KR20140003867A - System and method for monitoring sleep apnea and stage of sleep - Google Patents

Abstract

The present invention presents a monitoring system and method for sleep apnea and sleep stages. The sleep monitoring system according to the embodiment of the present invention generates respiration data of a user using the bio radar and monitors the sleep apnea of the user. It monitors the sleep stage of the user from motion data generated from a motion detection sensor. Using the invention, the sleep stage can be monitored with the external electron angular and non- restriction with the sleep apnea of the user. The dormant state of the user is monitored without the sleep interference due to the inconvenience of the user or the resistance caused.

Description

System and Method for Monitoring Sleep Apnea and Stage of Sleep

The present invention relates to a sleep monitoring system and method, and more particularly to a sleep monitoring system and method for monitoring the sleep state of an adult who is sleeping.

A study on chronic diseases and health care services as the treatment-oriented health paradigm shifts to prevention and management in response to changes in the current trends such as the improvement of quality of life as income increases and the progress of low birth rate and longevity of 100 years old. Development is underway.

In this regard, sleep is receiving attention as a health concern no less than a diet or exercise, and the industry is growing rapidly, according to the New York Times (NYT) reports that people with sleep disorders due to irregular living and worry, anxiety and excessive caffeine intake are reported. Sleepponomics is estimated to be worth US $ 20 billion (approximately 1.8 trillion won) in the US alone, and more than 1000 sleep clinics that check sleep apnea and other related accessories are helping to sleep well. It is said to be activated. However, even with this market revitalization, Americans' sleep satisfaction is still low.

Long-term sleep apnea adds to the heart and lungs and is associated with serious complications such as high blood pressure, heart attack, and seizures, and large studies have reported higher rates of mortality in people with sleep apnea than those without it. . In addition, it is related to sexual dysfunction, diabetes, concentration disorders, and in children and adolescents, it is associated with a decrease in academic ability, nocturnal enuresis and hyperactivity disorder syndrome. Therefore, sleep apnea is not an extension of snoring, but rather a symptom that causes various symptoms and complications.

The sleep test for sleep apnea is performed in the hospital, and the simultaneous examination of air intake through the nose and mouth, breathing in the chest and abdomen, brain waves, eye movement, blood oxygen saturation, electrocardiogram, and electromyography have.

Of course, there is a method to test in a non-hospital using a simple sleep test, but the method that requires additional measures, such as installing a device or attached to the body.

The present invention has been made to solve the above problems, an object of the present invention, the sleep monitoring to monitor the sleep apnea of the user by involuntary and non-restraint, and related sleep information, sleep monitoring for monitoring together A system and method are provided.

Sleep monitoring system according to an embodiment of the present invention for achieving the above object, a bio radar sensor for generating breathing data of the user using the bio radar; A motion sensor configured to detect motion of the user and generate motion data; And a monitoring device for monitoring the sleep apnea of the user using the breathing data generated by the bioradar sensor and monitoring the sleep phase of the user from the motion data generated by the motion detection sensor.

The bio radar sensor may be mounted on a stand type structure positioned around a bed where the user sleeps.

The monitoring apparatus may determine the sleep stage of the user based on the movement frequency determined from the movement data.

The monitoring device may determine the sleep stage of the user based on the motion size determined from the motion data.

The monitoring device may display information on the sleep apnea of the user and the sleep stage of the user.

On the other hand, sleep monitoring method according to another embodiment of the present invention, the step of generating breathing data of the user using a bio radar; Detecting movement of the user and generating movement data; Monitoring sleep apnea of the user using the breathing data; And monitoring the sleep phase of the user from the movement data.

As described above, according to the present invention, it is possible to monitor the sleep phase with the sleep apnea of the user by involuntary and unrestrained, thereby monitoring the sleep state of the user without disturbing sleep due to the user's discomfort or rejection Will be.

1 is a view showing a sleep monitoring system according to an embodiment of the present invention,
2 is a detailed block diagram of the sleep monitoring system shown in FIG. 1;
3 is a flowchart provided to explain a sleep monitoring method according to another embodiment of the present invention, and
4 is a diagram illustrating a state in which sleep apnea count, sleep stage, and sleep time are displayed on a display.

