JP4821395B2 - Sleep determination device - Google Patents

Description

    The present invention relates to a sleep determination apparatus, and particularly relates to determination of an awake state of a sleeping person.

2. Description of the Related Art Conventionally, a sleep determination device that determines a sleep state of a sleeper based on an output signal obtained by detecting the body motion of the sleeper is known. For example, in Patent Literature 1, a sleep determination device that determines that a person has fallen asleep is detected if an output signal obtained by detecting the body movement of a sleeping person continuously transitions between a first threshold value and a second threshold value for a predetermined time. It is disclosed.
Japanese Patent No. 2817358

    By the way, it is important to determine the sleep state after the sleep in addition to the sleep of the sleeper for the purpose of the health management of the sleeper.

    For example, as the determination method, in the sleep determination device of Patent Document 1 described above, if the body motion signal continues for a predetermined time between the first threshold value and the second threshold value as in the sleep determination, the body motion signal is It may be considered that the sleep state is determined to be below the second threshold for a predetermined time.

    However, the above-described method has a problem that it is easily influenced by noise in the bedroom such as opening and closing of a door, and erroneous determination is easily performed. That is, when affected by noise, the output body motion signal is temporarily higher than the actual body motion signal by the sleeping person, and may exceed the second threshold or the determination threshold. Then, the condition that the body motion signal continues to fall below the predetermined determination threshold is difficult to be satisfied, and it is erroneously determined that the body motion signal is not a sleep state (that is, an awake state) although it is actually a sleep state. . Accordingly, there is a problem that the determination accuracy of the sleep state is lowered.

    The present invention has been made in view of such a point, and the object of the present invention is to increase the sleep state (whether it is an awake state or a sleep state) of a sleeping person without being affected by noise. It is to detect with accuracy.

According to a first aspect of the present invention, a detection means (20) for detecting a body movement of a sleeping person and outputting a body movement signal and a body movement signal of the detection means (20) continuously exceed a determination threshold for a predetermined time or more The sleep determination device includes determination means (53) for determining that the sleeping person is in an awake state . And in the sleep determination device of the present invention, the determination threshold is a value larger than the signal level obtained by relaxing the change in the minimum value of the body motion signal at predetermined intervals of the detection means (20) by a predetermined function, Update means (60) for changing and updating the determination threshold according to the signal level is provided. The “body motion signal” includes a signal (original signal) detected by the detection means (20) and a signal obtained by modulating the detection signal to a predetermined signal level or a predetermined frequency band (preprocessing the original signal). Signal).

    In the above invention, when the body motion signal accompanying the body motion of the sleeping person output by the detection means (20) exceeds a predetermined determination threshold continuously for a predetermined time or more, it is determined that the sleeping person is in an awake state. (Hereinafter referred to as the determination method of the present invention). Therefore, for example, when the body motion signal continuously falls below the determination threshold for a predetermined time or more, the influence of noise or the like is compared with a case where it is determined that the sleeper is in a sleep state (herein referred to as a conventional determination method). Thus, the awakening state of the sleeping person is surely determined.

    That is, in the case of the conventional determination method, the time zone in which it is not determined that the patient is in the sleep state is the awake state. Here, for example, when affected by noise or the like, the body motion signal may temporarily be higher than the actual one and exceed the determination threshold. If it does so, in the conventional determination method, if it receives to the influence of noise, it will become difficult to satisfy | fill the condition that a body motion signal is continuously less than a determination threshold value. Therefore, although it is actually a sleep state, it is not determined that it is a sleep state, and it is assumed that it is an awake state. However, in the determination method of the present invention, even if the body motion signal temporarily exceeds the determination threshold value due to noise or the like in a sleep state, as long as the body motion signal does not continuously exceed the determination threshold value (a predetermined time or more), awakening It is not determined as a state. That is, although it is actually a sleep state, it is not erroneously determined to be an awake state.

