WO2018188526A1

WO2018188526A1 - Terminal, lamp-based carbon offset processing system, and method thereof

Info

Publication number: WO2018188526A1
Application number: PCT/CN2018/082128
Authority: WO
Inventors: Jinxiang Shen; Hongliang AN
Original assignee: Sengled Co Ltd
Current assignee: Sengled Co Ltd
Priority date: 2017-04-10
Filing date: 2018-04-08
Publication date: 2018-10-18
Anticipated expiration: 2019-10-10
Also published as: CN106993044A; CN106993044B

Abstract

A terminal, a lamp-based carbon offset processing system, and a method thereof are provided. The terminal includes a controller, and a display module connected to the controller. The controller acquires a tree-planting request, where the tree-planting request includes tree-planting location information and a lamp identification. Based on the tree-planting request, the controller generates a virtual tree corresponding to the lamp identification at a virtual location characterized by the tree-planting location information, where the virtual tree corresponds to a planted tree at a geological location corresponding to the virtual location. The display module displays the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted.

Description

TERMINAL, LAMP-BASED CARBON OFFSET PROCESSING SYSTEM, AND METHOD THEREOF

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the priority to Chinese Patent Application No. 201710230289. X filed on April 10, 2017, the entire content of which is incorporated herein by reference.

TECHNICAL FIELD

The present disclosure generally relates to the technical field of terminals, and more particularly, relates to a terminal, a lamp-based carbon offset processing system, and a method thereof.

BACKGROUND

As the terminal technologies develop, terminals are widely used in people’s daily life and work. The terminal may include various types of application programs, such as game application programs, video application programs, audio application programs, office application programs, management application programs, and traveling application programs, etc.

Often lighting devices, i.e., various types of lamps, have been widely used in various fields such as public illumination in the cities, and indoor office and home lightning. Further, with the application of lamps, people’s awareness of energy savings has grown stronger and stronger.

However, in existing technologies, regarding the power consumption of various types of household appliances, only the overall power consumption can be viewed, and it is impossible to monitor and check the power consumption of the lamps.

BRIEF SUMMARY OF THE DISCLOSURE

The present disclosure provides a terminal, a lamp-based carbon offset processing system, and a method thereof, thereby solving the issue that in existing technologies, only the overall power consumption can be viewed regarding the power consumption of various types of household appliances, and it is impossible to monitor and check the power consumption of lamps.

One aspect of the present disclosure provides a terminal, comprising: a controller and a display module, where the controller is connected to the display module. The controller is configured to acquire a tree-planting request, where the tree-planting request includes tree-planting location information and a lamp identification. Based on the tree-planting request, the controller may generate a virtual tree corresponding to the lamp identification at a virtual location characterized by the tree-planting location information, where the virtual tree corresponds to a planted tree at a geological location corresponding to the virtual location.

The display module is configured to display the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree.

Another aspect of the present disclosure provides a lamp-based carbon offset processing system, including: a cloud server, a gateway, a terminal as described above, and at least one lamp. The cloud server is connected to the getaway, and the terminal and each of the at least one lamp is respectively connected to the getaway.

The cloud server is configured to acquire the power consumption of the lamps bound to the getaway, determine the lamp carbon dioxide emission amount of the lamp corresponding to the power consumption, and send the lamp carbon dioxide emission amount and the tree carbon dioxide adsorption amount to the terminal. Each two of a lamp, a virtual tree, and a planted tree are in one-to-one correspondence.

Another aspect of the present disclosure provides a lamp-based carbon offset processing method, including: acquiring, by a terminal, a tree-planting request, where the tree-planting request includes tree-planting location information and a lamp identification; based on the tree-planting request, generating, by the terminal, a virtual tree corresponding to the lamp identification at a virtual location characterized by the tree-planting location information, where the virtual tree corresponds to a planted tree at a geological location corresponding to the virtual location; displaying, by the terminal, the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree.

The technical effects of the present disclosure are as follows. A terminal is formed by a controller and a display module, where the controller is connected to the display module. The controller is configured to acquire a tree-planting request, where the tree-planting request includes tree-planting location information and a lamp identification. Based on the tree-planting request, the controller generates a virtual tree corresponding to the lamp identification at a virtual location characterized by the tree-planting location information, where the virtual tree corresponds to a planted tree at a geological location corresponding to the virtual location. The display module is configured to display the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree location. Accordingly, the user may check the lamp carbon dioxide emission amount corresponding to each lamp and the tree carbon dioxide adsorption amount of each real planted tree corresponding to each lamp through a tree-planting APP at the terminal, which enables the user to check the power consumption of each lamp. Further, an approach of displaying the lamp power consumption and carbon dioxide emission amount is provided, which enhances the user’s usage interest and improves the user experience.

BRIEF DESCRIPTION OF THE DRAWINGS

To more clearly illustrate the technical solutions in embodiments of the present disclosure or the prior art, the accompanying drawings of the present disclosure or the prior art are briefly introduced hereinafter. Obviously, the accompanying drawings merely provide certain exemplary implementations, based on which, other drawings or implementations may be obtainable by those ordinarily skilled in the art without creative effort.

FIG. 1 is a structural schematic view of a terminal consistent with embodiments of the present disclosure;

FIG. 2 is a schematic view of an interface of a terminal in use consistent with embodiments of the present disclosure;

FIG. 3 is a schematic view of another interface of a terminal in use consistent with embodiments of the present disclosure;

FIG. 4 is a schematic view of another interface of a terminal in use consistent with embodiments of the present disclosure;

FIG. 5 is a structural schematic view of another terminal consistent with embodiments of the present disclosure;

FIG. 6 is a schematic view of another interface of a terminal in use consistent with embodiments of the present disclosure;

FIG. 7 is a schematic view of another interface of a terminal in use consistent with embodiments of the present disclosure;

FIG. 8 is a schematic view of another interface of a terminal in use consistent with embodiments of the present disclosure;

FIG. 9 is a schematic view of another interface of a terminal in use consistent with embodiments of the present disclosure;

FIG. 10 is a schematic view of another interface of a terminal in use consistent with embodiments of the present disclosure;

FIG. 11 is a schematic view of another interface of a terminal in use consistent with embodiments of the present disclosure;

FIG. 12 is a schematic view of another interface of a terminal in use consistent with embodiments of the present disclosure;

FIG. 13 is a schematic view of another interface of a terminal in use consistent with embodiments of the present disclosure;

FIG. 14 is a structural schematic view of a lamp-based carbon offset processing system, consistent with embodiments of the present disclosure;

FIG. 15 is a structural schematic view of an interface of a terminal of a lamp-based carbon offset processing system that is in use, consistent with embodiments of the present disclosure;

FIG. 16 is a flow chart of a lamp-based carbon offset processing method consistent with embodiments of the present disclosure;

FIG. 17 is a flow chart of another lamp-based carbon offset processing method consistent with embodiments of the present disclosure;

FIG. 18 is a flow chart of another lamp-based carbon offset processing method consistent with embodiments of the present disclosure;

FIG. 19 is a flow chart of another lamp-based carbon offset processing method consistent with embodiments of the present disclosure;

FIG. 20 is a flow chart of another lamp-based carbon offset processing method consistent with embodiments of the present disclosure; and

FIG. 21 is a flow chart of another lamp-based carbon offset processing method consistent with embodiments of the present disclosure.

In the accompanying drawings:

DETAILED DESCRIPTION

To make the objectives, technical solutions, and advantages of the present disclosure clearer, with reference to the accompanying drawings of the present disclosure, technical solutions of the present disclosure are described more fully hereinafter. Obviously, the disclosed embodiments only provide some exemplary implementations. Based on the disclosed embodiments, other embodiments obtainable by those ordinarily skilled in the relevant art without creative labor shall all fall within the protection scope of the present disclosure.

FIG. 1 is a structural schematic view of a terminal consistent with embodiments of the present disclosure. As shown in FIG. 1, the disclosed terminal 1 includes a controller 2 and a display module 3, where the controller 2 is connected to the display module 3. The controller 2 is configured to acquire a tree-planting request, where the tree-planting request includes tree-planting location information and a lamp identification. Based on the tree-planting request, the controller 2 generates a virtual tree corresponding to the lamp identification at a virtual location characterized by the tree-planting location information, where the virtual tree corresponds to a planted tree at a geological location corresponding to the virtual location.

The display module 3 is configured to display the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree.

