CN114100156B - Control method and system for electricity utilization state of electronic building block and building block system - Google Patents

Abstract

The application provides a control method and a system for the electricity utilization state of an electronic building block and a building block system, wherein the control method comprises the following steps: in the wireless building block network, one electronic building block sends a wake-up notice after receiving the wake-up operation of a user to inform other electronic building blocks to uniformly set the current power utilization state to be the working power utilization state; and the plurality of electronic bricks in the wireless building block network are communicated in a wireless mode. According to the application, a user can wake up other electronic building blocks through only one electronic building block, and the technical problem that other electronic building blocks are surrounded by the building blocks after being built and cannot be touched and operated is solved. The application provides the working electricity utilization state, the light sleep electricity utilization state, the deep sleep electricity utilization state and the shutdown state for the electronic building blocks, saves the energy consumption electricity utilization of the building blocks by switching the electricity utilization states, and improves the service time of the electronic building blocks after single charging.

Description

Control method and system for electricity utilization state of electronic building block and building block system

Technical Field

The application relates to the field of building blocks, in particular to a control method and system of an electric power utilization state of an electronic building block and a building block system.

Background

Patent document CN109107195a provides a power saving method of a building block master control component module and a building block master control component module, comprising: initializing a setting step: when the starting component building blocks are not spliced on the building block main control component module, the building block main control component module is set to be initialized, sleep is achieved when the first level signal is received, and wake-up is achieved when the second level signal is received; an inversion setting step: in the state that the building block main control component module receives the second level signal, if the duration of the building block main control component module which does not receive the working signal is larger than or equal to a preset value, the building block main control component module is reversely set to wake up when receiving the first level signal, and sleep when receiving the second level signal, otherwise, the building block main control component module keeps wake up; and a reduction judgment step: when the building block main control component module receives the second level and receives the first level signal in a sleeping state, the building block main control component module is awakened and returns to the initialization setting.

The patent document CN109107195a performs power saving control on electronic blocks which are physically connected and in wired communication, and saves electric energy.

Disclosure of Invention

Aiming at the defects in the prior art, the application aims to provide a control method and system for the electricity utilization state of an electronic building block and a building block system.

The application provides a control method of the electricity utilization state of an electronic building block, which comprises the following steps:

a wake-up notification step: in the wireless building block network, one electronic building block sends a wake-up notice after receiving the wake-up operation of a user to inform other electronic building blocks to uniformly set the current power utilization state to be the working power utilization state;

and the plurality of electronic bricks in the wireless building block network are communicated in a wireless mode.

Preferably, it comprises:

building and identifying: if the electronic blocks with the same attribute in the block network are gradually increased, enabling the electronic blocks in the block network to enter a deep sleep power utilization state;

disassembling and identifying: if the electronic blocks with the same attribute in the block network are gradually reduced, enabling the electronic blocks in the block network to enter a light sleep power utilization state;

the deep sleep power consumption state is lower than the shallow sleep power consumption state.

Preferably, the attribute comprises any one or more of:

the first acceleration attribute is used for indicating that the electronic building block is in a motion state;

the second acceleration attribute is used for indicating that the movement directions of the electronic building blocks are synchronous;

the physical electric connection attribute is used for indicating that the electronic building blocks are in physical electric connection with other electronic building blocks;

the electronic building block comprises an instruction receiving and transmitting state attribute, wherein the instruction receiving and transmitting state attribute is used for indicating that the electronic building block is in an instruction receiving and transmitting state;

and the signal strength attribute is used for indicating a strong signal state that the signal of the wireless building block network at the electronic building block exceeds a signal threshold value.

Preferably, it comprises:

light sleep leaving step: for the electronic building blocks in the light sleep power utilization state, if the electronic building blocks do not enter the deep sleep power utilization state within the first set time threshold, entering a shutdown state when the first set time threshold arrives;

deep sleep leaving step: and if the electronic building block in the deep sleep power utilization state does not leave the deep sleep power utilization state within the second set time threshold, entering the shallow sleep power utilization state when the second set time arrives.

And after the electronic building block is started, the electronic building block enters a working power utilization state, and the power consumption of the working power utilization state is higher than that of the light sleep power utilization state.

Preferably, after the electronic building block receives the wake-up notice, the electronic building block enters the working power-on state from the light sleep power-on state or enters the working power-on state from the deep sleep power-on state.