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

1 is a diagram illustrating a sleep monitoring system according to an exemplary embodiment of the present invention. The sleep monitoring system according to the present embodiment monitors sleep apnea based on a bio radar and monitors sleep state based on a motion sensor in order to monitor a user's sleep state by involuntary and unrestrained. Monitor the Stage of Sleep.

As shown in FIG. 1, the sleep monitoring system performing the above function is constructed by connecting the bio radar sensor 100, the motion detection sensor 200, and the sleep monitoring device 300 to communicate with each other.

The bioradar sensor 100 is a type of biosensor capable of measuring heart rate, respiration, and pulse of an adult user A sleeping in the bed 10 using a Doppler radar.

The bio radar sensor 100 is not attached to or in contact with the body of the user A, but is mounted on a stand-type structure positioned around the bed 10 where the user A sleeps, as shown in FIG. 1. do.

The motion sensor 200 is a sensor for detecting the movement of the user A sleeping in the bed 10, but is preferably implemented as a gyro sensor. .

The sleep monitoring apparatus 300 uses the breath data of the user A detected by the bio radar sensor 100 and the movement data detected by the motion detection sensor 200 to sleep sleep apnea of the user A sleeping, It monitors your sleep stage and sleep time and provides you with visual monitoring results.

Hereinafter, the devices configuring the sleep monitoring system will be described in detail with reference to FIG. 2. FIG. 2 is a detailed block diagram of the sleep monitoring system shown in FIG. 1.

As shown in FIG. 2, the bio radar sensor 100 includes a bio radar module 110, a breath data extraction / processing module 120, a wireless communication module 130, and a control module 140.

The bio radar module 110 receives the bio radar signal reflected after radiating a bio radar signal harmless to the human body toward the body of the user A sleeping in the bed 10. The reflected radar signal contains biometric data of the user A.

Since the bio radar module 110 is not attached to or in contact with the body, the bio radar module 110 does not cause sleep disturbance due to discomfort or rejection, and thus, bio data can be obtained relatively easily.

The respiratory data extraction / processing module 120 extracts only respiratory data among biological data contained in the reflected radar signal received by the bio radar module 110. The biometric data contained in the reflected radar signal includes heart rate data, respiration data, pulse data, and the like. Since these data have different frequencies, the respiration data extraction / processing module 120 may extract only respiration data through filtering.

In addition, the respiratory data extraction / processing module 120 performs necessary data processing processes such as noise removal, data conversion, data compensation, and the like on the extracted respiratory data.

The wireless communication module 130 wirelessly transmits the breathing data extracted / processed by the breathing data extraction / processing module 120 to the sleep monitoring device 300.

The control module 140 controls the operation of the bio radar module 110, and controls the operation of the bio radar module 110 according to a command received from the sleep monitoring apparatus 300 through the wireless communication module 130. Can be.

Meanwhile, as shown in FIG. 2, the motion detection sensor 200 includes a gyro sensor 210, a motion data processor 220, and a wireless communication unit 230.

The gyro sensor 210 is installed on the mat (or other position) of the bed 10 to detect movement of the user A and generate movement data.

The motion data processor 220 performs a necessary data processing procedure on the motion data generated by the gyro sensor 210.

The wireless communicator 230 wirelessly transfers the motion data processed by the motion data processor 220 to the sleep monitoring apparatus 300.

Lastly, as shown in FIG. 2, the sleep monitoring apparatus 300 includes a wireless communication interface 310, a processor 320, a display 330, and a storage 340.

The wireless communication interface 310 establishes and maintains a communication connection with the bio radar sensor 100 and the motion detection sensor 200 to receive respiration data and motion data of the user A, respectively.

The processor 320 analyzes the breathing data received from the bio radar sensor 100 through the wireless communication interface 310 to determine whether sleep apnea has occurred in the user A during sleep, and counts it when it occurs.

Sleep apnea is determined based on whether breathing has not occurred for more than 10 seconds. For reference, sleep apnea is diagnosed when more than 5 sleep apneas occur per hour or 30 times during 7 hours.

In addition, the processor 320 analyzes the motion data received from the motion sensor 200 through the wireless communication interface 310 to determine whether the user A has started to sleep in bed, and the user A who is sleeping ) To grasp the movement. From the movement of the sleeping user A, the processor 320 determines the sleeping stage of the user A. FIG.

