CN115423320B - Regional-based healthy and maintained project construction site selection analysis and evaluation method - Google Patents
Regional-based healthy and maintained project construction site selection analysis and evaluation method Download PDFInfo
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- CN115423320B CN115423320B CN202211072650.8A CN202211072650A CN115423320B CN 115423320 B CN115423320 B CN 115423320B CN 202211072650 A CN202211072650 A CN 202211072650A CN 115423320 B CN115423320 B CN 115423320B
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- 238000004458 analytical method Methods 0.000 title claims abstract description 39
- 238000010276 construction Methods 0.000 title claims abstract description 32
- 238000011156 evaluation Methods 0.000 title claims abstract description 22
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims abstract description 128
- 230000036541 health Effects 0.000 claims abstract description 38
- 150000002500 ions Chemical class 0.000 claims description 45
- 238000004364 calculation method Methods 0.000 claims description 39
- 241000894006 Bacteria Species 0.000 claims description 31
- 235000013619 trace mineral Nutrition 0.000 claims description 15
- 239000011573 trace mineral Substances 0.000 claims description 15
- 230000008901 benefit Effects 0.000 claims description 13
- 230000009286 beneficial effect Effects 0.000 claims description 8
- 238000004140 cleaning Methods 0.000 claims description 8
- 238000000034 method Methods 0.000 claims description 5
- 238000012937 correction Methods 0.000 claims description 3
- 230000036642 wellbeing Effects 0.000 claims description 3
- 230000000694 effects Effects 0.000 abstract description 6
- 229910052500 inorganic mineral Inorganic materials 0.000 description 3
- 235000010755 mineral Nutrition 0.000 description 3
- 239000011707 mineral Substances 0.000 description 3
- 238000004457 water analysis Methods 0.000 description 3
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- 238000007792 addition Methods 0.000 description 1
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- 239000003814 drug Substances 0.000 description 1
- 208000015181 infectious disease Diseases 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 238000006467 substitution reaction Methods 0.000 description 1
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- G06Q10/0639—Performance analysis of employees; Performance analysis of enterprise or organisation operations
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- G06Q—INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES; SYSTEMS OR METHODS SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES, NOT OTHERWISE PROVIDED FOR
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- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02A—TECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
- Y02A20/00—Water conservation; Efficient water supply; Efficient water use
- Y02A20/152—Water filtration
Abstract
The invention discloses a regional-based healthy and maintained project construction site selection analysis and evaluation method, which comprises the following steps: the invention can analyze the hot spring water and analyze the surrounding environment of the hot spring mountain villa, thereby ensuring the use of the hot spring mountain villa, reducing the cost loss of a hot spring villa operator to a certain extent, focusing on the functionality of the hot spring water when analyzing the hot spring water, and considering the safety of the hot spring water, thereby ensuring the curative effect of the hot spring water, ensuring the health of people to a certain extent and reducing the potential risk of the hot spring mountain villa.
Description
Technical Field
The invention relates to the technical field of site selection of health care projects, in particular to a regional-based site selection analysis and evaluation method for health care project construction.
Background
Along with the development of society and science, the living standard of people is also continuously improved, and further demands of health-care projects are gradually increased, the health-care projects comprise forest vegetation health-care projects, hot spring mineral health-care projects, coastal lake health-care projects, rural field health-care projects and the like, among the health-care projects, the hot spring mineral health-care projects have health-care and recuperation functions and are the most important resources in traditional health-care travel, under the condition, the health-care projects of the hot spring mineral health-care projects are gradually increased, and the hot spring health-care industry starts to have a leisure and comprehensive trend on the basis of original hot spring medicine and hot spring recuperation, so that the construction frequency of the hot spring mountain is also increased, and if the construction site of the hot spring mountain is unreasonable, the construction and later use of the hot spring mountain are affected.
The existing hot spring village site selection analysis has the following defects:
(1) The existing hot spring village site analysis is mostly carried out aiming at hot spring water, so that the influence of the surrounding environment of the hot spring village on the hot spring village site is ignored, and then the hot spring water possibly meets the requirement of building the hot spring village site, but the phenomenon that the surrounding environment of the hot spring village is unsuitable influences the use of the hot spring village, so that the cost loss of a hot spring village operator is caused to a certain extent.
(2) The prior hot spring village site selection analysis is mainly used for analyzing the functional aspect of hot spring water when the hot spring water analysis is carried out so as to meet the curative effect aim of the hot spring water, the attention of the safety analysis of the hot spring water is not high, and when people with weak body resistance go to the hot spring village and vacate, the hot spring village site selection analysis is possibly endangered by the body, and can cause certain infection to people, and further a hot spring village operator needs to bear certain responsibility, so that potential risks are brought to the hot spring village.
Disclosure of Invention
In order to overcome the defects in the background technology, the embodiment of the invention provides a regional-based well-being and health project construction site selection analysis and evaluation method, which can effectively solve the problems related to the background technology.