In some embodiments, the user may purchase and install a plurality of lamps, and the user may respectively bind and connect all lamps to one getaway. Further, the terminal 1 of the user may be bound to the getaway. In one embodiment, the terminal 1 may be a mobile terminal, or an immobilized terminal, such as a smart phone, a tablet, a notebook, or a desktop, etc. A cloud server may be provided for connection to the getaway. The connection manner between the each two of the aforementioned devices may be a wired connection or a wireless connection.

A tree-planting application (APP) may be configured at the terminal 1, and in the tree-planting APP, the user may acquire tree-planting opportunities. For each tree, there may be one tree-planting opportunity. That is, in the tree-planting APP, one lamp connected to the getaway may correspond to one virtual tree.

The tree-planting APP may be an application based on a map, with virtual trees planted at various locations. For example, the tree-planting APP may be a map-based application that enables the user to select a tree-planting location from various tree-planting locations shown in the map.

In some example, the various tree-planting locations may be large regions such as the African continent and Asian continent, and when the user selects a tree-planting location (e.g., the African continent) , a virtual tree may be generated at a specific location defined by the geographic coordinate system within the selected tree-planting location. In some other examples, the various tree-planting locations may be specific locations defined by corresponding addresses or the geographic coordinate system, and when the user selects a tree-planting location, a virtual tree may be generated at the selected tree-planting location.

That is, the map used in the tree-planting APP can be a real map. Further, the map may be, for example, designed to be a 2D-map, 3D-map, or a map with augmented reality (AR) elements (e.g., virtual trees) . Optionally, in certain cases, the map may be a fictional map created by the user or created based on a computer game application, and the present disclosure is not limited thereto.

In one embodiment, the terminal 1 may be formed by the controller 2 and the display module 3, where the controller 2 is connected to the display module 3. The tree-planting APP at the terminal 1 may display lamp-adding information at a first interaction interface thereof, such that the user may purchase and add desired lamp (s) to his or her account after getting to know there are newly-added lamps at the getaway.

FIG. 2 is a schematic view of an interface of a terminal in use consistent with embodiments of the present disclosure. As shown in FIG. 2, the tree-planting APP of the terminal 1 may display a first interaction interface, and notification information may be displayed at the first interaction interface to prompt the user whether or not to plant a tree. Further, the user may select a lamp that needs tree-planting at the first interaction interface, and the terminal 1 may determine the lamp identification of the lamp selected for tree-planting based on the selection of the user at the first interaction interface. Under such situation, the number of virtual trees available to plant may be equal to the number of lamps that the user selects for tree-planting. The controller 2 of the terminal 1 may acquire the lamp identification (s) of the lamp (s) selected and input by the user for tree-planting at the first interaction interface.

FIG. 3 is a schematic view of another interface of a terminal in use consistent with embodiments of the present disclosure. As shown in FIG. 3, the tree-planting APP of the terminal 1 may display a second interaction interface, a plurality of tree-planting locations may be displayed at the second interaction interface, and the user may select a tree-planting location at the second interaction interface. For example, the tree-planting locations may include regions such as North America, South America, Africa, and Asia. Optionally, an image representing each region may be displayed corresponding to the tree-planting locations.

Further, the controller 2 of the terminal 1 may acquire a tree-planting location selected by the user at the second interaction interface, and thus the controller 2 obtains the tree-planting location information. Further, the controller 2 may obtain a tree-planting request including the tree-planting location information and the lamp identification. The controller 2 of the terminal 1 may generate a virtual tree corresponding to the lamp identification at a virtual location characterized by the tree-planting location information. A tree may be planted at a geological location corresponding to the virtual location, and the tree planted at the geological location corresponding to the virtual location may be a real planted tree.

That is, a production and service department of the lamps may plant a real tree at a real tree-planting location based on the tree-planting location selected by the user at the tree-planting APP. In other words, one virtual tree may correspond to one real planted tree, and the generated virtual tree corresponds to the planted tree that corresponds to the virtual location of the virtual tree. Each two of a lamp, a virtual tree, and a planted tree are in one-to-one correspondence. Further, the controller 2 of the terminal 1 may send the virtual tree information of the generated virtual tree, and the planted tree information of the planted tree corresponding to the virtual tree to the display module 3.

Further, during the period when the lamp is on, the cloud server may, through the getaway, acquire the power consumption of each lamp bound to the getaway. Further, the cloud server may calculate the lamp carbon dioxide emission amount of each lamp based on the power consumption of each lamp. Each two of a lamp, a virtual tree, and a planted tree are in one-to-one correspondence. The cloud server may acquire the tree carbon dioxide adsorption amount of the planted tree corresponding to each virtual tree. Further, the cloud server may send the lamp carbon dioxide emission amount of each lamp and the tree carbon dioxide adsorption amount of the planted tree corresponding to each virtual tree to the terminal 1 that is bound to the getaway.

After the terminal 1 receives the lamp carbon dioxide emission amount of each lamp and the tree carbon dioxide adsorption amount of the planted tree corresponding to each virtual tree, the controller 2 of the terminal 1 may map the lamp carbon dioxide emission amount of each lamp and the tree carbon dioxide adsorption amount of the planted tree corresponding to each virtual tree to the virtual tree respectively corresponding to each lamp at the tree-planting APP.

FIG. 4 is a schematic view of another interface of a terminal in use consistent with embodiments of the present disclosure. As shown in FIG. 4, the display module 3 displays a virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree corresponding to the virtual tree at a third interaction interface of the tree-planting APP.

As such, the terminal 1 may be formed by including the controller 2 and the display module 3, where the controller 2 is connected to the display module 3. The controller 2 is configured to acquire a tree-planting request, where the tree-planting request includes tree-planting location information and a lamp identification; based on the tree-planting request, a virtual tree corresponding to the lamp identification is generated at a virtual location characterized by the tree-planting location information, where the virtual tree corresponds to a planted tree at a geological location corresponding to the virtual location. The display module 3 is configured to display the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree location.

Accordingly, the user may check the lamp carbon dioxide emission amount corresponding to each lamp through a tree-planting APP at the terminal 1, which enables the user to check the power consumption of each lamp. Further, an approach of displaying lamp power consumption and lamp carbon dioxide emission amount is provided, which enhances the user’s usage interests and improves the user experience.

FIG. 5 is a structural schematic view of another terminal consistent with embodiments of the present disclosure. As shown in FIG. 5, the present disclosure provides a terminal 1, and the terminal 1 may include a controller 2, a display module 3, and a user interface 4. The controller 2 may be connected to the display module 3, and the display module 3 may be connected to the user interface 4. Optionally, the terminal 1 may further include a sensor 9, a microphone 10, or a first memory 7, or any combination thereof.

The display module 3 may include a display screen module 5 and a printed circuit board (PCB) 6. The PCB 6 may be connected to the display screen module 5. The controller 2 may include a controlling chip 8.

Despite the aforementioned functions, the display module 3 may be further configured to display planting-notification information, where the planting-notification information characterizes the lamp without a generated virtual tree, thereby prompting the user whether or not to check the condition of the virtual tree.

The user interface 4 is configured to receive an examination request sent by the user. The display module 3 may be further configured to display virtual tree information based on the examination request, where the virtual tree information includes the lamp (s) without a generated virtual tree and the lamp (s) with a generated virtual tree.

The display screen module 5 may be configured to display a transition animation information after displaying the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree. The transition animation information may include tree information of various virtual trees, and the tree information may include virtual tree information, and planted tree information of the planted tree corresponding to the virtual tree.

In some embodiments, the terminal may include a first memory 7, and the first memory 7 may be connected to the controller 2 and the display module 3, respectively. The controller 2 may be further configured to generate an image of a tree-planting certificate after displaying the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree at the display module 3. The image of the planted tree certificate may include at least one of the following types of information: the total amount of the currently generated virtual trees, types of various planted trees corresponding to the currently generated virtual trees in one-to-one correspondence, tree-planting location information of various planted trees corresponding to the currently generated virtual trees in one-to-one correspondence, generation time of the currently generated virtual trees, and planting time of the planted trees corresponding to the currently generated virtual trees in one-to-one correspondence.

The display module 3 may be further configured to display the image of the planted tree certificate, and display saving-notification information, thereby prompting the user whether or not to save the image of the planted tree certificate. The user interface 4 may be further configured to acquire a saving request sent by the user, and send the saving request to the first memory 7. The first memory 7 may be configured to save the image of the planted tree certificate based on the saving request.

In some embodiments, the controller 2 may include a controlling chip 8. The display module 3 may be further configured to display sharing-notification information after displaying the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree, thereby prompting the user whether or not to share a current tree-planting status. The sharing-notification information may include links to at least one sharing-platform, virtual tree information of the virtual tree corresponding to the lamp characterized by the current tree-planting status, the planted tree information of the planted tree corresponding to the virtual tree, lamp carbon dioxide emission amount of the lamp, and the tree carbon dioxide adsorption amount of the planted tree.

