CN114788681B - Intelligent wearable eye health instrument based on image acquisition and processing technology - Google Patents

Abstract

The invention provides an intelligent wearable eye health instrument based on image acquisition and processing technology, which comprises: the device comprises a supporting frame, a first acquisition device, a second acquisition device, an eye conditioning device and a data processor; the support frame is suitable for being worn on the eyes of a human body, the first collecting device, the second collecting device and the eye conditioning device are all positioned on the support frame, and when the support frame is worn on the eyes of the human body, the eye conditioning device corresponds to acupuncture points of the eyes of the human body; the first acquisition device is used for acquiring external environment data and sending the external environment data to the data processor; the data processor judges the scene type of the scene where the user is located according to the external environment data and controls the second acquisition device to acquire the eye data according to the scene type; and controlling the eye conditioning device to condition the eyes according to the eye data and the scene type. According to the eye fatigue state detection method, the eye fatigue state can be accurately judged by collecting and processing the eye image data, and the eyes can be adaptively conditioned according to the eye fatigue state.

Description

Intelligent wearable eye health instrument based on image acquisition and processing technology

Technical Field

The invention belongs to the technical field of image acquisition and processing, and particularly relates to an intelligent wearable eye health instrument based on an image acquisition and processing technology.

Background

With the coming of the information age, people use electronic products more and more frequently, and people suffering from asthenopia syndrome are more and more. Many products for relieving eye fatigue appear on the market, and an eye massager is one of the products. The eye massager is mainly used for massaging channels and collaterals and acupuncture points around eyes, and can dredge channels and collaterals, harmonize qi and blood, improve blood microcirculation of eyes, promote metabolism, improve the adjusting function of eyes, relieve asthenopia and prevent the development of myopia. However, the existing eye massage apparatus cannot accurately judge the fatigue state of the eyes, and cannot perform adaptive conditioning on the eyes according to the fatigue state of the eyes.

Disclosure of Invention

In view of this, the embodiment of the present invention provides an intelligent wearable eye health apparatus based on image acquisition and processing technology, so as to accurately determine the eye fatigue state and perform adaptive conditioning on the eyes.

The embodiment of the invention provides an intelligent wearable eye health instrument, which comprises:

the system comprises a supporting frame, a first acquisition device, a second acquisition device, an eye conditioning device and a data processor;

the support frame is suitable for being worn on the eyes of a human body, the first collecting device, the second collecting device and the eye conditioning device are all positioned on the support frame, and when the support frame is worn on the eyes of the human body, the eye conditioning device corresponds to acupuncture points of the eyes of the human body;

the first acquisition device is used for acquiring external environment data and sending the external environment data to the data processor;

the data processor is used for judging the scene type of the scene where the user is located according to the external environment data and controlling the second acquisition device to acquire the eye data according to the scene type; and controlling the eye conditioning device to condition the eyes according to the eye data and the scene type.

Optionally, the second acquisition device includes a light source array, a first camera and an electromyographic signal sensor; the light source array comprises light sources with different wave bands; the data processor is specifically configured to:

and controlling the light sources started in the light source array and the emission angles of the started light sources according to the scene type, and controlling the first camera and the electromyographic signal sensor to acquire eye data.

Optionally, the light source is a VCSEL light source, and a microlens array and an optical filter are disposed in front of the image sensor of the first camera.

Optionally, the data processor is specifically configured to:

inquiring a light source wave band and a light source angle corresponding to the scene type from a preset scene comparison table; the scene comparison table comprises light source wave bands and light source angles corresponding to various scene types;

controlling the light sources switched on in the light source array according to the light source wave band;

and controlling the emission angle of the light source switched on in the light source array according to the light source angle.

Optionally, the data processor is specifically configured to:

inputting the eye data into an eye fatigue state classification model corresponding to the scene type to obtain the eye fatigue state of the current user; the eye fatigue state classification model is pre-established, and each scene type corresponds to one eye fatigue state classification model;

and controlling the eye conditioning device to condition the eyes according to the fatigue state of the eyes.

Optionally, the eye conditioning device comprises a massager and a heater corresponding to the acupuncture points of the human eyes;

the data processor is specifically configured to:

according to the fatigue state of eyes, the massage force of the massager and the heating temperature of the heater are controlled so as to condition the eyes.