The aim of the invention can be achieved by the following technical scheme:
a regional-based healthy and maintained project construction site selection analysis and evaluation method comprises the following steps:
step 1, obtaining parameters of hot spring village site selection: dividing the hot spring village site area into hot spring village site areas according to a preset area dividing mode, further obtaining longitude and latitude of each hot spring village site area, and obtaining hot spring water quality parameters, wherein the hot spring water quality parameters comprise ph value, turbidity, total bacteria number, content of various ions and content of various microelements beneficial to human bodies;
step 2, analyzing the water quality of the hot spring: analyzing the clean coefficient and the good coefficient of the hot spring water quality through the hot spring water quality parameters, and analyzing the proper coefficient of the hot spring water quality according to the clean coefficient and the good coefficient of the hot spring water quality;
step 3, feasibility analysis of hot spring villa site selection: analyzing the feasibility of the hot spring villa site selection place according to the longitude and latitude of each hot spring villa site selection sub-area, and further obtaining a feasibility coefficient corresponding to the hot spring villa site selection place;
and 4, analyzing the rainfall suitability of the hot spring villa site selection land: analyzing the rainfall of each hot spring mountain villa site selection subarea, and further obtaining the rainfall suitability corresponding to the hot spring mountain villa site selection subarea;
and 5, analyzing the temperature suitability of the hot spring villa site selection place: analyzing the temperature suitability of each hot spring mountain villa site selection subarea, and comprehensively analyzing the temperature suitability corresponding to the hot spring mountain villa site selection subarea according to the temperature suitability;
and 6, comprehensively evaluating coefficient analysis of the hot spring villa site selection: and analyzing the comprehensive evaluation coefficient of the hot spring villa site selection according to the water quality suitability coefficient of the hot spring villa, the feasible coefficient corresponding to the hot spring villa site selection, the rainfall suitability and the temperature suitability.
Further, the specific steps of analyzing the clean coefficient of the hot spring water quality in the step 2 are as follows:
step 211: extracting ph value, turbidity and total bacteria from the hot spring water quality parameters, respectively comparing the ph value, turbidity and total bacteria value with proper ph value, allowable turbidity and total bacteria value threshold values stored in a hot spring village health care project database, analyzing the proper ph value, the proper turbidity value and the proper total bacteria value of the hot spring water quality according to the ph value, the proper turbidity value and the proper total bacteria value, wherein the calculation formula is as follows: wherein d is 1 、d 2 、d 3 Respectively representing the proper value of the hot spring water quality ph, the proper value of the turbidity and the proper value of the total number of bacteria, wherein ph and ph ' respectively represent the proper value of the hot spring water quality ph and the proper value of the ph, TU and TU ' respectively represent the turbidity of the hot spring water quality and the allowable turbidity, C, C ' respectively represent the total number of bacteria and the threshold value of the total number of bacteria of the hot spring water quality, and e represents a natural constant;
step 212, analyzing the clean coefficient of the hot spring water quality according to the ph proper value, the turbidity proper value and the total bacteria proper value, wherein the calculation formula is as follows:wherein eta' is expressed as the water quality cleaning coefficient of the hot spring and delta 1 、δ 2 、δ 3 Respectively expressed as the influence coefficient of the preset proper value of the hot spring water quality ph, the influence coefficient of the turbidity proper value and the influence coefficient of the proper value of the total bacteria number, and delta 1 +δ 2 +δ 3 =1。
Further, the specific analysis steps of the hot spring water quality benefit coefficient in the step 2 are as follows:
step 221: extracting the content of various ions and the content of various microelements beneficial to human bodies from hot spring water quality parameters, and respectively numbering the various ions as 1,2, i, n, and 1,2, x, y;
step 222: extracting proper contents corresponding to various ions from a hot spring health project database;
step 223: according to the content and the proper content of various ions, analyzing the proper index of the ion content corresponding to the hot spring water quality, wherein the calculation formula is as follows:wherein eta 1 Expressed as the ion content suitability index corresponding to the hot spring water quality, Q i Expressed as the content of the ith ion, Q i ' represents a suitable content of the i-th ion, i represents the number of each ion, i=1, 2, n;
step 224: extracting proper contents corresponding to various microelements from a hot spring health care project database;
step 225: according to the content and the proper content of various microelements, analyzing the proper index of the content of microelements corresponding to the hot spring water quality, wherein the calculation formula is as follows:wherein eta 2 Expressed as the index of proper trace element content, q, corresponding to the quality of hot spring water x Expressed as the content of the x-th ion, q x ' represents a suitable content of an x-th ion, x represents the number of each trace element, x=1, 2,..y;
step 226:according to the ion content suitability index and the trace element content suitability index corresponding to the hot spring water quality, analyzing the hot spring water quality benefit coefficient, wherein the calculation formula is as follows:wherein eta' is expressed as the quality benefit coefficient of the hot spring water, lambda 1 、λ 2 Respectively expressed as weight factors of ion content suitable index and trace element content suitable index corresponding to preset hot spring water quality, and lambda 1 +λ 2 =1。
Further, the specific calculation formula of the coefficient suitable for the hot spring water quality is as follows:wherein eta is expressed as a proper coefficient of the water quality of the hot spring and χ 1 、χ 2 Respectively expressed as the duty factor of the preset hot spring water quality cleaning coefficient and the duty factor of the hot spring water quality benefit coefficient, χ 1 +χ 2 =1。
Further, the specific analysis steps of the feasible coefficients corresponding to the hot spring villa site selection in the step 3 are as follows:
step 31: the sub-areas of each hot spring mountain villa site selection are respectively numbered as 1,2, & gt, h, & gt, z;
step 32: acquiring the longitude and latitude of each hot spring village site selection subarea, comparing the longitude and latitude with the longitude and latitude range corresponding to the forbidden construction area stored in the hot spring village health care project database, and if the longitude and latitude of a certain hot spring village site selection subarea belongs to the longitude and latitude range corresponding to the forbidden construction area, marking the hot spring village site selection subarea as the forbidden construction subarea;
step 33: the number of the hot spring village site selection subareas and the number of the construction forbidden subareas are counted, and the feasible coefficients corresponding to the hot spring village site selection subareas are analyzed according to the number of the hot spring village site selection subareas, wherein the calculation formula is as follows:wherein mu represents a feasible coefficient corresponding to the hot spring villa site selection place, z represents the number of the hot spring villa site selection place sub-areas,alpha is expressed as the number of forbidden sub-regions.
