KR102383921B1 - Methods and system for customized sleep management - Google Patents

Abstract

The present invention provides a user-customized sleep management method performed by a user-customized sleep management system, the method comprising: collecting bio-signals through a computing device; generating user sleep data by performing a pre-processing process on the collected bio-signals; Classifying sleep stages through a sleep analysis model by inputting user sleep data, and detecting sleep disorders appearing in the classified sleep stages; and providing a user-customized stimulus for alleviating the detected sleep disorder. The biosignal includes at least one of an electrophysiological signal (EEG, EOG, EMG, ECG) or a non-electrophysiological signal (sound, body temperature, movement).

Description

User-customized sleep management method and system {METHODS AND SYSTEM FOR CUSTOMIZED SLEEP MANAGEMENT}

The present invention relates to a method and apparatus for detecting a sleep disorder according to a sleep stage and suggesting and controlling an optimal stimulus for alleviating the sleep disorder in order to improve the quality of sleep. In more detail, based on machine learning, it utilizes the user's biosignals during sleep to classify sleep stages and sleep disorders according to them, and to improve the quality of sleep by effectively alleviating the sleep disorders by presenting user-customized optimal stimuli. It relates to methods and systems.

Human-computer interface is a technology that analyzes brain signals generated during various brain activities to recognize user intentions and control external devices through them. A user can control a computer or machines through a human-computer interface without using muscles. Human-computer interfaces were mainly used to develop devices to assist the movement of patients with motor neuron disorders due to accidents or diseases. is in progress

Sleep is an important activity that maintains the body's circadian rhythm and enhances the body's recovery function. In particular, melatonin secreted from the brain during sleep has antioxidant and anti-aging properties, as well as regulating sleep rhythm to increase immunity through anticancer action, blood pressure control and stress relief. Such high-quality sleep is essential to maintain a healthy life. However, according to the report of the Organization for Economic Cooperation (OECD) in 2016, Korea ranked the lowest with 7 hours and 41 minutes in the 'Average Sleep Time by Country Survey'. This is 41 minutes shorter than the average (8 hours 22 minutes), and office workers recorded 6 hours and 6 minutes, much lower than that. In addition, according to the announcement of the National Health Insurance Corporation in 2013, the number of patients treated for sleep disorders is also rapidly increasing. Insufficient sleep or poor quality of sleep breaks the circadian rhythm and easily leads to weakened immunity. Examples of these sleep disorders include insomnia, hypersomnia, sleep apnea, and somnambulism. ) is there. Therefore, various methods for improving the quality of sleep by alleviating sleep disorders are required.

Methods for treating sleep disorders include drug therapy and stimulation therapy. Drugs for treating insomnia among sleep disorders include zolpidem, halcion, ativan, and diazepam, and drugs for snoring or sleep apnea include atomoxenin and oxybutynin. However, these medications are only a temporary alternative to sleep disorders, and if taken for more than 2-3 weeks, tolerance develops and it is difficult to see the effect, and if you stop taking it, the symptoms may get worse. Therefore, stimulation therapy is emerging as an alternative to alleviating sleep disorders. Treatment using sensory stimulation, such as hearing, sight, and smell, has the advantage of being relatively easy to use by ordinary people in real life and having relatively few side effects. However, existing technologies for detecting and alleviating sleep disorders detect specific sleep disorders and provide a notification service or only provide appropriate stimuli. Since these techniques did not simultaneously detect various sleep disorders that deteriorate the quality of sleep during sleep, the application of these techniques had a limitation in that they did not lead to improvement in the quality of sleep. In addition, it is difficult to consider that sleep disorders have been accurately detected because features related to sleep disorders cannot be accurately extracted by using only specific biosignals such as electroencephalogram or electromyogram signals to detect sleep disorders.