In addition, body motion signals associated with sleepers' body motion are roughly divided into fine motion signals derived from breathing and heartbeat, and coarse motion signals derived from bed movement, getting out of bed, turning over, and other sleeper body movements. Is done. Therefore, in determining the sleeping state of a sleeping person, it is necessary to obtain the boundary level between the fine motion signal and the coarse motion signal as a body motion determination threshold value. In FIG. 5, a signal component having a relatively low signal level is a fine motion signal, and a signal component protruding in a spike shape from these fine motion signals is a coarse motion signal. That is, the body motion signal is represented as a signal waveform in which the fine motion signal and the coarse motion signal are superimposed. Here, in the state where the sleeping person is in bed, the fine movement signal accompanying breathing and heartbeat is reliably detected by the detection means (20), so the minimum value of the body movement signal is the fine movement signal and the coarse movement signal. The value is equivalent to the boundary level.

In the above invention, when the minimum value of the body motion signal changes, the update means (60) relaxes the change of the minimum value by using a predetermined function such as an exponential function. Then, the updating means (60) changes and updates the determination threshold value, which is a value larger than the signal level thus relaxed, according to the signal level. That is, the updating means (60) updates the determination threshold that is larger than the body movement determination threshold by updating the relaxed signal level as the body movement determination threshold. For this reason, even when the minimum value of the body motion signal changes abruptly, the determination threshold value is appropriately updated at a change rate smaller than the change rate of the minimum value. Therefore, when an abnormality is detected due to noise or the like when the determination threshold is updated, or when a sudden change in body motion signal occurs due to the coarse movement of a sleeper, these sudden changes in noise or body motion signal are determined. It can be suppressed that the determination threshold value becomes an abnormal value because it is reflected in the threshold value.

    According to a second invention, in the first invention, the predetermined time is 3 minutes.

    In the above invention, when the body motion signal continuously exceeds the determination threshold for 3 minutes or more, it is determined that the sleeper is in the awake state. Thus, the awakening state is further discriminated by setting the sleep rhythm change time that is considered to be most appropriate in terms of sleep science as the predetermined time.

According to a third invention, in the first or second invention, when the minimum value of the body motion signal decreases, the updating means (60) relaxes the change in the minimum value by the first time constant. When the minimum value of the body motion signal increases while changing the determination threshold according to the signal level , the signal level obtained by relaxing the increase change of the minimum value with a second time constant larger than the first time constant The determination threshold value is changed and updated according to the above .

In the above-described invention, the time constant of the function for relaxing the change in the minimum value is set differently when the minimum value of the body motion signal is decreasing and when the minimum value is increasing. Specifically, for example, as shown in FIG. 6, when the minimum value of the body motion signal decreases, the change in the minimum value is alleviated by a relatively small function of the first time constant. Therefore, the body motion determination threshold value is decreased and updated relatively quickly following the change in the minimum value. On the other hand, when the minimum value of the body motion signal increases and changes, the change in the minimum value is reduced by a function of the second time constant larger than the first time constant. Therefore, the body motion determination threshold is not affected by the increase change of the minimum value, and is updated relatively slowly. In other words, updating means (60), while updating the determination threshold with a relatively quick response for decreasing the minimum change value, updates the determination threshold with a relatively slow response for increasing the change in the minimum value To do.

    By the way, as a factor that the body motion signal in the state of convergence near the body motion determination threshold decreases and changes, for example, the sleeping phase of a sleeping person who is in a supine or prone state changes to a lying state, and microtremor associated with breathing and heartbeat. It is assumed that the signal decreases. On the other hand, the cause of the increase in the body motion signal in the state of convergence near the body motion determination threshold is that the coarse motion signal increases as the sleeping person enters the bed, gets out of bed, turns over, etc. Contrary to the change in the sleep phase, it is assumed that the sleep phase of the bedridden who has been lying down changes to the supine or prone state, and the tremor signal accompanying breathing and heartbeat increases.

Here, in the case where the body motion signal changes increases, it is necessary to determine the body movement determination threshold value to reflect only the fine movement signal, but difficult to determine and the fine movement signal and coarse signal It is. By the way, in general, it is rare that the coarse movement of the sleeper as described above continues continuously, whereas the fine movement of the sleeper continues continuously until the sleep phase changes. In the present invention, in consideration of the above phenomenon, the influence of the coarse motion signal on the determination threshold is suppressed by devising the responsiveness when the determination threshold is updated.

