JP2007202939A - Biological information detecting apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a biological information detecting apparatus which is easy to remove and can freely detect biological information such as a cardiac potential signal and oxygen saturation of blood. <P>SOLUTION: The biological information detecting apparatus comprises a neck band 11 which can be mounted along the rear of the neck of a subject, a biological information detection unit 12 which is provided in the neck band 11 and detects the biological information by touching the neck of the subject when the subject carries the neck band 11, and a biological information output unit 13 which outputs the biological information detected by the biological information detection unit 12. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a biological information detection apparatus that detects biological information from a subject.

Conventionally, a living body such as a heart has been inspected by detecting biological information such as an electrocardiographic signal. In such a method for detecting biological information, a method for detecting biological information without restriction has been developed (see, for example, Patent Document 1).
Japanese Patent Laid-Open No. 2001-340311 (first page, FIG. 1, etc.)

  However, the conventional example has a problem that it is not easy to attach and detach a device for detecting biological information. For example, in the case of the above-mentioned Patent Document 1, since the biological information detection device is provided in the underwear, when wearing the underwear not provided with the detection device, the underwear is attached to the detection device. I had to change my clothes. The underwear had to be changed when the detector was removed.

  The present invention has been made to solve the above problems, and an object of the present invention is to provide a biological information detection device that can be easily attached and detached and can detect biological information without restriction.

  In order to achieve the above object, a biological information detection apparatus according to the present invention is provided on a neckband that can be worn along the back of a neck of a subject and the neckband, and when the subject wears the neckband, The neckband type device includes a biological information detection unit that detects biological information in contact with the neck and a biological information output unit that outputs the biological information detected by the biological information detection unit.

  With such a configuration, a biological information detection device that can be easily attached and detached can be realized. Further, it is possible to detect biological information without restriction and relatively unconsciously. As a result, it is possible to detect biological information for a long time. Then, by using the biological information detected for a long time, the health condition of the subject can be diagnosed in more detail. In addition, it is possible to reduce the influence of stress and the like on the subject due to detection of biological information. Furthermore, since the biological information detecting device is attached to the neck of the subject, the subject wearing the clothing with a collar or the subject with long hair may be wearing the biological information detecting device from the outside. There is also an advantage that it is difficult to notice.

Further, in the biological information detection apparatus according to the present invention, the biological information detection unit receives a light emitted from the light emitting means and reflected by the carotid artery, and a light emitting means that emits light toward the carotid artery of the subject. And a light receiving means.
With such a configuration, a subject's pulse rate, blood oxygen saturation, and the like can be detected as biological information.

Further, in the biological information detecting apparatus according to the present invention, the biological information detecting unit includes a transmittance calculating unit that calculates the transmittance of light in the carotid artery from the light received by the light receiving unit, and the transmittance calculating unit. And oxygen saturation calculation means for calculating the oxygen saturation of the blood of the carotid artery from the calculated permeability, and the biological information may be the oxygen saturation of the blood.
With such a configuration, the oxygen saturation of the blood of the subject can be detected as biological information.

In the biological information detection apparatus according to the present invention, the biological information detection unit includes two related electrodes provided at both ends of the neckband, and one indifferent electrode provided at the center of the neckband. You may have.
With such a configuration, the subject's electrocardiographic signal can be detected as biological information.

Moreover, in the biological information detection apparatus according to the present invention, the biological information detection unit further includes a measurement unit that measures a cardiac potential signal of a subject using the related electrode and the indifferent electrode, and the biological information is It may be an electrocardiographic signal.
With such a configuration, the subject's electrocardiogram signal can be detected as biological information.

Further, in the biological information detection device according to the present invention, a microphone provided in the neckband for converting sound generated in the oral cavity or throat of the subject into an electrical signal, and an audio output unit for outputting the electrical signal from the microphone, May be further provided.
With such a configuration, it is possible to acquire the voice produced by the subject together with the biological information of the subject, and various processes can be performed by using these.

  In the biological information detection apparatus according to the present invention, a posture information acquisition unit that is provided in the neckband and acquires posture information that is information related to the posture of the subject, and a posture that outputs the posture information acquired by the posture information acquisition unit And an information output unit.

