KR20140030489A - System for detecting sleep disorders with sensor unit attached to trousers - Google Patents

Abstract

According to embodiments of the present invention, a sleep disturbance detection system includes: a bottom-attached remote sensor unit which includes at least one sensor module inside an outer cover and of which the soft outer cover is attached to the top of the bottoms of a user; and a data collection unit which receives detection data generated in the sensor module from the bottom-attached remote sensor unit. If part of the soft outer cover is exposed outside the top of the bottoms and the remaining part is inserted into the inside in which the top of the bottoms and the body of the user are in contact, the exposed part of the soft outer cover and the remaining part are attracted closely and fixed by gravitation of two magnetic bodies so that the bottom-attached remote sensor unit can be attached to the top of the bottoms.

Description

Sleep disturbance detection system with bottom-mounted sensor unit {SYSTEM FOR DETECTING SLEEP DISORDERS WITH SENSOR Unit ATTACHED TO TROUSERS}

The present invention relates to a sleep disorder detection device.

Sleep disorder is a term for sleepless illness or sleepless illness. Common sleep disorders include insomnia, sleep apnea, and restless leg syndrome.

Insomnia may be a disease in itself, but it may also be a secondary symptom of other sleep disorders such as sleep apnea or periodic limb motility.

Sleep apnea is a condition in which a person who snores severely stops breathing temporarily. It is commonly found in people who are obese or who snore severely. Sleep apnea can reduce sleep quality and interfere with deep sleep, leading to chronic sleep deprivation that may not last long. It also lowers blood oxygen levels during sleep and can threaten your health, along with other physical problems such as cerebrovascular disease and myocardial infarction.

Anxiety syndrome is a disorder that prevents you from falling asleep because you have limbs or something that crawls when you try to sleep.

Sleep disorders usually occur in adults but often in children, which can interfere with growth and cause mental distress.

Because sleep disorders can be mental or physical disorders, they can be of various kinds, or they can overlap two or more complex problems, the first step in diagnosing sleep disorders is a sleep plural test. The sleep plural test is a sleep structure test that distinguishes REM and non-REM sleep through EEG, safety and jaw electromyography, and sleep through temperature sensor, pressure sensor, microphone, chest motion sensor, abdominal motion sensor and blood oxygen sensor. Sleep breath test to evaluate the smoothness of the middle breath, left and right leg EMG, arm EMG, sleep posture sensor, video recording, etc. sleep movement test to monitor and record the sleep movement, oxygen saturation and electrocardiogram by recording the cardiovascular system Cardiovascular tests to diagnose abnormalities.

Although these polysomnography tests can be diagnosed accurately, they are expensive equipment, and they can be rented for treatment and worn or installed for only one night.

Therefore, rather than precise and multi-dimensional diagnosis, there is a need for a sleep disorder detection device that can be used simply and personally in the home to help diagnose, or to monitor the basic sleep status of elderly patients or users in a nursing facility at all times. .

The problem to be solved by the present invention is to provide a sleep disorder detection system that is easy to wear and use, can collect a variety of data for diagnosis without inconvenience, free to configure and expand.

Sleep disorder detection system according to an aspect of the present invention,

A bottom attachable remote sensor unit including at least one sensor module inside the flexible skin and wherein the flexible skin is attached to the upper end of the user; And

It may include a data collection unit for receiving the detection data generated in the sensor module from the bottom attached remote sensor unit.

According to one embodiment, when the part of the soft skin is exposed to the outside of the top of the bottom and the other part is drawn inward to contact the body of the top of the bottom and the user, the exposed part and the remaining part of the soft skin The bottom-mounted remote sensor unit can be attached to the top of the bottom by being fixedly approached by the attraction force of at least two magnetic bodies.

According to an embodiment, the sensor module may include at least one of an accelerometer, an acoustic sensor, a temperature sensor, and a humidity sensor.

According to an embodiment of the present disclosure, the bottom attachable remote sensor unit may further include a hardware module in which electronic circuits are required to sample, digitize, and digitally output detection data generated by the sensor module to the data collection unit. .

The apparatus of claim 1, wherein the data collection unit is operable to analyze the detection data to extract sleep state information of the user.

