WO2023132655A1 - Management server for upgrading electronic device and method for upgrading electronic device - Google Patents

Abstract

A management server according to an embodiment of the present invention comprises: a storage unit storing upgrade data for upgrading an electronic device; a communication unit which transmits the upgrade data to the electronic device; and a control unit which controls storage of the upgrade data and transmission of the upgrade data, wherein the control unit determines an upgrade method on the basis of at least one of a function to be upgraded, a capacity of the upgrade data, a format of the upgrade data, an expected transmission time of the upgrade data, and identification information of a home appliance, and controls transmission of the upgrade data according to the determined upgrade method.

Description

Management server for upgrading electronic devices, and method for upgrading electronic devices

The present invention relates to a management server capable of upgrading functions and a method of upgrading an electronic device.

The electronic device includes a control unit that controls the operation of the electronic device. The controller controls the electronic device to implement a function desired by a user by executing a specific program.

In general, after an electronic device is sold, only simple support such as error correction is provided for the program. Accordingly, when a user needs an electronic device that performs a new function, the user must purchase a new electronic device. That is, the electronic device purchased by the user resulted in a significant decrease in residual value as time passed, and this became a user's complaint.

Accordingly, a method of improving the function of an electronic device or adding a function that the electronic device can perform by modifying the program is being studied, and some of these methods are actually implemented.

In order to modify the program of the electronic device, data including the program must be transmitted to the electronic device. However, it takes a lot of time to transmit such data, which becomes an obstacle in modifying the program.

In addition, according to the conventional method, the upgrade of the electronic device is performed according to one predetermined method. For example, the entire program is transmitted from the server to the electronic device, or the program is divided into predetermined units, the entire changed part of the divided units is transmitted from the server to the electronic device, and then the electronic device performs an update. proceeded.

However, the number of functions performed by electronic devices is increasing, and the capacity of programs required to perform each function is also diversifying. In addition, the time at which data including a program is transmitted varies greatly depending on the environment in which electronic devices are used or the characteristics of the electronic devices. Accordingly, there is a need for a method for upgrading electronic devices more efficiently.

For example, as the functions of an electronic device become more advanced, the size of a program for performing these functions may increase significantly. In this case, there is a problem in that the amount of data transmitted to upgrade the electronic device in the conventional method increases, and as a result, the time taken for the upgrade also increases.

Also, when the volume of data to be transmitted for the upgrade is large, the time required to receive the file for the upgrade may be very long. In this case, when users want to use the electronic device after upgrading the electronic device, they have to wait for the completion of the upgrade for a long time due to file reception time.

An object of the present invention is to provide a device and method for upgrading functions of an electronic device more conveniently and efficiently.

Another object of the present invention is to provide a device and method capable of reducing the time required to upgrade the function of an electronic device.

Another object of the present invention is to provide an apparatus and method capable of reducing the amount of data transmitted when upgrading the function of an electronic device.

In addition, an object of the present invention is to complete the function upgrade operation of the electronic device normally without causing problems such as an error even when the operation of the electronic device is stopped due to a power failure or the like while upgrading the function of the electronic device. To provide an apparatus and method.

Another object of the present invention is to provide a method and apparatus capable of reducing an upgrade time felt by a user when upgrading a function of an electronic device.

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention not mentioned above can be understood by the following description and will be more clearly understood by the examples of the present invention. It will also be readily apparent that the objects and advantages of the present invention may be realized by means of the instrumentalities and combinations indicated in the claims.

A management server and method according to an embodiment of the present invention considers the capacity of data for upgrading an electronic device and the time required to transmit data for upgrading an electronic device, and a method for upgrading an electronic device. can decide

A management server according to an embodiment of the present invention includes a storage unit for storing upgrade data for upgrading an electronic device, a communication unit for transmitting the upgrade data to the electronic device, storage of the upgrade data, and transmission of the upgrade data. And a control unit for controlling, wherein the control unit determines an upgrade method based on at least one or more of a function to be upgraded, a capacity of upgrade data, a format of upgrade data, an expected transmission time of upgrade data, and identification information of a home appliance, Transmission of the upgrade data is controlled according to the determined upgrade scheme.

The upgrade method of the management server according to an embodiment of the present invention is composed of data different from program data stored in the electronic device among program data of the latest version after the management server receives upgrade acceptance from the user of the electronic device. A delta upgrade scheme for transmitting the upgrade data including delta data, and an automatic upgrade scheme for receiving an upgrade acceptance from a user of the electronic device after the management server transmits the upgrade data.

The control unit of the management server according to an embodiment of the present invention controls the transmission of the upgrade data according to the automatic upgrade method when the capacity of the upgrade data is equal to or greater than the first standard capacity, and the capacity of the upgrade data is equal to or greater than the first standard capacity. If the capacity is less than the reference capacity, transmission of the upgrade data may be controlled according to the delta upgrade scheme.

The control unit of the management server according to an embodiment of the present invention controls the transmission of the upgrade data according to the automatic upgrade method when the expected transmission time is greater than or equal to the first reference time, and the expected transmission time is equal to or greater than the first reference time. If it is less than 0, the transmission of the upgrade data may be controlled according to the delta upgrade method.

The control unit of the management server according to an embodiment of the present invention controls transmission of the upgrade data according to the automatic upgrade method when the upgrade data does not include a command, and controls transmission of the upgrade data according to the delta upgrade method when the upgrade data includes a command. Transmission of the upgrade data may be controlled according to.

The upgrade method of the management server according to an embodiment of the present invention is a general upgrade method in which the management server transmits the upgrade data including all program data of the latest version after receiving an upgrade acceptance from the user of the electronic device. may further include.

The control unit of the management server according to an embodiment of the present invention controls the transmission of the upgrade data according to the automatic upgrade method when the capacity of the upgrade data is equal to or greater than the first standard capacity, and the capacity of the upgrade data is equal to or greater than the first standard capacity. If the capacity is less than the reference capacity and equal to or greater than the second reference capacity, which is smaller than the first reference capacity, the transmission of the upgrade data is controlled according to the delta upgrade scheme, and if the capacity of the upgrade data is less than the second reference capacity, the normal upgrade scheme is used. Transmission of the upgrade data may be controlled according to.

The control unit of the management server according to an embodiment of the present invention controls the transmission of the upgrade data according to the automatic upgrade method when the expected transmission time is greater than or equal to the first reference time, and the expected transmission time is equal to or greater than the first reference time. If the expected transmission time is less than the second reference time and is equal to or longer than the second reference time shorter than the first reference time, the transmission of the upgrade data is controlled according to the delta upgrade scheme, and if the expected transmission time is less than the second reference time, the upgrade data is controlled according to the normal upgrade scheme. The transmission of upgrade data can be controlled.

According to an embodiment of the present invention, a method for upgrading an electronic device by a management server includes at least one of a function to be upgraded, a capacity of upgrade data, a format of the upgrade data, an expected transmission time of the upgrade data, and identification information of the home appliance. Determining an upgrade method based on one or more, and controlling transmission of the upgrade data according to the determined upgrade method.

In the determining of the upgrade method of the method according to an embodiment of the present invention, the upgrade method may be determined based on the capacity of the upgrade data.

The step of controlling the transmission of the upgrade data of the method according to an embodiment of the present invention may include, after transmitting the upgrade data, when the capacity of the upgrade data is greater than or equal to the first reference capacity, upgrade from the user of the electronic device. Acceptance can be received.

The step of controlling the transmission of the upgrade data of the method according to an embodiment of the present invention may include, when the capacity of the upgrade data is less than the first reference capacity, after receiving an upgrade acceptance from the user of the electronic device, Among the program data of the version, the upgrade data including delta data composed of data different from the program data stored in the electronic device may be transmitted.

The step of controlling transmission of the upgrade data of the method according to an embodiment of the present invention may include receiving upgrade acceptance from the user of the electronic device when the capacity of the upgrade data is less than a second reference capacity smaller than the first reference capacity. After that, the upgrade data including all of the program data of the latest version can be transmitted.

In the step of determining the upgrade method of the method according to an embodiment of the present invention, the upgrade method may be determined based on the expected transmission time.

In the step of controlling the transmission of the upgrade data of the method according to an embodiment of the present invention, when the expected transmission time is greater than or equal to a first criterion, after the upgrade data is transmitted, the user of the electronic device accepts the upgrade. can receive

The step of controlling the transmission of the upgrade data of the method according to an embodiment of the present invention may include, when the expected transmission time is less than the first reference time, after receiving an upgrade acceptance from the user of the electronic device, the latest version The upgrade data including delta data composed of data different from program data stored in the electronic device among the program data of the electronic device may be transmitted.

In the step of controlling the transmission of the upgrade data of the method according to an embodiment of the present invention, if the expected transmission time is less than a second reference time shorter than the first reference time, upgrade acceptance is received from the user of the electronic device. Afterwards, the upgrade data including the entire program data of the latest version can be transmitted.

In the determining of the upgrade method of the method according to an embodiment of the present invention, the upgrade method may be determined based on the format of the upgrade data.

In the step of controlling transmission of the upgrade data of the method according to an embodiment of the present invention, if the upgrade data does not include a command, upgrade acceptance may be received from the user of the electronic device.

The step of controlling the transmission of the upgrade data of the method according to an embodiment of the present invention may include, if the upgrade data includes a command, after receiving an upgrade acceptance from the user of the electronic device, among the program data of the latest version The upgrade data including delta data composed of data different from program data stored in the electronic device may be transmitted.

According to the apparatus and method according to an embodiment of the present invention, the function of an electronic device can be upgraded more conveniently and efficiently.

In addition, according to the apparatus and method according to an embodiment of the present invention, it is possible to reduce the time required to upgrade the function of an electronic device.

In addition, according to the apparatus and method according to an embodiment of the present invention, the amount of data transmitted when upgrading the function of an electronic device can be reduced.

In addition, according to the apparatus and method according to an embodiment of the present invention, even when the operation of the electronic device is stopped due to a power failure or the like while upgrading the function of the electronic device, problems such as an error do not occur and the electronic device normally The function upgrade operation of can be completed.

In addition, according to the apparatus and method according to an embodiment of the present invention, when the capacity of a file for upgrading is large, the user can minimize the user's experience time when upgrading the home appliance by transmitting the file when the user does not recognize it.

In addition, according to the apparatus and method according to an embodiment of the present invention, it is possible to prevent an upgrade without the user's knowledge by performing the upgrade after the user agrees to the upgrade of the home appliance.

In addition, according to the apparatus and method according to an embodiment of the present invention, indiscriminate automatic transmission can be prevented by specifying a file to be automatically transmitted before user consent.

In addition to the effects described above, specific effects of the present invention will be described together while explaining specific details for carrying out the present invention.

1 is a diagram schematically showing the configuration of a system for upgrading an electronic device according to an embodiment of the present invention.

2 is a diagram schematically showing the configuration of a system for upgrading a home appliance according to an embodiment of the present invention, and is a diagram showing the user device of FIG. 1 in more detail.

3 is a block diagram schematically illustrating the configuration of a management server for upgrading a home appliance according to an embodiment of the present invention.

4 is an operational flowchart for explaining the operation of a management server according to an embodiment of the present invention.

5 is a block diagram schematically showing the configuration of an upgradable home appliance according to an embodiment of the present invention.

6 is a block diagram schematically showing a home appliance in which a plurality of devices are separately installed among upgradable home appliances according to an embodiment of the present invention.

7 to 10 are views for explaining overall operations of a method of upgrading a home appliance according to an embodiment of the present invention.

11 is an operation flowchart for explaining one of the upgrading methods of a home appliance according to an embodiment of the present invention.

12 is a diagram for explaining a process of updating program data in one of the methods of upgrading a home appliance according to an embodiment of the present invention.

13 is a diagram for explaining a process of generating and transmitting delta data in one of the methods of upgrading a home appliance according to an embodiment of the present invention.

14 is a diagram schematically showing an example of existing program data and new program data in one of the methods of upgrading a home appliance according to an embodiment of the present invention.

15 and 16 are views for explaining a process of updating program data in one of the methods of upgrading a home appliance according to an embodiment of the present invention.

17 is a diagram for explaining one of the methods of upgrading a home appliance according to an embodiment of the present invention.

18 to 20 are views for explaining a method of transmitting upgrade data of a method of upgrading a home appliance according to an embodiment of the present invention.