  With such a configuration, posture information indicating the posture of the subject can be acquired together with the biological information of the subject, and various processes can be performed by using them.

  Moreover, in the biological information detection apparatus according to the present invention, a motion information acquisition unit that is provided in the neckband and acquires motion information that is information related to a subject's motion, and a motion that outputs the motion information acquired by the motion information acquisition unit. And an information output unit.

  With such a configuration, motion information indicating the motion of the subject can be acquired together with the biological information of the subject, and various processes can be performed by using them.

  According to the biological information detection device of the present invention, the biological information detection device can be easily attached and detached by adopting a neckband type. In addition, biometric information can be acquired without restriction. Furthermore, since the biological information detection device is attached to the neck of the subject, in the case of a subject wearing a collared subject or a subject with long hair, he / she notices from the outside that the biological information detection device is attached. There is also a merit that it is hard to get it.

  Hereinafter, a biological information detection apparatus according to the present invention will be described using embodiments. Note that, in the following embodiments, the components given the same reference numerals are the same or equivalent, and repetitive description may be omitted.

(Embodiment 1)
A biological information detection apparatus according to Embodiment 1 of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram showing a configuration of a biological information detection apparatus 1 according to the present embodiment. In FIG. 1, the biological information detection apparatus 1 according to the present embodiment includes a neckband 11, a biological information detection unit 12, and a biological information output unit 13.

  The neck band 11 can be worn along the back of the subject's neck. That is, the neckband 11 is worn from the side of one neck of the subject to the side of the other neck via the back of the subject's neck. The neckband 11 is urged so as to shrink inward. Therefore, when the subject wears the neckband 11, the neckband 11 comes into contact with the neck of the subject, so that the position of the neckband 11 is maintained at the neck of the subject. The subject can easily attach and detach the neckband 11. Such a neckband 11 is conventionally known as a neckband microphone or the like, and a detailed description thereof will be omitted. The neck band 11 may be adapted to necks of various thicknesses by adjusting its length by an adjustment mechanism or the like. Further, the neckband 11 may be connected to the front of the neck as long as the neckband 11 can be mounted along the rear of the neck. That is, it may be in the form of a belt in the neck.

The biological information detection unit 12 is provided in the neckband 11 and detects biological information by contacting the neck of the subject when the subject wears the neckband 11. Here, the content of the biological information is not limited as long as it is information related to the biological body of the subject. For example, it may be the light transmittance related to the blood of the subject, the pulse rate obtained from the change in the light transmittance, or the oxygen saturation (SpO ₂ ) of the blood obtained from the light transmittance. Alternatively, it may be an electrocardiogram signal, or a voltage signal used for calculating the light transmittance of blood or the electrocardiogram signal. In the present embodiment, the biological information detection unit 12 detects blood oxygen saturation as biological information. In a second embodiment to be described later, a case where the biological information detection unit 12 detects a cardiac potential signal as biological information will be described.

  The biometric information output unit 13 outputs the biometric information detected by the biometric information detection unit 12. Here, the output may be, for example, display on a display device (for example, CRT or liquid crystal display), transmission via a wired or wireless communication line to a predetermined device, printing by a printer, Audio output by a speaker may be used, storage in a recording medium may be performed, and biological information may be transmitted to other devices via an output terminal. The biometric information output unit 13 may or may not include a device that performs output (for example, a display device or a printer). The biometric information output unit 13 may be realized by hardware (display device, communication device, output terminal, or the like), or may be realized by software such as a driver for driving these devices.

  Although FIG. 1 shows a configuration in which the biological information detection unit 12 is provided at one end of the neckband 11 and the biological information output unit 13 is provided at the other end, it is needless to say that the configuration is not limited thereto. The biological information detection unit 12 and the biological information output unit 13 may be provided at any position of the neckband 11 as long as these functions can be exhibited.

  FIG. 2 shows the configuration of the biological information detection unit 12. In FIG. 2, the biological information detection unit 12 includes a light emitting means 21, a light receiving means 22, a transmittance calculating means 23, and an oxygen saturation calculating means 24.