Further, the specific analysis step of the rainfall suitability corresponding to the hot spring villa site selection in the step 4 is as follows:
step 41: extracting rainfall of each hot spring mountain village site selection subarea in preset historical years from a hot spring mountain village health care project database, and counting total rainfall of each hot spring mountain village site selection subarea in each historical years;
step 42: analyzing the historical annual average rainfall of the hot spring villa site selection areas according to the total rainfall of the hot spring villa site selection areas in the historical years, wherein the calculation formula is as follows:wherein beta is expressed as the historical annual average rainfall of the hot spring villa site selection land, beta hm ' is expressed as total rainfall of the h hot spring villa site sub-area in the m-th history period, m is expressed as a number of each preset history period, m=1, 2,..k, h is expressed as a number of each hot spring villa site sub-area, h=1, 2,..z;
step 43: extracting the rainfall of set seasons from the rainfall of each hot spring mountain site selection land subarea in preset historical years, so as to obtain the rainfall of each hot spring mountain site selection land subarea in set seasons corresponding to the historical years, wherein the set seasons are hot spring mountain business vigorous seasons, and the maximum rainfall and the minimum rainfall of each hot spring mountain site selection land subarea in set seasons corresponding to the historical years are counted;
step 44: comparing the maximum rainfall of the hot spring village site selection subareas corresponding to the set seasons of the historical years, and further selecting the maximum value as the maximum rainfall of the hot spring village site selection subareas in the set seasons;
step 45: comparing the maximum rainfall of each hot spring mountain villa site selection subarea in a set season, and further selecting the maximum value as the rainfall upper limit value of the hot spring mountain villa site selection subarea in the set season;
step 46: similarly, analyzing to obtain a lower limit value of rainfall of the hot spring villa site selection place in a set season;
step 47: analyzing the rainfall suitability of the hot spring mountain land in the set season according to the rainfall upper limit value and the rainfall lower limit value of the hot spring mountain land in the set season and the rainfall upper limit warning value and the rainfall lower limit warning value of the hot spring mountain land in the set season stored in the hot spring mountain land health project database, wherein the calculation formula is as follows:wherein kappa is represented as the rainfall suitability corresponding to the hot spring villa site selection in a set season, Y Upper part 、Y Lower part(s) Respectively expressed as the upper limit value and the lower limit value of the rainfall of the hot spring mountain villa site selection in the set season,respectively representing an upper limit warning value and a lower limit warning value of the rainfall in a set season of the hot spring villa;
step 48: according to the historical annual average rainfall of the hot spring villa site selection place, the rainfall suitability corresponding to the set season and the safe rainfall of the hot spring villa site selection place stored in the hot spring villa health care project database, the rainfall suitability corresponding to the hot spring villa site selection place is analyzed, and the calculation formula is as follows:wherein omega is represented as the rainfall suitability corresponding to the hot spring mountain villa site selection, and beta' are respectively represented as the historical average rainfall of the hot spring mountain villa site selection and the safe rainfall of the hot spring mountain villa site selection, A 1 、A 2 Correction factors respectively expressed as the average rainfall suitability of the historical years of preset hot spring villa site selection places and the rainfall suitability corresponding to the set seasons, and A 1 +A 2 =1。
Further, the specific analysis step of the temperature suitability of each hot spring villa site selection land area in the step 5 is as follows:
step 51: extracting the temperature of each hot spring mountain village site selection subarea in each history year from a hot spring mountain village health care project database, and classifying the temperature of each hot spring mountain village site selection subarea in each history year according to seasons, so as to obtain a set of temperatures of each hot spring mountain village site selection subarea in each history year corresponding to each season;
step 52: each season is respectively numbered as M 1 、M 2 、M 3 And M 4 Wherein M is 1 M 1 、M 2 、M 3 And M 4 Respectively expressed as spring, summer, autumn and winter;
step 53: extracting the lowest temperature of each hot spring villa site selection land subarea corresponding to each season of each history period from each season temperature set of each hot spring villa site selection subarea corresponding to each history period;
step 54: comparing the lowest temperatures of the hot spring village site selection subareas corresponding to the seasons to which the historical years belong, and further selecting the minimum value as the lowest temperature of the hot spring village site selection subareas corresponding to the seasons;
step 55: comparing the lowest temperatures of the hot spring village site selection subareas corresponding to the seasons, and further selecting the minimum value as a temperature lower limit value of the hot spring village site selection subareas corresponding to the seasons;
step 56: extracting temperature lower limit warning values of the hot spring village site selection land subareas corresponding to seasons from a hot spring village health care project database;
step 57: analyzing the temperature suitability of each hot spring mountain villa site selection land subarea according to the temperature lower limit warning value of each season and the temperature lower limit value of each season corresponding to each hot spring mountain villa site selection land subarea, wherein the calculation formula is as follows:wherein ζ h Temperature suitability expressed as h hot spring villa site selection land area, ++>Respectively expressed as h hot spring villa site selection land subareasThe lower limit value of the temperature corresponding to spring, summer, autumn and winter, < >>The temperature lower limit warning values respectively indicated as the h hot spring villa site selection land subareas correspond to spring, summer, autumn and winter.
Further, the specific calculation formula of the temperature suitability corresponding to the hot spring villa site selection is as follows:wherein ζ is the temperature suitability corresponding to the location of the hot spring mountain villa.
Further, the specific calculation formula of the comprehensive evaluation coefficient of the hot spring mountain villa site selection is as follows:wherein psi is expressed as comprehensive evaluation coefficient of hot spring villa site selection, gamma 1 、γ 2 、γ 3 、γ 3 Respectively expressed as an influence factor of a proper coefficient of hot spring water quality, an influence factor of a feasible coefficient corresponding to a hot spring villa site selection, an influence factor of rainfall suitability, an influence factor of temperature suitability, and gamma 1 +γ 2 +γ 3 +γ 4 =1。
Compared with the prior art, the embodiment of the invention has at least the following advantages or beneficial effects:
(1) The analysis of the hot spring villa site selection can analyze hot spring water and the surrounding environment of the hot spring villa, so that the phenomenon that the hot spring water meets the requirement of the hot spring villa site selection construction but the surrounding environment of the hot spring villa is unsuitable is avoided, the use of the hot spring villa is ensured, and the cost loss of a hot spring villa operator is reduced to a certain extent.
