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CN-121421839-B - Multi-mode data fusion moxibustion constant temperature dynamic control method and device

CN121421839BCN 121421839 BCN121421839 BCN 121421839BCN-121421839-B

Abstract

The invention discloses a multi-mode data fusion moxibustion constant temperature dynamic control method and a device, and relates to the technical field of data processing; the method comprises the steps of obtaining skin subareas, obtaining skin state distribution based on the skin subareas, skin temperature distribution and medicine volatilization distribution, obtaining temperature consistency parameters and volatilization uniformity parameters based on the skin state distribution, obtaining a moxibustion constant temperature dynamic control scheme based on the temperature consistency parameters and the volatilization uniformity parameters, and carrying out moxibustion constant temperature dynamic control. The invention solves the technical problem of poor adaptability of moxibustion control parameters in the prior art.

Inventors

  • ZHAO XIANGXUAN
  • Sun Cuige
  • ZHENG XIAONAN
  • DI QING
  • YU RAN
  • DUAN XIAONAN
  • Sun Guyue

Assignees

  • 辽宁中医药大学

Dates

Publication Date
20260505
Application Date
20251112

Claims (3)

  1. 1. Multi-mode data fusion's moxa-moxibustion constant temperature dynamic control device, its characterized in that includes: the skin state acquisition module is used for acquiring skin temperature distribution and medicine volatilization distribution; The state distribution acquisition module is used for acquiring skin partitions, and acquiring skin state distribution based on the skin partitions, the skin temperature distribution and the medicine volatilization distribution; The consistency analysis module is used for acquiring temperature consistency parameters and volatilization uniformity parameters based on the skin state distribution; The control scheme acquisition module is used for acquiring a moxibustion constant temperature dynamic control scheme based on the temperature consistency parameter and the volatilization uniformity parameter and carrying out moxibustion constant temperature dynamic control; the control method of the multi-mode data fusion moxibustion constant temperature dynamic control device comprises the following steps: Obtaining skin temperature distribution and medicine volatilization distribution; Acquiring a skin partition, and acquiring a skin state distribution based on the skin partition, the skin temperature distribution, and the drug volatilization distribution, comprising: Mapping the skin temperature distribution to the skin subareas, and obtaining subarea average temperature and subarea temperature gradient; Mapping the medicine volatilization distribution to the skin subareas to obtain subarea average volatilization rate and subarea volatilization rate gradient; acquiring skin state distribution based on the partition average temperature, the partition temperature gradient, the partition average volatility and the partition volatility gradient; Based on the skin state distribution, obtaining a temperature uniformity parameter and a volatilization uniformity parameter, comprising: calculating an arithmetic average value of all the partition average temperatures to be used as a global temperature; calculating the deviation between the average temperature of all the skin subareas and the global temperature to obtain a temperature consistency parameter; Calculating an arithmetic average value of the average volatility of all the subareas as a global volatility; Calculating the deviation of the partition average volatilization rate of all the skin partitions and the global volatilization rate, and obtaining volatilization uniformity parameters; based on the temperature uniformity parameter and the volatilization uniformity parameter, a moxibustion constant temperature dynamic control scheme is obtained, and the moxibustion constant temperature dynamic control is performed, which comprises the following steps: Acquiring a current moxibustion control scheme; based on the partition temperature gradient and the partition volatility gradient, obtaining an adjustment amplitude includes: Judging whether the temperature consistency parameter exceeds a temperature consistency threshold value or not, and judging whether the volatilization uniformity parameter exceeds a volatilization uniformity threshold value or not; when the temperature consistency parameter exceeds a temperature consistency threshold, acquiring a first adjustment amplitude based on the partition temperature gradient, wherein the first adjustment amplitude comprises a first power adjustment amplitude and a first time length adjustment amplitude, the first power adjustment amplitude=average partition temperature gradient×a first power adjustment coefficient, the first time length adjustment amplitude=average partition temperature gradient×a first time length adjustment coefficient, and the first power adjustment coefficient and the first time length adjustment coefficient are preset unit values for adjusting power and time length based on the temperature gradient; When the volatilization uniformity parameter exceeds a volatilization uniformity threshold, acquiring a second adjustment amplitude based on the partition volatilization rate gradient, wherein the second adjustment amplitude comprises a second power adjustment amplitude and a second time length adjustment amplitude, wherein the second power adjustment amplitude = average partition volatilization rate gradient x a second power adjustment coefficient; Acquiring a first amplitude weight based on the temperature consistency parameter, the temperature consistency threshold and the skin flatness, wherein the first amplitude weight = [ (|temperature consistency parameter-temperature consistency threshold|/temperature consistency threshold) + (skin flatness ≡average skin flatness) ] ≡2; Based on the volatilization uniformity parameter and the volatilization uniformity threshold, obtaining a second amplitude weight, wherein the second amplitude weight is = [ |volatilization uniformity parameter-volatilization uniformity threshold|/volatilization uniformity threshold ]; Calculating a first volatilization weight based on the first amplitude weight and the second amplitude weight, calculating a second temperature weight based on the second amplitude weight, and calculating an obtained adjustment amplitude weight based on the first amplitude weight, the second amplitude weight, the first volatilization weight and the second temperature weight, wherein the adjustment amplitude weight comprises a temperature adjustment amplitude weight and a volatilization rate adjustment amplitude weight, the first volatilization weight=1-the first amplitude weight, the second temperature weight=1-the second amplitude weight, the temperature adjustment amplitude weight= (first amplitude weight+second temperature weight)/(2), and the volatilization rate adjustment amplitude weight= (second amplitude weight+first volatilization weight)/(2); acquiring the adjustment amplitude based on the first adjustment amplitude, the second adjustment amplitude and the adjustment amplitude weight, wherein the adjustment amplitude comprises a power adjustment amplitude and a duration adjustment amplitude, the power adjustment amplitude=a temperature adjustment amplitude weight×a first power adjustment amplitude+a volatilization adjustment amplitude weight×a second power adjustment amplitude, and the duration adjustment amplitude=a temperature adjustment amplitude weight×a first duration adjustment amplitude+a volatilization adjustment amplitude weight×a second duration adjustment amplitude; based on the adjustment amplitude, the current moxibustion control scheme is adjusted, the moxibustion constant temperature dynamic control scheme is obtained, and the moxibustion constant temperature dynamic control is performed.
  2. 2. The multi-modal data-fusion moxibustion thermostatic dynamic control device according to claim 1, wherein the obtaining of the skin partition comprises: acquiring the skin partition scale based on the moxibustion cup size parameter; based on the skin partition scale, obtaining a skin partition, and obtaining the skin flatness of the skin partition.
  3. 3. The multi-mode data fusion moxibustion thermostatic dynamic control device according to claim 1, wherein the current moxibustion control scheme is adjusted based on the adjustment amplitude, the moxibustion thermostatic dynamic control scheme is obtained, and moxibustion thermostatic dynamic control is performed, further comprising: acquiring a control temperature consistency parameter and a control volatilization uniformity parameter after the constant temperature dynamic control of the moxibustion; And when the control temperature consistency parameter exceeds a temperature consistency threshold or the control volatilization uniformity parameter exceeds a volatilization uniformity threshold, acquiring a control partition temperature gradient and a control partition volatilization rate gradient, and performing iterative optimization on the moxibustion constant temperature dynamic control scheme.

