CN107560071B

CN107560071B - Control method of remote controller, remote controller and storage medium

Info

Publication number: CN107560071B
Application number: CN201710759199.XA
Authority: CN
Inventors: 张三杰
Original assignee: Midea Group Co Ltd; GD Midea Heating and Ventilating Equipment Co Ltd
Current assignee: Midea Group Co Ltd; GD Midea Heating and Ventilating Equipment Co Ltd
Priority date: 2017-08-28
Filing date: 2017-08-28
Publication date: 2020-07-03
Anticipated expiration: 2037-08-28
Also published as: CN107560071A

Abstract

The invention discloses a control method of a remote controller, which comprises the following steps: recording an adjusting instruction which is triggered on the remote controller by a user and is used for adjusting the operating parameters of the electronic equipment within a preset time after the remote controller sends the control instruction, wherein the adjusting instructions of different parameter types form an adjusting instruction set; judging whether a learning instruction exists in a plurality of adjustment instruction sets recorded by continuous preset times, wherein the learning instruction is the same adjustment instruction existing in the adjustment instruction sets; and when learning instructions exist in a plurality of adjustment instruction sets recorded by continuous preset times, updating the preset parameters according to the learning instructions. The invention can solve the problem that the user needs to frequently modify the preset parameters of the air conditioner when the running state of the air conditioner needs to be changed along with the change of the running state of the air conditioner. The invention also provides a remote controller and a computer readable storage medium.

Description

Control method of remote controller, remote controller and storage medium

Technical Field

The present invention relates to the field of air conditioner technology, and more particularly, to a method for controlling a remote controller, a remote controller using the method, and a storage medium storing the method.

Background

Generally, in consideration of personal habits, comfort and power saving, a user needs to set a combination of a plurality of functions in some special scenes when using an electronic device. Take an air conditioner as an example: before sleeping, some users can set an operation mode (cooling/heating/air supply), set temperature, time off information, turn off the light of the display panel, mute, economical or electric auxiliary heating setting and the like.

In the prior art, a remote controller provides a function of triggering a shortcut key once for a user to enable an electronic device to reach a preset operation state, and the user initializes the shortcut key function by presetting corresponding operation parameters. However, the operation state can only adapt to a specific environment, and changes along with the habit of the user and the recent requirement of the user, which causes the user to continuously modify the preset parameters of the preset operation state of the air conditioner, and the process is complicated.

Disclosure of Invention

The invention mainly aims to provide a control method of a remote controller, and aims to solve the problem that a user is required to frequently modify preset parameters of the remote controller when the running state of electronic equipment needs to be changed along with the change of the running state of the electronic equipment.

In order to achieve the above object, the present invention provides a method for controlling a remote controller, where the remote controller has preset parameters, and the remote controller sends a control instruction to an electronic device according to the preset parameters to control the electronic device to operate according to the control instruction, and the method for controlling the remote controller includes the following steps:

recording an adjusting instruction which is triggered on the remote controller by a user and is used for adjusting the operating parameters of the electronic equipment within a preset time after the remote controller sends the control instruction, wherein the adjusting instructions of different parameter types form an adjusting instruction set;

judging whether a learning instruction exists in a plurality of adjustment instruction sets recorded by continuous preset times, wherein the learning instruction is the same adjustment instruction existing in the adjustment instruction sets;

and when learning instructions exist in a plurality of adjustment instruction sets recorded by continuous preset times, updating the preset parameters according to the learning instructions.

In a possible embodiment, the operating parameters of the electronic device include operating sub-parameters of different parameter types; the recording of the adjustment instruction triggered by the user on the remote controller for adjusting the operating parameters of the electronic device within the preset time after the remote controller sends the control instruction includes the steps of:

recording an adjusting sub-instruction which is triggered on the remote controller by a user and is used for adjusting the operation sub-parameters of the electronic equipment within a preset time after the remote controller sends the control instruction;

and generating an adjusting instruction of the parameter type according to the adjusting sub-instruction of the same parameter type, and further forming an adjusting instruction set according to the adjusting instructions of different parameter types.

In a possible embodiment, the preset parameters include preset sub-parameters of different parameter types; the step of updating the preset parameters according to the learning instruction comprises:

and updating preset sub-parameters with the same parameter types as the learning instruction according to the learning instruction, so as to update the preset parameters.

judging whether preset sub-parameters with the same parameter type as the learning instruction exist in the preset parameters or not;

and when the preset parameters do not have preset sub-parameters with the same parameter types as the learning instructions, adding the learning instructions into the preset parameters as the preset sub-parameters of the corresponding parameter types of the learning instructions, so as to update the preset parameters.

recording an adjusting sub-instruction and a triggering time which are triggered on the remote controller by a user and are used for adjusting the operation sub-parameters of the electronic equipment within a preset time after the remote controller sends the control instruction, wherein the triggering time is a time interval from the remote controller to the remote controller after the control instruction is sent;

generating an adjusting instruction of the parameter type according to the adjusting sub-instruction of the same parameter type and the trigger time corresponding to the adjusting sub-instruction, wherein the adjusting instruction changes along with the time change;

and forming an adjusting instruction set according to the adjusting instructions of different parameter types.