According to one embodiment, the sensor module includes an accelerometer,

The data collection unit may be operable to analyze the up and down of the user's abdomen from the detection data of the accelerometer to detect the user's breathing and apnea conditions during sleep.

According to one embodiment, the sensor module includes an accelerometer,

The data collection unit may be operable to detect a change in posture of the user during sleep by analyzing the user's inversion from the detection data of the accelerometer.

According to one embodiment, the sensor module includes an acoustic sensor,

The data collection unit may be operable to detect a user's snoring, apnea or sleep talking from the detection data of the acoustic sensor.

According to an embodiment, the data collection unit may be operable to adaptively adjust a period in which the sensor module generates detection data according to the extracted sleep state information.

According to one embodiment, the data collection unit may be operable to send the detection data or the extracted sleep state information to the outside for the external diagnostic server.

According to one embodiment, the sleep disorder detection system,

The apparatus may further include a diagnosis server configured to store the detection data so that the diagnosis data may be provided for diagnosis of a sleep disorder by a specialist or a case-based expert system.

According to one embodiment, when the part of the soft skin is exposed to the outside of the top of the bottom and the other part is drawn inward to contact the body of the top of the bottom and the user, the exposed part and the remaining part of the soft skin The lower attachment type remote sensor unit can be attached to the upper end by being fixedly approached by the elastic force of the elastic body.

Sleep disorder detection system according to another aspect of the present invention,

A plurality of bottom attached remote sensor units including at least one sensor module inside the flexible skin and wherein the soft skin is attached to the top of the bottom of the user;

A data collection gateway forming one sub-network with the plurality of bottom mounted remote sensor units and receiving detection data generated in the sensor module from each bottom mounted remote sensor unit; And

And a monitoring server configured to receive detection data from the data collection gateway, analyze the received detection data, and monitor a sleep state of the user based on the extracted sleep state information of the user.

According to an embodiment, the data collection unit may be operable to analyze the detection data to extract sleep state information of the user.

According to one embodiment, the sensor module includes an accelerometer,

The monitoring server may be operable to detect the user's respiration and apnea during sleep by analyzing the up and down of the user's abdomen from the detection data of the accelerometer.

According to one embodiment, the sensor module includes an accelerometer,

The monitoring server may be operable to detect a change in the posture of the user during sleep by analyzing the user's inclination from the detection data of the accelerometer.

According to one embodiment, the sensor module includes an acoustic sensor,

The monitoring server may be operable to detect a user's snoring, apnea or drool from the detection data of the acoustic sensor.

According to an embodiment, the data collection unit may be operable to adaptively adjust a period in which the sensor module generates detection data according to the extracted sleep state information.

Bottom attachable remote sensor unit according to another aspect of the present invention,

Soft shells that provide space within and can be grafted;

At least one sensor module mounted in an inner space of the flexible shell; And

When some of the soft skin is exposed to the outside of the top of the bottom and the other part is introduced into the inner contact with the top of the bottom and the user's body, the exposed part and the remaining part of the soft skin between the top of the bottom By means of fixed proximity, it may comprise clamping means for attaching the soft skin to the top of the bottom.

According to one embodiment, the clamping means,

The exposed portion and the remaining portion of the soft skin may be configured to be fixedly close by the attraction of at least two magnetic materials.

According to one embodiment, the clamping means,

The exposed portion and the remaining portion of the flexible shell may be configured to fixedly close by the elastic force of the elastic body.

According to an embodiment, the sensor module may include at least one of an accelerometer, an acoustic sensor, a temperature sensor, and a humidity sensor.

According to one embodiment, the below attached remote sensor unit,

The electronic device may further include a hardware module including electronic circuits necessary for sampling, digitizing, and wirelessly transmitting detection data generated by the sensor module.

According to an embodiment, the hardware module may be operable to analyze the detection data to extract sleep state information of the user.

According to one embodiment, the sensor module includes an accelerometer,

The hardware module may be operable to analyze the up and down of the user's abdomen from the detection data of the accelerometer to detect the user's breathing and apnea conditions during sleep.

According to one embodiment, the sensor module includes an accelerometer,

The hardware module may be operable to detect a change in the posture of the user during sleep by analyzing the user's inclination from the detection data of the accelerometer.