Optionally, the intelligent wearable eye health monitor further comprises:

the human-computer interaction device is used for receiving user information input from the outside;

the data processor is further used for storing the current user information, the scene type and the eye conditioning scheme after controlling the eye conditioning device to condition the eyes, so that when the user enters the scene of the same type next time, the corresponding eye conditioning scheme is directly taken to condition the eyes.

Optionally, the data processor is further configured to:

determining the user type of the user according to the user information, and initializing the functional mode of the correction instrument according to the user type; the functional modes comprise an eye conditioning mode, an eye disease detection mode, a fatigue driving detection mode and an eye use suggestion report generation mode;

under the eye conditioning mode, the rectification instrument conditions the eyes of the user;

in the eye disease detection mode, the data processor detects eye diseases of a user according to eye data and displays eye disease detection results through the human-computer interaction device;

in a fatigue driving detection mode, the data processor detects fatigue driving of the user according to the eye data and gives a fatigue driving warning to the user through the human-computer interaction device;

and under the eye use suggestion report generation mode, the data processor generates an eye use suggestion report of the user according to the eye data and displays the eye use suggestion report through the human-computer interaction device.

Optionally, the first collecting device comprises one or more of the following:

the second camera, attitude sensor, temperature sensor, humidity transducer, light intensity sensor, colour temperature sensor, baroceptor, range sensor and position sensor.

Optionally, the intelligent wearable eye health monitor further comprises:

a power supply device;

the power supply device is used for supplying power for the first acquisition device, the second acquisition device, the eye conditioning device and the data processor.

Compared with the prior art, the embodiment of the invention has the following beneficial effects:

when the correction instrument is worn, the first acquisition device acquires image data of an external environment and sends the image data to the data processor, the data processor judges the scene type of a scene where a user is located by analyzing and processing the image and adjusts the second acquisition device according to the scene type, so that eye data can be acquired more accurately; in addition, the correction instrument can also comprehensively analyze eye fatigue states by combining eye data and scene types to adjust and control the eye conditioning device, so that the eyes can be conditioned adaptively.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the embodiments or the prior art descriptions will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise.

Fig. 1 is a schematic structural diagram of an intelligent wearable eye health apparatus based on image acquisition and processing technology according to an embodiment of the present invention.

Detailed Description

In the following description, for purposes of explanation and not limitation, specific details are set forth, such as particular system structures, techniques, etc. in order to provide a thorough understanding of the embodiments of the invention. It will be apparent, however, to one skilled in the art that the present invention may be practiced in other embodiments that depart from these specific details. In other instances, detailed descriptions of well-known systems, devices, circuits, and methods are omitted so as not to obscure the description of the present invention with unnecessary detail.

In order to illustrate the technical means of the present invention, the following description is given by way of specific examples.

The embodiment of the invention provides an intelligent wearable eye health instrument, which comprises:

the device comprises a supporting frame, a first acquisition device, a second acquisition device, an eye conditioning device and a data processor.

In this embodiment, the supporting frame may be a frame as shown in fig. 1, or may be other devices capable of being worn on the eyes of a human body, such as a head-mounted fixing device. The first collecting device, the second collecting device and the eye conditioning device are all arranged on the supporting frame. The data processor can be arranged on the supporting frame or not, and can be connected with the first acquisition device, the second acquisition device, the eye conditioning device and other equipment in a wired or wireless mode to realize data transmission.

The first collecting means is a device for collecting external environmental information, and may be provided on the support frame at a position away from the eyes, for example, at the nose pad of the spectacle frame shown in fig. 1. The first acquisition device includes, but is not limited to, one or more of the following: the second camera, attitude sensor, temperature sensor, humidity sensor, light intensity sensor, colour temperature sensor, baroceptor, range finding sensor and position sensor (GPS/BD). The light intensity and the color temperature can also be obtained by data calculation through the image of the RGB camera.

The second collecting device is a device for collecting eye information, and as shown in fig. 1, two second collecting devices may be specifically provided, and correspond to the left and right eyes of the human body, respectively, so as to accurately collect the left and right eye information.

