CN117275435B - Energy-saving mode management system of medical display screen and control method thereof - Google Patents

Abstract

The application provides an energy-saving mode management system of a medical display screen and a control method thereof, which are characterized in that display screen current data are ablated through a historical medical display screen current value set, so that a historical medical display screen ablating current time sequence is determined, the historical medical display screen ablating current time sequence is subjected to sliding rotation and modulation, a sliding rotation and current time sequence is obtained, a historical current adjacent coefficient of the medical display screen is determined according to the sliding rotation and current time sequence and the historical medical display screen current value set, a historical environment volume time sequence is determined, an environment margin tuning factor of the medical display screen is determined according to the historical environment volume time sequence, a medical display screen current adjusting value of the medical display screen is determined according to the historical current adjacent coefficient and the environment margin tuning factor, the brightness of the medical display screen is adjusted according to the medical display screen current adjusting value, and the energy-saving adjusting response rate of the medical display screen can be improved.

Description

Energy-saving mode management system of medical display screen and control method thereof

Technical Field

The application relates to the technical field of medical display screens, in particular to an energy-saving mode management system of a medical display screen and a control method thereof.

Background

The medical display screen is specially designed for the screen equipment in the medical field, and has the following characteristics: high resolution, accurate color reproduction and contrast to ensure that doctors can accurately view medical images, such as X-rays, CT (Computed Tomography) scans and MRI (Magnetic Resonance Imaging), and in addition, the medical display screen also supports various image processing techniques, such as highlighting abnormal regions and measuring tools, to assist doctors in making diagnosis and treatment decisions, plays an important role in operating rooms, radiology departments and clinical diagnosis, helps to improve the accuracy of medical diagnosis and the treatment effect of patients, is an indispensable tool in medical imaging and medical practice, and provides reliable visual support for medical professionals.

The medical equipment widely uses the display screen with high energy consumption, the energy consumption of medical facilities can be reduced by effective energy-saving control, environmental burden is reduced, and medical cost is reduced.

Disclosure of Invention

The application provides an energy-saving mode management system of a medical display screen and a control method thereof, which are used for solving the technical problem that the energy-saving regulation response rate of the medical display screen is too low.

In order to solve the technical problems, the application adopts the following technical scheme:

in a first aspect, the present application provides a method for controlling an energy saving mode of a medical display screen, including the steps of:

acquiring a historical medical display screen current value set of a medical display screen;

performing display screen current data ablation on the historical medical display screen current value set to obtain a historical medical display screen ablation current value set, and further determining a historical medical display screen ablation current time sequence;

carrying out sliding rotation and modulation on the historical medical display screen ablation current time sequence to obtain sliding rotation and current time sequence, and determining a historical current adjacent coefficient of the medical display screen according to the sliding rotation and current time sequence and the historical medical display screen current value set;

acquiring a historical environment volume value set of a medical display screen, further determining a historical environment volume time sequence, and determining an environment margin tuning factor of the medical display screen according to the historical environment volume time sequence;

And determining a medical display screen current adjustment value of the medical display screen according to the historical current adjacent coefficient and the environmental margin tuning factor, and adjusting the brightness of the medical display screen according to the medical display screen current adjustment value.

In some embodiments, performing display screen current data ablation on the historical medical display screen current value set to obtain the historical medical display screen ablation current value set specifically includes:

normalizing each historical medical display screen current value in the historical medical display screen current value set to obtain a historical normalization current value of each historical medical display screen current value;

taking the set of all the historical normalization current values as a historical normalization current value set;

and eliminating the abnormal current value in the historical normalized current value set to obtain a historical medical display screen ablation current value set.

In some embodiments, removing the abnormal current value in the historical normalized current value set to obtain a historical medical display screen ablation current value set specifically includes:

calculating the average value of all the historical normalization current values in the historical normalization current value set;

selecting a historical normalization current value from the historical normalization current value set, and calculating the difference value between the historical normalization current value and the average value;

When the difference value is larger than a preset difference value threshold value, eliminating the historical normalization current value;

when the difference value is smaller than a preset difference value threshold value, the historical normalization current value is reserved, and the historical normalization current value is used as an ablation current value of a historical medical display screen;

repeating the steps, and judging the rest historical normalized current values to obtain a plurality of historical medical display screen ablation current values;

and taking the obtained set of all the historical medical display screen ablation current values as a set of the historical medical display screen ablation current values.