Basically, sleep is mainly composed of Non-Rapid Eye Movement (NREM) sleep and Rapid Eye Movement (REM) sleep. NREM sleep is a stage in which rapid pupil movement does not occur, and is further divided into three stages. Stage 1 (NREM1) is the stage between sleep and wakefulness. During the first stage of sleep, brain waves and muscle activity begin to slow down, and the representative brain wave at this time is theta wave (4-7Hz). Stage 2 (NREM2) is a stage of light sleep, and in this stage, a sleep spindle and a K-complex are prominently displayed along with theta wave. The sleep spindle (12~14Hz) and K-complex play a role in suppressing the body's response to external stimuli and protecting sleep. Stage 3 (NREM3) is the stage of deep sleep, also known as slow wave sleep. During this stage, the body responds less sensitively to the external environment, and the representative EEG is delta wave (0.5~4Hz). Depending on the frequency of the delta wave, it is sometimes divided into three stages and four stages. REM sleep is the stage in which rapid pupil movement occurs, during which you usually dream. The brain waves at this time appear similar to the waking state. Sleep disturbances do not appear continuously during sleep, but rather occur at specific stages of sleep. Therefore, there is a need for a method to accurately classify each sleep stage in order to fundamentally improve the user's sleep quality, detect sleep disorders that may appear in the corresponding sleep stage, and suggest an optimal stimulus to alleviate them.

Existing inventions have a limitation in that only one sleep disorder is detected, and machine learning is used to determine the sleep state and occurrence of sleep disorders only with the user's non-electrophysiological signals during sleep without measuring the electrophysiological signals. Since it is not done, there is a disadvantage in that the accuracy of accurate sleep stage measurement and sleep disorder detection is low. In addition, since one person may have various sleep disorders, it is necessary to present a machine learning-based user-customized optimal stimulus that can accurately detect and effectively alleviate sleep disorders according to sleep stages.

Republic of Korea Patent Publication No. 10-1763302 (Title of the invention: Smart functional pillow and sleep disorder diagnosis management system and sleep disorder diagnosis management method using the same)

In order to solve the above problems, according to an embodiment of the present invention, the present invention analyzes an electrophysiological signal including brain waves and a non-electrophysiological signal including movement and sound at the same time to provide accurate sleep stages and various An object of the present invention is to detect a sleep disorder and provide a user-customized optimal stimulus according to the sleep disorder.

However, the technical task to be achieved by the present embodiment is not limited to the technical task as described above, and other technical tasks may exist.

As a technical means for solving the above-described technical problem, the user-customized sleep management method performed by the user-customized sleep management system performed by the system according to the first aspect of the present disclosure is a method for collecting bio-signals through a computing device. step; generating user sleep data by performing a pre-processing process on the collected bio-signals; Classifying sleep stages through a sleep analysis model by inputting user sleep data, and detecting sleep disorders appearing in the classified sleep stages; and providing a user-customized stimulus for alleviating the detected sleep disorder. The biosignal includes at least one of an electrophysiological signal (EEG, EOG, EMG, ECG) or a non-electrophysiological signal (sound, body temperature, movement).

As a technical means for solving the above technical problem, the user-customized sleep management system according to the second aspect of the present disclosure includes: a measuring device including at least one measuring module for measuring bio-signals; a stimulus providing device including at least one stimulus providing module for providing a stimulus to a user; and a computing device that collects bio-signals through the measuring device and provides a user-customized stimulus through the stimulus providing device for alleviation of sleep disorders in the sleep phase classified by the analysis of the collected bio-signals. The computing device may include a memory in which a user-customized sleep management program is stored; It includes a processor for executing a program stored in the memory. The processor collects the bio-signals measured through the measuring device by executing the program, and performs a pre-processing process on the collected bio-signals so that the generated user sleep data is input to the sleep analysis model to output sleep disorder information, A user-customized stimulus matching the sleep disorder information is provided through the stimulus providing device. The biosignal includes at least one of an electrophysiological signal (EEG, EOG, EMG, ECG) or a non-electrophysiological signal (sound, body temperature, movement).