21 and 22 are diagrams illustrating an upgrading process in a user terminal for upgrading a home appliance according to an embodiment of the present invention.

The above objects, features and advantages will be described later in detail with reference to the accompanying drawings, and accordingly, those skilled in the art to which the present invention belongs will be able to easily implement the technical spirit of the present invention. In describing the present invention, if it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to indicate the same or similar components.

Although first, second, etc. are used to describe various components, these components are not limited by these terms, of course. These terms are only used to distinguish one component from another component, and unless otherwise stated, the first component may be the second component, of course.

Hereinafter, when a component is described as "connected", "coupled" or "connected" to another component, the components may be directly connected or connected to each other, but other components may be present between each component. It should be understood that "intervening" or that each element may be "connected", "coupled" or "connected" through another element.

Throughout the specification, unless otherwise stated, each element may be singular or plural.

Singular expressions used herein include plural expressions unless the context clearly dictates otherwise. In this application, terms such as "consisting of" or "comprising" should not be construed as necessarily including all of the various components or steps described in the specification, and some of the components or some of the steps It should be construed that it may not be included, or may further include additional components or steps.

Throughout the specification, when "A and/or B" is used, this means A, B or A and B unless otherwise specified, and when used as "C to D", this means unless otherwise specified As long as there is no, it means C or more and D or less.

Hereinafter, an upgradeable electronic device, a management server for upgrading an electronic device, and a method for upgrading an electronic device according to some embodiments of the present invention will be described.

1 is a diagram schematically showing the configuration of a system for upgrading an electronic device according to an embodiment of the present invention. The system according to an embodiment of the present invention includes a management server 100 and a plurality of user devices 210, 220, 230, 240) may be included.

The management server 100 may store information about electronic devices to be upgraded and information about electronic devices possessed by each user.

Information on electronic devices to be upgraded may include program data of the latest version of the electronic device. Depending on the embodiment, information on electronic devices to be upgraded may include identification information of the electronic device, program data for each previous version of the electronic device, and a delta derived according to a comparison result between program data of each previous version and program data of the latest version. At least one or more of data may be further included. Here, the program data is data related to the operation of the electronic device, and refers to data capable of improving the function of the electronic device or adding new functions to the electronic device. For example, when the electronic device is an air conditioner, the program data may be data for improving a program for adjusting one or more of air volume, air direction, and room temperature, or to improve an image displayed through a display module, or to create a new It may be data for displaying an image or data related to a voice guided through a voice guidance module.

Information on electronic devices possessed by each user may include user identification information and identification information of an electronic device associated with the user identification information.

The management server 100 may determine whether to upgrade the electronic device and an upgrade method based on information about the electronic device. A specific method for this will be described later.

In addition, the management server 100 may transmit data for upgrading functions of each of the user devices 210 , 220 , 230 , and 240 (hereinafter referred to as upgrade data). The upgrade data may include program data and/or the delta data of the latest version of the electronic device. Also, according to an embodiment, data transmitted by the management server 100 may include a command set to be executed by each of the user devices 210 , 220 , 230 , and 240 . The management server 100 may determine the type or transmission time of upgrade data according to the above-described upgrade status and upgrade method.

Each of the plurality of user devices 210, 220, 230, and 240 may include one or more electronic devices. Here, the electronic devices include various types of home appliances such as air conditioners, air purifiers, refrigerators, washing machines, clothes management devices, and water purifiers, mobile devices such as smartphones, and various types of electronic devices included in automobiles (for example, It may include various types of devices, such as a device provided for autonomous driving or a device for controlling the operation of a vehicle, etc.).

Also, each of the plurality of user devices 210, 220, 230, and 240 may include at least one user terminal. Each of the one or more electronic devices may update program data in response to a file (ie, a file including delta data and/or a command set) received from the management server 100 .

Hereinafter, as an example of an electronic device to be upgraded, a case of upgrading a home appliance will be described as an example. However, the scope of the present invention is not limited thereto.

FIG. 2 is a diagram schematically showing the configuration of a system for upgrading an electronic device according to an embodiment of the present invention, and is a diagram showing the user device of FIG. 1 in more detail. A system according to an embodiment of the present invention may include a management server 100, an access point 300, a plurality of home appliances 410, 420, 430, 440, 500, 600, and a user terminal 700. can That is, each of the plurality of user devices 210, 220, 230, and 240 in FIG. 1 includes an access point 300, a plurality of home appliances 410, 420, 430, 440, 500, and 600, and a user terminal ( 700) may include at least one or more.

Functions of the management server 100 may be the same as those described in FIG. 1 .

The access point 300 may serve as a relay between the management server 100 and the home appliances 410 , 420 , 500 , and 600 . The access point 300 may be a Wi-Fi router.

Each of the plurality of home appliances 410, 420, 430, 440, 500, and 600 may perform a unique function according to the execution of a corresponding program.

The home appliances 410, 420, 430, and 440 may be home appliances in which a plurality of devices are separately installed and connected to each other for a predetermined function. For example, the 1-1 home appliance 410, the 1-2 home appliance 420, and the 1-3 home appliance 430 control any one of indoor temperature, humidity, and air quality. It is an indoor unit of the air conditioner, and the 1st-4th home appliance 440 may be an outdoor unit of the air conditioner connected to the indoor units. The air quality may include the concentration of fine dust and/or chemicals that cause odors. In addition, the 1-1 home appliance 410 and the 1-2 home appliance 420 may include a communication module (eg, a Wi-Fi module) capable of accessing the access point 300 . In addition, the 1-1 home appliance 410, the 1-2 home appliance 420, the 1-3 home appliance 430, and the 1-4 home appliance 440 are communication modules capable of communicating with each other. can include Each of the 1-1 home appliance 410, 1-2 home appliance 420, and 1-3 home appliance 430 determines the temperature, humidity, and concentration of the indoor air according to the execution of the corresponding program. At least one or more can be adjusted. The 1-4 home appliance 440 may control the operation of at least one of a compressor and a fan according to execution of a corresponding program.

Each of the second home appliance 500 and the third home appliance 600 may be a home appliance that operates independently. For example, each of the second home appliance 500 and the third home appliance 600 may be one of various home appliances such as a washing machine, an air purifier, a clothes care machine, and a refrigerator. Each of the second home appliance 500 and the third home appliance 600 may include a communication module (eg, a Wi-Fi module).

The user terminal 700 may be a mobile terminal of a user who owns a plurality of home appliances 410 , 420 , 430 , 440 , 500 , and 600 .

Depending on the embodiment, the access point 300 may be excluded. In this case, each of the home appliances 410, 420, 500, and 600 may access the management server 100 through an Internet network or the like. In this case, each of the home appliances 410, 420, 500, and 600 may access the management server 100 by wire and/or wirelessly.

In addition, although not shown, according to an embodiment of the present invention, the user device may further include a remote controller capable of controlling each of the plurality of home appliances 410, 420, 430, 440, 500, and 600. The remote controller may transmit/receive data with each of the home appliances controlled by the remote control in a short-distance wireless communication method. For example, the remote controller may transmit/receive data with the home appliances it controls using a Bluetooth method. According to one embodiment of the present invention, not only the plurality of home appliances 410, 420, 430, 440, 500, and 600, but also remote controllers or other devices connected therewith can be upgraded.

3 is a block diagram schematically showing the configuration of a management server for upgrading an electronic device according to an embodiment of the present invention. The management server 100 includes a control unit 110, a communication unit 120, and a storage unit 130. can include

The control unit 110 may transmit program data stored in the storage unit 130 . At this time, the program data transmitted by the control unit 110 may be program data of the latest version. Depending on the embodiment, the control unit 110 generates delta data for each home appliance based on the data stored in the storage unit 130, and the home appliance (410, 420, 500, 600 in FIG. 2) through the communication unit 120. Delta data can also be transmitted with . When transmitting the program data and/or delta data, the control unit 110 may also transmit a command set to be executed by the control unit of the home appliance (410, 420, 500, 600 in FIG. 2).

Also, the controller 110 may determine whether or not to upgrade the home appliance and an upgrade method based on information about the home appliance.

The controller 110 may include at least one processing unit and/or memory. Here, the processing unit may include, for example, a central processing unit (CPU), a graphics processing unit (GPU), a microprocessor, an Application Specific Integrated Circuit (ASIC), Field Programmable Gate Arrays (FPGA), and the like, It can have multiple cores. The memory may be volatile memory (eg, RAM, etc.), non-volatile memory (eg, ROM, flash memory, etc.), or a combination thereof.

The communication unit 120 may transmit a signal to the outside under the control of the control unit 110 . Also, the communication unit 120 may receive a signal from the outside and output the received signal to the control unit 110 . The communication unit 120 may transmit and receive signals by wire and/or wirelessly. Communication unit 120 may include a modem, network interface card (NIC), integrated network interface, radio frequency transmitter/receiver, infrared port, USB connection, or other interface for communication with other computing devices.

The storage unit 130 may store data received through the communication unit 120 and/or data processed by the control unit 110 under the control of the control unit 110 . For example, the storage unit 130 includes user identification information, identification information of a home appliance associated with the user identification information, program data for each version of the home appliance, and program data of previous versions and program data of the latest version. At least one or more of the delta data derived according to the comparison result may be stored.

4 is an operational flowchart for explaining the operation of the management server 100 according to an embodiment of the present invention. Each step shown in FIG. 4 may be performed by the control unit 110 of the management server 100 .

First, the management server 100 may receive product information from the home appliance (step S11). Product information may include at least one or more of user identification information, identification information of a home appliance, and a current program version of the home appliance.

Next, the management server 100 may determine whether to upgrade and/or an upgrade method based on product information (step S12).

For example, the management server 100 may check the user's authority and/or the service being used by using the user's identification information, and determine whether or not to upgrade accordingly. Alternatively, the management server 100 may determine whether or not to upgrade based on the identification information of the home appliance. Alternatively, the management server 100 may determine whether or not to upgrade depending on whether the current program version of the home appliance is the latest version.

In addition, the management server 100 may determine an upgrade method based on at least one of a function to be upgraded, a capacity of upgrade data, a format of the upgrade data, an expected transmission time of the upgrade data, and identification information of the home appliance. For example, the management server 100 may determine an appropriate upgrade method according to functions to be upgraded. Alternatively, the management server 100 may compare the capacity of the upgrade data with at least one reference capacity, and determine an upgrade method according to the result. Alternatively, the management server 100 may determine an upgrade method according to whether the upgrade data includes a command. Alternatively, the management server 100 may determine the type of the home appliance or the connection state of the communication unit of the home appliance using identification information of the home appliance, and determine an upgrade method based on the result. Alternatively, the management server 100 may determine a transmission time required to transmit the upgrade data based on the capacity of the upgrade data and the identification information of the home appliance, and determine an upgrade method based on the result.

According to one embodiment of the present invention, the upgrade method includes a general upgrade method in which all data including a program to perform a function to be upgraded is transmitted to the home appliance and the home appliance is upgraded based on the entire transmitted data, and the delta data A delta upgrade method in which a home appliance is upgraded based on the transmitted delta data, and an automatic upgrade method in which the upgrade data is transmitted to the home appliance before receiving the user's acceptance of the upgrade, and then the home appliance is upgraded according to the user's acceptance of the upgrade. Upgrades may be included.

According to the normal upgrade method and the delta upgrade method, the management server 100 may transmit upgrade data after receiving the user's acceptance of the upgrade. In addition, according to the general upgrade method and the delta upgrade method, upgrade data may be transmitted to a home appliance (more specifically, a function module of the home appliance) in a state in which the intrinsic operation of the home appliance is stopped.

In this specification, the intrinsic operation of the home appliance means an operation for the home appliance to perform its original function. For example, in the case of an air conditioner, an operation of controlling a compressor or a fan to perform cooling or heating may be an inherent operation. In the case of a washing machine, an operation of controlling a motor or a valve to wash laundry may be an inherent operation. In the case of a refrigerator, an operation of controlling a compressor or a fan to adjust or maintain the internal temperature may be an intrinsic operation.

According to the automatic upgrade scheme, upgrade data can be transmitted to a home appliance (more specifically, a function module of the home appliance) regardless of whether the home appliance's intrinsic operation is stopped. That is, according to the automatic upgrade method, some or all of the upgrade data may be transmitted to the home appliance (more specifically, the functional module of the home appliance) while the home appliance performs its own operation.