In a possible embodiment, the preset parameters include preset sub-parameters corresponding to different parameter types; the step of updating the preset parameters according to the learning instruction comprises:

and updating the preset sub-parameters with the same parameter types as the learning instruction according to the learning instruction and the triggering time corresponding to the learning instruction, so as to update the preset parameters.

In a feasible embodiment, the control method of the remote controller is applied to control the operation parameters of the air conditioner, and the preset parameters comprise at least one of an air supply mode parameter, a timing on/off parameter, a volume parameter, a light brightness parameter, a wind speed parameter, a wind direction parameter and an electric auxiliary heating parameter;

the adjusting instruction set comprises at least one of an air supply temperature adjusting instruction, a timing on/off time adjusting instruction, a volume adjusting instruction, a light brightness adjusting instruction, a wind speed adjusting instruction, a wind direction adjusting instruction and an electric auxiliary heating parameter adjusting instruction.

In a feasible embodiment, the preset parameter includes an air supply mode parameter, the remote controller further prestores a refrigeration temperature and a heating temperature, the refrigeration temperature is not less than the heating temperature, and the step of sending a control instruction to the electronic device by the remote controller according to the preset parameter to control the electronic device to operate according to the control instruction includes:

acquiring the indoor environment temperature;

when the indoor environment temperature is lower than the heating temperature, the remote controller sends a control instruction that the air supply temperature is the heating temperature to control the air conditioner to operate according to heating mode parameters;

when the indoor environment temperature is higher than the refrigerating temperature, the remote controller sends out a control instruction that the air supply temperature is the refrigerating temperature to control the air conditioner to operate according to the refrigerating mode parameters;

and when the indoor environment temperature is between the heating temperature and the cooling temperature, the remote controller sends a ventilation/dehumidification control instruction to control the air conditioner to operate according to ventilation mode parameters/dehumidification mode parameters.

The invention also provides a remote controller which is applied to control the operation parameters of the air conditioner and comprises a timer, a temperature sensor, a signal transmitting module, a signal receiving module, a memory, a processor and a computer program which is stored on the memory and can be operated on the processor,

the timer is used for starting timing when the remote controller sends out a control instruction;

the temperature sensor is used for acquiring indoor temperature;

the signal transmitting module is used for sending a control instruction and an adjusting instruction to the air conditioner;

the signal receiving module is used for receiving an adjusting instruction triggered by a user on a remote controller;

the computer program, when executed by the processor, implements the steps of a method of controlling a remote control as set forth in any one of the above.

The present invention also provides a computer-readable storage medium, on which a control program of a remote controller is stored, wherein the preset parameter updating program, when executed by a processor, implements the steps of the control method of the remote controller as set forth in any one of the above.

In the embodiment of the invention, the adjusting instruction which is triggered on the remote controller by a user and is used for adjusting the operating parameters of the electronic equipment is recorded in the preset time after the remote controller sends the control instruction, and the adjusting instructions of different parameter types form an adjusting instruction set; judging whether a learning instruction exists in a plurality of adjustment instruction sets recorded by continuous preset times, wherein the learning instruction is the same adjustment instruction existing in the adjustment instruction sets; and when learning instructions exist in a plurality of adjustment instruction sets recorded by continuous preset times, updating the preset parameters according to the learning instructions. Therefore, the remote controller can autonomously learn the recent use habit of the user to the operation parameters of the electronic equipment from the adjustment instruction of the recent user, automatically update the preset parameters to the preset parameters meeting the use habit of the recent user according to the learning instruction, and improve the user experience.

Drawings

FIG. 1 is a schematic view of a remote control controlling an electronic device according to the present invention;

FIG. 2 is a flowchart illustrating a control method of a remote controller according to a first embodiment of the present invention;

FIG. 3 is a diagram illustrating a plurality of adjustment instruction sets according to a first embodiment of a control method of a remote controller of the present invention;

FIG. 4 is a sub-flowchart of step S10 in the second embodiment of the method for controlling a remote controller according to the present invention;

FIG. 5 is a schematic structural diagram of a remote controller according to a second embodiment of the control method of the remote controller of the present invention;

FIG. 6 is a diagram illustrating a plurality of adjustment sub-commands generating adjustment commands according to a second embodiment of a control method of a remote controller of the present invention;

FIG. 7 is a sub-flowchart of step S30 in the third embodiment of the method for controlling a remote controller according to the present invention;

FIG. 8 is a sub-flowchart of step S30 in the fourth embodiment of the method for controlling a remote controller according to the present invention;

fig. 9 is a schematic sub-flowchart of step S10 in the fifth embodiment of the method for controlling a remote controller according to the present invention;

FIG. 10 is a diagram illustrating parameter adjustment commands in a fifth embodiment of a method for controlling a remote controller according to the present invention;

FIG. 11 is a diagram illustrating a plurality of adjustment instruction sets according to a fifth embodiment of the method for controlling a remote controller of the present invention;

fig. 12 is a schematic sub-flowchart of step S30 in the sixth embodiment of the method for controlling a remote controller according to the present invention;

FIG. 13 is a diagram illustrating the integration of preset sub-parameters and learning commands in a sixth embodiment of a method for controlling a remote controller according to the present invention;

FIG. 14 is a diagram illustrating the integration of preset sub-parameters and learning commands in a second embodiment of a method for controlling a remote controller according to the present invention;

fig. 15 is a schematic sub-flowchart of step S00 in the seventh embodiment of the method for controlling a remote controller according to the present invention;

fig. 16 is a block diagram showing the structure of the remote controller according to the present invention.