In some embodiments, determining the historical current abutment coefficients for the medical display according to the sliding and current time sequence and the historical medical display current value set specifically includes:

acquiring sliding window length factor；

Acquisition of the first in the time series of the twitch and the currentIndividual gyrate and current values->；

Acquisition of the first in the time series of the twitch and the currentIndividual gyrate and current values->；

Acquiring the first time sequence of the ablation current of the history medical display screenAblation current value of historical medical display screen +.>；

According to the sliding window length factorThe third party in the time series of the sliding rotation and the current>Individual gyrate and current values- >The third party in the time series of the sliding rotation and the current>Individual gyrate and current values->And +.o in the historical medical display screen ablation current time series>Ablation current value of historical medical display screen +.>Determining a history current proximity coefficient of the medical display screenWherein the historical current abutment coefficient is determined by the following formula:

wherein,a history current approach factor representing the medical display,/->And the total number of the ablation current values of the historical medical display screen in the ablation current time sequence of the historical medical display screen is represented.

In some embodiments, performing the twitch modulation on the historical medical display screen ablation current time sequence to obtain the twitch and current time sequence specifically includes:

selecting a historical medical display screen ablation current value from the historical medical display screen ablation current time sequence;

carrying out sliding rotation and modulation on the historical medical display screen ablation current value to obtain sliding rotation and current values of the historical medical display screen ablation current value;

repeating the steps for the remaining ablation current values of the historical medical display screens to obtain the sliding rotation and current values of the remaining ablation current values of the historical medical display screens;

And sequencing according to the positions of the historical medical display screen ablation current values corresponding to each sliding rotation and current value in the historical medical display screen ablation current time sequence to obtain the sliding rotation and current time sequence.

In some embodiments, the ambient sound values of the medical display are acquired by a sound sensor.

In some embodiments, the medical display is a consultation large screen display.

In a second aspect, the present application provides an energy saving mode management system for a medical display screen, including:

the historical medical display screen current value set acquisition module is used for acquiring a historical medical display screen current value set of the medical display screen;

the historical medical display screen ablation current time sequence determining module is used for performing display screen current data ablation on the historical medical display screen current value set to obtain a historical medical display screen ablation current value set, and further determining a historical medical display screen ablation current time sequence;

the historical current adjacent coefficient determining module is used for carrying out sliding rotation tempering on the historical medical display screen ablation current time sequence to obtain sliding rotation and current time sequence, and determining the historical current adjacent coefficient of the medical display screen according to the sliding rotation and current time sequence and the historical medical display screen current value set;

The environment margin tuning factor determining module is used for acquiring a historical environment volume value set of the medical display screen, further determining a historical environment volume time sequence, and determining an environment margin tuning factor of the medical display screen according to the historical environment volume time sequence;

and the medical display screen brightness adjustment module is used for determining a medical display screen current adjustment value of the medical display screen according to the historical current adjacent coefficient and the environment margin tuning factor and adjusting the brightness of the medical display screen according to the medical display screen current adjustment value.

In a third aspect, the present application provides a computer device comprising a memory storing code and a processor configured to obtain the code and perform the above-described energy saving mode control method of a medical display.

In a fourth aspect, the present application provides a computer readable storage medium storing a computer program which, when executed by a processor, implements the above-described energy saving mode control method for a medical display.

The technical scheme provided by the embodiment of the application has the following beneficial effects:

According to the energy-saving mode management system of the medical display screen and the control method thereof, firstly, a historical medical display screen current value set of the medical display screen is obtained, display screen current data ablation is carried out on the historical medical display screen current value set, a historical medical display screen ablation current value set is obtained, further, a historical medical display screen ablation current time sequence is determined, the historical medical display screen ablation current time sequence is subjected to sliding rotation and modulation, a sliding rotation and current time sequence is obtained, a historical current adjacent coefficient of the medical display screen is determined according to the sliding rotation and current time sequence and the historical medical display screen current value set, a historical environment volume time sequence of the medical display screen is obtained, an environment margin tuning factor of the medical display screen is determined according to the historical environment volume time sequence, a medical display screen current adjustment value of the medical display screen is determined according to the historical current adjacent coefficient and the environment margin tuning factor, the brightness of the medical display screen is adjusted according to the medical display screen current adjustment value, compared with the existing energy-saving mode of the medical display screen, the medical display screen has a delay effect through the medical environment current adjacent coefficient and the medical environment margin tuning factor is determined according to the medical environment current adjacent coefficient, and the medical display screen adjacent coefficient has different environment response factor is determined, and the medical display environment response factor is different from the medical display environment current adjacent coefficient is determined, the medical display screen current adjustment value is used as the next input current of the control circuit of the medical display screen, so that the response time of the medical display screen circuit control system is reduced, and the energy-saving adjustment response rate of the medical display screen is improved.

