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CN117339118B - Intelligent monitoring and controlling method and system for illumination intensity of infrared therapeutic apparatus - Google Patents

Intelligent monitoring and controlling method and system for illumination intensity of infrared therapeutic apparatus Download PDF

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CN117339118B
CN117339118B CN202311652216.1A CN202311652216A CN117339118B CN 117339118 B CN117339118 B CN 117339118B CN 202311652216 A CN202311652216 A CN 202311652216A CN 117339118 B CN117339118 B CN 117339118B
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therapeutic apparatus
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CN117339118A (en
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游建锋
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Shenzhen Enduoke Medical Co ltd
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    • AHUMAN NECESSITIES
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    • AHUMAN NECESSITIES
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    • A61N5/00Radiation therapy
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    • A61N2005/0658Radiation therapy using light characterised by the wavelength of light used
    • A61N2005/0659Radiation therapy using light characterised by the wavelength of light used infrared
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
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    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
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Abstract

The invention relates to the technical field of medical equipment control, in particular to an intelligent monitoring and controlling method and system for illumination intensity of an infrared therapeutic apparatus. Constructing a three-dimensional dynamic simulation model of the infrared therapeutic instrument through engineering drawing information and standard operation parameter ranges of each unit in the infrared therapeutic instrument; determining the preset illumination intensity required by the infrared light of the infrared therapeutic apparatus when the infrared therapeutic apparatus works to irradiate a preset pathological area according to a preset work plan, and determining the actual illumination intensity required by the infrared light source according to the preset illumination intensity and the predicted loss rate; the method comprises the steps of obtaining actual operation parameters and preset operation parameters of each unit of the infrared therapeutic apparatus based on time sequences in a preset time period, and monitoring and analyzing the operation state of the infrared therapeutic apparatus based on the actual operation parameters and the preset operation parameters. The method can ensure that the illumination intensity of the infrared therapeutic apparatus is always within a safe range in the working process, thereby improving the working effect and efficiency of the infrared therapeutic apparatus.

Description

Intelligent monitoring and controlling method and system for illumination intensity of infrared therapeutic apparatus
Technical Field
The invention relates to the technical field of medical equipment control, in particular to an intelligent monitoring and controlling method and system for illumination intensity of an infrared therapeutic apparatus.
Background
With the increasing growth of the aging society and the increasing attention of people to health care, the demands of people for medical devices and home health care products are also increasing. An infrared therapeutic apparatus is a device commonly used in the medical and rehabilitation fields, and its working principle is based on the thermal effect of infrared light, and when tissue is irradiated by infrared light, light energy is converted into heat energy, resulting in a local temperature rise of the tissue, which promotes blood circulation, cellular metabolism and tissue repair, thereby helping to reduce pain and inflammation. The infrared treatment technology has the advantages of safety, no side effect and the like, and is widely applied clinically. The therapeutic effect of infrared treatment is closely related to the illumination intensity, and the treatment effect is not obvious due to the fact that the illumination intensity is too low, and tissue damage can be caused due to the fact that the illumination intensity is too high, so that it is important to ensure that the illumination intensity in the treatment process is always within a safe range.
Disclosure of Invention
The invention overcomes the defects of the prior art and provides an intelligent monitoring and controlling method and system for the illumination intensity of an infrared therapeutic apparatus.
The technical scheme adopted by the invention for achieving the purpose is as follows:
the invention discloses an intelligent monitoring and controlling method for the illumination intensity of an infrared therapeutic apparatus, which comprises the following steps:
Acquiring actual air medium composition data in an infrared therapeutic apparatus working environment, and determining a predicted loss rate of infrared light emitted when the current actual air medium composition data work according to the actual air medium composition data;
acquiring engineering drawing information of each unit in the infrared therapeutic apparatus, acquiring a standard operation parameter range of each unit, and constructing a three-dimensional dynamic simulation model of the infrared therapeutic apparatus according to the engineering drawing information and the standard operation parameter range of each unit;
acquiring a preset working plan of the infrared therapeutic apparatus, determining the preset illumination intensity required by the infrared therapeutic apparatus to irradiate infrared light to a preset pathological area during working according to the preset working plan, and determining the actual illumination intensity required by an infrared light source according to the preset illumination intensity and a predicted loss rate;
planning a preset operation parameter scheme for the infrared therapeutic apparatus to complete a preset work plan based on the actual illumination intensity required by the infrared light source and a three-dimensional dynamic simulation model of the infrared therapeutic apparatus, generating a corresponding control scheme based on the preset operation parameter scheme, and controlling a unit corresponding to the infrared therapeutic apparatus to work according to the preset operation parameter based on the control scheme;
Acquiring actual operation parameters and preset operation parameters of each unit of the infrared therapeutic apparatus based on a time sequence in a preset time period, and carrying out monitoring analysis on the operation state of the infrared therapeutic apparatus based on the actual operation parameters and the preset operation parameters to obtain a first monitoring result or a second monitoring result;
if the monitoring result is the first monitoring result, continuing to control the operation of the infrared therapeutic apparatus based on the preset operation parameter scheme; and if the monitoring result is the second monitoring result, regulating and controlling the control scheme to obtain a regulated and controlled control scheme, and controlling the operation of the infrared therapeutic apparatus based on the regulated and controlled control scheme.
Further, in a preferred embodiment of the present invention, actual air medium composition data in an operating environment of an infrared therapeutic apparatus is obtained, and a predicted loss rate of infrared light emitted when the current actual air medium composition data operates is determined according to the actual air medium composition data, which specifically includes:
acquiring loss rates of infrared light emitted by an infrared therapeutic instrument under different air medium component data combination conditions through a big data network, constructing a knowledge graph, and importing the loss rates of the infrared light under different air medium component data combination conditions into the knowledge graph;
Acquiring actual air medium component data in an infrared therapeutic apparatus working environment, inputting the actual air medium component data into the knowledge graph, and calculating the association degree between the actual air medium component data and each air medium component data combination by a gray association analysis method to obtain a plurality of association degrees;
establishing a size sorting table, inputting a plurality of association degrees into the size sorting table, sorting the association degrees based on numerical values, and extracting the maximum association degree after sorting is completed;
and acquiring an air medium component data combination corresponding to the maximum association degree, and determining the predicted loss rate of infrared light emitted by the infrared therapeutic instrument when the current actual air medium component data works according to the air medium component data combination corresponding to the maximum association degree.
Further, in a preferred embodiment of the present invention, engineering drawing information of each unit in the infrared therapeutic apparatus is obtained, and a standard operation parameter range of each unit is obtained, and a three-dimensional dynamic simulation model of the infrared therapeutic apparatus is constructed according to the engineering drawing information and the standard operation parameter range of each unit, specifically:
obtaining engineering drawing information of each unit in the infrared therapeutic apparatus, constructing a unit three-dimensional model diagram of each unit according to the engineering drawing information, and marking an assembly reference of each unit in the unit three-dimensional model diagram by combining the engineering drawing information;
Constructing a virtual assembly space, importing the three-dimensional model pictures of each unit into the virtual assembly space, and performing simulation assembly on each unit based on assembly references of the three-dimensional model pictures of each unit to obtain a simulation three-dimensional model picture of the infrared therapeutic instrument;
acquiring product specification information of each unit, and acquiring a standard operation parameter range of each unit according to the product specification information;
and importing the standard operation parameter ranges of the units into the simulated three-dimensional model diagram to obtain a three-dimensional dynamic simulation model of the infrared therapeutic instrument.
