JP2618630B2 - Alarm clock - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic timepiece, and more particularly, to an alarm clock capable of detecting a human sleep rhythm and sounding an alarm in accordance with the human sleep rhythm.

[Summary of the Invention]

The present invention, in an alarm clock, measuring the heartbeat from the electrode in contact with the human body while sleeping, by detecting the interval time between heartbeats, it is possible to detect the rhythm of sleep, particularly REM sleep period, during this REM sleep period By sounding the alarm for waking up, the player can be awakened exhilaratingly.

[Conventional technology]

Conventionally, the alarm clock is controlled only by the time, and the alarm clock that matches the sleep rhythm of the living body is RE
The problem is the detection of M sleep, and there have been detection methods using brain waves as in JP-A-53-77676 and detection methods based on eye movements as in JP-A-56-13955.

[Problems to be solved by the invention]

The alarm clock controlled only by the time ignores the rhythm of sleep in the living body, so if an alarm sounds and wakes up during sleep, it must be awakened with great discomfort. Also, when detecting the rhythm of sleep (REM sleep), when measuring brain waves, the measuring equipment becomes complicated and large, and when detecting eyeball movement, a sensor is attached to the face, so when you sleep, However, it was expected to be very uncomfortable and had a problem that it was not practical in ordinary households.

[Action]

With the above-described configuration, the average value data of the heartbeat pulse interval time is calculated based on the heartbeat pulse obtained from the electrode via the amplifier circuit, and the time at each time when the average value data greatly changes within a certain time period The REM sleep period can be detected by checking two points of the interval and the change value when the average value data largely changes within a certain time.

[Object of the invention]

SUMMARY OF THE INVENTION It is an object of the present invention to provide an alarm clock capable of easily attaching a sensor and detecting REM sleep by measuring a heartbeat and outputting an alarm during the REM sleep period.

[Means for solving the problem]

In order to solve the above-mentioned problem, in the present invention, when the sleeping state is divided into REM sleep and NONREM sleep, attention is paid to the large fluctuation of the heart rate among the changes of various phenomena appearing on the body in each sleep state. In order to capture changes in heart rate, a total of three electrodes, such as the chest or arm and two electrodes sandwiching the heart and a ground electrode, are attached to the body using a chest band or wrist band. CPU (Centr
al Processing Unit), ROM (Read Only Memory), RAM
(Random Access Memory), a REM sleep determination means is provided which is capable of detecting data in a REM sleep state by software analysis using a counter.

〔Example〕

Sleep rhythms can be broadly divided into REM sleep and NONREM sleep.The former is more awake and the latter is a deeper sleep state. Are known. During REM sleep, several phenomena characteristic of the body appear, and medically, some phenomena are measured to determine REM sleep. The typical phenomena are listed as follows: ・ Rapid eye movements ・ EEG becomes more noticeable from θ wave to α wave ・ Electromyogram becomes stable ・ Skin potential level at thermal sweating site decreases ・ Body There are known phenomena such as increased pulsation, faster pulse, erection of penis in men, and enormous clitoris in women.

In the present invention, attention is paid to a change in the pulse among the above phenomena, a cardiac potential is measured from an electrode worn on the body, and a heartbeat interval is stored and analyzed to perform REM sleep determination.
Hereinafter, a specific description will be given with reference to the drawings. FIG. 8 is a graph showing the REM sleep period and the heart rate per unit time detected by the electroencephalogram, and it can be seen from the graph that the increase or decrease in the heart rate is extremely related to the REM sleep period. (References: "Science of Sleep", Norio Torii, Asakura Shoten)
The heart rate increases significantly during the M sleep period, and there is no significant change except during the REM sleep period. REM sleep period is 4 ~ per night
There are 5 times, one time is about 5-10 minutes, the interval is 90-11
It is about 0 minutes.

Therefore, in the present invention, the cardiac potential is measured, amplified, and the memory data analyzed by an apparatus as shown in FIGS. 4, 5, and 6.
Detect REM sleep duration. FIG. 4 is a schematic configuration diagram. As shown in FIG. 5, electrodes sandwiching the heart such as the chest and wrist 1, a band 2 for mounting the electrode 1, a ground electrode 3, and a circuit example are shown in FIG. Sensor block 4 including amplifier circuit 3 shown
And an interface circuit 5 for taking the output from the sensor block 4 into the CPU 6, an arithmetic processing circuit (CPU) 6 for performing an arithmetic operation for data analysis, and a memory circuit 7 for recording an arithmetic processing program and data obtained during the measurement. A microcomputer block 9 comprising a counter circuit 8 for performing time counting and sample counting; a clock block 13 comprising an oscillating circuit 10, a timing circuit 11, an alarm circuit 12, a time display mechanism 21, and a speaker 15; The switch operation unit 14 includes a switch for instructing REM detection operation start. FIG. 6 is a circuit example of the amplifier circuit 3. Briefly referring to the schematic waveform diagram of FIG. 7, the cardiac potential obtained from the electrode is input to the operation amplifier 16 to obtain a point A waveform. This is input to the frequency selection amplifier 17, and only about 20 Hz is amplified (waveform at point B) and further amplified by the inverting amplifier 18 (waveform at point C) and passed through the comparator 19 to obtain a digital output. As shown in the waveform at point D, a rectangular pulse synchronized with the heartbeat (hereinafter, this pulse is referred to as a heartbeat pulse) can be obtained.