Drawings

FIG. 1 is a flow chart of an energy saving mode control method for a medical display according to some embodiments of the present application;

FIG. 2 is a flow chart of determining a time sequence of a toboggan and a current in some embodiments of the present application;

FIG. 3 is a block diagram of an energy saving mode management system for a medical display in accordance with some embodiments of the present application;

fig. 4 is a schematic structural diagram of a computer device in some embodiments of the present application.

Detailed Description

The method comprises the steps of performing display screen current data ablation on a historical medical display screen current value set, further determining a historical medical display screen ablation current time sequence, performing twiddling modulation on the historical medical display screen ablation current time sequence to obtain a twiddling modulation and current time sequence, determining a historical current adjacent coefficient of the medical display screen according to the twiddling modulation and current time sequence and the historical medical display screen current value set, determining a historical environment volume time sequence, determining an environment margin tuning factor of the medical display screen according to the historical environment volume time sequence, determining a medical display screen current adjustment value of the medical display screen according to the historical current adjacent coefficient and the environment margin tuning factor, adjusting the brightness of the medical display screen according to the medical display screen current adjustment value, and comparing the current adjacent coefficient and the environment margin tuning factor of the medical display screen in a state adjustment process by determining a current change trend of the medical display screen, wherein the environment margin factor is a medical display screen in a period, and is a medical display screen operating current adjacent coefficient of different environment display screen operation response time adjusting circuit, and the medical display screen response time adjusting value is controlled according to the environment margin tuning factor, and the medical display screen current adjustment value is improved.

In order to better understand the above technical solutions, the following detailed description will refer to the accompanying drawings and specific embodiments. Referring to fig. 1, which is an exemplary flowchart of a method for controlling an energy saving mode of a medical display according to some embodiments of the present application, the method 100 for controlling an energy saving mode of a medical display mainly includes the steps of:

in step 101, a set of historical medical display current values for a medical display is obtained.

When the method is specifically implemented, the display screen for traditional Chinese medicine can be a consultation large-screen display or an operation display screen, the method is not particularly limited herein, in the step, after the medical display screen power supply is connected, an energy-saving mode of the medical display screen is started, a historical medical display screen current value set is obtained from a data storage system of the medical display screen, the historical medical display screen current value set represents a set of all working current values of the medical display screen in a historical time period, the historical time period can be set to be 1 month in the past, the working current value is a current value of the medical display screen during working, and the occurrence time of each current value is recorded.

In step 102, the current value set of the historical medical display screen is subjected to display screen current data ablation to obtain an ablation current value set of the historical medical display screen, and then a time sequence of the ablation current of the historical medical display screen is determined.

In some embodiments, the display screen current data ablation is performed on the historical medical display screen current value set, and obtaining the historical medical display screen ablation current value set can be achieved by adopting the following steps:

normalizing each historical medical display screen current value in the historical medical display screen current value set to obtain a historical normalization current value of each historical medical display screen current value;

taking the set of all the historical normalization current values as a historical normalization current value set;

and eliminating the abnormal current value in the historical normalized current value set to obtain a historical medical display screen ablation current value set.

It should be noted that, medical display screen current data ablation in this application can be through carrying out normalization processing and rejecting abnormal current value to history medical display screen current value set, can improve the reliability of history medical display screen current value set.

When the method is specifically implemented, the current values of each historical medical display screen in the current value set of the historical medical display screen are normalized to obtain historical normalization current values of the current values of each historical medical display screen, namely, the current values of each historical medical display screen in the current value set of the historical medical display screen can be normalized by adopting a unit vector normalization technology in the prior art to obtain historical normalization current values of the current values of each historical medical display screen.

In some embodiments, removing the abnormal current value in the historical normalized current value set to obtain the historical medical display screen ablation current value set may be implemented by the following steps:

calculating the average value of all the historical normalization current values in the historical normalization current value set;

selecting a historical normalization current value from the historical normalization current value set, and calculating the difference value between the historical normalization current value and the average value;

when the difference value is larger than a preset difference value threshold value, eliminating the historical normalization current value;

when the difference value is smaller than a preset difference value threshold value, the historical normalization current value is reserved, and the historical normalization current value is used as an ablation current value of a historical medical display screen;

repeating the steps, and judging the rest historical normalized current values to obtain a plurality of historical medical display screen ablation current values;

and taking the obtained set of all the historical medical display screen ablation current values as a set of the historical medical display screen ablation current values.