According to an embodiment of the present invention, the management server 100 may determine an automatic upgrade method as an upgrade method when the capacity of the upgrade data is greater than or equal to the first reference capacity. And/or, if the capacity of the upgrade data is less than the first reference capacity, the management server 100 may determine the upgrade method as a delta upgrade method. And/or, if the capacity of the upgrade data is less than the second reference capacity smaller than the first reference capacity, the management server 100 may determine the upgrade method as a general upgrade method. The first reference capacity may be 1 Mbyte. The second reference capacity may be 128 kbytes. This is because, when the capacity of the upgrade data is equal to or greater than the first reference capacity, it takes a lot of time to transmit the data even if the delta upgrade method is used. In addition, if the capacity of the upgrade data is less than the second reference capacity, it does not take much time to transmit the data even if the delta upgrade method is not used.

Alternatively, according to an embodiment of the present invention, the management server 100 may determine an automatic upgrade method as an upgrade method when the expected transmission time of the upgrade data is equal to or longer than the first reference time. And/or, the management server 100 may determine the upgrade method as a delta upgrade method when the expected transmission time of the upgrade data is less than the first reference time. And/or, the management server 100 may determine an upgrade method as a normal upgrade method when the expected transmission time of the upgrade data is less than a second reference time shorter than the first reference time. The first reference time may be 20 minutes. The second reference dose may be 2 minutes.

Alternatively, according to an embodiment of the present invention, the management server 100 performs an upgrade method when the traffic of a communication line of a home appliance to be upgraded and/or a function module of the home appliance is equal to or greater than a reference ratio to the capacity of the communication line. You can decide on a normal upgrade method or a delta upgrade method. And/or, the management server 100 may determine an upgrade method in an automatic upgrade method when the traffic of a communication line of a home appliance to be upgraded and/or a function module of the home appliance is less than a reference ratio to the capacity of the communication line. . This is because it takes a lot of time to transmit the upgrade data even if the automatic upgrade method is used when traffic on the communication line is usually high.

Alternatively, according to an embodiment of the present invention, the management server 100 may determine an automatic upgrade method as an upgrade method when the upgrade data does not include a command.

The management server 100 may determine an upgrade method by complexly considering two or more of the various determination criteria described above.

Next, the management server 100 may provide upgrade information to the home appliance and/or user terminal 700 and receive upgrade acceptance from the home appliance and/or user terminal 700 (step S13). In addition, the management server 100 may transmit upgrade data to the home appliance (step S14).

The order of steps S13 and S14 may be changed. That is, as described above, the management server 100 may perform step S14 after performing step S13 when upgrading according to the normal upgrade method or the delta upgrade method. Alternatively, when upgrading according to the automatic upgrade method, the management server 100 may perform step S14 and then step S13.

Then, the management server 100 may request the home appliance to perform an upgrade operation.

5 is a block diagram schematically showing the configuration of an upgradable electronic device according to an embodiment of the present invention, and the electronic device according to an embodiment of the present invention includes a first communication unit 810, a control unit 820, and a second 3 storage unit 830 may be included. The first communication unit 810 may include a storage unit 811 and a transmission/reception unit 812, and the control unit 820 may include a processing unit 821, a first storage unit 822, and a second storage unit 823. ) may be included. Each of the home appliances 410 , 420 , 500 , and 600 of FIG. 2 may include the configuration shown in FIG. 4 . Also, according to embodiments, an electronic device according to an embodiment of the present invention may not include some of the first storage unit 822, the second storage unit 823, and the third storage unit 830. .

The first communication unit 810 may receive data from the management server (100 in FIG. 1 or 2) and transmit the received data to the controller 820. The data received from the management server (100 in FIG. 1 or 2) may include at least one of program data, delta data described above, and commands executed by the control unit 820. The communication unit 810 may include a radio frequency transmitter/receiver, an infrared port, a USB connection, or other interface. For example, the communication unit 160 may include a short-range communication module for transmitting and receiving signals according to a communication standard such as Wi-Fi or Bluetooth.

The storage unit 811 may store data received from the management server (100 in FIG. 1 or 2). The storage unit 811 may be a non-volatile memory. For example, the storage unit 811 may be a flash memory.

The transceiver 812 may transmit data stored in the storage 811 to the controller 820 .

The controller 820 may control the home appliance to perform a specific function by storing a program for implementing functions of the home appliance and executing a predetermined function by executing the stored program. Also, the controller 820 may update a stored program based on data received from the communication unit 810 .

The processing unit 821 may include a central processing unit (CPU), a graphic processing unit (GPU), a microprocessor, an application specific integrated circuit (ASIC), field programmable gate arrays (FPGA), and the like, and may include a plurality of can have a core.

The first storage unit 822 may be a non-volatile memory. For example, the first storage unit 822 may be a flash memory. The first storage unit 822 may store the program.

The second storage unit 823 may be a volatile memory. For example, the second storage unit 823 may be RAM. The second storage unit 823 may load some of the program data stored in the first storage unit 822, and program data stored in the second storage unit 823 may be stored in a specific area of the first storage unit 822. can be lighted

The third storage unit 830 may be a non-volatile memory. The third storage unit may be one of flash memory, magnetic storage, and optical storage. Programs for performing functions of the home appliance may be stored in the third storage unit 830 .

6 is a block diagram schematically illustrating a home appliance in which a plurality of devices are separately installed among upgradable electronic devices according to an embodiment of the present invention. As described above, the 1-1 home appliance 410, the 1-2 home appliance 420, and the 1-3 home appliance 430 are indoor units of an air conditioner, and the 1-4 home appliance ( 440) may be an outdoor unit of an air conditioner. In addition, as described in FIG. 2, the 1-1 home appliance 410 and the 1-2 home appliance 420 can access the management server 100 through the access point 300 and/or the Internet network. there is.

The 1-1 home appliance 410 may include a first communication unit 411, a main control unit 412, and a second communication unit 413. Depending on the embodiment, the 1-1 home appliance 410 may further include at least one of a display module 414, a voice guidance module 415, and a sensor unit 416.

The first communication unit 411 may receive data from the management server (100 in FIGS. 1 and 2 ) and transmit the received data to the main control unit 412 . The first communication unit 411 may have the same configuration as the first communication unit 810 of FIG. 4 and may perform the same functions.

The main controller 412 may receive data from the first communication unit 411 and transmit the received data to the second communication unit 413 . When the data received from the first communication unit 411 is data used in the display module 414 and/or voice guidance module 415, the main control unit 412 transmits the data to the display module 414 and/or voice guidance module 415. You can also send to module 415. The main controller 412 may have the same configuration as the controller 820 of FIG. 4 and perform the same functions.

The second communication unit 413 may transmit/receive data with at least one of the 1-2nd home appliance 420, the 1-3rd home appliance 430, and the 1-4th home appliance 440. The second communication unit 413 may transmit and receive data in an asynchronous serial communication method. By using the asynchronous serial communication method, the hardware of the home appliance can be implemented more simply. In addition, the second communication unit 413 may transmit and receive data at a rate of 4800 bps to 4 Mbps. Preferably, the second communication unit 413 may transmit and receive data at a speed of 9600 bps. As described above, the 1-1 home appliance 410 may be an indoor unit of an air conditioner, and the 1-4 home appliance 440 may be an outdoor unit of an air conditioner. Considering the distance between the indoor unit of the air conditioner and the outdoor unit of the air conditioner and the surrounding environment in a general installation environment, communication reliability can be secured and the transmission speed can be increased at the same time by having the communication speed. For example, the second communication unit 413 may include a universal asynchronous receiver/transmitter (UART), and may transmit and receive data in an RS485 communication method. The second communication unit 413 may include a buffer capable of temporarily storing data.

The display module 414 may visually display various information for user's convenience. For example, the display module 414 may display at least one of information related to the operation of the home appliance, information related to the state of the home appliance, and other living information. The display module 414 may operate under the control of the main controller 412 or may include a separate display controller. Predetermined data may be transmitted from the management server to drive the display module 414 . The display module 414 may receive the data through the main controller 412 .

The voice guidance module 415 may indicate various information by sound for user's convenience. Similar to the display module 414, the voice guidance module 415 may also display at least one or more of information related to the operation of the home appliance, information related to the state of the home appliance, and other life information through sound. The voice guidance module 415 may operate under the control of the main controller 412 or may include a separate voice controller. Predetermined data may be transmitted from the management server to drive the voice guidance module 415 . The voice guidance module 415 may receive the data through the main controller 412 .

The sensor unit 416 may obtain information related to the operation of the home appliance. For example, when the home appliance is an air conditioner, the sensor unit 416 measures at least one of the room temperature, the temperature of air discharged from the air conditioner, the room humidity, and the temperature and/or pressure of the circulating refrigerant. can detect The sensor unit 416 may include one or more sensors.

The 1-2 home appliance 420 may have substantially the same configuration as the 1-1 home appliance 410 . That is, each of the first communication unit 421, the main control unit 422, the second communication unit 423, the display module 424, the voice guidance module 425, and the sensor unit 426 is the first communication unit 411, Each of the main control unit 412, the second communication unit 413, the display module 414, the voice guidance module 415, and the sensor unit 416 may be substantially the same.

The 1-3 home appliance 430 may be substantially the same as the 1-1 home appliance, except that it does not include a first communication unit. That is, the main control unit 432, the second communication unit 433, the display module 434, the voice guidance module 435, and the sensor unit 436 are respectively the main control unit 412, the second communication unit 413, and the display module. 414, the voice guidance module 415, and the sensor unit 416 may be substantially the same as each other.

Each of the main control unit 442 and the second communication unit 443 of the 1-4th home appliance 440 is substantially compatible with each of the main control unit 412 and the second communication unit 413 of the 1-1 home appliance 410. can be the same As described above, the 1-4th home appliance 440 may be an outdoor unit of an air conditioner. In this case, the 1-4 home appliances 440 may further include a compressor 444 and a fan 445. The main controller 442 may control the compressor 444 and/or the fan 445 by using a program included in the data received from the 1-1 home appliance 410 . Home appliances 1-4 440 may also include a sensor unit 446 that obtains information related to the operation of the home appliance. When the 1-4 home appliance 440 is an outdoor unit of an air conditioner, the sensor unit 446 may sense at least one of pressure or temperature of the refrigerant, outdoor temperature, and outdoor humidity. The sensor unit 446 may include one or more sensors.

2 and 6 illustrate an air conditioner connected to one outdoor unit and three indoor units as an example of an electronic device to be upgraded, The number of indoor units can be adjusted as needed. For example, in the case of an air conditioner applied to a large building, dozens or more indoor units may be connected to one outdoor unit.

7 is a diagram for explaining an overall operation of a method of upgrading a home appliance according to an embodiment of the present invention. The method shown in FIG. 7 can be applied when upgrading according to the above-described general upgrade method or delta upgrade method.

First, the first communication unit 810 may request information (product information) on the home appliance from the control unit 820 (step S101). Product information may be identification information of a home appliance. Identification information of the home appliance may include at least one of a serial number and a model name of the home appliance. In step S101, the management server 100 requests information about the home appliance from the first communication unit 810, and in response to this, the first communication unit 810 may request information about the home appliance from the controller 820. .

Next, in response to the product information request, the controller 820 may return information about the home appliance (eg, identification information of the home appliance) to the first communication unit 810 (step S102).

Next, the first communication unit 810 may request information about whether the home appliance has details to be upgraded from the management server 100 (step S103). At this time, the communication unit 810 may transmit information about the home appliance (identification information of the home appliance) to the management server 100 . Also, the communication unit 810 may additionally transmit user information to the management server 100 . The communication unit 810 may transmit and receive data through a relay when transmitting and receiving data with the management server 100 . The repeater may be the access point of FIG. 2 .

Next, the management server 100 may return upgrade information to the first communication unit 810 (step S104). The upgrade information may include at least one of information on whether or not there is a detail to be upgraded for the home appliance identified based on the information on the home appliance and information on items or contents to be upgraded. To this end, the management server 100 may determine whether to upgrade the home appliance. Also, the management server 100 may determine an upgrade method. For example, the management server 100 may determine an item to be upgraded and determine an upgrade method accordingly. The upgrade scheme may include full upgrade, differential upgrade, and background upgrade.