Next, the analysis operation will be described based on the operation flowchart of the present invention shown in FIG. 1, FIG. 2, and FIG. The user first sets a time that must finally wake up, for example, 7 o'clock in the morning tomorrow (current time is 10 o'clock PM) and 7 o'clock AM as the alarm final time. Furthermore, turn on REM sleep judgment SW
And go to sleep. Then, first, there is a non-measurement period in which no operation is performed for 30 minutes. This is set assuming the time until the user falls asleep, and there is no adverse effect because it is a time zone that is hardly necessary for the subsequent data analysis. SW
After 30 minutes have passed since the ON was turned on, the cardiac potential measurement was started. The heartbeat pulse output from the amplifier circuit 3 is counted. Here, for example, if the unit heart rate is set to 120, 1
Each time counting 20 times heartbeat pulse, the difference t _n (t _n = T _n of the time the T _n to the memory, further the previous measurement time T _n-1 at that time -
T _n-1 ), and store them together with T _n as a set.

Repeat this operation two hours before the set alarm last time, that is, until 5:00 am, from 10:30 PM to AM5
Approximately 195 sets of average value data (T (n), t (n)) of heartbeat pulses obtained at a rate of about once every two minutes during six and a half hours until the hour will be stored. Based on this data, the period of REM sleep and the degree of change in heart rate are calculated.For the sake of explanation, a graph showing the change in heart rate that can be drawn from these data in time per unit number is shown in FIG. It is shown in FIG. Compared to Fig. 8, t _n
When is significantly reduced regularly, this is the REM sleep period. Two hours before the last alarm time,
First singled out accumulated tens points from the data in ascending order of t _n (e.g. 30 points) of those points
T _n is examining whether gathered in 90 minutes to 110 minutes interval corresponding to the period of REM sleep.

If the gathered if, to set most of the time T _n of the small value of REM sleep time R _N of t _n in each collection. The t _n and R _N mean value of the difference in time of _{t Rn t ar (t ar =} t n -t Rn) were calculated and each R _N each R _N near (for example, 10 minutes of time before and after the R _N) The average value of the interval time T _AR (T _AR = R _N −R _N−1 ) is calculated and the analysis is completed. If the samples are not collected at intervals of 90 minutes to 110 minutes, the number of samples selected in ascending order is sequentially reduced, and it is checked whether the samples are collected at intervals of 90 minutes to 110 minutes each time. Even if the number of samples drops below 10 points,
If they are not gathered at intervals of 90 minutes to 110 minutes, the second analysis method is performed and the operation shown in FIG. 3 is performed. Here, the determination is not based on the absolute value of t _n but on the rate of change. This calculates the M _n time t _n and the previous difference of t _n (for example 10 minutes before) the total t _n and M _n in. Then picked out in descending order of the number points M _n is the rate of change of t _n (e.g. 10 points), T _n of these points, it is checked whether the gathered 90 minutes to 110 minutes. If they were together,
R _N , t _a , and T _AR are calculated and the analysis is completed. If not gathered, calculate the degree of variation from the average value of the interval time between the points selected in the order of M _n in descending order, and if they are within 20%, set each point to R _N and set t _ar , calculating the T _AR to finish the analysis. If not, reduce the number of samples selected in ascending order of _Mn and check the time interval. 20% variation in time intervals
If the number of samples does not fall within a certain number of points (for example, 3 points), it is determined that the REM sleep period cannot be detected, and an alarm is output at the set final time of the alarm. The REM sleep period the average period time REM sleep except when undetectable as REM sleep periods data T _AR and REM sleep time of the current time immediately preceding R _N and REM sleep and NONREM sleep in the time the analysis is complete And a time difference per unit heart rate t _ar (rate of change in heart rate) is obtained. Next, based on these analysis results, t _n and T measured after the current time (about 2 hours before the alarm last time)
_The operation of comparing with _n at any time to determine whether or not it is during the REM sleep period will be described again with reference to FIGS. 1 and 10. Figure 10 shows the timing of ringing alarm when the average period T _AR is 110 minutes, for example REM sleep. First, a non-measurement time T _NK is set based on the analysis result. The no-measurement time T _NK is provided to avoid detecting the REM sleep state twice,
_TNK = 120− _TAR + 5 (min.) Obtained from the following equation based on the REM sleep average cycle T _AR in the analysis result: Nothing when the REM sleep average cycle _TAR is 110 minutes as shown in FIG. The measurement time T _NK is 15 minutes.

