TW201626951A - Wearable physiological monitoring device and system - Google Patents

Abstract

The present invention discloses a wearable physiological monitoring device for detecting a user's mental state, which includes an eyeglass structure having two temples and a frame to be mounted on the user's head through ears and nose of the user; a first electrode disposed on the frame of the eyeglass structure; a second electrode disposed on one temple of the eyeglass structure; and a physiological signal acquisition circuit to obtain EEG signal and EOG (Electrooculography) signal through the first electrode and second electrode, wherein the first electrode is involved in the acquisition of EEG signal, and the second electrode is involved in the acquisition of EOG signal, and the EEG signal and EOG signal are used to obtain the mental state of the user.

Description

Wearable physiological monitoring device and system

The present invention relates to a wearable physiological monitoring device and system, and more particularly to a wearable physiological monitoring device and system for determining a mental state through multiple physiological information.

During work or when you need to concentrate, you need to stay awake. Moreover, people's mental state, such as fatigue, concentration, sobriety, etc., may even affect personal safety, for example, mental state during driving. Especially important, if you can't maintain good concentration, it is very likely to cause a car accident and cause loss of life and property.

In general, a person's mental state can be known through many physiological signals, such as brain signals, eye signals, and the state of activity of the autonomic nervous system.

Usually, the electrical activity of the brain measured by placing the electrode on the scalp is called an electroencephalogram (EEG). The electroencephalogram can be used to detect and diagnose many physiological conditions. Among them, different brainwave frequencies are known. It represents the different mental states of the human body. For example, when the human body is in a state of waking and concentration, the dominant β wave (about 12-28 Hz) can be measured. On the other hand, when the human body is in a relaxed state, it can be measured. The dominant alpha wave (about 8-12 Hz), and when it is about to enter sleep state, a lower frequency brain wave can be observed, so it is indeed possible to understand human by distinguishing the dominant brain wave frequency. Mental state.

Furthermore, the autonomic nervous system includes the sympathetic nervous system and the parasympathetic nervous system. Through the antagonism between the two to complete the physiological functions of many non-autonomous consciousness control in the human body, when the sympathetic nerve activity increases, the human body tends to be in a state of tension, and when the parasympathetic activity increases, it will tend to The human body enters a state of relaxation, and during this period, various physiological phenomena of the human body will also have corresponding changes. For example, when the activity of parasympathetic nerves increases, the heart rate will decrease accordingly. Therefore, by observing the changes of the autonomic nervous system Physiological signals can also understand a person's mental state.

In addition, a large number of experiments have confirmed that the blink mode has a certain correlation with the degree of fatigue, lack of attention, and stress, and these also reflect the mental state of the person. Therefore, by detecting the EO signal. Knowing the blink mode, for example, the number of blinks per unit time, and the blink speed, also helps to understand the mental state of the person. In general, the most common means of obtaining the blink mode is to measure the electro-oculogram, which is measured by the electro-oculogram. It is the corneo-retinal standing potential that exists in the anterior and posterior eyes of the eye. It can measure the position of the eyeball and the physiological changes of the eye movement, so that the activity of the eye can be known.

Traditionally, devices that use the detection of EEG signals or EO signals to monitor a person's mental state have been used. As mentioned above, in this way, a certain understanding of the mental state can be achieved. However, since only a single physiology is used. Signals, so there may be problems with less accurate judgments.

Therefore, if the physiological information can be referenced at the same time, the accuracy of the detection result can be effectively improved. For example, when the EEG signal is obtained, the EEG signal is also referred to to know the user's eye activity. Or simultaneously analyze the state of brain waves and autonomic nervous activity to increase the accuracy of the judgment through multiple indicators. In addition, if the start time of the marker detection can be matched, for example, when entering the driving period, start the spirit. State detection, The judgment result will be provided more accurately.

On the other hand, since the detection of mental state is usually applied during normal daily work, for example, during driving, in addition to providing accurate judgment results, the physiological sensing elements for obtaining physiological signals are set. It is also very important for the user.

As can be seen from the above, most of the physiological signals used to determine the mental state can be obtained by the head, for example, EEG signals, EO signals, and heart rate information that can be used to obtain the state of autonomic nervous activity, so how to not affect the use of The completion of the setting of the physiological sensing element in the case of working will determine the user's acceptance of the monitoring device.

In recent years, glasses have no longer been limited to wearing by myopia patients, and have gradually become decorative accessories. They are common and frequently used accessories in daily life. Therefore, if glasses are used, it is not obvious, and the user's acceptance is large. The structure is also fully compatible with the position of the physiological sensing element for obtaining physiological signals such as EEG signals, EO signals, and heart rate information, and is therefore quite suitable.

In addition, in the case where the glasses structure can be used to achieve the acquisition of EO, EEG, and/or heart rate information, it can be further used as a brain computer interface (BCI), for example, through Detective The brain wave is analyzed to analyze the user's intention, and then converted into an operation command, or an instruction is given through an eye movement, and in recent years, such a brain-computer interface has been widely used in virtual reality. Glasses (Virtual Reality Glasses) and smart glasses (Smart Glasses) are gradually becoming popular in everyday life.

Therefore, it would be advantageous to provide a spectacle device that determines the mental state by detecting multiple physiological signals.