Also, the management server 100 may provide the upgrade information to the user terminal 700 (step S105). The management server 100 may search information on a user of the home appliance using information stored in the storage unit ( 130 in FIG. 3 ) or may receive user information from the first communication unit 810 .

Next, when the user accepts the upgrade using the user terminal 700, information about the upgrade acceptance may be transmitted from the user terminal 700 to the management server 100 (step S106).

Instead of accepting the upgrade using the user terminal 700, the user may accept the upgrade using the input/output device of the home appliance.

In response to the user's acceptance of the upgrade, the management server 100 may request the start of the upgrade to the first communication unit 810 (step S107). In this step, the management server 100 may determine an upgrade method. The decision on the upgrade method will be easily understood by referring to the description of step S104.

The first communication unit 810 may request file transmission in response to the upgrade start request of the management server 100 (step S108).

The management server 100 may transmit a file including data for upgrading the home appliance to the first communication unit 810 in response to the file transmission request of the first communication unit 810 (step S109). Data for upgrade may include at least one or more of program data, delta data, and/or instruction set of the latest version.

The first communication unit 810 and the control unit 820 may update the program of the home appliance using the file received from the management server 100 (step S110).

When the upgrade is completed, the first communication unit 810 may return upgrade completion to the management server 100 (step S111).

The management server 100 may provide upgrade completion-related information to the user terminal in response to the upgrade completion reply received from the first communication unit 810 (step S112).

As described above, the controller 820 of FIG. 7 may be the main controller 412 of FIG. 6 , and the first communication unit 810 of FIG. 7 may be the first communication unit 411 of FIG. 6 .

8 is a diagram for explaining an overall operation of a method of upgrading a home appliance according to an embodiment of the present invention. The method shown in FIG. 8 can be applied when upgrading according to the above-described general upgrade method or delta upgrade method.

First, the management server 100 may request information on the 1-3 home appliance 430 from the first communication unit 411 of the 1-1 home appliance 410 (step S121). Similar to that described in FIG. 6, the information on the 1-3 home appliance 430 may be identification information of the 1-3 home appliance 430, and the identification information of the 1-3 home appliance 430 is It may include any one or more of a serial number and a model name of the 1-3 home appliance 430 .

The product information request transmitted from the management server 100 to the first communication unit 411 is then sent to the main control unit 412 of the 1-1 home appliance 410 and the second communication unit of the 1-1 home appliance 410. 413, and the second communication unit 433 of the 1-3 home appliance 430 may be transmitted to the main control unit 432 of the 1-3 home appliance 430 (steps S122 to S125) .

In response to the product information request, the main control unit 432 of the 1-3 home appliance 430 transmits information on the 1-3 home appliance (eg, identification information of the 1-3 home appliance) to the first-third home appliance. -3 The second communication unit 433 of the home appliance 430, the second communication unit 413 of the 1-1 home appliance 410, the main control unit 412 of the 1-1 home appliance 410, and the th 1-1 A response may be made to the management server 100 through the first communication unit 411 of the home appliance 410 (steps S126 to S130).

Next, the management server 100 may return the upgrade information described above. More specifically, the management server 100 includes the first communication unit 411 of the 1-1 home appliance 410, the main controller 412 of the 1-1 home appliance 410, and the 1-1 home appliance ( The upgrade information described above is sent to the main control unit 432 of the 1-3 home appliance 430 through the second communication unit 413 of 410 and the second communication unit 433 of the 1-3 home appliance 430. It can be provided (steps S133 to S137). In addition, the management server 100 may provide the above-described upgrade information to the user terminal 700 (step S132). The management server 100 may retrieve information about a user of the home appliance using information stored in the storage unit ( 130 in FIG. 3 ) or may receive user information from the first communication unit 411 .

Next, the management server 100 may receive acceptance of the upgrade. More specifically, the management server 100 includes the second communication unit 433 of the 1-3 home appliance 430, the second communication unit 413 of the 1-1 home appliance 410, and the 1-1 home appliance Acceptance of the upgrade is received from the main controller 432 of the 1-3 home appliance 430 through the main controller 412 of 410 and the first communication unit 411 of the 1-1 home appliance 410. can receive For example, the 1-3 home appliance 430 may display upgrade information through a display unit (eg, a display panel or LED), and through an input unit (touch pad, switch, remote control, etc.) A user's input may be received, and in response to this, acceptance of the upgrade may be transmitted to the management server 100 . Alternatively, when the user accepts the upgrade using the user terminal 700, information on the upgrade acceptance may be transmitted from the user terminal 700 to the management server 100 (step S143).

Next, the management server 100 may determine an upgrade method (step S144). For example, the management server 100 may determine an item to be upgraded and determine an upgrade method accordingly. Upgrade schemes may include regular upgrades, delta upgrades, and automatic upgrades.

Next, in response to the user's acceptance of the upgrade, the management server 100 may request the start of the upgrade to the first communication unit 411 (step S145).

The first communication unit 411 may request file transmission in response to the upgrade start request of the management server 100 (step S146).

The management server 100 may transmit a file including data for upgrading the home appliance to the first communication unit 411 in response to the file transmission request of the first communication unit 411 (step S147). Data for upgrade may include at least one or more of program data, delta data, and/or instruction set of the latest version.

The first communication unit 411 of the 1-1 home appliance 410, the main control unit 412 of the 1-1 home appliance 410, the second communication unit 413 of the 1-1 home appliance 410, At least one of the second communication unit 433 of the 1-3 home appliance 430 and the main controller 432 of the 1-3 home appliance 430 may upgrade the home appliance using the received file. Yes (step S148). The process of upgrading the home appliance may include at least one of a process of transmitting data and a process of replacing data stored in the home appliance with data of a received file.

In step S148, the first communication unit 411 may transmit upgrade data when the home appliance does not perform its own operation. Alternatively, according to an embodiment, the first communication unit 411 may transmit upgrade data after temporarily stopping a specific operation of the home appliance.

When the upgrade is completed, the first communication unit 411 may return upgrade completion to the management server 100 (step S149).

The management server 100 may provide upgrade completion-related information to the user terminal 700 in response to the upgrade completion reply received from the first communication unit 411 (step S150).

9 is a diagram for explaining an overall operation of a method of upgrading a home appliance according to an embodiment of the present invention. The method shown in FIG. 9 can be applied when upgrading according to the above-described automatic upgrade method.

In FIG. 9 , processes indicated by the same reference numerals as in FIG. 8 are the same as those described in FIG. 8 . That is, the embodiment shown in FIG. 9 may be the same as that described in FIG. 8 except that data for upgrading the home appliance is transmitted to the 1-1 home appliance 410 before receiving acceptance of the upgrade from the user. there is.

More specifically, when the management server 100 receives information about the home appliance from the 1-3 home appliance 430, the management server 100 may determine whether or not to upgrade and an upgrade method (step S131-1). ). Step S131-1 may be the same as steps S131 and S144 of FIG. 7 .

Thereafter, the management server 100 requests the first communication unit 411 to start upgrading (step S131-2), and the first communication unit 411 transmits a file in response to the upgrade start request of the management server 100. (step S131-3), and the management server 100 transmits a file including data for upgrading the home appliance to the first communication unit 411 in response to the file transmission request of the first communication unit 411. It can be done (step S131-4). Steps S131-2 to S131-4 may be the same as steps S145 to S147 of FIG. 7 .

Thereafter, the management server 100 may transmit an upgrade execution request to the first communication unit 411 in response to the user's acceptance of the upgrade, and in response to the upgrade execution request of the management server 100, the 1-1 home appliance The first communication unit 411 of 410, the main control unit 412 of the 1-1 home appliance 410, the second communication unit 413 of the 1-1 home appliance 410, and the 1-3 home appliance At least one of the second communication unit 433 of 430 and the main controller 432 of the 1-3 home appliances 430 may upgrade the home appliance using the received file (step S148).

9 illustrates a case in which upgrade data is transmitted to the 1-1 home appliance 410 before receiving acceptance of the upgrade from the user, but upgrade data is transmitted to the 1-3 home appliance 430 before receiving the upgrade acceptance from the user. can also be sent to

10 is a diagram for explaining an overall operation of a method of upgrading an electronic device according to an embodiment of the present invention. The method shown in FIG. 10 can be applied when upgrading according to the above-described automatic upgrade method.

First, the management server 100 may request product information from the first communication unit 411 of the 1-1 home appliance 410 (step S161).

The first communication unit 411 may transmit the product information request received from the management server 100 to the main control unit 412 (step S162).

The main controller 412 may transmit product information to the first communication unit 411 in response to the product information request (step S163).

The first communication unit 411 may transmit the product information received from the main control unit 412 to the management server 100 (step S164).

Next, the management server 100 may determine whether or not to upgrade and how to upgrade (step S165).

Next, the management server 100 may request the start of the upgrade to the first communication unit 411 (step S166).

The first communication unit 411 may request file transmission to the management server 100 in response to the upgrade start request (step S167).

The management server 100 may transmit a file including upgrade data to the first communication unit 411 in response to the file transfer request of the first communication unit 411 (step S168).

The file transmitted to the first communication unit 411 may be transmitted to the display module 414 through the main control unit 412 (steps S169 and S170).

When the file reception is completed, the display module 414 may transmit a file reception completion message to the main control unit 412 (step S171).

The reception completion message received by the main control unit 412 may be transmitted to the management server 100 through the first communication unit 411 (steps S172 and S173).

Next, the management server 100 may provide upgrade information. More specifically, the management server 100 is the 1-1 home appliance through the first communication unit 411 of the 1-1 home appliance 410 and the main control unit 412 of the 1-1 home appliance 410. The above-described upgrade information may be provided to the display module 414 in step 410 (steps S175 to S177). In addition, the management server 100 may provide the above-described upgrade information to the user terminal 700 (step S174). The management server 100 may retrieve information about a user of the home appliance using information stored in the storage unit ( 130 in FIG. 3 ) or may receive user information from the first communication unit 411 .

Next, the management server 100 may receive acceptance of the upgrade. More specifically, the management server 100 is the 1-1 home appliance through the main controller 412 of the 1-1 home appliance 410 and the first communication unit 411 of the 1-1 home appliance 410. Acceptance of the upgrade may be received from the display module 414 of the device 410 (steps S178 to S180). Alternatively, when the user accepts the upgrade using the user terminal 700, information about the upgrade acceptance may be transmitted from the user terminal 700 to the management server 100 (step S181).

Next, in response to the user's acceptance of the upgrade, the management server 100 may request the first communication unit 411 to perform the upgrade (step S182).

The upgrade execution request received from the management server 100 may be transmitted to the display module 414 through the main control unit 412 (steps S183 and S184).

Next, the display module 414 may perform an upgrade operation in response to the upgrade request (step S185).

When the upgrade is completed, the display module 414 may return upgrade completion to the management server 100 through the main control unit 412 and the first communication unit 411 (steps S186 to S188).

The management server 100 may provide upgrade completion-related information to the user terminal 700 in response to the upgrade completion reply received from the first communication unit 411 (step S189).

10 illustrates the case of upgrading the display module 414 of the 1-1 home appliance 410, the voice guidance module 415 can be similarly upgraded. Also, according to embodiments, a method similar to that of FIG. 10 may be applied even when the function of the main control unit 412 is upgraded.

In addition, the display module or voice guidance module of the 1-2 home appliance 420 or the 1-3 home appliance 430 can be similarly upgraded.

Furthermore, although not shown, a method similar to that of FIG. 10 may be applied even when a specific function module of a home appliance is upgraded.

In addition, although FIGS. 7 to 10 illustrate that the main control unit provides product information, the first communication unit may also provide product information.

11 is an operation flowchart for explaining one of the upgrading methods of a home appliance according to an embodiment of the present invention. The upgrade method shown in FIG. 11 may be the above-described automatic upgrade method.

Before performing the upgrade method of a home appliance according to an embodiment of the present invention shown in FIG. 11, the home appliance 800 and the management server 100 may be connected to enable mutual communication, and upgrade related information may be sent to the management server ( It can be stored in the storage unit 130 of 100), and an upgrade schedule including an upgrade cycle, an upgrade reservation, and the like can be set. In addition, the upgrade schedule may include a notification schedule for notifying the user after the upgrade so that he/she can be aware of it.