The user interface 4 may be further configured to receive a sharing request of the user, where the sharing request includes a sharing-platform identification. The controlling chip 8 is configured to, based on the sharing request, share the current tree-plating status to the sharing platform corresponding to the sharing-platform identification according to the link to the sharing platform corresponding to the sharing-platform identification.

In some embodiments, the terminal 1 may further include a sensor 9, where the sensor 9 is connected to the controller 2. The controller 2 is further configured to, after displaying the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree, determine whether the lamp carbon dioxide emission amount is greater than or equal to the tree carbon dioxide adsorption amount. If the lamp carbon dioxide emission amount is determined to be greater than or equal to the tree carbon dioxide adsorption amount, the controller 2 may generate first notification information.

The display module 3 is further configured to display the first notification information, thereby prompting the user whether or not to adjust the lamp. The sensor 9 is configured to receive an action status sent by the user, and send the action status to the controller 2. The controller 2 is further configured to generate a first lamp-adjusting command based on the action status. The first lamp-adjusting command may include a lamp identification, and the first lamp-adjusting command is at least one of the followings: lamp turning-off command, lamp brightness-adjusting command, and lamp color-adjusting command. The controller 2 may further send the first lamp-adjusting command to the lamp corresponding to the lamp identification in the first lamp-adjusting command through the getaway and the cloud server, thus allowing the lamp to execute an operation corresponding to the first lamp-adjusting command.

In some embodiments, the terminal may further include a microphone 10, where the microphone 10 is connected to the controller 2. The controller 2 is further configured to, after displaying the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree, determine whether the lamp carbon dioxide emission amount is greater than or equal to the tree carbon dioxide adsorption amount. If the lamp carbon dioxide emission amount is determined to be greater than or equal to the tree carbon dioxide adsorption amount, the controller 2 may generate second notification information.

Correspondingly, the display module 3 may be further configured to display the second notification information, thereby prompting the user whether or not to adjust the lamp. The microphone 10 is configured to receive audio information sent by the user, and send the audio information to the controller 2. The controller 2 is further configured to generate a second lamp-adjusting command based on the audio information. The second lamp-adjusting command may include the lamp identification, and the second lamp-adjusting command may be at least one of the followings: lamp turning-off command, lamp brightness-adjusting command, and lamp color-adjusting command.

The controller 2 may be further configured to send the second lamp-adjusting command to the lamp corresponding to the lamp identification in the second lamp-adjusting command through the getaway and the cloud server, thus allowing the lamp to execute an operation corresponding to the second lamp-adjusting command.

The user interface 4 may include any one of the followings: manipulator, interface input module, and keyboard. The user interface 4 is further configured to receive a query command sent by the user, where the query command instructs and inquires the total number of virtual trees and the total number of users participating in planting the virtual trees, and to send the query command to the controller 2. The controller 2 is further configured to, based on the query command, determine the total number of virtual trees and the total number of users participating in planting the virtual trees. The display module 3 is further configured to display the total number of virtual trees and the total number of users participating in planting the virtual trees.

As such, the terminal 1 may be further configured with the user interface 4, and the display module 3 may be connected to the user interface 4. The user interface 4 includes any one of the followings: manipulator, interface input module, and keyboard. The display module 3 of the disclosed terminal 1 may include the display screen module 5 and the PCB 6, where the PCB 6 is connected to the display screen module 5.

In one embodiment, the display module 3 may display a transition animation after displaying the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree at a third interaction interface of the tree-planting APP. For example, FIG. 6 is a schematic view of such interface of a terminal in use consistent with embodiments of the present disclosure.

As shown in FIG. 6, the display screen module 5 of the terminal 1 may display the transition animation information at a fourth interaction interface of the tree-planting APP. The transition animation information may include the tree information of various virtual trees, and the tree information may include virtual tree information, and planted tree information of the planted tree corresponding to the virtual tree.

Further, the terminal 1 may be configured with the first memory 7. The first memory 7 may be connected to the controller 2 and the display module 3, respectively. After the display screen module 5 of the terminal 1 displays the transition animation information at the fourth interaction interface of the tree-planting APP, the controller 2 of the terminal 1 may generate an image of a planted tree certificate. The image of the planted tree certificate may include at least one of the following types of information: the total amount of the currently generated virtual trees, types of various planted trees corresponding to the currently generated virtual trees in one-to-one correspondence, tree-planting location information of various planted trees corresponding to the currently generated virtual trees in one-to-one correspondence, generation time of the currently generated virtual trees, and planting time of the planted trees corresponding to the currently generated virtual trees in one-to-one correspondence.

FIG. 7 is a schematic view of another interface of a terminal in use consistent with embodiments of the present disclosure. As shown in FIG. 7, the display module 3 of the terminal 1 displays the image of the planted tree certificate at a fifth interaction interface of the tree-planting APP, and displays saving-notification information to notify the user whether or not to save the image of the planted tree certificate. Further, the user may input a saving request at the fifth interaction interface, and the user interface 4 of the terminal 1 may acquire the saving request sent by the user. Further, the user interface 4 of the terminal 1 may send the saving request to the first memory 7 of the terminal 1, and the first memory 7 of the terminal 1 may save the image of the planted tree certificate based on the saving request.

Further, the controller 2 of the terminal 1 may include the controlling chip 8. After the display module 3 displays the image of the planted tree certificate at the fifth interaction interface of the tree-planting APP, FIG. 8 shows a schematic view of another interface of a terminal in use consistent with embodiments of the present disclosure.

As shown in FIG. 8, the display module 3 of the terminal 1 may display sharing-notification information at a sixth interaction interface of the tree-planting APP, thereby prompting the user whether or not to share the current tree-planting status. The sharing-notification information may include links to at least one sharing-platform (e.g., the link to Weibo and the link to WeChat) , virtual tree information of the virtual tree corresponding to the lamp characterized by the current tree-planting status, the planted tree information of the planted tree corresponding to the virtual tree, the lamp carbon dioxide emission amount of the lamp, and the tree carbon dioxide adsorption amount of the planted tree.

Further, the user may select a sharing-platform at the sixth interaction interface, and the user may further input the sharing request at the sixth interaction interface. The user interface 4 of the terminal 1 may receive the sharing request of the user, where the sharing request may include sharing-platform identification. Further, the controlling chip 8 may acquire the sharing request at the user interface 4. The controlling chip 8 may, based on the sharing request, share the current tree-plating status to the sharing platform corresponding to the sharing-platform identification according to the link to the sharing platform corresponding to the sharing-platform identification. If the user selects no sharing-platform at the sixth interaction interface, the current tree-planting process may be ended.

During any of the aforementioned processes, if the user re-enters the tree-planting APP of the terminal 1, FIG. 9 is a schematic view of another interface of a terminal in use consistent with embodiments of the present disclosure. As shown in FIG. 9, the terminal 1 may display a tree-planting main interface at a seventh interaction interface of the tree-planting APP, and the user may thus enter the tree-planting APP.

FIG. 10 is a schematic view of another interface of a terminal in use consistent with embodiments of the present disclosure. As shown in FIG. 10, the display module 3 of the terminal 1 may display planting-notification information at an eighth interaction interface of the tree-planting APP, and the planting-notification information characterizes the lamp without a generated virtual tree, thereby prompting the user whether or not to check the condition of the virtual tree.

For example, a red lamp may be displayed at the eighth interaction interface, and the red lamp may characterize the lamp without a generated virtual tree. The user may click to enter an interaction sub-interface within the red lamp, and further check the virtual tree planting condition. The user may input the examination request at the eighth interaction interface, and the user interface 4 of the terminal 1 may receive the examination request sent by the user.

FIG. 11 is a schematic view of another interface of a terminal in use consistent with embodiments of the present disclosure. As shown in FIG. 11, the display module 3 of the terminal 1 may display the virtual tree planting information at a ninth interaction interface of the tree-planting APP, and the virtual tree planting information may include a lamp without generated virtual tree, and a lamp with generated virtual tree.

During any of the aforementioned processes, the user interface 4 of the terminal 1 may receive a query command sent by the user, where the query command instructs and inquires the total number of virtual trees and the total number of users participating in planting the virtual trees. The controller 2 of the terminal 1 may acquire the query command, and the controller 2 may send the query command to the cloud server through the getaway. The cloud server may, based on the query command, determine the total number of virtual trees and the total number of users participating in planting the virtual trees.