An object of the present invention is to provide a wearable mental condition monitoring device that simultaneously detects multiple physiological signals as a basis for judging a mental state.

Another object of the present invention is to provide a glasses-type mental state monitoring device, which simultaneously uses an electroencephalogram signal and an electro-oculogram as a basis for judging a mental state.

Another object of the present invention is to provide an eyeglass-type mental condition monitoring device that simultaneously acquires an electroencephalogram signal and an electro-oculogram signal during wearing of the eyeglass structure through a pair of electrodes disposed in a pair of eyeglasses.

Another object of the present invention is to provide a glasses-type mental state monitoring device, which simultaneously uses heart rate information and an EO signal as a basis for judging a mental state.

Another object of the present invention is to provide a glasses-type mental state monitoring device that obtains heart rate information and an EO signal during wear of the eyeglass structure through at least two electrodes disposed in a spectacles structure and a light sensor.

Another object of the present invention is to provide a wearable physiological monitoring device that utilizes a spectacles structure and at least one ear-wearing structure to provide at least two physiological sensing elements to obtain at least one physiological signal during wear.

10,20,50,52‧‧‧electrodes

54‧‧‧Light sensor

1 is a perspective view of a spectacles-type mental condition monitoring device according to a preferred embodiment of the present invention; and FIG. 2A-2D is a view showing a possible embodiment of a spectacles-integrated physiology monitoring device according to a preferred embodiment of the present invention; FIG. A schematic view showing the inner structure of the auricle; and FIG. 4 is a schematic view showing the position of the cerebral cortex in the skull and the position of the auricle; Figures 5A-5C show possible embodiments of a physiological monitoring device in the form of a pair of eyeglasses in accordance with a preferred embodiment of the present invention.

The wearable physiological monitoring device according to the present invention mainly comprises a processor, a glasses structure, a plurality of physiological sensing components, an information providing interface, and a physiological signal capturing circuit, wherein the glasses structure is used to set the device to a user's head such that the physiological signal capture circuit can obtain the physiological signal of the user through the plurality of physiological sensing components, so that the processor can determine the user's Information about the state of mind and related mental state can be provided to the user through the information providing interface.

Generally, when the glasses are worn, the position where the glasses frame will naturally contact, including, but not limited to, the nose pads will contact the bridge of the nose and/or the area between the eyes, the frame will contact the area around the eyes, and when the frame is in the area between the eyes When there is a protrusion, the mountain root can be contacted, and the temples can contact the skull skin near the auricle, for example, the skull skin near the temple and/or above the auricle, and also the V-shaped depression between the auricle and the skull, and Touching the skin on the back of the auricle, it is a convenient choice to simultaneously achieve the setting of the physiological sensing element at these locations by the action of the wearing eyeglass structure.

However, it should be noted that the spectacles structure described in the present invention means that there are two temples and a frame, which are disposed on the head by the auricle and the nose as support points, and The wear structure of the skin of the head and/or the ear is not limited to the general eyeglass structure, and includes deformation thereof. For example, it may be a structure having a clamping force on both sides of the skull, or may further extend to the brain. After that, or alternatively, it can be implemented in the form of asymmetrical sides of the temples. For example, one side of the temple has a curved portion behind the auricle, and the other side has no bending. The curved portion is only placed above the auricle, and may or may not have a lens. Therefore, there are various possibilities and no limitation.

In addition, in the selection of materials, in addition to the hard material of ordinary glasses, it can also be implemented as an elastic material, which not only increases the stability of the electrode/sensor setting, but also provides the use comfort. For example, the memory metal can be used. The flexible plastic material forms a spectacles structure, and/or elastic rubber, silicone rubber, etc. are used at the position of the physiological sensing component to achieve a more stable setting state, and are not limited.

Moreover, it is advantageous that, based on the structural characteristics of the spectacles structure, when it is determined that the user's mental state is not good, for example, when a predetermined value is met, the user is required to improve the mental state by issuing a reminder message. The reminder message used to remind the user can be achieved naturally, that is, the information providing interface can be implemented to be combined with the eyeglass structure, for example, by means of a lens display, for example, light guiding To the lens to exhibit a color change, or to implement the lens as having a display function, etc.; or, to provide a light-emitting element in the vicinity of the eye, and to achieve a reminder effect by, for example, flashing light; or, by touching the structure of the eyeglasses with the skin The vibration module is disposed at a position to generate vibration; or, the sounding element may be disposed near the position where the temple is close to the ear, or may be implemented to extend the earphone by the temple to be reminded by sound and voice, and in particular Yes, the sounding element/earphone used can be in the form of bone conduction, in addition to the common air conduction form. For example, the bone conduction speaker may be directly disposed at a position where the temple is in contact with the skull, or the bone conduction earphone may be extended from the temple. Alternatively, the vibration module may be disposed in the earphone without limitation.

Of course, it can also be implemented to provide the judged mental state to the user immediately through the information providing interface. For example, the mental state can be digitized and digitally Display, or, can use the color change, vibration size, sound size, etc. to express the current state of mind, without limitation.

According to another aspect of the present invention, the eyeglass type device according to the present invention can also be implemented to communicate with an external device, for example, a wired or wireless device such as a headphone jack or a Bluetooth device, and an electronic device such as a smart phone or a tablet computer. The device communicates, in which case there will be more implementation options.

