JP2000189389A - Sleeping state monitor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To monitor the sleeping states of patients continuously. SOLUTION: The sleep state monitor device comprises a light source 1 for illuminating a subject M, a photographing means 2 for photographing the subject M, moire fringe generation slits 3a and 3b disposed in front of the light source 1 and photographing means 2, an A/D conversion part 4 for sequentially digitally imaging video signals sent from the photographing means 2, a first image memory 5a for storing digitized image data, a second image memory 5b for holding digitized image data, a storage control part 6 for passing image data kept in the first image memory 5a to the second image memory 5b and storing the first image memory 5a with new digitized image data from the A/D conversion part 4, and an analyzing means 7 for analyzing or comparing images stored in both first and second image memories 5a and 5b.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sleep state monitoring apparatus for monitoring a sleep state by observing minute movements of a subject in a non-contact manner.

[0002]

2. Description of the Related Art In hospitals and nursing homes, it is important to know in real time whether or not a patient has an abnormality. Therefore, at night when the eyes are difficult to see, the nurse or caregiver goes around the patient's room to see if there is any abnormality in the patient and goes to the bedside. Therefore, it is necessary to see how the patient is sleeping. In addition, in the case of a dementia patient, if the patient leaves the bed alone at night, there is a possibility that an injury due to a fall or an accident due to wandering may occur.

[0003] Therefore, at night or the like, the sensor detects whether the patient has an abnormality in the manner of breathing and the like, and whether the dementia patient has not left the bed, and automatically performs centralized monitoring. There is a request to want.

[0004]

By the way, moire fringes have been conventionally used as a device which can accurately observe minute movements in a non-contact manner. For example, JP
As described in Japanese Patent Application Laid-Open No. 6-8036, there is already known a moire fringe photographing apparatus for a lying position which can accurately observe minute movements of a human body lying on a bed due to breathing or the like. However, this is for the purpose of treatment and does not monitor the sleep state of the patient.

[0005] Conventionally, a CCTV camera (a cable television camera for communication communication in a specific building or facility) is installed in a hospital room to monitor a patient. But,
The video from the CCTV camera cannot be watched and monitored all night on a monitoring television, and there is a problem that it is difficult to constantly monitor the video.

In order to reduce the labor required for monitoring, there are also a type in which a load sensor is installed on the bed to detect that the patient is in the bed, and a type in which the movement of the patient is detected by using a CCTV camera and image processing. However, in any case, it is not possible to detect even the fine movement due to the patient's breathing, and there has been a problem that it is not possible to contactlessly monitor the patient's breathing state or sleep state such as turning over.

The present invention has been made in order to solve the above-mentioned problems, and an object thereof is to provide a non-contact method.
Precise monitoring of the patient's bedside tremor, such as breathing and turning, provides real-time information on the patient's sleep status, i.e., whether the patient is in bed, awake or asleep, and whether breathing is normal. An object of the present invention is to provide an excellent sleep state monitoring device that can constantly monitor the sleep state.

[0008]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems, the present invention provides a light source for illuminating a subject, an imaging means for imaging the subject, and a moiré disposed in front of the light source and the imaging means. A slit for generating stripes, an A / D converter for sequentially receiving a video signal from the imaging unit and sequentially converting the image into a digital image, a first image memory for storing digital image data, and a digital image A second image memory for storing data, and a first image memory for transferring image data stored in the first image memory to the second image memory and for digitizing image data of the A / D converter. And an analysis means for comparing and analyzing the image stored in the first image memory and the image stored in the second image memory.

Further, the analyzing means includes a correlation calculating means for sequentially calculating a correlation value between an image stored in the first image memory and an image stored in the second image memory; Sleep state estimating means for estimating the sleep state of the subject.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of a sleep state monitoring apparatus according to the present invention will be described below in detail with reference to FIGS. FIG. 1 is a schematic block diagram illustrating a sleep state monitoring device, FIG. 2 is a schematic explanatory diagram illustrating an image captured by an imaging unit,
FIG. 3 is an explanatory diagram showing a change in moiré fringes, and FIG. 4 is an explanatory diagram showing a method of monitoring a sleep state from a change in a correlation value.

As shown in FIG. 1, the sleep state monitoring device comprises:
A light source 1, a CCTV camera 2 corresponding to an imaging unit, moire fringe generating slits 3a and 3b, and an A / D converter 4
, An image memory 5, a storage control unit 6, and an analysis unit 7. M is a patient corresponding to the subject.