Description

Multi-mode data fusion moxibustion constant temperature dynamic control method and device Technical Field The invention relates to the technical field of data processing, in particular to a multi-mode data fusion moxibustion constant temperature dynamic control method and device. Background Moxibustion is used as an important component of external treatment in traditional Chinese medicine, and is widely applied in the field of health care by virtue of the unique efficacy of warming and dredging channels and collaterals and harmonizing qi and blood. Along with technological progress, traditional open flame moxa-moxibustion is gradually replaced to electron moxa-moxibustion equipment to promote operation security and control convenience. In the prior art, the moxibustion device mostly adopts simple feedback control to realize parameter adjustment, and the method depends on data acquired by a local temperature sensor, and maintains a preset temperature value by adjusting heating power or working time. However, the skin surface of the human body has complex anatomical and physiological characteristics, and the skin in different areas has obvious difference, so that the thermal field is unevenly distributed in the moxibustion process, and the overall effect of the moxibustion is reduced. Disclosure of Invention The application provides a multi-mode data fusion moxibustion constant temperature dynamic control method and device, which are used for solving the technical problem of poor adaptability of moxibustion control parameters in the prior art. In view of the above problems, the application provides a multi-mode data fusion moxibustion constant temperature dynamic control method and device. In a first aspect, the present application provides a method for dynamically controlling a moxibustion constant temperature by multi-modal data fusion, the method comprising: Obtaining skin temperature distribution and medicine volatilization distribution; Acquiring a skin partition, and acquiring a skin state distribution based on the skin partition, the skin temperature distribution and the medicine volatilization distribution; Acquiring a temperature uniformity parameter and a volatilization uniformity parameter based on the skin state distribution; and acquiring a moxibustion constant-temperature dynamic control scheme based on the temperature consistency parameter and the volatilization uniformity parameter, and performing moxibustion constant-temperature dynamic control. In a second aspect, the present application provides a multi-mode data fusion moxibustion thermostatic dynamic control device, including: the skin state acquisition module is used for acquiring skin temperature distribution and medicine volatilization distribution; The state distribution acquisition module is used for acquiring skin partitions, and acquiring skin state distribution based on the skin partitions, the skin temperature distribution and the medicine volatilization distribution; The consistency analysis module is used for acquiring temperature consistency parameters and volatilization uniformity parameters based on the skin state distribution; The control scheme acquisition module is used for acquiring a moxibustion constant temperature dynamic control scheme based on the temperature consistency parameter and the volatilization uniformity parameter and carrying out moxibustion constant temperature dynamic control. One or more technical schemes provided by the application have at least the following technical effects or advantages: The application provides a multi-mode data fusion moxibustion constant temperature dynamic control method and device, which are used for dynamically generating an optimal control scheme by integrating and analyzing multi-mode data such as skin temperature distribution, medicine volatilization distribution and the like and combining skin partition characteristics, thereby remarkably improving the accuracy of temperature control and the uniformity of medicine volatilization in the moxibustion treatment process. Compared with the traditional method, the technical scheme provided by the application remarkably solves the problems of local overheating or insufficient temperature, uneven drug effect permeation and the like caused by single-point monitoring and static control, achieves the aims of keeping the temperature field stable and consistent in the whole moxibustion process, simultaneously promotes the uniform absorption of active ingredients of the moxibustion medicine, and improves the intelligent level of the moxibustion equipment and the technical effect of user experience. Drawings In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the description of the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments of the present invention, and other drawing