CN114376531B - Diagnosis and treatment integrated health management system based on energy medicine - Google Patents

Abstract

The invention provides a health analysis system and a diagnosis and treatment integrated health management system based on energy medicine, which comprises the following components: module M1: acquiring a first human thermal image by controlling thermal image acquisition equipment; module M2: carrying out full-image scanning on the first human body thermal image to obtain each lattice temperature, calculating to form isotherms, and calculating to obtain a temperature radiation abnormal region by utilizing the temperature of the isotherms and the basic body temperature of the corresponding region; module M3: mapping the temperature radiation abnormal region to a human anatomy diagram in a cloud database to obtain organ projection of the temperature radiation abnormal region; module M4: acquiring the description information of an individual corresponding to the first human thermal image, and comparing the description information with the set information in the cloud database to obtain a final comparison result; and according to the final comparison result, combining organ projection of the temperature radiation abnormal region to obtain a thermal image analysis result. The invention discovers the disease risk of human body through the thermal image acquisition device and accurately locates the body surface projection part of the focus position.

Description

Diagnosis and treatment integrated health management system based on energy medicine

Technical Field

The invention relates to the technical field of health management systems of energy medicine, in particular to a diagnosis and treatment integrated health management system based on energy medicine, and more particularly relates to a thermal image acquisition and analysis system and a diagnosis and treatment integrated health management system based on energy medicine.

Background

Modern medical imaging techniques including Magnetic Resonance (MRI), ultrasound, PET scanning and nuclear medicine imaging have become fundamental methods for human medical diagnosis, which can provide tissue structures of the human body, but thermal images acquired by infrared cameras cannot intuitively derive specific conditions of each component of a test person, manual inquiry and positioning of the examined region are required, and the provided thermal images cannot fully reflect or predict functional changes in human organs.

Patent document CN208525665U (application number: 201721323014.2) discloses an energy medical treatment bed, including bedstead, physiotherapy mattress, infrared storehouse and negative potential generator, the physiotherapy mattress is fixed at the middle part of bedstead, and the physiotherapy mattress includes mattress support layer, heating plate layer and germanium mattress layer, mattress support layer is fixed on the bedstead, and the top of mattress support layer is fixed with the heating plate layer, be equipped with the hot plate in the heating plate layer, and the top of heating plate layer is fixed with the germanium bed layer, infrared storehouse has been placed on the top of germanium bed layer, the outside in infrared storehouse is fixed with the handle, and the inboard in infrared storehouse is fixed with far infrared lamp, the outside of far infrared lamp is equipped with the guard shield, the inboard in infrared storehouse is fixed to the guard shield, the rear end of bedstead is fixed with negative potential generator.

Patent document CN105559747a (application number: 201510796694.9) discloses a human viscera organ evaluation method based on infrared medical image, which comprises: setting a human viscera organ evaluation system based on infrared medical images, wherein the human viscera organ evaluation system comprises a far infrared lens, infrared thermal imaging equipment, a human body surface partitioning module, an image processing module, a viscera organ temperature arrangement module, a comparison module and an evaluation analysis module; the far infrared lens collects body surface infrared waves of the user, and the infrared thermal imaging equipment processes the infrared waves to obtain an infrared image of the user; the human body surface partitioning module divides the human body surface into heart, liver, spleen, lung, kidney, gall bladder, stomach, large intestine, small intestine and bladder areas; the image processing module calculates the temperature of each viscera area of the user; the viscera temperature arrangement module is used for arranging the temperatures of viscera areas from high to low; the comparison module compares the arrangement result of the viscera region temperature with the arrangement result of viscera energy in the traditional Chinese medicine classical theory; the evaluation analysis module obtains abnormal conditions of viscera and organs of the user.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a thermal image acquisition and analysis system and an energy medicine-based diagnosis and treatment integrated health management system.

According to the invention, a thermal image acquisition and analysis system comprises:

module M1: acquiring a first human thermal image by controlling thermal image acquisition equipment;

module M2: carrying out full-image scanning on the acquired first human body thermal image to obtain each lattice temperature, calculating to form an isotherm, and calculating to obtain a temperature radiation abnormal region by utilizing the temperature of the isotherm and the basic body temperature of the corresponding region;

module M3: mapping the temperature radiation abnormal region to a human anatomy diagram in a cloud database to obtain organ projection of the temperature radiation abnormal region;

module M4: acquiring the description information of an individual corresponding to the first human thermal image, and comparing the description information with the set information in the cloud database to obtain a final comparison result; and according to the final comparison result, combining organ projection of the temperature radiation abnormal region to obtain a thermal image analysis result.

Preferably, the first thermal image of the human body is acquired by controlling the thermal image acquisition equipment; carrying out full-image scanning on the first human body thermal image to obtain the temperature of each point array and calculating to form an isotherm; and calculating the average temperature of the first human body thermal image based on the temperature of each lattice and the formed isotherm, calculating the temperature difference and the area of the radiation abnormal region by utilizing the temperature of the isotherm and the basic body temperature of the corresponding region, and setting the corresponding alarm level based on the calculated temperature difference.

Preferably, the setting information in the cloud database includes: symptom data and pathology image data of corresponding symptoms in the cloud database;

in the module M4: acquiring descriptive symptom information of an individual corresponding to the first human thermal image, and comparing the descriptive symptom information with symptom data in a cloud database to obtain a second comparison result; mapping the second comparison result to pathological image data of the corresponding symptoms in the cloud database to obtain a final analysis result; and combining the final analysis result with the organ projection of the temperature radiation abnormal region to obtain an abnormal analysis result of the organ corresponding to the temperature radiation abnormal region.

According to the invention, the diagnosis and treatment integrated health management system based on energy medicine comprises:

module S1: acquiring a first human thermal image by controlling thermal image acquisition equipment;

module S2: carrying out full-image scanning on the acquired first human body thermal image to obtain each lattice temperature, calculating to form an isotherm, and calculating to obtain a temperature radiation abnormal region by utilizing the temperature of the isotherm and the basic body temperature of the corresponding region;

module S3: mapping the temperature radiation abnormal region to a human anatomy diagram in a cloud database to obtain organ projection of the temperature radiation abnormal region;

Module S4: acquiring the description information of an individual corresponding to the first human thermal image, and comparing the description information with the set information in the cloud database to obtain a final comparison result; determining an viscera abnormality analysis result corresponding to the temperature radiation abnormality region according to the final comparison result and the viscera projection of the temperature radiation abnormality region;

module S5: matching and attaching the human body acupoint map and the first human body thermal image map, collecting acupoint position pixels based on organ projection of the temperature radiation abnormal region, and determining the acupoint names and the meridians where the organs corresponding to the temperature radiation abnormal region are located;

module S6: based on the viscera abnormality analysis result corresponding to the temperature radiation abnormality region, controlling the physiotherapy equipment to execute physiotherapy work to the corresponding acupoints according to the acupoint names and the channels and collaterals;

module S7: re-acquiring a second human body thermal image after physiotherapy by physiotherapy equipment, and comparing the second human body thermal image after physiotherapy with the original first human body thermal image in curative effect.

