CN106765959A - Heat-air conditioner energy-saving control method based on genetic algorithm and depth B P neural network algorithms - Google Patents
Heat-air conditioner energy-saving control method based on genetic algorithm and depth B P neural network algorithms Download PDFInfo
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F2110/00—Control inputs relating to air properties
- F24F2110/10—Temperature
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/30—Control or safety arrangements for purposes related to the operation of the system, e.g. for safety or monitoring
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/62—Control or safety arrangements characterised by the type of control or by internal processing, e.g. using fuzzy logic, adaptive control or estimation of values
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F2110/00—Control inputs relating to air properties
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F2110/00—Control inputs relating to air properties
- F24F2110/20—Humidity
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F2110/00—Control inputs relating to air properties
- F24F2110/50—Air quality properties
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/62—Control or safety arrangements characterised by the type of control or by internal processing, e.g. using fuzzy logic, adaptive control or estimation of values
- F24F11/63—Electronic processing
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F2110/00—Control inputs relating to air properties
- F24F2110/10—Temperature
- F24F2110/12—Temperature of the outside air
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F2110/00—Control inputs relating to air properties
- F24F2110/20—Humidity
- F24F2110/22—Humidity of the outside air
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F2110/00—Control inputs relating to air properties
- F24F2110/30—Velocity
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F2110/00—Control inputs relating to air properties
- F24F2110/30—Velocity
- F24F2110/32—Velocity of the outside air
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F2110/00—Control inputs relating to air properties
- F24F2110/50—Air quality properties
- F24F2110/64—Airborne particle content
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Abstract
The present invention provides a kind of heating ventilation air-conditioning system automation control method based on genetic algorithm and depth B P neural network algorithms, to solve the problems, such as that heating ventilation air-conditioning system day-to-day operation process sees active Energy Saving Control, and the body-sensing experience for improving intelligent building indoor environment comfort level.The present invention builds the BP neural network based on intelligent building Monitoring Data, in order to improve system control effect, realize predictable precise control, by the use of heating ventilation air-conditioning system day-to-day operation data as training sample, carry out neural metwork training, heat-air conditioner energy-saving control forecasting model is set up, heating ventilation air-conditioning system is solved in itself because operating mode is complicated, the modeling problem with the complex control characteristic such as non-linear, large time delay and ambient influnence;Genetic algorithm is introduced into solve the problems, such as to be absorbed in local optimum in BP neural network training process and convergence is slow;The present invention carries out operational factor and adjusts control using neutral net, and the purpose of environment sensing and energy-conservation is actively improved to reach heating ventilation air-conditioning system.
Description
Technical field
The present invention relates to intelligent building field, and in particular to the Automated condtrol of heating ventilation air-conditioning system in intelligent building, profit
With genetic algorithm and depth B P neural network algorithms realizing the side to hvac equipment intelligentized control method and energy-conservation in building
Method.
Background technology
Genetic algorithm (Genetic Algorithm) is natural selection and the science of heredity machine for simulating Darwinian evolutionism
The computation model of the biological evolution process of reason, is a kind of method by simulating natural evolution process searches optimal solution.
Artificial neural network (Artificial Neural Network, i.e. ANN), it is from information processing angle to human brain
Neuroid carries out abstract, the simple analog model of foundation, and different networks are constituted by different connected modes.More than nearest ten
Nian Lai, the research work of artificial neural network deepens continuously, and has been achieved for very big progress, and it is in pattern-recognition, intelligent machine
Device people, automatically control, predicted estimate, biology, medical science, economic dispatch field have successfully solved many modern computers and have been difficult to solve
Practical problem certainly, shows good intelligent characteristic.
BP (Back Propagation, backpropagation) neutral net is a kind of by many of Back Propagation Algorithm training
Layer feedforward network, is one of current most widely used neural network model.BP networks can learn and store substantial amounts of input-defeated
Exit pattern mapping relations, and without disclosing the math equation of this mapping relations of description in advance.Its learning rules are to use ladder
Degree descent method, the weights and threshold value of network are constantly adjusted by backpropagation, make the error sum of squares of network minimum.BP nerves
Network model topological structure includes input layer (input), hidden layer (hidden layer) and output layer (output layer).