In addition, before performing the method of upgrading a home appliance according to an embodiment of the present invention shown in FIG. 11, a program file and/or data file (upgrade file) for upgrading the home appliance 800 is stored in the management server 100. can be registered in When an administrator uploads an upgrade file to the management server 100 , the upgrade file may be stored in the storage unit 130 . When uploading an upgrade file to the management server 100, the administrator may set whether to enable automatic download, which will be described later.

In addition, the management server 100 and the home appliance 800 communicate with each other so that the version of the installation file installed in the home appliance 800 and the version of the upgrade file registered in the management server 100 are different, so that the home appliance 800 The management server and/or the home appliance 800 may recognize that upgrade is required.

The upgrade file registered in the management server 100 can upgrade only one target of a plurality of home appliances (410, 420, 430, 440, 500, 600), or a plurality of home appliances (410, 420, 430, 440). , 500, 600) of a plurality of objects, for example, all of the 1-1 home appliance 410, the 1-2 home appliance 420, and the 1-3 home appliance 430 that are indoor units of an air conditioner. can be upgraded Accordingly, a home appliance 800 upgraded below means one or more home appliances 800 to which an upgrade file can be applied among a plurality of home appliances 410 , 420 , 430 , 440 , 500 , and 600 .

Referring to FIG. 11 , the management server 100 may determine whether an automatic download of an upgrade file is possible (step S21). The control unit 110 of the management server 100 may check whether the upgrade file stored in the storage unit 130 is subject to automatic download that is transmitted without the consent of the user.

The control unit 110 of the management server 100 may determine whether automatic download is possible with information set by an administrator when registering an upgrade file. The control unit 110 of the management server 100 may determine that the upgrade file stored in the storage unit 130 is automatically downloaded if the setting is automatic download, and if the setting is normal download, it is determined that automatic download is not possible. can do. It is recommended that the administrator set it to automatic download when the capacity of the upgrade file is large.

The control unit 110 of the management server 100 may determine whether automatic download is possible based on the capacity of the upgrade file (ie, upgrade data). The control unit 110 of the management server 100 may determine an automatic download if the capacity of the upgrade file is greater than or equal to 1 MB, and may determine a normal download if the capacity of the upgrade file is less than 1 MB.

The control unit 110 of the management server 100 may determine whether automatic download is possible in the form of an upgrade file. The control unit 110 of the management server 100 may determine that automatic download is possible when the upgrade file is a data file that does not include an execution command. For example, the management server 100 may determine that automatic download is possible when the upgrade file is an audio or image data file. The management server 100 may determine that a program file including an execution command is a general download. When it is determined that the download method is an automatic download, the management server 100 may determine the above-described automatic upgrade method as the upgrade method. When the download method is determined to be a normal download, the management server 100 may select the above-described normal upgrade method or delta upgrade method as the upgrade method.

Automatic download may refer to file transmission by the method shown in FIG. 7 by performing steps S22 to S26 below.

Normal download may refer to file transmission by the method shown in FIG. 6 by performing steps S27 to S29 and S26 below.

If automatic download is possible, the management server 100 and the home appliance 800 may initiate download (step S22). When the control unit 110 of the management server 100 determines that the upgrade file is automatically downloaded, the upgrade file may be transmitted through the communication unit 120 . The first communication unit 810 of the home appliance 800 receives the upgrade file, and the first storage unit 822, the second storage unit 823, or the third storage unit 830 of the home appliance 800 You can save the received upgrade file. Depending on the embodiment, in step S22, the upgrade file may be transmitted to the function module of the home appliance. For example, the upgrade file may be transmitted to the display module or voice guidance module of the 1-1 home appliance 410, 1-2 home appliance 420, and 1-3 home appliance 430 of FIG. 6. there is.

The management server 100 or the home appliance 800 may determine whether a problem occurs in downloading the upgrade file (step S23). The upgrade file is a large-capacity file and takes a relatively long time to download, and thus, a problem may occur due to frequent power on/off of the home appliance 800. In addition, the storage capacity of the storage units 822, 823, and 830 in which the upgrade file is stored may be insufficient because the capacity of the upgrade file is very large. In the case of such a problem, a normal download in which the user recognizes that a file is being downloaded and waits without turning off the power of the home appliance 800 may be better, so step S27 may be performed when a download problem occurs.

The home appliance 800 may notify the management server 100 that the download has been completed when the upgrade file reception is complete (step S24). The controller 820 of the home appliance 800 checks the checksum of the upgrade file stored in the storage units 822, 823, and 830, confirms that the download has been completed, and sends a download completion message to the management server 100 through the communication unit 810. can be sent

The management server 100 may confirm the user's consent to the upgrade of the home appliance 800 by the upgrade file (step S25). The management server 100 may check whether the user agrees to the upgrade through the user terminal 700 or the home appliance 800 . If an upgrade consent is not input to the user terminal 700 or the home appliance 800, the home appliance 800 may not be upgraded. The upgrade agreement through the user terminal 700 will be described in detail with reference to FIGS. 21 and 22 .

When the user terminal 700 or the home appliance 800 agrees to upgrade, the user terminal 700 or the home appliance 800 transmits that the upgrade agreement has been entered to the management server 100, and the management server 100 upgrades The home appliance 800 may be requested to perform.

The home appliance 800 may perform an upgrade in response to a request from the management server 100 (step S26). The controller 820 of the home appliance 800 may update programs or data stored in the storage units 822 , 823 , and 830 by installing upgrade files stored in the storage units 822 , 823 , and 830 . When the upgrade file stored in the storage units 822, 823, and 830 is a data file, the control unit 820 of the home appliance 800 may change and install only the memory address. The controller 820 of the home appliance 800 changes and stores the version of the installation file to the version of the upgrade file in the storage units 822, 823, and 830, and stores the version information in the management server 100 through the communication unit 810. Can transmit device information including.

If automatic download is not possible or a problem occurs in the download, the management server 100 may confirm the user's consent to the download of the upgrade file and the upgrade of the home appliance 800 (S27). If automatic download is not possible or if there is a problem with the download, a normal download is performed. Since step S27 is performed in the same way as step S25, a description thereof is omitted. Since steps S27 and S25 are the same, the user cannot recognize whether the upgrade file has already been downloaded or whether it is downloaded after consent.

If the upgrade agreement is not entered into the user terminal 700 or the home appliance 800, the upgrade file is not downloaded and the home appliance 800 is not upgraded.

When the user terminal 700 or the home appliance 800 agrees to upgrade, the user terminal 700 or the home appliance 800 transmits that the upgrade agreement is entered to the management server 100, and the management server 100 and the home appliance The device 800 may start downloading (step S28). Since step S28 is performed substantially the same as step S24, a description thereof is omitted.

When the home appliance 800 completes receiving the upgrade file, it may inform the management server 100 that the download is complete (step S29). Since step S29 is performed substantially the same as step S24, a description thereof is omitted.

When the download is complete, the home appliance 800 may perform an upgrade (step S26).

12 to 16 are views explaining a method of upgrading a home appliance according to the delta upgrade method described above.

12 is a diagram for explaining a process of updating program data in a method of upgrading a home appliance according to an embodiment of the present invention. In FIG. 12, 840 represents a non-volatile memory of a home appliance, and 850 represents a volatile memory of a home appliance, respectively. For example, 840 of FIG. 12 may be the same as the first storage unit 822 of FIG. 4 , and 850 of FIG. 12 may be the same as the second storage unit 823 of FIG. 4 . Delta data is data transmitted from the management server 100 and represents data of a changed part of program data.

According to one embodiment of the present invention, the management server 100 transmits delta data, which is data of a changed part of program data, a location where the delta data is to be written, and a command for writing the delta data in a predetermined location, to the home appliance.

Also, according to one embodiment of the present invention, a program for implementing functions of a home appliance may be divided into a plurality of sections and stored. Here, a section may mean one area of the storage unit.

As shown in FIG. 12, it is assumed that a program is divided into three sections and stored, and a new program file is one in which sections of sections 2 and 3 are modified.

Hereinafter, each operation may be performed by a controller of the home appliance (820 in FIG. 4 (more specifically, the processing unit 821 of the home appliance)).

First, data stored in section 2 of the non-volatile memory 840 may be read, and the read data may be written to the volatile memory 850 . Next, some of the program data written in the volatile memory 850 may be replaced with delta data received from the management server 100 . Next, a delete operation for section 2 of the non-volatile memory 840 is performed, and the modified program data 841 may be written to section 2 of the non-volatile memory 840 .

Similarly, data stored in section 3 of the non-volatile memory 840 may be read, and the read data may be written to the volatile memory 850 . Next, some of the program data written in the volatile memory 850 may be replaced with delta data received from the management server 100 . Thereafter, a deletion operation for section 3 of the nonvolatile memory 840 is performed, and the modified program data 842 may be written to section 3 of the nonvolatile memory 840 .

13 is a diagram for explaining a process of generating and transmitting delta data in a method of upgrading a home appliance according to an embodiment of the present invention. In FIG. 13, identification number 900 represents a terminal of a program developer. 13, it is assumed that PGM #1 represents a version 1 program, PGM #2 represents a version 2 program, PGM #3 represents a version 3 program, and the version 3 program is the latest version program. do.

When a program developer develops a new program, the developed program is transmitted to the management server 100 . At this time, identification information of the home appliance on which the corresponding program will be executed may also be transmitted to the management server 100 . The transmitted program may be stored in the storage unit ( 130 in FIG. 3 ) of the management server 100 .

The management server 100 (more specifically, the control unit (110 in FIG. 3) of the management server) may generate delta data based on the stored programs. That is, the management server 100 compares the version 3 program (PGM #3) with the version 1 program (PGM #1) to generate first delta data (Delta #1), and the version 3 program (PGM #1). 3) and the version 2 program (PGM #2) may be compared to generate second delta data (Delta #2).

Thereafter, the management server 100 may transmit first delta data (Delta #1) to the home appliance 801 in order to upgrade the home appliance 801 in which the current version 1 program (PGM #1) is stored. In order to upgrade the home appliance 802 in which the version 2 program (PGM #2) is stored, the second delta data Delta #2 may be transmitted to the home appliance 802 .

14 is a diagram schematically illustrating an example of existing program data (a) and new program data (b) in a method of upgrading a home appliance according to an embodiment of the present invention. In FIG. 14 , the hatched portion indicates the changed portion.

As shown in FIG. 14(a), existing program data includes A block stored in section 841, B block stored in section 842, C block stored in section 844, and D block stored in section 845. may contain blocks. As shown in FIG. 14(b), the new program data may include block A' stored in section 841, block B stored in section 842, and block D' stored in section 844.

The management server 100 (more specifically, the control unit (110 in FIG. 4) of the management server 100) compares the existing program data (FIG. 14(a)) with the new program data (FIG. 14(b)) Delta data can be generated.

Specifically, the management server 100 converts data most similar to the data (block A′) of the first section 841 of the new program data (FIG. 14(b)) from the existing program data (FIG. 14(a)). Search. During the search, the management server 100 may sequentially scan areas of the storage unit in which existing program data is stored. At this time, instead of scanning per section, scanning may be performed while sequentially increasing addresses. After determining that the data (block A) of the first section (841 in FIG. 14(a)) is the most similar data, the management server 100 determines that the data of the difference part (the shaded area in 841 in FIG. 14(b)) data) may be determined as the first configuration of delta data.

Next, the management server 100 searches the existing program data (FIG. 14 (a)) for data most similar to the data (block B) of the second section 842 of the new program data (FIG. 14 (b)). do. The management server 100 may determine that the data (block B) of the second section (842 in FIG. 14(a)) is the same data.

Next, the management server 100 converts data most similar to the data (D′ block) of the fourth section 844 of the new program data (FIG. 14 (b)) from the existing program data (FIG. 14 (a)). Search. After determining that the data (block D) of the fifth section (845 in FIG. 14(a)) is the most similar data, the management server 100 determines that the data of the difference part (the shaded area in 844 in FIG. 14(b)) Data of) can be determined as the second configuration of delta data.