Further, in a preferred embodiment of the present invention, a preset operation parameter scheme for completing a preset work plan of the infrared therapeutic apparatus is planned based on the actual illumination intensity required by the infrared light source and the three-dimensional dynamic simulation model of the infrared therapeutic apparatus, specifically:
a plurality of operation parameter schemes are prefabricated according to standard operation parameter ranges of all units in the infrared therapeutic apparatus, and the electric energy loss of a system when the infrared therapeutic apparatus operates under the condition of all operation parameter schemes is obtained;
importing each operation parameter scheme into the three-dimensional dynamic simulation model one by one for simulation so as to obtain real-time illumination intensity of an infrared light source when each unit in the infrared therapeutic apparatus operates under the condition of each operation parameter scheme by simulation, and obtaining a plurality of real-time illumination intensities;
Calculating illumination intensity deviation values between each real-time illumination intensity and the actual illumination intensity one by one to obtain a plurality of illumination intensity deviation values; comparing each illumination intensity deviation value with a preset threshold value;
removing the operation parameter schemes corresponding to the illumination intensity deviation value larger than the preset threshold value, and reserving the operation parameter schemes corresponding to the illumination intensity deviation value not larger than the preset threshold value to obtain operation parameter schemes after primary screening;
acquiring the electric energy loss corresponding to the residual operation parameter schemes in the operation parameter schemes after one-time screening, sorting the electric energy loss corresponding to the residual operation parameter schemes, and extracting the minimum electric energy loss after sorting;
and marking the rest operation parameter scheme corresponding to the minimum electric energy loss as a preset operation parameter scheme of the infrared therapeutic instrument.
Further, in a preferred embodiment of the present invention, the method includes obtaining an actual operation parameter and a preset operation parameter of each unit of the infrared therapeutic apparatus based on a time sequence in a preset time period, and performing monitoring analysis on an operation state of the infrared therapeutic apparatus based on the actual operation parameter and the preset operation parameter to obtain a first monitoring result or a second monitoring result, where the specific steps are as follows:
In the working process of an infrared therapeutic apparatus, acquiring actual operation parameters of each unit based on a time sequence in a preset time period, performing dimension reduction processing on the actual operation parameters based on the time sequence through a PCA algorithm to reduce the dimension of each actual operation parameter into a vector, obtaining first vector data of each actual operation parameter expressed in a vector form, and collecting the first vector data to obtain a first vector number set;
acquiring a preset operation parameter scheme of the infrared therapeutic apparatus, determining preset operation parameters of each unit based on time sequences in a preset time period according to the preset operation parameter scheme, performing dimension reduction processing on the preset operation parameters based on the time sequences through a PCA algorithm to reduce the dimension of each preset operation parameter into a vector, obtaining second vector data of each preset operation parameter expressed in a vector form, and collecting the second vector data to obtain a second vector number set;
constructing and obtaining a plane coordinate system by taking time scales as an X axis and vector sizes as a Y axis; mapping the vectors in the first vector number set into the plane coordinate system to obtain a plurality of first data points based on time sequences, and acquiring coordinate information of each first data point in the plane coordinate system; mapping the vectors in the second vector number set into the plane coordinate system to obtain a plurality of second data points based on time sequences, and obtaining coordinate information of each second data point in the plane coordinate system;
Pairing the first data point and the second data point of each same time node to obtain a plurality of data point pairs, and calculating the Euclidean distance of each data point pair based on the coordinate information of each data point to obtain a plurality of Euclidean distances;
averaging the Euclidean distances to obtain an average Euclidean distance; comparing the average Euclidean distance with a preset average Euclidean distance;
if the average Euclidean distance is not greater than the preset average Euclidean distance, indicating that the actual operation parameters of the corresponding units are normal, and generating a first monitoring result; and if the average Euclidean distance is larger than the preset average Euclidean distance, indicating that the actual operation parameters of the corresponding units are abnormal, marking the corresponding units as abnormal operation units, and generating a second monitoring result.
Further, in a preferred embodiment of the present invention, if the monitoring result is the second monitoring result, the control scheme is regulated and controlled to obtain a regulated and controlled control scheme, and the operation of the infrared therapeutic apparatus is controlled based on the regulated and controlled control scheme, specifically:
prefabricating standard regulation and control measures of each unit in the infrared therapeutic apparatus under various preset operation abnormal parameter combination conditions, constructing a database, and importing the prefabricated various standard regulation and control measures into the database to obtain a characteristic database;
If the monitoring result is the second monitoring result, acquiring the actual operation parameters of the abnormal operation unit; importing actual operation parameters of the abnormal operation unit into the database, and calculating the similarity between the actual operation parameters of the abnormal operation unit and various preset operation abnormal parameter combinations through a gray correlation analysis method to obtain a plurality of similarities;
extracting the maximum similarity from the plurality of similarities, acquiring a preset operation abnormal parameter combination corresponding to the maximum similarity, and determining standard regulation measures of the abnormal operation unit according to the preset operation abnormal parameter combination corresponding to the maximum similarity;
and regulating and controlling the control scheme based on standard regulation and control measures of the abnormal operation unit to obtain a regulated and controlled control scheme, and controlling the operation of the infrared therapeutic apparatus based on the regulated and controlled control scheme.
The invention discloses an intelligent monitoring and controlling system for the illumination intensity of an infrared therapeutic apparatus, which comprises a memory and a processor, wherein an intelligent monitoring and controlling method program for the illumination intensity is stored in the memory, and when the intelligent monitoring and controlling method program for the illumination intensity is executed by the processor, the following steps are realized:
Acquiring actual air medium composition data in an infrared therapeutic apparatus working environment, and determining a predicted loss rate of infrared light emitted when the current actual air medium composition data work according to the actual air medium composition data;
acquiring engineering drawing information of each unit in the infrared therapeutic apparatus, acquiring a standard operation parameter range of each unit, and constructing a three-dimensional dynamic simulation model of the infrared therapeutic apparatus according to the engineering drawing information and the standard operation parameter range of each unit;
acquiring a preset working plan of the infrared therapeutic apparatus, determining the preset illumination intensity required by the infrared therapeutic apparatus to irradiate infrared light to a preset pathological area during working according to the preset working plan, and determining the actual illumination intensity required by an infrared light source according to the preset illumination intensity and a predicted loss rate;
planning a preset operation parameter scheme for the infrared therapeutic apparatus to complete a preset work plan based on the actual illumination intensity required by the infrared light source and a three-dimensional dynamic simulation model of the infrared therapeutic apparatus, generating a corresponding control scheme based on the preset operation parameter scheme, and controlling a unit corresponding to the infrared therapeutic apparatus to work according to the preset operation parameter based on the control scheme;
Acquiring actual operation parameters and preset operation parameters of each unit of the infrared therapeutic apparatus based on a time sequence in a preset time period, and carrying out monitoring analysis on the operation state of the infrared therapeutic apparatus based on the actual operation parameters and the preset operation parameters to obtain a first monitoring result or a second monitoring result;
if the monitoring result is the first monitoring result, continuing to control the operation of the infrared therapeutic apparatus based on the preset operation parameter scheme; and if the monitoring result is the second monitoring result, regulating and controlling the control scheme to obtain a regulated and controlled control scheme, and controlling the operation of the infrared therapeutic apparatus based on the regulated and controlled control scheme.