According to one embodiment, the sensor module includes an acoustic sensor,

The hardware module may be operable to detect a user's snoring, apnea or sleep talking from the detection data of the acoustic sensor.

According to an embodiment, the hardware module may be operable to adaptively adjust a period in which the sensor module generates detection data according to the extracted sleep state information.

According to the sleep disorder detection system of the present invention, the remote sensor unit can be simply attached to the upper end of the lower part, and does not disturb sleep when worn and used.

According to the sleep disorder detection system of the present invention, detection data can be wirelessly transmitted to the data collection unit, and information such as movement during sleep, apnea, snoring, and temperature change can be processed based on the transmitted detection data. .

According to the sleep disorder detection system of the present invention, it is possible to determine whether an emergency occurs based on the transmitted detection data, and propagate the emergency through wired or wireless communication.

According to the sleep disorder detection system of the present invention, it is possible to wear a plurality of remote sensor units and monitor the sleep state of users for various users sleeping in a limited space.

1 is a conceptual diagram illustrating a sleep disorder detection system according to an embodiment of the present invention.
2 is a conceptual diagram illustrating a sleep disorder detection system according to another embodiment of the present invention.

For the embodiments of the invention disclosed herein, specific structural and functional descriptions are set forth for the purpose of describing an embodiment of the invention only, and it is to be understood that the embodiments of the invention may be practiced in various forms, The present invention should not be construed as limited to the embodiments described in Figs.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The same reference numerals are used for the same constituent elements in the drawings and redundant explanations for the same constituent elements are omitted.

1 is a conceptual diagram illustrating a sleep disorder detection system according to an embodiment of the present invention.

Referring to FIG. 1, the sleep failure detection system 10 may include an attached remote sensor unit 11, a data collection unit 12, a network 13, and a diagnosis server 14.

The remote sensor unit 11 is a flexible and flat printed circuit board (111a, 111b), accelerometer 112, acoustic sensor 113, temperature sensor 114, humidity sensor 115, hardware module 116, power module 117, the clamping means 118a, 118b and a thin, flexible, flat fabric, such as a cloth, a textile fabric, a synthetic resin film, which will at least partially contain and protect them 111-118 It may be fabricated to include a soft skin (119).

The flexible skin 119 is made of two layers of thin, flexible, and flat fabric that can be folded (eg folded halfway from the middle), and can house circuit boards, sensors, or modules without moving. It may be processed and provided in a shape having a space. The flexible sheath 119 may be waterproof so as not to be influenced by the operation of the remote sensor unit 11 due to body fluids or sweat, and may also protect the modules 112 to 117 to be mounted inside or on the surface. It can have a sufficient mechanical strength.

At least one pair of clamping means 118a, 118b, such as magnetic material, is fixed to the two faces that are encountered when the flexible shell 119 is folded, for example in a shape and a position that are adapted to attract each other with different polarities. Can be.

The remote sensor unit 11 enters a portion of the flexible shell 119 to which one of the magnetic bodies is fixed, for example, at an upper end of the lower portion, and comes into contact with the lower belly, and the other of the magnetic bodies 118b is fixed to the flexible shell ( The other part of 119 may be fixedly attached to the bottom by clamping means 118a, 118b, such as a magnetic body, which attracts each other, while being exposed outward at the top of the bottom.

According to an embodiment, the clamping means 118a, 118b may be in the form of forceps, clamps, tongs, clips, or clothespins which are mechanically compressed by pressing the upper end by elastic force.

The printed circuit board 111 may be fixedly accommodated in the inner receiving space provided by the flexible shell 119, may be embodied as the flexible circuit board, or the flexible shell 119 may be easily folded. It may also be divided into at least two small partial substrates (111a, 111b) illustratively so that the user does not feel a foreign object. According to an exemplary embodiment, all of the partial substrates 111a and 111b may be accommodated on some side of the flexible outer shell 119 which is exposed to the outside of the lower side.

According to an embodiment, all of the sensor modules 112 to 115, the hardware module 116, and the power module 117 may be mounted on one printed circuit board 111, but the respective modules 112 to 117 may be mounted. Each of the partial substrates 111a and 111b may be mounted separately, and the partial substrates 111a and 111b may be connected by a cable or a flexible connector substrate.