For example, in a preferred embodiment, the physiological signal obtained by the physiological sensing component can be transmitted to the external device, and the external device analyzes the mental state according to the received physiological signal. Information about the state of mind and a reminder message when a reminder is issued to the user, that is, the user is provided through the information providing interface of the external device; or, in another preferred embodiment, The device on the body transmits the mental state information and/or the reminder message to the external device, and the information providing interface of the external device provides the related mental state information and/or reminder message to the user, wherein the external device is also There are no restrictions on the provision of information and/or information to users through the form of tactile, audible, or visual signals.

Further, further, in the case of communicating with the external device, if the device according to the present invention is implemented to have a sounding element (air conduction or bone conduction type) and a sound pickup element, it can be used as a hands-free part of the external device. The earpiece is used for talking; and further, by providing a vibration module, a sounding element (air conduction or bone conduction type), a display element, and a light emitting element, etc., the device according to the present invention can be further implemented as the external The information providing interface of the device, for example, is used to provide call reminders, message notifications, etc., and is more integrated into the daily life of the user, and the information can be provided through various modes such as sound, vibration, illumination, and lens display. There are various possibilities.

Next, an embodiment in which the spectacles structure is used as a main wearing structure to obtain physiological information for judging a mental state will be described.

In a preferred embodiment, the present invention determines the mental state of a person by simultaneously detecting the brain electrical signal and the eye movement signal. The combination is selected based on the frequency of the brain wave to understand whether the user is mentally concentrated or In the relaxed state, if the eye movement signal can be used to confirm the user's eye activity status, it will help to determine that the user is not at rest. In addition, the eye-electric signal can also provide information about the user's blink mode. In this way, the user's mental state can be judged more accurately.

Please refer to FIG. 1 , which is a schematic view of a spectacles-type physiological monitoring device according to the present invention. As shown, an electrode 10 is disposed at a position where a pair of temples contact the auricle, and a region near the inter-ocular region of the frame has a The electrode 12, and in such a configuration, since the position of the electrode 12 is located between the eyes, the EEG signal and the EO signal can be obtained in the case where only two electrodes are arranged, and, because of the EEG signal And the EO signal has different signal characteristics. Therefore, the signal processing method can separate the two. After analyzing the obtained EEG signal, the current brain wave frequency can be known and obtained through analysis. The eye-eye signal can obtain information such as the number of blinks per user time and/or the speed of blinking.

Accordingly, two physiological signals for judging the mental state can be simultaneously obtained in a case where only at least two electrodes are required, which not only greatly reduces the complexity of setting the physiological sensing component, but also maximizes the use efficiency. It is quite advantageous, and through this design, users can easily monitor their mental state by simply wearing glasses, which is quite convenient.

Here, it should be noted that although the figure shows that there is electricity only on one side of the temple The pole 10, but can also be implemented as electrodes on both sides of the temple, and the contact position of the electrode 10 can also be implemented in other positions, for example, contact with the skull skin near the auricle of the temple, or when the temple is extended In the form of the posterior brain, the electrode can be placed in contact with the position of the occipital bone behind the brain. Therefore, there is no limitation; in addition, the electrode 12 can also be directly placed on the nose pad or the frame can be in contact with the position around the eye. no limit.

Next, in another preferred embodiment, the present invention utilizes both ocular electrical signals and heart rate information as a basis for determining mental state.

The reason for using these two kinds of physiological information is that in addition to the eye-eye signal analysis, the heart rate information can be analyzed, and many physiological information representing the mental state can be obtained. For example, analyzing heart rate information can be obtained. HRV (Heart Rate Variability) and autonomic nervous activity information. It is known that when the mental state is in tension and concentration, it will correspond to high sympathetic activity, and when the mental state is relaxed, it will correspond to high parasympathetic activity. Therefore, the sympathetic and parasympathetic activities can be obtained by performing HRV analysis to determine the mental state of the user. For example, a frequency domain can be performed to obtain a total power that can be used to estimate the overall heart rate variability. (Total Power, TP), which can reflect the high frequency power (HF) of parasympathetic activity, and can reflect the sympathetic nerve activity, or the low frequency power (LF) of the simultaneous regulation of sympathetic and parasympathetic nerves. And LF/HF (low HF power ratio) that can reflect the balance of sympathetic/parasympathetic activity In addition, after performing the frequency analysis, the degree of harmony of the operation of the autonomous nerve can be known by observing the state of the frequency distribution, or the time domain analysis (Time Domain) can be performed to obtain the overall heart rate variability. The indicator of SDNN, which can be used as an indicator of long-term overall heart rate variability, can be used as an indicator of short-term overall heart rate variability. RMSSD, and R-MSSD, NN50, and PNN50, which can be used to estimate high-frequency variation in heart rate variability; in addition, RSA (Respiratory Sinus Arrhythmia) information can be obtained by analyzing heart rate information. Pushing the user's breathing situation, in which the respiratory rate will also become lower when the mental state is relaxed, fatigued, and lethargic, so it can be used as a basis for judgment. In addition, the heart rate is controlled by the autonomic nervous system. A decrease in heart rate during relaxation, fatigue, and sleepiness. Therefore, by combining brain wave frequency and heart rate information, it can also help to more accurately judge the user's mental state.