That is, according to the present invention, when the body motion signal increases and changes, the responsiveness to the minimum value change is delayed and the determination threshold is updated. Therefore, it is possible to prevent the determination threshold value from greatly increasing with the sleeper's coarse movement. On the other hand, when the change in the minimum value of the body motion signal is changed, the reduction change in the fine motion signal accompanying the change in the sleep phase can be quickly reflected in the determination threshold .

    Therefore, according to the present invention or the second invention, when the body motion signal accompanying the body motion of the sleeping person exceeds the determination threshold continuously for a predetermined time, it is determined that the patient is in the awake state. Therefore, when the body motion signal falls below the determination threshold for a predetermined time continuously, it is possible to detect the sleep state of the sleeping person with high accuracy without being affected by noise so much as compared with the case where the sleep state is determined.

Further, according to the present invention, when the minimum value of the body motion signal changes, the determination threshold value that is a value larger than the signal level in which the change of the body motion signal is relaxed is set according to the signal level. Change and update. For this reason, even when a body movement signal fluctuates rapidly due to noise or coarse movement of a sleeping person, it is possible to prevent these sudden fluctuations from being reflected in the determination threshold . Therefore, it is possible to provide a sleep determination device which is not affected by such single layer noise.

Further, according to the third aspect of the invention, the response to the change in the minimum value is delayed at the time of the increase change than at the decrease change of the minimum value of the body motion signal. In this way, sleeping person in-bed, lifting, in a case where such the accompanying body motion signal rolling over is rapidly increasing change from the body movement determination threshold near the signal level, the determination threshold rises sharply, and abnormal It can suppress becoming. On the other hand, when the body motion signal decreases and changes from the signal level in the vicinity of the body motion determination threshold due to a change in the sleep phase of the sleeping person, the change in the sleep phase can be reliably reflected in the determination threshold . Therefore, sleep determination with higher accuracy can be performed.

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

    The sleep determination device (10) of the present embodiment performs health management of a sleeping person by monitoring the sleeping state of the sleeping person. The sleep determination device (10) includes a sleep sensor (20) and a circuit unit (30).

    The sleep sensor (20) constitutes detection means for detecting the body movement of the sleeping person and outputting a body movement signal. The sleep sensor (20) includes a pressure sensing part (21) and a pressure receiving part (22).

    As shown in FIG. 1 and FIG. 2, the pressure-sensitive part (21) of this embodiment is laid on a mattress laid on a bed of a bedding such as a bed. This pressure-sensitive part (21) is comprised by the elongate and hollow tube, and the space is formed in the inner side. When the sleeping person lies on the bed, pressure / vibration is transmitted to the pressure sensing part (21) along with the body movement of the sleeping person, and the internal pressure of the pressure sensing part (21) acts on the pressure receiving part (22).

    The pressure receiving part (22) includes a casing (23) and a sensor part (24) accommodated in the casing (23). A sensor part (24) is comprised by a microphone, a pressure sensor, etc. This sensor part (24) receives the internal pressure which acted from the pressure sensitive part (21), and outputs this internal pressure as a detection signal (body motion signal) to the circuit unit (30) via the lead wire (25). In the present embodiment, a minute leak groove (26) is formed at the connection position between the pressure sensitive part (21) and the pressure receiving part (22). For this reason, for example, when a sleeping person gives a strong impact to the bed, a sudden rise in internal pressure acts on the sensor unit (24), resulting in a failure of the sensor unit (24) or saturation of the detection signal. Suppressing the situation.

    As shown in FIG. 3, the circuit unit (30) includes a processing means (40), an updating means (60), an upper limit calculating means (51), a lower limit setting means (52), and a sleep determining means (53). .

    The processing means (40) modulates the detection signal output from the sleep sensor (20) into a signal of a predetermined level and a predetermined frequency band. Specifically, the processing means (40) includes a first smoothing unit (41), a band pass filter unit (42), an envelope detection unit (43), a low pass filter unit (44), and a second smoothing unit (45 ). The details of the processing means (40) will be described in the sleep determination operation described later.

    The updating means (60) determines and updates a body motion determination threshold value that is a boundary level between the coarse motion signal and the fine motion signal, based on the body motion signal modulated by the processing means (40). The update means (60) includes a calculation unit (61) and an update unit (62).

    The calculating part (61) of Embodiment 1 calculates the minimum value for every predetermined interval sequentially about the body motion signal after processing by the processing means (40). The minimum value calculation interval can be set arbitrarily, but is set to about 10 seconds in the present embodiment.