Through this process, the management server 100 replaces some of the data of the first section 841 with the first configuration of delta data in the existing program data (FIG. 14 (a)), and the fifth section ( After replacing some of the data of 845) with the second configuration of delta data, and then moving the data of the fifth section 845 to the fourth section, it can be seen that it becomes the same as the new program data (FIG. 14(b)). there is.

14 describes the case where data similar to data of one section of new program data is stored in one section of existing program data as an example, but data similar to data of one section of new program data is stored in one section of existing program data. It may also occur that the program data of is divided into two sections and stored. Even in this case, delta data may be generated in the same manner as described above.

15 is a diagram for explaining a process of updating program data in a method of upgrading a home appliance according to an embodiment of the present invention.

The method shown in FIG. 15 may be performed by the controller 820 (more specifically, the processing unit 821) of the home appliance, and the command set and delta data for the controller 820 to perform these operations are managed. It may be transmitted from the server 100 to the home appliance.

First, FIG. 15(a) shows the program data before updating.

Next, referring to FIG. 15( b ) , data A of section 841 may be changed to data A′ and written to section 843 . A specific process is the same as that described in FIG. 14 . That is, delta data in which data A of section 841 is read and written in a specific area of a volatile memory (eg, RAM), and data of a part of the specific area of the volatile memory is received from the management server 100 , and the data A' recorded in a specific area of the volatile memory may be written to the section 843 of the non-volatile memory (eg, flash memory).

Next, referring to FIG. 15(c), data D of section 845 may be changed to data D′ and written to section 846. A specific process is the same as that described in FIG. 14 .

Next, referring to FIG. 15( d ), data A' of section 843 may be written to section 841 . In detail, the data of the section 841 is deleted, the data (A') of the section 843 is read and written to a specific area of the volatile memory, and the data (A') written to the specific area of the volatile memory can be recorded in section 841.

Next, referring to FIG. 15(e), data D′ of section 846 may be written to section 844. A specific process is similar to that described in FIG. 15(d).

Next, referring to FIG. 15(f), unnecessary sections may be deleted. That is, data of sections 843, 845, and 846 may be deleted.

By going through this process, even if the update process is interrupted due to a power outage or the like while updating the program data, the home appliance itself can be restored.

16 is a diagram for explaining a process of updating program data in a method of upgrading a home appliance according to an embodiment of the present invention.

The method shown in FIG. 16 may be performed by the controller 820 (more specifically, the processing unit 821) of the home appliance, and the command set and delta data for the controller 820 to perform these operations are managed. It may be transmitted from the server 100 to the home appliance.

The embodiment shown in FIG. 16 is a case where the capacity of the non-volatile memory (eg, flash memory) is sufficiently large. For example, this is a case where the capacity of the first storage unit 822 shown in FIG. 5 is designed to be double the conventional capacity, or the home appliance includes a third storage unit (830 in FIG. 5). That is, 850 of FIG. 16 may be the first storage unit 822 shown in FIG. 5 , and 860 of FIG. 16 may be the third storage unit 830 shown in FIG. 5 .

First, FIG. 16(a) shows the program data before updating.

Next, referring to FIG. 16 ( b ) , data A, B, C, and D of the storage unit 850 may be copied to the storage unit 860 . Specifically, data of each section 851, 852, 853, 854 of the storage unit 850 is sequentially read and written to a specific area of the volatile memory, and then the data of the specific area of the volatile memory is stored in the storage unit 860. It can be recorded in each section (861, 862, 863, 864).

Next, referring to FIG. 16(c), the data A of the storage unit (section 851) may be changed to data A'. The specific process is the same as that described in FIG. 14. That is, the section ( 851) reads data (A) and writes it in a specific area of volatile memory (eg, RAM), and modifies data in some of the specific areas of volatile memory with delta data received from the management server 100 to obtain data (A'), data (A') recorded in a specific area of the volatile memory may be written to the section 851 of the non-volatile memory (eg, flash memory).

Next, referring to FIG. 16(d), data D of section 854 may be changed to data D'. A detailed process may be similar to that described in FIG. 16(c).

Next, referring to FIG. 16(e), data recorded in the storage unit 860 may be deleted.

According to the embodiment shown in FIG. 16, a previous program may be backed up before updating the program. Therefore, even if the update is interrupted due to a power failure or the like during the program update process, it can be restored without error.

17 is a diagram for explaining a process of updating program data in a method of upgrading a home appliance according to an embodiment of the present invention. The step shown in FIG. 17 may be performed in step S110 of FIG. 7 , step S148 of FIGS. 8 and 9 , step S185 of FIG. 10 , or step S26 of FIG. 11 .

First, the communication unit 810 may notify the control unit 820 that a process of updating program data starts (step S201).

Next, the communication unit 810 may transmit information on the history page to the control unit 820 (step S202). Information on the history page may be a specific address of a non-volatile memory included in the home appliance. Information on the number of commands executed by the control unit 820 in updating program data may be recorded in the specific address.

Next, the controller 820 can read the history page (step S203). As described above, information on the number of previously executed commands may be recorded in the history page.

Next, the control unit 820 may transmit a confirmation signal (ack) to the communication unit 810 (step S204).

The communication unit 810 may transmit a command and/or delta data to the controller 820 in response to the confirmation signal ack (step S205). In step S205, the communication unit 810 may sequentially transmit commands and/or delta data stored in the storage unit 811 in response to the confirmation signal (ack). A command transmitted by the communication unit 810 may include a serial number.

The controller 820 may determine whether a count value indicating the number of commands received after the program update starts is greater than a value stored in the history page (S206). The number of commands received may be a serial number included in commands transmitted by the communication unit 810 . If the serial number is not included in the command transmitted by the communication unit 810, the controller 820 may count it every time a command is received from when the program update starts.

As a result of the determination in step S206, if the count value is not greater than the value stored in the history page, the controller 820 may transmit a confirmation signal (ack) to the communication unit 810 without executing the corresponding command (step S207).

As a result of the determination in step S206, if the count value is greater than the value stored in the history page, the controller 820 may execute the corresponding command (step S208). At this time, the controller 820 may store the count value in the history page (step S208). The operation of storing the count value in the history page may be performed according to the type of the executed command. For example, a count value may be stored in a history page only when an operation of changing data of a non-volatile memory (eg, flash memory) is performed. Depending on an embodiment, the count value may be stored in the history page only when an operation of deleting data in a non-volatile memory (eg, flash memory) is performed.

Next, the control unit 820 may transmit a confirmation signal (ack) to the communication unit 810 (step S209).

By performing the above-described process, even when the update operation is stopped due to a power failure or other errors in the middle of updating the program data, the update can be normally completed. That is, when the update operation is restarted after recording commands performed until the update operation is stopped, the update operation may be performed subsequent to the operations performed before the update operation is stopped. At this time, by recording the count value in the history page only when a command for changing data in the non-volatile memory is executed, the operation for the volatile memory can be performed again. However, in the case of a task of writing data to a non-volatile memory, data may not be normally written if the operation is stopped. Therefore, by recording the count value in the history page only when data in the non-volatile memory is deleted, the reliability of the operation can be further improved.

Next, the communication unit 810 may determine whether updating of program data is completed (step S210). The communication unit 810 may determine that updating of program data is completed when all instruction sets stored in the storage unit 811 are transmitted to the control unit 820 .

Next, the communication unit 810 transmits the checksum to the control unit 820 (step S211), and the control unit 820 may return a confirmation signal (ack) to the communication unit 810 if there is no error after confirmation. Yes (step S212). That is, it is possible to check whether there is an error in data transmission or the like. Unlike the drawing, it is also possible to check whether there is an error in data transmission in a method other than the checksum.

Next, the communication unit 810 may notify the control unit 820 of disconnection (step S213).

The control unit 820 may return a confirmation signal (ack) to the communication unit 810 (step S214), and the communication unit 810 may finally disconnect from the control unit 820.

18 is a diagram for explaining a method of transmitting upgrade data of a method of upgrading an electronic device according to an embodiment of the present invention, from a 1-1 home appliance 410 to a 1-3 home appliance 430 This is an example of the case where data is transmitted to .

A method of transmitting upgrade data of a method of upgrading an electronic device according to an embodiment of the present invention will be described with reference to FIGS. 6 and 18 .

In the first time interval T1 , the first communication unit 411 may transmit first unit data data_1 having a unit size to the main control unit 412 . Hereinafter, the unit size may be 256 bytes.

In the second time period T2, the first communication unit 411 may transmit second unit data (data_2) having a unit size to the main control unit 412, and the main control unit 412 may transmit the first unit data ( data_1) may be transmitted to the second communication unit 413. At this time, the main control unit 412 may receive the second unit data data_2 from the first communication unit 411 after transmitting the first unit data data_1 to the second communication unit 413 . If necessary, the main controller 412 may store at least a portion of the first unit data data_1 and the second unit data data_2 in the storage unit.

In the third time interval T3, the first communication unit 411 may transmit third unit data (data_3) having a unit size to the main control unit 412, and the main control unit 412 may transmit the second unit data ( data_2) may be transmitted to the second communication unit 413, and the second communication unit 413 may transmit first unit data data_1 to the second communication unit 433. At this time, the main control unit 412 may receive the third unit data data_3 from the main control unit 412 after transmitting the second unit data data_2 to the second communication unit 413 . Also, the second communication unit 413 may receive the second unit data data_2 from the main control unit 412 after transmitting the first unit data data_1 to the second communication unit 433 . If necessary, the main control unit 412 may store at least some of the second unit data data_2 and the third unit data data_3 in the storage unit, and the second communication unit 413 may store the first unit data data_1 And at least a part of the second unit data (data_2) may be stored in the buffer.

In the fourth time interval T4, the first communication unit 411 may transmit fourth unit data (data_4) having a unit size to the main controller 412, and the main controller 412 may transmit the third unit data ( data_3) to the second communication unit 413, the second communication unit 413 can transmit the second unit data data_2 to the second communication unit 433, and the second communication unit 433 can transmit the second unit data data_2 to the second communication unit 433. 1 unit data (data_1) may be transmitted to the main control unit 432 . In this case, the main controller 412 may receive the fourth unit data data_4 from the main controller 412 after transmitting the third unit data data_3 to the second communication unit 413 . Also, the second communication unit 413 may receive the third unit data data_3 from the main control unit 412 after transmitting the second unit data data_2 to the second communication unit 433 . Also, the second communication unit 433 may receive the second unit data data_2 from the second communication unit 413 after transmitting the first unit data data_1 to the main control unit 432 . If necessary, the main control unit 412 may store at least some of the third unit data data_3 and the fourth unit data data_4 in the storage unit, and the second communication unit 413 may store the second unit data data_2 and at least a portion of the third unit data data_3 may be stored in the buffer, and the second communication unit 433 may store at least a portion of the first unit data data_1 and the second unit data data_2 in the buffer.

That is, in the n-th time interval Tn, the first communication unit 411 may transmit n-th unit data data_n having a unit size to the main control unit 412, and the main control unit 412 may transmit the n-th unit data data_n. 1 unit data (data_n-1) may be transmitted to the second communication unit 413, and the second communication unit 413 may transmit n-2 th unit data (data_n-2) to the second communication unit 433. And, the second communication unit 433 may transmit the n−3 th unit data data_n−3 to the main controller 432 . At this time, the main control unit 412 may receive the n-th unit data data_n from the main control unit 412 after transmitting the n−1 th unit data data_n−1 to the second communication unit 413 . In addition, the second communication unit 413 transmits the n-2 th unit data data_n-2 to the second communication unit 433 and then transmits the n-1 th unit data data_n-1 from the main control unit 412. can receive In addition, the second communication unit 433 transmits the n-2th unit data data_n-2 from the second communication unit 413 after transmitting the n-3th unit data data_n-3 to the main controller 432. can receive If necessary, the main controller 412 may store at least some of the n−1 th unit data data_n−1 and the n th unit data data_n in the storage unit, and the second communication unit 413 may store the n−1 th unit data data_n−1. At least some of the 2 unit data (data_n-2) and the n-1 th unit data (data_n-1) may be stored in a buffer, and the second communication unit 433 may store the n-3 th unit data (data_n-3) and the th unit data (data_n-3). At least some of the n-2 unit data (data_n-2) may be stored in the buffer.