Preferably, the first thermal image of the human body is acquired by controlling the thermal image acquisition equipment; carrying out full-image scanning on the first human body thermal image to obtain the temperature of each point array and calculating to form an isotherm; and calculating the average temperature of the first human body thermal image based on the temperature of each lattice and the formed isotherm, calculating the temperature difference and the area of the radiation abnormal region by utilizing the temperature of the isotherm and the basic body temperature of the corresponding region, and setting the corresponding alarm level based on the calculated temperature difference.

Preferably, the preset standard human body thermal image is a healthy human body thermal image.

Preferably, the setting information in the cloud database includes: symptom data and pathology image data of corresponding symptoms in the cloud database;

in the module M4: acquiring descriptive symptom information of an individual corresponding to the first human thermal image, and comparing the descriptive symptom information with symptom data in a cloud database to obtain a second comparison result; mapping the second comparison result to pathological image data of the corresponding symptoms in the cloud database to obtain a final analysis result; and combining the final analysis result with the organ projection of the temperature radiation abnormal region to obtain an abnormal analysis result of the organ corresponding to the temperature radiation abnormal region.

Preferably, in said module S6: based on the abnormal analysis result of the viscera corresponding to the abnormal temperature radiation area, acupoint combination is carried out according to the acupoint names and the meridians, and the physiotherapy equipment is controlled to output pulse current to the acupoints of the acupoint combination;

the way of matching the acupoints comprises the following steps: setting the acupoints corresponding to the abnormal temperature radiation areas as main acupoints and connecting the main acupoints with the negative electrode of the physiotherapy equipment, and taking 1-2 acupoints; the acupoint selection is connected with the positive electrode of the physiotherapy equipment, 4-6 acupoints are selected, and the far-end acupoints are selected from far-end acupoints of the same name of the far-end of the hand and the far-end acupoints of the exterior and interior meridians.

Preferably, the method comprises the steps of,

when the acquired abnormal temperature radiation area is the acupoint of the back bladder meridian, performing acupoint combination by using a remote acupoint matching method;

when the acquired abnormal temperature radiation area is an acupoint on the front surface of the trunk, the acupoint is set as a main acupoint and is connected with the cathode of the physiotherapy equipment; the acupoint matching is connected with the positive electrode of the physiotherapy equipment, the acupoint is the far-end acupoint of the meridian where the main acupoint is located, and if the pain is the pain, the far-end acupoint is selected; in the case of inflammation, a starter pool; if the viscera are in question, the original acupoint is allocated;

when the obtained abnormal temperature radiation area is an upper limb acupoint, the acupoint is set as a main acupoint and is connected with the negative electrode of the physiotherapy equipment; the acupoint matching is connected with the positive electrode of the physiotherapy equipment, and the big vertebral acupoint is selected;

when the obtained abnormal temperature radiation area is a lower limb acupoint, the acupoint is set as a main acupoint and is connected with the negative electrode of the physiotherapy equipment; the acupoint matching is connected with the positive electrode of the physiotherapy equipment, and Mingmen acupoint selection is performed;

when the obtained abnormal temperature radiation area is a head and face acupoint, the acupoint is set as a main acupoint and is connected with the negative electrode of the physiotherapy equipment; the acupoint matching is connected with the positive electrode of the physiotherapy equipment, the cereal is taken, and newly-set acupoints and/or yang-reaching acupoints are added according to the requirement.

Preferably, in said module S7:

module S7.1: acquiring a conditioned second human thermal image by controlling thermal image acquisition equipment;

Module S7.2: comparing and analyzing the original first human body thermal image with the second human body thermal image with the same angle after conditioning to obtain a curative effect comparison result;

in the module S7.2: temperature comparison is carried out on the same temperature radiation abnormal region to obtain temperature difference change of the temperature radiation abnormal region, and a comparison table is formed;

the comparison table includes: the early warning level, the highest temperature, the lowest temperature, the temperature difference and the range area of the temperature radiation abnormal region.

Compared with the prior art, the invention has the following beneficial effects:

1. according to the invention, the body surface projection part of the temperature radiation abnormal region is accurately positioned by the thermal image acquisition device;

2. according to the invention, the meridian point simulation diagram is attached to the human body thermal image diagram, the names of the points in the abnormal temperature radiation area are positioned, the physiotherapy equipment is controlled to output pulse current to the points in the group of points, and the local circulation metabolism is improved;

3. the invention controls the meridian leveling instrument based on the high-pressure low-frequency unidirectional rectangular wave pulse current to output pulse current to the acupoints of the group acupoints, and the pulse current accurately acts on the abnormal temperature radiation area, so that the meridian leveling therapy is green, noninvasive and free of side effects;

4. the invention combines the thermal image acquisition device and the meridian leveling therapy physiotherapy system, finds out the abnormal region of the human body temperature radiation according to the thermal image acquisition device, further upgrades the meridian leveling therapy into a software intelligent acupoint allocation system, individuates dialectical treatment and guides the leveling clinical practice; and after the treatment course treatment operation, performing image capturing analysis by a thermal image acquisition device to obtain curative effect comparison.

Drawings

Other features, objects and advantages of the present invention will become more apparent upon reading of the detailed description of non-limiting embodiments, given with reference to the accompanying drawings in which:

fig. 1 is a flow chart of early warning analysis of a disease risk part by medical thermal diagnosis of a thermal image acquisition device.

Fig. 2 is a flow chart of an intelligent acupoint-matching system for meridian flattening therapy.

Fig. 3 is a flow chart of the efficacy comparison software.

Fig. 4 is a schematic illustration of a thermal image of a human body.

Fig. 5 is a schematic illustration of a thermal image of a human body.