As for how to obtain the heart rate information, since the physiological sensing element is preferably disposed through the eyeglass structure, the present invention employs a light sensor, where the light sensor means having a light emitting element and a light receiving element. And a sensor that obtains an optical signal by using the principle of PPG (photoplethysmography), for example, by using a penetrating method or a reflection method to obtain a blood physiological signal of the user, so that it is further known by analyzing a continuous pulse change. User's heart rate information.

The position of the photo sensor may be a position on the structure of the lens that will contact the head and/or the ear, for example, a bridge of the nose, a mountain root, an area between the eyes, a V-shaped recessed area around the eyes, between the auricle and the skull, and an ear. The head near the profile, and the back of the auricle, etc., are not limited as long as the blood physiological signal can be stably obtained while the eyeglass structure is being worn. Further, it may be disposed near the electrode or combined with the electrode. In order to minimize the position of the physiological sensing component, the convenience of use is increased.

As for the position of the electrodes, only one of the electrodes is disposed on the bridge of the nose, the root of the mountain, the area between the eyes, or the area around the eyes. The position of the other electrode is not limited, and may be the bridge of the nose, the root of the mountain, and the area between the eyes. , around the eyes, the V-shaped recess between the auricle and the skull, Any of the skull near the auricle, the back of the auricle, and the occipital region, for example, may have two electrodes disposed between the eyes, around the eyes, or the bridge of the nose, or there may be one electrode away from the eyes, without limitation. Here, in particular, in this embodiment, when the position of the electrode is suitable, the brain signal can be obtained while obtaining the eye movement signal, so that one more item can be added to judge the mental state. The physiological signal helps to further improve the accuracy of the judgment results.

Further, in addition to the spectacles structure, the device according to the invention is also advantageous in that it can be used in conjunction with the spectacles structure and the ear-wearing structure to provide a physiological sensing element.

As shown in Figures 2A-2D, an ear-wearing structure, such as an earplug or ear clip, can be extended from the spectacles structure to be placed on the auricle, and the connection between the ear-wearing structure and the spectacles structure can be variously selected. For example, a connection line (as shown in Figure 2B), a connector (as shown in Figure 2C), or a structure with adjustable distance (as shown in Figure 2A) can be used to accommodate different The user, or alternatively, can be embodied in the form of a two-sided earplug (as shown in FIG. 2D), which is a possible embodiment. Furthermore, the connection between the earwear structure and the eyeglass structure can be implemented as a mechanical They can be combined and/or electrically connected to each other, for example, through a connector, and the ear-wearing structure can be further implemented in a removable form, all without limitation, and can be changed according to actual needs.

The advantage of this approach is that since the auricle is also a known EEG sampling point and a photosensor set point, in addition to the same through the ear-wearing structure, the physiological sensing element can be provided to achieve the desired In addition to the physiological signal, further fixation can be obtained by providing the ear wearing structure, for example, the earplug has an abutting force with the inner surface of the auricle, and the ear clip has a clamping force, and is fixed to the auricle through the extension. Ear-wearing structure, the lens structure may be issued during wear The movement of life can also be subject to certain restrictions.

In addition, it is also advantageous that the ear-wearing structure can be implemented in combination with an earphone, for example, an air-conducting earphone or a bone-conduction earphone, so that information and/or reminder information about the mental state can be directly transmitted through the earphone. Provided to the user, for example, through the voice, voice, that is, the headset as a information providing interface; and further, the earwear structure can also be implemented to have a vibration module to achieve information transmission through vibration And/or the effect of the reminder, therefore, there is no limit.

According to another aspect of the present invention, the eyeglasses and the ear-worn device according to the present invention can also be implemented to communicate with an external device, for example, a wired jack or a Bluetooth device such as a headphone jack or a Bluetooth device, and a smart phone. If computers and other electronic devices communicate, then in this case, there will be more implementation options.

For example, in a preferred embodiment, the physiological signal obtained by the physiological sensing component can be transmitted to the external device, and the external device analyzes the mental state according to the received physiological signal. Information about the state of mind and a reminder message when a reminder is issued to the user, that is, the user is provided through the information providing interface of the external device; or, in another preferred embodiment, The device on the body transmits the mental state information and/or the reminder message to the external device, and the information providing interface of the external device provides the related mental state information and/or reminder message to the user, wherein the external device is also There are no restrictions on the provision of information and/or information to users through the form of tactile, audible, or visual signals.

Furthermore, further, in the case of communication with the external device, the device according to the invention is embodied as having a sounding element (air conduction or bone conduction) and a sound element The piece (which can be located on the ear-wearing structure or the eyeglass structure) can be used as a hands-free earpiece of the external device for talking; and further, by providing a vibration module, the sounding element (air conduction or bone conduction) And a display element, and a light-emitting element or the like (which may be located on the ear-wearing structure or the eyeglass structure), the device according to the present invention may further implement an information providing interface as the external device, for example, for providing an incoming call reminder, a message notification In addition, it is more integrated into the daily life of the user. As for the provision of information, there are various possibilities such as sound, vibration, illumination, and lens display.

Moreover, by increasing the ear-wearing structure and making the setting of the physiological sensing component more diverse, the user can further select a form more suitable for himself according to actual needs.

