KR20220079224A - Intelligent home energy mangement system and method based on federated learning - Google Patents

Abstract

Intelligent home energy management method to which federated learning is applied according to the present invention comprises the steps of: (a) generating, by a master server, an artificial intelligence initial model for energy efficiency improvement; (b) distributing, by the master server, delivering the initial model to a plurality of home energy management systems; (c) generating, by the home energy management system, a weight difference using the initial model; (d) updating, by the master server, the initial model by reflecting the weight difference; And (e) redistributing the initial model updated by the master server to the home energy management system; using Federated Learning technology, including; to implement an optimal energy management system without external transmission of personal information It works.

Description

Intelligent home energy management system and method applying federated learning

The present invention relates to an intelligent home energy management system to which federated learning is applied. More specifically, the upper learning server distributes an artificial intelligence model to a plurality of lower terminals and updates the upper model based on the model weights re-learned in the lower terminals. It relates to an intelligent home energy management system that can optimize home energy consumption efficiency through federated learning to apply federated learning.

Conventionally, for the efficiency of a home energy management system (HEMS), personal information such as device operation information and behavior pattern of a resident must be transmitted to a higher learning server, but in this case, there is a problem in that personal information protection is weak.

In particular, since the learning in the upper server is concentrated, the upper server collects and processes the data transmitted from a number of home energy management systems, and in the process of transmitting and receiving a large amount of data according to re-learning, it places a considerable burden on the network load, which can reduce efficiency. There is a problem.

Republic of Korea Patent Publication No. 10-2044553 (2019.11.07)

In order to solve the above problems, the present invention utilizes Federated Learning technology to protect personal information by preventing personal information from being transmitted to the outside, and to improve network efficiency by preventing the information from being concentrated and collected to a higher server. The purpose of this is to provide an intelligent home energy management system to which joint learning is applied.

Intelligent home energy management method to which federated learning is applied according to the present invention for achieving the above object comprises the steps of: (a) generating, by a master server, an artificial intelligence initial model for energy efficiency improvement; (b) distributing, by the master server, delivering the initial model to a plurality of home energy management systems; (c) generating, by the home energy management system, a weight difference using the initial model; (d) updating, by the master server, the initial model by reflecting the weight difference; and (e) redistributing the initial model updated by the master server to the home energy management system.

Preferably, the step (c) of the intelligent home energy management method to which the federated learning is applied according to the present invention for achieving the above-described object includes (c-1) the home energy management system receiving the initial model; (c-2) collecting, by the home energy management system, data generated from devices in each home; (c-4) re-learning the initial model using the data collected in step (c-2) by the home energy management system; (c-5) generating, by the home energy management system, an optimal energy management model through re-learning; (c-6) calculating, by the home energy management system, a weight difference by comparing the initial model with the optimal energy management model generated in step (c-5); and (c-7) transmitting the weight difference (Model Weight Difference) calculated by the home energy management system 200 to the master server.

Preferably, (c-3) the home energy management system collects between steps (c-2) and (c-4) of the intelligent home energy management method to which the federated learning according to the present invention is applied to achieve the above-mentioned object. Refining one data so that it can be used in the initial model; characterized in that it further includes.

Preferably, in the step (c-4) of the intelligent home energy management method to which the federated learning is applied according to the present invention for achieving the above-mentioned object, the home energy management system is the user's It is characterized in that the re-learning is carried out in the direction of minimizing the consumption charge according to energy use.

Preferably, in the intelligent home energy management method to which the federated learning is applied according to the present invention for achieving the above object, the master server, which is the upper learning server, distributes the initial model to the plurality of home energy management systems that are lower terminals, and the lower It is characterized in that the initial model is updated through federated learning based on the weight difference of the re-learned model in the home energy management system.

The intelligent home energy management system to which federated learning is applied according to the present invention utilizes Federated Learning technology to optimize energy without external transmission of personal information.

It has the effect of implementing a management system.

In addition, since the intelligent home energy management system to which the federated learning according to the present invention is applied does not need to collect a large amount of information from the standpoint of the upper server, it is possible to increase the network efficiency.

1 is a block diagram of an intelligent home energy management system to which joint learning according to the present invention is applied.
2 is a flowchart of an intelligent home energy management method to which joint learning is applied according to the present invention.
3 is a flowchart of the step of generating a weight difference among the intelligent home energy management method to which the federated learning according to the present invention is applied.