Here, n is the home appliance (ie, the 1-3 home appliances 430 in the embodiment of FIG. 7) before the receiving home appliance (ie, the embodiment of FIG. 7) transmits the acknowledgment signal (ack). It may be the number of times the 1-1 home appliance 410 transmits unit data (ie, the number of units of data transmitted before transmitting the acknowledgment signal ack).

In the n+1th time interval (Tn+1), the main controller 412 may transmit the nth unit data data_n to the second communication unit 413, and the second communication unit 413 may transmit the n−1th unit data data_n. The unit data data_n−1 may be transmitted to the second communication unit 433 , and the second communication unit 433 may transmit the n−2 th unit data data_n−2 to the main control unit 432 . At this time, the second communication unit 413 may receive the n-th unit data data_n from the main control unit 412 after transmitting the n−1 th unit data data_n−1 to the second communication unit 433. . In addition, the second communication unit 433 transmits the n-2 th unit data data_n-2 to the main control unit 432, and then transmits the n-1 th unit data data_n-1 from the second communication unit 413. can receive The second communication unit 413 may store at least some of the n-1th unit data data_n-1 and the n-th unit data data_n in a buffer, and the second communication unit 433 may store the n-2th unit data ( data_n-2) and at least some of the n-1th unit data (data_n-1) may be stored in the buffer.

In the n+2 th time period (Tn+2), the second communication unit 413 may transmit the n-th unit data data_n to the second communication unit 433, and the second communication unit 433 may transmit the n-th unit data data_n. 1 unit data (data_n-1) may be transmitted to the main controller 432 . At this time, the second communication unit 433 may receive the n-th unit data data_n from the second communication unit 413 after transmitting the n−1 th unit data data_n−1 to the main control unit 432. . The second communication unit 433 may store at least some of the n−1 th unit data data_n−1 and the n th unit data data_n in a buffer.

In the n+3 th time period (Tn+3), the second communication unit 433 may transmit the n th unit data data_n to the main controller 432 .

In the n+4th time period (Tn+4), the main control unit 432 may transmit a acknowledgment signal (ack) to the second communication unit 433 . In the n+5th time period (Tn+5), the second communication unit 433 may transmit a reception confirmation signal (ack) to the second communication unit 413 . In the n+6 th time period (Tn+6), the second communication unit 413 may transmit a acknowledgment signal (ack) to the main controller 412 . In the n+7 th time period (Tn+7), the main controller 412 may transmit a acknowledgment signal (ack) to the first communication unit 411 .

Although not shown, the operation shown in FIG. 18 may be repeated until all data is transmitted. If abnormal transmission of data is confirmed after receiving the acknowledgment signal (ack), previously transmitted data may be retransmitted.

Table 1 below shows how a communication unit (eg, the first communication unit 412 in FIGS. 6 and 18) that receives data from the management server 100 by accessing an external network among home appliances finally receives data. The number (n) of unit data to be transmitted before receiving the acknowledgment signal (ack) from the data receiving unit (eg, the main control unit 432 of the 1-3 home appliance 430 of FIGS. 5 and 18) , It represents the average transmission time (T_ave) (unit: seconds), which is the average time until transmission of all data to be transmitted is completed. In Table 1, T_ideal represents the time (unit: second) taken in the ideal case without errors, and the ratio represents the ratio of the average transmission time to the average transmission time when n is 1, respectively. In addition, Table 1 shows that the communication speed between the first communication unit 411 and the main control unit 412 is 38.4 kbps, the main control unit 412 and the second communication unit 413, and the second communication unit 413 and the second communication unit ( 433), and the communication speed between the second communication unit 433 and the main control unit 432 is 9.6 kbps.

n	One	2	4	8	16
T_ave (sec)	2461.69	1454.04	1072.58	1336.61	5756.2
T_ideal(sec)	793.81	415.47	226.30	131.41	84.41
ratio(%)	100	59	44	54	234

From Table 1, it can be seen that when n is 2 to 8, preferably when n is 4, data is transmitted at a faster time.

Data transmission from the 1-1 home appliance 410 to the 1-2 home appliance 420 and/or the 1-4 home appliance 430 may also be performed in substantially the same manner as described in FIG. 7 .

19 is a diagram for explaining a method of transmitting upgrade data in a method of upgrading an electronic device according to an embodiment of the present invention, illustrating a case in which data is transmitted in a 1-1 home appliance 410 will be. More specifically, the data received from the management server relates to the driving of the display module 414, and therefore, the data received by the first communication unit 411 is transmitted to the display module 414 through the main control unit 412. Indicates the transmission case.

A method of transmitting data shown in FIG. 19 will be easily understood by referring to the description of FIG. 18 .

Briefly, in the first time period T1 , the first communication unit 411 may transmit first unit data data_1 having a unit size to the main control unit 412 . In the second time period T2, the first communication unit 411 may transmit second unit data (data_2) having a unit size to the main control unit 412, and the main control unit 412 may transmit the first unit data ( data_1) may be transmitted to the display module 415. Thereafter, in the n-th time period Tn, the first communication unit 411 may transmit second unit data data_2 having a unit size to the main control unit 412, and the main control unit 412 may transmit the first unit data Data (data_1) may be transmitted to the display module 415 . In the n-th time period Tn, the first communication unit 411 may transmit n-th unit data data_2 having a unit size to the main control unit 412, and the main control unit 412 may transmit n-1-th unit data. Data (data_n-1) may be transmitted to the display module 415 . In the n+1th time period T(n+1), the main controller 412 may transmit the nth unit data data_n to the display module 415 . In the n+2 th time period (Tn+2), the display module 415 may transmit a acknowledgment signal (ack) to the main control unit 412 . In the n+3 th time period (Tn+5), the main control unit 412 may transmit a acknowledgment signal (ack) to the first communication unit 411 .

Table 2 shows that in the embodiment shown in FIG. 19, the communication unit (eg, the first communication unit 412 in FIGS. 6 and 19) that receives data from the management server 100 by accessing the external network transmits the data to the final Transmission of the number (n) of unit data to be transmitted before receiving the acknowledgment signal (ack) from the data receiving unit (eg, the display module 414 of FIGS. 6 and 19) and the entire data to be transmitted. It represents the average transmission time (T_ave) (unit: seconds), which is the average time until the completion of the transmission. In Table 1, T_ideal represents the time (unit: second) taken in the ideal case without errors, and the ratio represents the ratio of the average transmission time to the average transmission time when n is 1, respectively. Also, Table 2 shows experimental data when the communication speed between the first communication unit 411 and the main controller 412 and between the main controller 412 and the display module 414 is 38.4 kbps.

n	One	32	64	96	128
T_ave (sec)	57.77	27.09	28.94	31.62	34.24
T_ideal(sec)	57.33	24.23	23.69	23.69	23.43
ratio(%)	100	46.87	50.09	54.74	59.27

From Table 2, it can be seen that when n is 32 to 128, preferably when n is 32, data is transmitted at a faster time.

Data in the 1-2nd home appliance 420, 1-3rd home appliance 430, 1-4th home appliance 440, 2nd home appliance 500, and 3rd home appliance 600 Transmission may also be performed in substantially the same manner as described in FIG. 19 .

20 is a diagram for explaining a method of transmitting upgrade data of a method of upgrading an electronic device according to an embodiment of the present invention, from a 1-1 home appliance 410 to a 1-2 home appliance 420 , A case in which data is transmitted to the 1-3 home appliance 430 and the 1-4 home appliance 440 is illustrated.

A method of transmitting data of a method of upgrading an electronic device according to an embodiment of the present invention will be described with reference to FIGS. 6 and 20 .

First, any one of a plurality of home appliances connected to each other may select a main device and notify the selected device of the selection result (step S301). When the 1-1 home appliance 410 to 1-4 home appliance 440 are separate air conditioners, the 1-4 home appliance 440 that is an outdoor unit may be selected as the main device. This is because all indoor units must be connected to the outdoor unit, and the outdoor unit has information about all the indoor units. The 1-4 home appliance 440 receives data from the management server 100 among the 1-1 home appliance 410, the 1-2 home appliance 420, and the 1-3 home appliance 430. A home appliance that can do this can be selected as the main appliance.

When there are a plurality of home appliances capable of receiving data from the management server 100, the main device is selected according to the order connected to the 1-4 home appliances 440, or the 1-1 communication unit and/or the 1-1 2 The main device can be selected according to the performance of the communication unit.

For example, the 1-4th home appliance 440 includes the 1-1st home appliance 410, the 1-2nd home appliance 420, And internal unique addresses can be assigned to the 1-3 home appliances 420 . Thereafter, the 1-4th home appliance 440 may select a main device using the internal unique address. More specifically, the 1-4th home appliance 440 may select the home appliance to which the fastest internal unique address (eg, No. 1 or No. 0) is assigned as the main device. Depending on the embodiment, the 1-4th home appliance 440 is a port to which the 1-1st home appliance 410, the 1-2nd home appliance 420, and the 1-3 home appliance 420 are respectively connected. You can also assign internal unique addresses accordingly.

Alternatively, the 1-4th home appliance 440 is a 1-1 communication unit from each of the 1-1st home appliance 410, the 1-2nd home appliance 420, and the 1-3rd home appliance 420, and / or information on the performance of the 1-2 communication unit is received, and a home appliance having the best performance (eg, transmission speed) of the 1-1 communication unit and / or the 1-2 communication unit is selected as the main device. may be Depending on the embodiment, the 1-4 home appliance 440 transmits and receives data with the 1-1 home appliance 410, the 1-2 home appliance 420, and the 1-3 home appliance 420, respectively. The state is grasped, and according to the result, the performance of the 1-2 communication unit of each of the 1-1 home appliance 410, the 1-2 home appliance 420, and the 1-3 home appliance 420, etc. can also figure out

Hereinafter, it is assumed that the 1-1 home appliance 410 is selected as the main appliance.

Next, the main controller 412 of the 1-1 home appliance 410 transmits information indicating that the 1-1 home appliance 410 has been selected as the main device and/or an upgrade request to the first communication unit 411. It can (step S302).

The first communication unit 411 of the 1-1 home appliance 410 receives upgrade data from the management server 100 in the same manner as described in FIGS. 6 to 8, and transmits the data to the 1-1 home appliance 410. It can be transmitted to the main controller 412 of the device 410 (step S303). At this time, when the size of the data received from the management server 100 is greater than the unit size, the first communication unit 411 divides the received data into a plurality of unit data having unit sizes, and then sequentially unites the unit data. can also be sent. In this case, the unit size may be 256 bytes.

Next, the main controller 412 broadcasts the received data (or unit data) to the 1-2 home appliance 420, the 1-3 home appliance 430, and the 1-4 home appliance ( 440), at least two of them can be transmitted (step S304). Depending on the embodiment, the 1-1 home appliance 410 may be one of the indoor units of the separate type air conditioner, and the main control unit 412 of the 1-1 home appliance 410 is an outdoor unit to which it is connected (ie, , Data can be transmitted to other indoor units (ie, the 1-2nd home appliance 420 and the 1-3rd home appliance 430) connected to the 1-4th home appliance 440 in a broadcasting manner. .

Transmitting in a broadcast manner means that the same data is simultaneously transmitted to two or more home appliances at one time. At this time, the data transmitted from the main control unit 412 is transmitted through the second communication unit 413 of the 1-1 home appliance 410 and the second communication units 423, 433, and 443 of each home appliance. It may be transmitted to the main controller 422, 432, 442. Depending on the embodiment, in step S204, one unit data may be transmitted or a plurality of unit data may be sequentially transmitted.

Next, among the 1-2nd home appliance 420, the 1-3rd home appliance 430, and the 1-4th home appliance 440, the home appliances that have received the data sequentially send a acknowledgment signal to the first home appliance. -1 It can be transmitted to the home appliance 410 (steps S305, S306, S307). At this time, the main controller 412 of the 1-1 home appliance 410 may transmit a request signal for requesting transmission of the acknowledgment signal in a broadcasting manner, and the home appliances respond to the request signal to transmit the acknowledgment signal. can send

The order in which the 1-2nd home appliance 420, 1-3rd home appliance 430, and 1-4th home appliance 440 transmit the acknowledgment signal may be set in advance. The order of transmitting the acknowledgment signal may be set by the 1-4 home appliance 440 when the 1-4 home appliance 440 selects the main device, or the 1-1 selected as the main device. It may also be set by the home appliance 440.