As the light source 1, the moire fringes are noticeable.
A light source close to a point light source is used. In addition, the light source 1 may be one that emits visible light or one that emits ultraviolet light or infrared light, and any light source may be used as long as it can illuminate the subject so that it can be imaged by the CCTV camera 2. In consideration of use during bedtime, it is preferable to use infrared rays.

The CCTV camera 2 captures an image of a patient M who is sleeping on a bed with a futon, and transmits a video signal of the image.
The moire fringe generating slits 3a and 3b are formed by forming chemical fibers such as black nylon at equal intervals of 1 mm to form a parallel lattice. The moire fringe generating slit 3a is disposed in front of the light source 1, and the moiré fringe generating slit 3b is disposed in front of the CCTV camera 2.

The A / D converter 4 sequentially converts the video signal sent from the CCTV camera 2 into a digital image and outputs digital image data. The image memory 5 stores digital image data, and includes a first image memory 5a and a second image memory 5b. The storage control unit 6 stores the first image stored in the first image memory 5a.
The image data for the frame is transferred to the second image memory 5b, and the A / D converter 4 stores the latest digital image data for one frame in the first image memory 5a.

The analyzing means 7 compares and analyzes one frame of image stored in the first image memory 5a and one frame of image stored in the second image memory 5b. In this case, the correlation operation means 7a
And sleep state estimating means 7b.

The correlation operation means 7a includes a first image memory 5
a of one frame of image data stored in
Of one frame stored in the first image memory 5a and one frame stored in the second image memory 5b based on the image data of one frame stored in the image memory 5b. The correlation value with the image for the frame is sequentially calculated. As the correlation calculating means 7a, FA (factory au) is used.
tomation) Use a pattern matching circuit often used for applications. The sleep state estimating means 7b includes a correlation calculating means 7
The correlation value output by “a” is sequentially monitored, and the sleep state of the subject is estimated based on the fluctuation of the correlation value.

The above-mentioned sleep state monitoring device operates as follows. That is, the light source 1 illuminates the subject M through the moire fringe generating slit 3a. CCTV
The camera 2 captures an image of the subject M, which is illuminated by light passing through the slits 3a for generating moiré fringes, through the slits 3b for generating moiré fringes. Therefore, moire fringes indicating the height information of the subject M by contour lines appear in the image captured by the CCTV camera 2.

The video signal of the image in which the moiré fringes appear is sequentially input to the A / D converter 4. A / D converter 4
Converts the video signal into a digital image sequentially, creates one frame of image data, and notifies the storage control unit 6 that the image data has been created. Then, the storage control unit 6 transfers the image data of one frame stored in the first image memory 5a to the second image memory 5b,
Image data of the digital image of the first
a, and notifies the analyzing means 7 that the transfer of the image data and the storage of the new image data have been completed.

The correlation calculating means 7a of the analyzing means 7 calculates one frame of image data stored in the first image memory 5a and one frame of image data stored in the second image memory 5b. Based on the first image memory 5
The correlation value ρ _n between the image for one frame stored in “a” and the image for one frame stored in the second image memory 5b is calculated and output to the sleep state estimating means 7b.
This sleep state monitoring device repeatedly performs the operation as described above.

The sleeping state estimation means 7b, while including a new correlation value [rho _n coming is sequentially calculated, the correlation value of the so far [rho _n,
Based on the change in ρ _n−1, ρ _n−2 . For example, the sleep state estimating means 7b determines that the correlation values ρ _n, ρ _n−1, ρ _n−2, ... Have a substantially constant amplitude and a period when a normal human breathes during sleep. If they are approximately equal, it is determined that the patient is in bed and is breathing normally.

The operation of the above-mentioned analyzing means 7 will be described with reference to FIGS.
Will be described visually using. FIG. 2 shows an image of a patient M who is sleeping on a bed B with a futon C on it, using a CCTV camera 2.

When the patient M breathes, inhales and inflates the chest and abdomen, the futon C is lifted by that amount, and FIG.
As shown in FIG. 3B, the moire fringes H having six layers change into seven-fold enlarged moire fringes H as shown in FIG. Thereafter, when the patient M exhales and narrows his chest and abdomen, the futon C sinks by that much, and the seven-fold moiré fringe H as shown in FIG. 3 (b) becomes as shown in FIG. 3 (a). Return to the sixfold moire fringe H again.