It should be noted that, the difference threshold in the application may be set by historical difference experimental data, the value range of the difference threshold is between 0.25 and 0.5, and the magnitude of the difference threshold may be selected according to actual requirements.

When the method is concretely implemented, the time sequence of the ablation current of the historical medical display screen is further determined, namely, the ablation current values of the historical medical display screen are sequenced according to the occurrence time of the current values of the historical medical display screen corresponding to the ablation current values of the historical medical display screen, and the sequenced sequence is used as the historical medical displayScreen ablation current time series, e.g. assuming historical medical display screen ablation current valuesCorresponding to the current value of the history medical display screen +.>The occurrence time of (2) is->Historical medical display screen ablation current value +.>Corresponding to the current value of the history medical display screen +.>The occurrence time of (2) is->Historical medical display screen ablation current valueCorresponding to the current value of the history medical display screen +.>The occurrence time of (2) is->Analogize, history medical display screen ablation current valueCorresponding to the current value of the history medical display screen +.>The occurrence time of (2) is->And, occurrence time ∈ ->Specific time of occurrence->Early, time of occurrence->Specific time of occurrence->Early, time of occurrence->Specific time of occurrence->Early, analogize in turn, occurrence time +.>Specific time of occurrence->Earlier, sorting the ablation current values of the historical medical display screens according to the occurrence time of the current value of the historical medical display screen corresponding to the ablation current value of each historical medical display screen, and adding the sorted sequence +. >As a historical medical display screen ablation current time series.

And 103, carrying out sliding rotation modulation on the historical medical display screen ablation current time sequence to obtain a sliding rotation and current time sequence, and determining a historical current adjacent coefficient of the medical display screen according to the sliding rotation and current time sequence and the historical medical display screen current value set.

In some embodiments, reference is made to fig. 2, which is a schematic flow chart of determining a time sequence of a toboggan and a current in some embodiments of the present application, where the determining of the time sequence of the toboggan and the current may be implemented by the following steps:

in step 1031, selecting a historical medical display screen ablation current value from the historical medical display screen ablation current time sequence;

in step 1032, the historical medical display screen ablation current value is processed by sliding rotation and modulation to obtain the sliding rotation and current value of the historical medical display screen ablation current value;

in step 1033, repeating the above steps for each remaining historical medical display screen ablation current value to obtain a sliding rotation and current value of each remaining historical medical display screen ablation current value;

in step 1034, the positions of the historical medical display screen ablation current values corresponding to each of the twiddle and current values in the historical medical display screen ablation current time sequence are ordered to obtain a twiddle and current time sequence.

In addition, in some embodiments, the sliding rotation and the turning of the historical medical display screen ablation current value are performed, and the sliding rotation and the turning of the historical medical display screen ablation current value can be achieved by adopting the following formula:

wherein,indicating +.f in the time series of the ablation current of the history medical display screen>Sliding and rotating of ablation current values of historical medical display screen and current value +.>Representing a sliding window length factor, ">Indicating +.f in the time series of the ablation current of the history medical display screen>The historical medical display screen ablates the current value.

It should be noted that, the sliding window length factor in the present application may be set according to historical experimental data of the sliding window length factor, where the value range of the sliding window length factor is between 10 and 30 and is an integer, and a larger sliding window length factor indicates a lower real-time performance required for data, and in other embodiments, other methods may be used for setting, which is not limited herein.

In particular, the positions of the corresponding historical medical display screen ablation current values in the historical medical display screen ablation current time sequence are sequenced according to the respective sliding rotation and current values to obtain the sliding rotation and current time sequence, namely, for example, the sliding rotation and current values are assumed to be The corresponding position of the ablation current value of the historical medical display screen in the ablation current time sequence of the historical medical display screen is +.>Let us assume a slick and current value +.>The corresponding position of the ablation current value of the historical medical display screen in the ablation current time sequence of the historical medical display screen is +.>Let us assume a slick and current value +.>The corresponding position of the ablation current value of the historical medical display screen in the ablation current time sequence of the historical medical display screen is +.>By analogy, let us assume a twitch and a current value +.>The corresponding position of the ablation current value of the historical medical display screen in the ablation current time sequence of the historical medical display screen is +.>And, position->In the position of +.>Before, position->In the position of +.>Before, analogize, position +.>In the position of +.>Before, sequencing according to the sequence of the positions of the ablation current values of the historical medical display screen corresponding to the current values of each sliding rotation and the current values in the ablation current time sequence of the historical medical display screen, and marking the sequenced sequence +.>As a time series of twiddle and current.