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The invention provides a control method of a remote controller, which mainly solves the problem that after the existing remote controller provides a function of triggering a shortcut key once for a user to enable electronic equipment to reach a preset operation state, the preset parameters of the remote controller are required to be frequently modified by the user to adapt to new user habits and user requirements along with the change of the user habits and the user requirements.

Referring to fig. 1 and 2, in the first embodiment of the control method of the remote controller, the electronic device may be an air conditioner, a washing machine, an electric water heater, a television, a projector, etc., and the air conditioner is taken as an example below, but should not be taken as a limitation to the scope of the present invention. The control method of the remote controller comprises the following steps:

and step S10, recording an adjusting instruction which is triggered by a user on the remote controller and is used for adjusting the operating parameters of the electronic equipment within a preset time after the remote controller sends the control instruction, wherein the adjusting instructions of different parameter types form an adjusting instruction set.

Specifically, before the step S10, the method may further include: and step S00, the remote controller sends a control instruction to the electronic equipment according to the preset parameter so as to control the electronic equipment to operate according to the control instruction.

The remote controller is pre-stored with preset parameters, and after a user triggers a shortcut key, the remote controller sends a control instruction to the electronic equipment according to the preset parameters to control the electronic equipment to operate according to the control instruction.

The preset parameters pre-stored in the remote controller of the air conditioner may include at least one preset sub-parameter of an air supply mode parameter, a timing on/off parameter, a volume parameter, a light brightness parameter, a wind speed parameter, a wind direction parameter and an electric auxiliary heating parameter. The user sets the parameter values of all preset sub-parameters in advance on the setting interface, and then sends out a control instruction according to the preset parameters to control the air conditioner to operate according to the control instruction only by pressing the shortcut key once.

For the preset parameters of the single mode, the control command sent by the remote controller is the same as the preset parameters, for example: when the preset parameter is that the wind speed is the second gear, the user presses the shortcut key, and the remote controller sends out a control instruction that the wind speed is the second gear to control the air conditioner to output air by taking the wind speed as the second gear. However, the multi-mode preset parameters such as the air supply mode parameter include a plurality of mode parameters such as a cooling mode parameter, a heating mode parameter, a dehumidification mode parameter, and a ventilation mode parameter, and one of the mode parameters needs to be selected according to a preset rule to control the air conditioner to operate, and a control command at this time is not completely the same as the preset parameter.

In step S10, if the user feels that the current operating parameters of the air conditioner are inappropriate within the preset time after pressing the shortcut key, the user triggers different operation keys to initiate an adjustment instruction to control the air conditioner to adjust the corresponding operating parameters, and finally the air conditioner operates according to the adjusted parameters desired by the user. At the moment, the remote controller records the adjustment instruction of the user to the remote controller within the preset time after the user triggers the shortcut key of the remote controller to send out the control instruction, and the adjustment instruction is used as a data basis for the remote controller to learn the current use habit of the user. The specific preset time may be set to 10min, 15min, 20min, 30min, etc., which is not limited in the present invention.

In a preset time after the remote controller triggers a shortcut key to send a control instruction containing the preset parameters, all recorded adjustment instructions form an adjustment instruction set; wherein, an adjustment instruction contains all adjustments of one parameter type by a user, and the adjustment instruction set comprises adjustment instructions aiming at different parameter types, which are triggered by the user on a remote controller. The adjusting instruction is used for adjusting the operation sub-parameters of the same parameter type in the operation parameters of the air conditioner, and the parameter type of the adjusting instruction can be a parameter type included in the preset parameters or a parameter type not included in the preset parameters. Specifically, the adjustment instruction set may include at least one of an air supply temperature adjustment instruction, a timing on/off time adjustment instruction, a volume adjustment instruction, a light brightness adjustment instruction, a wind speed adjustment instruction, a wind direction adjustment instruction, and an electric auxiliary heating parameter adjustment instruction.

Step S20, judging whether a plurality of adjustment instruction sets recorded by continuous preset times have learning instructions, wherein the learning instructions are the same adjustment instructions in the adjustment instruction sets;

in this embodiment, the recent usage habit of the user is learned by adopting a screening method that determines whether the same adjustment instruction exists in the multiple adjustment instruction sets recorded by the continuous preset times, and the adjustment instruction obtained by screening may be considered as a learning instruction which is obtained by the remote controller from the multiple adjustment instruction sets and conforms to the recent usage habit of the user.