(2) When the hot spring water analysis is carried out, the invention focuses on the functionality of the hot spring water on one hand, and considers the safety of the hot spring water on the other hand, thereby not only ensuring the curative effect of the hot spring water, but also solving the problem that people with weak body resistance may be harmed when going to the holiday of the hot spring villa, ensuring the physical health of people to a certain extent, and reducing the potential risk of the hot spring villa.
Drawings
The invention will be further described with reference to the accompanying drawings, in which embodiments do not constitute any limitation of the invention, and other drawings can be obtained by one of ordinary skill in the art without inventive effort from the following drawings.
FIG. 1 is a flow chart of the method of the present invention.
Detailed Description
The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.
Referring to FIG. 1, the invention provides a regional-based well-being and health project construction site selection analysis and evaluation method, which comprises the following steps:
step 1, obtaining parameters of hot spring village site selection: dividing the hot spring village site area into hot spring village site areas according to a preset area dividing mode, further obtaining longitude and latitude of each hot spring village site area, and obtaining hot spring water quality parameters, wherein the hot spring water quality parameters comprise ph value, turbidity, total bacteria number, content of various ions and content of various microelements beneficial to human bodies;
step 2, analyzing the water quality of the hot spring: analyzing the clean coefficient and the good coefficient of the hot spring water quality through the hot spring water quality parameters, and analyzing the proper coefficient of the hot spring water quality according to the clean coefficient and the good coefficient of the hot spring water quality;
in one specific embodiment, the specific steps of analyzing the clean coefficient of the hot spring water quality in the step 2 are as follows:
step 211: extracting ph, turbidity and total bacteria from hot spring water quality parameters, and mixing with Kang Yang hot spring villageThe proper ph value, the allowable turbidity and the total bacteria count threshold value stored in the mesh database are compared, and the proper ph value, the proper turbidity value and the proper total bacteria count value of the hot spring water quality are analyzed according to the comparison, wherein the calculation formula is as follows: wherein d is 1 、d 2 、d 3 Respectively representing the proper value of the hot spring water quality ph, the proper value of the turbidity and the proper value of the total number of bacteria, wherein ph and ph ' respectively represent the proper value of the hot spring water quality ph and the proper value of the ph, TU and TU ' respectively represent the turbidity of the hot spring water quality and the allowable turbidity, C, C ' respectively represent the total number of bacteria and the threshold value of the total number of bacteria of the hot spring water quality, and e represents a natural constant;
step 212, analyzing the clean coefficient of the hot spring water quality according to the ph proper value, the turbidity proper value and the total bacteria proper value, wherein the calculation formula is as follows:wherein eta' is expressed as the water quality cleaning coefficient of the hot spring and delta 1 、δ 2 、δ 3 Respectively expressed as the influence coefficient of the preset proper value of the hot spring water quality ph, the influence coefficient of the turbidity proper value and the influence coefficient of the proper value of the total bacteria number, and delta 1 +δ 2 +δ 3 =1。
It should be noted that, if the water quality of the hot spring is clean or not, it will have a certain influence on the health of people, if the water quality cleaning coefficient of the hot spring does not reach the qualified standard, people with possibly weak constitution will enter the hot spring village to vacate, and a certain physical hazard may be caused to them, so that the water quality cleaning coefficient of the hot spring needs to be analyzed.
In a specific embodiment, the specific analysis steps of the hot spring water quality benefit coefficient in the step 2 are as follows:
step 221: extracting the content of various ions and the content of various microelements beneficial to human bodies from hot spring water quality parameters, and respectively numbering the various ions as 1,2, i, n, and 1,2, x, y;
step 222: extracting proper contents corresponding to various ions from a hot spring health project database;
step 223: according to the content and the proper content of various ions, analyzing the proper index of the ion content corresponding to the hot spring water quality, wherein the calculation formula is as follows:wherein eta 1 Expressed as the ion content suitability index corresponding to the hot spring water quality, Q i Expressed as the content of the ith ion, Q i ' represents a suitable content of the i-th ion, i represents the number of each ion, i=1, 2, n;
step 224: extracting proper contents corresponding to various microelements from a hot spring health care project database;
step 225: according to the content and the proper content of various microelements, analyzing the proper index of the content of microelements corresponding to the hot spring water quality, wherein the calculation formula is as follows:wherein eta 2 Expressed as the index of proper trace element content, q, corresponding to the quality of hot spring water x Expressed as the content of the x-th ion, q x ' represents a suitable content of an x-th ion, x represents the number of each trace element, x=1, 2,..y;
step 226: according to the ion content suitability index and the trace element content suitability index corresponding to the hot spring water quality, analyzing the hot spring water quality benefit coefficient, wherein the calculation formula is as follows:wherein eta' is expressed as the quality benefit coefficient of the hot spring water, lambda 1 、λ 2 Respectively expressed as weight factors of ion content suitable index and trace element content suitable index corresponding to preset hot spring water quality, and lambda 1 +λ 2 =1。
It should be noted that, ions and trace elements in the hot spring water are beneficial to human body, but if the contents of ions and trace elements in the hot spring water are too low or too high, the recuperation effect of the hot spring water may be reduced to some extent, so that the contents of ions and trace elements in the hot spring water need to be analyzed.