Sigmoid functions, are a function for common S types in biology, also referred to as S sigmoid growth curves.In information
In science, due to properties such as its list increasing and the increasings of inverse function list, Sigmoid functions are often used as the threshold function table of neutral net,
By between variable mappings to 0,1.
BAS (Building Automation System), i.e. building automation system or equipments of building automation system,
It is by the electric power in building or groups of building, illumination, air-conditioning, plumbing, fire-fighting, transport, security personnel, garage management equipment or is
System, the integrated system constituted for the purpose of centralized watch, control and management.
IBMS (Intelligent Building Management System), i.e. intelligent building/building management system.
IBMS is the building collection for further realizing higher level with communications network system, information network system on the basis of BAS
Into management system.The core of IBMS is that each subsystem in building construction is integrated into the integrated system of " organic ", and it connects
Mouth Interface Standard, standardization, the information exchange and communications protocol for completing each subsystem are changed, and realize five function collection of aspect
Into:The integrated and integrated management of all subsystem informations, centralized watch and control to all subsystems, the pipe of clobal
Reason, process automation management.The final function of realizing centralized watch control and integrated management.
HVAC (Heating, Ventilation and Air Conditioning, abbreviation HVAC) refer to it is indoor or
The system or relevant device of the responsible heating of in-car, ventilation and air adjustment.
With the development of society, intelligent building conservation is global megatrend and main trend, is 21 century Chinese architecture
One emphasis and focus of career development, while be also an urgent demand of Chinese reform and development, and energy-conservation and environmental protection are to realize
The key of sustainable development.From sustained development theory, the crucial of building energy conservation is again to improve energy efficiency, therefore should
Using raising energy efficiency as building energy conservation the starting point, realize intelligent building highly modernize, high comfort while energy
Realize that energy resource consumption is greatly lowered, with the purpose for reaching building construction energy efficiency He cut operating costs.
Heating ventilation air-conditioning system is widely used in intelligent building, and it is larger in the overall energy consumption proportion of building, exceedes
25%.And the current energy saving means of heating ventilation air-conditioning system are limited, it is typically only possible by rational engineering design, improves building guarantor
Warm nature energy, improve the means such as controlled level to realize the purpose of energy-conservation.
The control mode of current heating ventilation air-conditioning system has two kinds:Manually control and arrange parameter are automatically controlled.This two
The experience that kind control mode is all based on people is pre-set, in actual moving process, heating ventilation air-conditioning system Energy Saving Control
Perceptually there is very big subjectivity random and limitation with environment body-sensing comfort level.
The content of the invention
Based on above mentioned problem, the present invention proposes to lift heating ventilation air-conditioning system based on genetic algorithm and neural network algorithm
The quantized data that some links such as Based Intelligent Control level, sensor, actuator, controller to heating ventilation air-conditioning system are collected enters
Row analysis and prediction, so that heating ventilation air-conditioning system Optimum operating control parameter is exported, it is continuable that operating system is carried out
Control adjustment, reaches the purpose of optimal overall efficiency, environmental degree of comfort sensing optimal and active energy-conservation.
The present invention provides a kind of heating ventilation air-conditioning system automation control based on genetic algorithm and depth B P neural network algorithms
Method processed, to solve the problems, such as heating ventilation air-conditioning system day-to-day operation process active Energy Saving Control, and improves ring in intelligent building room
The body-sensing experience of border comfort level.