Further, a processor of the cloud server may send the total number of virtual trees and the total number of users participating in planting the virtual trees to the terminal 1 via the getaway. After the terminal 1 receives the total number of virtual trees and the total number of users participating in planting the virtual tree, the display module 3 of the terminal 1 may display the total number of virtual trees and the total number of users participating in planting the virtual tree.

Further, the disclosed terminal 1 may provide a sensor 9, and the sensor 9 may be connected to the controller 2. The display module 3 of the terminal 1 may display the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree. The controller 2 may determine whether the lamp carbon dioxide emission amount is greater than or equal to the tree carbon dioxide adsorption amount. If the controller 2 determines that the lamp carbon dioxide emission amount is greater than or equal to the tree carbon dioxide adsorption amount, the controller 2 generates the first notification information.

FIG. 12 is a schematic view of another interface of a terminal in use consistent with embodiments of the present disclosure. As shown in FIG. 12, the display module 3 of the terminal 1 may display the first notification information, thereby prompting the user whether or not to adjust the lamp. Further, the user may generate an action status, and the sensor 9 may acquire the action status of the user and send the action status to the controller 2. The controller 2 may generate a first lamp-adjusting command corresponding to the action status based on the action status.

The first lamp-adjusting command may include the lamp identification, and the first lamp-adjusting command may be at least one of the followings: lamp turning-off command, lamp brightness-adjusting command, and lamp color-adjusting command. In some embodiments, the hand-raising action may be the action status of the user, and the controller 2 may generate a lamp turning-off command corresponding to the hand-raising action. In some other embodiments, the head-shaking action may be the action status of the user, and the controller 2 may generate a brightness-lowering command corresponding to the head-shaking action. That is, the hand-raising action may correspond to the lamp turning-off command, and the head-shaking action may correspond to the brightness-lowering command.

Further, the controller 2 may send the first lamp-adjusting command to the lamp corresponding to the lamp identification in the first lamp-adjusting command through the getaway and the cloud server, thus allowing the lamp to execute an operation corresponding to the first lamp-adjusting command. Or, the disclosed terminal 1 may provide a microphone 10, and the microphone 10 may be connected to the controller 2. After the display module 3 of the terminal 1 displays the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree, the controller 2 determines whether the lamp carbon dioxide emission amount is greater than or equal to the tree carbon dioxide adsorption amount. If the lamp carbon dioxide emission amount is determined to be greater than or equal to the tree carbon dioxide adsorption amount, the controller 2 may generate second notification information.

FIG. 13 is a schematic view of another interface of a terminal in use consistent with embodiments of the present disclosure. As shown in FIG. 13, the display module 3 of the terminal 1 may display the second notification information at an eleventh interaction interface of the tree-planting APP, thereby prompting the user whether or not to adjust the lamp. The user may send audio information, and the microphone 10 may receive the audio information sent by the user and further, send the audio information to the controller 2.

The controller 2 may generate a second lamp-adjusting command based on the audio information. The second lamp-adjusting command may include the lamp identification, and the second lamp-adjusting command may include at least one of the followings: lamp turning-off command, lamp brightness-adjusting command, and lamp color-adjusting command. The controller 2 may send the second lamp-adjusting command to the lamp corresponding to the lamp identification in the second lamp-adjusting command through the getaway and the cloud server, thus allowing the lamp to execute an operation corresponding to the second lamp-adjusting command.

Alternatively, after the display module 3 of the terminal 1 displays the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree, the controller 2 may determine whether the lamp carbon dioxide emission amount is greater than or equal to the tree carbon dioxide adsorption amount. If the controller 2 determines that the lamp carbon dioxide emission amount is greater than or equal to the tree carbon dioxide adsorption amount, the controller 2 may generate a third lamp-adjusting command.

As such, the terminal 1 may include the controller 2 and the display module 3, where the controller 2 is connected to the display module 3. The controller 2 is configured to acquire a tree-planting request, where the tree-planting request includes tree-planting location information and a lamp identification. Based on the tree-planting request, a virtual tree corresponding to the lamp identification is generated at a virtual location characterized by the tree-planting location information, where the virtual tree corresponds to a planted tree at a geological location corresponding to the virtual location.

The display module 3 is configured to display the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree. Accordingly, the user may check the lamp carbon dioxide emission amount corresponding to each lamp and the tree carbon dioxide adsorption amount of each real planted tree through the tree-planting APP at the terminal 1, which enables the user to check the power consumption of each lamp. Further, an approach of displaying the power consumption of the lamp and lamp carbon dioxide emission amount is provided, which enhances the user’s usage interests and improves the user experience.

Further, the terminal 1 may display the lamp-adding information, display the planting-notification information, display the virtual tree corresponding to the lamp identification and the carbon dioxide amount of the virtual tree, display the transition animation information, display the image of the planted tree certificate, and display the sharing-notification information.

Further, the terminal 1 may generate a lamp-adjusting command when it is determined that the lamp carbon dioxide emission amount is greater than or equal to the tree carbon dioxide adsorption amount of the planted tree corresponding to the lamp. The terminal 1 may further send the lamp-adjusting command to the lamp through the getaway and the cloud server, thus allowing the lamp to execute an operation corresponding to the lamp-adjusting command. Accordingly, the objective of adjusting the brightness and the color of the lamp may be achieved, which further reduces the power consumption amount of the lamp, thereby saving the energy resources.

FIG. 14 is a structural schematic view of a lamp-based carbon offset processing system, consistent with embodiments of the present disclosure. As shown in FIG. 14, the disclosed system may include a cloud server 11, a getaway 12, a terminal 1, and at least one lamp 13. In one embodiment, the system may include two lamps 13. In other embodiment, the system may include more than two lamps 13. Optionally, the cloud server 11 may include a communication interface 14, a processor 15, or a second memory 16, or any combination thereof.

Further, terminal 1 may be any of the aforementioned terminals. For example, the terminal 1 may include a controller 2, a display module 3, a user interface 4, a first memory 7, a sensor 9, and a microphone 10. The controller 2 may be connected to the display module 3, and the display module 3 may be connected to the user interface 4. The controller 2 may include a controlling chip 8. The display module 3 may include a display screen module 5 and a printed circuit board (PCB) 6, and the PCB 6 may be connected to the display screen module 5.

The cloud server 11 may be configured to acquire the power consumption of each lamp 13 bound to the getaway 12, determine the lamp carbon dioxide emission amount corresponding to the power consumption, determine the tree carbon dioxide adsorption amount of a planted tree corresponding to the lamp 13, and send the lamp carbon dioxide emission amount and the tree carbon dioxide adsorption amount to the terminal 1. Each two of a lamp 13, a virtual tree, and a planted tree are in one-to-one correspondence.

In some embodiments, the cloud server 11 includes the communication interface 14 and the processor 15. The communication interface 14 may be connected to the getaway 12 and the processor 15, respectively. The communication interface 14 may be configured to receive a lamp binding request sent by the getaway 12, where the lamp binding request is sent after the getaway 12 detects that the lamp 13 is connected to the getaway 12. The lamp binding request may include a lamp identification and a getaway identification.

The processor 15 may be configured to acquire the lamp binding request received by the communication interface 14, determine the terminal 1 corresponding to the getaway identification based on the lamp binding request, and add the lamp identification to the terminal 1. The processor 15 may further send lamp-adding information to the terminal 1, thus allowing the terminal 1 to display newly-added lamp information. The lamp-adding information may include the lamp identification, and the newly-added lamp information may represent that the getaway 12 includes a newly-added lamp 13.

The cloud server 11 may further include the second memory 16, and the second memory 16 may be connected to the processor 15. The processor 15 may be further configured to receive the first lamp-adjusting command or the second lamp-adjusting command sent by the terminal 1 through the getaway 12. The processor 15 may further send the first lamp-adjusting command or the second lamp-adjusting command to the lamp 13 indicated by the first lamp-adjusting command or the second lamp-adjusting command through the getaway 12, thus allowing the lamp 13 to execute an operation corresponding to the lamp-adjusting command. The second memory 16 may be configured to receive and store the lamp-adjusting command sent by the processor 15.

In one embodiment, based on FIG. 5, an example of a lamp-based carbon offset processing system is introduced hereinafter. The user may purchase and install a plurality of lamps 13, and the plurality of lamps 13 may be bound and connected to the getaway 12, respectively. Further, the terminal 1 of the user may be bound and connected to the getaway 12, and the cloud server 11 may be provided. The cloud server 11 may be connected to the getaway 12. The connection manner between the aforementioned devices may be a wired connection, or a wireless connection.