The invention solves the technical defects existing in the background technology, and has the following beneficial effects: constructing a three-dimensional dynamic simulation model of the infrared therapeutic instrument through engineering drawing information and standard operation parameter ranges of each unit in the infrared therapeutic instrument; determining the preset illumination intensity required by the infrared light of the infrared therapeutic apparatus when the infrared therapeutic apparatus works to irradiate a preset pathological area according to a preset work plan, and determining the actual illumination intensity required by the infrared light source according to the preset illumination intensity and the predicted loss rate; planning a preset operation parameter scheme for the infrared therapeutic apparatus to complete a preset work plan based on the actual illumination intensity required by the infrared light source and a three-dimensional dynamic simulation model of the infrared therapeutic apparatus, generating a corresponding control scheme based on the preset operation parameter scheme, and controlling a unit corresponding to the infrared therapeutic apparatus to work according to the preset operation parameter based on the control scheme; the method comprises the steps of obtaining actual operation parameters and preset operation parameters of each unit of the infrared therapeutic apparatus based on time sequences in a preset time period, and carrying out monitoring analysis on the operation state of the infrared therapeutic apparatus based on the actual operation parameters and the preset operation parameters to obtain a first monitoring result or a second monitoring result. The method can ensure that the illumination intensity of the infrared therapeutic apparatus is always within a safe range in the working process, thereby improving the working effect and efficiency of the infrared therapeutic apparatus.
Drawings
In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the invention, and that other embodiments of the drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.
FIG. 1 is a schematic diagram of a novel therapeutic sheet;
FIG. 2 is a flow chart of a first method for intelligent monitoring and controlling of the illumination intensity of an infrared therapeutic apparatus;
FIG. 3 is a flow chart of a second method for intelligent monitoring and controlling of the illumination intensity of an infrared therapeutic apparatus;
fig. 4 is a system block diagram of an intelligent monitoring and control system for the illumination intensity of an infrared therapeutic apparatus.
Detailed Description
In order that the above-recited objects, features and advantages of the present invention will be more clearly understood, a more particular description of the invention will be rendered by reference to the appended drawings and appended detailed description. It should be noted that, in the case of no conflict, the embodiments of the present application and the features in the embodiments may be combined with each other.
In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced in other ways than those described herein, and therefore the scope of the present invention is not limited to the specific embodiments disclosed below.
As shown in fig. 2, the first aspect of the present invention discloses a method for intelligently monitoring and controlling illumination intensity of an infrared therapeutic apparatus, which comprises the following steps:
s102: acquiring actual air medium composition data in an infrared therapeutic apparatus working environment, and determining a predicted loss rate of infrared light emitted when the current actual air medium composition data work according to the actual air medium composition data;
s104: acquiring engineering drawing information of each unit in the infrared therapeutic apparatus, acquiring a standard operation parameter range of each unit, and constructing a three-dimensional dynamic simulation model of the infrared therapeutic apparatus according to the engineering drawing information and the standard operation parameter range of each unit;
s106: acquiring a preset working plan of the infrared therapeutic apparatus, determining the preset illumination intensity required by the infrared therapeutic apparatus to irradiate infrared light to a preset pathological area during working according to the preset working plan, and determining the actual illumination intensity required by an infrared light source according to the preset illumination intensity and a predicted loss rate;
S108: planning a preset operation parameter scheme for the infrared therapeutic apparatus to complete a preset work plan based on the actual illumination intensity required by the infrared light source and a three-dimensional dynamic simulation model of the infrared therapeutic apparatus, generating a corresponding control scheme based on the preset operation parameter scheme, and controlling a unit corresponding to the infrared therapeutic apparatus to work according to the preset operation parameter based on the control scheme;
s110: acquiring actual operation parameters and preset operation parameters of each unit of the infrared therapeutic apparatus based on a time sequence in a preset time period, and carrying out monitoring analysis on the operation state of the infrared therapeutic apparatus based on the actual operation parameters and the preset operation parameters to obtain a first monitoring result or a second monitoring result;
s112: if the monitoring result is the first monitoring result, continuing to control the operation of the infrared therapeutic apparatus based on the preset operation parameter scheme; and if the monitoring result is the second monitoring result, regulating and controlling the control scheme to obtain a regulated and controlled control scheme, and controlling the operation of the infrared therapeutic apparatus based on the regulated and controlled control scheme.
Further, in a preferred embodiment of the present invention, actual air medium composition data in an operating environment of an infrared therapeutic apparatus is obtained, and a predicted loss rate of infrared light emitted when the current actual air medium composition data operates is determined according to the actual air medium composition data, which specifically includes:
Acquiring loss rates of infrared light emitted by an infrared therapeutic instrument under different air medium component data combination conditions through a big data network, constructing a knowledge graph, and importing the loss rates of the infrared light under different air medium component data combination conditions into the knowledge graph;
acquiring actual air medium component data in an infrared therapeutic apparatus working environment, inputting the actual air medium component data into the knowledge graph, and calculating the association degree between the actual air medium component data and each air medium component data combination by a gray association analysis method to obtain a plurality of association degrees;
establishing a size sorting table, inputting a plurality of association degrees into the size sorting table, sorting the association degrees based on numerical values, and extracting the maximum association degree after sorting is completed;
and acquiring an air medium component data combination corresponding to the maximum association degree, and determining the predicted loss rate of infrared light emitted by the infrared therapeutic instrument when the current actual air medium component data works according to the air medium component data combination corresponding to the maximum association degree.
Among them, air media include gases (oxygen, nitrogen, carbon dioxide, etc.), aerosol particles, dust, etc. The concentration of each component of the air medium may be obtained by a series of sensors or other detection devices, such as obtaining carbon dioxide concentration data by a carbon dioxide concentration sensor.
The main idea of gray correlation analysis is to evaluate the influence degree of factors on a certain target by comparing the correlation degree between the factors, and by calculating the correlation degree function between each factor and the target factor, the functions can be used for representing the correlation degree between the factors and the target.
It should be noted that, the infrared light emitted by the infrared therapeutic apparatus interacts with the air medium in the environment during the propagation process, which may cause absorption and scattering of the light, so as to reduce the intensity of the light, so that the infrared light is emitted by the LED until the infrared light propagates and irradiates the pathological area, and a certain loss, that is, a loss rate, of the infrared light occurs. In addition, under the condition of different air medium component combinations, the propagation characteristics and the loss rate of infrared light are different, and because different gas molecules and particles vibrate and rotate in different modes, the absorption lines of the infrared light are different, and in general, the higher the concentration of each component in the air medium, the more obvious the absorption effect on the infrared light and the higher the loss rate of the infrared light. According to the method, the loss rate of infrared light in the working propagation process can be rapidly and accurately determined according to the air medium composition in the working environment of the infrared therapeutic apparatus, complex algorithm operation is not needed, and the robustness of the system can be improved.