  The light emitting means 21 emits light toward the subject's carotid artery. The light emitting means 21 may be, for example, a light emitting diode (LED) or the like, or may have another configuration that emits light.

  The light receiving means 22 receives light emitted from the light emitting means 21 and reflected by the subject's carotid artery. The light receiving means 22 may be, for example, a photo detector or the like, or may be another configuration that receives light.

  The light emitting means 21 and the light receiving means 22 are preferably configured to be in close contact with the neck of the subject so as not to be affected by external light. For example, by providing an elastic member such as a flexible urethane resin on the opposite side of the light emitting means 21 and the light receiving means 22 from the subject, when the subject wears the biological information detection device 1, each adheres closely to the neck of the subject. You may make it do.

  The transmittance calculating means 23 calculates the light transmittance in the carotid artery of the subject from the light received by the light receiving means 22. Here, the light transmittance may be other information as long as the light transmittance is known as a result. For example, it may be light absorption. In order to calculate the oxygen saturation level of the blood, the transmittance calculating means 23 uses, for example, two lights of red light (light having a wavelength near 660 nm) and near infrared light (light having a wavelength near 880 nm). Calculate the transmittance.

  The oxygen saturation calculator 24 calculates the oxygen saturation of the blood of the subject's carotid artery from the permeability calculated by the permeability calculator 23. This calculation method is conventionally known as a pulse oximeter technique, and a detailed description thereof will be omitted. In this way, the biological information detector 12 detects the oxygen saturation level of blood as biological information. In addition, the method by which the biological information detection unit 12 detects the oxygen saturation of blood is not limited to the above description, and may be detected by other methods.

  Next, a method for using the biological information detection apparatus 1 will be briefly described. Here, it is assumed that the biological information output unit 13 transmits information indicating the oxygen saturation level of blood as biological information by wireless communication means.

  First, the subject wears the biological information detection device 1 on the neck. FIG. 3 is a diagram illustrating an example of a state in which the biological information detection apparatus 1 is attached to a subject. When the subject wears the biological information detecting apparatus 1, it is preferable that the light emitting means 21 and the light receiving means 22 exist at the position of the subject's carotid artery. The light emitting means 21 and the light receiving means 22 are in close contact with the neck of the subject by the urging force of the neckband 11, and the light emitted from the light emitting means 21 and reflected by the carotid artery is received by the light receiving means 22. Then, the light transmittance in the carotid artery is calculated by the transmittance calculator 23, and the oxygen saturation of the carotid blood is calculated by the oxygen saturation calculator 24. The calculated oxygen saturation is transmitted from the biological information output unit 13, received by a receiving unit (not shown), and stored as data on the oxygen saturation of the subject. Thereafter, the accumulated oxygen saturation data can be used for the examination of the subject.

  As described above, in the biological information detection apparatus 1 according to the present embodiment, the biological information detection apparatus 1 is made to be a neckband type, so that it can be easily attached to and detached from the subject. That is, there is no need to change clothes as in the conventional example in order to attach and detach the biological information detecting device 1. In particular, even if the human neck may vary in thickness, the shape is not so different, so it is relatively easy to fit the neckband 11 to the necks of various subjects.

  In addition, the biological information detection apparatus 1 can detect biological information without restriction. Furthermore, when the biological information detection apparatus 1 is worn on the neck, the subject is not so concerned, and thus the biological information can be detected relatively unconsciously. As a result, it is possible to detect biological information for a long time. Then, by using the biological information detected for a long time, the health condition of the subject can be diagnosed in more detail. In addition, since the biological information can be detected unconstrained and unconsciously, it is possible to reduce the influence of stress on the subject caused by the detection of the biological information.

  Furthermore, since the biological information detection device 1 is attached to the neck of the subject, the biological information detection device 1 may be attached to a subject wearing a collared subject or a subject with long hair. There is also an advantage that it is difficult to be noticed from the outside.

  In the present embodiment, the case where the biological information detected by the biological information detection unit 12 is the blood oxygen saturation is described. However, the biological information is used for obtaining the blood oxygen saturation as described above. It may be information, for example, a voltage indicating the intensity of light received by the light receiving means. In such a case, a pulse rate, a blood oxygen saturation level, or the like may be detected in a device or the like that has received the output biological information.

