CN113503623A - Air conditioning unit on-line measuring monitored control system - Google Patents

Abstract

The invention discloses an air conditioning unit online detection monitoring system, which comprises a region monitoring module, a unit synchronization unit, a monitoring analysis unit, a basic database and a processor, wherein the region monitoring module is used for monitoring the region of an air conditioning unit; the unit synchronization unit is used for synchronizing air conditioner setting information in the controlled area, and the air conditioner setting information is the distribution position and the total number of air conditioners in the corresponding controlled area; then, a region monitoring module is combined with a unit synchronization unit to carry out range monitoring, and regulation and control information formed by fusion of the scaling rate, the top rate, the bottom rate and the neutral rate is obtained mainly through related simulation operations; through regulation and control information, and the condition of on-the-spot number of people, open different air conditioner regulation and control steps under the different condition, when the people is many and relevant user's specific demand, carry out the quick adjustment of a temperature, can also avoid opening unnecessary air conditioner, under the condition of guaranteeing the temperature control effect, the purpose of temperature regulation and control is reached in the minimum air conditioner that opens.

Description

Air conditioning unit on-line measuring monitored control system

Technical Field

The invention belongs to the field of air conditioner monitoring, relates to a temperature regulation and control technology, and particularly relates to an air conditioner unit online detection monitoring system.

Background

Patent publication No. CN111478835A discloses an air conditioning unit monitoring device, a monitoring method, an air conditioning system, and a storage medium. Wherein, air conditioning unit supervisory equipment includes: a first register; the processor is used for acquiring the data of the air conditioning unit communicated with the air conditioning unit monitoring equipment and storing the data of the communicated air conditioning unit into the first register; and the interactive interface is used for reading the data of the communicated air conditioning unit in the first register and displaying the data of the communicated air conditioning unit. According to the air conditioning unit monitoring equipment, the data of the communicated air conditioning unit is stored as the local variable in advance, so that the phenomenon that communication blockage is caused by the fact that the variable of the remote register of the air conditioning unit is still inquired when some air conditioning units do not exist (namely are not communicated) is avoided, the data refreshing speed of other air conditioning units is reduced, and the occupation of processor resources of the air conditioning unit monitoring equipment is reduced.

However, for some controlled areas, when joint temperature control of communication of a plurality of air conditioning units is adopted, how to coordinately start the air conditioning units is avoided, resource waste caused by simultaneous starting is avoided, meanwhile, the number of started air conditioners can be reasonably distributed, the effect is guaranteed, and the problem is not provided for a corresponding solution.

Disclosure of Invention

The invention aims to provide an air conditioning unit online detection monitoring system.

The purpose of the invention can be realized by the following technical scheme:

an air conditioning unit on-line detection monitoring system comprises a region monitoring module, a unit synchronization unit, a monitoring analysis unit, a basic database and a processor;

the unit synchronization unit is used for synchronizing air conditioner setting information in the controlled area, wherein the air conditioner setting information is the distribution position and the total number of air conditioners in the corresponding controlled area; the region monitoring module is used for carrying out range monitoring in combination with the unit synchronization unit, and the range monitoring comprises the following specific steps:

the method comprises the following steps: acquiring air conditioner setting information stored in a unit synchronization unit, and acquiring the positions of all air conditioners;

step two: then, carrying out area division on the controlled areas to obtain a plurality of primary areas Yi, i which is 1.. n and a plurality of secondary areas Ej, j which is 1.. m;

step three: then, all the air conditioners in the primary region are turned on simultaneously, and correlation analysis is carried out when the temperature of the primary region is reduced, so that the standard direction variability, the top direction variability, the bottom direction variability and the neutral direction variability are obtained;

step four: the four modes of regulation and control and the corresponding standard variability, top variability, bottom variability and neutral variability are fused to form regulation and control information;

the monitoring and analyzing unit is used for transmitting the regulation and control information to the processor, and the processor is used for transmitting the regulation and control information to the basic database.

