JP2016101349A - Bruxism detection device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a detection device that can detect bruxism of a sleeper with high accuracy.SOLUTION: A bruxism detection device 20 comprises: a vibration detection part 21 that detects vibration generated from a head 16 of a sleeper 15; and a bruxism determination part 31 that determines the presence or absence of bruxism of the sleeper 15 from the detected vibration.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a bruxism detection device.

  Conventionally, it is known that a sleeper's bruxism is detected based on a sleeper's biometric information. For example, Patent Document 1 describes detecting a sleeper's bruxism by detecting and analyzing a sound generated by the sleeper using a microphone.

JP 2008-000222 A

  However, when detecting a sound generated by a sleeper using a microphone, the detection accuracy may deteriorate due to the influence of ambient noise and the like. When the detection accuracy of the sound generated by the sleeper is deteriorated, the accuracy of the detection of the bruxism is inevitably lowered because the accuracy of the sound information is low even if the detection of the bruxism is detected from the detected sound information.

  This invention is made | formed in view of this point, The objective is to detect a sleeper's bruxism with high precision.

  The first invention is directed to the bruxism detection device (20). The bruxism detection device (20) includes a vibration detection unit (21) that detects vibration generated from the head (16) of the sleeper (15), and the presence or absence of bruxism of the sleeper (15) from the vibration. And a bruxism determination unit (31) for determination.

  In the said 1st invention, the vibration which generate | occur | produces from a sleeper's (15) head (16) is detected, and the presence or absence of a bruxism of a sleeper (15) is determined from the detected vibration. When detecting the vibration generated from the head (16), even if noise is generated in the surroundings, the influence of the noise on the detection result is small. For this reason, even if noise is generated around the sleeper (15), vibration generated from the head (16) of the sleeper (15) is detected with high accuracy. And since the bruxism of the sleeper (15) is detected from the vibration detected with high accuracy, the bruxism of the sleeper (15) is also detected with high accuracy.

  Here, when recording a brux sound generated by the sleeper (15) with a microphone, for example, a sound other than a brux sound such as sleep is also recorded, which may cause a problem in terms of privacy protection. On the other hand, in the first invention, the vibration of the sleeper (15) 's head (16) is detected, not the sound of the sleeper's (15), but based on the detected vibration. The presence or absence of bruxism in the sleeper (15) is determined. For this reason, in the present invention, unlike the case where the sound itself is recorded, there is almost no possibility of causing a problem regarding privacy protection.

  According to a second invention, in the first invention, the vibration detector (21) is configured such that the internal pressure changes according to vibration generated from the head (16) of the sleeper (15). And a pressure receiving part (23) for detecting a change in the internal pressure of the pressure sensitive tube (22).

  In the second invention, the internal pressure of the pressure sensitive tube (22) changes due to vibration generated from the head (16) of the sleeper (15). A pressure receiving part (23) detects. The internal pressure of the pressure-sensitive tube (22) changes according to vibration generated from the head (16) of the sleeper (15), but does not substantially change depending on ambient noise. For this reason, it is reliably prevented that the accuracy of detection of bruxism is deteriorated by ambient noise.

  According to a third invention, in the first or second invention, the bruxism determining unit (31) calculates a power spectrum of the vibration, and based on the calculated power spectrum, the sleeper (15) It is characterized by determining the presence or absence of bruxism.

  In the said 3rd invention, the presence or absence of bruxism of a sleeper (15) is determined based on the power spectrum of the vibration which generate | occur | produces from a sleeper's (15) head (16). For this reason, compared with the case where the bruxism is detected based on the frequency of occurrence of vibrations, for example, the bruxism of the sleeper (15) is more reliably detected.

  According to a fourth invention, in any one of the first to third inventions, the vibration detection unit (21) is disposed below the head (16) of the sleeper (15). It is characterized by that.

  In the fourth invention, since the vibration detection unit (21) is near the head (16) of the sleeper (15), vibration generated from the head (16) of the sleeper (15) It does not attenuate so much until it is transmitted to (21). For this reason, the vibration which generate | occur | produces from a sleeper's (15) head (16) and by extension, a sleeper's (15) bruxism can be detected with higher precision.

  In a fifth aspect based on the fourth aspect, the vibration detection section (21) is provided inside a pillow (11) that supports the head (16) of the sleeper (15). And

  In the fifth invention, the vibration detection unit (21) is provided inside the pillow (11) on which the head (16) of the sleeper (15) is placed. For this reason, vibration generated from the head (16) of the sleeper (15) is reliably transmitted to and detected by the vibration detector (21).