(Embodiment 2)
A biological information detection apparatus according to Embodiment 2 of the present invention will be described with reference to the drawings. In the biological information detection apparatus according to the present embodiment, the biological information detection unit detects an electrocardiogram signal.

  FIG. 4 is a diagram showing a configuration of the biological information detection apparatus 2 according to the present embodiment. In FIG. 4, the biological information detection apparatus 2 according to the present embodiment includes a neckband 11, a biological information output unit 13, and a biological information detection unit 14. The configurations and operations of the neckband 11 and the biological information output unit 13 are the same as those in the first embodiment, and a description thereof is omitted.

  The biological information detection unit 14 is provided in the neckband 11 and detects biological information by contacting the neck of the subject when the subject wears the neckband 11, but in the present embodiment, the above-described biological information is detected. Thus, an electrocardiographic signal is detected. The cardiac potential signal is a signal related to the action potential of the heart. The biological information detection unit 14 includes one indifferent electrode 31 provided at the center of the neckband 11, two related electrodes 32 provided at both ends of the neckband 11, and a measuring unit 33.

  The indifferent electrode 31 and the related electrode 32 may be any electrodes as long as they can detect a cardiac potential signal. For example, it may be a conductive fiber, a gel electrode, a metal electrode, or a disposable electrode. Here, the conductive fiber is a fiber having conductivity. The conductive fiber may be a fiber made of a conductive polymer, for example. In addition, the conductive fiber may be a fiber in which an electrically conductive material such as metal or carbon is attached or kneaded to the surface or center of a fiber such as nylon, polyester, acrylic, or cotton. The metal may be copper or aluminum, for example. The conductive fiber may be any material as long as it has a low contact resistance with the skin and does not harm the human body. In the case where the indifferent electrode 31 and the related electrode 32 are conductive fibers, the electrode follows the shape of the subject's skin, and is more likely to be in close contact with the subject's skin, thereby detecting an electrocardiographic signal with less noise. It becomes possible. Further, the indifferent electrode 31 and the related electrode 32 may have elasticity. In the case where the indifferent electrode 31 and the related electrode 32 have elasticity, the adhesion to the skin of the subject can be further improved, which is preferable.

One indifferent electrode 31 and two related electrodes 32 are preferably present in the indifferent electrode region and the related electrode region, respectively, when the subject wears the neckband 11. Here, an indifferent electrode area | region is an area | region which performs a measurement by a test subject's indifferent electrode. The related electrode region is a region where measurement is performed using the related electrode of the subject.
The measuring means 33 measures the cardiac potential signal of the subject using the indifferent electrode 31 and the related electrode 32.

  FIG. 5 is a block diagram showing the configuration of the measuring means 33. In FIG. 5, the measuring means 33 includes potential difference measuring units 41 and 42, a differential amplifier 43, and a notch filter 44.

  The potential difference measuring unit 41 measures the potential between the indifferent electrode 31 and one of the related electrodes 32. That is, the potential of one of the related electrodes 32 with respect to the indifferent electrode 31 is measured.

  The potential difference measuring unit 42 measures the potential between the indifferent electrode 31 and the other related electrode 32. That is, the potential of the other related electrode 32 with respect to the indifferent electrode 31 is measured.

  The differential amplifier 43 performs differential amplification using each potential difference measured by the potential difference measuring units 41 and 42 as two inputs.

  The notch filter 44 is a filter that attenuates a predetermined frequency with respect to the output signal of the differential amplifier 43. The predetermined frequency is the frequency of the noise source. For example, in a region where the frequency of the AC commercial power supply is 60 Hz, the predetermined frequency is 60 Hz.

Note that a method for measuring a cardiac potential signal using the potential difference measuring units 41 and 42, the differential amplifier 43, the notch filter 44, and the like has been conventionally known, and a detailed description thereof will be omitted.
The method of using the biological information detecting device 2 is the same as that in the first embodiment except that the biological information is an electrocardiographic signal, and the description thereof is omitted.

  As described above, also in the biological information detection apparatus 2 according to the present embodiment, the biological information detection apparatus 2 can be easily attached to and removed from the subject by making the biological information detection apparatus 2 a neckband type. Will be obtained.