The case that the preset times are 3 times, the air conditioner operates in the refrigeration mode with preset parameters of 24 ℃, the air outlet angle is 30 degrees, and the wind speed is the second gear is taken as an example for explanation:

referring to fig. 3, the adjustment instruction set obtained after the user presses the shortcut key N times includes: raising the refrigeration temperature by 2 ℃, raising the wind speed by one step, and increasing the wind outlet angle by 10 degrees for wind outlet;

the obtained adjustment instruction set after the user presses the shortcut key for the (N + 1) th time comprises the following steps: the wind speed is reduced by one gear, the wind outlet angle is increased by 10 degrees, the noise is reduced, and the refrigerating temperature is increased by 2 ℃;

the adjustment instruction set obtained after the user presses the shortcut key N +2 times comprises: raising the refrigerating temperature by 2 ℃, turning off the light, muting and reducing the wind speed by one gear;

the adjustment instruction set obtained after the user presses the shortcut key for the (N + 3) th time comprises the following steps: the refrigeration temperature is raised by 1 ℃, and the wind speed is reduced by one gear and is muted.

By judging the three consecutive adjustment instruction sets obtained at the nth time, the N +1 time and the N +2 time, it can be judged that the three adjustment instruction sets all have the learning instruction of the refrigerating temperature being increased by 2 ℃, so that the remote controller timely enters the step S30 after learning the learning instruction of the refrigerating temperature being increased by 2 ℃.

By judging the three consecutive adjustment instruction sets obtained at the N +1 th time, the N +2 th time and the N +3 th time, it can be judged that two learning instructions of first gear reduction and mute exist in the three adjustment instruction sets, and therefore, after the remote controller learns the two learning instructions of 2 ℃ increase of the refrigerating temperature and mute, the operation goes to step S30.

Step S30, when there is a learning instruction in the plurality of adjustment instruction sets recorded by the consecutive preset times, updating the preset parameter according to the learning instruction.

After updating, when the user presses the shortcut key again, the remote controller can send out a control instruction according to the updated preset parameter to control the air conditioner to press the control instruction, namely after the user continuously presets the times for adjustment, when the user presses the shortcut key again, the remote controller can learn new user habits to control the air conditioner to operate according to the new user habits, and the user does not need to adjust again after pressing the shortcut key.

Further, referring to fig. 4, based on the first embodiment of the control method of the remote controller of the present invention, in the second embodiment of the control method of the remote controller of the present invention, the operation parameters of the electronic device include operation sub-parameters of different parameter types; the step S10 includes:

step S11, recording an adjusting sub-instruction which is triggered by a user on the remote controller and is used for adjusting the operation sub-parameters of the electronic equipment within the preset time after the remote controller sends the control instruction;

referring to fig. 5, the remote controller includes keys for increasing 1 c, decreasing 1 c, increasing one gear of wind speed, decreasing one gear of wind speed, muting, turning on/off the light, and the user triggers an adjustment sub-command every time the user presses one key on the remote controller. When a user adjusts the current operating parameters of the air conditioner, a key on the remote controller is pressed, the remote controller sends an adjusting sub-instruction corresponding to the key to the air conditioner, and the operating parameters of the air conditioner are controlled to be changed correspondingly according to the operating sub-parameters with the same parameter types as the adjusting sub-instruction, so that the operating parameters of the air conditioner are changed. And when the user triggers the adjustment sub-instruction within the preset time after the remote controller sends the control instruction, the remote controller records all the adjustment sub-instructions.

Step S12, generating an adjustment instruction of the parameter type according to the adjustment sub-instruction corresponding to the same parameter type, and further forming an adjustment instruction set according to the adjustment instructions of different parameter types.

And the remote controller classifies all recorded adjusting sub-instructions according to the parameter types, integrates the adjusting sub-instructions with the same parameter types, and finally, each recorded adjusted parameter type obtains only one integrated adjusting instruction.

Please refer to fig. 6, for example: after the user presses the shortcut key for the Mth time, the user presses the shortcut key within the preset time: raising the temperature by 1 ℃, raising the wind speed by 1 grade, reducing the wind speed by 1 grade and muting; after recording the adjustment sub-instructions, the remote controller integrates the adjustment instructions of the same parameter type, namely integrates the temperature rise of 1 ℃ and the temperature rise of 1 ℃ of the corresponding temperature parameters to obtain an adjustment instruction of 2 ℃ of temperature rise; and integrating the wind speed increase by 1 gear, the wind speed reduction by 1 gear and the wind speed reduction by 1 gear corresponding to the wind speed parameters to obtain an adjustment instruction of reducing the wind speed by one gear. For the case that the parameter type has only one adjustment sub-instruction, the adjustment sub-instruction is an adjustment instruction, and the adjustment instruction corresponding to the volume parameter is mute in the above example.

And in a preset time after the remote controller triggers a shortcut key to send a control instruction containing the preset parameters, all recorded adjusting sub-instructions are integrated to obtain a plurality of adjusting instructions corresponding to different parameters, and the adjusting instructions of the different parameters form an adjusting instruction set.

In some cases, a user presses a key on the key remote controller once to trigger an adjustment sub-instruction once, and cannot adjust the corresponding parameter type to an ideal state once, so that the user needs to press the key many times to trigger the adjustment sub-instruction many times. If all the adjustment sub-parameters corresponding to one parameter type are not integrated, the difficulty of determining whether the learning instruction exists in the continuous adjustment instruction set in the subsequent step S20 is very high, and once the user presses a wrong key during adjustment, even if the user returns the adjustment instruction after pressing the wrong key, the adjustment instruction cannot be considered as the same as the previous two times by the remote controller, so that the intelligence of the remote controller in learning the habit of the user is reduced. Therefore, the present embodiment can obtain one adjustment instruction per parameter type by integrating adjustment sub-instructions of the same parameter type. In the subsequent step of judging in step S20, the integrated adjustment instruction can be used for judgment, so that the learning accuracy of the remote controller is improved, and the customer experience is optimized.