Fig. 6 is a schematic diagram showing a comparison of the first thermal image of the human body with the second thermal image of the human body.

Detailed Description

The present invention will be described in detail with reference to specific examples. The following examples will assist those skilled in the art in further understanding the present invention, but are not intended to limit the invention in any way. It should be noted that variations and modifications could be made by those skilled in the art without departing from the inventive concept. These are all within the scope of the present invention.

Example 1

According to the invention, a thermal image acquisition and analysis system comprises:

module M1: the first human thermal image is acquired by controlling thermal image acquisition equipment, and the thermal image acquisition device comprises a thermal imager. Specifically, in the module M1, the thermal image capturing device is controlled to obtain thermal images of the head and face, the chest, the upper body, the lower body, the front, the back, the right 45 degrees, and the left 45 degrees of the whole body of the first human body, and store the obtained thermal images of each angle of each part of the first human body to the cloud.

Module M2: carrying out full-image scanning on the obtained first human body thermal image to obtain each lattice temperature, calculating to form an isotherm, and calculating to obtain the range and the area of the temperature difference and the abnormal temperature radiation region by utilizing the temperature of high radiation or low radiation in the isotherm and the basic body temperature of the corresponding region; the temperature radiation abnormality includes an increase or decrease in temperature. The temperature above the basal body temperature is the temperature of high radiation; the temperature below the base body temperature is a low radiation temperature;

module M3: mapping the temperature radiation abnormal region to a human anatomy diagram in a cloud database to obtain organ projection of the temperature radiation abnormal region. Specifically, the temperature radiation abnormal region in the first human thermal image is mapped to a human anatomy figure, and the human anatomy figure is stored in a cloud database to obtain a specific part of viscera, wherein the temperature abnormality phenomenon occurs.

Module M4: acquiring the description information of an individual corresponding to the first human thermal image, and comparing the description information with the set information in the cloud database to obtain a final comparison result; and according to the final comparison result, combining organ projection of the temperature radiation abnormal region to obtain a thermal image analysis result. The setting information in the cloud database comprises: symptom data and pathology image data of corresponding symptoms in the cloud database. Specifically, acquiring descriptive symptom information of an individual corresponding to the first human thermal image, and comparing the descriptive symptom information with symptom data in a cloud database to obtain symptom data corresponding to the descriptive symptom information in the cloud database; mapping the symptom data corresponding to the described symptom information in the cloud database to the pathology image data of the corresponding symptoms in the cloud database to obtain pathology image data of the corresponding symptoms; and combining pathological image data of the corresponding symptoms with organ projection of the temperature radiation abnormal region, so as to obtain a specific symptom analysis result of the organ with abnormal temperature.

More specifically, as shown in fig. 1, n images to be processed of a first human body are acquired by a thermal image acquisition device; carrying out full-image scanning on each image, measuring the temperature of each lattice, and calculating to form an isotherm; and calculating the average temperature of each image based on the temperatures of the lattices and the formed isotherms, and obtaining a high-temperature region and a low-temperature region in each image. The high temperature area and the low temperature area are different in base temperature of each person relative to the temperature of the individual, the base temperature of different areas of the same individual is different, and the high temperature area and the low temperature area are relative to the base temperature of the areas. In general, there is an inflammatory region, an abnormal temperature, and a clear boundary with normal tissue. Obtaining basic temperature of most of human body in a selected human body region, identifying and obtaining the highest temperature or the lowest temperature of the region, and comparing the highest temperature or the lowest temperature with the basic temperature, wherein the temperature difference is the highest temperature-the basic temperature; the temperature difference= |minimum temperature-base temperature|, and corresponding alarm levels and alarm information are set based on the calculated temperature differences of all areas. For example: the method comprises the steps of displaying first-level warning information, displaying second-level warning information, displaying third-level warning information, displaying fourth-level warning information, displaying fifth-level warning information and displaying fifth-level warning information.

The thermal image acquisition and analysis method provided by the invention comprises the following steps:

step M1: the first human thermal image is acquired by controlling thermal image acquisition equipment, and the thermal image acquisition device comprises a thermal imager. Specifically, in the step M1, the thermal image capturing device is controlled to obtain thermal images of the head and face, the chest, the upper body, the lower body, the front side, the back side, the right side 45 degrees and the left side 45 degrees of the whole body of the first human body, and store the obtained thermal images of each angle of each part of the first human body to the cloud.

Step M2: carrying out full-image scanning on the obtained first human body thermal image to obtain each lattice temperature, calculating to form an isotherm, and calculating to obtain the range and the area of the temperature difference and the abnormal temperature radiation region by utilizing the temperature of high radiation or low radiation in the isotherm and the basic body temperature of the corresponding region; the temperature radiation abnormality includes an increase or decrease in temperature. The temperature above the basal body temperature is the temperature of high radiation; the temperature below the base body temperature is a low radiation temperature;

step M3: mapping the temperature radiation abnormal region to a human anatomy diagram in a cloud database to obtain organ projection of the temperature radiation abnormal region. Specifically, the temperature radiation abnormal region in the first human thermal image is mapped to a human anatomy figure, and the human anatomy figure is stored in a cloud database to obtain a specific part of viscera, wherein the temperature abnormality phenomenon occurs.

Step M4: acquiring the description information of an individual corresponding to the first human thermal image, and comparing the description information with the set information in the cloud database to obtain a final comparison result; and according to the final comparison result, combining organ projection of the temperature radiation abnormal region to obtain a thermal image analysis result. The setting information in the cloud database comprises: symptom data and pathology image data of corresponding symptoms in the cloud database. Specifically, acquiring descriptive symptom information of an individual corresponding to the first human thermal image, and comparing the descriptive symptom information with symptom data in a cloud database to obtain symptom data corresponding to the descriptive symptom information in the cloud database; mapping the symptom data corresponding to the described symptom information in the cloud database to the pathology image data of the corresponding symptoms in the cloud database to obtain pathology image data of the corresponding symptoms; and combining pathological image data of the corresponding symptoms with organ projection of the temperature radiation abnormal region, so as to obtain a specific symptom analysis result of the organ with abnormal temperature.