Further, the area division in the step two specifically includes:

s1: acquiring the moving range of a controlled area; the activity range determination mode is as follows:

when people exist in the corresponding area and the stay time of one day exceeds T1 time, marking the people as activity;

connecting the outermost movable points to form a movable range;

s2: then acquiring the area of the movable range and the air conditioner in the area of the movable range, and marking the air conditioner as a first-stage unit;

s3: marking the rest air conditioners as secondary units;

s4: then dividing the area of the movable range by the number of the first-stage units to obtain a single area;

s5: then dividing the activity range into a plurality of equally divided single areas, wherein the air conditioner in each primary unit is positioned at the central position;

s6: obtaining a plurality of primary regions, and marking the primary regions as Yi, i-1.. n;

s7: dividing the secondary unit into a plurality of secondary areas by taking the position of the secondary unit as a center, and marking the secondary areas as Ej, j being 1.

Further, the specific manner of the correlation analysis in step three is as follows:

s01: when opening all the air conditioners in the primary areas, taking four monitoring points on the peripheral side of each primary area;

s02: selecting a first-level area, and marking the time from starting the air conditioner to the time when the temperature is adjusted to change by X1 temperature as an adjustment value when all the temperatures of the four monitoring points are adjusted to change by X1 temperatures;

s03: dividing X1 by the modulation value to obtain a temperature-rate;

s04: optionally selecting the next one-level region, and repeating the steps S02-S04 to obtain all temperature-rate changes which are marked as temperature-rate change groups;

s05: calculating the mean value of the temperature change rates, and deleting the temperature change rates of which the difference values between all the temperature change rates and the mean value exceed X2;

s06: averaging the rest temperature change rates again, and marking the obtained average as a standard direction change rate;

s07: then opening all air conditioners in the first-level area and the second-level area, repeating the steps S02-S06, and marking the obtained value as the top variability;

s08: then, only turning on all air conditioners in the secondary area, repeating the principle of the steps S02-S06, and marking the measured value as a bottom gradient rate;

s09: then all the air conditioners in the primary area are obtained, the air conditioners in the primary area are opened in a mode of separating one air conditioner, namely after one air conditioner is opened, the adjacent air conditioners are closed;

s010: the principles of steps S02-S06 are then repeated, with the measured values labeled as the intermediate variability.

Furthermore, the system also comprises a temperature measuring unit, an air conditioning unit regulating and controlling module and an item combination analyzing unit;

the temperature measurement unit is used for acquiring a combination item analysis unit and an air conditioning unit regulation and control module to regulate the temperature;

the device also comprises a management unit which is in communication connection with the processor and is used for recording all preset numerical values.

Further, the specific manner of temperature adjustment is as follows:

SS 1: acquiring the maximum quantification of the controlled area;

SS 2: then acquiring the real-time number of people in the controlled area, and marking the people at the corresponding positions when the people appear in the primary area or the secondary area for more than T4 time; t4 is a preset value;

SS 3: marking the personnel appearing in the first-level area as first-level personnel, and marking the personnel appearing in the second-level area as second-level personnel;

SS 4: the real-time parameters of the calculators are specifically calculated by the following formula:

real-time personnel parameters 0.675 +0.325 for the first personnel and the second personnel;

SS 5: dividing the real-time personnel parameters by the maximum quantification, and marking the obtained value as a control parameter value Kc;

SS 6: determining the slight item standard value in the following mode:

SS 61: acquiring the maximum number of people in a controlled area, and dividing an interval value, wherein the interval value is a preset numerical value of a manager;

SS 62: dividing the number of people in the controlled area into a plurality of areas according to the area values to obtain an area people array;

SS 63: acquiring the proportion of the maximum number of people occupied by the maximum number of people and the minimum number of people in each interval, and marking the proportion as the corresponding interval occupation ratio;

SS 64: then acquiring a temperature drop time reference table required by corresponding personnel, wherein the temperature drop time reference table is used for adjusting the temperature to a target value for a time corresponding to different intervals;

SS 66: when the corresponding temperature drop of the human array in each interval is obtained, marking the value as a mark-less value;

SS 6: acquiring the indoor temperature at the moment, and when the difference value between the indoor temperature and the preset comfortable temperature is obtained, sequentially dividing the difference value by the standard direction variability, the top direction variability, the bottom direction variability and the middle direction variability to obtain values which are sequentially calibrated to be standard direction time, top direction time, bottom direction time and middle direction time;

SS 7: acquiring a corresponding interval human array of the corresponding control parameter value Kc, and acquiring a corresponding abbreviated index value; marking the scaling rate, the top rate, the bottom rate and the middle rate which are most approximate to the trivial item scaling value in the scaling time, the top rate, the bottom rate and the middle rate as regulation and control modes;

if the slight item value is larger than the top direction time, the regulation and control mode still adopts a mode corresponding to the top direction variability;

if the slight item value is smaller than the bottom direction time mode, the regulation mode still adopts the mode corresponding to the bottom direction variability;

SS 8: and regulating and controlling the temperature of the air conditioner according to a regulation and control mode by means of an air conditioning unit regulation and control module.