In a specific embodiment, the specific calculation formula of the thermal spring water quality suitability coefficient is as follows:wherein eta is expressed as a proper coefficient of the water quality of the hot spring and χ 1 、χ 2 Respectively expressed as the duty factor of the preset hot spring water quality cleaning coefficient and the duty factor of the hot spring water quality benefit coefficient, χ 1 +χ 2 =1。
When the hot spring water analysis is carried out, the invention focuses on the functionality of the hot spring water on one hand, and considers the safety of the hot spring water on the other hand, thereby not only ensuring the curative effect of the hot spring water, but also solving the problem that people with weak body resistance may be harmed when going to the holiday of the hot spring villa, ensuring the physical health of people to a certain extent, and reducing the potential risk of the hot spring villa.
Step 3, feasibility analysis of hot spring villa site selection: analyzing the feasibility of the hot spring villa site selection place according to the longitude and latitude of each hot spring villa site selection sub-area, and further obtaining a feasibility coefficient corresponding to the hot spring villa site selection place;
in a specific embodiment, the specific analysis steps of the feasible coefficients corresponding to the hot spring mountain villa site in the step 3 are as follows:
step 31: the sub-areas of each hot spring mountain villa site selection are respectively numbered as 1,2, & gt, h, & gt, z;
step 32: acquiring the longitude and latitude of each hot spring village site selection subarea, comparing the longitude and latitude with the longitude and latitude range corresponding to the forbidden construction area stored in the hot spring village health care project database, and if the longitude and latitude of a certain hot spring village site selection subarea belongs to the longitude and latitude range corresponding to the forbidden construction area, marking the hot spring village site selection subarea as the forbidden construction subarea;
step 33: the number of the hot spring village site selection subareas and the number of the construction forbidden subareas are counted, and the feasible coefficients corresponding to the hot spring village site selection subareas are analyzed according to the number of the hot spring village site selection subareas, wherein the calculation formula is as follows:wherein mu represents a feasible coefficient corresponding to the hot spring villa site selection place, z represents the number of the hot spring villa site selection place sub-areas, and alpha represents the number of the construction forbidden sub-areas.
It should be noted that, the hot spring mountain site includes many areas, and may include farmlands and other planning sites, if the ratio of the farmlands and other planning sites is large, the approval of the hot spring mountain site may be affected, and thus the hot spring mountain site may not be used as the hot spring mountain site, so that a feasible coefficient corresponding to the hot spring mountain site needs to be analyzed.
And 4, analyzing the rainfall suitability of the hot spring villa site selection land: analyzing the rainfall of each hot spring mountain villa site selection subarea, and further obtaining the rainfall suitability corresponding to the hot spring mountain villa site selection subarea;
in a specific embodiment, the specific analysis step of the rainfall suitability corresponding to the hot spring mountain villa site in the step 4 is as follows:
step 41: extracting rainfall of each hot spring mountain village site selection subarea in preset historical years from a hot spring mountain village health care project database, and counting total rainfall of each hot spring mountain village site selection subarea in each historical years;
step 42: analyzing the historical annual average rainfall of the hot spring villa site selection areas according to the total rainfall of the hot spring villa site selection areas in the historical years, wherein the calculation formula is as follows:wherein beta is expressed as the historical annual average rainfall of the hot spring villa site selection land, beta hm ' total rainfall at the mth historical years expressed as the h hot spring villa site selection land subarea, m expressed as preset historical yearsNumber m=1, 2,..k, h represents the number of the sub-area of each spa mountain site, h=1, 2,..z;
step 43: extracting the rainfall of set seasons from the rainfall of each hot spring mountain site selection land subarea in preset historical years, so as to obtain the rainfall of each hot spring mountain site selection land subarea in set seasons corresponding to the historical years, wherein the set seasons are hot spring mountain business vigorous seasons, and the maximum rainfall and the minimum rainfall of each hot spring mountain site selection land subarea in set seasons corresponding to the historical years are counted;
the set seasons include spring, summer, autumn or winter.
Step 44: comparing the maximum rainfall of the hot spring village site selection subareas corresponding to the set seasons of the historical years, and further selecting the maximum value as the maximum rainfall of the hot spring village site selection subareas in the set seasons;
step 45: comparing the maximum rainfall of each hot spring mountain villa site selection subarea in a set season, and further selecting the maximum value as the rainfall upper limit value of the hot spring mountain villa site selection subarea in the set season;
step 46: similarly, analyzing to obtain a lower limit value of rainfall of the hot spring villa site selection place in a set season;
step 47: analyzing the rainfall suitability of the hot spring mountain land in the set season according to the rainfall upper limit value and the rainfall lower limit value of the hot spring mountain land in the set season and the rainfall upper limit warning value and the rainfall lower limit warning value of the hot spring mountain land in the set season stored in the hot spring mountain land health project database, wherein the calculation formula is as follows:wherein kappa is represented as the rainfall suitability corresponding to the hot spring villa site selection in a set season, Y Upper part 、Y Lower part(s) Respectively expressed as the upper limit value and the lower limit value of the rainfall of the hot spring mountain villa site selection in the set season,respectively representing an upper limit warning value and a lower limit warning value of the rainfall in a set season of the hot spring villa;
step 48: according to the historical annual average rainfall of the hot spring villa site selection place, the rainfall suitability corresponding to the set season and the safe rainfall of the hot spring villa site selection place stored in the hot spring villa health care project database, the rainfall suitability corresponding to the hot spring villa site selection place is analyzed, and the calculation formula is as follows:wherein omega is represented as the rainfall suitability corresponding to the hot spring mountain villa site selection, and beta' are respectively represented as the historical average rainfall of the hot spring mountain villa site selection and the safe rainfall of the hot spring mountain villa site selection, A 1 、A 2 Correction factors respectively expressed as the average rainfall suitability of the historical years of preset hot spring villa site selection places and the rainfall suitability corresponding to the set seasons, and A 1 +A 2 =1。
When analyzing the rainfall suitability corresponding to the hot spring mountain villa site, the method analyzes not only the historical annual average rainfall of the hot spring mountain villa site, but also the rainfall suitability corresponding to the set season of the hot spring mountain villa site, and when analyzing the rainfall suitability corresponding to the set season of the hot spring mountain villa site, analyzes whether the maximum rainfall and the minimum rainfall of the set season of the hot spring mountain villa site meet the requirements, if not meet the requirements, the quality of the hot spring water and the trip wish of people are influenced, and the rainfall suitability corresponding to the hot spring mountain villa site is analyzed in two aspects, so that the analysis is more accurate.