More specifically, as shown in fig. 1, n images to be processed of a first human body are acquired by a thermal image acquisition device; carrying out full-image scanning on each image, measuring the temperature of each lattice, and calculating to form an isotherm; and calculating the average temperature of each image based on the temperatures of the lattices and the formed isotherms, and obtaining a high-temperature region and a low-temperature region in each image. The high temperature area and the low temperature area are different in base temperature of each person relative to the temperature of the individual, the base temperature of different areas of the same individual is different, and the high temperature area and the low temperature area are relative to the base temperature of the areas. In general, there is an inflammatory region, an abnormal temperature, and a clear boundary with normal tissue. Obtaining basic temperature of most of human body in a selected human body region, identifying and obtaining the highest temperature or the lowest temperature of the region, and comparing the highest temperature or the lowest temperature with the basic temperature, wherein the temperature difference is the highest temperature-the basic temperature; the temperature difference= |minimum temperature-base temperature|, and corresponding alarm levels and alarm information are set based on the calculated temperature differences of all areas. For example: the method comprises the steps of displaying first-level warning information, displaying second-level warning information, displaying third-level warning information, displaying fourth-level warning information, displaying fifth-level warning information and displaying fifth-level warning information.

According to the invention, an integrated diagnosis and treatment health management system based on energy medicine is provided, as shown in fig. 1 to 6, and comprises:

module S1: the first human thermal image is acquired by controlling thermal image acquisition equipment, and the thermal image acquisition device comprises a thermal imager. Specifically, in the module S1, the thermal image capturing device is controlled to obtain thermal images of the head, the face, the chest, the upper body, the lower body, the front, the back, 45 degrees on the right side, 45 degrees on the left side, and the left side of the whole body of the human body, and store the thermal images of each angle of each part of the first human body to the cloud.

Module S2: carrying out full-image scanning on the obtained first human body thermal image to obtain each lattice temperature, calculating to form an isotherm, and calculating to obtain the range and the area of the temperature difference and the abnormal temperature radiation region by utilizing the temperature of high radiation or low radiation in the isotherm and the basic body temperature of the corresponding region; the temperature radiation abnormality includes an increase or decrease in temperature. The temperature above the basal body temperature is the temperature of high radiation; the temperature below the base body temperature is a low radiation temperature;

module S3: mapping the temperature radiation abnormal region to a human anatomy diagram in a cloud database to obtain organ projection of the temperature radiation abnormal region; specifically, the temperature radiation abnormal region in the first human thermal image is mapped to a human anatomy figure, and the human anatomy figure is stored in a cloud database to obtain a specific part of viscera, wherein the temperature abnormality phenomenon occurs.

Module S4: acquiring the description information of an individual corresponding to the first human thermal image, and comparing the description information with the set information in the cloud database to obtain a final comparison result; and according to the final comparison result, combining the viscera projection of the temperature radiation abnormal region, and determining viscera abnormality analysis results corresponding to the temperature radiation abnormal region. The setting information in the cloud database comprises: symptom data and pathology image data of corresponding symptoms in the cloud database; specifically, acquiring descriptive symptom information of an individual corresponding to the first human thermal image, and comparing the descriptive symptom information with symptom data in a cloud database to obtain symptom data corresponding to the descriptive symptom information in the cloud database; mapping the symptom data corresponding to the described symptom information in the cloud database to the pathology image data of the corresponding symptoms in the cloud database to obtain pathology image data of the corresponding symptoms; and combining pathological image data of the corresponding symptoms with organ projection of the temperature radiation abnormal region, so as to obtain a specific symptom analysis result of the organ with abnormal temperature.

Module S5: matching and attaching the human body acupoint map and the first human body thermal image map, collecting acupoint position pixels based on organ projection of the temperature radiation abnormal region, and determining the acupoint names and the meridians where the organs corresponding to the temperature radiation abnormal region are located; defining the attribute of each acupoint in the human body acupoint map, including the channels and collaterals, the well points, the original points, the five-acupoint points, the extra-channel odd points and the like; specifically, a human body acupoint map with each acupoint attribute is matched and attached with a first human body thermal image map, acupoint position pixels are collected, and the acupoint names and the meridians where the temperature radiation abnormal region is located are determined based on viscera projection of the temperature radiation abnormal region.

Module S6: based on the viscera abnormality analysis result corresponding to the temperature radiation abnormality region, controlling the physiotherapy equipment to execute physiotherapy work to the corresponding acupoints according to the acupoint names and the channels and collaterals; specifically, based on the specific symptom analysis result of the viscera with abnormal temperature, acupoint combination is carried out according to the names of the acupoints and the channels and collaterals where the acupoints are positioned, and the physiotherapy equipment is controlled to output pulse current to the acupoints of the acupoint combination; the physiotherapy equipment adopts a meridian flattening device applying a pulse current principle of a high-voltage low-frequency special waveform;

the way of matching the acupoints comprises the following steps: setting the acupoints corresponding to the abnormal temperature radiation areas as main acupoints and connecting the main acupoints with the negative electrode of the physiotherapy equipment, and taking 1-2 acupoints; selecting acupoints matched with the positive electrode of physiotherapy equipment, taking 4-6 acupoints, and selecting far-end acupoints of the same name of the far ends of hands and feet and the far-end acupoints of the exterior and interior meridians;

for example: when the acquired abnormal temperature radiation area is the acupoint of the back bladder meridian, performing acupoint combination by using a remote acupoint matching method;

when the acquired abnormal temperature radiation area is an acupoint on the front surface of the trunk, the acupoint is set as a main acupoint and is connected with the cathode of the physiotherapy equipment; the acupoints are connected with the positive electrode of the physiotherapy equipment, and the acupoints are the back acupoints corresponding to anatomical positions, for example: anatomical locations are the "stomach", and corresponding back acupoints are the "stomach acupoints"; anatomical locations are "liver", and corresponding back acupoints are "liver acupoints"; the five zang-organs, six fu-organs, heart, liver, spleen, lung and kidney all have corresponding acupoints; adding the far-end acupoint of the main acupoint, if it is pain, selecting the far-end acupoint; in the case of inflammation, a starter pool; if the viscera are in question, the original acupoint is allocated;

When the obtained abnormal temperature radiation area is an upper limb acupoint, the acupoint is set as a main acupoint and is connected with the negative electrode of the physiotherapy equipment; the acupoint matching is connected with the positive electrode of the physiotherapy equipment, and the big vertebral acupoint is selected;

when the obtained abnormal temperature radiation area is a lower limb acupoint, the acupoint is set as a main acupoint and is connected with the negative electrode of the physiotherapy equipment; the acupoint matching is connected with the positive electrode of the physiotherapy equipment, and Mingmen acupoint selection is performed;

when the obtained abnormal temperature radiation area is a head and face acupoint, the acupoint is set as a main acupoint and is connected with the negative electrode of the physiotherapy equipment; the acupoint matching is connected with the positive electrode of the physiotherapy equipment, the cereal is taken, and newly-set acupoints and/or yang-reaching acupoints are added according to the requirement.