The case of an air conditioner will be described as an example. In the case of an air conditioner, data may be transmitted to the 1st-2nd home appliance 420 and the 1st-3rd home appliance 430 (ie, indoor units). Also, as described above, the 1-2nd home appliance 420 and the 1-3rd home appliance 430 (ie, indoor units) are connected to the 1-4th home appliance 440 (ie, the outdoor unit). . In this case, internal unique numbers may be assigned to the first-second home appliances 420 and the first-third home appliances 430 (ie, indoor units) according to the order in which they are connected. Internal unique numbers can be assigned sequentially. Each of the 1-2nd home appliance 420 and the 1-3rd home appliance 430 (ie, indoor units) may determine its own standby time based on the internal unique number assigned to it. More specifically, each of the 1-2 home appliance 420 and 1-3 home appliance 430 (ie, indoor units) determines their own standby time by multiplying the internal unique number assigned to them by the unit standby time. can For example, it is assumed that the internal unique number assigned to the 1-2 home appliance 420 is 2, the internal unique number assigned to the 1-3 home appliance 430 is 3, and the unit standby time is 1 second. If so, the 1-2 home appliance 420 may determine its standby time as 2 seconds, and the 1-3 home appliance 430 may determine its standby time as 3 seconds. Thereafter, when the 1-1 home appliance 410 transmits a request signal requesting an acknowledgment signal, the 1-2 home appliance 420 and the 1-3 home appliance 430 (ie, indoor units), respectively may transmit an acknowledgment signal when its waiting time elapses from the time it receives the request signal.

Alternatively, the 1-2nd home appliance 420 and the 1-3rd home appliance 430 (ie, indoor units) may each transmit an acknowledgment signal after transmitting the line occupancy signal. More specifically, when the 1-1st home appliance 410 transmits a request signal, one of the 1-2nd home appliance 420 and the 1-3rd home appliance 430 (ie, indoor units) first The line occupancy signal may be transmitted in a broadcasting manner. Other home appliances receiving the line occupancy signal may wait for a unit waiting time, and the home appliance that has transmitted the line occupancy signal may transmit an acknowledgment signal within the unit waiting time. After the unit waiting time has elapsed, any one of the home appliances that failed to transmit the acknowledgment signal may transmit the line occupancy signal again and transmit the acknowledgment signal in the same way.

Next, when the main control unit 412 receives the acknowledgment signal from all home appliances, it may notify the completion of data transmission to the first communication unit 411 (step S308).

In the above-described embodiment of the air conditioner, a case in which one of the indoor units is a main unit has been exemplified, but the present invention is not limited thereto. That is, the outdoor unit may be the main unit. For example, when it is determined that there is no device suitable for operating as a main device among connected indoor units or that none of the indoor units are in a state in which data is not received from the management server, the outdoor unit receives data from the management server and receives the received data. can be transmitted to the indoor units connected to it in a broadcasting method. To this end, the outdoor unit (eg, the first-fourth home appliance 440) may further include a communication unit that communicates with the management server. According to the embodiment, after the indoor unit (eg, the 1-1 home appliance 410) transmits data for function upgrade to the outdoor unit (eg, the 1-4 home appliance 440), the outdoor unit (For example, the 1-4 home appliances 440) may transmit data to other indoor units in a broadcasting manner. Also, in this case, the indoor units may sequentially transmit acknowledgment signals to the outdoor units. An operation in which each of the indoor units transmits an acknowledgment signal may be the same as that described with reference to FIG. 20 .

Although not shown, when data is divided into unit data and transmitted, the above operation shown in FIG. 20 may be repeated until all data is transmitted. That is, the first communication unit 411 receiving the completion notification may transmit the next unit data to the main control unit 412 . After receiving the acknowledgment signal, if abnormal transmission of data is confirmed, previously transmitted data may be transmitted again.

In addition, the data transmission method shown in FIG. 20 can be more usefully used when several home appliances can be upgraded using the same data. For example, in the case of an air conditioner in which several indoor units (tens or more, depending on the embodiment) are connected to one outdoor unit, as shown in FIG. It is possible to reduce the time required for data transmission by transmitting data to the indoor units in a broadcasting manner and receiving an acknowledgment signal from other indoor units in a time-division manner.

The method of transmitting upgrade data shown in FIGS. 18 to 20 may be applied to a case where upgrade data is automatically downloaded, or may be applied to a case where upgrade data is normally downloaded.

21 and 22 are diagrams illustrating an upgrading process in a user terminal for upgrading a home appliance according to an embodiment of the present invention.

21(a) is an exemplary view showing a pop-up indicating that the user terminal 700 is ready to upgrade the home appliance 800. Referring to FIG. 21(b) is an exemplary diagram in which the user terminal 700 displays information about upgrading the home appliance 800. (c) of FIG. 21 is an exemplary view showing a screen for the user terminal 700 to input an agreement to upgrade the home appliance 800. FIG. 22 is an exemplary diagram in which the user terminal 700 displays a state in which the home appliance 800 is being upgraded and that the home appliance 800 has been upgraded.

Referring to (a) of FIG. 21 , the user terminal 700 may display a pop-up 711 notifying that an upgrade is possible for at least one home appliance 800 in the home. The management server 100 transmits upgrade information including an upgrade availability notification, a type and description of a function implemented by the upgrade, to the user terminal 20 (S105 and S207). When upgrade information is received, the user terminal 700 may display a pop-up 711 through an application (eg, LG ThinQ application).

Referring to (b) of FIG. 21 , the user terminal 700 may display types and descriptions of functions implemented by upgrade among upgrade information on an application screen. The application may display a screen 721 for selecting the type, description, and function of the upgrade function of the home appliance 800 and a button 722 requesting an upgrade of the selected function.

Referring to (c) of FIG. 21 , the user terminal 700 displays a pop-up 731 asking whether to upgrade at least one function of the home appliance 800 and a button 732 for entering the upgrade agreement on the application screen. can do.

When the user selects the upgrade consent button 732, an upgrade is performed (S26, S210) or a download is performed (S28, S109).

Referring to FIG. 22 , the user terminal 700 displays a screen 741 indicating that the home appliance 800 is being upgraded on an application screen. In the case of automatic download, when the screen 741 indicating that the home appliance 800 is being upgraded is displayed, the upgrade is performed (S26 and S210). In the case of a normal download, when the screen 741 indicating that the home appliance 800 is being upgraded is displayed, the download is performed (S28 and S109) or the upgrade is performed (S26 and S210).

Then, when the upgrade is completed, the user terminal 700 displays a screen 751 indicating that the upgrade of the home appliance 800 has been completed and a button 752 for completing all upgrade processes of the home appliance 800 on the application screen. do.

As described above, the present invention has been described with reference to the drawings illustrated, but the present invention is not limited by the embodiments and drawings disclosed in this specification, and various modifications are made by those skilled in the art within the scope of the technical idea of the present invention. It is obvious that variations can be made. In addition, although the operational effects according to the configuration of the present invention have not been explicitly described and described while describing the embodiments of the present invention, it is natural that the effects predictable by the corresponding configuration should also be recognized.

Claims (14)

1. a storage unit that stores upgrade data for upgrading an electronic device;

   a communication unit transmitting the upgrade data to the electronic device; and

   A control unit controlling storage of the upgrade data and transmission of the upgrade data;

   The controller determines an upgrade method based on at least one of a function to be upgraded, a capacity of upgrade data, a format of upgrade data, an expected transmission time of upgrade data, and identification information of a home appliance, and the upgrade according to the determined upgrade method. A management server that controls the transmission of data.
2. According to claim 1,

   The upgrade method includes transmitting the upgrade data including delta data composed of data different from program data stored in the electronic device among program data of the latest version after the management server receives upgrade acceptance from the user of the electronic device. A management server comprising a delta upgrade method and an automatic upgrade method in which an upgrade acceptance is received from a user of the electronic device after the management server transmits the upgrade data.
3. The method of claim 2, wherein the control unit

   If the capacity of the upgrade data is greater than or equal to the first reference capacity, the transmission of the upgrade data is controlled according to the automatic upgrade scheme, and if the capacity of the upgrade data is less than the first reference capacity, the upgrade data is controlled according to the delta upgrade scheme. A management server that controls egress.
4. The method of claim 2, wherein the control unit

   If the expected transmission time is greater than or equal to the first reference time, the transmission of the upgrade data is controlled according to the automatic upgrade scheme, and if the expected transmission time is less than the first reference time, transmission of the upgrade data is controlled according to the delta upgrade scheme. The management server that controls it.
5. The method of claim 2, wherein the control unit

   A management server for controlling the transmission of the upgrade data according to the automatic upgrade method when the upgrade data does not include a command, and controlling the transmission of the upgrade data according to the delta upgrade method when the upgrade data includes a command.
6. According to claim 2,

   The upgrade method further includes a general upgrade method in which the management server transmits the upgrade data including all program data of the latest version after receiving an upgrade acceptance from the user of the electronic device.
7. The method of claim 6, wherein the control unit

   control transmission of the upgrade data according to the automatic upgrade method when the capacity of the upgrade data is equal to or greater than the first standard capacity; A management server for controlling transmission of the upgrade data according to the delta upgrade method when the capacity is greater than or equal to the reference capacity, and controlling transmission of the upgrade data according to the general upgrade method when the capacity of the upgrade data is less than the second reference capacity.
8. The method of claim 6, wherein the control unit

   If the expected transmission time is equal to or greater than the first reference time, the transmission of the upgrade data is controlled according to the automatic upgrade method, and the expected transmission time is less than the first reference time and a second reference time shorter than the first reference time. The management server for controlling the transmission of the upgrade data according to the delta upgrade method if it is greater than or equal to, and controlling the transmission of the upgrade data according to the general upgrade method if the expected transmission time is less than the second reference time.
9. A method for a management server to upgrade an electronic device,

   Determining an upgrade method based on at least one of a function to be upgraded, a capacity of the upgrade data, a format of the upgrade data, an expected transmission time of the upgrade data, and identification information of the home appliance; and

   and controlling transmission of the upgrade data according to the determined upgrade method.
10. 10. The method of claim 9, wherein determining the upgrade method comprises:

    determining an upgrade method based on the capacity of the upgrade data;

    The step of controlling transmission of the upgrade data is

    receiving upgrade acceptance from a user of the electronic device after transmitting the upgrade data when the capacity of the upgrade data is greater than or equal to a first reference capacity; and

    When the capacity of the upgrade data is less than the first reference capacity, after receiving an upgrade acceptance from the user of the electronic device, delta data composed of data different from program data stored in the electronic device among program data of the latest version A method of upgrading an electronic device comprising the step of transmitting the upgrade data comprising:
11. 11. The method of claim 10, wherein controlling transmission of upgrade data comprises:

    If the capacity of the upgrade data is smaller than the second standard capacity, which is smaller than the first standard capacity, transmitting the upgrade data including all of the latest version of program data after receiving an upgrade acceptance from the user of the electronic device. How to upgrade electronic gadgets, including more.
12. 10. The method of claim 9, wherein determining the upgrade method comprises:

    Determine an upgrade method based on the expected transmission time;

    The step of controlling transmission of the upgrade data is

    receiving an upgrade acceptance from a user of the electronic device after transmitting the upgrade data when the expected transmission time is greater than or equal to a first criterion; and

    When the expected transmission time is less than the first reference time, after receiving an upgrade acceptance from the user of the electronic device, including delta data composed of data different from program data stored in the electronic device among program data of the latest version A method of upgrading an electronic device comprising the step of transmitting the upgrade data to
13. 13. The method of claim 12, wherein controlling transmission of upgrade data comprises:

    If the expected transmission time is less than a second reference time shorter than the first reference time, after receiving upgrade acceptance from the user of the electronic device, transmitting the upgrade data including all of the latest version of program data. How to upgrade electronic devices, including.
14. 10. The method of claim 9, wherein determining the upgrade method comprises:

    determine an upgrade method based on the format of the upgrade data;

    The step of controlling transmission of the upgrade data is

    receiving upgrade acceptance from a user of the electronic device if the upgrade data does not include a command; and

    If the upgrade data includes a command, after receiving upgrade acceptance from the user of the electronic device, the upgrade data including delta data composed of data different from program data stored in the electronic device among program data of the latest version A method of upgrading an electronic device comprising the step of transmitting.

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