It should be noted that, the sliding rotation and the demodulation in the application can reduce noise in the historical medical display screen ablation current time sequence, so that trend identification errors of the historical medical display screen ablation current time sequence are reduced.

In some embodiments, determining the historical current abutment coefficients for the medical display from the sliding and current time series and the historical medical display current value set may be accomplished by:

acquiring sliding window length factor；

Acquisition of the first in the time series of the twitch and the currentSliding and rotating adjustmentAnd current value->；

Acquisition of the first in the time series of the twitch and the currentIndividual gyrate and current values->；

Acquiring the first time sequence of the ablation current of the history medical display screenAblation current value of historical medical display screen +.>；

According to the sliding window length factorThe third party in the time series of the sliding rotation and the current>Individual gyrate and current values->The third party in the time series of the sliding rotation and the current>Individual gyrate and current values->And +.o in the historical medical display screen ablation current time series>Ablation current value of historical medical display screen +.>Determining a historical current approach factor of the medical display screen, whichWherein, the historical current adjacent coefficient is determined by adopting the following formula:

wherein,a history current approach factor representing the medical display,/->And the total number of the ablation current values of the historical medical display screen in the ablation current time sequence of the historical medical display screen is represented.

It should be noted that the historical current approach coefficient in the present application reflects the current change trend of the medical display screen in the past period of time.

In step 104, a set of historical environmental volume values of the medical display screen is obtained, a historical environmental volume time sequence is further determined, and an environmental margin tuning factor of the medical display screen is determined according to the historical environmental volume time sequence.

In specific implementation, a historical environment volume value set of the medical display screen is acquired, and then a historical environment volume time sequence is determined, namely, the historical environment volume value set of the medical display screen is acquired from a data storage system of the medical display screen, the historical environment volume value set represents a set of the environment volume values of the medical display screen acquired through a sound sensor in a historical time period, the acquisition time of each environment volume value is recorded, the historical time period can be set to be 1 month in the past, each historical environment volume value in the historical environment volume value set is ordered according to the sequence of the corresponding acquisition time, and the ordered sequence is used as the historical environment volume time sequence.

In some embodiments, determining the environmental margin tuning factor for the medical display from the historical environmental volume time series may be accomplished by:

Acquiring a light sensor calibration coefficient of the medical display screen；

Acquiring an ambient light intensity value of the medical display screen；

Determining a medical display screen working condition checking coefficient of the medical display screen；

Acquiring the first time sequence of the historical environmental volumeHistorical ambient volume value->；

According to the light sensor calibration coefficientThe ambient light intensity value +.>Checking coefficient of the medical display screen working condition>And +.f. in the historical ambient volume time series>Historical ambient volume value->Determining an environmental margin tuning factor of the medical display screen, wherein the environmental margin tuning factor can be determined by adopting the following formula:

wherein,an environmental margin tuning factor representing said medical display screen,>representing the total number of volume values in the historical ambient volume time series.

In the application, the optical sensor calibration coefficient can be obtained by referring to the use description document of the optical sensor, the optical sensor calibration coefficient is used for calibrating the optical sensor, the system error caused by the optical sensor is reduced, and the value range of the optical sensor calibration coefficient is between 0.5 and 0.8; the ambient light intensity value can be obtained through the light sensor; the rated power and the actual power of the medical display screen are obtained, the rated power and the actual power are subjected to difference, the ratio obtained by dividing the absolute value of the difference obtained by the difference by the rated power is used as a medical display screen working condition checking coefficient, the medical display screen working condition checking coefficient is used for calibrating the actual power of the medical display screen, the power error caused by aging of the medical display screen is reduced, the value range of the medical display screen working condition checking coefficient is between 0.01 and 0.3, and the medical display screen working condition checking coefficient can be obtained by adopting other methods in other embodiments, and the medical display screen working condition checking coefficient is not limited herein.

In addition, the environmental margin tuning factor in the application is an adjusting parameter of the medical display screen in different working environments, and the larger the environmental margin tuning factor is, the larger the influence of the environmental factor on the working performance of the medical display screen is.

In step 105, a medical display screen current adjustment value of the medical display screen is determined according to the historical current approach coefficient and the environmental margin tuning factor, and the brightness of the medical display screen is adjusted according to the medical display screen current adjustment value.