Module S7: re-acquiring a second human body thermal image after physiotherapy by physiotherapy equipment, and comparing the second human body thermal image after physiotherapy with the original first human body thermal image in curative effect.

Specifically, in the module S7:

module S7.1: acquiring the conditioned thermal images of all angles of all parts of the second human body by controlling a thermal image acquisition device;

module S7.2: comparing and analyzing the thermal images of each angle of each part of the original first human body with the thermal images of the second human body of the corresponding angle of the corresponding part after conditioning to obtain a curative effect comparison result; specifically, temperature comparison is carried out in the same temperature radiation abnormal region to obtain temperature difference change of the temperature radiation abnormal region, a comparison table is formed, and information is displayed in the same region in different temperature and wide ranges to form a dynamic flash map; the comparison table includes: early warning level, highest temperature, lowest temperature, temperature difference and temperature radiation abnormal region range area of the temperature radiation abnormal region;

More specifically, as shown in fig. 1, n images to be processed of a first human body are obtained through imaging by a thermal imager; carrying out full-image scanning on each image, measuring the temperature of each lattice, and calculating to form an isotherm; calculating to obtain the average temperature of each image based on the temperature of each lattice and the formed isotherm, and obtaining a high-temperature region and a low-temperature region in each image; the high temperature area and the low temperature area are different in base temperature of each person relative to the temperature of the individual, the base temperature of different areas of the same individual is different, and the high temperature area and the low temperature area are relative to the base temperature of the areas. In general, there is an inflammatory region, an abnormal temperature, and a clear boundary with normal tissue. Obtaining basic temperature of most of human body in a selected human body region, identifying and obtaining the highest temperature or the lowest temperature of the region, and comparing the highest temperature or the lowest temperature with the basic temperature, wherein the temperature difference is the highest temperature-the basic temperature; the temperature difference is the lowest temperature-the basic temperature, and corresponding alarm levels and alarm information are set based on the calculated temperature difference of each region; for example: the method comprises the steps of displaying first-level warning information, displaying second-level warning information, displaying third-level warning information, displaying fourth-level warning information, displaying fifth-level warning information and displaying fifth-level warning information.

The invention provides an integrated diagnosis and treatment health management method based on energy medicine, which comprises the following steps:

step S1: the first human thermal image is acquired by controlling thermal image acquisition equipment, and the thermal image acquisition device comprises a thermal imager. Specifically, in step S1, the thermal image acquisition equipment is controlled to acquire thermal images of the head, the face, the chest, the upper body, the lower body, the front, the back, 45 degrees on the right side and 45 degrees on the left side of the whole body of the human body, and store the acquired thermal images of each angle of each part of the first human body to the cloud.

Step S2: carrying out full-image scanning on the obtained first human body thermal image to obtain each lattice temperature, calculating to form an isotherm, and calculating to obtain the range and the area of the temperature difference and the abnormal temperature radiation region by utilizing the temperature of high radiation or low radiation in the isotherm and the basic body temperature of the corresponding region; the temperature radiation abnormality includes an increase or decrease in temperature. The temperature above the basal body temperature is the temperature of high radiation; the temperature below the base body temperature is a low radiation temperature;

step S3: mapping the temperature radiation abnormal region to a human anatomy diagram in a cloud database to obtain organ projection of the temperature radiation abnormal region; specifically, the temperature radiation abnormal region in the first human thermal image is mapped to a human anatomy figure, and the human anatomy figure is stored in a cloud database to obtain a specific part of viscera, wherein the temperature abnormality phenomenon occurs.

Step S4: acquiring the description information of an individual corresponding to the first human thermal image, and comparing the description information with the set information in the cloud database to obtain a final comparison result; and according to the final comparison result, combining the viscera projection of the temperature radiation abnormal region, and determining viscera abnormality analysis results corresponding to the temperature radiation abnormal region. The setting information in the cloud database comprises: symptom data and pathology image data of corresponding symptoms in the cloud database; specifically, acquiring descriptive symptom information of an individual corresponding to the first human thermal image, and comparing the descriptive symptom information with symptom data in a cloud database to obtain symptom data corresponding to the descriptive symptom information in the cloud database; mapping the symptom data corresponding to the described symptom information in the cloud database to the pathology image data of the corresponding symptoms in the cloud database to obtain pathology image data of the corresponding symptoms; and combining pathological image data of the corresponding symptoms with organ projection of the temperature radiation abnormal region, so as to obtain a specific symptom analysis result of the organ with abnormal temperature.

Step S5: matching and attaching the human body acupoint map and the first human body thermal image map, collecting acupoint position pixels based on organ projection of the temperature radiation abnormal region, and determining the acupoint names and the meridians where the organs corresponding to the temperature radiation abnormal region are located; defining the attribute of each acupoint in the human body acupoint map, including the channels and collaterals, the well points, the original points, the five-acupoint points, the extra-channel odd points and the like; specifically, a human body acupoint map with each acupoint attribute is matched and attached with a first human body thermal image map, acupoint position pixels are collected, and the acupoint names and the meridians where the temperature radiation abnormal region is located are determined based on viscera projection of the temperature radiation abnormal region.

