TW202141234A - Method for compensating visual field defects, electronic device, smart glasses, computer readable storage medium - Google Patents

Abstract

The invention provides a method for compensating visual field defects, electronic device, smart glasses, and a computer readable storage medium. The method includes: obtaining a visual field graph of a wearer, and identifying a visual field defect area in the visual field graph; obtaining a visual content, and identifying a specific area in the visual content corresponding to the visual field defect area, where the specific area includes a plurality of specific pixels; adjusting the brightness value of each specific pixel according to the corresponding light sensitivity value to adjust the visual content; display the adjusted visual content.

Description

Method for compensating visual field defect, electronic device, smart glasses and computer readable storage medium

The present invention relates to a visual aid technology, and particularly relates to a method for compensating visual field defects, electronic devices, smart glasses, and computer-readable storage media.

For patients with glaucoma, their visual field will have a visual field defect area due to poor light sensitivity of the eye in some areas, and this visual field defect area will bring a certain degree of trouble to the patient's life.

With the maturity of virtual reality (VR)/augmented reality (AR) technology, various technologies that use VR/AR to provide users with visual aids have appeared on the market, but there is no such technology yet. A technology that can provide visual aids to patients with glaucoma or visual field defects.

In view of this, the present invention provides a method, electronic device, smart glasses, and computer-readable storage medium for compensating for visual field defects, which can be used to solve the above technical problems.

The present invention provides a method for compensating visual field defects. The method includes: obtaining a visual field image of a wearer; identifying a visual field defect area in the visual field image, wherein the visual field defect area includes a plurality of light sensitivity values, and each light sensitivity The value is lower than a preset threshold; obtain a visual content, and identify a specific area corresponding to the visual field defect area in the visual content, wherein the specific area includes a plurality of specific pixels, and each specific pixel corresponds to the aforementioned light sensitivity value One of; adjust the brightness value of each specific pixel according to the corresponding light sensitivity value to adjust the visual content; display the adjusted visual content.

The invention provides an electronic device including a storage circuit and a processor. The storage circuit stores multiple modules. The processor is coupled to the storage circuit and accesses the aforementioned module to perform the following steps: obtain a visual field image of a wearer; identify a visual field defect area in the visual field image, wherein the visual field defect area includes a plurality of light sensitivity values, and Each light sensitivity value is lower than a preset threshold; obtain a visual content, and identify a specific area corresponding to the visual field defect area in the visual content, wherein the specific area includes a plurality of specific pixels, and each specific pixel corresponds to the aforementioned One of the light sensitivity values; adjust the brightness value of each specific pixel according to the corresponding light sensitivity value to adjust the visual content; display the adjusted visual content.

The present invention provides a method for compensating visual field defects, suitable for a smart glasses with a front lens, the method includes: obtaining a visual field map of a wearer; identifying a visual field defect area in the visual field map, wherein the visual field defect The area includes multiple light sensitivity values, and each light sensitivity value is lower than a preset threshold; obtain a visual content captured by the front lens and a gaze center point of the wearer, and identify the visual content according to the gaze center point A specific area corresponding to the visual field defect area, where the specific area includes a plurality of specific pixels, and each specific pixel corresponds to one of the aforementioned light sensitivity values; adjust the brightness value of each specific pixel according to the corresponding light sensitivity value to adjust Specific area; the adjusted specific area is presented based on the center of gaze.

The invention provides a smart glasses including a storage circuit, a front lens and a processor. The storage circuit stores multiple modules. The processor is coupled to the storage circuit and the front lens, and accesses the aforementioned module to perform the following steps: obtain a visual field image of a wearer; identify a visual field defect area in the visual field image, wherein the visual field defect area includes multiple light sensitivities Value, and each light sensitivity value is lower than a preset threshold; obtain a visual content shot by the front lens and a gaze center point of the wearer, and identify the visual content corresponding to the visual field defect area according to the gaze center point A specific area, wherein the specific area includes a plurality of specific pixels, and each specific pixel corresponds to one of the aforementioned light sensitivity values; adjusts the brightness value of each specific pixel according to the corresponding light sensitivity value to adjust the specific area; according to the center of gaze The dots show the adjusted specific area.