Further, in a preferred embodiment of the present invention, engineering drawing information of each unit in the infrared therapeutic apparatus is obtained, and a standard operation parameter range of each unit is obtained, and a three-dimensional dynamic simulation model of the infrared therapeutic apparatus is constructed according to the engineering drawing information and the standard operation parameter range of each unit, as shown in fig. 3, specifically:
s202: obtaining engineering drawing information of each unit in the infrared therapeutic apparatus, constructing a unit three-dimensional model diagram of each unit according to the engineering drawing information, and marking an assembly reference of each unit in the unit three-dimensional model diagram by combining the engineering drawing information;
s204: constructing a virtual assembly space, importing the three-dimensional model pictures of each unit into the virtual assembly space, and performing simulation assembly on each unit based on assembly references of the three-dimensional model pictures of each unit to obtain a simulation three-dimensional model picture of the infrared therapeutic instrument;
s206: acquiring product specification information of each unit, and acquiring a standard operation parameter range of each unit according to the product specification information;
s208: and importing the standard operation parameter ranges of the units into the simulated three-dimensional model diagram to obtain a three-dimensional dynamic simulation model of the infrared therapeutic instrument.
The infrared therapeutic apparatus includes an emitter, a controller, an illumination unit, a cooling unit, a power supply unit, a safety protection unit, and the like. The engineering drawing information is design drawing information, and comprises size information, assembly reference plane information and the like of each unit. And drawing a unit three-dimensional model diagram of each unit by combining three-dimensional software such as SolidWorks, CAD with engineering drawing information, and then performing simulation assembly on each unit in the three-dimensional software, so as to obtain a simulation three-dimensional model diagram of the infrared therapeutic apparatus. The product specification information of each unit is provided by the manufacturer and includes standard operating parameter ranges of each unit, such as the maximum capacitance and the minimum capacitance of the power supply unit, i.e. the capacitance range. The standard operation parameter range of each unit is converted into a data stream, the data stream is imported into three-dimensional software, and then the simulated three-dimensional model diagram is combined with the data stream, so that a three-dimensional dynamic simulation model of the infrared therapeutic apparatus is obtained, and the three-dimensional dynamic simulation model comprises hardware parameter information and software parameter information of infrared therapy.
It should be noted that, the preset work plan of the infrared therapeutic apparatus is formulated by medical staff according to the pathological condition of the patient, and the preset work plan includes preset irradiation time, preset illumination intensity and the like required for treating the patient region of the patient. In the actual working process of the red light therapeutic apparatus, due to the influence of an air medium, the infrared light can be scattered and absorbed in the propagation process, so that loss is caused, therefore, after the preset illumination intensity required by a patient region of a treated patient is obtained from a preset working plan, the light source intensity of the infrared therapeutic apparatus cannot be determined only according to the preset illumination intensity, if the preset illumination intensity is only enabled to be equal to the light source intensity of the infrared therapeutic apparatus, the infrared light intensity irradiated into a pathological region is smaller due to the loss phenomenon of the infrared light, and the prediction loss rate obtained through calculation in the steps is required, and the actual illumination intensity required by the infrared light source is accurately determined by combining the preset illumination intensity. In conclusion, the method can fully consider the environmental influence, so that the illumination intensity of the light source required by the infrared therapeutic apparatus can be accurately determined, the illumination intensity in the therapeutic process can be ensured to be in a proper range, high-precision control is realized, and the therapeutic effect and efficiency are improved.
Further, in a preferred embodiment of the present invention, a preset operation parameter scheme for completing a preset work plan of the infrared therapeutic apparatus is planned based on the actual illumination intensity required by the infrared light source and the three-dimensional dynamic simulation model of the infrared therapeutic apparatus, specifically:
a plurality of operation parameter schemes are prefabricated according to standard operation parameter ranges of all units in the infrared therapeutic apparatus, and the electric energy loss of a system when the infrared therapeutic apparatus operates under the condition of all operation parameter schemes is obtained;
importing each operation parameter scheme into the three-dimensional dynamic simulation model one by one for simulation so as to obtain real-time illumination intensity of an infrared light source when each unit in the infrared therapeutic apparatus operates under the condition of each operation parameter scheme by simulation, and obtaining a plurality of real-time illumination intensities;
calculating illumination intensity deviation values between each real-time illumination intensity and the actual illumination intensity one by one to obtain a plurality of illumination intensity deviation values; comparing each illumination intensity deviation value with a preset threshold value;
removing the operation parameter schemes corresponding to the illumination intensity deviation value larger than the preset threshold value, and reserving the operation parameter schemes corresponding to the illumination intensity deviation value not larger than the preset threshold value to obtain operation parameter schemes after primary screening;
Acquiring the electric energy loss corresponding to the residual operation parameter schemes in the operation parameter schemes after one-time screening, sorting the electric energy loss corresponding to the residual operation parameter schemes, and extracting the minimum electric energy loss after sorting;
and marking the rest operation parameter scheme corresponding to the minimum electric energy loss as a preset operation parameter scheme of the infrared therapeutic instrument.
It should be noted that, a plurality of operation parameter schemes are prefabricated according to the standard operation parameter ranges of each unit in the infrared therapeutic apparatus. And then, each operation parameter scheme is led into the three-dimensional dynamic simulation model one by one to perform simulation, so that the real-time illumination intensity of the infrared light source when each unit in the infrared therapeutic apparatus operates under the condition of each operation parameter scheme is obtained through simulation, for example, the real-time illumination intensity of the infrared light source when the operation power of the cooling unit is 50W and the voltage of the power supply unit is 5 volts is combined, for example, the luminous efficiency and the performance of the infrared light source are closely related to the temperature, and therefore the real-time illumination intensity of the infrared light source of the cooling unit under each operation power condition needs to be considered. If the illumination intensity deviation value is larger than a preset threshold value, the fact that the deviation between the real-time illumination intensity and the actual illumination intensity of the infrared light source is too large when the operation parameter scheme is operated is indicated, and the fact that if the operation parameter scheme is operated, the light source intensity of the infrared light source does not meet the requirement, at the moment, the corresponding operation parameter scheme is removed to obtain a once-screened operation parameter scheme so as to ensure that the illumination intensity of the infrared therapeutic instrument meets the requirement when the infrared therapeutic instrument works, the electric energy consumption corresponding to the rest operation parameter scheme in the once-screened operation parameter scheme is obtained, the rest operation parameter scheme corresponding to the minimum electric energy consumption is marked as the preset operation parameter scheme of the infrared therapeutic instrument, the operation parameter scheme meeting the requirement on the treatment illumination intensity can be screened out quickly through the step, the operation parameter scheme with the lowest energy consumption can be screened out, the energy consumption of the system can be reduced, and resources are saved.