According to the problem solving means of the present invention described above, it is possible to accurately determine a sleep stage and a sleep disorder by simultaneously analyzing an electrophysiological signal and a non-electrophysiological signal.

In addition, it is possible to adjust the intensity of stimulation by presenting an optimal stimulus that can effectively alleviate each sleep disorder and continuously measuring the user's sleep state.

It is possible to improve the quality of sleep more effectively than existing technologies because it analyzes the user's sleep stage and sleep disorder in real time, suggests the optimal stimulus tailored to the user, and adjusts the intensity of the stimulus.

1 is a block diagram illustrating a configuration of a user-customized sleep management system according to an embodiment of the present invention.
2 is a block diagram illustrating a configuration of a user terminal in a user-customized sleep management system according to an embodiment of the present invention.
3 is a flowchart illustrating a process step of a user-customized sleep management method according to an embodiment of the present invention.
4 is a diagram illustrating sleep analysis result data on a visualized user interface provided by a user-customized sleep management method according to an embodiment of the present invention.

Hereinafter, embodiments of the present application will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art can easily implement them. However, the present application may be implemented in several different forms and is not limited to the embodiments described herein. And in order to clearly explain the present application in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Throughout this specification, when a part is "connected" with another part, this includes not only the case where it is "directly connected" but also the case where it is "electrically connected" with another element interposed therebetween. do. In addition, when a part "includes" a certain component, it means that other components may be further included, rather than excluding other components, unless otherwise stated, and one or more other features However, it is to be understood that the existence or addition of numbers, steps, operations, components, parts, or combinations thereof is not precluded in advance.

In the present specification, a 'terminal' may be a wireless communication device with guaranteed portability and mobility, for example, any type of handheld-based wireless communication device such as a smart phone, a tablet PC, or a notebook computer. In addition, the 'terminal' may be a wired communication device such as a PC that can connect to another terminal or a server through a network. In addition, the network refers to a connection structure capable of exchanging information between each node, such as terminals and servers, and includes a local area network (LAN), a wide area network (WAN), and the Internet (WWW). : World Wide Web), wired and wireless data networks, telephone networks, and wired and wireless television networks.

Examples of wireless data communication networks include 3G, 4G, 5G, 3rd Generation Partnership Project (3GPP), Long Term Evolution (LTE), World Interoperability for Microwave Access (WIMAX), Wi-Fi, Bluetooth communication, infrared communication, ultrasound Communication, Visible Light Communication (VLC), LiFi, and the like are included, but are not limited thereto.

The following examples are detailed descriptions to help the understanding of the present invention, and do not limit the scope of the present invention. Accordingly, an invention of the same scope performing the same function as the present invention will also fall within the scope of the present invention.

1 is a block diagram illustrating a configuration of a user-customized sleep management system according to an embodiment of the present invention.

The user-customized sleep management method may be implemented in the computing device 300 , the user terminal 100 , or the server 200 linked to the user terminal 100 . In the user-customized sleep management method, sleep data collection may be performed through one or more computing devices 300 and measuring devices 400 . The collected data analysis is performed in the server 200 , and the analysis result data may be provided to each user terminal 100 . A plurality of users may each perform a user-customized sleep management method through their own computing device 300 .

The user terminal 100 may be a device of various types, such as a smart phone, a tablet PC, a laptop, and a smart watch. The computing device 300 may utilize the user terminal 100 alone, and in this case, the measurement device 400 and the stimulus providing device 500 linked to the user terminal 100 may be used.

The measuring apparatus 400 for measuring a biosignal may measure an electrophysiological signal and a non-electrophysiological signal that appear when the user is sleeping. For example, it is possible to measure the user's electroencephalogram (EEG), electromyography (EMG), electrocardiogram (ECG), and safety level (EOG) signals and sound, body temperature, and movement signals during sleep. The measuring device 400 may include a measuring module for each biosignal to be measured.

The stimulus providing apparatus 500 for providing a user-customized stimulus may provide a stimulus including at least one of sound, vibration, or light to the user in order to alleviate the detected sleep disorder.