The present invention adopts the following technical scheme that realization:
A kind of heating ventilation air-conditioning system automation control method based on genetic algorithm and depth B P neural network algorithms, passes through
The control parameter and environmental index parameter of the heating ventilation air-conditioning system collected to IBMS carry out data quantization, utilize the data as
Training sample, carries out neural metwork training, sets up heat-air conditioner energy-saving control forecasting model, using the characteristic reality of BP neural network
The Complex Modeling of existing heating ventilation air-conditioning system;Genetic algorithm is wherein introduced into solve to be absorbed in local optimum in BP neural network training process
The problem slow with convergence;
After the completion of neural metwork training, IBMS passes through air-conditioning system configuration data and the environmental monitoring data for collecting,
From amenity and the angle of energy-conservation, periodically attempt calculating air conditioner operation parameters, and be input in neutral net
It is predicted, according to the feedback result of neutral net, IBMS carries out automatic operating adjustment, is finally reached to heating ventilation air-conditioning system
Optimal and active energy-conservation the purpose of environment sensing.
Comprise the following steps that;
Step S201, IBMS system completes number by collecting current HVAC service data and environmental monitoring data
According to normalized;
Step S202, IBMS system calculates HVAC combustion adjustment of lower a moment ginseng from environmental degree of comfort and Energy Angle
Number;
Step S203, combustion adjustment parameter of lower a moment is input to carries out validity in the neutral net for having trained and comment
Estimate;
Step S204, the neutral net for having trained output assessment result, if assessment result is not up to desirable level,
IBMS systems recalculate adjusting parameter, re-start assessment;
Step S205, HVAC combustion adjustment parameter evaluation reach desirable level, IMBS systems then output control signal,
Operational factor adjustment is carried out to HVAC;
Step S206, heating ventilation air-conditioning system combustion adjustment control flow terminate.
The process of the neural metwork training includes:
Determine |input paramete;
It is determined that after |input paramete, carrying out |input paramete normalized, deviation standardization, is the line to initial data
Property conversion, numerical value is mapped between [0-1.0];Transfer function is as follows:
Wherein, max is sample data codomain maximum, and min is sample data codomain minimum value, and x samples for sample data
Value, x* is the data value after linear transformation;
After normalized, start to build the neutral net on basis, determine the neutral net number of plies and each layer nerve
The quantity of unit;
It is determined that after complete each layer of neuronal quantity, setting excitation function:
Wherein, e is natural constant;
The amount of bias Bias values of each neuron, the i.e. default weight value of each neuron are set;
One group of weight coefficient of satisfaction requirement is found by learning using genetic algorithm, makes given error function minimum;
In learning process, judge whether the error amount of network meets requirement and use following computational methods:
Wherein, tjIt is desired value, yjIt is the output valve of each neuron, EpBe an error for nervous layer and, E is whole
The error of neutral net and;
By the study of many wheels, deconditioning is just started until error reaches expected accuracy.
The Weight Training step adjusted by genetic algorithm between the initial neuron of BP neural network is as follows;
Step S102, BP neural network parameter initialization, are normalized to sample data, again to output after training
Carry out renormalization treatment, training sample, by using genetic algorithm and depth B P Neural Network Predictions after normalized
Model is trained;
Step S103, initialization population, population is obtained using roulette, and Population Size can determine based on experience value, base
Present principles are that calculating is sampled to sample, and the purpose of optimization is reached by crossover operation;
Step S104, calculating Population adaptation value, the error between prediction data and expected data is used as fitness function;
Step S105, crossover operation, hybrid rate are adjusted based on experience value, and are determined by testing;
In step S106, mutation operation, aberration rate is adjusted based on experience value, and is determined by testing;
Step S107, circulation are selected, intersected, being made a variation, being calculated adaptation Value Operations, until reaching evolution number of times, are obtained
Optimal initial weight;
Step S108, acquisition neutral net initial weight, using genetic algorithm initialization weight, threshold value, work as genetic algorithm
When having performed a generation, the weight of a new generation reinserts neutral net;
Step S109, the output valve for calculating hidden layer, exporting node layer;
Step S110, calculating hidden layer, the output error value of output layer;
Step S111, using error calculation method calculation error, judge whether to reach acceptable error range, be subjected to
Error then train and terminate;
Step S112, constantly adjust each layer connection weight and threshold value;
Step S113, neural metwork training terminate.