    On the other hand, the update unit (62) updates the body movement determination threshold based on the minimum value obtained by the calculation unit (61). That is, as shown in FIG. 5, the update unit (62) traces the minimum value obtained by the calculation unit (61) and updates the body motion determination threshold value of the coarse motion signal and the fine motion signal as needed. . Therefore, the body motion determination threshold value of the present embodiment is a variation value that is appropriately changed according to the variation of the minimum value of the body motion signal. Thereafter, the updating unit (62) multiplies the body movement determination threshold value by a predetermined magnification or adds a certain offset, and sets the obtained value as the sleep determination value. Therefore, this sleep determination value is also a variation value that is changed according to the variation of the body movement determination threshold. In the present embodiment, the sleep determination value is twice the body movement determination threshold.

    The upper limit calculating means (51) calculates an upper limit signal level that the sleeping person clearly considers to cause coarse movement. As shown in FIG. 6, the upper limit signal level is larger than the body motion determination threshold value updated by the updating means (60), and is multiplied by a predetermined magnification. Therefore, the upper limit signal level is a fluctuation value that varies with the update of the body movement determination threshold. In the present embodiment, the predetermined magnification is set to 4 times. The upper limit signal level may be a fixed eigenvalue that can be arbitrarily changed.

    In the lower limit setting means (52), a lower limit signal level (bed threshold) that the sleeper clearly considers to be out of bed is set. This lower limit signal level is a fixed value smaller than the body movement determination threshold. In addition, the lower limit signal level can be changed as appropriate after being calibrated based on the detection signal output from the sleep sensor (20) in the bed where the sleeping person is in a bed leaving state and standing still. Yes. In the present embodiment, the lower limit signal level is determined by calibration for about 3 minutes. Further, the lower limit signal level may be a fluctuation value that is appropriately calculated based on the body movement determination threshold, like the upper limit signal level described above.

    The sleep determination means (53) compares the body motion signal output from the processing means (40) with the sleep determination value updated by the update means (60) described above to determine the sleep state of the sleeping person. It is. That is, the sleep determination value is a determination threshold value for determining the sleep state of the sleeping person. Specifically, the sleep determination means (53) determines that the sleeper is in an awake state when the body motion signal output from the processing means (40) exceeds the sleep determination value for a set time or longer. . The set time can be arbitrarily changed, but is set to 3 minutes in the present embodiment.

-Sleep judgment operation-
Next, the sleep determination operation of the sleep determination device (10) of the present embodiment will be described with reference to FIGS.

    When the sleep determination device (10) is in an ON state, a detection signal is output from the sleep sensor (20) to the circuit unit (30) with the body movement of the sleeper. This detection signal is input to the processing means (40) at about 6400 [sample / sec].

    When the detection signal is input to the processing means (40), in step S1, the first smoothing unit (41) integrates and averages the signal to 100 [sample / sec]. Next, in step S2, the band pass filter unit (42) filters the signal in a band (7.5 ± 2.5 Hz) corresponding to the natural vibration band of the human body. Thereafter, in step S3, the envelope detector (43) rectifies the signal (converts it to an absolute value), performs peak hold for a predetermined time, and performs so-called envelope detection processing. Next, in step S4, the low-pass filter unit (44) extracts a signal in a relatively low frequency vibration band (0.5 Hz).

    Subsequently, in step S5, the second smoothing unit (45) adds and averages the body motion signals extracted by the low-pass filter unit (44) at intervals of about 10 seconds. As a result, instantaneous fluctuations in the body motion signal are alleviated. Here, the interval of the averaging process by the second smoothing unit (45) is the period of the fine movement signal (from about 3 seconds) in order to reflect the fine movement signal of the sleeping person (especially a signal derived from the sleeping person's breathing). An interval greater than 5 seconds) is preferred. On the other hand, the interval of the averaging process is set so that the sleeper's convulsion cycle (generally, from 20 seconds to suppress fluctuations in body motion signals caused by involuntary limb spasms during sleep of the sleeper. An interval smaller than 30 seconds) is preferred.