The application provides a control system for the electricity utilization state of an electronic building block, which comprises the following components:

and a wake-up notification module: in the wireless building block network, one electronic building block sends a wake-up notice after receiving the wake-up operation of a user to inform other electronic building blocks to uniformly set the current power utilization state to be the working power utilization state;

and the plurality of electronic bricks in the wireless building block network are communicated in a wireless mode.

Preferably, it comprises:

building an identification module: if the electronic blocks with the same attribute in the block network are gradually increased, enabling the electronic blocks in the block network to enter a deep sleep power utilization state;

disassembling the identification module: if the electronic blocks with the same attribute in the block network are gradually reduced, enabling the electronic blocks in the block network to enter a light sleep power utilization state;

the deep sleep power consumption state is lower than the shallow sleep power consumption state.

Preferably, the attribute comprises any one or more of:

the first acceleration attribute is used for indicating that the electronic building block is in a motion state;

the second acceleration attribute is used for indicating that the movement directions of the electronic building blocks are synchronous;

the physical electric connection attribute is used for indicating that the electronic building blocks are in physical electric connection with other electronic building blocks;

the electronic building block comprises an instruction receiving and transmitting state attribute, wherein the instruction receiving and transmitting state attribute is used for indicating that the electronic building block is not in an instruction receiving and transmitting state or an instruction receiving and transmitting state;

and the signal intensity attribute is used for indicating the signal intensity of the wireless building block network at the electronic building block.

Preferably, it comprises:

light sleep leaving module: for the electronic building blocks in the light sleep power utilization state, if the electronic building blocks do not enter the deep sleep power utilization state within the first set time threshold, entering a shutdown state when the first set time threshold arrives;

deep sleep departure module: and if the electronic building block in the deep sleep power utilization state does not leave the deep sleep power utilization state within the second set time threshold, entering the shallow sleep power utilization state when the second set time arrives.

And after the electronic building block is started, the electronic building block enters a working power utilization state, and the power consumption of the working power utilization state is higher than that of the light sleep power utilization state.

Preferably, after the electronic building block receives the wake-up notice, the electronic building block enters the working power-on state from the light sleep power-on state or enters the working power-on state from the deep sleep power-on state.

According to the application, a computer readable storage medium is provided, in which a computer program is stored, which when being executed by a processor, implements the steps of the method for controlling the power utilization state of the electronic building block.

According to the building block system provided by the application, the power utilization state of the electronic building blocks in the building block system is controlled by adopting the control method of the power utilization state of the electronic building blocks, or the control system of the power utilization state of the electronic building blocks is included, or the electronic building blocks of the building block system comprise a computer readable storage medium storing a computer program.

Compared with the prior art, the application has the following beneficial effects:

1. for a plurality of electronic blocks, a user can wake up other electronic blocks only through one electronic block, and the technical problem that other electronic blocks are surrounded by the blocks after being built and cannot be touched and operated is solved.

2. The application provides the working electricity utilization state, the light sleep electricity utilization state, the deep sleep electricity utilization state and the shutdown state for the electronic building blocks, saves the energy consumption electricity utilization of the building blocks by switching the electricity utilization states, and improves the service time of the electronic building blocks after single charging.

3. According to the application, whether a user is splicing or dismantling the building blocks is identified by gradually increasing or decreasing the electronic building blocks with the same attribute in the building block network, so that the electronic building blocks correspondingly enter a deep sleep power utilization state or a light sleep power utilization state.

Drawings

Other features, objects and advantages of the present application will become more apparent upon reading of the detailed description of non-limiting embodiments, given with reference to the accompanying drawings in which:

fig. 1 is a schematic diagram of a control principle among various power utilization states in the present application.

Detailed Description

The present application will be described in detail with reference to specific examples. The following examples will assist those skilled in the art in further understanding the present application, but are not intended to limit the application in any way. It should be noted that variations and modifications could be made by those skilled in the art without departing from the inventive concept. These are all within the scope of the present application.

The control method of the electricity utilization state of the electronic building blocks comprises the following steps:

a wake-up notification step: in the wireless building block network, one electronic building block sends a wake-up notice after receiving the wake-up operation of a user to inform other electronic building blocks to uniformly set the current power utilization state to be the working power utilization state; and the plurality of electronic bricks in the wireless building block network are communicated in a wireless mode.