The present invention provides a computer-readable storage medium, which is embedded with an executable computer program mechanism. The executable computer program mechanism includes instructions for: obtaining a visual field image of a wearer; identifying a visual field defect area in the visual field image, wherein The visual field defect area includes multiple light sensitivity values, and each light sensitivity value is lower than a preset threshold; obtain a visual content, and identify a specific area corresponding to the visual field defect area in the visual content, wherein the specific area includes multiple Each specific pixel corresponds to one of the aforementioned light sensitivity values; the brightness value of each specific pixel is adjusted according to the corresponding light sensitivity value to adjust the visual content; and the adjusted visual content is displayed.

The present invention provides a computer-readable storage medium, which is embedded with an executable computer program mechanism. The executable computer program mechanism includes instructions for: obtaining a visual field image of a wearer; identifying a visual field defect area in the visual field image, wherein The visual field defect area includes multiple light sensitivity values, and each light sensitivity value is lower than a preset threshold; obtain a visual content captured by the front lens and a gaze center point of the wearer, and based on the gaze center point in the visual content Identify a specific area corresponding to the visual field defect area, where the specific area includes a plurality of specific pixels, and each specific pixel corresponds to one of the aforementioned light sensitivity values in the visual field defect area; adjust each specific pixel according to the corresponding light sensitivity value The brightness value of to adjust a specific area; the adjusted specific area is presented according to the center of gaze.

Based on the above, the present invention can provide a certain degree of visual assistance to a wearer with a visual field defect area, so that the wearer can smoothly observe the visual content in the visual field defect area.

Please refer to FIG. 1, which is a schematic diagram of an electronic device and a head-mounted display according to an embodiment of the present invention. In FIG. 1, the electronic device 110 is, for example, a personal computer, a smart device, or other devices that can be used to generate/provide visual content (such as VR/AR content) to the head-mounted display 120 (such as a VR) connected to the head-mounted display 120. /AR helmet, VR/AR smart glasses), but not limited to this.

As shown in FIG. 1, the electronic device 110 may include a storage circuit 112 and a processor 114, where the storage circuit 112 is, for example, any type of fixed or removable random access memory (Random Access Memory, RAM), read-only memory Read-Only Memory (ROM), Flash memory (Flash memory), hard disk or other similar devices or a combination of these devices can be used to record multiple codes or modules.

The processor 114 is coupled to the storage circuit 112, and can be a general purpose processor, a special purpose processor, a traditional processor, a digital signal processor, multiple microprocessors, one or more combined digital signal processing The core microprocessor, controller, microcontroller, Application Specific Integrated Circuit (ASIC), Field Programmable Gate Array (FPGA), any other type of integrated circuit , State machines, processors based on Advanced RISC Machine (ARM) and similar products.

In an embodiment of the present invention, the head-mounted display 120 may have a front lens 122 that can be used to photograph the landscape in front of the wearer of the head-mounted display 120 and provide it to the electronic device 110 as the visual content VC. Generally speaking, in the embodiment of the present invention, the electronic device 110 can adjust the brightness of a specific area corresponding to the visual field defect area in the visual content VC after obtaining the wearer's visual field defect area, and adjust the adjusted visual field The content VC' is provided to the head-mounted display 120, so that the head-mounted display 120 presents the adjusted visual content VC' to the wearer for viewing. In this way, the wearer who cannot normally observe the landscape in the visual field defect area can smoothly observe the landscape in the visual field defect area. The relevant details will be detailed later.