The display 330 displays the number of sleep apneas, sleep stages, and sleep times of the user A, which are detected by the processor 320.

The storage unit 340 is a storage medium in which the display 330 stores the number of sleep apneas, sleep stages, and sleep times of the user A, which are detected by the processor 320.

Hereinafter, the sleep monitoring process of the user A by the sleep monitoring system shown in FIG. 1 will be described in detail with reference to FIG. 3. 3 is a flowchart provided to explain a sleep monitoring method according to another embodiment of the present invention.

As shown in FIG. 3, first, the motion detection sensor 200 detects the movement of the user A in the bed 10 and generates motion data (S410). The motion data generated in step S410 is transmitted to the sleep monitoring device 300.

The processor 320 of the sleep monitoring apparatus 300 determines whether the movement of the user A is detected on the bed 10 through the movement data generated in operation S410 (S420). Movement determination in step S420 is to determine whether the user (A) is lying on the bed for sleep.

When the motion is detected in step S420 (S420-Y), the processor 320 instructs the bio radar sensor 100 through the wireless communication interface 310, the bio radar sensor 100 is a user (A) Generate respiratory data (S430). Respiratory data generated in step S430 is also delivered to the sleep monitoring device 300.

The processor 320 of the sleep monitoring apparatus 300 analyzes the breathing data generated in operation S430 to determine whether sleep apnea has occurred to the user A, and counts when the sleep apnea occurs. Monitor (S440).

In addition, the processor 320 analyzes the motion data generated continuously from step S410 to determine the sleep step of the user A who is sleeping (S450).

In operation S450, the processor 320 may determine a motion frequency and a motion size from the motion data, and determine a sleep stage of the user A based on the detected motion frequency and the motion size.

Specifically, the higher the frequency of movement and the larger the size of movement, the user A determines that the user is in a shallow sleep phase, and the lower the frequency of movement and the smaller the size of the movement determines that the user A is in the deep sleep phase. do.

On the other hand, the processor 320 calculates the sleep time of the user A (S460). The sleep start time can be determined by analyzing the breathing data of the user A, and the sleep time can be calculated using a counter operated from the sleep start time.

Thereafter, the processor 320 displays the sleep apnea count, the sleep stage, and the sleep time of the user A identified through the steps S440 to S460 on the display 330 (S470). 4 illustrates a state in which the sleep apnea count, the sleep stage, and the sleep time are displayed on the display 330 as a result of the step S470.

Meanwhile, the processor 320 may store the information on the number of sleep apneas, sleep stages, and sleep times of the user A in the storage unit 340, and may also transmit the information to the medical institution through the wireless communication interface 310. .

In addition, if sleep apnea lasts for a long time, an alert message may be sent to the guardian or emergency services to inform them.

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, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention.

100: bio radar sensor 110: bio radar module
120: respiration data extraction / processing module 130: wireless communication module
140: control module 200: motion detection sensor
210: gyro sensor 220: motion data processing unit
230: wireless communication unit 300: sleep monitoring device
310: wireless communication interface 320: processor
330: display 340: storage

Claims (6)

A bioradar sensor for generating respiration data of the user using the bioradar;
A motion sensor configured to detect motion of the user and generate motion data; And
And a monitoring device for monitoring the sleep apnea of the user using the breathing data generated by the bio radar sensor and monitoring the sleep phase of the user from the movement data generated by the motion detection sensor. Monitoring system.
The method of claim 1,
The bio radar sensor,
Sleep monitoring system, characterized in that mounted to the stand-type structure located in the vicinity of the bed for the user to sleep.
The method of claim 1,
The monitoring device includes:
The sleep monitoring system, characterized in that for determining the sleep stage of the user based on the movement frequency identified from the movement data.
The method of claim 3, wherein
The monitoring device includes:
The sleep monitoring system, characterized in that for determining the sleep stage of the user based on the motion size determined from the motion data.
The method of claim 1,
The monitoring device includes:
Sleep monitoring system, characterized in that for displaying information about the sleep apnea of the user and the sleep phase of the user.
Generating breathing data of the user using the bio radar;
Detecting movement of the user and generating movement data;
Monitoring sleep apnea of the user using the breathing data; And
And monitoring the sleep stage of the user from the movement data.

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