JPH04208135A - Physiological condition sensing device - Google Patents

Abstract

PURPOSE:To sense brain waves only through fitting an earphone to the ear by furnishing a physiolosipal condition sensor in that part of earphone or any earphone-shaped member which contacts the skin. CONSTITUTION:An earphone 10 equipped with a sound emitting element 77 has an insertion part 12 to an earhole, and this part 12 is provided with a pair of electrodes 13, 13, which are connected to an alpha-wave sensor 20 through wirings 14, 14. This alpha-wave sensor 20 is fitted with an amplifier 21, band-pass filter 22, comparator 23, and tone signal generator 24, the last named being connected to the sound emitting element 77 of the earphone 10 through wirings 15, 15. That is, it is practicable to locate a physiological condition sensor according to the invention in that part of earphone 10 which contacts the skin. This enables easy performance of mental concentration using sensing of the alpha-wave state, or continuous measuring of the physical temp., blood pressure, etc.

Description

[Detailed description of the invention] Industrial applications The present invention detects physiological conditions such as brain waves, body temperature, and blood pressure. Ru.

BACKGROUND OF THE INVENTION It has been known that there is a high correlation between a state of mental unity and a state in which alpha waves, which are detected by brain waves, are detected.

Therefore, using this fact, biofeedback equipment is used when training to concentrate the mind. A device called ``1'etc.'' is sometimes used that assists in graphical control of the mental state by detecting the alpha wave state and informing the degree of mental unity2゜This type of device 4 It is possible to measure brain waves, myoelectric potential, and skin-to-skin resistance by attaching an electrode called a so-called Hen 1 band to the head, or by pinching the earlobe with a clothespin-shaped electrode. etc., and detect whether these are in a predetermined state or not, thereby detecting an alpha wave state, etc. When an alpha wave state is detected, a tone sound or the like is generated from the speaker to notify the user.

In other words, by knowing whether or not the user has entered the alpha wave state through the sensation of , it becomes easier for the user to unify his or her mind.

In addition, in recent years, with the development of electronic technology, devices that easily measure body temperature, blood pressure, etc. 1:1 have come into widespread use.

This type of device can easily measure body temperature, blood pressure, etc. by simply attaching a detection device such as x, :, rα, piezoelectric element, etc. to the arm or finger. It has become.

Problems to be Solved by the Invention However, in the conventional biofeedback devices and the like described above, it is necessary to attach a relatively large-scale device such as a headband or clothespin-shaped electrodes to the head or the like. For this reason, the alpha wave detection device itself has the ability to be relatively miniaturized.
Although it is a 4F function, it has the problem that it is difficult to carry and use it in a place where it will come close to a person, such as inside a heavy truck.

In addition, since the 1:Ill device that measures body temperature, blood pressure, etc. requires a relatively large device to be attached to the finger or arm, it is necessary to continuously measure the temperature and blood pressure to know the steady state and changing state in daily life. It was difficult to locate the corridor.

In view of the points mentioned in -I-, the present invention makes it easy for a person to unify his or her mind using detection of alpha wave state without worrying about ``1'', and to continuously measure body temperature, blood pressure, etc. The object of the present invention is to provide a physiological state detection sensor device that enables the following.

Means for Solving the Problems 1 - In order to achieve the object, the present invention provides a physiological state detection sensor device for detecting the physiological state of a human body, in which the physiological state detection body is connected to the skin of the earphone. The feature is that it is provided at the contact area.

The present invention is also a physiological state detection sensor device for detecting the physiological state of a human body, and is characterized in that a physiological state detection body is provided at a contact site with the skin In of the earphone-shaped member.

The physiological state detection sensor device detects the physiological state of a human body, and includes two earphones, a connecting member that connects the two earphones, and a conductive detection wire disposed at the connecting portion 3+4. (1::i).

According to the configuration described in Operation-4-, simply by wearing the earphone or earphone shape part + A on the ear, the physiological state detector provided at the contact site with the skin and the connecting part of the earphone +4 can be used. Electroencephalograms, myoelectric potential, skin resistance, body temperature, blood pressure, etc. can be measured through the conductive detection wires.

First Embodiment FIG. 1 is a configuration diagram showing the configuration of a biofeedback device to which the physiological state detection sensor device of the present invention is applied.

The earphone 10 equipped with the sounding body 11 is provided with an insertion section 12 for insertion into the ear canal, and this insertion section]2 has a pair of electrodes 13.
・13 are provided. -1- electrodes 13, 13,
It is connected to an alpha wave detector 20 via connections 14 and 14.

The alpha wave detector 20 includes an amplifier 21, a bandpass filter 22 that passes a frequency component of, for example, about 10H2, a comparator 23 that detects when the output from the bandpass filter 22 reaches a predetermined level. C and 1
--The generator 24 is constructed in a sunken manner. The 1--tone signal generator 24 is connected to the sounding body 11 of the earphone 10 via connections 15 and 15.

In the configuration described in -4-, the insertion portion 1- of the earphone 10
2 is inserted into the ear canal, the electrodes 13 come into contact with the inner wall of the ear canal, and a potential difference based on myoelectricity or the like is generated between the electrodes 13. Since this potential difference has a correlation with brain waves, after being amplified by the amplifier 21, only the α wave state component is output from the band pass filter 22 and input to the comparator 23. Therefore, when the alpha wave state component exceeds a preset level, comparators 2 and 3 are turned on, and
Ai+ 24 moves I1 and emits E (, 1-- from body 11
A person wearing an earphone 10 that emits a tone sound will learn the feeling when the tone sound is emitted, and by intentionally entering into a similar sensory state, it will be easier to unify the mind. be able to.