Specifically, the plurality of electronic building blocks communicate in a wireless manner, and a wireless networking, namely a wireless building block network is constructed. The electronic blocks in a wireless block network are communicated through the wireless block network, and all the electronic blocks in the same wireless block network are considered as a set of blocks, for example, in classroom classrooms, and are networked together with the electronic blocks belonging to the same table to form the wireless block network corresponding to the table. Preferably, an electronic building block can only join a wireless building block network at the same time. Thus, wake-up may be transmitted in broadcast form in the wireless building block network, and only other electronic building blocks under the same wireless building block network may be able to receive wake-up notifications.

When a user is ready to wake up each electronic building block in the wireless building block network, the electronic building blocks need to be waken up. The wake-up operation includes: the electronic building block is started by operating switches such as buttons on the electronic building block, and the electronic building block is shaken to trigger a sensor of the electronic building block. The sensor may be an infrared sensor, a photoresistor, a varistor, or the like.

The wake-up notice is used for indicating the electronic building blocks receiving the wake-up notice to set the current power utilization state to be the working power utilization state, and if the current power utilization state of the electronic building blocks is the working power utilization state, the working power utilization state is continuously maintained unchanged.

Thus, for all electronic blocks in a wireless block network, a user only needs to wake up one electronic block, so that all electronic blocks can be waken up without waking up each electronic block one by one. The electronic bricks are preferably granular bricks, and in practice of building the electronic bricks, part of the electronic bricks are enclosed in granular bricks of other electronic bricks or other non-electronic bricks, so that a user cannot touch the enclosed electronic bricks, and therefore, the user can wake up the touch electronic bricks, and then the electronic bricks which are awakened up inform the enclosed electronic bricks.

The control method of the electricity utilization state of the electronic building block comprises the following steps:

building and identifying: if the electronic blocks with the same attribute in the block network are gradually increased, enabling the electronic blocks in the block network to enter a deep sleep power utilization state;

disassembling and identifying: if the electronic blocks with the same attribute in the block network are gradually reduced, enabling the electronic blocks in the block network to enter a light sleep power utilization state;

the deep sleep power consumption state is lower than the shallow sleep power consumption state.

Specifically, the core of the building block is to build, and the electronic building block also has a building function, for example, a particle head with a male head and a female head is arranged on a shell of the electronic building block, and a circuit formed by electronic components such as a wireless communication module is arranged in the shell, so that the electronic building block is formed. Generally, only after the electronic building block is built, a user starts to control the electronic building block to execute instructions, for example, the user needs to build a plurality of electronic building blocks and non-electronic building blocks into a robot, and then control the robot to execute instructions such as movement, sounding, lighting and the like. In the building process before the completion of the building, a user usually does not input instructions to the electronic building blocks, so that the electronic building blocks can be in a deep sleep power utilization state for saving electric energy in the building process, and the power consumption is reduced.

In this regard, the present application is able to intelligently identify that a user is in the process of being set up. If the electronic blocks with the same attribute in the block network are gradually increased, the electronic blocks in the block network enter a deep sleep power utilization state, wherein the gradual increase means that the number of the electronic blocks with the same attribute is increased more and more in a set time period, or the gradual increase also means that the difference value of the number of the electronic blocks with the same attribute minus the number of the electronic blocks with the same attribute at the beginning of the time period is larger than or equal to a set positive integer in a set time period at one end of the time period.

It is considered here that the process of building blocks is essentially a process of convergence of properties, which are increasingly processes of electronic blocks with properties set, i.e. with properties set, which the electronic blocks are considered to have, or which the electronic blocks are considered not to have. For example, the built blocks can move together, that is, more and more electronic blocks have movement attributes so that the movement attributes are converged, for example, the built blocks can move towards the same direction, that is, the attributes of which direction the more and more electronic blocks move towards are converged, and for example, physical connection exists between the built blocks, that is, the more and more electronic blocks have physical splicing attributes so that the physical splicing attributes are converged. Therefore, whether the electronic building block is in the building stage of a user or not can be identified, and the electronic building block enters a deep sleep power utilization state with lower power consumption. The process of building block disassembly is basically a process of gradually reducing the convergence of attributes, namely a reverse process of building blocks, and after the building blocks are disassembled, a user can build the building blocks again, or the user is ready to store the building blocks.