    The body motion signal modulated by the processing means (40) as described above is input to the update means (60), and in step S6, the body motion signal and the lower limit signal level (set in the lower limit setting means (52) are set. Comparison with the threshold of staying). If the body motion signal is equal to or higher than the lower limit signal level, the sleeper is considered to be in the bed and the process proceeds to step S7. On the other hand, when the body motion signal is smaller than the lower limit signal level, the sleeper is regarded as being out of bed, and the process proceeds to step S11.

    In step S7, the body motion signal is compared with the upper limit signal level determined by the upper limit calculating means (51). If the body motion signal is greater than the upper limit signal level, the sleeper is clearly regarded as causing coarse motion, and the process proceeds to step S11. On the other hand, when the body motion signal is equal to or lower than the upper limit signal level, the process proceeds to step S8.

    In step S8, the calculation unit (61) calculates a minimum value from the body motion signal. Here, this minimum value is calculated every 10 seconds, like the averaging process interval by the second smoothing unit (45). Next, the updating unit (62) appropriately updates the body motion determination threshold value by tracing the minimum value calculated as described above. Here, the update unit (62) updates the signal level obtained by relaxing the change in the minimum value of the actual body motion signal with an exponential function as the body motion determination threshold value. Also, the time constant used in this exponential function is a different time constant between when the minimum value increases and when it decreases. Specifically, for example, when the minimum value at a predetermined time is Min and the minimum value increases and changes to Xi in the subsequent update interval to (when Xi> Min), in this embodiment, the time constant τ1 is set to 30 [ As a min], a new minimum value Min ′ is updated by the following formula.

Min ′ = Min × α + Xi (1−α)
Here, α = exp (−to / τ1) and τ1 = 30 [min].

    On the other hand, when the minimum value at the predetermined time is Min and the minimum value decreases and changes to Xi in the subsequent update interval to (when Xi <Min), in this embodiment, the time constant τ2 is set to 1.0 [min]. As a result, the new minimum value Min ′ is updated by the following equation.

Min ′ = Min × β + Xi (1−β)
Here, β = exp (−to / τ2) and τ2 = 1.0 [min].

    The updating unit (62) updates the signal level relaxed by the exponential function as the body movement determination threshold (step S9). For this reason, even when the minimum value of the body motion signal changes abruptly, the body motion determination threshold value is appropriately updated at a change rate smaller than the change rate of the minimum value. In addition, the time constant of the exponential function is a value that is larger at the time of increase change than at the time of change decrease of the minimum value. For this reason, for example, as shown in FIG. 6, the body movement determination threshold is updated with a relatively fast response to a decrease in the minimum value, while a relatively slow response to an increase in the minimum value. The body motion determination threshold is updated. In addition to the exponential function (1-hour delay step function), for example, a 2-hour delay step function or other functions may be used as the function for relaxing the change in the minimum value of the body motion signal. .

    Next, in step S10, the updating unit (62) appropriately updates a value obtained by doubling the body movement determination threshold obtained as described above as a sleep determination value. Thereafter, in step S11, the sleep determination means (53) compares the sleep determination value updated by the update means (60) with the body motion signal obtained by the processing means (40). And when a body motion signal is continuously larger than a sleep determination value for 3 minutes or more, it is considered that the continuous coarse motion has arisen from the sleeper, and it is determined that the sleeper is awake.

    Specifically, the determination method of the sleep determination means (53) will be described with reference to FIG. In this figure, each body motion signal shows an average value for one minute and is plotted at one minute intervals. In this figure, it is determined that “Awakening Section A” and “Awakening Section B” are in the awake state. That is, in the “awakening section A”, since the three body motion signals exceed the sleep determination value, the body motion signal continuously exceeds the sleep determination value for 3 minutes. Further, in the “wakeful section B”, since the four body motion signals exceed the sleep determination value, the body motion signal continuously exceeds the sleep determination value for 4 minutes.

    And a sleep determination means (53) detects awakening time for the body motion signal except the first and last body motion signals in the awakening section. That is, the first and last minutes are excluded from the time when the state is awake. For example, in “Awakening section A” in FIG. 7, the second body motion signal (black circle in the figure) of the three body motion signals is a target for detection of awakening time, and the waking time is 1 minute (3 minutes−2 Min). In “Awakening section B”, the second and third body movement signals (black circles in the figure) of the four body movement signals are the targets for detection of the awakening time, and the awakening time is 2 minutes (4 minutes-2 minutes). It becomes. Thus, in the wakefulness section determined to be in the wakefulness state, the body motion signal line as a whole has a mountain shape, so the body motion signals at both ends thereof are closer to the sleep determination value. By detecting the awakening time by removing the body motion signals at both ends as described above, a more reliable awakening state can be determined.