Further, during the period where the lamp 13 is on, the cloud server 11 may acquire the power consumption of each lamp 13 bound to the getaway 12 through the getaway 12. Further, the cloud server 11 may calculate the lamp carbon dioxide emission amount of each lamp 13 based on the power consumption of each lamp 13. Each two of a lamp, a virtual tree, and a planted tree are in one-to-one correspondence, and the cloud server 11 may acquire the tree carbon dioxide adsorption amount of the planted tree corresponding to each virtual tree. Further, the cloud server 11 may send the lamp carbon dioxide emission amount of each lamp 13 and the tree carbon dioxide adsorption amount of each planted tree corresponding to each virtual tree to the terminal 1 that is bound to the getaway 12.

For example, a power consumption of 1 kWh may equal to a lamp carbon dioxide emission amount of 0.702766 kg. Thus, given the power consumption of x kWh, the processor 15 of the cloud server 11 may determine the lamp carbon dioxide emission amount A of the lamp 13 to be x*0.702766 kg.

Given the tree carbon dioxide adsorption amount of one tree during 10 years to be 18213 kg, the processor 15 of the cloud server 11 may calculate the tree carbon dioxide adsorption amount B of a planted tree to be B= (18213 kg÷365÷10) *y, where y is the number of planting days of the planted tree. Specifically, the value of 18213 kg÷365÷10 may be calculated, that is, the daily tree carbon dioxide adsorption amount of a planted tree may be calculated. Given such calculated value and the number of planting days y of the planted tree, the processor 15 may acquire the tree carbon dioxide adsorption amount B of each planted tree corresponding to the virtual tree.

Further, the cloud server 11 may include the communication interface 14 and the processor 15. The communication interface 14 may be connected to the getaway 12 and the processor 15, respectively. The terminal 1 herein may be same as or similar to the aforementioned terminal. The structure and principles of the terminal 1 may refer to aforementioned descriptions, and repeated descriptions are not provided herein.

When the getaway 12 detects that the lamp 13 is connected to the getaway 12, the getaway 12 may send a lamp binding request to the communication interface 14 of the cloud server 11. The communication interface 14 of the cloud server 11 may receive a lamp binding request sent by the getaway 12, and the lamp binding request may include a lamp identification and a getaway identification.

The processor 15 of the cloud server 11 may be configured to acquire the lamp binding request received by the communication interface 14, determine the terminal 1 corresponding to the getaway identification based on the lamp binding request, and add the lamp identification to the terminal 1. The processor 15 of the cloud server 11 may send the lamp-adding information to the terminal 1 through the communication interface 14 and the getaway 12, where the lamp-adding information may include the lamp identification. The terminal 1 may receive newly-added lamp information, where the newly-added lamp information represents that the getaway 12 includes a newly-added lamp 13.

In some embodiments, the user interface 4 of the terminal 1 may receive a query command sent by the user, where the query command instructs and inquires the total number of virtual trees and the total number of users participating in planting the virtual trees. The controller 2 of the terminal 1 may acquire the query command, and the controller 2 may send the query command to the cloud server through the getaway. The cloud server 11 may, based on the query command, determine the total number of virtual trees and the total number of users participating in planting the virtual trees.

Further, the processor 15 may send the total number of virtual trees and the total number of users participating in planting the virtual trees to the terminal 1 via the getaway 12. After the terminal 1 receives the total number of virtual trees and the total number of users participating in planting the virtual tree, the display module 3 of the terminal 1 may display the total number of virtual trees and the total number of users participating in planting the virtual tree.

FIG. 15 is a structural schematic view of an interface of a terminal of a lamp-based carbon offset processing system that is under use, consistent with embodiments of the present disclosure. As shown in FIG. 15, the tree-planting APP of the terminal 1 may display lamp-adding information at a twelfth interaction interface, thus enabling the user to know that the getaway 12 includes a newly-added lamp 13.

The cloud server 11 may further include the second memory 16. The second memory 16 may be connected to the processor 15. After the display module 3 of the terminal 1 displays the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp 13 corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree, the controller 2 of the terminal 1 may determine whether the lamp carbon dioxide emission amount is greater than or equal to the tree carbon dioxide adsorption amount. If the controller 2 of the terminal 1 determines that the lamp carbon dioxide emission amount is greater than or equal to the tree carbon dioxide adsorption amount, the controller 2 may generate the first lamp-adjusting information or the second lamp-adjusting information based on the user’s choice.

Further, the controller 2 of the terminal 1 sends the first or second lamp-adjusting command to the processor 15 of the cloud server 11 through the getaway 12. The processor 15 of the cloud server 11 may send the first lamp-adjusting information or the second lamp-adjusting information to the lamp 13 indicated by the first lamp-adjusting information or the second lamp-adjusting information through the getaway 12. Thus, the lamp 13 may perform operations such as turning off the lamp, increasing or decreasing the lamp brightness, or changing the color of the light based on the first lamp-adjusting information or the second lamp adjusting information. Further, the second memory 16 of the cloud server 11 may receive and store the first lamp-adjusting information or the second lamp-adjusting information sent by the processor 15.

As such, a carbon offset processing system including a cloud server 11, a gateway 12, a terminal 1 described in aforementioned embodiments, and at least one lamp 13 is provided. The cloud server 11 may be connected to the getaway 12, and the terminal 1 and each lamp 13 may be connected to the getaway 12, respectively. The cloud server 11 may be configured to acquire the power consumption of each lamp 13 bound to the getaway 12, determine the lamp carbon dioxide emission amount corresponding to the power consumption, determine the tree carbon dioxide adsorption amount of the planted tree corresponding to the lamp 13, and send the lamp carbon dioxide emission amount and the tree carbon dioxide adsorption amount to the terminal 1. Each two of a lamp 13, a virtual tree, and a planted tree are in one-to-one correspondence.

Accordingly, the user may check the lamp carbon dioxide emission amount corresponding to each lamp and the tree carbon dioxide adsorption amount of each real planted tree through the tree-planting APP at the terminal 1, which enables the user to check the power consumption of each lamp. Further, an approach of displaying lamp power consumption and lamp carbon dioxide emission amount is provided, which enhances the user’s usage interests and improves the user experience.

Further, the terminal 1 may display the newly-added lamp information, display the planting-notification information, display the virtual tree corresponding to the lamp identification and the carbon dioxide amount of the virtual tree, display the transition animation information, display the image of the planted tree certificate, and display the sharing-notification information. Thus, a virtual tree-planting system and process based on the lamp 13 are provided to the user.

Further, the terminal 1 may generate a lamp-adjusting command when it is determined that the lamp carbon dioxide emission amount corresponding to the lamp 13 is greater than or equal to the tree carbon dioxide adsorption amount of the planted tree corresponding to the lamp 13. The terminal 1 may further send the lamp-adjusting command to the lamp 13 through the getaway 12 and the cloud server 11, thus allowing the lamp 13 to execute an operation corresponding to the lamp-adjusting command. Accordingly, the objective of adjusting the brightness and the color of the lamp 13 may be achieved, which further reduces the power consumption amount of the lamp 13, thereby saving the energy resources.

FIG. 16 is a flow chart of a lamp-based carbon offset processing method consistent with embodiments of the present disclosure. As shown in FIG. 16, the method includes the followings.

At S101, a terminal acquires a tree-planting request, where the tree-planting request includes tree-planting location information and a lamp identification.

At S102, the terminal generates a virtual tree corresponding to the lamp identification at a virtual location characterized by the tree-planting location information, where the virtual tree corresponds to a planted tree at a geological location corresponding to the virtual location.

At S103, the terminal displays the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree.

The detailed descriptions of the disclosed method may refer to the terminal and the lamp-based carbon offset processing system provided in the aforementioned embodiments, which are not repeated herein.

As such, the terminal acquires the tree-planting request, where the tree-planting request includes tree-planting location information and a lamp identification. Based on the tree-planting request, the terminal generates a virtual tree corresponding to the lamp identification at a virtual location characterized by the tree-planting location information, where the virtual tree corresponds to a planted tree at a geological location corresponding to the virtual location. The terminal displays the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree location. Accordingly, the user may check the lamp carbon dioxide emission amount corresponding to each lamp and the tree carbon dioxide adsorption amount of the real planted tree corresponding to each lamp through a tree-planting APP at the terminal, which enables the user to check the power consumption of each lamp. Further, an approach of displaying lamp power consumption and the lamp carbon dioxide emission amount is provided, which enhances the user’s usage interests and improves the user experience.

FIG. 17 is a flow chart of another lamp-based carbon offset processing method consistent with embodiments of the present disclosure. As shown in FIG. 17, in the disclosed method, before S101, the method may further include the followings.