  In the present embodiment, the case where the biological information detected by the biological information detection unit 12 is an electrocardiographic signal has been described. However, the biological information includes, for example, the indifferent electrode 31, May be information indicating the potential difference between them, and may be information output by the differential amplifier 43 that does not perform the processing by the notch filter 44. In such a case, detection of an electrocardiogram signal, processing by a notch filter, or the like may be performed in a device or the like that has received the output biological information.

  In this embodiment, the case where the cardiac potential signal is detected by using three electrodes has been described. However, the number of electrodes used to detect the cardiac potential signal is limited to the above description. is not. The biological information detection unit 14 may include two or more indifferent electrodes or three or more related electrodes. Further, the position of each electrode is not limited to the above description as long as an electrocardiographic signal can be detected.

  Moreover, in each said embodiment, you may make it acquire the sound which generate | occur | produces in a test subject's oral cavity or throat using a microphone. That is, as shown in FIG. 6, the biological information detection apparatus may include a microphone 51 and an audio output unit 52. The microphone 51 is provided in the neckband 11 and converts sound generated in the oral cavity or throat of the subject into an electrical signal. Here, the throat is a region including the pharynx and the larynx, and is a so-called “throat” part. The sound generated in the oral cavity or throat of the subject is, for example, conversation, laughter, swallowing sound, snoring sound, mastication sound, coughing, and the like. As such a microphone 51, for example, one disclosed in US Pat. No. 5,780,079 may be used, and any other sound can be used as long as it can acquire sound generated in the oral cavity or throat of the subject. A thing may be used. The audio output unit 52 outputs an electrical signal from the microphone 51. Here, this output may be, for example, transmission via a wired or wireless communication line to a predetermined device, or storage in a recording medium, and the output from the microphone 51 to another device or the like via the output terminal. It may be a signal. Note that the audio output unit 52 may or may not include a device (for example, a communication device or an output terminal) that performs output. The audio output unit 52 may be realized by hardware (communication device, output terminal, etc.), or may be realized by software such as a driver for driving these devices. Note that the microphone 51 and the audio output unit 52 may be provided at any position of the neckband 11 as long as the microphone 51 can acquire sound generated in the oral cavity or throat of the subject.

  By providing such a microphone 51 and the sound output unit 52, it is possible to acquire sound generated in the oral cavity or throat of the subject and biological information of the subject. And you may perform various processes using them. For example, it is known that when a human laughs from the bottom of his heart, his heart rate falls after laughing than before laughing. On the other hand, if you laugh only on the surface, like laughter, there is not much change in heart rate before and after laughter. Therefore, laughter is detected by using the technology such as the laughter detection device disclosed in Japanese Patent Application Laid-Open No. 2004-243023, and the heart rate is detected by using the technology such as the pulse oximeter described in the second embodiment. However, by counting the number of times of laughing only when the heart rate is lower than before laughing, the number of times of laughing from the bottom of the heart can be counted. And checking the number of laughs every day, like checking the number of steps every day with a pedometer, can help maintain health. In addition, by acquiring sound generated in the oral cavity or throat of the subject, it can be used for diagnosis of apnea syndrome, diagnosis of dysphagia, measurement of stress reduction effect by laughter, and the like.

  Further, in each of the above embodiments, information related to the posture of the subject may be acquired using an inclination sensor or the like. That is, as illustrated in FIG. 7, the biological information detection apparatus may include a posture information acquisition unit 61 and a posture information output unit 62. The posture information acquisition unit 61 is provided in the neckband 11 and acquires posture information that is information regarding the posture of the subject. The posture information acquisition unit 61 may be, for example, an inclination sensor. The posture information indicates whether the subject is sleeping or standing. The posture information output unit 62 outputs the posture information acquired by the posture information acquisition unit 61. Here, this output may be transmitted via a wired or wireless communication line to a predetermined device, or may be stored in a recording medium, and conveys posture information to other devices via the output terminal. But you can. Note that the posture information output unit 62 may or may not include a device that performs output (for example, a communication device or an output terminal). In addition, the posture information output unit 62 may be realized by hardware (communication device, output terminal, or the like), or may be realized by software such as a driver that drives these devices. Note that the posture information acquisition unit 61 and the posture information output unit 62 may be provided at any position of the neckband 11 as long as posture information can be acquired by the posture information acquisition unit 61. For example, in the inclination sensor, when the standing position of the subject is set to 0 degrees and the state where the subject is sleeping is set to 90 degrees, the value of the posture information output from the posture information output unit 62 Whether the subject is in a standing position or in a sleeping state can be determined based on whether the angle is close to 0 degrees or close to 90 degrees.