In addition, in other embodiments, when the head-mounted display 120 is implemented as an all-in-one, the above-mentioned mechanism for adjusting the visual content VC can also be executed by the head-mounted display 120, and the The adjusted visual content VC' is presented to the wearer for viewing, so as to provide the wearer with visual assistance, but it may not be limited to this.

For ease of description, it is temporarily assumed that the above-mentioned mechanism for adjusting the visual content VC is executed by the electronic device 110 in FIG. 1, but it is not intended to limit the possible implementation manners of the present invention.

In the embodiment of the present invention, the processor 114 can access the modules and program codes recorded in the storage circuit 112 to implement the method of compensating for visual field defect proposed by the present invention. The details are described in detail as follows.

Please refer to FIG. 2, which is a flowchart of a method for compensating visual field defects according to an embodiment of the present invention. The method of this embodiment can be executed by the electronic device 110 in FIG. 1. The details of each step in FIG. 2 are described below with the components shown in FIG. 1.

First, in step S210, the processor 114 may obtain a visual field map of the wearer, and identify the visual field defect area in the visual field map. Generally speaking, the visual field map of the wearer can be generated by relevant medical personnel using relevant instruments (such as Humphrey perimeter) to perform visual field detection on the wearer, and can be stored by the wearer or other relevant personnel in a specific storage accessible to the processor 114 Location (such as a cloud database or storage circuit 112). Based on this, the processor 114 can directly access the above-mentioned specific storage location to obtain the visual field of the wearer, but it is not limited to this.

Please refer to FIG. 3, which is a view of the field of view according to an embodiment of the present invention. In this embodiment, it is assumed that the visual field diagram 300 is the visual field diagram of the wearer of the head mounted display 120, wherein the horizontal axis corresponds to the wearer's horizontal viewing angle, the vertical axis corresponds to the wearer's vertical viewing angle, and the origin O1 corresponds to The center point of the wearer's field of vision. In the field of view map 300, each point shown has a light sensitivity value (in dB), which can be used to characterize the light sensitivity of the wearer at the corresponding viewing angle.

In the embodiment of the present invention, it is assumed that a lower light sensitivity value corresponds to a darker color. Therefore, as can be seen from FIG. 3, there are multiple pieces of weaker photosensitivity at the lower left and upper left of the center point of the wearer’s field of view. The field of view.

In one embodiment, after the processor 114 obtains the wearer's field of view map, it can identify one or more light sensitivity values in it that are lower than a preset threshold (which can be determined by the designer according to requirements). And the area formed by these light sensitivity values is defined as the visual field defect area. Taking FIG. 3 as an example, assuming that the light sensitivity values in the areas 310 and 320 are lower than the aforementioned preset threshold, the processor 114 can define the areas 310 and 320 as the wearer's visual field defect area, but it may not be limited to this. . In another embodiment, the processor 114 can simultaneously obtain the information of the visual field defect area while obtaining the visual field map of the wearer.

After that, in step S220, the processor 114 may obtain the visual content VC, and identify a specific area corresponding to the visual field defect area in the visual content VC. As mentioned earlier, the visual content VC may be obtained by capturing the landscape in front of the wearer by the front lens 122 of the head-mounted display 120, but it may not be limited to this.

In an embodiment, the processor 114 may obtain the first relative position between the visual field defect area (ie, the areas 310 and 320) and the center point of the visual field (ie, the origin O1). After that, the processor 114 can obtain the wearer's gaze center point on the visual content VC, and define a specific area in the visual content VC according to the first relative position and the gaze center point, where the second gaze center point between the specific area and the gaze center point The relative position corresponds to the first relative position between the visual field defect area and the visual field center point, and each specific area may include a plurality of specific pixels. In one embodiment, the wearer's gaze center point can be tracked by a technology such as eye tracking, so as to calculate the wearer's gaze center point.

For ease of understanding, the following description will be supplemented with FIGS. 4A to 4B, in which FIG. 4A is a schematic diagram of visual content drawn according to an embodiment of the present invention, and FIG. 4B is a schematic diagram of obtaining a specific area corresponding to a visual field defect area.