The eye conditioning device comprises but is not limited to a massager and a heater corresponding to the human eye acupuncture points, the human body is fed back through a thermal signal, an electric signal and a pulse signal, the human eye acupuncture points can be conditioned and massaged, the direct fatigue relieving and muscle relaxing is realized, the eye muscles are actively relaxed, the eyebrows are opened, the continuous capability and effect of the eye fatigue are indirectly realized, and the eye fatigue is effectively relieved.

The intelligent wearable eye health instrument further comprises a power supply device for supplying power to the first acquisition device, the second acquisition device, the eye conditioning device and the data processor.

The rectification apparatus mainly works in the following ways:

the first acquisition device acquires external environment data and sends the external environment data to the data processor;

the data processor judges the scene type of the scene where the user is located according to the external environment data and controls the second acquisition device to acquire the eye data according to the scene type; and controlling the eye conditioning device to condition the eyes according to the eye data and the scene type.

In this embodiment, the data processor may input each external environment data acquired by the first acquisition device into a classification model for classification, so as to obtain a scene type of a scene where the user is located. The scene can be divided into an indoor scene and an outdoor scene, the indoor scene can be further divided into a work/study scene, an entertainment scene, a living scene and the like, and the outdoor scene can be further divided into a driving scene, an aviation scene, an aerospace scene, a diving scene and the like. Aiming at different scenes, the eye data can be more accurately acquired by adaptively adjusting the second acquisition device. And eye fatigue conditions are analyzed by combining the eye data and scene types, and the massage force of the massager, the heating temperature of the heater and the like are adjusted, so that the adaptive conditioning on the eyes is realized.

Therefore, the correction instrument provided by the embodiment of the invention can acquire the image data of the external environment through the first acquisition device and send the image data to the data processor, the data processor judges the scene type of the scene where the user is located through analyzing and processing the image, and adjusts the second acquisition device according to the scene type, so that the eye data can be acquired more accurately; in addition, the correction instrument can also comprehensively analyze eye fatigue states by combining eye data and scene types to adjust and control the eye conditioning device, so that the eyes can be conditioned adaptively.

As a possible implementation manner, the second collecting device includes a light source array, a first camera, and an electromyographic signal sensor. The first camera may be a light field camera, an RGB camera, or the like. The light source array includes light sources of different wavelength bands, and the light sources include, but are not limited to, any one of a near infrared light source, an infrared light source, and a visible light source. The data processor is specifically configured to:

and controlling the started light source in the light source array and the emission angle of the started light source according to the scene type, and controlling the light field camera and the electromyographic signal sensor to acquire eye data.

As a possible implementation, the data processor is specifically configured to:

inquiring a light source wave band and a light source angle corresponding to the scene type from a preset scene comparison table; the scene comparison table comprises light source wave bands and light source angles corresponding to various scene types;

controlling the light sources switched on in the light source array according to the light source wave band;

and controlling the emission angle of the light sources turned on in the light source array according to the light source angle.

As a possible implementation manner, the light source is a VCSEL light source, and a microlens array and a filter are disposed in front of the image sensor of the first camera.

In the embodiment of the invention, the light source is a near infrared, infrared or color visible light source with spectral frequency domain characteristics. In view of the complexity, the tiny and the sensitivity of eyeball muscle tissues, the vision enhancement processing is realized by digitally sensing and acquiring the more easily sensed states and changes of the eye and face muscle tissues and controlling the light sources started in the light source array and the emission angles of the started light sources according to the scene types.

The first camera of the embodiment adds the micro-lens array in front of the image sensor, and can acquire the space and direction information of light while acquiring an image. The techniques may reconstruct images in a variety of ways, including multi-view acquisition, refocusing acquisition, and 3D image acquisition. However, optical crosstalk between the shadow caused by an external light source and the microlens in the environment causes the conventional camera to fail to provide high image contrast and an accurate 3D reconstructed image. And supplementary lighting is performed through a light source, for example, a VCSEL is used in a near infrared range to stabilize the 3D image reconstruction accuracy depending on ambient light, and when an external VCSEL light source irradiates a human face at angles of 0 °, 30 ° and 60 °, a 3D image reconstruction error can be reduced by 54%.

As a possible implementation, the data processor is specifically configured to:

inputting the eye data into an eye fatigue state classification model corresponding to the scene type to obtain the eye fatigue state of the current user; the eye fatigue state classification model is pre-established, and each scene type corresponds to one eye fatigue state classification model;

and controlling the eye conditioning device to condition the eyes according to the fatigue state of the eyes.

In the embodiment of the invention, the difference of the eye data under different scenes is considered. The invention establishes eye fatigue state classification models, such as neural network models, for a plurality of scenes. When a user is in a certain scene, fatigue identification is carried out on eye data through the classification model corresponding to the scene, and eye fatigue states including a healthy state, a light fatigue state, a severe fatigue state and the like can be judged more accurately.

As a possible implementation, the intelligent wearable eye health monitor further comprises:

and the man-machine interaction device is used for receiving user information input from the outside.

The data processor is further used for storing the current user information, the scene type and the eye conditioning scheme after controlling the eye conditioning device to condition the eyes, so that when the user enters the scene of the same type next time, the corresponding eye conditioning scheme is directly taken to condition the eyes.

In the embodiment of the invention, the human-computer interaction device can be a terminal such as a mobile phone and the like, can be connected with the data processor of the correction instrument, and can log in user information. The data processor can also store the eye conditioning schemes of the user in different scenes, and when the same user enters a certain scene subsequently, the data processor can directly call the existing eye conditioning schemes to condition the eyes.

As a possible implementation mode, the intelligent wearable eye health instrument can further comprise a voice prompter, the voice prompter can be arranged on one side or two sides of the intelligent wearable eye health instrument, and the working mode and the working state of the intelligent wearable eye health instrument can be broadcasted. Or, one side or both sides of the wearable eye health instrument of intelligence can also be provided with voice input equipment for receiving user's voice command, according to voice command change wearable eye health instrument of intelligence's mode and operating condition.

As a possible implementation, the data processor is further configured to:

determining the user type of the user according to the user information, and initializing the functional mode of the correction instrument according to the user type; the functional modes comprise an eye conditioning mode, an eye disease detection mode, a fatigue driving detection mode and an eye use suggestion report generation mode;

under the eye conditioning mode, the correction instrument conditions the eyes of the user;

in the eye disease detection mode, the data processor detects eye diseases of a user according to eye data and displays eye disease detection results through the human-computer interaction device;

in the fatigue driving detection mode, the data processor performs fatigue driving detection on the user according to the eye data and performs fatigue driving warning on the user through the human-computer interaction device;

and in the eye use suggestion report generation mode, the data processor generates an eye use suggestion report of the user according to the eye data and displays the eye use suggestion report through the human-computer interaction device.

The intelligent wearable eye health instrument provided by the embodiment of the invention supports the personalized function setting of the user, can adapt to different user groups, and provides different functions for different user groups. For example, when the user information is input, the data processor may classify the users into categories of teenagers, drivers, elderly people, employees, etc. according to the user information and initialize the functions of the rectification apparatus according to the categories. Wherein, teenagers can detect and condition the eye fatigue state correspondingly, drivers can detect and warn the fatigue driving correspondingly, and the elderly can detect chronic eye diseases (including early anticipation, middle anticipation, treatment period monitoring, rehabilitation period guidance and the like of ophthalmic diseases, such as the slow-formed pathological changes of pterygium, cornea, conjunctival diseases, meibomian glands and the like can be found in time, diagnosis information can be given in time, and pathological change identification can be accurately and intelligently carried out according to some focus changes of the eye face.

In addition, the correction instrument can accumulate the eye and face data of the user, and performs fusion calculation with ophthalmologic professional examination data in the future, so that the eye health file can be established more conveniently, the eye health problem can be found more conveniently, and the daily eye health care of the user can be realized. Or providing eye and face image data to provide rapid classification for daily symptoms of the eye and face (such as acne, acne and the like). The system can also be matched with products such as eyepatches, VR, DR and XR, digital model establishment is carried out on the external environment and the eye states in a virtual reality scene or an augmented reality scene, and the eye-face states are identified and classified, so that the emotion state, fatigue state and eye health state information and data of a person are further provided, and interaction with the human body is carried out by combining other acquisition and feedback devices.

The above-mentioned embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the embodiments of the present invention, and they should be construed as being included therein.