More specifically, in the preferred embodiment, if the following electronic blocks with the same attribute in the block network are all gradually increased, the electronic blocks in the block network enter a deep sleep power utilization state:

the first acceleration attribute is used for indicating that the electronic building blocks are in a motion state. Specifically, the electronic building block is provided with an acceleration sensor, if the acceleration detected by the acceleration sensor in the detection period is 0 all the time, the electronic building block is considered to be in a static state, and otherwise, the electronic building block is considered to be in a moving state. The user usually holds the building block combination in the construction process in the left hand or rotates and hands the building block combination to adjust the angle suitable for adding the building blocks, and the constructed building block combination does not always move in the process, but moves in a detection period, for example, 15 seconds, so that it is considered that the electronic building blocks in the constructed building block combination move in the detection period to generate acceleration which is not 0. When more and more electronic bricks are built in the built brick combination, the more electronic bricks with the first acceleration attribute are opened.

And the second acceleration attribute is used for indicating that the movement directions of the electronic building blocks are synchronous. Specifically, the electronic toy has an acceleration sensor that is capable of detecting a corresponding acceleration when the electronic toy is moved. For each electronic building block in the building block combination which is already built together, when the building block combination moves, each electronic building block also moves together, for example, the building block combination is a trolley which is not completely spliced, and when the trolley moves forwards, a sensor of the electronic building block in the trolley detects forward acceleration. The acceleration of each electronic building block in the building block combination is not necessarily identical under the complex actions of the wrist and the arm when a user is used for handling the building block combination, so that the acceleration of the direction difference smaller than the set angle threshold value is considered to be synchronous, otherwise, the acceleration is not synchronous.

And the physical electric connection attribute is used for indicating that the electronic building blocks are in physical electric connection with other electronic building blocks. Specifically, the electronic building blocks are provided with circuits, and the circuits can detect the physical and electrical connection relation between the electronic building blocks. When the electronic building block is spliced to the spliced building block combination, the electronic building block has an attribute state of being in physical and electrical connection with other electronic building blocks. Therefore, when more and more electronic bricks are newly added and spliced to the building block combination, the number of the electronic bricks in the state of physically and electrically connecting other electronic bricks is more and more, that is, the electronic bricks with the same physical and electrical connection attribute are gradually increased.

Therefore, when the electronic bricks with the same attribute in the brick network are gradually increased, the user is considered to splice the bricks, so that the electronic bricks in the brick network enter a deep sleep power utilization state. Conversely, when the electronic blocks with the same attribute in the block network gradually decrease, the user considers that the block already spliced is disassembled, and then the block is possibly spliced again, for example, spliced into other models, and the block is possibly stored after being disassembled. Correspondingly, the control method of the electricity utilization state of the electronic building block comprises the following steps: light sleep leaving step: and if the electronic building block in the light sleep power utilization state does not enter the deep sleep power utilization state within the first set time threshold, entering a shutdown state when the first set time threshold arrives. Specifically, if the user is identified to disassemble the building blocks, entering a light sleep power utilization state; if the user builds the building blocks again, the electronic building blocks with the same attribute gradually increase, and the user enters a deep sleep power utilization state; if the user does not build the building blocks again, that is, the electronic building blocks with the same attributes are not found to be gradually increased, the user is considered to disassemble the building blocks for storage, so that the building blocks enter a shutdown state.

And the non-instruction receiving and transmitting state attribute is used for indicating that the electronic building block is not in an instruction receiving and transmitting state. Specifically, the instruction includes command information which is output to the electronic building blocks by the user and indicates the electronic building blocks to execute the acousto-optic-electric multimedia action or the motion action, and/or the instruction includes command information which is sent to other electronic building blocks by the electronic building blocks to execute the command information and indicates to execute the acousto-optic-electric multimedia action or the motion action. By analyzing the status attribute of the un-transmitted instruction, the operation status of the electronic building block by the user or the status of the electronic building block allowed by the user to execute the action can be intelligently identified. The instruction receiving and transmitting state can be whether the electronic building block receives or transmits an instruction in a set time period, and if the electronic building block does not receive the instruction and does not transmit the instruction in the set time period, the electronic building block is considered to have the attribute of not receiving and transmitting the instruction. When the electronic building blocks with the attribute of not receiving and transmitting the instruction state are gradually increased, the user is considered to not need the electronic building blocks to execute actions, for example, the user does not need the electronic building blocks to execute actions in the process of splicing the electronic building blocks, so that the user enters a deep sleep power utilization state to save energy consumption and prolong the service time of a battery in the electronic building blocks.