When the output of the comparator 23 is +, instead of manually inputting it to the 1st generation generator 24 as described above, input it manually to the remote I~ terminal of the tape recorder 31, and α When you are in a wave state, for example, if you play back the 1゛f voice that you have recorded for the word you want to memorize, you can memorize words efficiently.

Furthermore, the tape recorder 31 may be configured to generate RF music, etc. for indulging in crimping meditation.Also, instead of the earphone 10, the electrodes 123 and 13 may be attached to an earphone-shaped member not provided with the sounding body 11. (When an α-wave state is detected by using a device equipped with J, it is also possible to generate a tone sound etc. from another speaker or make it blink with a built-in α-wave detector 20. .

In addition, the electrodes 13 and 13 are not limited to the straight lines as described above, but may be concentric electrodes 41 and 41, as shown in FIG. Third
As shown in the figure, a pair of earphones 3-0 and 10 may be provided with one electrode 42 and 42, respectively.

Furthermore, the earphones 10, 10 are not limited to those in which the insertion portions 12, 12 are formed as shown in 1-, but may be of a so-called in-ear type, as shown in FIG. 4, for example. .

In addition, the device to which the electrodes 1-3... are connected is not limited to the α-wave detector 20 as described in 1; for example, the electrical resistance between the electrodes 13... It may also be possible to detect various conditions such as sweating or the like.

Embodiment 2 FIG. 5 is a diagram showing the structure of a body temperature/pulse/sphygmomanometer equipped with a physiological state detection sensor having a thermistor and piezoelectric teeth -r. Note that members having the same functions as those in the 1)02 first embodiment are given the same numbers and their explanations are omitted.

The insertion portion 12 of the earphone 50 is provided with a thermistor 51 and a piezoelectric element 52. The thermistor 51 and the piezoelectric teeth T and 52 are each connected to the wire 14...
It is connected to body temperature/pulse/1f11 pressure gauge 61 via.

- Recording Body temperature/pulse/sphygmomanometer 61 measures body temperature, pulse rate, and blood pressure using a well-known electronic circuit. In addition to storing the measured values, it also detects the alpha wave state described in hU and generates a l--on signal, etc.
It is designed to generate a warning sound when the measured value indicates, for example, high blood pressure.

In the above configuration as well, just by wearing the earphone 50 in the ear, the physiological state can be detected as in the first embodiment.
'I;: can be easily measured continuously, so it can be effectively used for health management, etc.

Third Embodiment FIG. 6 is a perspective view showing the structure of a physiological nail detection sensor device according to a twenty-third embodiment of the present invention.

A pair of earphones 7 each equipped with sounding bodies 71 and 71
0 and 70 are connected via connecting members 72 and 72. The connecting members 72, 72 are rotatably attached to the earphones 70, 70L via pins 73, 73, so that the angle between them can be varied. A conductive detection line 74 is provided on one of the connecting members 72, 72, and is connected to an electroencephalogram detection device (not shown).

The above physiological state detection sensor device is used in earphones 70 and 70.
When worn so that it is positioned near both ears, an induced current or electromagnetic wave current caused by brain waves flows through the conductive detection wire 74, and the brain wave detection device can detect alpha wave states, etc. .

According to the physiological state detection sensor device as described above, since the connecting members 72, 72 can be rotated with respect to the earphones 70, 70, the isoelectric detection wire 74 can be positioned near the frontal lobe of the brain, for example. Brain waves can be detected efficiently. .

As described above, according to the present invention, a physiological state detector is provided at the earphone or the contact area of the earphone shape with the skin IfI, or a conductive detector is provided at the connecting portion of the earphone. Because the wires are arranged, it is possible to detect brain waves just by wearing the earphones in your ears, so you can easily practice mental concentration even on a train, for example, without worrying about other people. This has the effect of making it easy to carry out such tasks and continuously measure body temperature, blood pressure, etc.

[Brief explanation of the drawing]

Fig. 1 is a block diagram showing the configuration of a biofeedback device according to a first embodiment of the present invention, Fig. 2 is a perspective view showing another example of the earphone, and Fig. 3 is a perspective view showing still another example of the earphone. 4 is a perspective view showing still another example of the earphone, FIG. 5 is a configuration diagram showing the configuration of a body temperature/pulse/sphygmomanometer according to the second embodiment of the present invention, and FIG. 6 is a perspective view showing another example of the earphone. FIG. 7 is a perspective view showing the configuration of a physiological state detection sensor device according to a third example. 10.50.70...Iafon, 13.41.42
...electrode, 5]-...thermistor, 52...piezoelectric element, 72...cardiac detection wire

Claims (3)

[Claims] (1) A physiological state detection sensor device for detecting the physiological state of a human body, characterized in that a physiological state detection body is provided at a portion of an earphone that comes into contact with the skin. (2) A physiological state detection sensor device for detecting the physiological state of a human body, wherein the physiological state detection body is provided at a portion of an earphone-shaped member that comes into contact with the skin. (3) A physiological state detection sensor device that detects the physiological state of a human body, comprising two earphones, a connecting member that connects the two earphones, and a conductive detection line disposed on the connecting member. A physiological state detection sensor device characterized by: