Five-sense adjustment system for medical professional display

By integrating multiple sensors, the display achieves intelligent adjustment, solving problems related to brightness, orientation switching, privacy, and energy management in medical displays, thereby improving the display's performance and user experience.

CN122177066APending Publication Date: 2026-06-09SHENZHEN RUIYING MEDICAL TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
SHENZHEN RUIYING MEDICAL TECHNOLOGY CO LTD
Filing Date
2026-04-15
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

Existing displays in the medical field cannot automatically adjust their brightness according to ambient light, requiring the use of third-party light boxes for viewing films. Switching between portrait and landscape modes requires manual adjustment, and the lack of privacy protection and energy management results in high energy consumption, low efficiency, and a high risk of misdiagnosis.

Method used

It integrates an external ambient light sensor, a film viewing lightbox sensor, an orientation gravity sensor, a human body detection sensor, and LCD screen brightness, color, and grayscale detection sensors to achieve intelligent adjustment, automatically adjust backlight brightness, display direction, and screen status, and monitor display parameters in real time to ensure compliance with DICOM standards.

Benefits of technology

It enables automatic brightness adjustment of the monitor under different lighting conditions, reduces reliance on third-party light boxes, improves ease of use and efficiency, saves energy, protects privacy, reduces the risk of misdiagnosis, and enhances the performance and reliability of the monitor.

✦ Generated by Eureka AI based on patent content.

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Abstract

This invention relates to the field of display control technology, specifically to a five-sensor adjustment system for a medical professional display. The system includes: using an external ambient light sensor to acquire brightness data of the external ambient light, and automatically adjusting the backlight brightness of the liquid crystal display screen based on this data; extracting medical imaging film and inserting a trigger-activated viewing lightbox sensor, using a directional gravity sensor to extract the mechanical rotation direction information of the display screen through detection, and analyzing and processing the acquired information; and using liquid crystal display screen brightness, color, and grayscale detection sensors to extract display parameter information of the display screen through real-time monitoring, and comparing the acquired display parameter information with preset standards. This invention solves the problems of conventional displays in medical applications, such as the need for manual adjustment when switching between portrait and landscape modes, lack of privacy protection and energy management, and the tendency for display parameters to deviate from standards, leading to misdiagnosis.
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Description

Technical Field

[0001] This invention belongs to the field of display control technology, specifically relating to a five-element sensor control system for a medical professional display. Background Technology

[0002] Currently, the application of conventional monitors in the medical field is mainly limited to daily office scenarios, and their functional design does not fully consider the specific needs of the medical industry. Existing monitors have significant shortcomings in terms of energy conservation, environmental protection, scene adaptability, and medical viewing lightbox functionality. Specifically, traditional monitors cannot automatically adjust backlight brightness according to changes in ambient light, resulting in poor display quality under different lighting conditions and high energy consumption, failing to meet energy conservation and environmental protection requirements. Furthermore, during the viewing of medical images, doctors often need to rely on third-party lightbox equipment, which not only increases operating costs but also reduces work efficiency. In addition, traditional monitors require users to manually adjust the display orientation when switching between portrait and landscape modes, which is inconvenient. Regarding privacy protection and energy management, existing monitors also lack effective intelligent sensing mechanisms and cannot automatically turn off the screen when someone leaves, easily leading to energy waste and privacy leaks.

[0003] To address the aforementioned issues, this invention proposes a five-sensor adjustment system for medical professional displays. By integrating an external ambient light sensor, a viewing lightbox sensor, an orientation gravity sensor, a human body detection sensor, and LCD screen brightness, color, and grayscale detection sensors, the system achieves intelligent adjustment of the display, effectively improving the performance and user experience of displays in the medical field. Summary of the Invention

[0004] To address the aforementioned issues, this invention provides a five-sensor adjustment system for a medical professional display. This system solves the problems of conventional displays in medical applications, such as the inability to automatically adjust brightness based on ambient light, reliance on third-party light boxes for viewing images, manual adjustment required for switching between portrait and landscape modes, lack of privacy protection and energy management, and the tendency for display parameters to deviate from standards, leading to misdiagnosis. To achieve the above objectives, this invention adopts the following technical solution:

[0005] The aforementioned five-element sensing adjustment system for a medical professional display includes: a sensing adjustment module for acquiring ambient light brightness data using an external ambient light sensor, and automatically adjusting the backlight brightness of the LCD screen based on the brightness data; a sensing adjustment module for using a viewing lightbox sensor, which is triggered by inserting a medical imaging film into the sensor, and uses the sensing signal as an instruction to immediately display a white screen image with maximum backlight brightness; a gravity sensing module for using a directional gravity sensor to extract the mechanical rotation direction information of the display screen, and automatically adjusting the corresponding display image when the display screen switches between landscape and portrait display; a human detection module for using a human detection sensor to extract information on the presence of people within a certain angle and distance range opposite the display screen, and analyzing and processing the acquired information; and a real-time monitoring module for using LCD screen brightness, color, and grayscale sensors to extract display parameter information of the display screen through real-time monitoring, and comparing the acquired display parameter information with preset standards.

[0006] Furthermore, the sensing adjustment module includes: a data acquisition submodule, used to employ an external ambient light sensor, positioned at a location capable of fully sensing changes in external light, continuously scanning and extracting brightness information of the external ambient light through the light sensor to obtain accurate brightness data; a backlight adjustment submodule, used to transmit the acquired brightness data to a processing module, which analyzes the data according to a preset algorithm and automatically adjusts the backlight brightness of the LCD screen based on the analysis results, so that the backlight brightness dynamically changes with the intensity of ambient light; and a precision adjustment submodule, used to control the adjustment precision to ensure that the display effect of the screen conforms to the DICOM display curve standard in different environments.

[0007] Furthermore, the sensing adjustment module includes: a real-time monitoring submodule, used to install the film viewing lightbox sensor on the display screen so that the sensor can accurately sense the film insertion status and monitor it in real time; a trigger sensing submodule, used to extract film insertion information and trigger the sensor to generate a sensing signal when the medical imaging film approaches and is inserted; and a backlight activation submodule, used to quickly transmit the sensing signal as an instruction, and the LCD screen receives the instruction, acquires data, and displays a white screen image.

[0008] Furthermore, the gravity sensing module includes: a rotation direction submodule, used to install a direction gravity sensor inside the display screen, continuously scan and extract the mechanical rotation motion of the display screen through the detection function of the direction gravity sensor, and obtain rotation direction information; and a display switching submodule, used to compare and analyze the obtained rotation direction information with the initially set direction, and automatically adjust the corresponding display screen according to the analysis results, so that the screen content is adapted to the new display direction.

[0009] Furthermore, the human body detection module includes: a continuous scanning submodule, used to install the human body detection sensor in front of the display to ensure full coverage of the detection angle and distance range, and continuously scan the angle and distance area opposite the display through the detection function of the human body detection sensor to extract information on whether there is a person within the range; and an information processing submodule, used to transmit the acquired information to the processing module, which analyzes and processes it according to preset rules.

[0010] Furthermore, the real-time monitoring module includes: a display information submodule, used to continuously scan the display screen and extract display parameter information of brightness, color, and grayscale by using the brightness, color, and grayscale detection sensors of the liquid crystal display screen through the real-time monitoring function of the sensors; and a comparison and analysis submodule, used to quickly transmit the acquired display parameter information to the processing module, which performs detailed comparison and analysis of the received parameter information according to the set standard range of GAMMA and DICOM curves.

[0011] Furthermore, the display switching submodule is used to compare and analyze the acquired rotation direction information with the initial set direction. When the display screen switches between landscape and portrait display, the rotation direction information is used as an instruction based on the analysis results to automatically adjust the corresponding display screen so that the screen content adapts to the new display direction.

[0012] Furthermore, the information processing submodule is used to transmit the acquired information to the processing module. The processing module analyzes and processes the information according to preset rules. When the person being judged leaves the display screen, the processing module issues an instruction to automatically turn off the screen to reduce power consumption. When the person being judged approaches the display screen, the processing module issues another instruction to automatically turn on the screen.

[0013] Furthermore, the comparison and analysis submodule is used to quickly transmit the acquired display parameter information to the processing module. The processing module performs a detailed comparison and analysis of the received parameter information based on the set standard range of GAMMA and DICOM curves. When it finds that the parameters deviate from the standard range, it immediately issues an adjustment command. According to the command, the display screen automatically fine-tunes the display parameters to ensure that the display remains stable within the standard range of GAMMA and DICOM curves during long-term use.

[0014] In the technical solution provided by this invention, the sensing adjustment module is used to acquire brightness data of the external ambient light using an external ambient light sensor, and automatically adjust the backlight brightness of the LCD screen based on the brightness data; the sensing adjustment module is used to acquire a white screen image with maximum backlight brightness by extracting medical imaging film and inserting it to trigger the viewing light box sensor, using the sensing signal as an instruction; the gravity sensing module is used to acquire the mechanical rotation direction information of the display screen by using a directional gravity sensor, and automatically adjust the corresponding display image when the display screen switches between landscape and portrait display; the human body detection module is used to acquire information on whether there are people within the angle and distance range opposite the display screen by using a human body detection sensor, and analyze and process the acquired information; the real-time monitoring module is used to acquire display parameter information of the display screen by using brightness, color, and grayscale detection sensors of the LCD screen, and compare the acquired display parameter information with preset standards by using a real-time monitoring function. This invention solves the problems of conventional displays in the medical field, such as the inability to automatically adjust brightness according to ambient light, the need to rely on third-party light boxes for viewing films, the need for manual adjustment when switching between landscape and portrait modes, the lack of privacy protection and energy management, and the tendency for display parameters to deviate from standards, leading to misdiagnosis. Attached Figure Description

[0015] Various other advantages and benefits will become apparent to those skilled in the art upon reading the following detailed description of preferred embodiments. The accompanying drawings are for illustrative purposes only and are not intended to limit the invention.

[0016] Figure 1 This is a schematic diagram of the first embodiment of a five-sensor adjustment system for a medical professional display according to an embodiment of the present invention.

[0017] Figure 2 This is a schematic diagram illustrating the functional application layout of a five-sensor adjustment system for a medical professional display according to an embodiment of the present invention.

[0018] Figure 3 This is an exploded view of the functional structure of a five-sensor adjustment system for a medical professional display according to an embodiment of the present invention. Detailed Implementation

[0019] To make the objectives, technical solutions, and advantages of this invention clearer, the invention will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative and not intended to limit the invention.

[0020] Those skilled in the art will understand that, unless specifically stated otherwise, the singular forms “a,” “an,” “the,” and “the” used herein may also include the plural forms. It should be further understood that the term “comprising” as used in this specification means the presence of the stated features, integers, steps, operations, elements, and / or components, but does not exclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and / or groups thereof.

[0021] A five-position sensor adjustment system for a medical professional display, such as Figure 1 As shown, it includes: a sensing adjustment module, used to acquire ambient light brightness data using an external ambient light sensor, and automatically adjust the backlight brightness of the LCD screen based on the brightness data; a sensing adjustment module, used to acquire a viewing lightbox sensor, which is triggered by inserting a medical imaging film into the sensor, and uses the sensing signal as an instruction for the LCD screen to immediately acquire a white screen displaying the maximum backlight brightness; a gravity sensing module, used to acquire mechanical rotation direction information of the display screen using a directional gravity sensor, and automatically adjusts the corresponding display image when the display screen switches between landscape and portrait display; a human detection module, used to acquire information on the presence of people within the angle and distance range opposite the display screen, and analyzes and processes the acquired information; and a real-time monitoring module, used to acquire display parameter information of the display screen using brightness, color, and grayscale sensors, and compares the acquired display parameter information with preset standards.

[0022] In this embodiment, the sensing adjustment module includes: a data acquisition submodule, which uses an external ambient light sensor, positioned at a location capable of fully sensing changes in external light, to continuously scan and extract brightness information of the external ambient light, thereby obtaining accurate brightness data; a backlight adjustment submodule, which transmits the acquired brightness data to a processing module, which analyzes the data according to a preset algorithm and automatically adjusts the backlight brightness of the LCD screen based on the analysis results, so that the backlight brightness dynamically changes with the intensity of ambient light; and a precision adjustment submodule, which ensures that the display effect of the screen conforms to the DICOM display curve standard under different environments by controlling the adjustment precision.

[0023] The data acquisition submodule strategically positions the ambient light sensor to continuously scan and extract precise brightness data, providing a reliable basis for subsequent adjustments. The backlight adjustment submodule transmits the acquired data to the processing module, where it is analyzed by a preset algorithm and automatically adjusts the LCD backlight brightness to dynamically change with ambient light intensity. This meets viewing needs in different environments while also achieving energy conservation and environmental protection. The precision adjustment submodule controls the adjustment accuracy, ensuring the display effect conforms to the DICOM display curve standard in any environment. This is crucial in the medical field, preventing misdiagnosis due to inaccurate display and effectively improving the performance and reliability of medical professional displays, providing more accurate and efficient display support for medical work.

[0024] In this embodiment, the sensing adjustment module includes: a real-time monitoring submodule, used to install the film viewing lightbox sensor on the display screen so that the sensor can accurately sense the film insertion status and monitor it in real time; a trigger sensing submodule, used to extract film insertion information and trigger the sensor to generate a sensing signal when the medical imaging film approaches and is inserted; and a backlight activation submodule, used to quickly transmit the sensing signal as an instruction, and the LCD screen receives the instruction, acquires data, and displays a white screen image.

[0025] The real-time monitoring submodule integrates the viewing lightbox sensor with the display screen, accurately sensing and monitoring the film insertion status to provide precise information for subsequent operations. The trigger sensing submodule quickly extracts insertion information and triggers the sensor to generate a signal when the medical imaging film approaches insertion, demonstrating rapid response. The backlight activation submodule uses the sensing signal as a command to quickly display a white screen with maximum backlight brightness on the LCD screen, realizing the traditional lightbox viewing function. This not only eliminates reliance on third-party lightbox equipment and reduces operating costs but also improves work efficiency, allowing doctors to view medical imaging films more conveniently, providing strong support for medical diagnosis, and enhancing the intelligence level of the entire medical imaging viewing process.

[0026] In this embodiment, the gravity sensing module includes: a rotation direction submodule, which is used to install a direction gravity sensor inside the display screen, continuously scan and extract the mechanical rotation motion of the display screen through the detection function of the direction gravity sensor, and obtain rotation direction information; and a display switching submodule, which is used to compare and analyze the obtained rotation direction information with the initial set direction, and automatically adjust the corresponding display screen according to the analysis results, so that the screen content is adapted to the new display direction.

[0027] The rotation direction submodule integrates a gravity sensor inside the display screen. Utilizing its detection function, it continuously scans and accurately extracts the mechanical rotation motion of the display screen, acquiring rotation direction information to provide accurate baseline data for display switching. The display switching submodule compares and analyzes the acquired rotation direction information with the initially set direction, automatically adjusting the corresponding display image based on the analysis results, allowing the screen content to quickly adapt to the new display direction. This process eliminates the need for manual secondary adjustments to the system software's display direction, greatly improving ease of use, especially suitable for professional display scenarios in the medical field. When doctors rotate the display screen as needed, they can immediately see the adapted image, improving work efficiency and enhancing the user experience.

[0028] In this embodiment, the human body detection module includes: a continuous scanning submodule, which is used to install the human body detection sensor in front of the display to ensure full coverage of the detection angle and distance range. Through the detection function of the human body detection sensor, it continuously scans the angle and distance area opposite the display to extract information on whether there is a person within the range; and an information processing submodule, which is used to transmit the acquired information to the processing module, which analyzes and processes the information according to preset rules.

[0029] The continuous scanning submodule mounts a human detection sensor directly in front of the display, ensuring comprehensive coverage of the detection angle and distance range. It continuously scans the area opposite the display to accurately determine the presence of a person. The information processing submodule then transmits the acquired information to the processing module for analysis and processing according to preset rules. When a person leaves the display screen, the processing module automatically turns off the screen to avoid energy waste; when a person approaches, the screen automatically turns on for ease of use. This invention effectively solves the problem of energy consumption caused by forgetting to turn off the display screen after a long period of absence, achieving energy conservation and environmental protection while protecting the privacy of relevant personnel. It has significant application value in scenarios such as medical care where privacy and energy conservation are crucial.

[0030] In this embodiment, the real-time monitoring module includes: a display information submodule, used to continuously scan the display screen and extract display parameter information of brightness, color, and grayscale by using the brightness, color, and grayscale detection sensors of the liquid crystal display screen through the real-time monitoring function of the sensors; and a comparison and analysis submodule, used to quickly transmit the acquired display parameter information to the processing module, which performs detailed comparison and analysis of the received parameter information according to the set GAMMA and DICOM curve standard ranges.

[0031] The display information submodule employs LCD screen brightness, chromaticity, and grayscale sensors. Leveraging its real-time monitoring function, it continuously scans the screen, accurately extracting display parameters for brightness, chromaticity, and grayscale, providing detailed data for subsequent analysis. The comparison and analysis submodule rapidly transmits the acquired parameter information to the processing module, which meticulously compares and analyzes it against predefined GAMMA and DICOM curve standards. This process allows for real-time monitoring of whether the display parameters conform to standards, ensuring accurate display in the medical field, preventing misdiagnosis due to display deviations, and providing reliable assurance for medical diagnosis. This significantly improves the accuracy and reliability of medical professional displays in medical applications.

[0032] Specifically, GAMMA and DICOM curves differ: GAMMA curves describe the non-linear relationship between the input signal and output brightness of a display device, used to correct image brightness. Their core function is to compensate for the non-linear perception of brightness by adjusting the curve shape, making details in dark areas clearer while avoiding overexposure in highlights. In the medical field, ordinary displays often use the GAMMA 2.2 standard, but this standard cannot meet the stringent requirements of medical imaging for grayscale accuracy. The DICOM (Digital Imaging and Communications in Medicine) standard's DICOM curve (GSDF, Grayscale Standard Display Function) is specifically designed for medical imaging, defining the functional relationship between human vision and brightness response. By adjusting the grayscale range and center position of medical images, it ensures that the display can accurately present subtle grayscale differences at different brightness levels, such as distinguishing the density difference between cysts and water. Medical displays must conform to the DICOM curve standard; otherwise, insufficient grayscale and contrast deviations may occur, leading to missed diagnoses of minute lesions. The key difference between the two lies in their application scenarios: GAMMA curves focus on brightness correction for general display devices, while DICOM curves focus on the grayscale accuracy and diagnostic reliability of medical images. High-end medical displays typically support both GAMMA and DICOM curve calibration, such as DICOM correction via hardware Gamma registers or GPU shaders, to ensure the accuracy and stability of image display.

[0033] In this embodiment, the display switching submodule is used to compare and analyze the acquired rotation direction information with the initial set direction. When the display screen switches between landscape and portrait display, the rotation direction information is used as the basis for the instruction based on the analysis results to automatically adjust the corresponding display screen so that the screen content is adapted to the new display direction.

[0034] When the display switches between landscape and portrait modes, it first meticulously compares and analyzes the acquired rotation direction information with the initially set direction. This process ensures accurate judgment of the display rotation. Subsequently, based on the analysis results, the rotation direction information is used as a command to automatically and quickly adjust the corresponding display screen, ensuring the content perfectly adapts to the new display orientation. This function eliminates the need for manual secondary adjustment of the system software's display orientation, greatly improving ease of use, especially suitable for professional scenarios such as medical settings. Doctors can immediately see the appropriate image when rotating the display screen as needed, effectively improving work efficiency and enhancing the user experience.

[0035] In this embodiment, the information processing submodule is used to transmit the acquired information to the processing module. The processing module analyzes and processes the information according to preset rules. When the person being judged leaves the display screen, the processing module issues an instruction to automatically turn off the screen to reduce power consumption. When the person being judged approaches the display screen, the processing module issues another instruction to automatically turn on the screen.

[0036] The information acquired by the human body detection sensor is transmitted to the processing module, which analyzes it precisely according to preset rules. When a person is detected leaving the display screen, a command is quickly issued to automatically turn off the screen, effectively reducing power consumption and aligning with energy conservation and environmental protection principles. When a person is detected approaching, a command is immediately issued to automatically turn on the screen for convenient use. This process requires no manual operation, improving ease of use and ensuring both rational energy utilization and timely availability in scenarios such as medical settings.

[0037] In this embodiment, the comparison and analysis submodule is used to quickly transmit the acquired display parameter information to the processing module. The processing module performs detailed comparison and analysis on the received parameter information according to the set standard range of GAMMA and DICOM curves. When it finds that the parameters deviate from the standard range, it immediately issues an adjustment command. According to the command, the display screen automatically fine-tunes the display parameters to ensure that the display remains stable within the standard range of GAMMA and DICOM curves during long-term use.

[0038] The comparative analysis submodule quickly transmits the acquired display parameter information to the processing module, which then meticulously compares and analyzes the data against the set GAMMA and DICOM curve standard ranges. If any parameters deviate from the standard, an adjustment command is immediately issued, causing the display to automatically fine-tune its parameters. This ensures that the display remains stable within the standard range during prolonged use, effectively preventing misdiagnosis and other problems caused by display deviations. It provides accurate and reliable display support for medical diagnosis, improving the performance and stability of medical professional displays.

[0039] The foregoing has shown and described the basic principles, main features, and advantages of the present invention. Those skilled in the art should understand that the present invention is not limited to the above embodiments. The embodiments and descriptions in the specification are merely preferred examples and are not intended to limit the invention. Various changes and modifications can be made to the invention without departing from its spirit and scope, and all such changes and modifications fall within the scope of the present invention as claimed. The scope of protection of the present invention is defined by the appended claims and their equivalents.

Claims

1. A five-position sensor adjustment system for a medical professional display, characterized in that, The medical professional display's five-position sensor adjustment system includes: The sensing adjustment module is used to acquire the brightness data of the external ambient light using an external ambient light sensor, and automatically adjust the backlight brightness of the LCD screen based on the brightness data; The sensing adjustment module is used to extract medical imaging film, insert it into the trigger sensing light box sensor, and use the sensing signal as an instruction for the LCD screen to immediately obtain a white screen image displaying the maximum backlight brightness. The gravity sensing module uses a directional gravity sensor to extract the mechanical rotation direction information of the display screen through detection. Based on the obtained rotation direction information, the display screen automatically adjusts the corresponding display screen when switching between landscape and portrait display. The human detection module is used to extract information on whether there are people within the angle and distance range opposite the display through the detection function using a human detection sensor, and then analyzes and processes the acquired information. The real-time monitoring module uses LCD screen brightness, color, and grayscale detection sensors to extract display parameter information from the screen through real-time monitoring and compares the acquired display parameter information with preset standards.

2. The five-element sensor adjustment system for a medical professional display according to claim 1, characterized in that, The sensing adjustment module includes: The data acquisition submodule is used to employ an external ambient light sensor, which is placed in a position that can fully perceive changes in external light. The sensor continuously scans and extracts the brightness information of the external ambient light to obtain accurate brightness data. The backlight adjustment submodule is used to transmit the acquired brightness data to the processing module. The processing module analyzes the data according to a preset algorithm and automatically adjusts the backlight brightness of the LCD screen based on the analysis results, so that the backlight brightness changes dynamically with the intensity of ambient light. The precision adjustment submodule is used to control and adjust the precision to ensure that the display effect of the screen conforms to the DICOM display curve standard in different environments.

3. The five-element sensor adjustment system for a medical professional display according to claim 1, characterized in that, The sensing adjustment module includes: The real-time monitoring submodule is used to install the film viewing lightbox sensor on the display screen, so that the sensor can accurately sense the film insertion status and monitor it in real time. The trigger sensing submodule is used to extract film insertion information and trigger the sensor to generate a sensing signal when the medical imaging film approaches and is inserted. The backlight sub-module is activated to quickly transmit the sensing signal as an instruction. The LCD screen receives the instruction, acquires the data, and displays a white screen image.

4. The five-element sensor adjustment system for a medical professional display according to claim 1, characterized in that, The gravity sensing module includes: The rotation direction submodule is used to install the orientation gravity sensor inside the display screen. Through the detection function of the orientation gravity sensor, it continuously scans and extracts the mechanical rotation motion of the display screen to obtain the rotation direction information. The display switching submodule is used to compare and analyze the acquired rotation direction information with the initial set direction, and automatically adjust the corresponding display screen based on the analysis results so that the screen content is adapted to the new display direction.

5. The five-element sensor adjustment system for a medical professional display according to claim 1, characterized in that, The human body detection module includes: The continuous scanning submodule is used to install the human body detection sensor in front of the display to ensure full coverage of the detection angle and distance range. Through the detection function of the human body detection sensor, it continuously scans the angle and distance area opposite the display to extract information on whether there is a person in the range. The information processing submodule is used to transmit the acquired information to the processing module, which then analyzes and processes the information according to preset rules.

6. The five-element sensor adjustment system for a medical professional display according to claim 1, characterized in that, The real-time monitoring module includes: The display information submodule is used to continuously scan the display screen and extract display parameter information of brightness, color and grayscale by using the brightness, color and grayscale detection sensors of the LCD screen through the real-time monitoring function of the sensors. The comparison and analysis submodule is used to quickly transmit the acquired display parameter information to the processing module. The processing module performs detailed comparison and analysis on the received parameter information according to the set standard range of GAMMA and DICOM curves.

7. A five-element sensor adjustment system for a medical professional display according to claim 4, characterized in that, The display switching submodule is used to compare and analyze the acquired rotation direction information with the initial set direction. When the display screen switches between landscape and portrait display, the rotation direction information is used as an instruction based on the analysis results to automatically adjust the corresponding display screen so that the screen content adapts to the new display direction.

8. A five-element sensor adjustment system for a medical professional display according to claim 5, characterized in that, The information processing submodule is used to transmit the acquired information to the processing module. The processing module analyzes and processes the information according to preset rules. When the person being judged leaves the display screen, the processing module issues a command to automatically turn off the screen to reduce power consumption. When the person being judged approaches the display screen, the processing module issues another command to automatically turn on the screen.

9. A five-element sensor adjustment system for a medical professional display according to claim 6, characterized in that, The comparison and analysis submodule is used to quickly transmit the acquired display parameter information to the processing module. The processing module performs detailed comparison and analysis on the received parameter information according to the set standard range of GAMMA and DICOM curves. When the parameter is found to deviate from the standard range, an adjustment command is immediately issued. According to the command, the display screen automatically fine-tunes the display parameters to ensure that it remains stable within the standard range of GAMMA and DICOM curves during long-term use.