According to the detected sleep disturbance, the optimal stimulus (sound, light, stimulation using an ultrasonic humidifier, vibration, temperature/humidity, electrical stimulation, etc.) can be presented to the user. For example, in a person who develops snoring, bruising, or, in severe cases, sleep apnea, breathing passages (upper airways) such as the nasal passages and sinuses are narrowed, making it difficult to supply oxygen to the brain, so the quality of sleep is lowered. At this time, if fine water particles are sprayed inside the nose using the ultrasonic humidifier sensor module, the effect of widening the upper airway can be obtained, and thus oxygen can be smoothly supplied to the brain. As a result, it is possible to improve the quality of sleep by alleviating the sleep disorder symptoms of users with sleep apnea. The stimulus providing device 500 may include a stimulus providing module for each stimulus type to be provided.

After the stimulus is presented, the user's sleep state is evaluated whether the sleep disorder has been alleviated in real time. If the symptoms of sleep disorder are not alleviated, the stimulus intensity is adjusted again in consideration of the characteristics of each user.

In addition, the measuring device 400 and the stimulus providing device 500 are connected to the user terminal 100 using a communication module to configure a user-customized sleep management system. For example, the user terminal 100 is a personalization device such as a mobile phone or a tablet PC, and the measurement device 400 and the stimulus providing device 500 use short-distance communication such as Bluetooth, Wi-Fi, and zigbee in the same form as a mobile accessory. It may be used in conjunction with the user terminal 100 . In this case, the biosignal measured by the measuring device 400 is transmitted to the server 200 through the user terminal 100 and analyzed by the server 200, and the analyzed result is transmitted to the user terminal 100 again and displayed. , the user-customized stimulus may also be transmitted from the server 200 to the stimulus providing device 500 via the user terminal 100 and then provided to the user.

2 is a block diagram illustrating a configuration of a user terminal in a user-customized sleep management system according to an embodiment of the present invention.

As shown, the user terminal 100 of the user-customized sleep management system may include a communication module 110 , a memory 120 , a processor 130 , a database 140 , and an input module 150 .

The communication module 110 communicates data with the connected user terminal 100 and the interworking server 200, respectively. The communication module 110 may be a device including hardware and software necessary for transmitting and receiving signals such as control signals or data signals through wired/wireless connection with other network devices.

A user-customized sleep management program is stored in the memory 120 . The user-customized sleep management program collects bio-signals through a computing device, performs a pre-processing process on the collected bio-signals to generate user sleep data, and classifies sleep stages through a sleep analysis model with user sleep data as input. , it is possible to detect sleep disorders that appear in each of the classified sleep stages, and provide a user-customized stimulus for alleviating the detected sleep disorders.

In the memory 120 , various types of data generated during the execution of an operating system for driving the user-customized sleep management server 200 or a user-customized sleep management program are stored.

In this case, the memory 120 collectively refers to a non-volatile storage device that continuously maintains stored information even when power is not supplied, and a volatile storage device that requires power to maintain the stored information.

The processor 130 executes the program stored in the memory 140, but controls the entire process according to the execution of the user-customized sleep management program. Each operation performed by the processor 130 will be described in more detail later.

The processor 130 may include all kinds of devices capable of processing data. For example, it may refer to a data processing device embedded in hardware having a physically structured circuit to perform a function expressed as code or instructions included in a program. As an example of the data processing device embedded in the hardware as described above, a microprocessor, a central processing unit (CPU), a processor core, a multiprocessor, an application-specific (ASIC) An integrated circuit) and a processing device such as a field programmable gate array (FPGA) may be included, but the scope of the present invention is not limited thereto.