Control method described in the invention needs to be integrated with intelligent building management system (hereinafter referred to as IBMS), whole
Individual invention is divided into two parts:One is that heating ventilation air-conditioning system day-to-day operation data and indoor and outdoor surroundingses monitoring number are obtained from IBMS
According to, using obtain sample data neutral net is trained, period can using genetic algorithm carry out weights it is miscellaneous plus variation, enter
Row Multiple Training is until neutral net is ripe;Two is IBMS according to obtaining heating ventilation air-conditioning system in the neutral net for having trained maturation
Control assessment parameter, adjustment is controlled to heating ventilation air-conditioning system operational factor.
Due to heating ventilation air-conditioning system operating mode complexity in itself, with the complicated control such as non-linear, large time delay and ambient influnence
Characteristic processed so that basis modeling is extremely difficult, in order to improve system control effect, realizes predictable precise control, the present invention
By the use of heating ventilation air-conditioning system day-to-day operation data as training sample, neural metwork training is carried out, set up heat-air conditioner energy-saving control
Forecast model processed.
Realize heating ventilation air-conditioning system automation control method in intelligent building using the method described in the present invention, with
Under several advantages:
(1) forecast model is trained based on heating ventilation air-conditioning system day-to-day operation data and environmental monitoring data, realizes air-conditioning
Full automation Based Intelligent Control, and preferable environmental degree of comfort can be obtained perceive.
(2) realize that the automatic control air conditioner of HVAC is opened, closed, automatically adjust temperature, humidity, ventilation value, can reach
To preferable energy-saving effect.
Brief description of the drawings
Fig. 1 is the relation schematic diagram in embodiment between neural computing unit and IBMS systems;
Fig. 2 trains flow chart to combine the BP neural network of genetic algorithm in embodiment;
Fig. 3 realizes intelligent control to assess heating ventilation air-conditioning system control parameter validity using neutral net in embodiment
The flow chart of system.
Specific embodiment
Highly preferred embodiment of the present invention needs to use IBMS systems, and IBMS systems will have heating ventilation air-conditioning system data to adopt
Collection is accessed and control ability.Wherein IBMS can gather the data such as heating ventilation air-conditioning system, environment temperature, humidity detection.The present invention
The control method of proposition belongs to the part in IBMS systems, with the relation of IBMS as shown in Figure 1.In having this implementation process also
Need to have BP neural network and the corresponding rudimentary knowledge of genetic algorithm.
The present invention proposes that heating ventilation air-conditioning system control method is mainly every by the heating ventilation air-conditioning system collected to IBMS
Control parameter and environmental index parameter carry out data quantization, and the complexity of heating ventilation air-conditioning system is realized using the characteristic of BP neural network
Modeling.
First, |input paramete is determined.IBMS systems have been usually directed to HVAC empty in building construction information system management is carried out
Adjusting system control parameter, environmental monitoring data, season (spring, summer, autumn, winter), period, people stream counting etc..Wherein HVAC control
Parameter processed mainly includes current air-conditioning temperature, blasting humidity, air-supply wind speed;Environmental monitoring data mainly includes outdoor temp
Degree, indoor temperature, outside humidity, indoor humidity, outdoor wind speed, indoor air velocity, gas concentration lwevel, outdoor PM2.5 concentration, room
Interior PM2.5 concentration.
It is determined that after |input paramete, carrying out |input paramete normalized, deviation standardization, is the line to initial data
Property conversion, numerical value is mapped between [0,1.0].Transfer function is as follows:
In transfer function, max is sample data codomain maximum, and min is sample data codomain minimum value, and x is sample number
According to sample value.After completing to calculate, x* is the data value after linear transformation, and codomain is in [0,1.0] interval.
For the conversion of discontinuous change input variable, such as season, can be quantified as:[spring, summer, autumn, winter]=[0.0,
0.33,0.66,1.0];24 hours can be quantified as whole day by the period:[0,1/24,…,23/24].Use above-mentioned input variable
Transform method come complete input variable numerical transformation work.