Further, the maximum quantitative determination in step SS1 is:

and (4) SS 101: acquiring the daily number of people in the controlled area within nearly X3 days, wherein the number of people is confirmed in a manner that when the people appear in the controlled area and the appearance time exceeds T2, the number of people is increased by one; here X3 is a preset number;

and the SS 102: the number of people present each day is then marked as Lo, o 1.. X3; wherein L1 is represented as the first day of the first X3 days, then Lo is represented as day o of the first X3 days;

and SS 103: then, carrying out weight calibration on the number of people in each day, firstly summing the numerical values of 1-X3, marking the sum as a day sum, and then defining the weight of the number of people corresponding to each day, wherein the weight is specifically as follows:

when the number is X3, the weight of the number of people is X3/day sum;

and the SS 104: and then, multiplying the number of people in each day by the weight, then, accumulating all the people, then, calculating the average value, and marking the obtained average value as the maximum quantification of the controlled area.

The invention has the beneficial effects that:

the unit synchronization unit is used for synchronizing the air conditioner setting information in the controlled area, and the air conditioner setting information is the distribution position and the total number of the air conditioners in the corresponding controlled area; then, a region monitoring module is combined with a unit synchronization unit to carry out range monitoring, and regulation and control information formed by fusion of the scaling rate, the top rate, the bottom rate and the neutral rate is obtained mainly through related simulation operations;

then through regulation and control information, and the condition of on-the-spot number of people, open different air conditioner regulation and control steps under the different condition, when the people is many and relevant user's specific demand, carry out the quick adjustment of a temperature, can also avoid opening unnecessary air conditioner, under the condition of guaranteeing the temperature control effect, the minimum air conditioner that opens reaches the purpose of temperature regulation and control.

Drawings

In order to facilitate understanding for those skilled in the art, the present invention will be further described with reference to the accompanying drawings.

FIG. 1 is a block diagram of the system of the present invention.

Detailed Description

As shown in fig. 1, an on-line detection monitoring system for an air conditioning unit includes a region monitoring module, a unit synchronization unit, a monitoring analysis unit, a basic database and a processor;

the unit synchronization unit is used for synchronizing air conditioner setting information in the controlled area, wherein the air conditioner setting information is the distribution position and the total number of air conditioners in the corresponding controlled area; the region monitoring module is used for carrying out range monitoring in combination with the unit synchronization unit, and the range monitoring comprises the following specific steps:

the method comprises the following steps: acquiring air conditioner setting information stored in a unit synchronization unit, and acquiring the positions of all air conditioners;

step two: and then, carrying out area division of the controlled area, wherein the specific division steps are as follows:

s1: acquiring the moving range of a controlled area; the activity range determination mode is as follows:

when people exist in the corresponding area and the stay time of one day exceeds T1 time, marking the people as activity;

connecting the outermost movable points to form a movable range;

s2: then acquiring the area of the movable range and the air conditioner in the area of the movable range, and marking the air conditioner as a first-stage unit;

s3: marking the rest air conditioners as secondary units;

s4: then dividing the area of the movable range by the number of the first-stage units to obtain a single area;

s5: then dividing the activity range into a plurality of equally divided single areas, wherein the air conditioner in each primary unit is positioned at the central position;

s6: obtaining a plurality of primary regions, and marking the primary regions as Yi, i-1.. n;

s7: dividing the secondary unit into a plurality of secondary areas by taking the position of the secondary unit as a center, and marking the secondary areas as Ej, j being 1.. m;

step three: and then, opening all the air conditioners in the primary area at the same time, and when the temperature of the primary area is reduced, specifically acquiring the following modes:

s01: when opening all the air conditioners in the primary areas, taking four monitoring points on the peripheral side of each primary area;

s02: selecting a first-level area, and marking the time from starting the air conditioner to the time when the temperature is adjusted to change by X1 temperature as an adjustment value when all the temperatures of the four monitoring points are adjusted to change by X1 temperatures; the temperature adjustment table moves the temperature of X1, namely the temperature of the corresponding monitoring point is increased or decreased by X1 temperatures;