Further, referring to fig. 7, based on the above-mentioned embodiment of the control method of the remote controller of the present invention, in a third embodiment of the control method of the remote controller of the present invention, the preset parameters include preset sub-parameters of different parameter types; the step S30 includes:

step S31, updating the preset sub-parameters with the same parameter type as the learning instruction according to the learning instruction, thereby updating the preset parameters.

And when the preset parameters are updated, finding the preset sub-parameters with the same parameter types as the learning instructions in the preset parameters, and integrating the preset sub-parameters with the same parameter types with the learning instructions to obtain the integrated preset sub-parameters of the parameter types. The preset sub-parameters in the original preset parameters are changed into the integrated preset sub-parameters, so that the original preset parameters are updated to new preset parameters after integration.

For example: the preset parameters are a 24 ℃ refrigeration mode, the wind speed is the second gear, the shutdown is carried out after 5 hours, the learning instruction is the shutdown which is prolonged by 1 hour, the shutdown after 5 hours and the shutdown which is prolonged by 1 hour are integrated to obtain new preset sub-parameters of the shutdown after 6 hours, and therefore the updated preset parameters are the 24 ℃ refrigeration mode, the wind speed is the second gear, and the shutdown is carried out after 6 hours.

It is to be understood that the integration of the preset sub-parameters and the learning commands of the same parameter type may be the integration of the preset sub-parameters and the learning commands of the same parameter type according to actual parameter logic.

In the embodiment, the preset sub-parameters in the preset parameters, which have the same parameter type as the learning instruction, are updated according to the learning instruction, so that new preset parameters are obtained.

Further, referring to fig. 8, based on the first embodiment or the second embodiment of the control method of the remote controller of the present invention, in a fourth embodiment of the control method of the remote controller of the present invention, the preset parameters include preset sub-parameters of different parameter types; the step S30 includes:

step S32, judging whether the preset parameters have preset sub-parameters with the same parameter type as the learning instruction;

if there is no preset sub-parameter of the same parameter type as the learning instruction in the preset parameters, the process proceeds to step S33.

Step S33, adding the learning instruction as a preset sub-parameter of the corresponding parameter type to the preset parameter, so as to update the preset parameter.

The learning instruction is the recent use habit of the user learned by the remote controller through the adjustment instruction of the user, and if the preset parameter does not have the parameter type of the learning instruction, the user habit is not existed before and is generated in the recent period of the user, so that the learning instruction is added to the preset parameter as the preset sub-parameter of the corresponding parameter type by the remote controller, and the preset parameter according with the recent use habit of the user is updated.

For example: the preset parameters are a 24 ℃ refrigeration mode, the wind speed is the second gear, the machine is turned off after 5 hours, the learning instruction is mute, the mute is taken as a preset sub-parameter of the volume parameter and is added into the preset parameters, and therefore the updated preset parameters are the 24 ℃ refrigeration mode, the wind speed is the second gear, and the machine is turned off and mute after 5 hours.

In this embodiment, the learning instruction is added to the original preset parameter as a preset sub-parameter of the corresponding parameter, so as to update the preset parameter. The remote controller can learn the recent new use habit of the user, and update the preset parameters according to the learning instruction, the user can enjoy the new use habit only by pressing the shortcut key, the user does not need to enter the setting interface for setting, and the user does not need to adjust after pressing the shortcut key at every time, so that the learning capacity of the remote controller is improved, and the user experience of the remote controller is optimized.

Further, please refer to fig. 9 in combination, based on the first embodiment of the control method of the remote controller of the present invention, in the fifth embodiment of the control method of the remote controller of the present invention, the operation parameters of the electronic device include operation sub-parameters of different parameter types; the step S10 includes:

step S13, recording an adjusting sub-instruction and a triggering time which are triggered by a user on the remote controller and are used for adjusting the operation sub-parameters of the electronic equipment within a preset time after the remote controller sends the control instruction, wherein the triggering time is a time interval from the remote controller to the remote controller after the control instruction is sent;

referring to fig. 5 again, the remote controller of the air conditioner includes keys for increasing 1 c, decreasing 1 c, increasing the wind speed by one step, decreasing the wind speed by one step, muting, turning on/off the light, etc., and the user triggers an adjustment sub-command every time the user presses one key on the remote controller. When a user adjusts the current operating parameters of the air conditioner, a key on the remote controller is pressed, the remote controller sends an adjusting sub-instruction corresponding to the key to the air conditioner, and the operating parameters of the air conditioner are controlled to be changed correspondingly according to the operating sub-parameters with the same parameter types as the adjusting sub-instruction, so that the operating parameters of the air conditioner are changed. And when the user triggers the adjustment sub-instructions within the preset time after the remote controller sends the control instructions, the remote controller records all the adjustment sub-instructions and the triggering time corresponding to each adjustment sub-instruction. And the timer in the remote controller starts timing when the remote controller sends out a control instruction, and the time on the timer when the adjustment sub-instruction triggers is taken as the triggering time corresponding to the adjustment sub-instruction.