Step S6: based on the viscera abnormality analysis result corresponding to the temperature radiation abnormality region, controlling the physiotherapy equipment to execute physiotherapy work to the corresponding acupoints according to the acupoint names and the channels and collaterals; specifically, the step S6 employs: based on the specific symptom analysis result of the viscera with abnormal temperature, acupoint combination is carried out according to the names of the acupoints and the channels and collaterals where the acupoints are positioned, and the physiotherapy equipment is controlled to output pulse current to the acupoints of the acupoint combination; the physiotherapy equipment adopts a meridian flattening device applying a pulse current principle of a high-voltage low-frequency special waveform;

the way of matching the acupoints comprises the following steps: setting the acupoints corresponding to the abnormal temperature radiation areas as main acupoints and connecting the main acupoints with the negative electrode of the physiotherapy equipment, and taking 1-2 acupoints; selecting acupoints matched with the positive electrode of physiotherapy equipment, taking 4-6 acupoints, and selecting far-end acupoints of the same name of the far ends of hands and feet and the far-end acupoints of the exterior and interior meridians;

for example: when the acquired abnormal temperature radiation area is the acupoint of the back bladder meridian, performing acupoint combination by using a remote acupoint matching method;

when the acquired temperature radiation abnormal area is an acupoint on the front of the trunk, the acupoint is set as a main acupoint negative electrode; the acupoint-matching anode is the far-end acupoint of the main acupoint corresponding to the anatomical position, and if the pain is the pain, the far-end acupoint is selected; in the case of inflammation, a starter pool; if the viscera are in question, the original acupoint is allocated;

When the obtained abnormal temperature radiation area is an upper limb acupoint, the acupoint is set as a main acupoint and is connected with the negative electrode of the physiotherapy equipment; the acupoint matching is connected with the positive electrode of the physiotherapy equipment, and the big vertebral acupoint is selected;

when the obtained abnormal temperature radiation area is a lower limb acupoint, the acupoint is set as a main acupoint and is connected with the negative electrode of the physiotherapy equipment; the acupoint matching is connected with the positive electrode of the physiotherapy equipment, and Mingmen acupoint selection is performed;

when the obtained abnormal temperature radiation area is a head and face acupoint, the acupoint is set as a main acupoint and is connected with the negative electrode of the physiotherapy equipment; the acupoint matching is connected with the positive electrode of the physiotherapy equipment, the cereal is taken, and newly-set acupoints and/or yang-reaching acupoints are added according to the requirement.

Step S7: re-acquiring a first human body thermal image after physiotherapy by physiotherapy equipment, and comparing the first human body thermal image after physiotherapy with the original first human body thermal image in curative effect.

Further, in addition to meridian balancing therapy, different physical therapies may be selected for rehabilitation for different indications, including magnetic therapy, ultrasound therapy, infrared moxibustion or laser therapy.

Specifically, in the step S7:

step S7.1: acquiring the conditioned thermal images of all angles of all parts of the first human body by controlling a thermal image acquisition device;

step S7.2: comparing and analyzing the thermal images of each angle of each part of the original first human body with the thermal images of the first human body of the corresponding angles of the corresponding parts after conditioning to obtain curative effect comparison results; specifically, temperature comparison is carried out in the same temperature radiation abnormal region to obtain temperature difference change of the temperature radiation abnormal region, a comparison table is formed, and information is displayed in the same region in different temperature and wide ranges to form a dynamic flash map; the comparison table includes: early warning level, highest temperature, lowest temperature, temperature difference and temperature radiation abnormal region range area of the temperature radiation abnormal region;

More specifically, as shown in fig. 1, n images to be processed of a first human body are obtained through imaging by a thermal imager; carrying out full-image scanning on each image, measuring the temperature of each lattice, and calculating to form an isotherm; calculating to obtain the average temperature of each image based on the temperature of each lattice and the formed isotherm, and obtaining a high-temperature region and a low-temperature region in each image; the high temperature area and the low temperature area are different in base temperature of each person relative to the temperature of the individual, the base temperature of different areas of the same individual is different, and the high temperature area and the low temperature area are relative to the base temperature of the areas. In general, there is an inflammatory region, an abnormal temperature, and a clear boundary with normal tissue. Obtaining basic temperature of most of human body in a selected human body region, identifying and obtaining the highest temperature or the lowest temperature of the region, and comparing the highest temperature or the lowest temperature with the basic temperature, wherein the temperature difference is the highest temperature-the basic temperature; the temperature difference is the lowest temperature-the basic temperature, and corresponding alarm levels and alarm information are set based on the calculated temperature difference of each region; for example: the method comprises the steps of displaying first-level warning information, displaying second-level warning information, displaying third-level warning information, displaying fourth-level warning information, displaying fifth-level warning information and displaying fifth-level warning information.

The main uses of the invention include:

1. according to the invention, the body surface projection part of the temperature radiation abnormal region is accurately positioned by the thermal image acquisition device; typically, the heat radiation variation includes temperature and decrease;

2. the invention is attached with the human body thermal image by the human body acupoint map, positions the names of the acupoints in the abnormal temperature radiation area, and controls the physiotherapy equipment to output pulse current to the acupoints of the group acupoint; accurately acts on the abnormal temperature radiation area, and the meridian leveling therapy is green, noninvasive and free of side effects;

3. the invention combines the thermal image acquisition device and the meridian leveling therapy physiotherapy system, finds out the abnormal region of the human body temperature radiation according to the thermal image acquisition device, further upgrades the meridian leveling therapy into a software intelligent acupoint allocation system, individuates dialectical treatment and guides the leveling clinical practice; and after the treatment course treatment operation, performing image capturing analysis by a thermal image acquisition device to obtain curative effect comparison.

The important meaning of the invention is as follows: the thermal image acquisition equipment acquires a thermal image of a human body, detects and receives the temperature distribution of the human body by using an infrared band of 8-14 microns, and finds abnormal temperature radiation caused by abnormal metabolism by digital conversion imaging and application software technology processing. For example: cells, tissues and organs of the human body are different in heat radiation generated by metabolism of cells under normal and abnormal conditions, and when an abnormality occurs in a certain part of the human body, there is generally a change in heat radiation including an increase or decrease in temperature. The local pathological change condition is judged according to the temperature difference, the disease risk can be found in the very early stage, and the risk level is quantified through data. The meridian leveling therapy is further upgraded into a software intelligent acupoint-matching system, and the personalized dialectical treatment is performed to guide the leveling clinical practice; the novel mode is provided, a thermal image acquisition device is fused with a meridian leveling instrument, a corresponding viscera abnormality analysis result is obtained according to a temperature radiation abnormality region, and physiotherapy is performed by controlling intelligent acupoint allocation of meridian leveling therapy; the defect of single inspection of the thermal image acquisition device is overcome to a great extent.