s03: dividing X1 by the modulation value to obtain a temperature-rate;

s04: optionally selecting the next one-level region, and repeating the steps S02-S04 to obtain all temperature-rate changes which are marked as temperature-rate change groups;

s05: calculating the mean value of the temperature change rates, and deleting the temperature change rates of which the difference values between all the temperature change rates and the mean value exceed X2;

s06: averaging the rest temperature change rates again, and marking the obtained average as a standard direction change rate;

s07: then opening all air conditioners in the first-level area and the second-level area, repeating the steps S02-S06, and marking the obtained value as the top variability;

s08: then, only turning on all air conditioners in the secondary area, repeating the principle of the steps S02-S06, and marking the measured value as a bottom gradient rate;

s09: then all the air conditioners in the primary area are obtained, the air conditioners in the primary area are opened in a mode of separating one air conditioner, namely after one air conditioner is opened, the adjacent air conditioners are closed;

s010: repeating the principle of steps S02-S06, and marking the measured values as the moderate variability;

step four: the four modes of regulation and control and the corresponding standard variability, top variability, bottom variability and neutral variability are fused to form regulation and control information;

the monitoring and analyzing unit is used for transmitting the regulation and control information to the processor, and the processor is used for transmitting the regulation and control information to the basic database;

as another embodiment of the present invention, on the basis of the first embodiment, the present application further includes a temperature measurement unit, an air conditioning unit regulation and control module, and an item combination analysis unit;

the temperature measurement unit is used for acquiring a combination item analysis unit and an air conditioning unit regulation and control module to regulate the temperature, and the specific mode of temperature regulation is as follows:

SS 1: obtaining the maximum quantification of the controlled area, wherein the maximum quantification determination mode is as follows:

and (4) SS 101: acquiring the daily number of people in the controlled area within nearly X3 days, wherein the number of people is confirmed in a manner that when the people appear in the controlled area and the appearance time exceeds T2, the number of people is increased by one; here X3 is a preset number;

and the SS 102: the number of people present each day is then marked as Lo, o 1.. X3; wherein L1 is represented as the first day of the first X3 days, then Lo is represented as day o of the first X3 days;

and SS 103: then, carrying out weight calibration on the number of people in each day, firstly summing the numerical values of 1-X3, marking the sum as a day sum, and then defining the weight of the number of people corresponding to each day, wherein the weight is specifically as follows:

when the number is X3, the weight of the number of people is X3/day sum;

and the SS 104: then, the number of people in each day is multiplied by the weight value and then all the people are accumulated, then the average value is obtained, and the obtained average value is marked as the maximum quantification of the controlled area;

SS 2: then acquiring the real-time number of people in the controlled area, and marking the people at the corresponding positions when the people appear in the primary area or the secondary area for more than T4 time; t4 is a preset value;

SS 3: marking the personnel appearing in the first-level area as first-level personnel, and marking the personnel appearing in the second-level area as second-level personnel;

SS 4: the real-time parameters of the calculators are specifically calculated by the following formula:

real-time personnel parameters 0.675 +0.325 for the first personnel and the second personnel;

SS 5: dividing the real-time personnel parameters by the maximum quantification, and marking the obtained value as a control parameter value Kc;

SS 6: determining the slight item standard value in the following mode:

SS 61: acquiring the maximum number of people in a controlled area, and dividing an interval value, wherein the interval value is a preset numerical value of a manager;

SS 62: dividing the number of people in the controlled area into a plurality of areas according to the area values to obtain an area people array;

SS 63: acquiring the proportion of the maximum number of people occupied by the maximum number of people and the minimum number of people in each interval, and marking the proportion as the corresponding interval occupation ratio;

SS 64: then acquiring a temperature drop time reference table required by corresponding personnel, wherein the temperature drop time reference table is used for adjusting the temperature to a target value for a time corresponding to different intervals; the temperature control device is used for indicating how long the temperature needs to be controlled within a corresponding range when the number of people corresponds to different numbers, and is obtained by repeated experiments for a manager when the temperature is reduced;

SS 66: when the corresponding temperature drop of the human array in each interval is obtained, marking the value as a mark-less value;

SS 6: acquiring the indoor temperature at the moment, and when the difference value between the indoor temperature and the preset comfortable temperature is obtained, sequentially dividing the difference value by the standard direction variability, the top direction variability, the bottom direction variability and the middle direction variability to obtain values which are sequentially calibrated to be standard direction time, top direction time, bottom direction time and middle direction time;