Claims (8)

1. An intelligent wearable eye health apparatus based on image acquisition and processing technology, comprising:

the device comprises a supporting frame, a first acquisition device, a second acquisition device, an eye conditioning device and a data processor;

the supporting frame is suitable for being worn on the eyes of a human body, the first collecting device, the second collecting device and the eye conditioning device are all positioned on the supporting frame, and when the supporting frame is worn on the eyes of the human body, the eye conditioning device corresponds to acupuncture points of the eyes of the human body;

the first acquisition device comprises a second camera, an attitude sensor, a temperature sensor, a humidity sensor, a light intensity sensor, a color temperature sensor, an air pressure sensor, a distance measurement sensor and a position sensor, and is used for acquiring external environment data and sending the external environment data to the data processor;

the data processor is used for judging the scene type of the scene where the user is located according to the external environment data and controlling the second acquisition device to acquire the eye data according to the scene type; controlling the eye conditioning device to condition eyes according to the eye data and the scene type;

the second acquisition device comprises a light source array, a first camera and an electromyographic signal sensor; the light source array comprises light sources with different wave bands;

the data processor is specifically configured to:

controlling the started light source in the light source array and the emission angle of the started light source according to the scene type, and controlling the first camera and the electromyographic signal sensor to acquire eye data;

and the data processor is specifically configured to:

inputting the eye data into an eye fatigue state classification model corresponding to the scene type to obtain the eye fatigue state of the current user; the eye fatigue state classification model is pre-established, and each scene type corresponds to one eye fatigue state classification model;

and controlling the eye conditioning device to condition the eyes according to the eye fatigue state.

2. The intelligent wearable eye health monitor based on image acquisition and processing technology of claim 1, wherein the light source is a VCSEL light source, and a micro lens array and a filter are arranged in front of the image sensor of the first camera.

3. The intelligent wearable eye health monitor based on image acquisition and processing technology of claim 1, wherein the data processor is specifically configured to:

inquiring a light source wave band and a light source angle corresponding to the scene type from a preset scene comparison table; the scene comparison table comprises light source wave bands and light source angles corresponding to various scene types;

controlling the light sources turned on in the light source array according to the light source wave band;

and controlling the emission angle of the turned-on light source in the light source array according to the light source angle.

4. The intelligent wearable eye health monitor based on image acquisition and processing technology of claim 1, wherein the eye conditioning device comprises a massager and a heater corresponding to the acupuncture points of the human eye;

the data processor is specifically configured to:

and controlling the massage force of the massager and the heating temperature of the heater according to the eye fatigue state so as to condition eyes.

5. The intelligent wearable eye health monitor based on image acquisition and processing technology of claim 1, further comprising:

the human-computer interaction device is used for receiving user information input from the outside;

the data processor is further used for storing the current user information, scene types and eye conditioning schemes after controlling the eye conditioning device to condition the eyes, so that when the user enters the same type of scene next time, the corresponding eye conditioning scheme is directly called for eye conditioning.

6. The intelligent wearable eye health monitor based on image acquisition and processing technology of claim 5, wherein the data processor is further configured to:

determining the user type of the user according to the user information, and initializing the functional mode of the correction instrument according to the user type; wherein the functional modes comprise an eye conditioning mode, an eye disease detection mode, a fatigue driving detection mode and an eye advice report generation mode;

in the eye conditioning mode, the rectification instrument conditions the eyes of the user;

in the eye disease detection mode, the data processor detects eye diseases of a user according to the eye data and displays eye disease detection results through the human-computer interaction device;

in the fatigue driving detection mode, the data processor performs fatigue driving detection on the user according to the eye data and performs fatigue driving warning on the user through the human-computer interaction device;

and under the eye use suggestion report generation mode, the data processor generates an eye use suggestion report of the user according to the eye data and displays the eye use suggestion report through the human-computer interaction device.

7. The intelligent wearable eye health monitor based on image acquisition and processing technology of claim 1, wherein the first acquisition device comprises one or more of:

the second camera, attitude sensor, temperature sensor, humidity transducer, light intensity sensor, colour temperature sensor, baroceptor, range sensor and position sensor.

8. The intelligent wearable eye health monitor based on image acquisition and processing technology of any one of claims 1-7, further comprising:

a power supply device;

the power supply device is used for supplying power to the first acquisition device, the second acquisition device, the eye conditioning device and the data processor.

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