The user's breathing state can be detected during sleep from the data measured by the accelerometer 112. Since the remote sensor unit 11 is preferably attached on the lower abdomen, the accelerometer 112 can detect the rise and fall of the abdomen during normal abdominal breathing, and can detect that the abdominal movement stops during abnormal apnea. have.

Furthermore, from the data measured by the accelerometer 112, a large movement of the user's reversal during sleep can be distinguished from the breath and analyzed, and a change in the sleeping posture of the user can be detected.

From the data measured by the acoustic sensor 113, it is possible to detect Cocoy, which frequently occurs with sleep disorders, and furthermore, apnea and accompanying drooling. In order to detect apnea or movement during sleep, the measurement data of the acoustic sensor 113 and the measurement data of the accelerometer 112 may be used together.

The temperature sensor 114 may measure the temperature around the body during sleep. Furthermore, it is possible to detect whether the user sleeps, for example, covers a blanket and whether the room temperature during sleep is appropriate.

The humidity sensor 115 may measure the ambient humidity of the body during sleep. Furthermore, it functions auxiliary to the temperature sensor 114, and can detect a user's sleeping habit, for example, whether to cover a blanket.

The hardware module 116 has a digital processing function of sampling, digitizing and collecting detection data generated by the sensors 112 to 115 and storing them temporarily or long-term together with visual information, and additionally, detecting data and visual information. The radio communication function to be transmitted to 12 can be provided.

According to an embodiment, the hardware module 116 may control the sensing period of the sensors 112 to 115 fixedly, but if the breath is normally detected, for example, if the breathing is detected abnormally, the sensing period is increased. In a manner of reducing the sensing period, the sensing period of the sensors 112 to 115 may be adaptively adjusted according to the periodicity of the breath.

According to an embodiment, the hardware module 116 may have only a small amount of processing capacity and storage capacity for small size and light weight, and may have a small-capacity short-range communication function such as Radio Frequency Identification (RFID) and Bluetooth (Bluetooth).

The hardware module 116 may transmit bursts in a single burst instead of continuously sending out generated detection data to minimize power consumption.

The power supply module 117 supplies power for the sensor modules 112 to 115 and the hardware module 116 to operate.

The data collection unit 12 can be fixedly installed within the communication distance with the remote sensor unit 11 adjacent to the position where the user wears the remote sensor unit 11 and takes the water surface.

The data collection unit 12 may be connected to the remote sensor unit 11 according to a predetermined short range wireless communication standard to receive detection data from the remote sensor unit 11.

The data collection unit 12 sorts and analyzes the detection data based on visual information to extract sleep state information of at least one of respiratory frequency, apnea occurrence or retention time, degree of Coco, movement during sleep, ambient temperature and humidity. can do.

According to an embodiment, the data collection unit 12 may increase the sensing period when the breath is normally detected based on the extracted sleep state information, and reduce the sensing period when the breath is abnormally detected, such as apnea. 116 may be instructed to adjust the sensing period adaptively according to the periodicity of the breath.

According to an embodiment, the data collection unit 12 may be implemented as a mobile information processing device 15 of a user such as a smartphone, and may display sleep state information and its history to the user by itself.

In another embodiment, the data collection unit 12 may communicate sleep state information to the remote diagnostic server 14 via the medium / long range network 13.

The diagnosis server 14 may sleep information such as sleep status information and history, sleep habits such as Coco, apnea, and overturning, and sleep environment such as temperature and humidity so as to diagnose a user's sleep disorder by an expert or case-based expert system. It can store and manage the detection data about.

In addition, the diagnosis server 14 may provide a result of the sleep disorder diagnosis to the user's mobile information processing device 15 such as a smartphone through the medium / long distance network 13 to feed back the cause of the sleep disorder to the user.

2 is a conceptual diagram illustrating a sleep disorder detection system according to another embodiment of the present invention.

Referring to FIG. 2, a sleep failure detection system 20 according to another embodiment may include a plurality of attached remote sensor units 11, a data collection gateway 22, a network 23, and a monitoring server 24. It may include.