Example 2

Example 2 is a preferred example of example 1

The invention provides a thermal image acquisition and analysis system, which comprises:

module M1: acquiring a thermal image by controlling a thermal image acquisition device; as shown in fig. 4 to 5, the specific image capturing portion includes: the upper part of the collarbone and the upper half of the body of the head and the face; the specific image capturing mode is as follows: the parts above the collarbone of the head face are respectively provided with thermal images of the front face, the left side, the right side and the back face at 45 degrees; when the upper half body is used for taking an image, two palm parts are opened at the side face of the body, the palm center is forward, and thermal images of the front face, the left side 45 degrees, the right side 45 degrees and the back face are respectively taken;

module M2: processing the first human body thermal image, finding the highest temperature and the lowest temperature, and identifying a temperature radiation abnormal region according to the basic body temperature;

specifically, 4 thermal images of the front side, the left side, the right side and the back side, which are respectively acquired by the parts above the collarbone of the head and the face, are simultaneously processed, and the areas with the highest temperature are respectively found: the method comprises the following steps of (1) pre-warning the paranasal sinuses on two sides of the median nasalar of a patient with fever, the ethmoid sinus, the forehead, the collarbone fossa and the temperature difference of 0.7-0.9 level; back neck: the high-temperature radiation temperature difference between the two sides of the back of the ear and the middle part of the back of the neck is 0.7-0.9 level to early warn; the simultaneous processing of the upper body four images finds that: back part: the positions of Jianzhu, dazhui, zhuangyang and Mingmen are high-radiation first-stage early warning, and the arm: the front median line is highly radiating.

Module M3: mapping the temperature radiation abnormal region to a human anatomy diagram in a cloud database to obtain organ projection of the temperature radiation abnormal region; the midline of the face is the paranasal sinus region: the maxillary sinus, ethmoid sinus, and frontal sinus are highly radiating. The collar-bone fossa cervical lymph nodes are highly irradiated;

module M4: acquiring the description information of an individual corresponding to the first human thermal image, and comparing the description information with the set information in the cloud database to obtain a final comparison result; determining an viscera abnormality analysis result corresponding to the temperature radiation abnormality region according to the final comparison result and the viscera projection of the temperature radiation abnormality region; the midline of the face is the paranasal sinus region: the maxillary sinus, ethmoid sinus, and frontal sinus are highly radiating (paranasal sinusitis may occur), and the patient may have symptoms such as dizziness, headache, hypomnesis, nasal obstruction, runny nose, and hyposmia. The cervical lymph nodes of the clavicle fossa were highly irradiated (indicating enlargement of lymph nodes with inflammation surrounding them)

Module M5: matching and attaching the human body acupoint map and the first human body thermal image map, acquiring acupoint position pixels based on organ projection of the temperature radiation abnormal region, and determining the acupoint names and the channels of the organs corresponding to the temperature radiation abnormal region: the sinuses on the two sides of the middle nasal wing of the face of the patient suffering from fever (corresponding to Ying Xiang point- -large intestine meridian), the ethmoid sinus (Jingming point- -bladder meridian), the forehead, the collarbone fossa and the temperature difference (0.7-0.9 level early warning) are arranged on the back neck: the high temperature radiation temperature difference (0.7-0.9 level early warning) between the two sides behind the ear (Fengchi acupoint-gall meridian) and the middle behind the neck (Fengfu acupoint-governor meridian) with the ear as a horizontal line is found by the simultaneous processing of four images of the upper body: back part: high radiation (primary early warning) is presented at the position of the Jianzhongshu (small intestine meridian), dazhui (governor vessel), to the yang (governor vessel), mingmen (governor vessel), arm: the anterior normal pericardial route is highly radiating.

Module M6: based on the viscera abnormality analysis result corresponding to the temperature radiation abnormality region, the physiotherapy equipment is controlled to execute physiotherapy work to the corresponding acupoints according to the acupoint names and the channels and collaterals:

solving headache symptom: the main acupoint negative electrode is a double-eye Ming acupoint, and the auxiliary acupoint positive electrode is a double-wind pond for physiotherapy for 30 minutes;

solving the symptom of nasal obstruction: the negative electrode of the main acupoint is a double Ying Xiang acupoint, and the positive electrode of the auxiliary acupoint is a double Hegu acupoint for physiotherapy for 30 minutes;

fever abating: the negative electrode of the main acupoint is the big cone, the positive electrode of the auxiliary acupoint is the gate, the alternating electrode is used for physiotherapy for 30 minutes;

and re-acquiring a second human body thermal image after physiotherapy by physiotherapy equipment, and comparing the curative effect of the second human body thermal image after physiotherapy with that of the original first human body thermal image, as shown in fig. 6, so as to obtain a curative effect comparison result.

Those skilled in the art will appreciate that the systems, apparatus, and their respective modules provided herein may be implemented entirely by logic programming of method steps such that the systems, apparatus, and their respective modules are implemented as logic gates, switches, application specific integrated circuits, programmable logic controllers, embedded microcontrollers, etc., in addition to the systems, apparatus, and their respective modules being implemented as pure computer readable program code. Therefore, the system, the apparatus, and the respective modules thereof provided by the present invention may be regarded as one hardware component, and the modules included therein for implementing various programs may also be regarded as structures within the hardware component; modules for implementing various functions may also be regarded as being either software programs for implementing the methods or structures within hardware components.

The foregoing describes specific embodiments of the present invention. It is to be understood that the invention is not limited to the particular embodiments described above, and that various changes or modifications may be made by those skilled in the art within the scope of the appended claims without affecting the spirit of the invention. The embodiments of the present application and features in the embodiments may be combined with each other arbitrarily without conflict.

Claims (8)

1. A thermal image acquisition analysis system, comprising:

module M1: acquiring a first human thermal image by controlling thermal image acquisition equipment;

module M2: carrying out full-image scanning on the acquired first human body thermal image to obtain each lattice temperature, calculating to form an isotherm, and calculating to obtain a temperature radiation abnormal region by utilizing the temperature of the isotherm and the basic body temperature of the corresponding region;

module M3: mapping the temperature radiation abnormal region to a human anatomy diagram in a cloud database to obtain organ projection of the temperature radiation abnormal region;

module M4: acquiring the description information of an individual corresponding to the first human thermal image, and comparing the description information with the set information in the cloud database to obtain a final comparison result; according to the final comparison result, combining organ projection of the temperature radiation abnormal region to obtain a thermal image analysis result;

The setting information in the cloud database comprises: symptom data and pathology image data of corresponding symptoms in the cloud database;

in the module M4: acquiring descriptive symptom information of an individual corresponding to the first human thermal image, and comparing the descriptive symptom information with symptom data in a cloud database to obtain a second comparison result; mapping the second comparison result to pathological image data of the corresponding symptoms in the cloud database to obtain a final analysis result; and combining the final analysis result with the organ projection of the temperature radiation abnormal region to obtain an abnormal analysis result of the organ corresponding to the temperature radiation abnormal region.