In FIG. 4A, the visual content VC is, for example, the front view captured by the front lens 122. In FIG. 4B, assuming that the wearer has a gaze center point 405 when viewing the visual content VC, the processor 114 may define specific areas 410 and 420 in the visual content VC according to the first relative position and the gaze center point 405 described above.

In an embodiment, the processor 114 may regard the center of gaze 405 as the origin O1 (that is, the center point of the field of view) in FIG. A specific area 410 corresponding to the area 310 is identified in, wherein the relative position between the specific area 410 and the gaze center point 405 corresponds to the relative position between the area 310 and the origin O1 in FIG. 3. In the same way, the processor 114 can then identify the specific area 420 corresponding to the area 320 in the visual content VC according to the relative position between the area 320 and the origin O1 in FIG. The relative position of corresponds to the relative position between the area 320 and the origin O1 in FIG. 3.

After identifying the specific areas 410 and 420 corresponding to the visual field defect area, in step S230, the processor 114 may adjust the brightness value of each specific pixel according to the corresponding light sensitivity value to adjust the visual content VC.

For example, suppose that a first position in the area 310 has a first light sensitivity value, and the specific area 410 has a first specific pixel whose position corresponds to the first position in the area 310, and then corresponds to the first The first light sensitivity value of the location. After that, the processor 114 may obtain the original brightness value of the first specific pixel (that is, the original brightness value of the first specific pixel), and increase the original brightness value to the first brightness value according to the first light sensitivity value.

In an embodiment, the first brightness value may be expressed as the sum of the original brightness value and a brightness difference value, and the brightness difference value may be negatively related to the first light sensitivity value. That is, the lower the first light sensitivity value corresponding to the first specific pixel in the area 310, the higher the above-mentioned brightness difference, and vice versa.

In short, the processor 114 can increase the brightness value of each specific pixel in the specific area 410, 420 according to the light sensitivity value of the corresponding position, so that the adjusted visual content VC' of the specific area 410, 420 The medium may have higher brightness, but it may not be limited to this.

After that, in step S240, the processor 114 may display the adjusted visual content VC'. In an embodiment, the processor 114 may send the adjusted visual content VC' to the head-mounted display 120, so that the head-mounted display 120 displays the adjusted visual content VC' for the wearer to watch.

Please refer to FIG. 4C, which is a schematic diagram of the adjusted visual content shown in FIGS. 4A and 4B. As shown in FIG. 4C, in the adjusted visual content VC', because the specific areas 410' and 420' (which are the specific areas 410 and 420 after the brightness value is increased) have higher brightness, they can be The wearer in the visual field defect area shown in FIG. 3 smoothly observes the content in the specific areas 410' and 420'. In addition, since the visual content VC is the landscape in front of the wearer, the wearer can watch the complete front landscape by watching the adjusted visual content VC' without being limited to the defect area of his vision.

It can be seen from the above that the present invention can adjust the visual content by increasing the brightness value of the specific area corresponding to the visual field defect area in the visual content, so that the wearer with the visual field defect area will not be affected by the adjusted visual content when viewing the adjusted visual content. One's own field of vision is impaired and the complete visual content (such as the front view) cannot be viewed.

In addition, as mentioned previously, each step in FIG. 2 can also be independently completed by the head-mounted display 120 implemented as an all-in-one machine, but the present invention is not limited to this.

In other embodiments, the present invention can also implement the proposed method of compensating visual field defects by smart glasses, which will be further described below.

Please refer to FIG. 5, which is a schematic diagram of smart glasses according to an embodiment of the present invention. In the embodiment of the present invention, the smart glasses 500 are, for example, AR glasses or other glasses with similar functions, but it is not limited thereto.

As shown in FIG. 5, the smart glasses 500 may include a storage circuit 510, a processor 502, a front lens 503, a display interface 504 and/or a projection module 505. In different embodiments, the possible implementations of the storage circuit 510 and the processor 502 can refer to the related description of the storage circuit 112 and the processor 114 in FIG. 1, which will not be repeated here.

The front lens 503 can be used to photograph the landscape in front of the wearer of the smart glasses 500 as the visual content VC, for example. The display interface 504 is, for example, the lens of the smart glasses 500 or other elements that can be used to present visual content (such as AR content) to the wearer. The projection module 505, for example, can be used to project visual content to the eyes of the wearer or the lenses of the smart glasses 500 for the wearer to watch the visual content, but it is not limited to this.

It should be understood that for the wearer of the smart glasses 500, he can directly observe the front landscape through the lenses of the smart glasses 500, but the wearer cannot fully observe the front because of his visual field defect area. landscape.

Roughly speaking, the processor 502 of this embodiment can adjust the brightness of a specific area corresponding to the visual field defect area in the visual content VC after obtaining the wearer's visual field defect area, and display the adjusted specific area on the display interface. 504 and/or projection module 505, the display interface 504 and/or projection module 505 presents the adjusted visual content VC' to the wearer for viewing. In this way, the wearer who cannot normally observe the landscape in the visual field defect area can smoothly observe the landscape in the visual field defect area. The relevant details will be detailed later.

In the embodiment of the present invention, the processor 502 can access the modules and program codes recorded in the storage circuit 501 to implement the method for compensating the visual field defect proposed by the present invention. The details are described in detail as follows.

Please refer to FIG. 6, which is a flowchart of a method for compensating visual field defects according to an embodiment of the present invention. The method of this embodiment can be executed by the smart glasses 500 in FIG. 5. The details of each step in FIG. 6 are described below in conjunction with the components shown in FIG. 5.

In step S610, the processor 502 may obtain a visual field map of the wearer, and identify the visual field defect area in the visual field map. For the relevant details of step S610, please refer to the relevant description of step S210, which will not be repeated here. For ease of description, this embodiment still assumes that the wearer has the visual field diagram 300 shown in FIG.

After that, in step S620, the processor 502 may obtain the visual content VC captured by the front lens 503 and the gaze center point of the wearer, and identify a specific area corresponding to the visual field defect area in the visual content VC according to the gaze center point. For ease of description, the following description will still be made using the scenarios shown in FIGS. 4A to 4C, but the present invention may not be limited to this.

In an embodiment, the processor 502 may obtain the first relative position between the visual field defect area (for example, the areas 310 and 320 in FIG. 3) and the center point of the visual field (for example, the origin O1 in FIG. 3), and according to the first relative position The position and gaze center 405 define specific areas 410 and 420 in the visual content VC.

More specifically, the processor 502 may regard the center of gaze 405 as the origin O1 (that is, the center of the field of view) in FIG. 3, and the relative position between the region 310 and the origin O1 in FIG. The specific area 410 corresponding to the area 310 is identified, wherein the relative position between the specific area 410 and the gaze center point 405 corresponds to the relative position between the area 310 and the origin O1 in FIG. 3. In the same way, the processor 502 can identify the specific area 420 corresponding to the area 320 in the visual content VC according to the relative position between the area 320 and the origin O1 in FIG. The relative position of corresponds to the relative position between the area 320 and the origin O1 in FIG. 3.

After that, in step S630, the processor 502 may adjust the brightness value of each specific pixel displayed or projected according to the corresponding light sensitivity value, so as to adjust the specific areas 410 and 420. For details of step S630 in this embodiment, reference may be made to the related description of step S230 in FIG. 2, which will not be repeated here.

Then, in step S640, the processor 502 may present the adjusted specific areas 410', 420' according to the gaze center 405. In an embodiment, the processor 502 can control the display interface 504 to display the adjusted specific areas 410', 420', or control the projection module 505 to project the adjusted specific areas 410', 420' to the wearer’s eyes Inside. In another embodiment, a projection method can also be used to project the adjusted specific areas 410', 420' onto the lenses of the smart glasses 500 for the user to observe.

In detail, since the wearer can observe a part of the front view through the lens of the smart glasses 500, the processor 502 uses step S640 to adjust the adjusted specific areas 410', 420' (that is, the wearer cannot After the normally observed field of view is presented to the wearer, the smart glasses 500 fill the wearer’s field of vision with a part of the front view corresponding to the visual field defect area, so that the wearer can observe the complete front view ( For example, as shown in Figure 4C), it is no longer limited to its own visual field defect area.

The present invention further provides a computer-readable storage medium for executing the above-mentioned method of compensating for visual field defects. The computer-readable storage medium is composed of multiple program instructions (such as setting program instructions and deployment program instructions) embedded in it. These program instructions can be loaded into the electronic device and/or smart glasses, and execute the same method of compensating the visual field defect, the function of the electronic device and the smart glasses as described above.

In summary, the method, electronic device, smart glasses, and computer-readable storage medium of the present invention can identify the corresponding specific area in the visual content according to the wearer’s visual field defect area, and increase the brightness of the specific area, thereby Allow the wearer to smoothly observe the visual content in the defect area of his visual field. In this way, a wearer with a visual field defect area (such as a glaucoma patient) can smoothly observe the complete visual content (such as a front view), thereby improving the wearer's quality of life.

Although the present invention has been disclosed in the above embodiments, it is not intended to limit the present invention. Anyone with ordinary knowledge in the technical field can make some changes and modifications without departing from the spirit and scope of the present invention. The scope of protection of the present invention shall be subject to those defined by the attached patent scope.

110: electronic device 112,501: storage circuit 114,502: Processor 120: Head-mounted display 122,503: front camera 300: Field of Vision 310, 320: area 405: Look at the center point 410,420,410’,420’: specific area 500: Smart glasses 504: display interface 505: Projection Module O1: Origin S210~S240, S610~S640: steps VC,VC’: visual content

FIG. 1 is a schematic diagram of an electronic device and a head-mounted display according to an embodiment of the present invention. Fig. 2 is a flowchart of a method for compensating visual field defects according to an embodiment of the present invention. Fig. 3 is a view of the field of view according to an embodiment of the present invention. FIG. 4A is a schematic diagram of visual content drawn according to an embodiment of the present invention. FIG. 4B is a schematic diagram of obtaining a specific area corresponding to a visual field defect area. 4C is a schematic diagram of the adjusted visual content shown in FIGS. 4A and 4B. FIG. 5 is a schematic diagram of smart glasses according to an embodiment of the present invention. Fig. 6 is a flowchart of a method for compensating visual field defects according to an embodiment of the present invention.

S210~S240: steps

Claims (22)