Here, special attention should be paid to the special position of the electrode on the auricle. Please refer to the auricle (also known as pinna) structure shown in Figure 3, in which the inner ear of the auricle (superior concha) And around the inferior concha, there is a concha floor (ie, parallel to the plane of the skull) that is connected upwards to a vertical area of the antihelix and the antitragus. Known as the concha wall, the natural physiological structure of the ear provides a continuous plane perpendicular to the bottom of the ear, and, immediately below the wall of the ear, between the tragus and the tragus An intertragic notch, as well as an adjacent tragus, also provides a contact area perpendicular to the bottom of the ear.

During the experiment, it was found that the continuous vertical area consisting of the ear wall, the tragus between the tragus, and the tragus was not only sufficient for the EEG signal strength to be analyzed, but also for brain activity information. More advantageously, when this area is used as the electrode contact position, the force required to fix the electrode will be parallel to the force of the bottom of the ear, especially when implemented as an earplug, through the earplug and the inner surface of the auricle. The abutting force between the bulge and the depression, Naturally, stable contact between the electrode and the vertical region can be achieved at the same time.

In addition, the experiment also found that the intensity of the EEG signal obtained on the back of the auricle is also sufficient to carry out relevant EEG signal analysis and provide information on brain activity, and this contact position is suitable for glasses. In general, when the form of glasses is used, the V-shaped depression between the auricle and the skull and/or the upper part of the skin on the back of the auricle is the position where the temples are in contact, and if the end of the temple is curved When it is enlarged, it can contact the skin on the lower part of the back of the auricle, and the stable contact of the electrode can be naturally achieved.

Furthermore, please refer to Fig. 4, which is a schematic diagram of the position of the cerebral cortex in the skull and the position of the auricle. It can be seen from the figure that the cerebral cortex falls on the upper part of the skull and the auricle is on both sides of the skull. And prominently outside the skull, wherein, roughly speaking, separated by the ear canal, the position of the upper auricle falls on the side of the cerebral cortex, while the inner part of the skull corresponding to the lower auricle has no cerebral cortex.

In the experimental results, it was found that a good brain wave signal can be measured in the upper part of the auricle part, and the lower the EEG signal is, the lower the physiologic structure of the head is, it is because the upper auricle is The corresponding internal part of the skull is the position of the cerebral cortex. Therefore, in this case, the brain wave can be measured in the upper part of the auricle through the transmission of the skull and the ear cartilage, and the lower auricle is far away from the cerebral cortex. In addition, the interval between the ear canal is weakened. Therefore, the lower the EEG signal strength becomes weaker, and the earlobe is considered to be a very weak position of the EEG signal in the field of EEG detection. In the present invention, when the auricle (inner surface and back surface) is used as the electroencephalogram signal sampling position, in principle, the ear canal is used as a boundary, and the upper auricle portion is regarded as a position at which the electroencephalogram signal can be measured, which is suitable for setting an activity. The electrode is detected, and the lower auricle is considered to be a weak position of the EEG signal, which is suitable for setting the reference electrode.

The following is an example of how to set the physiological sensing element through the lens structure and the ear wearing structure, and obtain multiple physiological signals.

First, in a preferred embodiment, the two electrodes are respectively disposed on the inter-ocular area of the eyeglass structure and the ear-wearing structure, for example, on the nose pad, and on the earplug, so that the configuration can be At the same time, the EEG signal and the EEG signal are obtained. In this case, if it is necessary to obtain the heart rate information, the photo sensor may be disposed on the lens structure or the earwear structure, and may be implemented to be combined with the electrode. Together, either placed near the electrode or placed in a different location, there is no limit. Therefore, in the case where the eyeglass structure does not have a light sensor and no physiological signal can be obtained, the setting of the electrophysiological signal (and heart rate information) can be achieved by combining the upper ear wearing structure, if the eyeglass structure is already set. When there is a light sensor, the whole device is upgraded to obtain an electrophysiological signal by combining the upper ear wearing structure.

In another preferred embodiment, the two electrodes are disposed on the spectacles structure, for example, at the position of the temples, the head near the auricle, the V-shaped depression between the auricle and the skull, and the ear. The back of the profile is either placed on the nose pad to contact the bridge of the nose or placed on the frame to contact the area between the mountain roots, between the eyes, or around the eyes, and then the light sensor is placed on the earwear structure, for example Provided on the inner surface of the auricle through the earplug or on the earlobe through the ear clip, and the advantage of this method is that when the earwear structure is implemented in a removable form, it is provided when needed Then connect the ear wearing structure to increase the choice of another physiological signal detection. Since the light sensor is in the heart rate information, by wearing or not wearing the ear wearing structure, it is equal to whether the heart rate needs to be detected. Information, so the user can change the configuration of the physiological sensing component according to his own needs, which is quite convenient.

Furthermore, according to the above experimental results, even inside the same auricle, The electroencephalogram signal can also be obtained by arranging the electrodes separately in the upper half and the lower half of the ear canal. As shown in FIG. 5A, two electrodes 50, 52 can be simultaneously disposed on the earplug structure. Therefore, the EEG signal can be obtained even through a single ear-wearing structure. In this case, the photo sensor can be disposed on the eyeglass structure, for example, on the glasses on the same side as the earplug, or on the nose. On the mat, it is a very convenient implementation.