    Next, the method of detecting the awakening time during sleep by determining the awakening state (B method) as in the present invention is more than the method of detecting the awakening time during sleep by detecting the sleeping state (A method). FIG. 8 shows a test result indicating that the accuracy is high. Here, said A system determines that it is a sleep state when the body motion signal input from the said processing means (40) to the update means (60) becomes continuously below the sleep determination value for 3 minutes or more, This is a method in which the time that is not determined to be a sleep state is the awakening time.

    In FIG. 8, “total awakening time” is the total sum of the awakening times detected during a predetermined test time. In this test, the degree of coincidence with the awakening time of each method was verified using the awakening time detected by a restraint type sensor different from the sleep determination device (10) of the present embodiment as a reference value. That is, the “coincidence time” in FIG. 8 is the time when the time zone determined to be awake in the “total awake time” in each method matches the time zone determined to be awake by the restraint type sensor. . The restraint-type sensor used is worn on the wrist of a sleeping person and makes a sleep / wake determination, and the determination result is 90% or higher with respect to the polysomnogram, which is an international standard.

    As shown in FIG. 8, first, the “total awakening time” of the A method is longer than that detected by the constraining sensor, and it is understood that the state is excessively determined to be awakening. Then, it can be seen that the “coincidence rate” of the awakening time with the constraint type sensor is higher in the B method of the present invention than in the A method. Therefore, it can be seen that in the B method of the present invention, the “total awakening time” is less than that detected by the restraint type sensor, but the awakening state is more reliably determined than in the A method.

    Thus, in the case of the A method, in order to focus on the fact that the body motion signal is continuously below the determination threshold, for example, when the level of the body motion signal temporarily increases due to the influence of noise and exceeds the determination threshold, The condition that it is continuously below the determination threshold is easily broken. As a result, although it is actually a sleeping state, it is not determined to be a sleeping state, and the frequency of misidentifying it as an arousal state increases. However, in the case of the B method of the present invention, attention is paid to the fact that the body motion signal continuously exceeds the determination threshold value. Therefore, even if the level of the body motion signal temporarily exceeds the determination threshold value due to the noise, it continues. The condition that the determination threshold is exceeded is not significantly affected. Therefore, even if it is a sleep determination system (non-restraint system) which does not attach sensors directly to a sleeping person, the awakening state of a sleeping person can be detected with high accuracy without being affected by noise so much.

-Effect of the embodiment-
As described above, according to the present embodiment, when the body motion signal accompanying the body motion of the sleeping person exceeds the determination threshold (sleep determination value) for a predetermined time continuously, it is determined that the patient is in the awake state. Yes. Therefore, when the body motion signal falls below the determination threshold for a predetermined time continuously, it is possible to detect the sleep state of the sleeping person with high accuracy without being affected by noise so much as compared with the case where the sleep state is determined.

    In addition, in the section where the body motion signal exceeds the determination threshold continuously for a predetermined time, the awakening time is extracted for the body motion signal excluding the first and last body motion signals, so the influence of noise etc. In response, the body motion signal that temporarily exceeds the determination threshold can be removed. Thereby, since it is not received to the influence of noise further, a more accurate sleep determination apparatus can be provided.

    In addition, the body motion determination threshold is appropriately updated by tracing the minimum value of the body motion signal at predetermined intervals. For this reason, for example, even when the body motion signal changes according to the sleeping phase and weight of the sleeping person and the type and state of the bedding, the body motion determination threshold can be changed as needed by reflecting these effects. Therefore, the awakening state of the sleeping person can be determined regardless of the influence of the sleeping phase and weight of the sleeping person or the type and state of the bedding, and the determination accuracy can be improved.