It is determined that after |input paramete, starting to build the neutral net on basis.Select to build 3 layers of nerve net in implementation process
Network, includes 1 input layer, 1 output layer and 1 hidden layer.The selection of the neutral net number of plies under normal circumstances needs to be based on
Experience judges, for facility on describing, it is 3 that the number of plies is selected here.
It is determined that after the neutral net number of plies, starting to determine the quantity of each layer neuron.Input layer god is selected in the present embodiment
It is 5 through first quantity, because the |input paramete respectively obtained from IBMS systems has been divided into 5 classes totally 15 quantizating index:HVAC system
System control parameter, environmental monitoring data, season (spring, summer, autumn, winter), period, people stream counting, therefore basis in the present embodiment
Input data categorizing selection input layer quantity is 5.The selection of output layer neuron number is 3, then middle hidden layer
Neuron number is 4, and computational methods can use following empirical equation:
Wherein, in is input layer number, and out is output layer neuron number, and h is individual for hidden layer neuron
Number;
It is determined that being that each nerve sets Sigmoid excitation functions after complete each layer of neuronal quantity.BP neural network
Sigmoid functions or linear function are generally used as excitation function, can be in the hope of BP using Sigmoid functions or its derivative
The summation of certain neuron, desired value and error amount in neutral net.Formula is described as follows:
Wherein, e is natural constant e (about 2.71828), and the codomain of f (x) is interval [0,1] after calculating, is judged with this
Neuron is state of activation or holddown.
The amount of bias Bias values of each neuron are set, that is, each neuron default weight value.Neutral net
Essence is a non-linear expressions for complexity, and bias is equivalent to its zero degree term coefficient.1 is set in the present embodiment.
So far can set up substantially and contain a BP neural network for the standard of hidden layer.But standard BP neural network
Have the following disadvantages:Convergence rate is slow, is absorbed in local optimum, it is difficult to determine the implicit number of plies and hidden layer neuron number.Therefore
Each layer weight is hybridized present invention introduces genetic algorithm, it is complete to reach Fast Convergent and solve the problems, such as that local optimum is realized
The optimal purpose of office.Because being related to the complexity of heating ventilation air-conditioning system, it is impossible to determine the concrete structure and weight of neutral net
Coefficient, can only be by obtaining a model for meeting day-to-day operation demand after study, its cardinal principle is, by study, to find
One group of weight coefficient of satisfaction requirement, makes given error function minimum.In sample data learning process, the mistake of network is judged
Whether difference meets requirement mainly uses following computational methods:
Wherein, tjIt is the desired value of each neuron, yjBe the output valve of each neuron, m be each layer of neuron
Number, p is the number of plies of neutral net, EpFor an error for nervous layer and, E be whole neutral net error and.
By the study of many wheels, deconditioning is just started until error reaches expected accuracy.
After the completion of network training, during heating ventilation air-conditioning system day-to-day operation, IBMS systems pass through the sky for collecting
Adjusting system configuration data and environmental monitoring data, from amenity and the angle of energy-conservation, periodically attempt calculating empty
Allocation and transportation line parameter, and be input in neutral net and be predicted, according to the feedback result of neutral net, IBMS is to HVAC system
System carries out automatic operating adjustment, is finally reached optimal and active energy-conservation the purpose of environment sensing.
Next, just two idiographic flows of the invention are described:
The Weight Training flow S100 adjusted by genetic algorithm between the initial neuron of BP neural network in the present invention
As shown in Fig. 2 flow S100 originates in S101.
In step s 102, BP neural network parameter initialization, is normalized to sample data, right again after training
Output carries out renormalization treatment, training sample, by using genetic algorithm and depth B P neural network algorithms after normalized
Forecast model is trained.
In step s 103, population is initialized, population is obtained using roulette, Population Size can be true based on experience value
Fixed, general principle is that calculating is sampled to sample, and the purpose of optimization is reached by crossover operation.
In step S104, Population adaptation value is calculated, the error between prediction data and expected data is used as fitness letter
Number.