Step S14, generating an adjusting instruction of the parameter type according to the adjusting sub-instruction of the same parameter type and the triggering time corresponding to the adjusting sub-instruction;

in this embodiment, after the user presses the shortcut key once, the air conditioner may automatically adjust the operation parameters in a time-phased manner, so that the remote controller needs to learn a habit of the user to adjust the operation parameters of the air conditioner in a time-phased manner in a previous adjustment sub-instruction of the user.

And the remote controller classifies all recorded adjusting sub-instructions according to the parameter types, and generates adjusting instructions of the parameter types according to the adjusting sub-instructions of the same parameter types and the respective corresponding trigger time. If the remote controller needs to send out an adjusting instruction, according to the time sequence, when the time reaches the trigger time, sending out an adjusting sub-instruction corresponding to the trigger time.

The case that the preset time is 30min, the preset parameter of the air conditioner is a 24 ℃ refrigeration mode, and the wind speed is the third gear is taken as an example for explanation:

referring to fig. 10, the user raises the cooling temperature by 2 ℃ at the 3 rd minute after pressing the shortcut key, lowers the wind speed by one step at the 12 th minute, and raises the cooling temperature by 1 ℃ at the 25 th minute. Based on all the adjustment sub-commands, two adjustment commands, i.e., a temperature parameter adjustment command and a wind speed parameter adjustment command, can be generated. The temperature parameter adjustment instructions were refrigeration temperature increase of 2 ℃ at the 3 rd minute, refrigeration temperature increase of 1 ℃ at the 25 th minute, and no adjustment of temperature for the remaining time. The wind speed parameter adjustment instruction is to reduce the wind speed by one gear in the 12 th minute, and the rest of the time is to not adjust the wind speed.

And step S15, forming an adjusting instruction set according to the adjusting instructions of different parameter types.

And forming an adjusting instruction set by all parameter types of adjusting instructions recorded within preset time after a user presses a shortcut key once.

In this embodiment, the adjustment instruction does not set the operating parameters of the electronic device at one time, but adjusts the operating parameters of the electronic device in a staged manner through the actual operation habit of the user, so that the remote controller can learn how to adjust the operating parameters of the electronic device more intelligently, the user can adjust the operating parameters of the electronic device in a staged manner within a preset time after pressing a shortcut key, the higher-order requirements of the user are met, and the user experience of the product is improved.

Further, in step S20, it is necessary to determine whether the same adjustment command exists in the plurality of adjustment command sets recorded continuously, and in this embodiment, if the parameter values of the two adjustment sub-commands are equal and the trigger time is within the preset time range, the two adjustment sub-commands are considered to be the same. And if all the adjusting sub-instructions in the two adjusting instructions are the same, the two adjusting instructions are considered to be the same. Step S20 determines whether the same adjustment command exists in a plurality of adjustment commands recorded continuously by using the determination rule, and uses the latest adjustment command of the plurality of the same adjustment commands as the learning command. In other embodiments, the average time of each adjustment sub-instruction may also be calculated as the trigger time of the corresponding learning sub-instruction in the learning instruction, which is not specifically limited in the present invention. In addition, the preset time range in the embodiment may be 2min, 3min, and 5min, which is not limited in the present invention.

The operation example is described with the preset times of 3 times, the preset time range of 2min, the preset parameters of the air conditioner of 24 ℃ in the refrigeration mode and the air speed of the second gear:

referring to fig. 11, the adjustment instruction set obtained after the xth key press includes: the wind speed is reduced by 5 ℃ in the 1 st minute, increased by 3 ℃ in the 7 th minute, increased by 1 ℃ in the 10 th minute, increased by 1 ℃ in the 15 th minute, increased by 2 in the 1 st minute, and reduced by 2 in the 9 th minute;

the adjustment instruction set obtained after pressing the shortcut key for the X +1 th time comprises the following steps: reducing the wind speed by 5 ℃ in the 1 st minute, increasing the temperature by 3 ℃ in the 8 th minute, increasing the temperature by 1 ℃ in the 14 th minute, increasing the wind speed by 1 ℃ in the 16 th minute, increasing the wind speed by 2 steps in the 2 nd minute, reducing the wind speed by 2 steps in the 9 th minute and muting in the 26 th minute;

the adjustment instruction set obtained after pressing the shortcut key for the X +2 times comprises: reducing the temperature by 5 ℃ in the 1 st minute, increasing the temperature by 3 ℃ in the 8 th minute, increasing the temperature by 1 ℃ in the 15 th minute, increasing the temperature by 1 ℃ in the 17 th minute, increasing the wind speed by 2 steps in the 2 nd minute, reducing the wind speed by 2 steps in the 8 th minute, and shutting down the wind turbine after timing for 3 hours in the 21 st minute;

the adjustment instruction set obtained after pressing the shortcut key for the X +3 times comprises: decreasing the temperature by 5 ℃ in the 2 nd minute, increasing the temperature by 3 ℃ in the 8 th minute, increasing the temperature by 1 ℃ in the 15 th minute, increasing the temperature by 1 ℃ in the 16 th minute, and turning on the lamp in the 26 th minute;

by determining the three consecutive adjustment instruction sets obtained at the X, X +1, and X +2 times, it can be determined that the learning instruction of the 2 nd minute wind speed increase by 2 nd gear and the 8 th minute wind speed decrease by 2 nd gear exists in the three adjustment instruction sets, and after the remote controller learns the learning instruction, the process proceeds to step S30.

