defined in consideration of the functions of the embodiments of the present invention and can be sufficiently modified according to the intentions and customs of the user or operator. It should be based on the contents of.

Recently, accelerometers have been developed by I2C or SPI method and can interface with MPU to easily detect x, y, and z axis movements. It is equipped with a skin resistance sensor to measure the skin resistance value between the gold-plated electrode surface on the bottom surface of the ring-type finger and the gold-plated electrode surface on the lower part of the watch-type communication module, To measure the skin resistance value.

As shown in FIG. 5, an LED and a photo sensor are mounted on a PCB as shown in FIG. 5, and the light amount of the light according to the amount of blood flowing on the finger Convert the change to a voltage to obtain heart beat value. The skin resistance value is obtained by measuring the resistance value between the gold-plated electrode as shown in Fig. 5 and the gold-plated electrode adhering on the back of the hand as shown in Fig.

The pulse wave value and the skin resistance value are input to a module formed in a clock shape and converted into a voltage form according to a change in resistance value, and then A / D converted as shown in FIG. 4, The pulse wave value is FFT and the HF value and the LF value, which are measured by the HRV value indicating the activity of the sympathetic nerve and the parasympathetic nervous system, which are shown as the activity of the autonomic nervous system, are calculated to determine whether the human body is under sympathetic nerves, Of the world.

In addition, the skin resistance value measured at the same time can determine the degree of relaxation by calculating a variation value that is changed according to the degree of relaxation of the human body, using the initially measured value as a reference value. As the human body relaxes, The phenomenon that the skin resistance value is increased can be confirmed.

7, it is possible to grasp the change in the pulse rate during the period given by the histogram chart in which the respective pulse rate values are accumulated for a given period for each measurer, and FFT (Pulse Fourier Transform) The LF and HF values are plotted on the LF and HF charts and the LF values are shown to be higher than the HF values as the human body is warmed. . Also, it can be confirmed that the skin resistance value measured at the same time is increased to a state higher than the initial measured value and then maintained.

8 is a chart for comparing when the human body is relaxed and when it wakes up from relaxation. In order to relax the human body, when the eye is closed and the eyes are opened and the eyes are opened and the consciousness is changed to the normal state, the skin resistance values are rapidly lowered and the pulse values distributed on the lower side are shifted toward the higher side as shown in the histogram can see. In the relaxation period, the LF value was changed to 6.73 and the HF value was changed to 7.5 when the LF value remained at 8.61 and the HF value remained at 7.71.

Therefore, it is possible to confirm the relaxation degree of the human body by observing the change values of the pulse rate and the skin resistance value, and also to teach the human body relaxation by letting the measurer speak the human relaxation guide voice prepared according to the pulse rate and the skin resistance value can do.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. .

INDUSTRIAL APPLICABILITY The present invention is industrially applicable in the field of stress diagnosis technology and its application field.

Claims (1)

And a photocoupler capable of measuring a change amount of light reflected when the blood flow rate changes according to the heartbeat of the heart when the fingertip is irradiated with light. The photocoupler is fixed in a ring shape so as to measure the volume pulse wave, And the measurement efficiency is improved by error processing of the pulse wave and the skin resistance value measured at this time when the motion of the human body is detected by detecting the motion of the human body by using the acceleration sensor, Stress diagnostic device.

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