In some embodiments, the current adjustment value of the medical display screen is determined according to the historical current adjacent coefficient and the environmental margin tuning factor, when the current adjustment value of the medical display screen is specifically implemented, firstly, the silence current value of the medical display screen is obtained, then, the historical current adjacent coefficient is adjusted by using the environmental margin tuning factor, and the final current adjustment value of the medical display screen is determined according to the adjusted adjustment prediction value and the silence current value of the medical display screen, as a preferred embodiment, the current adjustment value of the medical display screen is determined by adopting the following formula, namely:

wherein,a medical display screen current adjustment value representing the medical display screen,/- >Representing the history current abutment coefficient,/->Representing an environmental margin tuning factor, in->Representing the silence current value of the medical display.

It should be noted that, the silence current value in the present application may be set according to the power of a specific medical display screen, and the minimum value is 0.2, where the silence current value represents the lowest current value in the silence state of the medical display screen.

When the current regulation value of the medical display screen is large, the brightness of the medical display screen is high, and when the current regulation value of the medical display screen is small, the brightness of the medical display screen is dark, so that the automatic regulation of the brightness of the medical display screen is realized, and the energy consumption of the medical display screen is further reduced.

It should be noted that, the current adjustment value of the medical display screen in the present application is used to dynamically adjust the brightness of the medical display screen according to the historical current approach value and the environmental margin correction factor, so as to provide better user experience and reduce energy consumption.

Additionally, in another aspect of the present application, in some embodiments, the present application provides an energy saving mode management system for a medical display, referring to fig. 3, which is a schematic diagram of exemplary hardware and/or software of the energy saving mode management system for a medical display according to some embodiments of the present application, the energy saving mode management system 300 for a medical display includes: the historical medical display screen current value set acquisition module 301, the historical medical display screen ablation current time sequence determination module 302, the historical current adjacent coefficient determination module 303, the environment margin tuning factor determination module 304 and the medical display screen brightness adjustment module 305 are respectively described as follows:

the historical medical display screen current value set acquisition module 301 is mainly used for acquiring a historical medical display screen current value set of a medical display screen by the historical medical display screen current value set acquisition module 301;

the historical medical display screen ablation current time sequence determining module 302 is mainly used for performing display screen current data ablation on the historical medical display screen current value set to obtain the historical medical display screen ablation current value set, so that the historical medical display screen ablation current time sequence is determined;

The historical current adjacent coefficient determining module 303 is mainly used for carrying out sliding rotation harmonization on the historical medical display screen ablation current time sequence to obtain a sliding rotation and current time sequence, and determining the historical current adjacent coefficient of the medical display screen according to the sliding rotation and current time sequence and the historical medical display screen current value set;

the environment margin tuning factor determining module 304 is mainly used for acquiring a historical environment volume value set of the medical display screen, further determining a historical environment volume time sequence, and determining the environment margin tuning factor of the medical display screen according to the historical environment volume time sequence;

the medical display screen brightness adjustment module 305 is mainly used for determining a medical display screen current adjustment value of the medical display screen according to the history current adjacent coefficient and the environment margin tuning factor, and adjusting the brightness of the medical display screen according to the medical display screen current adjustment value.

In addition, the application also provides computer equipment, which comprises a memory and a processor, wherein the memory stores codes, and the processor is configured to acquire the codes and execute the energy-saving mode control method of the medical display screen.

In some embodiments, reference is made to fig. 4, which is a schematic structural diagram of a computer device according to some embodiments of the present application, which uses a method for controlling an energy saving mode of a medical display. The method for controlling the power saving mode of the medical display in the above embodiment may be implemented by a computer device shown in fig. 4, which includes at least one processor 401, a communication bus 402, a memory 403, and at least one communication interface 404.

The processor 401 may be a general purpose central processing unit (central processing unit, CPU), application Specific Integrated Circuit (ASIC) or execution of one or more power saving mode control methods for controlling the medical display in the present application.

Communication bus 402 may include a path to transfer information between the aforementioned components.

The Memory 403 may be, but is not limited to, a read-only Memory (ROM) or other type of static storage device that can store static information and instructions, a random access Memory (random access Memory, RAM) or other type of dynamic storage device that can store information and instructions, or an electrically erasable programmable read-only Memory (electrically erasable programmable read-only Memory, EEPROM), a compact disc (compact disc read-only Memory) or other optical disk storage, optical disk storage (including compact disc, laser disc, optical disc, digital versatile disc, blu-ray disc, etc.), magnetic disk or other magnetic storage device, or any other medium that can be used to carry or store the desired program code in the form of instructions or data structures and that can be accessed by a computer. The memory 403 may be self-contained and be coupled to the processor 401 via the communication bus 402. Memory 403 may also be integrated with processor 401.