In step S105, crossover operation, hybrid rate can be adjusted based on experience value, and be determined by testing.
In step s 106, mutation operation, aberration rate can be adjusted based on experience value, and be determined by testing.
In step s 107, circulation is selected, intersected, being made a variation, being calculated adaptation Value Operations, until reaching evolution number of times,
Obtain optimal initial weight.
In step S108, neutral net initial weight is obtained, using genetic algorithm initialization weight, threshold value, work as heredity
During the complete generation of algorithm performs, the weight of a new generation reinserts neutral net, and weight can be evolved into arbitrary size, not by any
The limitation of form.
In step S109, hidden layer, the output valve of output node layer are calculated.
In step s 110, hidden layer, the output error value of output layer are calculated.
In step S111, using error calculation method calculation error, judge whether to reach acceptable error range, can
The error of receiving is then trained and terminated.
In step S112, each layer connection weight and threshold value are constantly adjusted.
In step S113, neural metwork training terminates.
So far, the BP neural network training flow that genetic algorithm is combined in the present invention is described.
The IBMS of realization of the invention assesses heating ventilation air-conditioning system control parameter validity by neutral net, realizes intelligence
Change the flow of control method as shown in figure 3, starting from S200.
In step s 201, IBMS systems are by collecting current HVAC service data and environmental monitoring data and complete
Into data normalization treatment.
In step S202, IBMS systems calculate the operation of HVAC of lower a moment and adjust from environmental degree of comfort and Energy Angle
Whole parameter.
In step S203, combustion adjustment parameter of lower a moment is input in the neutral net for having trained carries out validity
Assessment.
In step S204, the neutral net output assessment result for having trained, if assessment result is not up to preferable water
Flat, then IBMS systems recalculate adjusting parameter, re-start assessment.
In step S205, HVAC combustion adjustment parameter evaluation reaches desirable level, IMBS systems then output control
Signal, operational factor adjustment is carried out to HVAC.
In step S206, heating ventilation air-conditioning system combustion adjustment control flow terminates.
So far, heating ventilation air-conditioning system control parameter validity is assessed using neutral net in the present embodiment, is realized intelligent
The flow of control is described.
Using the method described in the present invention, using heating ventilation air-conditioning system day-to-day operation data as training sample, carry out
Neural metwork training, sets up heat-air conditioner energy-saving control forecasting model, finally realizes that heating ventilation air-conditioning system is automatic in intelligent building
Change control method, with following advantage:
(1) forecast model is trained based on heating ventilation air-conditioning system day-to-day operation data and environmental monitoring data, realizes air-conditioning
Full automation Based Intelligent Control, and preferable environmental degree of comfort can be obtained perceive.
(2) realize that the automatic control air conditioner of HVAC is opened, closed, automatically adjust temperature, humidity, ventilation value, can reach
To preferable energy-saving effect.
The description of above-described embodiment flow only for clear explanation basic skills of the invention, but on the present invention is not limited in
State embodiment;Every any simple modification, equivalent variations and modification made according to embodiment in technical spirit of the invention,
Fall within the protection domain of technical scheme.
Claims (4)
1. a kind of heating ventilation air-conditioning system automation control method based on genetic algorithm and depth B P neural network algorithms, its feature
It is:Data quantization is carried out by the control parameter and environmental index parameter of the heating ventilation air-conditioning system collected to IBMS, is utilized
The data carry out neural metwork training as training sample, heat-air conditioner energy-saving control forecasting model are set up, using BP nerve nets
The characteristic of network realizes the Complex Modeling of heating ventilation air-conditioning system;Genetic algorithm is wherein introduced into solve to be fallen into BP neural network training process
Enter local optimum and the slow problem of convergence;
After the completion of neural metwork training, IBMS passes through air-conditioning system configuration data and the environmental monitoring data for collecting, from ring
The angle of border comfortableness and energy-conservation is set out, and periodically attempts calculating air conditioner operation parameters, and is input in neutral net and is carried out
Prediction, according to the feedback result of neutral net, IBMS carries out automatic operating adjustment, is finally reached environment to heating ventilation air-conditioning system
Perceive the purpose of optimal and active energy-conservation.