At S201, the cloud server receives a lamp binding request sent by the getaway, where the lamp binding request is sent after the getaway detects that the lamp is connected to the getaway. The lamp binding request may include a lamp identification and a getaway identification.

At S202, the cloud server determines the terminal corresponding to the getaway identification based on the lamp binding request, and adds the lamp identification to the terminal, and send the lamp-adding information to the terminal, thereby allowing the terminal to display the newly-added lamp information. The lamp-adding information may include the lamp identification, and the newly-added lamp information represents that the getaway includes a newly added lamp.

As such, the terminal acquires the tree-planting request, where the tree-planting request includes tree-planting location information and a lamp identification. Based on the tree-planting request, the terminal generates a virtual tree corresponding to the lamp identification at a virtual location characterized by the tree-planting location information, where the virtual tree corresponds to a planted tree at a geological location corresponding to the virtual location. The terminal displays the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree location.

Accordingly, the user may check the lamp carbon dioxide emission amount corresponding to each lamp through a tree-planting APP at the terminal, which enables the user to check the power consumption of each lamp. Further, an approach of displaying lamp power consumption and lamp carbon dioxide emission amount is provided, which enhances the user’s usage interests and improves the user experience.

Further, the cloud server may receive the lamp binding request sent by the getaway, where the lamp binding request includes the lamp identification and the getaway identification. The could server determines the terminal corresponding to the getaway identification based on the lamp binding request, and adds the lamp identification to the terminal. Thus, each two of a lamp, a virtual tree, and a planted tree may show one-to-one correspondence.

FIG. 18 is a flow chart of another lamp-based carbon offset processing method consistent with embodiments of the present disclosure. As shown in FIG. 18, the disclosed method may further include the followings.

At S301, the terminal displays planting-notification information, where the planting-notification information characterizes the lamp without a generated virtual tree, thereby prompting the user whether or not to check the condition of the virtual tree.

At S302, the terminal receives an examination request sent by the user.

At S303, the terminal displays virtual tree information based on the examination request, where the virtual tree information includes the lamp without a generated virtual tree and the lamp with a generated virtual tree.

Accordingly, the user may check the lamp carbon dioxide emission amount corresponding to each lamp through a tree-planting APP at the terminal, which enables the user to check the power consumption of each lamp. Further, an approach of displaying lamp power consumption and lamp carbon dioxide emission amount is provided, which enhances the user’s usage interests and improves the user experience. Further, the terminal may display the newly-added lamp information, and display the planting-notification information.

FIG. 19 is a flow chart of another lamp-based carbon offset processing method consistent with embodiments of the present disclosure. As shown in FIG. 19, the disclosed method may further include the followings.

At S401, the terminal receives a query command sent by the user, where the query command instructs and inquires the total number of virtual trees and the total number of users participating in planting the virtual trees, and the terminal sends the query command to the controller.

At S402, the terminal, based on the query command, determines the total number of virtual trees and the total number of users participating in planting the virtual trees.

At S403, the terminal displays the total number of virtual trees and the total number of users participating in planting the virtual trees.

Accordingly, the user may check the lamp carbon dioxide emission amount corresponding to each lamp through a tree-planting APP at the terminal, which enables the user to check the power consumption of each lamp. Further, an approach of displaying lamp power consumption and lamp carbon dioxide emission amount is provided, which enhances the user’s usage interests and improves the user experience. Further, the terminal may display the newly-added lamp information, display the planting-notification information, and display the total number of virtual trees.

FIG. 20 is a flow chart of another lamp-based carbon offset processing method consistent with embodiments of the present disclosure. As shown in FIG. 20, based on the aforementioned embodiments, the disclosed method may, before S103, further include the followings.

At S501, the cloud server acquires the power consumption of a lamp bound to the getaway, calculates the lamp carbon dioxide emission amount corresponding to the power consumption, and determines the tree carbon dioxide adsorption amount of the planted tree corresponding to the lamp. The cloud server may send the lamp carbon dioxide emission amount and the tree carbon dioxide adsorption amount to the terminal.

For example, the power consumption of 1 kWh may equal to the lamp carbon dioxide emission amount of 0.702766 kg. Thus, the processor 15 of the cloud server 11 may determine the lamp carbon dioxide emission amount A of the lamp 13 to be x*0.702766 kg, given the power consumption being x kWh.

Further, given the tree carbon dioxide adsorption amount of one tree during 10 years to be 18213 kg, the processor 15 of the cloud server 11 may calculate the tree carbon dioxide adsorption amount B of a planted tree during y days to be B= (18213 kg÷365÷10) *y. Specifically, the value of 18213 kg÷365÷10 may be calculated, and given calculated value of 18213 kg÷365÷10 and the number of planting days y of the planted tree, the processor 15 may acquire the tree carbon dioxide adsorption amount B of the planted tree corresponding to each virtual tree.

After S103, the method may further include the followings.

At S502, the terminal displays transition animation information, where the transition animation information includes the tree information of various virtual trees, and the tree information of each virtual tree includes virtual tree information, and planted tree information of the planted tree corresponding to the virtual tree.

At S503, the terminal generates an image of a planted tree certificate. The image of the planted tree certificate may include at least one of the following types of information: the total amount of the currently generated virtual trees, types of various planted trees corresponding to the currently generated virtual trees in one-to-one correspondence, tree-planting location information of various planted trees corresponding to the currently generated virtual trees in one-to-one correspondence, generation time of the currently generated virtual trees, and planting time of the planted trees corresponding to the currently generated virtual trees in one-to-one correspondence.

At S504, the terminal displays the image of the planted tree certificate, and displays saving-notification information, thereby prompting the user whether or not to save the image of the planted tree certificate.

At S505, the terminal acquires a saving request sent by the user, and saves the image of the planted tree certificate based on the saving request.

At S506, the terminal displays sharing-notification information, thereby prompting the user whether or not to share the current tree-planting status. The sharing-notification information may include links to at least one sharing-platform, virtual tree information of the virtual tree corresponding to the lamp characterized by the current tree-planting status, the planted tree information of the planted tree corresponding to the virtual tree, lamp carbon dioxide emission amount of the lamp, and the tree carbon dioxide adsorption amount of the planted tree.

At S507, the terminal receives a sharing request of the user, where the sharing request includes a sharing-platform identification.

At S508, the terminal, based on the sharing request, shares the current tree-plating status to the sharing platform corresponding to the sharing-platform identification according to the link to the sharing platform corresponding to the sharing-platform identification.

Accordingly, the user may check the lamp carbon dioxide emission amount corresponding to each lamp through a tree-planting APP at the terminal, which enables the user to check the power consumption of each lamp. Further, an approach of displaying lamp power consumption and lamp carbon dioxide emission amount is provided, which enhances the user’s usage interests and improves the user experience. Further, the terminal may display the newly-added lamp information, display the planting-notification information, display the virtual tree corresponding to the lamp identification and the carbon dioxide amount of the virtual tree, display the transition animation information, display the image of the planted tree certificate, and display the sharing-notification information. Thus, the present disclosure provides the user with a system and a procedure of virtual tree planting based on the power consumption of the lamp.

FIG. 21 is a flow chart of another lamp-based carbon offset processing method consistent with embodiments of the present disclosure. As shown in FIG. 21, based on the aforementioned embodiments, the disclosed may, after S103, further include the followings.

At S601, the terminal determines whether the lamp carbon dioxide emission amount is greater than or equal to the tree carbon dioxide adsorption amount. If the lamp carbon dioxide emission amount is determined to be greater than or equal to the tree carbon dioxide adsorption amount, the terminal generates first notification information.

At S602, the terminal displays the first notification information, thereby prompting the user whether or not to adjust the lamp.

At S603, the terminal receives an action status sent by the user, and generates a first lamp-adjusting command based on the action status. The first lamp-adjusting command includes a lamp identification, and the first lamp-adjusting command is at least one of the followings: lamp turning-off command, lamp brightness-adjusting command, and lamp color-adjusting command.

At S604, the terminal sends the first lamp-adjusting command to the lamp corresponding to the lamp identification in the first lamp-adjusting command through the getaway and the cloud server, thus allowing the lamp to execute an operation corresponding to the first lamp-adjusting command.

Alternatively, after S103, the method may further include the followings.

At S701, the terminal determines whether the lamp carbon dioxide emission amount is greater than or equal to the tree carbon dioxide adsorption amount. If the lamp carbon dioxide emission amount is determined to be greater than or equal to the tree carbon dioxide adsorption amount, the terminal generates second notification information.

At S702, the terminal displays the second notification information, thereby prompting the user whether or not to adjust the lamp.