And the signal strength attribute is used for indicating a strong signal state that the signal of the wireless building block network at the electronic building block exceeds a signal threshold value. Specifically, in the wireless building block network, the more electronic building blocks are gathered, the more signals of the electronic building blocks become stronger, for example, when all the electronic building blocks are spliced together, the signals of the wireless building block network are strongest, otherwise, if the electronic building blocks are in a scattering state, the signals are weakened due to the fact that the electronic building blocks are far away from each other. Therefore, if the electronic building block detects that the signal intensity of the electronic building block exceeds the set signal threshold value, the electronic building block considers that the electronic building block is spliced or already spliced. When the electronic building blocks with the strong signal attribute gradually increase, the user is considered to splice the building blocks, and the electronic building blocks enter a deep sleep power utilization state.

It can be understood by those skilled in the art that the first acceleration attribute, the second acceleration attribute, the physical and electrical connection attribute, the non-receiving instruction state attribute, and the signal strength attribute are all set attributes, that is, only statistics is performed on whether the set attributes of the electronic building blocks are converged, and not statistics is performed on whether the situation opposite to the set attributes is converged, that is, the situation opposite to the set attributes is not regarded as the set attributes. For example, if the electronic blocks in the moving state are gradually increased, the electronic blocks in the static state are gradually decreased, but the electronic blocks in the moving state are only considered to be gradually increased, and the electronic blocks with the same attribute in the block network are considered to be gradually increased, so that the first acceleration attribute is converged, and the result of gradually decreasing the electronic blocks in the static state is not obtained, namely the result of gradually decreasing the electronic blocks with the same attribute in the block network as the opposite condition of the first attribute is not obtained.

In a preferred embodiment, the method for controlling the electricity utilization state of the electronic building block includes: deep sleep leaving step: and if the electronic building block in the deep sleep power utilization state does not leave the deep sleep power utilization state within the second set time threshold, entering the shallow sleep power utilization state when the second set time arrives. If the instruction of the user to enter the working power state is not received within the second set time threshold, the user is considered to have spent enough time on building blocks to be spliced, namely the second set time threshold is 5 minutes, and the user enters the light sleep power state from the deep sleep power state to prepare for entering the working power state, so that the response time for entering the working power state is shortened. In addition, the electronic building blocks enter into a working power utilization state after being started, and the power consumption of the working power utilization state is higher than that of the light sleep power utilization state. And after the electronic building block receives the awakening notice, the electronic building block enters the working power-on state from the light sleep power-on state or enters the working power-on state from the deep sleep power-on state. The wake-up notice can be used for directly adjusting the power utilization state of the electronic building block from the current power utilization state to the working power utilization state.

In one application scenario, a user takes out each electronic building block from the package, and after the electronic building block is started, the electronic building blocks enter an operating power state, and a wireless communication network is built and added. And then, recognizing that the user starts building blocks, and entering a deep sleep power utilization state. And then, the user wakes up the electronic building blocks to enter an operating power state for playing. And then, recognizing that the user disassembles the building block combination, and enabling the electronic building block to enter a light sleep power utilization state. And then, recognizing that the user starts to splice and build the building block combination, and enabling the electronic building block to enter a deep sleep power utilization state. And then, the user wakes up the electronic building block to enter an operating power state for playing, and finally instructs the electronic building block to shut down. In the whole playing process, the electronic building blocks intelligently identify the relation between the user and the building blocks, and the energy consumption is saved through the shallow sleep power utilization state and the deep sleep power utilization state, so that the service time of single charging of the electronic building blocks is prolonged. If the electronic building block is in the deep sleep power utilization state, the electronic building block does not enter the working power utilization state or the light sleep power utilization state within a set time, and is automatically powered off, in a preferred example, the set time before the automatic power off can be set long enough in consideration of low energy consumption in the deep sleep power utilization state, so that a user can enter the light sleep power utilization state from the deep sleep power utilization state during normal use.

The application also provides a control system of the electric state of the electronic building block, and a person skilled in the art can realize the control system of the electric state of the electronic building block by executing the step flow of the control method of the electric state of the electronic building block, namely the control method of the electric state of the electronic building block can be understood as a preferred implementation mode of the control system of the electric state of the electronic building block.