A method for compensating visual field defects, the method comprising: Obtain a view of a wearer; Identifying a visual field defect area in the visual field map, where the visual field defect area includes a plurality of light sensitivity values, and each light sensitivity value is lower than a preset threshold; Obtain a visual content, and identify a specific area corresponding to the visual field defect area in the visual content, wherein the specific area includes a plurality of specific pixels, and each specific pixel corresponds to one of the light sensitivity values ； Adjusting the brightness value of each specific pixel according to the corresponding light sensitivity value to adjust the visual content; Display the adjusted visual content. The method according to claim 1, wherein the visual field map has a visual field center point, and the step of identifying the specific area corresponding to the visual field defect area in the visual content includes: Obtaining a first relative position between the visual field defect area and the central point of the visual field; Obtain a gaze center point of the wearer on the visual content, and define the specific area in the visual content according to the first relative position and the gaze center point, wherein a distance between the specific area and the gaze center point is The second relative position corresponds to the first relative position between the visual field defect area and the central point of the visual field. The method according to claim 1, wherein the light sensitivity values include a first light sensitivity value, the specific pixels include a first specific pixel corresponding to the first light sensitivity value, and are based on the corresponding light sensitivity The steps of adjusting the brightness value of each specific pixel include: Obtain an original brightness value of the first specific pixel, and increase the original brightness value to a first brightness value according to the first light sensitivity value, wherein a brightness difference between the original brightness value and the first brightness value The value is negatively related to the first light sensitivity value. The method according to claim 1, wherein the visual content is captured by a front lens of a head-mounted display. An electronic device including: A storage circuit, which stores a plurality of modules; A processor is coupled to the storage circuit and accesses the modules to perform the following steps: Obtain a view of a wearer; Identifying a visual field defect area in the visual field map, where the visual field defect area includes a plurality of light sensitivity values, and each light sensitivity value is lower than a preset threshold; Obtain a visual content, and identify a specific area corresponding to the visual field defect area in the visual content, wherein the specific area includes a plurality of specific pixels, and each specific pixel corresponds to one of the light sensitivity values ； Adjusting the brightness value of each specific pixel according to the corresponding light sensitivity value to adjust the visual content; Display the adjusted visual content. The electronic device according to claim 5, wherein the field of view map has a field of view center point, and the processor is configured to: Obtaining a first relative position between the visual field defect area and the central point of the visual field; Obtain a gaze center point of the wearer on the visual content, and define the specific area in the visual content according to the first relative position and the gaze center point, wherein a distance between the specific area and the gaze center point is The second relative position corresponds to the first relative position between the visual field defect area and the central point of the visual field. The electronic device according to claim 5, wherein the light sensitivity values include a first light sensitivity value, the specific pixels include a first specific pixel corresponding to the first light sensitivity value, and the processor is configured by: Obtain an original brightness value of the first specific pixel, and increase the original brightness value to a first brightness value according to the first light sensitivity value, wherein a brightness difference between the original brightness value and the first brightness value The value is negatively related to the first light sensitivity value. The electronic device according to claim 5, wherein the visual content is captured by a front lens of a head-mounted display. A method for compensating for visual field defects is suitable for a smart glasses with a front lens, and the method includes: Obtain a view of a wearer; Identifying a visual field defect area in the visual field map, where the visual field defect area includes a plurality of light sensitivity values, and each light sensitivity value is lower than a preset threshold; Obtain a visual content captured by the front lens and a gaze center point of the wearer, and identify a specific area corresponding to the visual field defect area in the visual content according to the gaze center point, where the specific area includes multiple Specific pixels, and each specific pixel corresponds to one of the light sensitivity values in the visual field defect area; Adjusting the brightness value of each specific pixel according to the corresponding light sensitivity value to adjust the specific area; The adjusted specific area is presented according to the gaze center point. The method according to claim 9, wherein the visual field map has a visual field center point, and the step of identifying the specific area corresponding to the visual field defect area in the visual content according to the gaze center point includes: Obtaining a first relative position between the visual field defect area and the central point of the visual field; The specific area is defined in the visual content according to the first relative position and the gaze center point, wherein a second relative position between the specific area and the gaze center point corresponds to the difference between the visual field defect area and the visual field center point The first relative position between. The method according to claim 9, wherein the light sensitivity values include a first light sensitivity value, the specific pixels include a first specific pixel corresponding