And 5, analyzing the temperature suitability of the hot spring villa site selection place: analyzing the temperature suitability of each hot spring mountain villa site selection subarea, and comprehensively analyzing the temperature suitability corresponding to the hot spring mountain villa site selection subarea according to the temperature suitability;
in a specific embodiment, the specific analysis step of the temperature suitability of each hot spring mountain villa site selection sub-area in the step 5 is as follows:
step 51: extracting the temperature of each hot spring mountain village site selection subarea in each history year from a hot spring mountain village health care project database, and classifying the temperature of each hot spring mountain village site selection subarea in each history year according to seasons, so as to obtain a set of temperatures of each hot spring mountain village site selection subarea in each history year corresponding to each season;
step 52: each season is respectively numbered as M 1 、M 2 、M 3 And M 4 Wherein M is 1 M 1 、M 2 、M 3 And M 4 Respectively expressed as spring, summer, autumn and winter;
step 53: extracting the lowest temperature of each hot spring villa site selection land subarea corresponding to each season of each history period from each season temperature set of each hot spring villa site selection subarea corresponding to each history period;
step 54: comparing the lowest temperatures of the hot spring village site selection subareas corresponding to the seasons to which the historical years belong, and further selecting the minimum value as the lowest temperature of the hot spring village site selection subareas corresponding to the seasons;
step 55: comparing the lowest temperatures of the hot spring village site selection subareas corresponding to the seasons, and further selecting the minimum value as a temperature lower limit value of the hot spring village site selection subareas corresponding to the seasons;
step 56: extracting temperature lower limit warning values of the hot spring village site selection land subareas corresponding to seasons from a hot spring village health care project database;
step 57: analyzing the temperature suitability of each hot spring mountain villa site selection land subarea according to the temperature lower limit warning value of each season and the temperature lower limit value of each season corresponding to each hot spring mountain villa site selection land subarea, wherein the calculation formula is as follows:wherein ζ h Temperature suitability expressed as h hot spring villa site selection land area, ++>The temperature lower limit value of the h hot spring villa site selection land subarea corresponding to spring, summer, autumn and winter respectively is +.>The temperature lower limit warning values respectively indicated as the h hot spring villa site selection land subareas correspond to spring, summer, autumn and winter.
In a specific embodiment, a specific calculation formula of the temperature suitability corresponding to the hot spring villa site selection is as follows:wherein->Expressed as the temperature suitability corresponding to the location of the spa mountain villa.
It should be noted that, too low temperature will affect the activity of the hot spring water on one hand, and will affect the trip willingness of people on the other hand, so the temperature lower limit value adaptation index corresponding to the location sub-area of each hot spring mountain villa needs to be analyzed.
And 6, comprehensively evaluating coefficient analysis of the hot spring villa site selection: analyzing the comprehensive evaluation coefficient of the hot spring villa site selection area according to the water quality suitability coefficient, the feasible coefficient corresponding to the hot spring villa site selection area, the rainfall suitability and the temperature suitability of the hot spring villa site selection area;
in a specific embodiment, the specific calculation formula of the comprehensive evaluation coefficient of the hot spring villa site selection is as follows:wherein psi is expressed as comprehensive evaluation coefficient of hot spring villa site selection, gamma 1 、γ 2 、γ 3 、γ 3 Respectively expressed as an influence factor of a proper coefficient of hot spring water quality, an influence factor of a feasible coefficient corresponding to a hot spring villa site selection, an influence factor of rainfall suitability, an influence factor of temperature suitability, and gamma 1 +γ 2 +γ 3 +γ 4 =1。
The analysis of the hot spring villa site selection can analyze hot spring water and the surrounding environment of the hot spring villa, so that the phenomenon that the hot spring water meets the requirement of the hot spring villa site selection construction but the surrounding environment of the hot spring villa is unsuitable is avoided, the use of the hot spring villa is ensured, and the cost loss of a hot spring villa operator is reduced to a certain extent.
The foregoing is merely illustrative of the structures of this invention and various modifications, additions and substitutions for those skilled in the art can be made to the described embodiments without departing from the scope of the invention or from the scope of the invention as defined in the accompanying claims.