  In a sixth aspect based on the fourth aspect, the vibration detector (21) is provided under the pillow (11) that supports the head (16) of the sleeper (15). And

  In the sixth invention, the vibration detection unit (21) is provided under the pillow (11) on which the head (16) of the sleeper (15) is placed. That is, the vibration detection unit (21) is installed near the head (16) of the sleeper (15). For this reason, vibration generated from the head (16) of the sleeper (15) is reliably transmitted to and detected by the vibration detector (21).

  In the present invention, the vibration generated from the head (16) of the sleeper (15) is detected instead of the sound of the sleeper (15), and the presence or absence of the sleeper (15) is detected from the detected vibration. judge. For this reason, even if there is noise around the sleeper (15), it is possible to detect the bruxism of the sleeper (15) with high accuracy. Moreover, it is possible to prevent the occurrence of a privacy problem that is a concern when recording sounds around the sleeper (15) including sounds other than bruxism.

  Moreover, in the said 2nd invention, the internal pressure of the pressure sensing tube (22) which changes according to the vibration generate | occur | produced from a sleeper's (15) head (16) is detected by the pressure receiving part (23). For this reason, vibration generated from the head (16) of the sleeper (15) can be reliably detected using the pressure-sensitive tube (22) having a simple structure.

  Moreover, in the said 3rd invention, the presence or absence of a bruxism of a sleeper (15) is determined based on the power spectrum of the vibration generate | occur | produced from a sleeper (15) head (16). For this reason, compared with the case where the bruxism is detected based on the frequency of occurrence of vibration, for example, the bruxism of the sleeper (15) can be detected more reliably.

  Moreover, according to the said 4th-6th invention, a vibration detection part (21) can be arrange | positioned near the head (16) of a sleeper (15), and it originates in sleepiness of a sleeper (15) The vibration of the head (16) to be detected can be detected with higher accuracy.

FIG. 1 is a schematic diagram showing a bruxism detection device and bedding according to an embodiment of the present invention. FIG. 2 is a side view showing the arrangement of the pressure-sensitive tubes. FIG. 3 is a flowchart for explaining a method for detecting sleepiness of a sleeper. FIG. 4 is a side view showing the arrangement of pressure-sensitive tubes according to another embodiment. FIG. 5 is a side view showing the arrangement of pressure-sensitive tubes according to other embodiments.

  Embodiments of the present invention will be described in detail with reference to the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

  FIG. 1 is a schematic diagram illustrating a configuration of a bruxism detecting device (20) according to the embodiment. As shown in the figure, the bruxism detection device (20) is used together with a bedding (10) such as a futon or a bed, for example, and includes a vibration detection unit (21) and a signal processing unit (30). Yes. In this description, the left / right direction viewed from the sleeper (15) is referred to as “left / right direction”, and the vertical direction (different from the vertical direction viewed from the sleeper (15)) is referred to as “vertical direction”. .

-Vibration detector-
The vibration detection unit (21) detects vibration generated from the head (16) of the sleeper (15) and includes a pressure-sensitive tube (22) and a pressure receiving unit (23). .

<Pressure-sensitive tube>
The pressure-sensitive tube (22) is formed in a tube shape, and the internal pressure changes according to the vibration generated from the head (16) of the sleeper (15). Specifically, the pressure-sensitive tube (22) is constituted by a resin (for example, vinyl chloride) tube having an inner diameter of about 4 mm, one end thereof is opened, and the other end is connected to the pressure receiving portion (23). Yes. With such a configuration, when the pressure accompanying the vibration generated from the head (16) of the sleeper (15) acts on the pressure sensitive tube (22), the internal pressure of the pressure sensitive tube (22) changes. One end of the pressure sensitive tube (22) may be closed.

  The pressure sensitive tube (22) is provided inside the pillow (11) that supports the head (16) of the sleeper (15) (see FIG. 2). That is, the pressure sensitive tube (22) is disposed below the head (16) of the sleeper (15). Moreover, the pressure-sensitive tube (22) is provided so as to extend from one end of the pillow (11) to the other end along the left-right direction of the sleeper (15). For this reason, even if the sleeper (15) moves left and right due to turning over, etc., the pressure sensitive tube (22) is located on the floor side of the head (16) of the sleeper (15), and the sleeper Vibration generated from the head (16) of (15) is efficiently transmitted to the pressure sensitive tube (22).