The attached remote sensor units 11 of FIG. 2 are substantially the same as the attached remote sensor units 11 of FIG. 1, and thus description thereof is omitted.

However, the attached remote sensor units 11 of FIG. 2 may have a low power wireless sensor network communication function such as 6LoWPAN and ZigBee.

The sleep disorder detection system 20 illustrated in FIG. 2 illustrates a configuration suitable for, for example, a nursing home or the like that requires careful monitoring of sleep conditions of users.

Many users wear sleeper attached remote sensor units 11 at the time of sleep. A data collection gateway 22 is installed in each call room used by users, and the data collection gateway 22 constitutes a plurality of attached remote sensor units 11 and a wireless short-range communication network (WPAN) subnetwork.

The data collection gateway 22 collects detection data from the remote sensor units 11 constituting the corresponding subnetwork and transmits the detected data to the monitoring server 24 through the network 23.

The monitoring server 24 extracts sleep state information by analyzing the detection data received for each of the remote sensor units 11 of the users, and when determined to be an abnormal sleep state, for example, the apnea state becomes longer than a predetermined time or If Cocall determines that it is excessive, it can alert the manager. In addition, the monitoring server 24 may monitor the user's sleep habits such as sleep status information, histories, and his / her sleep habits such as Cocoon, Apnea, and Retreat to diagnose the user's sleep disorder by an expert or case-based expert system. It can store and manage the detection data about.

For example, the monitoring server 24 may detect a user's breathing state during sleep or a large movement of the user's reversal during sleep from the data measured by the accelerometer 112 of the remote sensor unit 11 to distinguish from the breathing. Can be.

Furthermore, the monitoring server 24 can detect the co-occurrence that frequently occurs with sleep disorders, and also the apnea situation accompanied by the co-col from the data measured by the acoustic sensor 113 of the remote sensor unit 11, or the drool. have.

The monitoring server 24 may use the measurement data of the acoustic sensor 113 and the measurement data of the accelerometer 112 together to detect apnea or movement during sleep.

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, the spirit of the present invention should be understood only in accordance with the following claims, and all of the equivalent or equivalent variations will fall within the scope of the present invention.

10, 20 sleep disorder detection system
11 Attachable Remote Sensor Unit
12 Data Acquisition Unit 22 Data Acquisition Gateway
13, 23 networks
14 Diagnostic Server 24 Monitoring Server
111a, 111b printed circuit board 112 accelerometer
113 Acoustic Sensor 114 Temperature Sensor
115 Humidity Sensor 116 Hardware Module
117 power supply module 118a, 118b clamping means
119 ductile sheath

Claims (28)