  By including the posture information acquisition unit 61 and the posture information output unit 62, the posture of the subject and the biological information of the subject can be acquired. And you may perform various processes using them. For example, when the posture information output from the posture information output unit 62 indicates that the subject is in the sleeping posture, and the biological information output from the biological information output unit 13 (for example, blood If the subject is detected to be in an apnea state (for example, when the oxygen saturation level of the blood falls below a threshold value), the subject sleeps. It is also possible to detect that the patient is in a state of apnea and execute a predetermined process corresponding thereto. The predetermined processing may be, for example, waking up the subject or the family of the subject by sounding an alarm. In addition, by using posture information and blood oxygen saturation as biological information, it is possible to perform a sleep quality test or the like. In this way, the biological information detection device includes, for example, an apnea determination unit that determines whether the subject is in an apnea state based on the biological information output from the biological information output unit 13, and an apnea determination unit. A warning output unit that outputs warning information when the subject is determined to be in an apneic state and the posture information output from the posture information output unit 62 determines that the subject is sleeping. You may prepare. The warning information is information that warns that the subject is in a sleep apnea state, such as the alarm described above.

  Moreover, in each said embodiment, you may make it acquire the information regarding a test subject's motion using an acceleration sensor etc. FIG. That is, as illustrated in FIG. 8, the biological information detection apparatus may include a motion information acquisition unit 71 and a motion information output unit 72. The movement information acquisition unit 71 is provided in the neckband 11 and acquires movement information that is information relating to the movement of the subject. The motion information acquisition unit 71 may be, for example, an acceleration sensor. The movement information indicates whether the subject is stopped, moving, moving violently when moving, or moving slowly. The motion information output unit 72 outputs the motion information acquired by the motion information acquisition unit 71. Here, this output may be transmitted via a wired or wireless communication line to a predetermined device, or may be stored in a recording medium, and the movement information is transmitted to other devices via the output terminal. But you can. The motion information output unit 72 may or may not include a device that performs output (for example, a communication device or an output terminal). Further, the motion information output unit 72 may be realized by hardware (communication device, output terminal, or the like), or may be realized by software such as a driver that drives these devices. Note that the motion information acquisition unit 71 and the motion information output unit 72 may be provided at any position of the neckband 11 as long as the motion information can be acquired by the motion information acquisition unit 71. For example, when the motion information acquisition unit 71 is an acceleration sensor and the value of the motion information output from the motion information output unit 72 is 0.5 G or more, it may be determined that the subject is moving violently.

  By providing such a movement information acquisition unit 71 and a movement information output unit 72, it is possible to acquire the movement of the subject and the biological information of the subject. And you may perform various processes using them. For example, when it is detected from the motion information output from the motion information output unit 72 that the subject is moving vigorously (for example, when the value of the motion information is greater than or equal to a threshold value), the biological information It is highly possible that the detection unit is not properly in contact with the subject's neck, and it is highly likely that the biological information cannot be detected properly. Also good. In this way, the biological information detection apparatus includes, for example, a determination unit that determines whether or not the subject's movement is equal to or greater than a threshold value based on the movement information output from the movement information output unit 72, and the movement of the subject is determined by the determination unit. An invalidation unit that invalidates the biological information output from the biological information output unit 13 when it is determined that the value is greater than or equal to the value may be further provided. The invalidation of the biometric information by the invalidation unit may be, for example, stopping the output of the biometric information or outputting information indicating that the biometric information is invalid.