SS 7: acquiring a corresponding interval human array of the corresponding control parameter value Kc, and acquiring a corresponding abbreviated index value; marking the scaling rate, the top rate, the bottom rate and the middle rate which are most approximate to the trivial item scaling value in the scaling time, the top rate, the bottom rate and the middle rate as regulation and control modes;

if the slight item value is larger than the top direction time, the regulation and control mode still adopts a mode corresponding to the top direction variability;

if the slight item value is smaller than the bottom direction time mode, the regulation mode still adopts the mode corresponding to the bottom direction variability;

SS 8: regulating and controlling the temperature of the air conditioner according to a regulation and control mode by means of an air conditioning unit regulation and control module;

the device also comprises a management unit which is in communication connection with the processor and is used for recording all preset numerical values.

The foregoing is merely exemplary and illustrative of the present invention and various modifications, additions and substitutions may be made by those skilled in the art to the specific embodiments described without departing from the scope of the invention as defined in the following claims.

Claims (6)

1. The utility model provides an air conditioning unit on-line measuring monitored control system which characterized in that includes:

the unit synchronization unit is used for synchronizing air conditioner setting information in the controlled area, wherein the air conditioner setting information is the distribution position and the total number of air conditioners in the corresponding controlled area;

the regional monitoring module is used for carrying out range monitoring by combining the unit synchronization unit, and the range monitoring comprises the following specific steps:

the method comprises the following steps: acquiring air conditioner setting information stored in a unit synchronization unit, and acquiring the positions of all air conditioners;

step two: then, carrying out area division on the controlled areas to obtain a plurality of primary areas Yi, i which is 1.. n and a plurality of secondary areas Ej, j which is 1.. m;

step three: then, all the air conditioners in the primary region are turned on simultaneously, and correlation analysis is carried out when the temperature of the primary region is reduced, so that the standard direction variability, the top direction variability, the bottom direction variability and the neutral direction variability are obtained;

step four: the four modes of regulation and control and the corresponding standard variability, top variability, bottom variability and neutral variability are fused to form regulation and control information;

the monitoring and analyzing unit is used for transmitting the regulation and control information to the processor, and the processor is used for transmitting the regulation and control information to the basic database.

2. The air conditioning unit on-line detection monitoring system according to claim 1, wherein the area division in the second step comprises the following specific division steps:

s1: acquiring the moving range of a controlled area; the activity range determination mode is as follows:

when people exist in the corresponding area and the stay time of one day exceeds T1 time, marking the people as activity;

connecting the outermost movable points to form a movable range;

s2: then acquiring the area of the movable range and the air conditioner in the area of the movable range, and marking the air conditioner as a first-stage unit;

s3: marking the rest air conditioners as secondary units;

s4: then dividing the area of the movable range by the number of the first-stage units to obtain a single area;

s5: then dividing the activity range into a plurality of equally divided single areas, wherein the air conditioner in each primary unit is positioned at the central position;

s6: obtaining a plurality of primary regions, and marking the primary regions as Yi, i-1.. n;

s7: dividing the secondary unit into a plurality of secondary areas by taking the position of the secondary unit as a center, and marking the secondary areas as Ej, j being 1.

3. The air conditioning unit on-line detection monitoring system according to claim 1, wherein the correlation analysis in step three is specifically as follows:

step S01: when opening all the air conditioners in the primary areas, taking four monitoring points on the peripheral side of each primary area;

step S02: selecting a first-level area, and marking the time from starting the air conditioner to the time when the temperature is adjusted to change by X1 temperature as an adjustment value when all the temperatures of the four monitoring points are adjusted to change by X1 temperatures;

step S03: dividing X1 by the modulation value to obtain a temperature-rate;

step S04: optionally selecting the next one-level region, and repeating the steps S02-S04 to obtain all temperature-rate changes which are marked as temperature-rate change groups;

step S05: calculating the mean value of the temperature change rates, and deleting the temperature change rates of which the difference values between all the temperature change rates and the mean value exceed X2;

step S06: averaging the rest temperature change rates again, and marking the obtained average as a standard direction change rate;

step S07: then opening all air conditioners in the first-level area and the second-level area, repeating the steps S02-S06, and marking the obtained value as the top variability;

step S08: then, only turning on all air conditioners in the secondary area, repeating the principle of the steps S02-S06, and marking the measured value as a bottom gradient rate;

step S09: then all the air conditioners in the primary area are obtained, the air conditioners in the primary area are opened in a mode of separating one air conditioner, namely after one air conditioner is opened, the adjacent air conditioners are closed;

s010: the principles of steps S02-S06 are then repeated, with the measured values labeled as the intermediate variability.