The memory 403 is used for storing program codes for executing the embodiments of the present application, and is controlled by the processor 401 to execute the embodiments. The processor 401 is used to execute program code stored in the memory 403. One or more software modules may be included in the program code. The method for controlling the power saving mode of the medical display according to the above embodiment may be implemented by one or more software modules of the processor 401 and the program codes in the memory 403.

The communication interface 404 uses any transceiver-like device for communicating with other devices or communication networks, such as ethernet, radio access network (radio access network, RAN), wireless local area network (wireless local area networks, WLAN), etc.

In a specific implementation, as an embodiment, a computer device may include a plurality of processors, where each of the processors may be a single-core (single-CPU) processor or may be a multi-core (multi-CPU) processor. A processor herein may refer to one or more devices, circuits, and/or processing cores for processing data (e.g., computer program instructions).

The computer device may be a general purpose computer device or a special purpose computer device. In particular implementations, the computer device may be a desktop, laptop, web server, palmtop (personal digital assistant, PDA), mobile handset, tablet, wireless terminal device, communication device, or embedded device. Embodiments of the present application are not limited in the type of computer device.

In addition, the application further provides a computer readable storage medium, wherein the computer readable storage medium stores a computer program, and the computer program realizes the energy-saving mode control method of the medical display screen when being executed by a processor.

In summary, in the energy-saving mode management system of a medical display screen and the control method thereof disclosed in the embodiments of the present application, firstly, a historical medical display screen current value set of the medical display screen is obtained, display screen current data ablation is performed on the historical medical display screen current value set to obtain a historical medical display screen ablation current value set, and then a historical medical display screen ablation current time sequence is determined, the historical medical display screen ablation current time sequence is processed by sliding and modulating to obtain a sliding and current time sequence, a historical current adjacent coefficient of the medical display screen is determined according to the sliding and current time sequence and the historical medical display screen current value set, and then a historical environmental volume time sequence is determined, an environmental margin tuning factor of the medical display screen is determined according to the historical environmental volume time sequence, a medical display screen current adjustment value of the medical display screen is determined according to the historical current adjacent coefficient and the environmental margin tuning factor, the medical display screen current adjustment value is adjusted according to the medical display screen current adjustment value, the medical display screen current adjacent coefficient and the medical display screen current adjustment factor is compared with the existing in the energy-saving mode of the existing medical display screen, the medical display screen has a response to the current adjacent current adjustment factor of the medical display screen in response to the current adjacent coefficient, and the medical display screen has a different environmental margin tuning factor is determined, and the medical environment volume time sequence is determined according to the environmental margin current adjacent coefficient, the medical display screen current adjustment value is used as the next input current of the control circuit of the medical display screen, so that the response time of the medical display screen circuit control system is reduced, and the energy-saving adjustment response rate of the medical display screen is improved.

While preferred embodiments of the present application have been described, additional variations and modifications in those embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. It is therefore intended that the following claims be interpreted as including the preferred embodiments and all such alterations and modifications as fall within the scope of the application.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present application without departing from the spirit or scope of the invention. Thus, if such modifications and variations of the present application fall within the scope of the claims and the equivalents thereof, the present application is intended to cover such modifications and variations.

Claims (7)

1. The energy-saving mode control method of the medical display screen is characterized by comprising the following steps of:

acquiring a historical medical display screen current value set of a medical display screen;

performing display screen current data ablation on the historical medical display screen current value set to obtain a historical medical display screen ablation current value set, and further determining a historical medical display screen ablation current time sequence;

carrying out sliding rotation and modulation on the historical medical display screen ablation current time sequence to obtain sliding rotation and current time sequence, and determining a historical current adjacent coefficient of the medical display screen according to the sliding rotation and current time sequence and the historical medical display screen current value set;

Acquiring a historical environment volume value set of a medical display screen, further determining a historical environment volume time sequence, and determining an environment margin tuning factor of the medical display screen according to the historical environment volume time sequence;

determining a medical display screen current adjustment value of the medical display screen according to the historical current adjacent coefficient and the environmental margin tuning factor, and adjusting the brightness of the medical display screen according to the medical display screen current adjustment value;

the method for obtaining the historical medical display screen ablation current value set comprises the following steps of:

normalizing each historical medical display screen current value in the historical medical display screen current value set to obtain a historical normalization current value of each historical medical display screen current value;

taking the set of all the historical normalization current values as a historical normalization current value set;

removing abnormal current values in the historical normalized current value set to obtain a historical medical display screen ablation current value set;

the method for obtaining the time sequence of the sliding rotation and the current specifically comprises the following steps of:

Selecting a historical medical display screen ablation current value from the historical medical display screen ablation current time sequence;

carrying out sliding rotation and modulation on the historical medical display screen ablation current value to obtain sliding rotation and current values of the historical medical display screen ablation current value;

repeating the steps for the remaining ablation current values of the historical medical display screens to obtain the sliding rotation and current values of the remaining ablation current values of the historical medical display screens;

sequencing according to the positions of the historical medical display screen ablation current values corresponding to each sliding rotation and current value in the historical medical display screen ablation current time sequence to obtain a sliding rotation and current time sequence;

the method comprises the steps of carrying out sliding rotation and modulation on the historical medical display screen ablation current value, and obtaining the sliding rotation and current value of the historical medical display screen ablation current value by adopting the following formula:

wherein,indicating +.f in the time series of the ablation current of the history medical display screen>Sliding and rotating of ablation current values of historical medical display screen and current value +.>Representing a sliding window length factor, ">Indicating +.f in the time series of the ablation current of the history medical display screen>The historical medical display screen ablation current values;

The method for determining the historical current adjacent coefficient of the medical display screen according to the sliding rotation and current time sequence and the historical medical display screen current value set specifically comprises the following steps:

acquiring sliding window length factor；

Acquisition of the first in the time series of the twitch and the currentIndividual gyrate and current values->；

Acquisition of the first in the time series of the twitch and the currentIndividual gyrate and current values->；

Acquiring the first time sequence of the ablation current of the history medical display screenMedical display screen for eliminating historyMelt current value->；

According to the sliding window length factorThe third party in the time series of the sliding rotation and the current>Slip and current valuesThe third party in the time series of the sliding rotation and the current>Individual gyrate and current values->And +.o in the historical medical display screen ablation current time series>Ablation current value of historical medical display screen +.>Determining a historical current proximity coefficient of the medical display screen, wherein the historical current proximity coefficient is determined by adopting the following formula:

wherein,a history current approach factor representing the medical display,/->And the total number of the ablation current values of the historical medical display screen in the ablation current time sequence of the historical medical display screen is represented.

2. The method of claim 1, wherein removing the abnormal current values in the historical normalized current value set to obtain a historical medical display screen ablation current value set comprises:

Calculating the average value of all the historical normalization current values in the historical normalization current value set;

selecting a historical normalization current value from the historical normalization current value set, and calculating the difference value between the historical normalization current value and the average value;

when the difference value is larger than a preset difference value threshold value, eliminating the historical normalization current value;

when the difference value is smaller than a preset difference value threshold value, the historical normalization current value is reserved, and the historical normalization current value is used as an ablation current value of a historical medical display screen;

repeating the steps, and judging the rest historical normalized current values to obtain a plurality of historical medical display screen ablation current values;

and taking the obtained set of all the historical medical display screen ablation current values as a set of the historical medical display screen ablation current values.

3. The method of claim 1, wherein the ambient sound values of the medical display are acquired by a sound sensor.

4. The method of claim 1, wherein the medical display is a consultation large screen display.

5. An energy saving mode management system for a medical display screen, which is controlled by the method of claim 1, wherein the energy saving mode management system for a medical display screen comprises:

The historical medical display screen current value set acquisition module is used for acquiring a historical medical display screen current value set of the medical display screen;

the historical medical display screen ablation current time sequence determining module is used for performing display screen current data ablation on the historical medical display screen current value set to obtain a historical medical display screen ablation current value set, and further determining a historical medical display screen ablation current time sequence;

the historical current adjacent coefficient determining module is used for carrying out sliding rotation tempering on the historical medical display screen ablation current time sequence to obtain sliding rotation and current time sequence, and determining the historical current adjacent coefficient of the medical display screen according to the sliding rotation and current time sequence and the historical medical display screen current value set;

the environment margin tuning factor determining module is used for acquiring a historical environment volume value set of the medical display screen, further determining a historical environment volume time sequence, and determining an environment margin tuning factor of the medical display screen according to the historical environment volume time sequence;

and the medical display screen brightness adjustment module is used for determining a medical display screen current adjustment value of the medical display screen according to the historical current adjacent coefficient and the environment margin tuning factor and adjusting the brightness of the medical display screen according to the medical display screen current adjustment value.

6. A computer device comprising a memory storing code and a processor, wherein the processor is configured to acquire the code and to perform the power saving mode control method of a medical display according to any one of claims 1 to 4.

7. A computer-readable storage medium storing a computer program, wherein the computer program, when executed by a processor, implements the energy saving mode control method of a medical display screen according to any one of claims 1 to 4.