In addition, the photo sensor can be directly disposed on the ear wearing structure at the same time. For example, as shown in FIG. 5B, the same earplug has two electrodes 50, 52 respectively contacting the upper part of the inner surface of the auricle and The lower portion, and a position where the light sensor 54 contacts the bottom of the ear, or as shown in FIG. 5C, provides two electrodes 50, 52 contacting the back of the auricle through an ear-worn structure sleeved on the temple. And a light sensor 54 that contacts the skull, or, in a form similar to the 2D image, an electrode and a light sensor are disposed on one side of the earplug, and another electrode is placed on the other side of the earplug, and then through the two sides The temples are fixed on both sides of the earplugs, which is also a convenient way.

In this way, the user is provided with the option of supporting the ear-wearing structure by using the self-contained eyeglass structure. As shown in FIG. 5C, the effect of obtaining multiple physiological signals can be achieved without changing the glasses. It is a fairly advantageous implementation.

In addition, the ear-wearing structure and the eyeglass structure can also be electrically connected to each other, for example, through the connector to achieve electrical connection. In this case, if the form is as shown in FIG. 2D, the connection circuit between the two earplugs can be further disposed. In the eyeglass structure, or the earplug structure as shown in FIG. 5A-5B is implemented to be electrically connected to the eyeglass structure, in this case, the eyeglass structure can be implemented as a message providing interface, for example, the user needs to lift the spirit. The generated reminder message can be provided through the glasses, for example, the color change can be provided by the lens, or the message can be displayed, or the hair can be made by the structure of the glasses. Light-emitting elements, etc., are also convenient and advantageous choices.

On the other hand, in addition to being implemented as two electrodes, the device according to the present invention may further have a third or more electrodes, and the method of adding electrodes may allow the acquisition of electrophysiological signals and the use of the device. A further option, wherein the additional electrode can be implemented together with the original two electrodes to obtain an electrophysiological signal to increase the type of electrophysiological signal that can be obtained, or to increase the position at which the electrophysiological signal is obtained, or can be implemented In order to replace the original electrode, to change the type of the electrophysiological signal obtained, or to change the position of the obtained signal, and the additional electrode can be disposed on the eyeglass structure or the ear wearing structure, which is not limited, and can be used according to the needs of use. change.

As for the embodiment of the additional electrode, there are many options. For example, an electrode may be additionally connected to the eyeglass structure or the ear wearing structure through a connecting port, or may be disposed in the eyeglass structure or the earwear structure. One of them is connected to another structure along with the structure. In this case, the connection between the two structures is implemented as an electrical connection, or alternatively, it may be implemented as an optical structure and/or The ear is worn on the structure, but is selected by switching. For example, it can be switched between when all the electrodes are enabled together and one of the electrodes is disabled. As for how to switch, there are many possibilities, for example, can be implemented. In order to switch the switch manually, the switching can be achieved through the plugging action of the connector, or the switching can be achieved through the mechanical action of the two structures, and the switching can be achieved through the circuit control without limitation. .

Wherein, when the form of the connector is used, for example, in the case where the earphone jack is electrically connected between the eyeglass structure and the ear wearing structure, the internal electrical connection of the connector can be realized by the action of insertion. Change, and then complete the switching of the electrodes, is the phase When it is suitable and convenient.

For example, in the case where the spectacles structure already has two electrodes, a third electrode can be added by the ear-wearing structure. In a preferred embodiment, if the original electrode configuration on the spectacles structure is only an eye obtainable In the case of an electrical signal, the electrode on the ear-wearing structure can be implemented to replace one of the electrodes, for example, instead of an electrode disposed between the two eyes or around the eye, and change to obtain only the EEG signal, or change to simultaneously Obtaining an EOG signal and an EEG signal; or, in another preferred embodiment, the electrode on the ear-worn structure is combined with the original electrode for electrophysiological signal extraction, for example, the electrode on the original spectacles structure is set In the occipital region behind the brain, the electroencephalogram signal of the temporal lobe area beside the ear can be obtained through the electrode provided by the ear wearing structure; or, in another preferred embodiment, if the electrode configuration on the lens structure is already If the EEG signal can be obtained, the sampling position of the EEG signal can be changed by replacing the electrode on the ear structure with one of the electrodes, for example, changing from the sampling position of the original occipital region to 颞Sampling location area. Therefore, there may be various possibilities without limitation. Moreover, in the above case, the photo sensor may be implemented to be located on the spectacles structure or in the erectile structure, which is a possible embodiment.

In addition, in the case where the ear wearing structure already has two electrodes, the effect of adding the electrodes can be achieved by connecting the eyeglass structure. For example, the ear wearing structure has two electrodes as shown in FIG. 5A. The EEG signal can be obtained by electrically connecting the electrodes on the structure of the glasses, for example, the electrodes located around the eyes, so that the eye movement signal can be obtained or the electrodes on the other side of the glasses can be obtained. The whole brain activity, not the EEG signal in the temporal region near the ear-wearing structure, or the EEG signal obtained through the temples extending to the back of the brain, can be set according to the electrode on the lens structure. There are various possibilities for the position; in addition, if there is no light sensor on the ear wearing structure, the heart rate can also be obtained by connecting the eyeglass structure. News.