Further, in a preferred embodiment of the present invention, the method includes obtaining an actual operation parameter and a preset operation parameter of each unit of the infrared therapeutic apparatus based on a time sequence in a preset time period, and performing monitoring analysis on an operation state of the infrared therapeutic apparatus based on the actual operation parameter and the preset operation parameter to obtain a first monitoring result or a second monitoring result, where the specific steps are as follows:
in the working process of an infrared therapeutic apparatus, acquiring actual operation parameters of each unit based on a time sequence in a preset time period, performing dimension reduction processing on the actual operation parameters based on the time sequence through a PCA algorithm to reduce the dimension of each actual operation parameter into a vector, obtaining first vector data of each actual operation parameter expressed in a vector form, and collecting the first vector data to obtain a first vector number set;
acquiring a preset operation parameter scheme of the infrared therapeutic apparatus, determining preset operation parameters of each unit based on time sequences in a preset time period according to the preset operation parameter scheme, performing dimension reduction processing on the preset operation parameters based on the time sequences through a PCA algorithm to reduce the dimension of each preset operation parameter into a vector, obtaining second vector data of each preset operation parameter expressed in a vector form, and collecting the second vector data to obtain a second vector number set;
Constructing and obtaining a plane coordinate system by taking time scales as an X axis and vector sizes as a Y axis; mapping the vectors in the first vector number set into the plane coordinate system to obtain a plurality of first data points based on time sequences, and acquiring coordinate information of each first data point in the plane coordinate system; mapping the vectors in the second vector number set into the plane coordinate system to obtain a plurality of second data points based on time sequences, and obtaining coordinate information of each second data point in the plane coordinate system;
pairing the first data point and the second data point of each same time node to obtain a plurality of data point pairs, and calculating the Euclidean distance of each data point pair based on the coordinate information of each data point to obtain a plurality of Euclidean distances;
averaging the Euclidean distances to obtain an average Euclidean distance; comparing the average Euclidean distance with a preset average Euclidean distance;
if the average Euclidean distance is not greater than the preset average Euclidean distance, indicating that the actual operation parameters of the corresponding units are normal, and generating a first monitoring result; and if the average Euclidean distance is larger than the preset average Euclidean distance, indicating that the actual operation parameters of the corresponding units are abnormal, marking the corresponding units as abnormal operation units, and generating a second monitoring result.
Principal component analysis (Principal Component Analysis, PCA) is a commonly used data dimension reduction technique for reducing the dimension of a data set while retaining as much information as possible. By PCA, the dimensionality of the original data can be reduced to a lower dimensionality while preserving the variance structure of the original data as much as possible. The data after dimension reduction can be used for various tasks such as visualization, model establishment and analysis, and meanwhile, the complexity and storage requirement of the data are reduced.
In the working process of the infrared therapeutic apparatus, the actual operation parameters of each unit based on time sequences are obtained through the sensors in the infrared therapeutic apparatus in a preset time period, for example, the real-time voltage data of the power supply unit is obtained through the voltage sensor, if the average Euclidean distance of each data point pair in the first vector number set and the second vector number set is not larger than the preset average Euclidean distance, the height coincidence of the first vector number set and the second vector number set is indicated, the height coincidence of the actual operation parameters in the corresponding unit and the preset operation parameters is indicated, the parameter operation of the corresponding unit is indicated to be normal, and the operation of the infrared therapeutic apparatus is controlled continuously based on the scheme of the preset operation parameters. If the average euclidean distance between each data point pair in the first vector number set and the second vector number set is greater than the preset average euclidean distance, which indicates that the coincidence ratio between the first vector number set and the second vector number set is lower, which indicates that the coincidence ratio between the actual operation parameter in the corresponding unit and the preset operation parameter is lower, which indicates that the parameter of the corresponding unit operates normally, at this time, the abnormal operation parameter of the corresponding unit needs to be adjusted to avoid that the growth time of each unit operation parameter is continuously abnormal and the illumination intensity of the infrared light source is influenced, for example, the luminous efficiency and the performance of the infrared light source are closely related to the temperature, and if the cooling unit is in an abnormal operation state for a long time, the heat dissipation efficiency is reduced, thereby leading to the increase of the equipment temperature and further influencing the illumination intensity of the infrared light source. The method can reduce the dimension of the original data of the infrared therapeutic apparatus to a lower dimension, thereby reducing the complexity of the data, rapidly analyzing whether the operation parameters of each unit are abnormal, and realizing the intelligent monitoring function.
Further, in a preferred embodiment of the present invention, if the monitoring result is the second monitoring result, the control scheme is regulated and controlled to obtain a regulated and controlled control scheme, and the operation of the infrared therapeutic apparatus is controlled based on the regulated and controlled control scheme, specifically:
prefabricating standard regulation and control measures of each unit in the infrared therapeutic apparatus under various preset operation abnormal parameter combination conditions, constructing a database, and importing the prefabricated various standard regulation and control measures into the database to obtain a characteristic database;
if the monitoring result is the second monitoring result, acquiring the actual operation parameters of the abnormal operation unit; importing actual operation parameters of the abnormal operation unit into the database, and calculating the similarity between the actual operation parameters of the abnormal operation unit and various preset operation abnormal parameter combinations through a gray correlation analysis method to obtain a plurality of similarities;
extracting the maximum similarity from the plurality of similarities, acquiring a preset operation abnormal parameter combination corresponding to the maximum similarity, and determining standard regulation measures of the abnormal operation unit according to the preset operation abnormal parameter combination corresponding to the maximum similarity;
And regulating and controlling the control scheme based on standard regulation and control measures of the abnormal operation unit to obtain a regulated and controlled control scheme, and controlling the operation of the infrared therapeutic apparatus based on the regulated and controlled control scheme.
It should be noted that, standard regulation and control measures of each unit in the infrared therapeutic apparatus under various preset abnormal operation parameter combination conditions are prepared in advance, and the standard regulation and control measures are imported into a database, so as to obtain a characteristic database; and if the monitoring result is the second monitoring result, acquiring the actual operation parameters of the abnormal operation unit, then importing the actual operation parameters of the abnormal operation unit into a characteristic database for pairing retrieval, so as to obtain standard regulation and control measures of the abnormal operation unit, regulating and controlling the control scheme based on the standard regulation and control measures of the abnormal operation unit, obtaining a regulated control scheme, and controlling the operation of the infrared therapeutic apparatus based on the regulated control scheme. The method can regulate the abnormal operation unit, so that the abnormal operation unit returns to the normal parameter range, the influence on the illumination intensity of the infrared light source caused by continuous abnormality of the growth time of each unit operation parameter is avoided, automatic regulation and control are realized, and the problem caused by human errors is reduced.