to the first light sensitivity value, and are based on the corresponding light sensitivity The steps of adjusting the brightness value of each specific pixel include: Obtain an original brightness value of the first specific pixel, and increase the original brightness value to a first brightness value according to the first light sensitivity value, wherein a brightness difference between the original brightness value and the first brightness value The value is negatively related to the first light sensitivity value. The method according to claim 9, wherein the smart glasses further include a display interface, and the step of presenting the adjusted specific area according to the gaze center point includes: The adjusted specific area is presented on the display interface according to the gaze center point. The method according to claim 9, wherein the smart glasses further include a projection module, and the step of presenting the adjusted specific area according to the gaze center point includes: The projection module is controlled to project the adjusted specific area to the wearer's eyes according to the gaze center point. The method according to claim 9, wherein the smart glasses further include a projection module, and the step of presenting the adjusted specific area according to the gaze center point includes: The projection module is controlled to project the adjusted specific area to the lens of the smart glasses according to the gaze center point. A smart glasses, including: A storage circuit, which stores a plurality of modules; A front camera A processor is coupled to the storage circuit and the front lens, and accesses the modules to perform the following steps: Obtain a view of a wearer; Identifying a visual field defect area in the visual field map, where the visual field defect area includes a plurality of light sensitivity values, and each light sensitivity value is lower than a preset threshold; Obtain a visual content captured by the front lens and a gaze center point of the wearer, and identify a specific area corresponding to the visual field defect area in the visual content according to the gaze center point, where the specific area includes multiple Specific pixels, and each specific pixel corresponds to one of the light sensitivity values; Adjusting the brightness value of each specific pixel according to the corresponding light sensitivity value to adjust the specific area; The adjusted specific area is presented according to the gaze center point. The smart glasses according to claim 15, wherein the field of view map has a field of view center point, and the processor is configured to: Obtaining a first relative position between the visual field defect area and the central point of the visual field; The specific area is defined in the visual content according to the first relative position and the gaze center point, wherein a second relative position between the specific area and the gaze center point corresponds to the difference between the visual field defect area and the visual field center point The first relative position between. The smart glasses according to claim 15, wherein the light sensitivity values include a first light sensitivity value, the specific pixels include a first specific pixel corresponding to the first light sensitivity value, and the processor is controlled by Configure to: Obtain an original brightness value of the first specific pixel, and increase the original brightness value to a first brightness value according to the first light sensitivity value, wherein a brightness difference between the original brightness value and the first brightness value The value is negatively related to the first light sensitivity value. The smart glasses according to claim 15, wherein the smart glasses further include a display interface, and the processor is configured to: The adjusted specific area is presented on the display interface according to the gaze center point. The smart glasses according to claim 15, wherein the smart glasses further include a projection module, and the processor is configured to: The projection module is controlled to project the adjusted specific area to the wearer's eyes according to the gaze center point. The smart glasses according to claim 15, wherein the smart glasses further include a projection module, and the processor is configured to: The projection module is controlled to project the adjusted specific area to the lens of the smart glasses according to the gaze center point. A computer-readable storage medium is embedded with an executable computer program mechanism, and the executable computer program mechanism includes instructions for: Obtain a view of a wearer; Identifying a visual field defect area in the visual field map, where the visual field defect area includes a plurality of light sensitivity values, and each light sensitivity value is lower than a preset threshold; Obtain a visual content, and identify a specific area corresponding to the visual field defect area in the visual content, wherein the specific area includes a plurality of specific pixels, and each specific pixel corresponds to one of the light sensitivity values ； Adjusting the brightness value of each specific pixel according to the corresponding light sensitivity value to adjust the visual content; Display the adjusted visual content. A computer-readable storage medium is embedded with an executable computer program mechanism, and the executable computer program mechanism includes instructions for: Obtain a view of a wearer; Identifying a visual field defect area in the visual field map, where the visual field defect area includes a plurality of light sensitivity values, and each light sensitivity value is lower than a preset threshold; Obtain a visual content captured by the front lens and a gaze center point of the wearer, and identify a specific area corresponding to the visual field defect area in the visual content according to the gaze center point, where the specific area includes multiple Specific pixels, and each specific pixel corresponds to one of the light sensitivity values in the visual field defect area; Adjusting the brightness value of each specific pixel according to the corresponding light sensitivity value to adjust the specific area; The adjusted specific area is presented according to the gaze center point.

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