The database 140 stores or provides data necessary for a user-customized sleep management system under the control of the processor 130 . For example, electrophysiological signals including electroencephalogram signals, non-electrophysiological signals including movement, sound, body temperature, etc., and data in a specific frequency domain that have passed through a preprocessor can be stored and classified in a user-customized sleep management system. Data for one sleep stage, sleep disorder, sleep analysis data, and user-customized stimuli may also be stored. The database 140 may be included as a component separate from the memory 140 , or may be built in a part of the memory 140 .

The server 200 may include a communication module, a memory, a processor, a database, and an input module, and the configuration and content may be the same as that of the user terminal. The user-customized sleep management method may be performed by the server 200 , the computing device 300 , or the user terminal 100 .

3 is a flowchart illustrating a process step of a user-customized sleep management method according to an embodiment of the present invention.

The processor 130 collects bio-signals through the computing device (S110). The biosignal may include one or more of an electrophysiological signal (EEG, EOG, EMG, ECG) or a non-electrophysiological signal (sound, body temperature, movement).

The computing device is a human-computer interface device and may include a user terminal 100 , a measurement device 400 , and a stimulus providing device 500 . The user terminal may receive the biosignal measured through the measuring device 400 , and a user-customized stimulus may be provided through the stimulus providing device 500 .

The bio-signals may include bio-signals measured from a waking state before sleep, and may include bio-signals measured in real time according to sleep stages and sleep disorders after sleep starts.

The processor 130 generates user sleep data by performing a pre-processing process on the collected bio-signals (S120). The processor 130 may perform a pre-processing process such as removing noise unnecessary for analyzing a corresponding signal from the measured bio-signal, filtering it in a specific frequency band, and the like. For example, in order to analyze the corresponding signal from the measured EEG data, a preprocessing process such as removing unnecessary noise and filtering to a specific frequency range (delta wave, theta wave, alpha wave, beta wave, gamma wave) may be performed. .

The processor 130 classifies sleep stages through a sleep analysis model by receiving user sleep data as input, and detects sleep disorders appearing in the classified sleep stages.

The sleep analysis model uses machine learning algorithms such as Support Vector Machine, Autoencoder, Convolution Neural Network, and Recurrent Neural Network to determine the start time of each sleep phase, Based on information such as the frequency of the sleep phase, the user's sleep phase is analyzed and classified in real time, and based on the classified sleep phase and the user's bio-signals, a machine learning algorithm is used to detect sleep disorders that may appear in the sleep phase. can be analyzed and detected in real time.

The measured EEG signals can be further analyzed to detect sleep disorders that may occur according to the classified sleep stages: Wake, NREM1, NREM2, NREM3, and REM. In addition, it is possible to detect a user's sleep disorder in real time by using the pre-processed EMG, ECG, and safety signals and the feature extracted sound, body temperature, and movement signals at the same time. Typical sleep disorders by sleep phase include insomnia in alpha/beta (wake) phase, bruising in theta (NREM1) phase, sleep apnea in K-complex (NREM2), sleepwalking in delta (NREM3) sleepwalking, night terrors, theta/beta In REM, restless legs syndrome, behavioral disorders, etc.

The processor 130 may generate sleep analysis result data and provide it to the computing device (S140).

The processor 130 generates sleep analysis result data including at least one of a sleep stage, a sleep disorder, a sleep phase time, whether a sleep disorder is detected, quality of life data, a user-customized stimulus type, or a user-customized stimulus intensity, and sleep analysis The resulting data may be provided to the computing device via a visualized user interface.

The processor 130 receives user information including one or more of age, gender, height, and weight in addition to user sleep data, and calibrates user sleep data to correct differences in bio-signals for each user based on the user information. can At this time, since the characteristics of the brain signal vary according to the characteristics of the user's age and gender, for each sleep stage, the typical frequency band, amplitude, power spectrum, and sleep spindle density of the sleep phase, which are the characteristics of the brain signal. (Sleep spindle density), sleep spindle duration, etc. can be considered as calibration targets.

The processor 130 may provide a user-customized stimulus for alleviating the detected sleep disorder (S150).