<Pressure receiving part>
A pressure receiving part (23) detects the change of the internal pressure of a pressure sensitive tube (22), and outputs the sensor signal according to the change of the internal pressure of a pressure sensitive tube (22). Specifically, the pressure receiving part (23) is connected to the other end of the pressure sensitive tube (22), and converts a change in internal pressure of the pressure sensitive tube (22) into a sensor signal (electric signal). The pressure receiving part (23) is constituted by a microphone, for example. The sensor signal is sent to the bruxism judgment unit (31).

-Signal processing unit-
The signal processing unit (30) includes a bruxism determination unit (31) and a recording unit (32). The signal processing unit (30) is electrically connected to the pressure receiving unit (23) and receives an output signal of the pressure receiving unit (23).

  The signal processing unit (30) may include a display unit such as a liquid crystal panel for displaying information recorded in the recording unit (32) described later. The signal processing unit (30) may include an output port for outputting information recorded in the recording unit (32) to an external device such as a personal computer.

<Grushing judgment part>
The bruxism determining unit (31) is configured to determine the presence or absence of bruxism of the sleeper (15) by processing the sensor signal from the pressure receiving unit (23). That is, the bruxism determining unit (31) determines whether or not the sleeper (15) has bruxism from vibrations generated from the head (16) of the sleeper (15). For example, the bruxism determination unit (31) is configured by a CPU, a memory (a memory that stores a program for operating the CPU), and the like. The operation by the bruxism judging unit (31) will be described later in detail.

<Recording section>
The recording unit (32) is configured with a memory or the like, and when the bruxism determination unit (31) determines that the sleeper (15) is bruxized, that is, when the sleeper (15) is detected In addition, information indicating that bruxism has been detected is recorded together with information such as the detected time. Thereby, the sleeper (15) can confirm after waking up whether he / she was bruised during sleep.

-Operation of the bruxism judging unit and recording unit-
Next, operations of the bruxism determining unit (31) and the recording unit (32) will be described with reference to FIG. This figure is a flowchart for explaining a method for detecting sleepiness of a sleeper.

  The bruxism determining unit (31) and the recording unit (32) repeatedly execute steps S1 to S5 while the sleeper (15) is sleeping.

  First, in step S1, the bruxism determining unit (31) collects sensor signals from the pressure receiving unit (23). At this time, the bruxism determining unit (31) samples the sensor signal from the pressure receiving unit (23) at a predetermined cycle, thereby obtaining time series data of the internal pressure of the pressure sensitive tube (22).

  In step S2, the bruxism determining unit (31) extracts a low-frequency signal by subjecting the sensor signal from the pressure receiving unit (23) to low-pass filtering. The cutoff frequency of the low-pass filter is set so that, for example, a signal of 6.3 kHz or less can be extracted. Hereinafter, the extracted low-frequency signal is referred to as “extracted signal”.

  In step S3, the bruxism determining unit (31) calculates a power spectrum of vibration generated from the head (16) of the sleeper (15) based on the extracted signal. Specifically, the bruxism determination unit (31) calculates the power of the extracted signal, which is time-series data sampled at a predetermined period, and obtains a power spectrum by performing frequency analysis on the waveform of the power.

  In step S4, the bruxism determining unit (31) determines the presence or absence of bruxism of the sleeper (15) based on the calculated power spectrum. Here, when the vibration generated from the head (16) of the sleeper (15) includes a component due to bruxism, in the power spectrum of the vibration, there is one peak in a region of 2 kHz or less, In addition, it is known that a plurality of peaks exist in the region of 3 to 6.3 kHz.

  Therefore, in step S4, the bruxism determining unit (31) has a case where one peak is present in the region of 2 kHz or less and a plurality of peaks are present in the region of 3 to 6.3 kHz in the calculated power spectrum. Furthermore, it is determined that the sleeper (15) is bruxized. If it is determined that the sleeper (15) is bruxized, the process proceeds to step S6. In other cases, the series of processes is terminated and the process returns to step S1 again.

  In step S5, a recording part (32) records that the sleeper (15) bruxized with the time. Then, the series of processes is terminated and the process returns to step S1 again.