The terms or words used in the present specification and claims should not be construed as being limited to their ordinary or dictionary meanings, and the inventor may properly define the concept of the term in order to best describe his invention. Based on the principle that there is, it should be interpreted as meaning and concept consistent with the technical idea of the present invention.

Accordingly, the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiment of the present invention and do not represent all the technical spirit of the present invention, so they can be substituted at the time of the present application It should be understood that various equivalents and modifications may exist.

Hereinafter, an intelligent home energy management system and method to which joint learning is applied according to the present invention will be described with reference to the accompanying drawings.

As shown in FIG. 1 , the intelligent home energy management system to which the federated learning according to the present invention is applied is built in the master server 100 and the smart home to manage the energy of the home, and the home connected to the master server 100 wirelessly It includes an energy management system (HEMS: 200), and an Internet communication network 300 that provides a wireless communication environment between the master server 100 and the home energy management system 200 built in the smart home.

A plurality of home energy management systems 200 connected to the master server 100 include a system control unit 210, a smart meter connected to the system control unit 210 (SMART METER: 220), various home appliances 230, health Devices that affect consumption and generation of power in the home, such as the band 240 and the solar power generation device 250 are connected.

The smart meter 220 generates power consumption and voltage applied to the load while monitoring the wiring cables wired in the home.

The various home appliances 230 are smart devices and are connected to the Home Network to generate operation data according to operation.

In addition, the health band 240 generates bio-information, and the photovoltaic device 250 generates photovoltaic power generation amount and charge/discharge data.

An energy management method by an intelligent home energy management system to which joint learning is applied according to the present invention having the configuration as described above will be described in detail with reference to FIG. 2 .

2 is a flowchart of an energy management method by an intelligent home energy management system to which federated learning according to the present invention is applied.

The master server 100 performs the step of generating an artificial intelligence initial model for improving energy efficiency (S100).

More specifically, the master server 100 includes household power consumption and voltage generated by the smart meter 220 , device operation data generated by the home appliance 230 , and bioinformation generated by the health band 240 . , and generating an artificial intelligence initial model for improving energy efficiency by using the amount of power generated by the photovoltaic device 250 and charging/discharging data as parameters.

In particular, the master server 100 is connected to the plurality of home energy management systems 200 to receive the above-described parameters from each household to generate a different initial model for each household.

The initial model is an energy management algorithm learned based on data that can be collected in a general household as described above.

The master server 100 transmits and distributes the initial model to the home energy management system 200 (S200).

The home energy management system 200 performs the step of generating a weight difference using the initial model distributed in the step (S200) (S300).

Referring to FIG. 3, the step S300 will be described in more detail. First, the system control unit 210 of the home energy management system 200 performs a step of receiving the distributed initial model (S310).

Thereafter, the home energy management system 200 may obtain an optimal artificial intelligence model specialized for each household after learning the energy consumption pattern of the corresponding household for a predetermined time with the initial model distributed.

The initial model is a model with the most basic and general energy consumption pattern characteristics, and is a model of an average concept.

Thereafter, the home energy management system 200 performs a step of collecting data generated from various devices in each home, such as the aforementioned smart meter, various home appliances, and health band for a certain period ( S320 ).

The home energy management system 200 performs a step of refining the data collected in step S320 into data for model re-learning (S330).

Data acquired to achieve optimal energy consumption efficiency and can be differentiated according to the configuration of energy facilities in each home.

Based on various power sources (commercial power source, solar power generation, wind power generation, etc.) and load unit (home appliance), an optimal energy management model that reflects the living pattern of the resident will be constructed.

At this time, the living pattern of the resident is estimated based on biometric information such as home appliance operation information and health band (heart rate, moving distance, going out, etc.).

With the initial model distributed from the master server 100, the home energy management system 200 receives the data collected from the load unit through the system control unit 210 as learning data, and the consumption rate according to the user's energy use A step of re-learning is performed for the purpose of minimizing (S340).

The home energy management system 200 through the above-described learning reflects the diversity of energy facilities and consumption patterns of each home, and generates an optimal energy management model reflecting the life pattern of each household resident ( S350).

In this case, the optimal energy management model generated by the home energy management system 200 may have various learnable data parameters, and may be a model that can better express the characteristics of the household over a long period of time.