The processor 130 may provide a stimulus including one or more of sound, vibration, or light to the user to alleviate the detected sleep disturbance. According to the detected sleep disturbance, the optimal stimulus (sound, light, stimulation using an ultrasonic humidifier, vibration, temperature/humidity, electrical stimulation, etc.) can be presented to the user. For example, in a person who develops snoring, bruising, or, in severe cases, sleep apnea, breathing passages (upper airways) such as the nasal passages and sinuses are narrowed, making it difficult to supply oxygen to the brain, so the quality of sleep is lowered. At this time, if fine water particles are sprayed inside the nose using the ultrasonic humidifier sensor module, the effect of widening the upper airway can be obtained, and thus oxygen can be smoothly supplied to the brain. As a result, it is possible to improve the quality of sleep by alleviating the sleep disorder symptoms of users with sleep apnea.

In addition, auditory stimulation is effective for insomnia, visual and auditory stimulation are effective for sleep hallucinations, electrical stimulation and vibration stimulation are effective for sleep paralysis, and temperature/humidity is effective for jet lag, shift work disorder and restless legs syndrome. Electrical stimulation and electrical stimulation are effective for sleepwalking and night terrors, electrical stimulation, visual stimulation, and auditory stimulation are effective for sleepwalking and night terrors, electrical stimulation is effective for enuresis, and electrical stimulation, visual stimulation, and auditory stimulation are effective for REM sleep behavior disorders.

After the stimulus is presented, the processor 130 evaluates the user's sleep state whether the sleep disorder has been alleviated in real time. If the sleep disorder symptoms are not alleviated, the intensity of stimulation can be adjusted again in consideration of the characteristics of each user. Considering that the optimal stimulus intensity required to alleviate sleep disorders varies depending on the user's age and gender characteristics, it is also possible to adjust the stimulus intensity according to the user's condition.

4 is a diagram illustrating sleep analysis result data on a visualized user interface provided by a user-customized sleep management method according to an embodiment of the present invention.

On the visualized user interface, it is possible to display sleep stages by sleep time as a graph. Sleep stages can be classified into Wake, NREM1, NREM2, NREM3, and REM.

In addition to the electroencephalogram signals measured at each sleep stage, the detected sleep disturbances can be displayed in a graph along with the degree of preprocessed EMG, electrocardiogram, and safety signals and feature extracted sound, body temperature, and movement signals simultaneously. Typical sleep disorders by sleep phase include insomnia in alpha/beta (wake) phase, bruising in theta (NREM1) phase, sleep apnea in K-complex (NREM2), sleepwalking in delta (NREM3) sleepwalking, night terrors, theta/beta In REM, restless legs syndrome, behavioral disorders, etc.

When the degree of sleep disturbance exceeds a preset standard, a necessary stimulus may be presented. According to the detected sleep disturbance, the optimal stimulus (sound, light, stimulation using an ultrasonic humidifier, vibration, temperature/humidity, electrical stimulation, etc.) can be presented to the user. For example, in a person who develops snoring, bruising, or, in severe cases, sleep apnea, breathing passages (upper airways) such as the nasal passages and sinuses are narrowed, making it difficult to supply oxygen to the brain, so the quality of sleep is lowered. At this time, if fine water particles are sprayed inside the nose using the ultrasonic humidifier sensor module, the effect of widening the upper airway can be obtained, and thus oxygen can be smoothly supplied to the brain. As a result, it is possible to improve the quality of sleep by alleviating the sleep disorder symptoms of users with sleep apnea.

In addition, auditory stimulation is effective for insomnia, visual and auditory stimulation are effective for sleep hallucinations, electrical stimulation and vibration stimulation are effective for sleep paralysis, and temperature/humidity is effective for jet lag, shift work disorder and restless legs syndrome. Electrical stimulation and electrical stimulation are effective for sleepwalking and night terrors, electrical stimulation, visual stimulation, and auditory stimulation are effective for sleepwalking and night terrors, electrical stimulation is effective for enuresis, and electrical stimulation, visual stimulation, and auditory stimulation are effective for REM sleep behavior disorders.