    Here, when the body motion determination threshold is updated based on the minimum value of the body motion signal, a significant variation in the body motion determination threshold is suppressed using an exponential function. For this reason, even when a body motion signal fluctuates abruptly due to noise or coarse movement of a bedridden person, it is possible to prevent these sudden body motion signal fluctuations from being reflected in the body motion determination threshold. Therefore, the body motion determination threshold value can be brought close to the boundary level between the actual fine motion signal and the coarse motion signal, and the arousal determination accuracy can be increased.

    In addition, the time constant of the exponential function is a value that is larger at the time of increase change than at the time of change decrease of the minimum value. In other words, the responsiveness to the minimum value change is delayed when the body movement signal is increasing more than when the minimum value is decreasing. In this way, when the body motion signal suddenly increases and changes from the signal level in the vicinity of the body motion determination threshold as the sleeping person enters the bed, leaves the bed, turns over, etc., the body motion determination threshold increases rapidly, and the abnormal value Can be suppressed. On the other hand, when the body motion signal decreases and changes due to a change in the sleeping phase of the sleeping person, the change in the sleeping phase can be reliably reflected in the body motion determination threshold. Therefore, it is possible to effectively improve the determination accuracy of the arousal state.

    The signal level obtained by quadrupling the body motion determination threshold updated by the updating means (60) is appropriately calculated as the upper limit signal level, and only the body motion signal below the upper signal level is newly updated. It is made to reflect in. For this reason, it is possible to reliably suppress that the body motion signal is reflected in the body motion determination threshold value and the body motion determination threshold value becomes an abnormal value when the bedridden person is causing coarse motion.

    In addition, only the body motion signal equal to or higher than the lower limit signal level set in the lower limit setting means (52) is reflected in the body motion determination threshold value. For this reason, when the sleeping person is getting out of bed, it is possible to reliably prevent the body motion signal from being reflected in the body motion determination threshold value and causing the body motion determination threshold value to become an abnormal value.

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

For example, sleep determination value is set to 2 times the body movement determination threshold may be other ratio of 3 or 4 times and the like.

    Moreover, in the said embodiment, the elongate tubular pressure-sensitive part (21) is applied to the sleep sensor (20). However, the pressure-sensitive portion (21) can be constituted by, for example, a curved one tube, a plurality of tubes connected, or a mat-like one.

Moreover, although the sleep determination apparatus (10) mentioned above is used for a sleeper's health management, for example, this sleep determination apparatus is used for the sleep capsule etc. which perform air conditioning by following a sleep state of a sleeper. It can also be applied.

In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

    As described above, the present invention is useful as a sleep determination device that determines a sleep state of a sleeper based on a body motion signal associated with the sleeper's body motion.

It is a perspective view which shows the whole structure of the sleep determination apparatus which concerns on embodiment. It is sectional drawing which shows the structure of the sleep sensor which concerns on embodiment. It is a block diagram which shows the structure of the circuit unit which concerns on embodiment. It is a flowchart which shows sleep determination operation | movement. It is a graph for demonstrating the update operation | movement of a body movement determination threshold value. It is a graph for demonstrating the update operation | movement of a body movement determination threshold value. It is a graph for demonstrating determination of an arousal state and an arousal time. It is a table | surface which shows the test result of sleep determination.

10 Sleep determination device
20 Sleep sensor (detection means)
53 Sleep determination means (determination means)
60 Update means

Claims (3)

Detection means (20) for detecting the body movement of the sleeping person and outputting a body movement signal;
When the body motion signal of the detection means (20) exceeds a determination threshold continuously for a predetermined time or more, the sleep determination apparatus includes a determination means (53) that determines that a sleeper is in an awake state ,
The determination threshold is a value larger than a signal level obtained by relaxing a change in the minimum value of the body motion signal at predetermined intervals of the detection means (20) by a predetermined function,
A sleep determination device comprising update means (60) for changing and updating the determination threshold value according to the signal level . In claim 1,
The sleep determination apparatus, wherein the predetermined time is 3 minutes. In claim 1 or 2 ,
When the minimum value of the body movement signal decreases, the update means (60) changes and updates the determination threshold according to the signal level obtained by relaxing the decrease in the minimum value with the first time constant, When the minimum value of the body movement signal increases, the determination threshold is changed and updated according to the signal level obtained by relaxing the increase change of the minimum value with a second time constant larger than the first time constant . Sleep determination device.

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