4. The air conditioning unit on-line detection monitoring system according to claim 1, further comprising a temperature measuring unit, an air conditioning unit regulating and controlling module, and an item combining and analyzing unit;

the temperature measurement unit is used for acquiring a combination item analysis unit and an air conditioning unit regulation and control module to regulate the temperature;

the device also comprises a management unit which is in communication connection with the processor and is used for recording all preset numerical values.

5. The air conditioning unit on-line detection monitoring system according to claim 1, wherein the temperature is adjusted in a specific manner as follows:

SS 1: acquiring the maximum quantification of the controlled area;

SS 2: then acquiring the real-time number of people in the controlled area, and marking the people at the corresponding positions when the people appear in the primary area or the secondary area for more than T4 time; t4 is a preset value;

SS 3: marking the personnel appearing in the first-level area as first-level personnel, and marking the personnel appearing in the second-level area as second-level personnel;

SS 4: the real-time parameters of the calculators are specifically calculated by the following formula:

real-time personnel parameters 0.675 +0.325 for the first personnel and the second personnel;

SS 5: dividing the real-time personnel parameters by the maximum quantification, and marking the obtained value as a control parameter value Kc;

SS 6: determining the slight item standard value in the following mode:

SS 61: acquiring the maximum number of people in a controlled area, and dividing an interval value, wherein the interval value is a preset numerical value of a manager;

SS 62: dividing the number of people in the controlled area into a plurality of areas according to the area values to obtain an area people array;

SS 63: acquiring the proportion of the maximum number of people occupied by the maximum number of people and the minimum number of people in each interval, and marking the proportion as the corresponding interval occupation ratio;

SS 64: then acquiring a temperature drop time reference table required by corresponding personnel, wherein the temperature drop time reference table is used for adjusting the temperature to a target value for a time corresponding to different intervals;

SS 66: when the corresponding temperature drop of the human array in each interval is obtained, marking the value as a mark-less value;

SS 6: acquiring the indoor temperature at the moment, and when the difference value between the indoor temperature and the preset comfortable temperature is obtained, sequentially dividing the difference value by the standard direction variability, the top direction variability, the bottom direction variability and the middle direction variability to obtain values which are sequentially calibrated to be standard direction time, top direction time, bottom direction time and middle direction time;

SS 7: acquiring a corresponding interval human array of the corresponding control parameter value Kc, and acquiring a corresponding abbreviated index value; marking the scaling rate, the top rate, the bottom rate and the middle rate which are most approximate to the trivial item scaling value in the scaling time, the top rate, the bottom rate and the middle rate as regulation and control modes;

if the slight item value is larger than the top direction time, the regulation and control mode still adopts a mode corresponding to the top direction variability;

if the slight item value is smaller than the bottom direction time mode, the regulation mode still adopts the mode corresponding to the bottom direction variability;

SS 8: and regulating and controlling the temperature of the air conditioner according to a regulation and control mode by means of an air conditioning unit regulation and control module.

6. The air conditioning unit on-line detection monitoring system of claim 5, wherein the maximum quantitative determination in SS1 is as follows:

and (4) SS 101: acquiring the daily number of people in the controlled area within nearly X3 days, wherein the number of people is confirmed in a manner that when the people appear in the controlled area and the appearance time exceeds T2, the number of people is increased by one; here X3 is a preset number;

and the SS 102: the number of people present each day is then marked as Lo, o 1.. X3; wherein L1 is represented as the first day of the first X3 days, then Lo is represented as day o of the first X3 days;

and SS 103: then, carrying out weight calibration on the number of people in each day, firstly summing the numerical values of 1-X3, marking the sum as a day sum, and then defining the weight of the number of people corresponding to each day, wherein the weight is specifically as follows:

when the number is X3, the weight of the number of people is X3/day sum;

and the SS 104: and then, multiplying the number of people in each day by the weight, then, accumulating all the people, then, calculating the average value, and marking the obtained average value as the maximum quantification of the controlled area.

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