After the non-measurement time T _NK has passed, the measurement of the heart rate is started again, and the obtained data t _n , T _n are checked as needed with the following items.

・ REM sleep cycle check, the current time is the previous REM
As a check of the heart rate of change per one-unit time if it is within 10 minutes before and after the time at which the time has elapsed of REM sleep period T _AR from sleep time R _N, t _n and 10 minutes before t _n of the current time REM obtained from the data
The average t 2 items or more whether it is 60% or more of the values of _ar difference t _n the sleep time and NONREM sleep, detecting REM sleep periods in both items of the period and heart rate change become. When a measurement value that passes both items is obtained, it is determined to be REM sleep time, and an alarm is sounded immediately to wake the user. If a measurement value that passes both items is not obtained even when the measurement is repeated at the final time of the alarm, it is determined that the REM sleep period cannot be detected, and an alarm is sounded at the final time of the alarm to wake the user. Except for the case where the REM sleep period cannot be detected by the above operation, it is possible to sound the alarm during the REM sleep period and awaken the user. The amplifier circuit shown in this embodiment is merely an example, and other circuits may be used, and the numerical values (the number of selected samples, the unit heart rate at the time of counting, etc.) used in this embodiment are also used. Actually, this is not the case because it is listed as an example.

〔The invention's effect〕

As described above, according to the present invention, the heart rate is measured by attaching a simple electrode, and the obtained heart rate data is analyzed, thereby enabling the detection of the REM sleep state, and further detecting the REM sleep immediately before the alarm final time. When the alarm is sounded and the user is awakened, the alarm is set slightly longer (REM) than the alarm last time set by the user as shown in FIG.
Approximately one hour at worst, depending on sleep cycle and timing
(40 minutes ago) I wake up early, but I can wake up to the biological rhythm of sleep, and as a result, I can get up very refreshingly. In addition, since the electrodes are attached by a band and data analysis by a microcomputer is used, the sensor can be easily set, and the whole device is small and can be practically used in ordinary households.

[Brief description of the drawings]

FIGS. 1, 2, and 3 are operation flowcharts of the present invention. FIG. 4 is a schematic configuration diagram of the present invention. FIG. 5 is an installation diagram of an electrode for measuring a cardiac potential. FIG. Example FIG. 7 is a schematic waveform of a cardiac potential amplifying circuit. FIG. 8 is a diagram showing a correlation between a REM sleep period and a heart rate per unit time by detecting an electroencephalogram. FIG. 10 is an alarm timing diagram when T _AR = 110 minutes 1... Electrodes 3... Amplifier circuits 6... CPU (Central Processing Unit) 7... Memory 9... … Oscillation circuit 11… Time counting circuit 12 …… Alarm circuit 21 …… Time display mechanism

Claims (2)

(57) [Claims] At least an oscillation circuit, a clock circuit, a time display mechanism, an alarm sounding circuit, an electrode for sensing a cardiac potential for measuring a heartbeat, and amplifying a cardiac potential signal obtained from the electrode and converting the amplified signal into a rectangular pulse. An electronic timepiece comprising an amplifier circuit for outputting a heartbeat pulse synchronized with the heartbeat, a data storage means for storing the interval time of the heartbeat pulse and the measured time as data, and a change amount and a change time of the heart rate based on the data. REM sleep period determining means for analyzing and extracting REM (Rapid Eye Movement) sleep period information, and comparing the REM sleep period information with the data of the interval time between newly obtained heartbeat pulses and comparing the REM sleep period information with the REM sleep period information for a predetermined period immediately before the alarm time. If a sleep period is detected, an alarm signal is output.If a REM sleep period is not detected during a predetermined period, an alarm signal is output at the set alarm time. Alarm clock, characterized in that it comprises an alarm signal output determining means for outputting. 2. The REM sleep period judging means compares the data of the heartbeat pulse interval, and determines the interval between the time when the heartbeat pulse data has a large change and the next time when the heartbeat pulse has a large change; The REM sleep period information is configured to extract REM sleep period information based on two pieces of information of a difference between the value of the heartbeat pulse when the interval data greatly changes and the value of the heartbeat pulse when the interval data does not greatly change. 2. The alarm clock according to claim 1.