The application provides a control system for the electricity utilization state of an electronic building block, which comprises the following components:

and a wake-up notification module: in the wireless building block network, one electronic building block sends a wake-up notice after receiving the wake-up operation of a user to inform other electronic building blocks to uniformly set the current power utilization state to be the working power utilization state; the plurality of electronic bricks in the wireless building block network are communicated in a wireless mode;

building an identification module: if the electronic blocks with the same attribute in the block network are gradually increased, enabling the electronic blocks in the block network to enter a deep sleep power utilization state;

disassembling the identification module: if the electronic blocks with the same attribute in the block network are gradually reduced, enabling the electronic blocks in the block network to enter a light sleep power utilization state;

light sleep leaving module: for the electronic building blocks in the light sleep power utilization state, if the electronic building blocks do not enter the deep sleep power utilization state within the first set time threshold, entering a shutdown state when the first set time threshold arrives;

deep sleep departure module: and if the electronic building block in the deep sleep power utilization state does not leave the deep sleep power utilization state within the second set time threshold, entering the shallow sleep power utilization state when the second set time arrives.

The electronic building block enters a working power utilization state after being started, and the power consumption of the working power utilization state is higher than that of the light sleep power utilization state; the deep sleep power consumption state is lower than the shallow sleep power consumption state. And after the electronic building block receives the awakening notice, the electronic building block enters the working power-on state from the light sleep power-on state or enters the working power-on state from the deep sleep power-on state.

The attributes include any one or more of the following:

the first acceleration attribute is used for indicating the electronic building blocks to be in a moving state or a static state;

the second acceleration attribute is used for indicating whether the movement direction of the electronic building blocks is synchronous or asynchronous;

and the physical electric connection attribute is used for indicating that the electronic building block is in physical electric connection with other electronic building blocks or that the electronic building block is not in physical electric connection with other electronic building blocks.

Those skilled in the art will appreciate that the systems, apparatus, and their respective modules provided herein may be implemented entirely by logic programming of method steps such that the systems, apparatus, and their respective modules are implemented as logic gates, switches, application specific integrated circuits, programmable logic controllers, embedded microcontrollers, etc., in addition to the systems, apparatus, and their respective modules being implemented as pure computer readable program code. Therefore, the system, the apparatus, and the respective modules thereof provided by the present application may be regarded as one hardware component, and the modules included therein for implementing various programs may also be regarded as structures within the hardware component; modules for implementing various functions may also be regarded as being either software programs for implementing the methods or structures within hardware components.

According to the application, a computer readable storage medium is provided, in which a computer program is stored, which when being executed by a processor, implements the steps of the method for controlling the power utilization state of the electronic building block.

According to the building block system provided by the application, the power utilization state of the electronic building blocks in the building block system is controlled by adopting the control method of the power utilization state of the electronic building blocks, or the control system of the power utilization state of the electronic building blocks is included, or the electronic building blocks of the building block system comprise a computer readable storage medium storing a computer program.

The foregoing describes specific embodiments of the present application. It is to be understood that the application is not limited to the particular embodiments described above, and that various changes or modifications may be made by those skilled in the art within the scope of the appended claims without affecting the spirit of the application. The embodiments of the application and the features of the embodiments may be combined with each other arbitrarily without conflict.

Claims (10)

1. The method for controlling the power utilization state of the electronic building block is characterized by comprising the following steps of:

a wake-up notification step: in the wireless building block network, one electronic building block sends a wake-up notice after receiving the wake-up operation of a user to inform other electronic building blocks to uniformly set the current power utilization state to be the working power utilization state;

building and identifying: if the electronic blocks with the same attribute in the block network are gradually increased, enabling the electronic blocks in the block network to enter a deep sleep power utilization state;

disassembling and identifying: if the electronic blocks with the same attribute in the block network are gradually reduced, enabling the electronic blocks in the block network to enter a light sleep power utilization state;

the power consumption of the deep sleep power consumption state is lower than that of the shallow sleep power consumption state;

the plurality of electronic bricks in the wireless building block network are communicated in a wireless mode;

the attributes can be converged in the building block construction process.