Furthermore, further, based on the form of glasses (and the ear-wearing form), the device is excellent in ease of use, and the device according to the present invention can also be used merely for physiological signal monitoring, for example, by adding a switch. Allows the user to manually select to perform mental state monitoring or perform physiological signal monitoring to further increase the use of benefits. For example, by analyzing heart rate information, information about cardiovascular activities can be provided, while glasses forms (and ear wear forms) provide Continuously obtaining a good wearing form of heart rate, therefore, even when there is no need for mental state monitoring, the device of the present invention can be used for physiological monitoring to achieve a multi-purpose effect; and, such a selection action is equivalent to confirming that the device is positive. The mode of mental state monitoring can help to optimize the judgment of mental state.

In addition to obtaining the above-mentioned EEG signals, EOG signals, and heart rate information, the device of the present invention is also suitable for obtaining an electrocardiogram signal by means of a spectacles structure and an ear-wearing structure, for example, in glasses. An electrocardiographic electrode is disposed at a position where the structure or the ear-wearing structure is in contact with the head and/or the ear, for example, in the earplug, or in the position where the temple is in contact with the V-shaped recess, or in the frame and the bridge of the nose, the root of the mountain, or the periphery of the eye. The position of the contact, after which an electrocardiographic electrode is disposed on an outer surface of the eyeglass structure or the earwear structure, for example, the outer surface of the earplug or the outer surface of the temple, in such a manner that the user can simply It is quite convenient to obtain an electrocardiographic signal by the action of the upper limb, for example, the hand, contacting the exposed electrode, and further, the electrocardiographic electrode in the spectacles structure or the ear-worn structure can be further implemented as an electroencephalogram electrode Sharing, that is, using one of the electrodes as the electroencephalic electrode and the electrocardiographic electrode at the same time, in addition to the reduction in manufacturing cost and complexity, The desired position of the contact increases convenience in use.

Here, it should be noted that after the experiment, it is known that the body part contacting the exposed electrode has a considerable influence on the signal quality. Among them, when the left upper limb touches the exposed electrode, the quality of the obtained electrocardiogram signal is excellent. The signal obtained by contacting the right upper limb, especially the electrode contacting the left half head and the left upper limb respectively has the best signal quality. Therefore, when performing ECG measurement, it is preferable to use the left upper limb to contact the exposed electrode to Avoid poor signal quality due to contact with the right upper limb, which may lead to misjudgment in the analysis.

In addition, since the device according to the present invention acquires multiple physiological signals by being worn on the head, it is also suitable for use as a brain-computer interface, and the detected physiological signals mainly include brain electric signals, ocular signals, and heart rate information. In this case, there are several possible ways in which instructions can be generated.

For example, but not limited to, the user can change the focus or relaxation state by actively adjusting his own consciousness, thereby affecting the ratio between the alpha wave and the beta wave, and using this as a basis for generating instructions; The action of the eye produces instructions, such as short blinks, long blinks, continuous blinks, left turn or right turn, to make different commands; further, because breathing is a physiological activity that the human body can control, Breathing can affect heart rate (that is, the so-called Respiratory Sinus Arrhythmia (RSA)). Therefore, it can be used as a basis for generating instructions by changing the breathing behavior pattern. For example, the user can simply pass through Deliberately pull the period of inhalation and give instructions, or you can increase the heartbeat variability by deepening the breathing, and then increase the effect of the RSA amplitude, as a basis for issuing instructions, so there is no limit.

In addition, further, when the motion sensing element is mated, for example, an accelerometer, there may be more instructions for issuing instructions, for example, when the various physiological phenomena described above can be coordinated. By turning up and down, turning the head left and right, you can combine more types of commands to make the application wider.

Moreover, these methods of generating instructions can achieve the effect of correctly issuing instructions after a certain training and learning. Whether it is applied to the fields of operating computers, virtual reality glasses, or smart glasses, it is quite advantageous.

In summary, the wearable mental condition monitoring device according to the present invention is worn on the head through the eyeglass structure, and can obtain multiple physiological signals, which is advantageous for increasing the accuracy of determining the mental state, and is also suitable for use on weekdays. The physiological monitoring has the function of multi-purpose, and further, in the case of further combining the structure of the glasses and the structure of the ear, it can also provide multiple physiological signals to obtain the selection, and is more effective.

10‧‧‧ electrodes

12‧‧‧ electrodes

Claims (32)