By determining the three consecutive adjustment instruction sets obtained by the X +1 th time, the X +2 th time, and the X +3 th time, it can be determined that there is a learning instruction in the three adjustment instruction sets, which is decreased by 5 ℃ at the 2 nd minute, increased by 3 ℃ at the 8 th minute, increased by 1 ℃ at the 15 th minute, and increased by 1 ℃ at the 16 th minute, and after the remote controller learns the learning instruction, the process proceeds to step S30.

Further, referring to fig. 12, based on the first embodiment or the fifth embodiment of the method for controlling a remote controller of the present invention, in the sixth embodiment of the method for controlling a remote controller of the present invention, the step S30 includes:

step S34, updating the preset sub-parameters with the same parameter type as the learning instruction according to the learning instruction and the trigger time corresponding to the learning instruction, so as to update the preset parameters.

In this embodiment, the preset parameter may be a static parameter, that is, each preset sub-parameter of the preset parameter is zero, and after the user presses the shortcut key, the remote controller immediately sends out all control instructions according to the preset parameter in unit time; the preset parameters can also be dynamic instructions, that is, after the user presses the shortcut key, the remote controller will send out corresponding control sub-instructions according to the triggering time of each preset sub-parameter.

In this embodiment, the learning instruction is a dynamic parameter, that is, different adjustment sub-instructions are triggered at different trigger times in the learning instruction recorded by the remote controller.

And integrating the learning instruction and the preset sub-parameters with the same parameter types as the learning instruction to generate new preset parameters. The following description will be given by taking the air conditioner in the heating mode and the preset parameter as a static instruction as a first example: referring to fig. 13, the original preset parameters include two preset sub-parameters, that is, the initial heating temperature is 22 ℃ and the wind speed is the third gear, the learning instruction includes two learning sub-instructions, that is, the heating temperature is increased by 1 ℃ in the 5 th minute and the wind speed is increased by 1 ℃ in the 12 th minute, the preset temperature sub-parameters of the same parameter type as the learning instruction are integrated, the updated preset temperature sub-parameters include the initial heating temperature of 22 ℃, the heating temperature is increased by 1 ℃ in the 5 th minute and the heating temperature is increased by 1 ℃ in the 12 th minute, so that the updated preset parameters include the initial heating temperature of 22 ℃ and the wind speed of the third gear, the heating temperature is increased by 1 ℃ in the 5 th minute and the heating temperature is increased by 1 ℃ in the 12 th minute. The following description will be given by taking the air conditioner in the heating mode and the preset parameters as dynamic instructions as a second example: referring to fig. 14, the original preset parameters include three preset sub-parameters, namely, the heating temperature is 22 ℃ at the initial time, the wind speed is the third gear, and the heating temperature is increased by 1 ℃ in the 7 th minute, the learning instruction includes two learning sub-instructions, namely, the heating temperature is decreased by 1 ℃ at the initial time, and the heating temperature is decreased by 2 ℃ in the 7 th minute, the preset temperature sub-parameters of the same parameter type as the learning instruction are integrated, the updated preset temperature sub-parameters include the heating temperature is 21 ℃ at the initial time, the heating temperature is decreased by 1 ℃ in the 7 th minute, and accordingly, the updated preset parameters include the heating temperature of 21 ℃ at the initial time, the wind speed is the third gear, and the heating temperature is decreased by 1 ℃ in the 7 th minute.

Further, referring to fig. 15, based on the above-mentioned embodiment of the control method of the remote controller of the present invention, in a seventh embodiment of the control method of the remote controller of the present invention, the preset parameter includes an air supply mode parameter, the remote controller further prestores a cooling temperature and a heating temperature, the cooling temperature is not less than the heating temperature, and the step S00 includes:

step S01, acquiring indoor environment temperature;

the remote controller is provided with a temperature sensor for acquiring the indoor temperature of the air conditioner. The remote controller should be located in the same indoor space as the air conditioner when controlling the air conditioner.

Step S02, when the indoor environment temperature is lower than the heating temperature, the remote controller sends out a control instruction that the air supply temperature is the heating temperature to control the air conditioner to operate according to the heating mode parameters;

step S03, when the indoor environment temperature is higher than the refrigeration temperature, the remote controller sends out a control instruction that the air supply temperature is the refrigeration temperature to control the air conditioner to operate according to the refrigeration mode parameters;

and step S04, when the indoor environment temperature is between the heating temperature and the cooling temperature, the remote controller sends a ventilation/dehumidification control instruction to control the air conditioner to operate according to the ventilation mode parameter/dehumidification mode parameter.