2. The thermal image acquisition and analysis system of claim 1, wherein the first thermal image of the human body is acquired by controlling a thermal image acquisition device; carrying out full-image scanning on the first human body thermal image to obtain the temperature of each point array and calculating to form an isotherm; and calculating the average temperature of the first human body thermal image based on the temperature of each lattice and the formed isotherm, calculating the temperature difference and the area of the radiation abnormal region by utilizing the temperature of the isotherm and the basic body temperature of the corresponding region, and setting the corresponding alarm level based on the calculated temperature difference.

3. Diagnosis and treatment integrated health management system based on energy medicine is characterized by comprising:

module S1: acquiring a first human thermal image by controlling thermal image acquisition equipment;

module S2: carrying out full-image scanning on the acquired first human body thermal image to obtain each lattice temperature, calculating to form an isotherm, and calculating to obtain a temperature radiation abnormal region by utilizing the temperature of the isotherm and the basic body temperature of the corresponding region;

module S3: mapping the temperature radiation abnormal region to a human anatomy diagram in a cloud database to obtain organ projection of the temperature radiation abnormal region;

module S4: acquiring the description information of an individual corresponding to the first human thermal image, and comparing the description information with the set information in the cloud database to obtain a final comparison result; determining an viscera abnormality analysis result corresponding to the temperature radiation abnormality region according to the final comparison result and the viscera projection of the temperature radiation abnormality region;

module S5: matching and attaching the human body acupoint map and the first human body thermal image map, collecting acupoint position pixels based on organ projection of the temperature radiation abnormal region, and determining the acupoint names and the meridians where the organs corresponding to the temperature radiation abnormal region are located;

Module S6: based on the viscera abnormality analysis result corresponding to the temperature radiation abnormality region, controlling the physiotherapy equipment to execute physiotherapy work to the corresponding acupoints according to the acupoint names and the channels and collaterals;

module S7: re-acquiring a second human body thermal image after physiotherapy by physiotherapy equipment, and comparing the second human body thermal image after physiotherapy with the original first human body thermal image in curative effect.

4. The energy medical-based diagnosis and treatment integrated health management system according to claim 3, wherein the first human thermal image is acquired by controlling the thermal image acquisition equipment; carrying out full-image scanning on the first human body thermal image to obtain the temperature of each point array and calculating to form an isotherm; and calculating the average temperature of the first human body thermal image based on the temperature of each lattice and the formed isotherm, calculating the temperature difference and the area of the temperature radiation abnormal region by utilizing the temperature of the isotherm and the basic body temperature of the corresponding region, and setting the corresponding alarm level based on the calculated temperature difference.

5. The energy medical-based diagnosis and treatment integrated health management system according to claim 3, wherein the setting information in the cloud database includes: symptom data and pathology image data of corresponding symptoms in the cloud database;

In the module S4: acquiring descriptive symptom information of an individual corresponding to the first human thermal image, and comparing the descriptive symptom information with symptom data in a cloud database to obtain a second comparison result; mapping the second comparison result to pathological image data of the corresponding symptoms in the cloud database to obtain a final analysis result; and combining the final analysis result with the organ projection of the temperature radiation abnormal region to obtain an abnormal analysis result of the organ corresponding to the temperature radiation abnormal region.

6. The energy medical based diagnosis and treatment integrated health management system according to claim 3, wherein in the module S6: based on the abnormal analysis result of the viscera corresponding to the abnormal temperature radiation area, acupoint combination is carried out according to the acupoint names and the meridians, and the physiotherapy equipment is controlled to output pulse current to the acupoints of the acupoint combination;

the way of matching the acupoints comprises the following steps: setting the acupoints corresponding to the temperature radiation abnormal areas as main acupoints and connecting the main acupoints with the negative electrode of the physiotherapy equipment, and taking 1-2 acupoints; selecting acupoints matched with the positive electrode of physiotherapy equipment, taking 4-6 acupoints, and selecting far-end acupoints of the same name of the far ends of hands and feet and the far-end acupoints of the exterior and interior meridians.

7. The integrated energy medical based medical treatment health management system of claim 6, wherein,

When the acquired abnormal temperature radiation area is the acupoint of the back bladder meridian, performing acupoint combination by using a remote acupoint matching method;

when the acquired abnormal temperature radiation area is an acupoint on the front surface of the trunk, the acupoint is set as a main acupoint and is connected with the cathode of the physiotherapy equipment; the acupoint matching is connected with the positive electrode of the physiotherapy equipment, the acupoint is the far-end acupoint of the meridian where the main acupoint is located, and if the pain is the pain, the far-end acupoint is selected; in the case of inflammation, a starter pool; if the viscera are in question, the original acupoint is allocated;

when the obtained abnormal temperature radiation area is an upper limb acupoint, the acupoint is set as a main acupoint and is connected with the negative electrode of the physiotherapy equipment; the acupoint matching is connected with the positive electrode of the physiotherapy equipment, and the big vertebral acupoint is selected;

when the obtained abnormal temperature radiation area is a lower limb acupoint, the acupoint is set as a main acupoint and is connected with the negative electrode of the physiotherapy equipment; the acupoint matching is connected with the positive electrode of the physiotherapy equipment, and Mingmen acupoint selection is performed;

when the obtained abnormal temperature radiation area is a head and face acupoint, the acupoint is set as a main acupoint and is connected with the negative electrode of the physiotherapy equipment; the acupoint matching is connected with the positive electrode of the physiotherapy equipment, the cereal is taken, and newly-set acupoints and/or yang-reaching acupoints are added according to the requirement.

8. The energy medical based diagnosis and treatment integrated health management system according to claim 3, wherein in the module S7:

Module S7.1: acquiring a conditioned second human thermal image by controlling thermal image acquisition equipment;

module S7.2: comparing and analyzing the original first human body thermal image with the second human body thermal image with the same angle after conditioning to obtain a curative effect comparison result;

in the module S7.2: temperature comparison is carried out on the same temperature radiation abnormal region to obtain temperature difference change of the temperature radiation abnormal region, and a comparison table is formed;

the comparison table includes: the early warning level, the highest temperature, the lowest temperature, the temperature difference and the range area of the temperature radiation abnormal region.