The home energy management system 200 compares the initial model initially received from the master server 100 with the optimal energy management model generated in step S600 by re-learning through the step S500 and weight difference (Model Weight Difference) A step of calculating is performed (S360).

The home energy management system 220 performs the step of transmitting the weight difference calculated in step S360 to the master server 100 (S370).

The difference in weight can be explained as the difference in the numerical value of the connection when the degree of connection between numerous nodes (nodes on the graph that determines the weight) in a specific network is expressed numerically, after the first learning.

The artificial intelligence model can be expressed as a set of weights expressing the degree of connection between nodes numerically. By transmitting, the initial model or the optimal energy management model can be distributed without leaking personal information to the outside.

The master server 100 performs the step of updating the initial model by using the weight difference (Model Weight Difference) (S400).

That is, the master server 100 collects the weight difference (Model Weight Difference) of each household received from the home energy management system 200 and reflects the initial model as an optimal energy management model for the household. update

For reference, a machine learning machine recognizes the world as a formula such as H(x) = wx + b. Here, x is the input elements, and w is multiplied by each input element to determine how much the input element affects the result, and each model that has undergone machine learning has its own weight, the master server Reinforcement learning performed in (100) improves this weight through re-learning.

The master server 100 redistributes the optimal energy management model updated from the initial model to the system control unit 210 of the home energy management system 200 (S900).

The system controller 210 receives the updated optimal energy management model and updates the home energy management system 200, thereby operating the optimal home energy management system 200 (S600).

As a core technology of Federated Learning, it can be explained by the difference between the global artificial intelligence model deployed in the initial upper system and the model reconstructed through additional learning with data generated at home (Smart Home).

The specific value is the calculation result between the layers constituting the artificial neural network and the nodes constituting each layer, and the value is determined according to the activation function applied to each layer.

Unlike the existing method of learning artificial intelligence by collecting all data into a server, federated learning processes data and strengthens the model on the mobile device used by the user, and collects the model in one place to create a more sophisticated model is a method to create and redistribute. The possibility of information leakage is low because only the model is transmitted/shared, not the training data to the server.

In the above, the technical idea of the present invention has been described along with the accompanying drawings, but the preferred embodiment of the present invention is exemplarily described and does not limit the present invention. In addition, it is clear that various modifications and imitations are possible without departing from the scope of the technical spirit of the present invention by anyone having ordinary knowledge in the technical field to which the present invention pertains.

100 : master server
200: Home Energy Management System (HEMS:HOME ENERGY MANGEMENT SYSTEM)
210: system control unit
220 : smart meter
230: home appliances
240: health band
250: solar power generation device
300: communication network

Claims (5)

(a) generating, by the master server, an artificial intelligence initial model for energy efficiency improvement;
(b) distributing the master server by delivering the initial model to a plurality of home energy management systems;
(c) generating, by the home energy management system, a weight difference using the initial model;
(d) updating, by the master server, the initial model by reflecting the weight difference; and
(E) redistributing the initial model updated by the master server to the home energy management system; Intelligent home energy management method to which federated learning is applied, comprising: a.
The method of claim 1,
Step (c) is
(c-1) the home energy management system receiving the initial model;
(c-2) collecting, by the home energy management system, data generated from devices in each home;
(c-4) re-learning the initial model using the data collected in step (c-2) by the home energy management system;
(c-5) generating, by the home energy management system, an optimal energy management model through re-learning;
(c-6) calculating, by the home energy management system, a weight difference by comparing the initial model with the optimal energy management model generated in step (c-5); and
(c-7) transmitting the weight difference (Model Weight Difference) calculated by the home energy management system 200 to the master server; Intelligent home energy management method to which federated learning is applied, comprising: a.
3. The method of claim 2,
Between the steps (c-2) and (c-4)
(c-3) refining the data collected by the home energy management system so that it can be used in the initial model; intelligent home energy management method to which federated learning is applied, characterized in that it further comprises.
4. The method of claim 3
In step (c-4) above
The home energy management system is
Intelligent home energy management method to which federated learning is applied, characterized in that re-learning is carried out in the direction of minimizing consumption charges according to the user's energy use with data generated and collected by devices in each home.
5. The method of claim 4,
The master server, which is the upper learning server,
Distributing an initial model to a plurality of the home energy management system that is a lower level terminal, and updating the initial model through federated learning based on the weight difference of the model re-learned in the lower home energy management system. An intelligent home energy management method applying learning.

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