In this embodiment, the remote controller stores the parameters of the cooling temperature, the heating temperature and various air supply modes, the indoor temperature of the air conditioner is compared with the cooling temperature and the heating temperature respectively to serve as a judgment condition for the remote controller to send a control instruction to control the air conditioner to operate in the heating mode, the cooling mode or the ventilation mode/dehumidification mode, the air supply mode can be intelligently selected for a user, the user does not need to adjust the air supply mode, the operation of the user is simplified, the intelligent learning capability of the remote controller is improved, and the user experience is improved.

The invention also provides an embodiment of the remote controller.

In the first embodiment of the remote controller of the present invention, applied to the control of the operating parameters of the air conditioner, the remote controller 200 includes a timer 210, a temperature sensor 220, a signal transmitting module 230, a signal receiving module 240, a memory 250, a processor 260 and a computer program stored in and executable on the memory,

the timer 210 is configured to start timing when the remote controller sends a control instruction;

the temperature sensor 220 is used for acquiring indoor temperature;

the signal transmitting module 230 is configured to send a control instruction and an adjustment instruction to the air conditioner;

the signal receiving module 240 is configured to receive an adjustment instruction triggered by a user on a remote controller;

when executed by the processor, the computer program implements the steps of any of the first to seventh embodiments of the method for controlling a remote controller, which are not described herein again.

Embodiments of a computer-readable storage medium are also provided.

In the first embodiment of the computer-readable storage medium of the present invention, a control program of a remote controller is stored in the computer-readable storage medium, and when the control program of the remote controller is executed by a processor, the steps of any one of the first to seventh embodiments of the control method of the remote controller are implemented, which are not described herein again.

It should also be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

The above-mentioned serial numbers of the embodiments of the present invention are merely for description and do not represent the merits of the embodiments.

Through the above description of the embodiments, those skilled in the art will clearly understand that the method of the above embodiments can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware, but in many cases, the former is a better implementation manner. Based on such understanding, the technical solutions of the present invention may be embodied in the form of a software product, which is stored in a storage medium (e.g., ROM/RAM, magnetic disk, optical disk) and includes instructions for enabling a terminal device (e.g., a mobile phone, a computer, a server, or a network device) to execute the method according to the embodiments of the present invention.

The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. A control method of a remote controller is characterized in that preset parameters are prestored in the remote controller, the preset parameters comprise preset sub-parameters corresponding to different parameter types, the remote controller sends a control instruction to electronic equipment according to the preset parameters to control the electronic equipment to operate according to the control instruction, the operating parameters of the electronic equipment comprise operating sub-parameters of different parameter types, and the control method of the remote controller comprises the following steps:

recording an adjusting sub-instruction and a triggering time which are triggered by a user on a remote controller and are used for adjusting operation sub-parameters of electronic equipment within a preset time after the remote controller sends the control instruction, wherein the triggering time is a time interval from the remote controller to the remote controller after the control instruction is sent, generating the adjusting instruction of the parameter type according to the adjusting sub-instruction of the same parameter type and the triggering time corresponding to the adjusting sub-instruction, and the adjusting instructions of different parameter types form an adjusting instruction set;

when one or more learning instructions exist in a plurality of adjustment instruction sets recorded by continuous preset times, updating preset sub-parameters with the same parameter types as the learning instructions according to the one or more learning instructions and the triggering time of the corresponding learning instructions, so as to update the preset parameters.

2. The control method of a remote controller according to claim 1, wherein the operation parameters of the electronic device include operation sub-parameters of different parameter types; the recording of the adjustment instruction triggered by the user on the remote controller for adjusting the operating parameters of the electronic device within the preset time after the remote controller sends the control instruction includes the steps of:

3. The control method of a remote controller according to claim 1, wherein the preset parameters include preset sub-parameters of different parameter types; the step of updating the preset parameters according to the learning instruction comprises:

4. The control method of a remote controller according to claim 1, wherein the preset parameters include preset sub-parameters of different parameter types; the step of updating the preset parameters according to the learning instruction comprises:

5. The control method of the remote controller according to any one of claims 1 to 4, wherein the control method of the remote controller is applied to control of an operation parameter of an air conditioner, and the preset parameter includes at least one of an air supply mode parameter, a timing on/off parameter, a volume parameter, a light brightness parameter, a wind speed parameter, a wind direction parameter, and an electric auxiliary heating parameter;

6. The method as claimed in claim 5, wherein the preset parameter includes an air supply mode parameter, the remote controller further has a preset cooling temperature and a preset heating temperature, the cooling temperature is not less than the heating temperature, and the step of sending a control command to the electronic device by the remote controller according to the preset parameter to control the electronic device to operate according to the control command includes:

acquiring the indoor environment temperature;

7. A remote controller is applied to control the operation parameters of an air conditioner and is characterized by comprising a timer, a temperature sensor, a signal transmitting module, a signal receiving module, a memory, a processor and a computer program which is stored on the memory and can be operated on the processor,

the temperature sensor is used for acquiring indoor temperature;

the computer program realizes the steps of the control method of the remote control according to any one of claims 1-6 when executed by the processor.

8. A computer-readable storage medium, characterized in that the computer-readable storage medium has stored thereon a control program of a remote controller, which when executed by a processor implements the steps of the control method of the remote controller according to any one of claims 1-6.