Claims (6)
1. The regional-based healthy and maintained project construction site selection analysis and evaluation method is characterized by comprising the following steps of:
step 1, obtaining parameters of hot spring village site selection: dividing the hot spring village site area into hot spring village site areas according to a preset area dividing mode, further obtaining longitude and latitude of each hot spring village site area, and obtaining hot spring water quality parameters, wherein the hot spring water quality parameters comprise ph value, turbidity, total bacteria number, content of various ions and content of various microelements beneficial to human bodies;
step 2, analyzing the water quality of the hot spring: analyzing the clean coefficient and the good coefficient of the hot spring water quality through the hot spring water quality parameters, and analyzing the proper coefficient of the hot spring water quality according to the clean coefficient and the good coefficient of the hot spring water quality;
the specific steps for analyzing the clean coefficient of the hot spring water quality in the step 2 are as follows:
step 211: extracting ph value, turbidity and total bacteria from the hot spring water quality parameters, respectively comparing the ph value, turbidity and total bacteria value with proper ph value, allowable turbidity and total bacteria value threshold values stored in a hot spring village health care project database, analyzing the proper ph value, the proper turbidity value and the proper total bacteria value of the hot spring water quality according to the ph value, the proper turbidity value and the proper total bacteria value, wherein the calculation formula is as follows: wherein d is 1 、d 2 、d 3 Respectively representing the proper value of the hot spring water quality ph, the proper value of the turbidity and the proper value of the total number of bacteria, wherein ph and ph ' respectively represent the proper value of the hot spring water quality ph and the proper value of the ph, TU and TU ' respectively represent the turbidity of the hot spring water quality and the allowable turbidity, C, C ' respectively represent the total number of bacteria and the threshold value of the total number of bacteria of the hot spring water quality, and e represents a natural constant;
step 212, analyzing the clean coefficient of the hot spring water quality according to the ph proper value, the turbidity proper value and the total bacteria proper value, wherein the calculation formula is as follows:wherein eta' is expressed as the water quality cleaning coefficient of the hot spring and delta 1 、δ 2 、δ 3 Respectively expressed as the influence coefficient of the preset proper value of the hot spring water quality ph, the influence coefficient of the turbidity proper value and the influence coefficient of the proper value of the total bacteria number, and delta 1 +δ 2 +δ 3 =1;
The specific analysis steps of the hot spring water quality benefit coefficient in the step 2 are as follows:
step 221: extracting the content of various ions and the content of various microelements beneficial to human bodies from hot spring water quality parameters, and respectively numbering the various ions as 1,2, i, n, and 1,2, x, y;
step 222: extracting proper contents corresponding to various ions from a hot spring health project database;
step 223: according to the content and the proper content of various ions, analyzing the proper index of the ion content corresponding to the hot spring water quality, wherein the calculation formula is as follows:wherein eta 1 Expressed as the ion content suitability index corresponding to the hot spring water quality,Q i expressed as the content of the ith ion, Q i ' represents a suitable content of the i-th ion, i represents the number of each ion, i=1, 2, n;
step 224: extracting proper contents corresponding to various microelements from a hot spring health care project database;
step 225: according to the content and the proper content of various microelements, analyzing the proper index of the content of microelements corresponding to the hot spring water quality, wherein the calculation formula is as follows:wherein eta 2 Expressed as the index of proper trace element content, q, corresponding to the quality of hot spring water x Expressed as the content of the x-th ion, q x ' represents a suitable content of an x-th ion, x represents the number of each trace element, x=1, 2,..y;
step 226: according to the ion content suitability index and the trace element content suitability index corresponding to the hot spring water quality, analyzing the hot spring water quality benefit coefficient, wherein the calculation formula is as follows:wherein eta' is expressed as the quality benefit coefficient of the hot spring water, lambda 1 、λ 2 Respectively expressed as weight factors of ion content suitable index and trace element content suitable index corresponding to preset hot spring water quality, and lambda 1 +λ 2 =1;
The specific calculation formula of the hot spring water quality suitability coefficient is as follows:wherein eta is expressed as a proper coefficient of the water quality of the hot spring and χ 1 、χ 2 Respectively expressed as the duty factor of the preset hot spring water quality cleaning coefficient and the duty factor of the hot spring water quality benefit coefficient, χ 1 +χ 2 =1;
Step 3, feasibility analysis of hot spring villa site selection: analyzing the feasibility of the hot spring villa site selection place according to the longitude and latitude of each hot spring villa site selection sub-area, and further obtaining a feasibility coefficient corresponding to the hot spring villa site selection place;
and 4, analyzing the rainfall suitability of the hot spring villa site selection land: analyzing the rainfall of each hot spring mountain villa site selection subarea, and further obtaining the rainfall suitability corresponding to the hot spring mountain villa site selection subarea;
and 5, analyzing the temperature suitability of the hot spring villa site selection place: analyzing the temperature suitability of each hot spring mountain villa site selection subarea, and comprehensively analyzing the temperature suitability corresponding to the hot spring mountain villa site selection subarea according to the temperature suitability;
and 6, comprehensively evaluating coefficient analysis of the hot spring villa site selection: and analyzing the comprehensive evaluation coefficient of the hot spring villa site selection according to the water quality suitability coefficient of the hot spring villa, the feasible coefficient corresponding to the hot spring villa site selection, the rainfall suitability and the temperature suitability.
2. The regional health care project construction site selection analysis and evaluation method according to claim 1, which is characterized in that: the specific analysis steps of the feasible coefficients corresponding to the hot spring villa site selection in the step 3 are as follows:
step 31: the sub-areas of each hot spring mountain villa site selection are respectively numbered as 1,2, & gt, h, & gt, z;
step 32: acquiring the longitude and latitude of each hot spring village site selection subarea, comparing the longitude and latitude with the longitude and latitude range corresponding to the forbidden construction area stored in the hot spring village health care project database, and if the longitude and latitude of a certain hot spring village site selection subarea belongs to the longitude and latitude range corresponding to the forbidden construction area, marking the hot spring village site selection subarea as the forbidden construction subarea;
step 33: the number of the hot spring village site selection subareas and the number of the construction forbidden subareas are counted, and the feasible coefficients corresponding to the hot spring village site selection subareas are analyzed according to the number of the hot spring village site selection subareas, wherein the calculation formula is as follows:wherein mu represents a feasible coefficient corresponding to the hot spring villa site selection place, z represents the number of the hot spring villa site selection place sub-areas, and alpha represents the number of the construction forbidden sub-areas.