-Effect of the embodiment-
In the bruxism detection device (20) of the present embodiment, vibration generated from the head (16) of the sleeper (15) is detected by the pressure-sensitive tube (22), and the sleeper (15) is detected from the detected vibration. The presence or absence of bruxism is determined. Since the vibration is transmitted from the head (16) of the sleeper (15) to the pressure-sensitive tube (22) via the pillow (11), noise was generated in the surroundings, unlike the case of detecting sound waves. However, the vibration detection result is not affected. For this reason, even if there is noise around, vibrations generated from the head (16) of the sleeper (15) are detected with high accuracy. And since the bruxism of the sleeper (15) is detected from the vibration detected with high accuracy, the bruxism of the sleeper (15) can be detected with high accuracy.

  Further, the bruxism detection device (20) of the present embodiment determines the presence or absence of bruxism based on the vibration of the head (16) caused by bruxism, not the sound of bruxism of the sleeper (15) itself. . Therefore, according to the present embodiment, it is possible to prevent the occurrence of privacy problems that are a concern when recording sounds around the sleeper (15) including sounds other than bruxism.

  Moreover, although the internal pressure of a pressure sensitive tube (22) changes according to the vibration which generate | occur | produces from a sleeper's (15) head (16), it does not change substantially with ambient noise. For this reason, it can prevent reliably that the accuracy of tooth-gear detection deteriorates by surrounding noise.

  Moreover, the presence or absence of a bruxism of a sleeper (15) is determined based on the power spectrum of the vibration which generate | occur | produces from a sleeper (15) head (16). For this reason, compared with the case where the bruxism is detected based on the frequency of occurrence of vibration, for example, the bruxism of the sleeper (15) can be detected more reliably.

  Moreover, the pressure-sensitive tube (22) of the vibration detector (21) is provided on the pillow (11) that supports the head (16) of the sleeper (15). For this reason, the pressure sensitive tube (22) is near the head (16) of the sleeper (15), and vibration generated from the head (16) of the sleeper (15) is transmitted to the pressure sensitive tube (22). It does not attenuate so much. Therefore, vibration generated from the head (16) of the sleeper (15), and consequently, the bruxism of the sleeper (15) can be detected with higher accuracy.

<< Other Embodiments >>
About the said embodiment, it is good also as the following structures.

  For example, as shown in FIG. 4, the pressure-sensitive tube (22) may be provided under the pillow (11) that supports the head (16) of the sleeper (15), or as shown in FIG. In addition, it may be provided under the body of the sleeper (15). In these cases, the sleeper (15) in the left-right direction so that vibrations generated from the head (16) of the sleeper (15) can be detected even when the sleeper (15) moves left and right due to turning over, etc. It is preferable to provide a pressure sensitive tube (22) so as to extend along.

  Further, for example, the bruxism detection pillow may be configured by integrating the vibration detection unit (21) and the bruxism determination unit (31) integrally with the pillow.

  Further, the bruxism determining unit (31) may not perform the low-pass filter process on the sensor signal from the pressure receiving unit (23).

  In addition, the bruxism detection device (20) may not necessarily be used with the bedding (10), for example, with a cushion, a sofa, or any other device that transmits vibration generated from the head (16) of the sleeper (15). It may be used.

  As described above, the present invention is useful for a bruxism detection device.

11 pillows
20 bruxism detection device
21 Vibration detector
22 Pressure sensitive tube
23 Pressure receiver
24 bruxism judgment part

Claims (6)

A vibration detector (21) for detecting vibrations generated from the head (16) of the sleeper (15);
A bruxism detection device comprising: a bruxism determination unit (31) for determining the presence or absence of bruxism of the sleeper (15) from the vibration. In claim 1,
The vibration detector (21) includes a pressure-sensitive tube (22) whose internal pressure changes according to vibration generated from the head (16) of the sleeper (15), and an internal pressure of the pressure-sensitive tube (22). It has a pressure-receiving part (23) which detects a change, The bruxism detection apparatus characterized by the above-mentioned. In claim 1 or 2,
The bruxism detection unit (31) calculates a power spectrum of the vibration and determines the presence or absence of bruxism of the sleeper (15) based on the calculated power spectrum. In any one of Claims 1-3,
The vibration detection unit (21) is disposed below the head (16) of the sleeper (15). In claim 4,
The vibration detection unit (21) is provided in a pillow (11) that supports the head (16) of the sleeper (15), and is a bruxism detection device. In claim 4,
The vibration detection part (21) is provided under the pillow (11) that supports the head (16) of the sleeper (15).

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