In addition, the intelligent monitoring and controlling method for the illumination intensity of the infrared therapeutic apparatus further comprises the following steps:
acquiring offset of infrared light emitted by the infrared therapeutic instrument under the combination condition of different air medium component data through a big data network, constructing a second knowledge graph, and importing the offset of the infrared light emitted by the infrared therapeutic instrument under the combination condition of different air medium component data into the second knowledge graph;
acquiring actual air medium component data in an infrared therapeutic apparatus working environment, inputting the actual air medium component data into the knowledge graph, and calculating the correlation degree between the actual air medium component data and each air medium component data combination by a gray correlation analysis method to obtain a plurality of correlation degrees;
establishing a second size sorting table, inputting a plurality of correlations into the second size sorting table so as to sort the correlations based on the values, and extracting the maximum correlations after sorting is completed;
acquiring an air medium component data combination corresponding to the maximum correlation degree, and determining a predicted offset of infrared light emitted by the infrared therapeutic instrument when the current actual air medium component data works according to the air medium component data combination corresponding to the maximum correlation degree;
And acquiring the position information of the pathological area to be treated, acquiring the position information of the infrared light source, and correcting the position information of the infrared light source based on the position information of the pathological area to be treated and the predicted offset.
When infrared light enters one medium from the other medium, the propagation speed of the light is different due to the difference of the refractive indexes of the different mediums, so that the direction of the light is changed. This is because light propagates slower in denser media and faster in thinner media (e.g., air). Thus, when infrared light enters other materials (such as human tissue) from air, it refracts, causing the light to change direction. The method can correct the infrared light refraction phenomenon caused by the air medium so as to ensure that infrared light can accurately irradiate into a pathological region to be treated and improve the working accuracy of equipment.
In addition, the intelligent monitoring and controlling method for the illumination intensity of the infrared therapeutic apparatus further comprises the following steps:
obtaining predicted operation data information of the abnormal operation unit in a preset time period after regulation and control through the standard regulation and control measures;
Acquiring actual operation data information of the abnormal operation unit after regulation and control in a preset time period; calculating a hash value between the actual operation data information and the predicted operation data information through a hash algorithm; comparing the hash value with a preset hash value;
if the hash value is not greater than the preset hash value, a Bayesian network is constructed, and the actual operation data information is imported into the Bayesian network to perform fault prediction, so that the fault probability of the abnormal operation unit is obtained;
and comparing the fault probability with a preset fault probability, and marking the abnormal operation unit as a fault unit if the fault probability is larger than the preset fault probability.
After the abnormal operation unit is regulated, if the hash value between the actual operation data information and the predicted operation data information is too large, the parameters of the regulated abnormal operation unit are still abnormal, and whether the abnormal operation unit has faults or not is further predicted through the Bayesian network pair. By the method, whether each unit in the infrared therapeutic apparatus has faults or not can be automatically monitored.
In addition, the intelligent monitoring and controlling method for the illumination intensity of the infrared therapeutic apparatus further comprises the following steps:
Acquiring temperature information fed back by a temperature sensor through a signal receiver in a preset time period, judging that the temperature information can be received by the receiver in the preset time period, and if the temperature information cannot be received by the receiver, marking the temperature sensor as a fault device;
if yes, extracting the characteristics of the temperature information to obtain delay information of the temperature information fed back by the temperature sensor;
comparing the delay information with preset delay information; and if the delay information is larger than the preset delay information, marking the temperature sensor as a fault device.
It should be noted that, by the above method, whether the temperature sensor has a fault can be detected in a targeted manner, so as to ensure that the temperature sensor can provide reliable data, and avoid the occurrence of treatment safety accidents in the treatment process.
As shown in fig. 4, the second aspect of the present invention discloses an intelligent monitoring and controlling system for illumination intensity of an infrared therapeutic apparatus, the intelligent monitoring and controlling system for illumination intensity includes a memory 11 and a processor 22, the memory 11 stores an intelligent monitoring and controlling method program for illumination intensity, and when the intelligent monitoring and controlling method program for illumination intensity is executed by the processor 22, the following steps are implemented:
Acquiring actual air medium composition data in an infrared therapeutic apparatus working environment, and determining a predicted loss rate of infrared light emitted when the current actual air medium composition data work according to the actual air medium composition data;
acquiring engineering drawing information of each unit in the infrared therapeutic apparatus, acquiring a standard operation parameter range of each unit, and constructing a three-dimensional dynamic simulation model of the infrared therapeutic apparatus according to the engineering drawing information and the standard operation parameter range of each unit;
acquiring a preset working plan of the infrared therapeutic apparatus, determining the preset illumination intensity required by the infrared therapeutic apparatus to irradiate infrared light to a preset pathological area during working according to the preset working plan, and determining the actual illumination intensity required by an infrared light source according to the preset illumination intensity and a predicted loss rate;
planning a preset operation parameter scheme for the infrared therapeutic apparatus to complete a preset work plan based on the actual illumination intensity required by the infrared light source and a three-dimensional dynamic simulation model of the infrared therapeutic apparatus, generating a corresponding control scheme based on the preset operation parameter scheme, and controlling a unit corresponding to the infrared therapeutic apparatus to work according to the preset operation parameter based on the control scheme;
Acquiring actual operation parameters and preset operation parameters of each unit of the infrared therapeutic apparatus based on a time sequence in a preset time period, and carrying out monitoring analysis on the operation state of the infrared therapeutic apparatus based on the actual operation parameters and the preset operation parameters to obtain a first monitoring result or a second monitoring result;
if the monitoring result is the first monitoring result, continuing to control the operation of the infrared therapeutic apparatus based on the preset operation parameter scheme; and if the monitoring result is the second monitoring result, regulating and controlling the control scheme to obtain a regulated and controlled control scheme, and controlling the operation of the infrared therapeutic apparatus based on the regulated and controlled control scheme.
In another embodiment of the present invention, in existing infrared therapeutic apparatus, the temperature of the therapeutic sheet is not detected, and if the temperature of the therapeutic sheet exceeds the standard, unpredictable injury to the user may result. Therefore, in order to ensure the safety of the near infrared therapeutic sheet, it is necessary to monitor the body temperature of the user. This can be achieved by a small sensor that can monitor the body temperature of the user in real time and feed the data back to the controller.
In order to solve the problems, the invention provides a novel treatment sheet, which is composed of a silica gel sleeve 1, a silica gel sleeve 2, a flexible circuit board 3, an LED lamp 4 and a temperature sensor 5 as shown in figure 1. The LED lamp and the highly integrated electronic device temperature sensor are arranged on the circuit board, after the circuit board, the plate and the flexible circuit board are designed, the LED lamp and the sensor are welded on the flexible circuit board, the welded flexible circuit board is sleeved with the silica gel sleeve, glue is applied, the treatment sheet is manufactured, the near infrared host is connected with the treatment sheet, the treatment sheet is fixed on the body to start treatment, the temperature sensor on the treatment sheet can monitor the temperature of the skin of a human body in real time during treatment, and the output is stopped to protect the skin from being scalded when the temperature of the skin of the human body is too high. The silica gel cover provides good comfort for the user, there is LED lamp array on the flexible circuit board, the electronic components temperature sensor of high integration is embedded to the central point of treating the piece, temperature sensor probe exposes the silica gel cover, carry out real-time supervision to the treating piece temperature, when treating piece surface and skin contact, temperature sensor can the temperature on the real-time perception skin surface to give control chip with data transmission, control chip can judge whether the treating piece is overheated according to the temperature threshold value of settlement, if overheated then in time stop heating, avoid causing the damage to the human body. The traditional infrared therapeutic apparatus is easy to overheat skin and generate risks such as scalds, and the near infrared therapeutic sheet with the temperature monitoring and protecting functions can automatically adjust the luminous power, so that the safety and stability in the treatment process are ensured, and meanwhile, the treatment effect can be improved, the pain is relieved, the blood circulation is promoted, the inflammation is eliminated, and the like.