The quality of sleep can be evaluated through several criteria. The sleep evaluation indicators were the time to sleep, the number of wakes after falling asleep, the total sleep time, the duration of the deep sleep (NREM3) phase, and sleep. sleep efficiency, and the like. In addition, the method of alleviating the symptoms of sleep disorders is also one of the important criteria for sleep quality. Therefore, based on these indicators, the user's sleep quality is evaluated.

The present invention detects accurate sleep stages and various sleep disorders in real time by simultaneously analyzing electrophysiological signals including brain waves and non-electrophysiological signals including motion and sound, and provides user-customized optimal stimulation according to sleep disorders By doing so, it is possible to effectively improve the quality of sleep.

Meanwhile, the method according to an embodiment of the present invention may also be implemented in the form of a recording medium including instructions executable by a computer, such as a program module executed by a computer. Computer-readable media can be any available media that can be accessed by a computer and includes both volatile and nonvolatile media, removable and non-removable media. Also, computer-readable media may include computer storage media. Computer storage media includes both volatile and nonvolatile, removable and non-removable media implemented in any method or technology for storage of information such as computer readable instructions, data structures, program modules or other data. Although the methods and systems of the present invention have been described with reference to specific embodiments, some or all of their components or operations may be implemented using a computer system having a general purpose hardware architecture.

The foregoing description of the present application is for illustration, and those of ordinary skill in the art to which the present application pertains will understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present application. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive. For example, each component described as a single type may be implemented in a dispersed form, and likewise components described as distributed may be implemented in a combined form.

The scope of the present application is indicated by the following claims rather than the above detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present application.

10: system
100: user terminal
110: communication module
120: memory
130: processor
140: display module
150: input module
200: server
300: computing device
400: measuring device
500: stimulus providing device

Claims (17)