2. a kind of heating ventilation air-conditioning system based on genetic algorithm and depth B P neural network algorithms according to claim 1 from
Dynamicization control method, it is characterised in that:Comprise the following steps that;
Step S201, IBMS system is returned by collecting current HVAC service data and environmental monitoring data, and completing data
One change is processed;
Step S202, IBMS system calculates HVAC combustion adjustment parameter of lower a moment from environmental degree of comfort and Energy Angle;
Step S203, combustion adjustment parameter of lower a moment is input in the neutral net for having trained carries out efficiency assessment;
Step S204, the neutral net for having trained output assessment result, if assessment result is not up to desirable level, IBMS
System recalculates adjusting parameter, re-starts assessment;
Step S205, HVAC combustion adjustment parameter evaluation reach desirable level, IMBS systems then output control signal, to warm
Logical air-conditioning carries out operational factor adjustment;
Step S206, heating ventilation air-conditioning system combustion adjustment control flow terminate.
3. a kind of heating ventilation air-conditioning system based on genetic algorithm and depth B P neural network algorithms according to claim 2 from
Dynamicization control method, it is characterised in that;The process of the neural metwork training includes:
Determine |input paramete;
It is determined that after |input paramete, carrying out |input paramete normalized, deviation standardization, is the linear change to initial data
Change, numerical value is mapped between [0-1.0];Transfer function is as follows:
Wherein, max is sample data codomain maximum, and min is sample data codomain minimum value, and x is sample data sample value, x*
It is the data value after linear transformation;
After normalized, start to build the neutral net on basis, determine the neutral net number of plies and each layer neuron
Quantity;
It is determined that after complete each layer of neuronal quantity, setting excitation function:
Wherein, e is natural constant;
The amount of bias Bias values of each neuron, the i.e. default weight value of each neuron are set;
One group of weight coefficient of satisfaction requirement is found by learning using genetic algorithm, makes given error function minimum;Learning
During habit, judge whether the error amount of network meets requirement and use following computational methods:
Wherein, tjIt is desired value, yjIt is the output valve of each neuron, EpBe an error for nervous layer and, E is whole nerve
The error of network and;
By the study of many wheels, deconditioning is just started until error reaches expected accuracy.
4. a kind of heating ventilation air-conditioning system based on genetic algorithm and depth B P neural network algorithms according to claim 3 from
Dynamicization control method, it is characterised in that:The Weight Training adjusted by genetic algorithm between the initial neuron of BP neural network is walked
It is rapid as follows;
Step S102, BP neural network parameter initialization, are normalized to sample data, and output is carried out again after training
Renormalization treatment, training sample, by using genetic algorithm and depth B P Neural Network Prediction models after normalized
It is trained;
Step S103, initialization population, population is obtained using roulette, and Population Size can determine based on experience value, substantially former
Reason is that calculating is sampled to sample, and the purpose of optimization is reached by crossover operation;
Step S104, calculating Population adaptation value, the error between prediction data and expected data is used as fitness function;
Step S105, crossover operation, hybrid rate are adjusted based on experience value, and are determined by testing;
In step S106, mutation operation, aberration rate is adjusted based on experience value, and is determined by testing;
Step S107, circulation are selected, intersected, being made a variation, being calculated adaptation Value Operations, until reaching evolution number of times, obtain optimal
Initial weight;
Step S108, acquisition neutral net initial weight, using genetic algorithm initialization weight, threshold value, when genetic algorithm is performed
During a complete generation, the weight of a new generation reinserts neutral net;
Step S109, the output valve for calculating hidden layer, exporting node layer;
Step S110, calculating hidden layer, the output error value of output layer;
Step S111, using error calculation method calculation error, judge whether to reach acceptable error range, acceptable mistake
Poor then training terminates;
Step S112, constantly adjust each layer connection weight and threshold value;
Step S113, neural metwork training terminate.
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