In the several embodiments provided in this application, it should be understood that the disclosed apparatus and method may be implemented in other ways. The above described device embodiments are only illustrative, e.g. the division of the units is only one logical function division, and there may be other divisions in practice, such as: multiple units or components may be combined or may be integrated into another system, or some features may be omitted, or not performed. In addition, the various components shown or discussed may be coupled or directly coupled or communicatively coupled to each other via some interface, whether indirectly coupled or communicatively coupled to devices or units, whether electrically, mechanically, or otherwise.
The units described above as separate units may or may not be physically separate, and units shown as units may or may not be physical units; can be located in one place or distributed to a plurality of network units; some or all of the units may be selected according to actual needs to achieve the purpose of the solution of this embodiment.
In addition, each functional unit in each embodiment of the present invention may be integrated in one processing unit, or each unit may be separately used as one unit, or two or more units may be integrated in one unit; the integrated units may be implemented in hardware or in hardware plus software functional units.
Those of ordinary skill in the art will appreciate that: all or part of the steps for implementing the above method embodiments may be implemented by hardware related to program instructions, and the foregoing program may be stored in a computer readable storage medium, where the program, when executed, performs steps including the above method embodiments; and the aforementioned storage medium includes: a mobile storage device, a Read-Only Memory (ROM), a random access Memory (RAM, random Access Memory), a magnetic disk or an optical disk, or the like, which can store program codes.
Alternatively, the above-described integrated units of the present invention may be stored in a computer-readable storage medium if implemented in the form of software functional modules and sold or used as separate products. Based on such understanding, the technical solutions of the embodiments of the present invention may be embodied in essence or a part contributing to the prior art in the form of a software product stored in a storage medium, including several instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to execute all or part of the methods of the embodiments of the present invention. And the aforementioned storage medium includes: a removable storage device, ROM, RAM, magnetic or optical disk, or other medium capable of storing program code.
The foregoing is merely illustrative embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily think about variations or substitutions within the technical scope of the present invention, and the invention should be covered. Therefore, the protection scope of the invention is subject to the protection scope of the claims.

Claims (7)

1. The intelligent monitoring and controlling method for the illumination intensity of the infrared therapeutic apparatus is characterized by comprising the following steps:
acquiring actual air medium composition data in an infrared therapeutic apparatus working environment, and determining a predicted loss rate of infrared light emitted when working under the current actual air medium composition data condition according to the actual air medium composition data;
acquiring engineering drawing information of each unit in the infrared therapeutic apparatus, acquiring a standard operation parameter range of each unit, and constructing a three-dimensional dynamic simulation model of the infrared therapeutic apparatus according to the engineering drawing information and the standard operation parameter range of each unit;
acquiring a preset working plan of the infrared therapeutic apparatus, determining the preset illumination intensity required by the infrared therapeutic apparatus to irradiate infrared light to a preset pathological area during working according to the preset working plan, and determining the actual illumination intensity required by an infrared light source according to the preset illumination intensity and a predicted loss rate;
Planning a preset operation parameter scheme for the infrared therapeutic apparatus to complete a preset work plan based on the actual illumination intensity required by the infrared light source and a three-dimensional dynamic simulation model of the infrared therapeutic apparatus, generating a corresponding control scheme based on the preset operation parameter scheme, and controlling a unit corresponding to the infrared therapeutic apparatus to work according to the preset operation parameter based on the control scheme;
acquiring actual operation parameters and preset operation parameters of each unit of the infrared therapeutic apparatus based on a time sequence in a preset time period, and carrying out monitoring analysis on the operation state of the infrared therapeutic apparatus based on the actual operation parameters and the preset operation parameters to obtain a first monitoring result or a second monitoring result;
if the monitoring result is the first monitoring result, continuing to control the operation of the infrared therapeutic apparatus based on the preset operation parameter scheme; and if the monitoring result is the second monitoring result, regulating and controlling the control scheme to obtain a regulated and controlled control scheme, and controlling the operation of the infrared therapeutic apparatus based on the regulated and controlled control scheme.
2. The intelligent monitoring and controlling method for the illumination intensity of the infrared therapeutic apparatus according to claim 1, wherein the method is characterized in that the actual air medium composition data in the working environment of the infrared therapeutic apparatus is obtained, and the predicted loss rate of the infrared light emitted when working under the current actual air medium composition data is determined according to the actual air medium composition data, specifically:
Acquiring loss rates of infrared light emitted by an infrared therapeutic instrument under different air medium component data combination conditions through a big data network, constructing a knowledge graph, and importing the loss rates of the infrared light under different air medium component data combination conditions into the knowledge graph;
acquiring actual air medium component data in an infrared therapeutic apparatus working environment, inputting the actual air medium component data into the knowledge graph, and calculating the association degree between the actual air medium component data and each air medium component data combination by a gray association analysis method to obtain a plurality of association degrees;
establishing a size sorting table, inputting a plurality of association degrees into the size sorting table, sorting the association degrees based on numerical values, and extracting the maximum association degree after sorting is completed;
and acquiring an air medium component data combination corresponding to the maximum association degree, and determining the predicted loss rate of infrared light emitted by the infrared therapeutic instrument when the infrared therapeutic instrument works under the current actual air medium component data condition according to the air medium component data combination corresponding to the maximum association degree.
3. The intelligent monitoring and controlling method for the illumination intensity of the infrared therapeutic apparatus according to claim 1, wherein the method is characterized in that engineering drawing information of each unit in the infrared therapeutic apparatus is obtained, standard operation parameter ranges of each unit are obtained, and a three-dimensional dynamic simulation model of the infrared therapeutic apparatus is constructed according to the engineering drawing information and the standard operation parameter ranges of each unit, and specifically comprises the following steps:
Obtaining engineering drawing information of each unit in the infrared therapeutic apparatus, constructing a unit three-dimensional model diagram of each unit according to the engineering drawing information, and marking an assembly reference of each unit in the unit three-dimensional model diagram by combining the engineering drawing information;
constructing a virtual assembly space, importing the three-dimensional model pictures of each unit into the virtual assembly space, and performing simulation assembly on each unit based on assembly references of the three-dimensional model pictures of each unit to obtain a simulation three-dimensional model picture of the infrared therapeutic instrument;
acquiring product specification information of each unit, and acquiring a standard operation parameter range of each unit according to the product specification information;
and importing the standard operation parameter ranges of the units into the simulated three-dimensional model diagram to obtain a three-dimensional dynamic simulation model of the infrared therapeutic instrument.