3. The regional-based well-being and maintaining project construction site selection analysis and evaluation method as claimed in claim 2, wherein the method is characterized by comprising the following steps: the specific analysis steps of the rainfall suitability corresponding to the hot spring villa site selection in the step 4 are as follows:
step 41: extracting rainfall of each hot spring mountain village site selection subarea in preset historical years from a hot spring mountain village health care project database, and counting total rainfall of each hot spring mountain village site selection subarea in each historical years;
step 42: analyzing the historical annual average rainfall of the hot spring villa site selection areas according to the total rainfall of the hot spring villa site selection areas in the historical years, wherein the calculation formula is as follows:wherein beta is expressed as the historical annual average rainfall of the hot spring villa site selection land, beta hm ' is expressed as total rainfall of the h hot spring villa site sub-area in the m-th history period, m is expressed as a number of each preset history period, m=1, 2,..k, h is expressed as a number of each hot spring villa site sub-area, h=1, 2,..z;
step 43: extracting the rainfall of set seasons from the rainfall of each hot spring mountain site selection land subarea in preset historical years, so as to obtain the rainfall of each hot spring mountain site selection land subarea in set seasons corresponding to the historical years, wherein the set seasons are hot spring mountain business vigorous seasons, and the maximum rainfall and the minimum rainfall of each hot spring mountain site selection land subarea in set seasons corresponding to the historical years are counted;
step 44: comparing the maximum rainfall of the hot spring village site selection subareas corresponding to the set seasons of the historical years, and further selecting the maximum value as the maximum rainfall of the hot spring village site selection subareas in the set seasons;
step 45: comparing the maximum rainfall of each hot spring mountain villa site selection subarea in a set season, and further selecting the maximum value as the rainfall upper limit value of the hot spring mountain villa site selection subarea in the set season;
step 46: similarly, analyzing to obtain a lower limit value of rainfall of the hot spring villa site selection place in a set season;
step 47: analyzing the rainfall suitability of the hot spring mountain land in the set season according to the rainfall upper limit value and the rainfall lower limit value of the hot spring mountain land in the set season and the rainfall upper limit warning value and the rainfall lower limit warning value of the hot spring mountain land in the set season stored in the hot spring mountain land health project database, wherein the calculation formula is as follows:wherein kappa is represented as the rainfall suitability corresponding to the hot spring villa site selection in a set season, Y Upper part 、Y Lower part(s) Respectively expressed as the upper limit value and the lower limit value of the rainfall of the hot spring mountain villa site selection in the set season,respectively representing an upper limit warning value and a lower limit warning value of the rainfall in a set season of the hot spring villa;
step 48: according to the historical annual average rainfall of the hot spring villa site selection place, the rainfall suitability corresponding to the set season and the safe rainfall of the hot spring villa site selection place stored in the hot spring villa health care project database, the rainfall suitability corresponding to the hot spring villa site selection place is analyzed, and the calculation formula is as follows:wherein omega is represented as the rainfall suitability corresponding to the hot spring mountain villa site selection, and beta' are respectively represented as the historical average rainfall of the hot spring mountain villa site selection and the safe rainfall of the hot spring mountain villa site selection, A 1 、A 2 Correction factors respectively expressed as the average rainfall suitability of the historical years of preset hot spring villa site selection places and the rainfall suitability corresponding to the set seasons, and A 1 +A 2 =1。
4. The regional health care project construction site selection analysis and evaluation method according to claim 3, wherein the method comprises the following steps of: the specific analysis steps of the temperature suitability of each hot spring villa site selection land area in the step 5 are as follows:
step 51: extracting the temperature of each hot spring mountain village site selection subarea in each history year from a hot spring mountain village health care project database, and classifying the temperature of each hot spring mountain village site selection subarea in each history year according to seasons, so as to obtain a set of temperatures of each hot spring mountain village site selection subarea in each history year corresponding to each season;
step 52: each season is respectively numbered as M 1 、M 2 、M 3 And M 4 Wherein M is 1 M 1 、M 2 、M 3 And M 4 Respectively expressed as spring, summer, autumn and winter;
step 53: extracting the lowest temperature of each hot spring villa site selection land subarea corresponding to each season of each history period from each season temperature set of each hot spring villa site selection subarea corresponding to each history period;
step 54: comparing the lowest temperatures of the hot spring village site selection subareas corresponding to the seasons to which the historical years belong, and further selecting the minimum value as the lowest temperature of the hot spring village site selection subareas corresponding to the seasons;
step 55: comparing the lowest temperatures of the hot spring village site selection subareas corresponding to the seasons, and further selecting the minimum value as a temperature lower limit value of the hot spring village site selection subareas corresponding to the seasons;
step 56: extracting temperature lower limit warning values of the hot spring village site selection land subareas corresponding to seasons from a hot spring village health care project database;
step 57: analyzing the temperature suitability of each hot spring mountain villa site selection land subarea according to the temperature lower limit warning value of each season and the temperature lower limit value of each season corresponding to each hot spring mountain villa site selection land subarea, wherein the calculation formula is as follows:wherein ζ h Temperature suitability expressed as h hot spring villa site selection land area, ++>The temperature lower limit value of the h hot spring villa site selection land subarea corresponding to spring, summer, autumn and winter respectively is +.>The temperature lower limit warning values respectively indicated as the h hot spring villa site selection land subareas correspond to spring, summer, autumn and winter.
5. The regional health care project construction site selection analysis and evaluation method based on claim 4 is characterized in that: the specific calculation formula of the temperature suitability corresponding to the hot spring mountain villa site selection place is as follows:wherein the method comprises the steps ofExpressed as the temperature suitability corresponding to the location of the spa mountain villa.
6. The regional health care project construction site selection analysis and evaluation method based on claim 5 is characterized in that: the specific calculation formula of the comprehensive evaluation coefficient of the hot spring mountain villa site selection is as follows:wherein psi is expressed as comprehensive evaluation coefficient of hot spring villa site selection, gamma 1 、γ 2 、γ 3 、γ 3 Respectively expressed as an influence factor of a proper coefficient of hot spring water quality, an influence factor of a feasible coefficient corresponding to a hot spring villa site selection, an influence factor of rainfall suitability, an influence factor of temperature suitability, and gamma 1 +γ 2 +γ 3 +γ 4 =1。
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