A wearable physiological monitoring device for detecting a mental state of a user, comprising: a spectacles structure having two temples and a frame, and being disposed on the user's head through the user's auricle and nose a first electrode disposed on the frame of the eyeglass structure; a second electrode disposed on a temple of the eyeglass structure; and a physiological signal capturing circuit for transmitting the first electrode and the second electrode Acquiring an EEG signal and an EEG signal, wherein the first electrode participates in the acquisition of the EEG signal, and the second electrode participates in the acquisition of the EEG signal; wherein the EEG signal and the EEG signal are used A mental state of the user. The device of claim 1, wherein the first electrode is implemented to contact one or more of the following positions of the user, including: a bridge of the nose, a mountain root, an area between the eyes, and an area around the eye. The device of claim 1, wherein the second electrode is configured to contact one or more of the following positions of the user, including: abdomen back, auricle and cranial V-shaped depression, auricle The nearby skull skin, as well as the occipital region. The device of claim 1, wherein the mental state comprises a degree of fatigue, a degree of concentration, and a degree of waking. The device of claim 1, further comprising a sounding component disposed on or connected to the eyeglass structure, and the sounding component is an air conduction sounding component or a bone conduction sounding component. The device of claim 5, further comprising a sound collecting component disposed on the eye The mirror structure is coupled to the lens structure and is configured to communicate with an external device to provide a call function for the external device. The device of claim 1, further comprising an information providing interface for providing one or more of the following to the user, including: an electroencephalogram signal, an EO, and the mental state. The device of claim 7, wherein the mental state is used as a basis for generating a reminder message, and the reminder message is implemented to be provided to the user through the information providing interface. The device of claim 8, wherein the reminder message is implemented in one or more of the following forms, including: a tactile message, an audible message, and a visual message. The device of claim 1, wherein the device is configured to communicate with an external device, and the external device has an information providing interface to provide one or more of the following to the user, including : EEG signals, eye signals, and the state of mind. The device of claim 10, wherein the mental state is used as a basis for generating a reminder message, and the reminder message is implemented to be provided to the user through the information providing interface. The device of claim 1, further comprising a light sensor disposed on the eyeglass structure for obtaining heart rate information from the head and/or the auricle of the user. The device of claim 12, wherein the electroencephalogram, the electro-oculogram, and the heart rate information are used to derive the mental state. The apparatus of claim 1, wherein the mental state is used as a basis for determining an operational command for an external device. A wearable physiological monitoring system for detecting a mental state of a user, comprising: a wearable physiological monitoring device, comprising: a glasses structure having two temples and a frame, and passing through the user's auricle and a nose is disposed on the head of the user; a first electrode is disposed on the frame of the eyeglass structure; a second electrode is disposed on a temple of the eyeglass structure; and a physiological signal capturing circuit transmits The first electrode and the second electrode obtain an EEG signal and an EEG signal, wherein the first electrode participates in the acquisition of the EEG signal, and the second electrode participates in the acquisition of the EEG signal; and an external device, Receiving the EEG signal and the EEG signal to obtain a mental state of the user by analyzing the EEG signal and the EEG signal. The system of claim 15, wherein the external device further comprises an information providing interface for providing one or more of the following to the user, including: an electroencephalogram signal, an EO, and the Mental state. The system of claim 16, wherein the external device further generates an alert message by analyzing the mental state, and the alert message is implemented to be provided to the user through the information providing interface. A wearable physiological monitoring device includes: a plurality of physiological sensing elements; a lens structure disposed on a head of the user through a user's auricle and nose, and having a physiological sensing element disposed thereon; An ear-wearing structure electrically connected to the spectacles structure and disposed on at least one of the auricles of the user And having another physiological sensing component disposed thereon; and a physiological signal capturing circuit for obtaining at least one physiological signal from the head and/or the ear of the user through the at least two physiological sensing components. The device of claim 18, wherein the plurality of physiological sensing elements are implemented as one or more of the following, including: an electrode, and a light sensor. The device of claim 19, wherein the electrode located on the spectacles structure is configured to contact one or more of the following positions, including: the back of the auricle, the auricle and the cranial V-shaped depression, the auricle Nearby skull skin, occipital region, bridge of the nose, roots of the mountains, areas between the eyes, around the eyes, and an upper limb. The device of claim 19, wherein the electrode on the ear-wearing structure is implemented to contact one or more of the following positions, including: in the ear canal, the ear canal, the bottom of the ear, and the ear wall , tragus, between the tragus, the earlobe, and an upper limb. The device of claim 18, wherein the ear-wearing structure is implemented as an earplug structure or an ear clip structure. The device of claim 18, wherein the plurality of physiological sensing elements are implemented as at least two electrodes. The device of claim 23, wherein the physiological signal is one or more of the following, including: an electroencephalogram signal, an ocular electrical signal, and an electrocardiogram signal. The apparatus of claim 18, wherein the plurality of physiological sensing elements are implemented as at least two electrodes and a light sensor, and the light sensor is configured to obtain heart rate information of the user. The device of claim 25, wherein the at least two electrodes are disposed in the eye The mirror structure, and the light sensor is disposed on the earwear structure; or wherein the at least two electrodes are disposed on the earwear structure, and the light sensor is disposed on the eyeglass structure; or wherein At least two electrodes are respectively disposed on the eyeglass structure and the earwear structure, and the light sensor is disposed on the eyeglass structure or the earwear structure. The device of claim 18, further comprising a sound emitting component disposed on the earwear structure or the eyeglass structure, and the sounding component is an air conduction sounding component or a bone conduction sounding component. The device of claim 27, further comprising a sound pickup component disposed on the earwear structure or the eyeglass structure and configured to communicate with an external device to provide a call function for the external device. The device of claim 18, wherein the device is implemented as a brain-computer interface. The device of claim 18, wherein the device derives a mental state of the user based on the physiological signal. A wearable physiological monitoring device comprises: a plurality of physiological sensing components; a glasses structure having two temples and a frame, and is disposed on the user's head through a user's auricle and nose; The structure is connected to at least one of the temples of the eyeglass structure, and is disposed on at least one of the auricles of the user, and has at least one physiological sensing component disposed thereon; and a physiological signal capturing circuit The plurality of physiological sensing elements acquire at least one physiological signal from the head and/or the ear of the user. The device of claim 31, wherein the plurality of physiological sensing elements are One or more of the following, including: an electrode, and a light sensor.