A bottom attachable remote sensor unit including at least one sensor module inside the flexible skin and wherein the flexible skin is attached to the upper end of the user; And
And a data collection unit for receiving detection data generated in the sensor module from the bottom-mounted remote sensor unit. The method according to claim 1, wherein when some of the soft skin is exposed to the outside of the upper end of the lower part and the remaining part is drawn into the inner contact with the upper end of the lower body and the user's body, the exposed portion and the remaining part of the soft outer shell at least A sleep disturbance detection system, characterized in that the bottom-mounted remote sensor unit is attached to the top of the bottom by being fixedly approached by the attraction of two magnetic bodies. The sleep disorder detection system of claim 1, wherein the sensor module comprises at least one of an accelerometer, an acoustic sensor, a temperature sensor, and a humidity sensor. The method according to claim 1, wherein the attached remote sensor unit further comprises a hardware module formed with electronic circuits necessary for sampling and digitizing the detection data generated in the sensor module and wireless transmission to the data collection unit. Sleep disorder detection system. The sleep disorder detection system according to claim 1, wherein the data collection unit is operative to analyze the detection data to extract sleep state information of a user. The method according to claim 5, wherein the sensor module includes an accelerometer,
And the data collection unit is operable to analyze the up and down of the abdomen of the user from the detection data of the accelerometer to detect the breathing and apnea state of the user during sleep. The method according to claim 5, wherein the sensor module includes an accelerometer,
And the data collection unit is operable to detect a change in the posture of the user during sleep by analyzing the user's inclination from the detection data of the accelerometer. The method of claim 5, wherein the sensor module comprises an acoustic sensor,
And the data collection unit is operable to detect a snoring, apnea or sleep talking of the user from detection data of the acoustic sensor. The system of claim 5, wherein the data collection unit is operative to adaptively adjust a period in which the sensor module generates detection data according to the extracted sleep state information. 6. The sleep disorder detection system according to claim 5, wherein the data collection unit is operative to send out the detection data or the extracted sleep state information to an external diagnostic server. The sleep disorder detection system of claim 1, further comprising a diagnostic server that stores the detection data so that it can be provided to diagnose a sleep disorder of a user by an expert or case based expert system. 2. The exposed part of the flexible skin and the remaining part of the flexible skin when the part of the soft skin is exposed to the outside of the top of the bottom and the other part is brought into the inner contact with the body of the user and the top of the bottom. Sleeping disorder detection system, characterized in that the bottom-mounted remote sensor unit is attached to the top of the bottom by being fixed close by the elastic force of the bottom. A plurality of bottom attached remote sensor units including at least one sensor module inside the flexible skin and wherein the soft skin is attached to the top of the bottom of the user;
A data collection gateway forming one sub-network with the plurality of bottom mounted remote sensor units and receiving detection data generated in the sensor module from each bottom mounted remote sensor unit; And
And a monitoring server configured to receive detection data from the data collection gateway, analyze the received detection data, and monitor a sleep state of the user based on the extracted sleep state information of the user. The system of claim 13, wherein said data collection unit is operative to analyze said detection data to extract sleep status information of a user. The method of claim 14, wherein the sensor module comprises an accelerometer,
And said monitoring server is operable to detect the user's respiration and apnea during sleep by analyzing the up and down of the user's abdomen from the detection data of the accelerometer. The method of claim 14, wherein the sensor module comprises an accelerometer,
And the monitoring server is operable to detect a change in the posture of the user during sleep by analyzing the user's backwards from the detection data of the accelerometer. The method of claim 14, wherein the sensor module comprises an acoustic sensor,
And said monitoring server is operable to detect a snoring of a user from apnea to sleepiness from detection data of said acoustic sensor. 15. The system of claim 14, wherein said data collection unit is operative to adaptively adjust a period in which said sensor module generates detection data according to said extracted sleep state information. Soft shells that provide space within and can be grafted;
At least one sensor module mounted in an inner space of the flexible shell; And
When the part of the soft skin is exposed to the outside of the top of the bottom and the other part is drawn into the inner contact with the top of the bottom and the user's body, the exposed part and the remaining part of the soft skin between the top of the bottom And a clamping means for attaching the soft skin to the upper end by fixing it in close proximity. The method of claim 19, wherein the clamping means,
And the exposed part of the flexible skin and the remaining part are fixedly close by the attraction of at least two magnetic bodies. The method of claim 19, wherein the clamping means,
The bottom-mounted remote sensor unit of claim 1, wherein the exposed part and the remaining part of the flexible shell are configured to be fixedly close by the elastic force of the elastic body. 20. The bottom attachable remote sensor unit of claim 19, wherein said sensor module comprises at least one of an accelerometer, an acoustic sensor, a temperature sensor, and a humidity sensor. The method of claim 19,
And a hardware module having electronic circuits necessary for sampling, digitizing, and wirelessly transmitting detection data generated by the sensor module to the outside. 24. The bottom attachable remote sensor unit according to claim 23, wherein the hardware module is operative to analyze the detection data to extract sleep state information of the user. The method of claim 24, wherein the sensor module comprises an accelerometer,
And the hardware module is operable to analyze the up and down of the user's abdomen from the detection data of the accelerometer to detect the user's breathing and apnea during sleep. The method of claim 24, wherein the sensor module comprises an accelerometer,
And the hardware module is operable to detect a change in the posture of the user during sleep by analyzing the user's reversal from the detection data of the accelerometer. The method of claim 24, wherein the sensor module comprises an acoustic sensor,
And said hardware module is operable to detect a snoring of a user from apnea or a drool from detection data of said acoustic sensor. 25. The bottom attachable remote sensor unit of claim 24, wherein the hardware module is operative to adaptively adjust a period in which the sensor module generates detection data according to the extracted sleep state information.

Images