As described above, the moire fringes H change in fringe interval, the number of fringes, and the shape of the fringes according to the slight movement due to the respiration of the patient M or the like. Since the change in the moire fringe H due to breathing is very small, the correlation value is generally high.
At the moment when the breath is completely exhaled or when the breath is completely exhaled, the movement stops for a moment, so that there is almost no change in the moire fringe H, and the correlation value ρ shows the maximum value. Conversely, when breathing or exhaling, the Moire fringe H slightly changes, and the correlation value ρ
Decreases relatively. Further, when the patient M moves largely due to turning over or the like, the pattern of the moiré fringes H is largely displaced, and the correlation value becomes very low.

Therefore, the sleep state estimating means 7b receives the correlation values ρ _n, ρ _n-1, ρ _n-2,
.. Are graphed as shown in FIG. 4, for example, analysis is performed as follows. That is, the sleep state estimating means 7b keeps a relatively high correlation value from time t _{0 to} t ₁ , and the correlation value changes periodically, and its cycle is equal to the normal case. It is determined that the patient M is in the bed and is breathing in a healthy state. Incidentally, respiratory cycle may be determined as a 2 cycle T at time t ₀ ~t _1. At this time, if the respiratory cycle of the patient M is shorter than usual, the patient M
Is determined to be changing.

The sleep state estimating means 7b operates at time t _1.
There is a short period toward ~t ₂ but have correlation value becomes very low, as in the case of the time t ₂ later subjected to a time t ₀ ~t ₁ again, while maintaining a relatively high correlation value, yet the correlation values thereof its period is changing periodically is also equal to the normal case, therefore, the patient M to a time t ₁ ~t ₂ hit the turn, it is determined that doing breathing again healthy. If a large decrease in the correlation value frequently occurs, it is determined that the patient M is awake and moving.

[0026]

According to the first aspect of the present invention, whether the patient is present or absent, whether the patient is awake or sleeping,
An effect of being able to provide an excellent sleep state monitoring device that can monitor the sleep state of the patient, such as whether the patient's breathing is normal or abnormal, in a non-contact manner.

According to the second aspect of the present invention, while determining the correlation value of the digital image sequentially converted into a digital image, based on the change in the correlation value, whether the patient is present or not, and whether the patient is awake Since the sleep state of the patient, such as sleeping or whether the patient's breathing is normal or abnormal, is monitored, it is possible to provide an excellent sleep state monitoring device that can relatively easily and accurately monitor the sleep state of the patient. Play.

[Brief description of the drawings]

FIG. 1 is a schematic block diagram showing a sleep state monitoring device according to an embodiment of the present invention.

FIG. 2 is a schematic explanatory view showing a video imaged by an imaging means of the sleep state monitoring device.

FIG. 3 is an explanatory diagram showing changes in moiré fringes.

FIG. 4 is an explanatory diagram showing a method of monitoring a sleep state from a change in a correlation value.

[Explanation of symbols]

 Reference Signs List 1 light source 2 imaging means 3a slit for generating moiré fringes 3b slit for generating moiré fringes 4 A / D converter 5a first image memory 5b second image memory 6 storage controller 7 analyzer 7a correlation calculator 7b sleep state estimation Means M Subject

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) H04N 7/18 G06F 15/62 380 F Term (Reference) 4C038 KL07 VA04 VA15 VB32 VC04 5B057 AA07 AA19 BA29 CA13 CC03 CH01 CH11 DA08 DC05 DC34 5C054 AA01 CA04 CC02 CH01 EA01 FC13 HA12 5C087 BB03 DD03 DD29 DD30 EE18 FF01 FF04 FF30 GG02 GG03 GG08 GG18 GG19 GG24 GG30

Claims (2)

[Claims] 1. A light source for illuminating a subject, an imaging unit for imaging the subject, a moire fringe generating slit disposed in front of the light source and the imaging unit, and sequentially receiving a video signal from the imaging unit. A / D conversion unit for converting digital image, first image memory for storing digital image data, second image memory for storing digital image data, and first image memory A storage control unit that transfers the image data stored in the image data to the second image memory and stores the digitalized image data of the A / D conversion unit in the first image memory; and the first image memory stores the image data. Analysis means for comparing and analyzing the image and the image stored in the second image memory. 2. The image processing apparatus according to claim 1, wherein the analyzing unit sequentially calculates a correlation value between an image stored in the first image memory and an image stored in the second image memory; 2. A sleep state estimating means for estimating a sleep state of a subject.
The sleep state monitoring device as described in the above.