4. The intelligent monitoring and controlling method for the illumination intensity of the infrared therapeutic apparatus according to claim 1, wherein a preset operation parameter scheme for completing a preset work plan of the infrared therapeutic apparatus is planned based on the actual illumination intensity required by the infrared light source and a three-dimensional dynamic simulation model of the infrared therapeutic apparatus, specifically comprising:
a plurality of operation parameter schemes are prefabricated according to standard operation parameter ranges of all units in the infrared therapeutic apparatus, and the electric energy loss of a system when the infrared therapeutic apparatus operates under the condition of all operation parameter schemes is obtained;
Importing each operation parameter scheme into the three-dimensional dynamic simulation model one by one for simulation so as to obtain real-time illumination intensity of an infrared light source when each unit in the infrared therapeutic apparatus operates under the condition of each operation parameter scheme by simulation, and obtaining a plurality of real-time illumination intensities;
calculating illumination intensity deviation values between each real-time illumination intensity and the actual illumination intensity one by one to obtain a plurality of illumination intensity deviation values; comparing each illumination intensity deviation value with a preset threshold value;
removing the operation parameter schemes corresponding to the illumination intensity deviation value larger than the preset threshold value, and reserving the operation parameter schemes corresponding to the illumination intensity deviation value not larger than the preset threshold value to obtain operation parameter schemes after primary screening;
acquiring the electric energy loss corresponding to the residual operation parameter schemes in the operation parameter schemes after one-time screening, sorting the electric energy loss corresponding to the residual operation parameter schemes, and extracting the minimum electric energy loss after sorting;
and marking the rest operation parameter scheme corresponding to the minimum electric energy loss as a preset operation parameter scheme of the infrared therapeutic instrument.
5. The method for intelligently monitoring and controlling the illumination intensity of the infrared therapeutic apparatus according to claim 1, wherein the method is characterized in that the actual operation parameters and the preset operation parameters of each unit of the infrared therapeutic apparatus based on the time sequence in a preset time period are obtained, and the operation state of the infrared therapeutic apparatus is monitored and analyzed based on the actual operation parameters and the preset operation parameters to obtain a first monitoring result or a second monitoring result, specifically:
In the working process of an infrared therapeutic apparatus, acquiring actual operation parameters of each unit based on a time sequence in a preset time period, performing dimension reduction processing on the actual operation parameters based on the time sequence through a PCA algorithm to reduce the dimension of each actual operation parameter into a vector, obtaining first vector data of each actual operation parameter expressed in a vector form, and collecting the first vector data to obtain a first vector number set;
acquiring a preset operation parameter scheme of the infrared therapeutic apparatus, determining preset operation parameters of each unit based on time sequences in a preset time period according to the preset operation parameter scheme, performing dimension reduction processing on the preset operation parameters based on the time sequences through a PCA algorithm to reduce the dimension of each preset operation parameter into a vector, obtaining second vector data of each preset operation parameter expressed in a vector form, and collecting the second vector data to obtain a second vector number set;
constructing and obtaining a plane coordinate system by taking time scales as an X axis and vector sizes as a Y axis; mapping the vectors in the first vector number set into the plane coordinate system to obtain a plurality of first data points based on time sequences, and acquiring coordinate information of each first data point in the plane coordinate system; mapping the vectors in the second vector number set into the plane coordinate system to obtain a plurality of second data points based on time sequences, and obtaining coordinate information of each second data point in the plane coordinate system;
Pairing the first data point and the second data point of each same time node to obtain a plurality of data point pairs, and calculating the Euclidean distance of each data point pair based on the coordinate information of each data point to obtain a plurality of Euclidean distances;
averaging the Euclidean distances to obtain an average Euclidean distance; comparing the average Euclidean distance with a preset average Euclidean distance;
if the average Euclidean distance is not greater than the preset average Euclidean distance, indicating that the actual operation parameters of the corresponding units are normal, and generating a first monitoring result; and if the average Euclidean distance is larger than the preset average Euclidean distance, indicating that the actual operation parameters of the corresponding units are abnormal, marking the corresponding units as abnormal operation units, and generating a second monitoring result.
6. The intelligent monitoring and controlling method for the illumination intensity of the infrared therapeutic apparatus according to claim 5, wherein if the monitoring result is the second monitoring result, the controlling scheme is regulated and controlled to obtain a regulated and controlled controlling scheme, and the operation of the infrared therapeutic apparatus is controlled based on the regulated and controlled controlling scheme, specifically comprising:
prefabricating standard regulation and control measures of each unit in the infrared therapeutic apparatus under various preset operation abnormal parameter combination conditions, constructing a database, and importing the prefabricated various standard regulation and control measures into the database to obtain a characteristic database;
If the monitoring result is the second monitoring result, acquiring the actual operation parameters of the abnormal operation unit; importing actual operation parameters of the abnormal operation unit into the database, and calculating the similarity between the actual operation parameters of the abnormal operation unit and various preset operation abnormal parameter combinations through a gray correlation analysis method to obtain a plurality of similarities;
extracting the maximum similarity from the plurality of similarities, acquiring a preset operation abnormal parameter combination corresponding to the maximum similarity, and determining standard regulation measures of the abnormal operation unit according to the preset operation abnormal parameter combination corresponding to the maximum similarity;
and regulating and controlling the control scheme based on standard regulation and control measures of the abnormal operation unit to obtain a regulated and controlled control scheme, and controlling the operation of the infrared therapeutic apparatus based on the regulated and controlled control scheme.
7. The intelligent illumination intensity monitoring and controlling system of the infrared therapeutic apparatus is characterized by comprising a memory and a processor, wherein an intelligent illumination intensity monitoring and controlling method program is stored in the memory, and when the intelligent illumination intensity monitoring and controlling method program is executed by the processor, the following steps are realized:
Acquiring actual air medium composition data in an infrared therapeutic apparatus working environment, and determining a predicted loss rate of infrared light emitted when working under the current actual air medium composition data condition according to the actual air medium composition data;
acquiring engineering drawing information of each unit in the infrared therapeutic apparatus, acquiring a standard operation parameter range of each unit, and constructing a three-dimensional dynamic simulation model of the infrared therapeutic apparatus according to the engineering drawing information and the standard operation parameter range of each unit;
acquiring a preset working plan of the infrared therapeutic apparatus, determining the preset illumination intensity required by the infrared therapeutic apparatus to irradiate infrared light to a preset pathological area during working according to the preset working plan, and determining the actual illumination intensity required by an infrared light source according to the preset illumination intensity and a predicted loss rate;
planning a preset operation parameter scheme for the infrared therapeutic apparatus to complete a preset work plan based on the actual illumination intensity required by the infrared light source and a three-dimensional dynamic simulation model of the infrared therapeutic apparatus, generating a corresponding control scheme based on the preset operation parameter scheme, and controlling a unit corresponding to the infrared therapeutic apparatus to work according to the preset operation parameter based on the control scheme;
Acquiring actual operation parameters and preset operation parameters of each unit of the infrared therapeutic apparatus based on a time sequence in a preset time period, and carrying out monitoring analysis on the operation state of the infrared therapeutic apparatus based on the actual operation parameters and the preset operation parameters to obtain a first monitoring result or a second monitoring result;
if the monitoring result is the first monitoring result, continuing to control the operation of the infrared therapeutic apparatus based on the preset operation parameter scheme; and if the monitoring result is the second monitoring result, regulating and controlling the control scheme to obtain a regulated and controlled control scheme, and controlling the operation of the infrared therapeutic apparatus based on the regulated and controlled control scheme.
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