At S703, the terminal receives the audio information sent by the user, and generates a second lamp-adjusting command based on the audio information. The second lamp-adjusting command includes the lamp identification, and the second lamp-adjusting command includes at least one of the followings: lamp turning-off command, lamp brightness-adjusting command, and lamp color-adjusting command.

At S704, the terminal sends the second lamp-adjusting command to the lamp corresponding to the lamp identification in the second lamp-adjusting command through the getaway and the cloud server, thus allowing the lamp to execute an operation corresponding to the second lamp-adjusting command.

The execution of S601～S604 and the execution of S701～S704 may be conducted, separately, or simultaneously.

Further, the terminal generates a lamp-adjusting command when determining whether the lamp carbon dioxide emission amount is greater than or equal to the tree carbon dioxide adsorption amount. The terminal further sends the lamp-adjusting command to the lamp through the getaway and the cloud server, thus allowing the lamp to execute an operation corresponding to the lamp-adjusting command. Accordingly, the objective of adjusting the brightness and the color of the lamp may be achieved, which further reduces the power consumption amount of the lamp, thereby saving the energy resources.

Those ordinarily skilled in the relevant art may understand that all or partial steps in the aforementioned embodiments may be implemented through hardware related to program instructions. The aforementioned program may be stored in a computer-readable storage medium. When the program is executed, steps included in each aforementioned embodiment may be executed. The aforementioned storage medium may be any medium for storing program codes, such as ROM, RAM, magnetic disc, or optical disc.

It should be illustrated that, the aforementioned embodiments are only used to illustrate technical solutions of the present disclosure, but not intended to be limiting of the present disclosure. Though the present disclosure is illustrated in detail with reference to the aforementioned embodiments, those ordinarily skilled in the relevant art shall understand that technical solutions recorded in each aforementioned embodiment may be modified, or part of the technical characteristics may be equally replaced. Such modification or replacement shall not depart the nature of the technical solutions from the spirit and scope of the technical solutions in each embodiment of the present disclosure.

Claims

A terminal, comprising:

a controller; and

a display module,

wherein the controller is connected to the display module,

the controller is configured to acquire a tree-planting request, and the tree-planting request includes tree-planting location information and a lamp identification,

based on the tree-planting request, the controller is further configured to generate a virtual tree corresponding to the lamp identification at a virtual location characterized by the tree-planting location information, wherein the virtual tree corresponds to a planted tree at a geological location corresponding to the virtual location, and

the display module is configured to display the virtual tree corresponding to the lamp identification, a lamp carbon dioxide emission amount of a lamp corresponding to the lamp identification, and a tree carbon dioxide adsorption amount of the planted tree.
The terminal according to claim 1, further comprising:

a user interface,

wherein the display module is connected to the user interface,

the display module is further configured to display planting-notification information, wherein the planting-notification information characterizes one or more lamps without a generated virtual tree to prompt a user whether or not to check a condition of the virtual tree,

the user interface is configured to receive an examination request sent by the user, and

the display module is further configured to display virtual tree information based on the examination request, wherein the virtual tree information includes the one or more lamps without a generated virtual tree and a lamp with a generated virtual tree.
The terminal according to claim 1, wherein:

the display module includes a display screen module and a printing circuit board (PCB) ,

the PCB circuit board is connected to the display screen module, and

the display screen module is configured to display transition animation information after displaying the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree,

wherein the transition animation information includes tree information of each virtual tree, and the tree information includes virtual tree information and planted tree information of the planted tree corresponding to the virtual tree.
The terminal according to claim 2, further comprising:

a first memory,

the first memory is connected to the controller and the display module, respectively,

the controller is further configured to generate an image of a planted tree certificate after displaying the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree at the display module, wherein the image of the planted tree certificate includes at least one of following types of information: a total amount of the currently generated virtual trees, types of various planted trees corresponding to the currently generated virtual trees in one-to-one correspondence, tree-planting location information of the various planted trees corresponding to the currently generated virtual trees in one-to-one correspondence, generation time of the currently generated virtual trees, and planting time of the planted trees corresponding to the currently generated virtual trees in one-to-one correspondence,

the display module is further configured to display the image of the planted tree certificate, and display saving-notification information, thereby prompting the user whether or not to save the image of the planted tree certificate,

the user interface is further configured to acquire a saving request sent by the user, and send the saving request to the first memory, and

the first memory is configured to save the image of the planted tree certificate based on the saving request.
The terminal according to claim 1, wherein:

the controller includes a controlling chip,

the display module is further configured to display sharing-notification information after displaying the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree, thereby prompting the user whether or not to share a current tree-planting status, wherein the sharing-notification information includes links to at least one sharing-platform, virtual tree information of the virtual tree corresponding to the lamp characterized by the current tree-planting status, planted tree information of the planted tree corresponding to the virtual tree, lamp carbon dioxide emission amount of the lamp, and the tree carbon dioxide adsorption amount of the planted tree,

the user interface is configured to receive the sharing request of the user, wherein the sharing request includes a sharing-platform identification, and

the controlling chip is configured to, based on the sharing request, share the current tree-plating status to the sharing platform corresponding to the sharing-platform identification according to the link to the sharing platform corresponding to the sharing-platform identification.
The terminal according to claim 1, further comprising:

a sensor,

wherein the sensor is connected to the controller,

the controller is further configured to, after displaying the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree, determine whether the lamp carbon dioxide emission amount is greater than or equal to the tree carbon dioxide adsorption amount,

if the lamp carbon dioxide emission amount is determined to be greater than or equal to the tree carbon dioxide adsorption amount, the controller generates first notification information,

the display module is further configured to display the first notification information, thereby prompting the user whether or not to adjust the lamp,

the sensor is configured to receive an action status sent by the user, and send the action status to the controller, and

the controller is further configured to generate a first lamp-adjusting command based on the action status, wherein the first lamp-adjusting command includes the lamp identification, and the first lamp-adjusting command is at least one of followings: a lamp turning-off command, a lamp brightness-adjusting command, and a lamp color-adjusting command, and

the controller is further configured to send the first lamp-adjusting command to the lamp corresponding to the lamp identification in the first lamp-adjusting command through the getaway and the cloud server, thus allowing the lamp to execute an operation corresponding to the first lamp-adjusting command.
The terminal according to claim 1, further comprising:

a microphone,

wherein the microphone is connected to the controller,

the controller is further configured to, after displaying the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree, determine whether the lamp carbon dioxide emission amount is greater than or equal to the tree carbon dioxide adsorption amount,

if the lamp carbon dioxide emission amount is determined to be greater than or equal to the tree carbon dioxide adsorption amount, the controller generates second notification information,

the display module is further configured to display the second notification information, thereby prompting the user whether or not to adjust the lamp,

the microphone is configured to receive audio information sent by the user, and send the audio information to the controller,

the controller is further configured to generate a second lamp-adjusting command based on the audio information, wherein the second lamp-adjusting command includes the lamp identification, and the second lamp-adjusting command includes at least one of followings: a lamp turning-off command, a lamp brightness-adjusting command, and a lamp color-adjusting command, and

the controller is further configured to send the second lamp-adjusting command to the lamp corresponding to the lamp identification in the second lamp-adjusting command through the getaway and the cloud server, thus allowing the lamp to execute an operation corresponding to the second lamp-adjusting command.
The terminal according to claim 1, wherein:

the user interface includes a manipulator, an interface input module, or a keyboard,

the user interface is further configured to receive a query command sent by the user, wherein the query command instructs and inquires a total number of virtual trees and a total number of users participating in planting the virtual trees, and the user interface is further configured to send the query command to the controller,

the controller is further configured to, based on the query command, determine the total number of virtual trees and the total number of users participating in planting the virtual trees, and

the display module is further configured to display the total number of virtual trees and the total number of users participating in planting the virtual trees.
A lamp-based carbon offset processing system, comprising:

a cloud server;

a getaway;

a terminal; and

at least one lamp,

wherein the terminal includes a controller and a display module,

the controller is connected to the display module,

the controller is configured to acquire a tree-planting request, and the tree-planting request includes tree-planting location information and a lamp identification,

based on the tree-planting request, the controller is further configured to generate a virtual tree corresponding to the lamp identification at a virtual location characterized by the tree-planting location information, wherein the virtual tree corresponds to a planted tree at a geological location corresponding to the virtual location, and

the display module is configured to display the virtual tree corresponding to the lamp identification, a lamp carbon dioxide emission amount of a lamp corresponding to the lamp identification, and a tree carbon dioxide adsorption amount of the planted tree.
The system according to claim 9, wherein:

the cloud server is connected to the getaway,

the terminal and the at least one lamp are connected to the getaway, respectively,

the cloud server is configured to acquire a power consumption of each lamp bound to the getaway, determine the lamp carbon dioxide emission amount corresponding to the power consumption, determine a tree carbon dioxide adsorption amount of a planted tree corresponding to the lamp, and send the lamp carbon dioxide emission amount and the tree carbon dioxide adsorption amount to the terminal, and

each two of a lamp, a virtual tree, and a planted tree are in one-to-one correspondence.
The system according to claim 10, wherein:

the cloud server includes a communication interface and a processor,

the communication interface is connected to the getaway and the processor, respectively,

the communication interface is configured to receive a lamp binding request sent by the getaway, wherein the lamp binding request is sent after the getaway detects that the lamp is connected to the getaway, and lamp binding request includes the lamp identification and a getaway identification,

the processor is configured to acquire the lamp binding request received by the communication interface, determine the terminal corresponding to the getaway identification based on the lamp binding request, and add the lamp identification to the terminal, and

the processor further sends lamp-adding information to the terminal, thus allowing the terminal to display newly-added lamp information, wherein the lamp-adding information includes the lamp identification, and the newly-added lamp information represents that the getaway include a newly added lamp.
The system according to claim 10, wherein:

the cloud server further includes a second memory,

the second memory is connected to the processor,

the processor is further configured to receive a first lamp-adjusting command or a second lamp-adjusting command sent by the terminal through the getaway, and send the first lamp-adjusting command or the second lamp-adjusting command to a lamp indicated by the first lamp-adjusting command or the second lamp-adjusting command through the getaway, thus allowing the lamp to execute an operation corresponding to the first or second lamp-adjusting command, and

the second memory is configured to receive and store the first or second lamp-adjusting command sent by the processor.
A lamp-based carbon offset processing method, comprising:

acquiring, by a terminal, a tree-planting request, wherein the tree-planting request includes tree-planting location information and a lamp identification;

generating, by the terminal, a virtual tree corresponding to the lamp identification at a virtual location characterized by the tree-planting location information, wherein the virtual tree corresponds to a planted tree at a geological location corresponding to the virtual location; and

displaying, by the terminal, the virtual tree corresponding to the lamp identification, a lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and a tree carbon dioxide adsorption amount of the planted tree.
The method according to claim 13, further comprising:

displaying, by the terminal, planting-notification information, wherein the planting-notification information characterizes lamps without a generated virtual tree, thereby prompting the user whether or not to check a condition of the virtual tree;

receiving, by the terminal, an examination request sent by the user; and

displaying, by the terminal, virtual tree information based on the examination request, wherein the virtual tree information includes the lamps without a generated virtual tree and lamps with a generated virtual tree.
The method according to claim 13, wherein after displaying, by the terminal, the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree, the method further comprising:

displaying, by the terminal, transition animation information, wherein the transition animation information includes the tree information of various virtual trees, and the tree information includes virtual tree information, and planted tree information of the planted tree corresponding to the virtual tree.
The method according to claim 13, wherein after displaying, by the terminal, the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree, the method further comprising:

generating, by the terminal, an image of a planted tree certificate, wherein the image of the planted tree certificate includes at least one of following types of information: a total amount of currently generated virtual trees, types of various planted trees corresponding to the currently generated virtual trees in one-to-one correspondence, tree-planting location information of various planted trees corresponding to the currently generated virtual trees in one-to-one correspondence, generation time of the currently generated virtual trees, and planting time of the planted trees corresponding to the currently generated virtual trees in one-to-one correspondence,

displaying, by the terminal, the image of the planted tree certificate,

displaying, by the terminal, saving-notification information, thereby prompting the user whether or not to save the image of the planted tree certificate,

acquiring, by the terminal, a saving request sent by the user, and

saving, by the terminal, the image of the planted tree certificate based on the saving request.
The method according to claim 13, wherein after displaying, by the terminal, the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree, the method further comprising:

displaying, by the terminal, sharing-notification information, thereby prompting the user whether or not to share a current tree-planting status, wherein the sharing-notification information includes links to at least one sharing-platform, virtual tree information of the virtual tree corresponding to a lamp characterized by the current tree-planting status, planted tree information of the planted tree corresponding to the virtual tree, lamp carbon dioxide emission amount of the lamp, and tree carbon dioxide adsorption amount of the planted tree,

receiving, by the terminal, a sharing request of the user, wherein the sharing request includes a sharing-platform identification, and

based on the sharing request, sharing by the terminal, the current tree-plating status to the sharing platform corresponding to the sharing-platform identification according to the link to the sharing platform corresponding to the sharing-platform identification.
The method according to claim 13, after displaying, by the terminal, the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree, the method further comprising:

determining, by the terminal, whether the lamp carbon dioxide emission amount is greater than or equal to the tree carbon dioxide adsorption amount,

if the lamp carbon dioxide emission amount is determined to be greater than or equal to the tree carbon dioxide adsorption amount, the terminal generates first notification information,

displaying, by the terminal, the first notification information, thereby prompting the user whether or not to adjust the lamp,

receiving, by the terminal, an action status sent by the user,

generating, by the terminal, a first lamp-adjusting command based on the action status, wherein the first lamp-adjusting command includes the lamp identification, and the first lamp-adjusting command is at least one of followings: a lamp turning-off command, a lamp brightness-adjusting command, and a lamp color-adjusting command,

sending, by the terminal, the first lamp-adjusting command to the lamp corresponding to the lamp identification in the first lamp-adjusting command through the getaway and the cloud server, thus allowing the lamp to execute an operation corresponding to the first lamp-adjusting command.
The method according to claim 13, after displaying, by the terminal, the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree, the method further comprising:

determining, by the terminal, whether the lamp carbon dioxide emission amount is greater than or equal to the tree carbon dioxide adsorption amount,

if the lamp carbon dioxide emission amount is determined to be greater than or equal to the tree carbon dioxide adsorption amount, the terminal generates second notification information,

displaying, by the terminal, second notification information, thereby prompting the user whether or not to adjust the lamp,

displaying, by the terminal, audio information sent by the user,

generating, by the terminal, a second lamp-adjusting command based on the audio information, wherein the second lamp-adjusting command includes the lamp identification, and the second lamp-adjusting command includes at least one of followings: a lamp turning-off command, a lamp brightness-adjusting command, and a lamp color-adjusting command, and

sending, by the terminal, the second lamp-adjusting command to the lamp corresponding to the lamp identification in the second lamp-adjusting command through the getaway and the cloud server, thus allowing the lamp to execute an operation corresponding to the second lamp-adjusting command.
The method according to claim 13, further comprising:

receiving, by the terminal, a query command sent by the user, wherein the query command instructs and inquires a total number of virtual trees and a total number of users participating in planting the virtual trees,

sending, by the terminal, the query command to the controller,

determining, by the terminal, the total number of virtual trees and the total number of users participating in planting the virtual trees based on the query command, and

displaying, by the terminal, the total number of virtual trees and the total number of users participating in planting the virtual trees.
The method according to claim 13, wherein before displaying, by the terminal, the virtual tree corresponding to the lamp identification, the lamp carbon dioxide emission amount of the lamp corresponding to the lamp identification, and the tree carbon dioxide adsorption amount of the planted tree, the method further comprising:

acquiring, by a cloud server, power consumption of each lamp bound to the getaway,

determining, by the cloud server, a lamp carbon dioxide emission amount corresponding to the power consumption,

determining, by the cloud server, a tree carbon dioxide adsorption amount of a planted tree corresponding to the lamp, and

sending, by the cloud server, the lamp carbon dioxide emission amount and the tree carbon dioxide adsorption amount to the terminal.
The method according to claim 21, wherein:

a lamp carbon dioxide emission amount A corresponding to the power consumption is A= x*0.702766 kg, where x is power consumption of the lamp.
The method according to claim 21, wherein:

a tree carbon dioxide adsorption amount B of a tree is B= (18213 kg÷365÷10) *y, wherein y is a number of planting days of the planted tree.
The method according to claim 21, further comprising:

receiving, by the cloud server, a lamp binding request sent by the getaway, wherein the lamp binding request is sent after the getaway detects that the lamp is connected to the getaway, and the lamp binding request includes the lamp identification and the getaway identification, and

determining, by the cloud server, the terminal corresponding to the getaway identification based on the lamp binding request, and

adding, by the cloud server, lamp-adding information to the terminal, thereby allowing the terminal to display newly-added lamp information,

wherein the lamp-adding information includes the lamp identification, and the newly-added lamp information represents that the getaway includes a newly added lamp.