2. The method for controlling the power utilization state of an electronic building block according to claim 1, wherein the attribute includes any one or more of the following:

the first acceleration attribute is used for indicating that the electronic building block is in a motion state;

the second acceleration attribute is used for indicating that the movement directions of the electronic building blocks are synchronous;

the physical electric connection attribute is used for indicating that the electronic building blocks are in physical electric connection with other electronic building blocks;

the electronic building block comprises an instruction receiving and transmitting state attribute, wherein the instruction receiving and transmitting state attribute is used for indicating that the electronic building block is in an instruction receiving and transmitting state;

and the signal strength attribute is used for indicating that the signal of the wireless building block network at the electronic building block is in a strong signal state exceeding a signal threshold value.

3. The method for controlling the power utilization state of the electronic building block according to claim 1, comprising:

light sleep leaving step: for the electronic building blocks in the light sleep power utilization state, if the electronic building blocks do not enter the deep sleep power utilization state within the first set time threshold, entering a shutdown state when the first set time threshold arrives;

deep sleep leaving step: for the electronic building blocks in the deep sleep power utilization state, if the electronic building blocks do not leave the deep sleep power utilization state within the second set time threshold, entering the shallow sleep power utilization state when the second set time arrives;

and after the electronic building block is started, the electronic building block enters a working power utilization state, and the power consumption of the working power utilization state is higher than that of the light sleep power utilization state.

4. The method for controlling the power utilization state of the electronic building block according to claim 1, wherein the electronic building block enters the power utilization state from the light sleep power utilization state or enters the power utilization state from the deep sleep power utilization state after receiving the wake-up notice.

5. The utility model provides a control system of electronic building blocks power consumption state which characterized in that includes:

and a wake-up notification module: in the wireless building block network, one electronic building block sends a wake-up notice after receiving the wake-up operation of a user to inform other electronic building blocks to uniformly set the current power utilization state to be the working power utilization state;

building an identification module: if the electronic blocks with the same attribute in the block network are gradually increased, enabling the electronic blocks in the block network to enter a deep sleep power utilization state;

disassembling the identification module: if the electronic blocks with the same attribute in the block network are gradually reduced, enabling the electronic blocks in the block network to enter a light sleep power utilization state;

the power consumption of the deep sleep power consumption state is lower than that of the shallow sleep power consumption state;

the plurality of electronic bricks in the wireless building block network are communicated in a wireless mode;

the attributes can be converged in the building block construction process.

6. The system of claim 5, wherein the attributes include any one or more of the following:

the first acceleration attribute is used for indicating that the electronic building block is in a motion state;

the second acceleration attribute is used for indicating that the movement directions of the electronic building blocks are synchronous;

the physical electric connection attribute is used for indicating that the electronic building blocks are in physical electric connection with other electronic building blocks;

the electronic building block comprises an instruction receiving and transmitting state attribute, wherein the instruction receiving and transmitting state attribute is used for indicating that the electronic building block is in an instruction receiving and transmitting state;

and the signal strength attribute is used for indicating a strong signal state that the signal of the wireless building block network at the electronic building block exceeds a signal threshold value.

7. The system for controlling the power utilization state of an electronic toy according to claim 5, comprising:

light sleep leaving module: for the electronic building blocks in the light sleep power utilization state, if the electronic building blocks do not enter the deep sleep power utilization state within the first set time threshold, entering a shutdown state when the first set time threshold arrives;

deep sleep departure module: for the electronic building blocks in the deep sleep power utilization state, if the electronic building blocks do not leave the deep sleep power utilization state within the second set time threshold, entering the shallow sleep power utilization state when the second set time arrives;

and after the electronic building block is started, the electronic building block enters a working power utilization state, and the power consumption of the working power utilization state is higher than that of the light sleep power utilization state.

8. The system of claim 5, wherein the electronic toy enters the power on state from the power on state for light sleep or enters the power on state from the power on state for deep sleep after receiving the wake-up notice.

9. A computer-readable storage medium storing a computer program, wherein the computer program, when executed by a processor, implements the steps of the method for controlling the power consumption state of an electronic toy according to any one of claims 1 to 4.

10. A building block system, characterized in that the control method of the electricity consumption state of the electronic building block according to any one of claims 1 to 4 is used for controlling the electricity consumption state of the electronic building block in the building block system, or the control system of the electricity consumption state of the electronic building block according to any one of claims 5 to 8 is included, or the electronic building block of the building block system includes a computer readable storage medium storing a computer program.