  Further, two or more processes may be executed in one biological information detection apparatus among the process of acquiring and outputting the voice of the subject, the process of acquiring and outputting the posture information, and the process of acquiring and outputting the motion information. . By using them, it is possible to perform diagnosis of apnea syndrome, diagnosis of dysphagia, measurement of stress reduction effect by laughter, and the like.

  Further, the method for detecting biological information is not limited to the above description, and other methods may be used. For example, the biological information detection apparatus may detect the heart rate by detecting carotid artery vibration.

In each of the above embodiments, each component may be configured by dedicated hardware, or a component that can be realized by software may be realized by executing a program. For example, each component can be realized by a program execution unit such as a CPU reading and executing a software program recorded on a recording medium such as a hard disk or a semiconductor memory.
Further, the present invention is not limited to the above-described embodiment, and various modifications are possible, and it goes without saying that these are also included in the scope of the present invention.

  As described above, the biological information detection apparatus according to the present invention can detect biological information without restriction, and is useful as an apparatus for detecting biological information.

The figure which shows the structure of the biometric information detection apparatus by Embodiment 1 of this invention. The block diagram which shows the structure of the biometric information detection part in the embodiment The figure which shows an example of the mounting state of the biometric information detection apparatus in the embodiment The figure which shows the structure of the biometric information detection apparatus by Embodiment 2 of this invention. The block diagram which shows the structure of the measurement means in the embodiment The figure which shows an example of the biometric information detection apparatus which acquires the audio | voice in other embodiment The figure which shows an example of the biometric information detection apparatus which acquires the attitude | position information in other embodiment The figure which shows an example of the biometric information detection apparatus which acquires the motion information in other embodiment

Explanation of symbols

DESCRIPTION OF SYMBOLS 1, 2 Biological information detection apparatus 11 Neckband 12 Biological information detection part 13 Biological information output part 14 Biological information detection part 21 Light emission means 22 Light reception means 23 Permeability calculation means 24 Oxygen saturation calculation means 31 Indifferent electrode 32 Related electrode 33 Measuring means 41, 42 Potential difference measuring unit 43 Differential amplifier 44 Notch filter 51 Microphone 52 Audio output unit 61 Posture information acquisition unit 62 Posture information output unit 71 Information acquisition unit 72 Information output unit

Claims (8)

A neckband that can be worn along the back of the subject's neck;
A biological information detection unit that is provided in the neckband and detects biological information by contacting the neck of the subject when the subject wears the neckband;
A neckband type biological information detection apparatus comprising: a biological information output unit that outputs biological information detected by the biological information detection unit. The biological information detection unit
A light emitting means for emitting light toward the subject's carotid artery;
The neckband type biological information detection apparatus according to claim 1, further comprising: a light receiving unit configured to receive light emitted from the light emitting unit and reflected by the carotid artery. The biological information detection unit
A transmittance calculating means for calculating the transmittance of light in the carotid artery from the light received by the light receiving means;
Oxygen saturation calculation means for calculating oxygen saturation of the blood of the carotid artery from the permeability calculated by the permeability calculation means;
The biological information detection apparatus according to claim 2, wherein the biological information is blood oxygen saturation. The biological information detection unit
Two Seki electrodes provided at both ends of the neckband;
The neckband-type biological information detection apparatus according to claim 1, further comprising: one indifferent electrode provided at a center of the neckband. The biological information detection unit further includes a measuring unit that measures a cardiac potential signal of a subject using the related electrode and the indifferent electrode,
The neckband type biological information detection apparatus according to claim 4, wherein the biological information is a cardiac potential signal. A microphone that is provided in the neckband and converts sound generated in the oral cavity or throat of the subject into an electrical signal;
The neckband type biological information detection device according to claim 1, further comprising: an audio output unit that outputs an electric signal from the microphone. A posture information acquisition unit that is provided in the neckband and acquires posture information that is information related to the posture of the subject;
The neckband type biological information detection device according to any one of claims 1 to 6, further comprising a posture information output unit that outputs posture information acquired by the posture information acquisition unit. A movement information acquisition unit that is provided in the neckband and acquires movement information that is information related to the movement of the subject;
The neckband-type biological information detection device according to claim 1, further comprising: a motion information output unit that outputs the motion information acquired by the motion information acquisition unit.