In the user-customized sleep management method performed by the user-customized sleep management system,
(a) collecting biosignals through a computing device;
(b) generating user sleep data by performing a pre-processing process on the collected bio-signals;
(c) classifying sleep stages through a sleep analysis model by receiving the user sleep data as input, and detecting sleep disorders appearing in the classified sleep stages; and
(d) providing a user-customized stimulus for alleviating the detected sleep disturbance;
The biosignal includes at least one of an electrophysiological signal or a non-electrophysiological signal, and
(e) it is determined whether the detected sleep disorder is alleviated according to the user-customized stimulus according to step (d), but when it is determined that the detected sleep disorder is not alleviated, the intensity of the user-customized stimulus is adjusted based on the user-specific characteristics of the user which further comprises the step of
A personalized way to manage your sleep. According to claim 1,
The computing device is a human-computer interface device, and includes a user terminal, a measurement device, and a stimulus providing device,
In step (a), the user terminal receives the biosignal measured by the measuring device,
In step (d), the user-customized stimulus is provided through the stimulus providing device,
A personalized way to manage your sleep. According to claim 1,
The bio-signals of step (a) include bio-signals measured from the awake state before sleep,
That includes biosignals measured in real time according to sleep stages and sleep disorders after sleep starts,
A personalized way to manage your sleep. According to claim 1,
In the step (b), the pre-processing process removes noise included in the collected bio-signals, and extracts a preset frequency signal region for sleep phase classification through frequency filtering,
A personalized way to manage your sleep. According to claim 1,
In the sleep analysis model, the user sleep data including sleep start time and frequency information is learned through machine learning, classifies sleep stages, and detects sleep disorders appearing in the classified sleep stages,
Support Vector Machine (Support Vector Machine), Autoencoder (Autoencoder), Convolution Neural Network (Convolution Neural Network) or Recurrent Neural Network (Recurrent Neural Network) using any one of the machine learning algorithm,
A personalized way to manage your sleep. According to claim 1,
The step (a) further includes receiving user information including one or more of age, gender, height, and weight,
The step (b) further comprises calibrating the user sleep data based on the user information,
The step (c) classifies sleep stages through the sleep analysis model by inputting the user sleep data and the user information, and detecting sleep disorders appearing in the classified sleep stages.
A personalized way to manage your sleep. According to claim 1,
After step (d), sleep analysis result data including at least one of sleep phase, sleep disorder, sleep phase time, sleep disorder detection or not, quality of life data, user-customized stimulus type, or user-customized stimulus intensity is generated, That comprising providing the sleep analysis result data to the computing device through a visualized user interface,
A personalized way to manage your sleep. According to claim 1,
After the step (d), updating the sleep analysis result data changed by the user-customized stimulus, and further comprising the step of adjusting the intensity of the user-customized stimulus,
A personalized way to manage your sleep. In the user-customized sleep management system,
a measuring device including at least one measuring module for measuring a biosignal;
a stimulus providing device including at least one stimulus providing module for providing a stimulus to a user;
A computing device that collects bio-signals through the measurement device and provides a user-customized stimulus through the stimulus providing device for alleviation of sleep disorders in the sleep phase classified by analysis of the collected bio-signals,
The computing device includes a memory in which a user-customized sleep management program is stored;
A processor for executing the program stored in the memory;
The processor collects bio-signals measured through the measuring device by executing the program, and user sleep data generated by performing a pre-processing process on the collected bio-signals is input to a sleep analysis model to obtain sleep disorder information output, and the user-customized stimulus matching the sleep disorder information is provided through the stimulus providing device,
The biosignal includes at least one of an electrophysiological signal or a non-electrophysiological signal, and
The processor determines whether the sleep disorder is alleviated by providing the user-customized stimulus matching the sleep disorder information by executing the program. configured to further perform modulating the intensity of the stimulus,
A customizable sleep management system. 10. The method of claim 9,
The computing device is a user terminal,
The collected bio-signals are transmitted to an external server to generate the user sleep data, and the user sleep data is input to a sleep analysis model operating in the external server to output sleep disorder information, and by the external server A user-customized sleep management system that receives information on the generated user-customized stimulus and provides it through the stimulus providing device. 10. The method of claim 9,
The bio-signals include bio-signals measured from the awake state before sleep and bio-signals measured in real time according to sleep stages and sleep disorders after sleep starts,
A customizable sleep management system. 10. The method of claim 9,
The pre-processing process is to remove noise included in the collected bio-signals, and to extract a preset frequency signal region for sleep phase classification through frequency filtering,
A customizable sleep management system. 10. The method of claim 9,
In the sleep analysis model, the user sleep data including sleep start time and frequency information is learned through machine learning, classifies sleep stages, and detects sleep disorders appearing in the classified sleep stages,
Support Vector Machine (Support Vector Machine), Autoencoder (Autoencoder), Convolution Neural Network (Convolution Neural Network) or Recurrent Neural Network (Recurrent Neural Network) using any one of the machine learning algorithm,
A customizable sleep management system. 10. The method of claim 9,
The processor receives user information including one or more of age, gender, height, and weight through the computing device,
Calibrate the user sleep data based on the user information,
Classifying sleep stages through the sleep analysis model by inputting the user sleep data and the user information, and detecting sleep disorders appearing in the classified sleep stages,
A customizable sleep management system. 10. The method of claim 9,
After the processor provides the user-customized stimulus, the sleep analysis result including at least one of a sleep stage, a sleep disorder, a time for each sleep step, whether a sleep disorder is detected, quality of life data, a user-customized stimulus type, or a user-customized stimulus intensity generating data and providing the sleep analysis result data to the computing device through a visualized user interface,
A customizable sleep management system. 10. The method of claim 9,
After providing the user-customized stimulus, the processor updates the sleep analysis result data changed by the user-customized stimulus, and adjusts the intensity of the user-customized stimulus,
A customizable sleep management system. A non-transitory computer-readable recording medium on which a computer program for performing the method according to claim 1 is recorded.

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