CN111969734B

CN111969734B - Intelligent mutual inductance type equipment charging management system and method

Info

Publication number: CN111969734B
Application number: CN202010995765.9A
Authority: CN
Inventors: 彭秋萍
Original assignee: Suzhou Pulun Electronic Technology Co ltd
Current assignee: Suzhou pulun Electronic Technology Co.,Ltd.
Priority date: 2020-09-21
Filing date: 2020-09-21
Publication date: 2021-06-25
Anticipated expiration: 2040-09-21
Also published as: CN115313673A; CN111969734A

Abstract

The invention relates to the technical field of communication, and particularly discloses an intelligent mutual inductance type equipment charging management system and a method, wherein the charging system comprises a wireless identification module, an electric quantity analysis module, a credit feedback module and a mutual inductance charging module, wherein the electric quantity analysis module is used for optimizing a charging scheme for charging equipment, the integral feedback module is used for actively rewarding the equipment which needs to be charged by integral conversion, and the mutual inductance type charging module is used for remotely supplying power to the successfully matched charging equipment when the charged equipment is charged. Thereby enabling the desired charging device to receive power.

Description

Intelligent mutual inductance type equipment charging management system and method

Technical Field

The invention relates to the technical field of communication, in particular to an intelligent mutual inductance type equipment charging management system and method.

Background

With the rapid development of electronic communication, the living standard of people is gradually increased, at present, the articles carried by people are not various electronic devices such as mobile phones and PADs, and in daily travel of people, the electronic devices are required to perform relevant work such as code scanning, verification, payment and communication.

Therefore, modes such as a charger and a wireless charging mode appear in the market, when the electric quantity is low, the electric quantity of the electronic equipment is continued through the connection of the charger and the mobile phone or the mobile phone is wirelessly charged, the mobile phone is placed on the induction charging equipment, and the electronic equipment is powered by the principle of electromagnetic induction, the two methods are generally applied to the market at present, but inconvenience is brought to life, when the charger is used for powering the electronic equipment, a great deal of inconvenience is brought to users walking on the road due to the fact that the charger has heavy components and the data line is long, the mobile phone is powered by the wireless charging mode, and due to the fact that the voltage of a power supply is insufficient, the charging speed of the electronic equipment is slow, and the urgent need cannot be solved;

in patent application No. 201611192701.5, the electric quantity value of the charged device is detected in real time according to the state information of the charged device, when the detected electric quantity value is higher than a preset value, the device to be charged is supplied with power according to the distance between the charged device and the charging device, so that the problems encountered above are completely solved, but in the power supply process, the power supply analysis of the charged device is not carried out optimally, and when the electric quantity value of other user devices is detected to be lower than a predicted value, the user devices cannot be supplied with power actively, so that the urgency of the user is solved;

therefore, there is a need for a system and method for managing charging of intelligent and mutual inductive devices to solve the above problems

Disclosure of Invention

The present invention is directed to a system and a method for charging management of an intelligent mutual inductance device, so as to solve the problems mentioned in the background art.

In order to solve the technical problems, the invention provides the following technical scheme: the system comprises a wireless identification module, an electric quantity analysis module, a credit feedback module, a mutual inductance type charging module and an intelligent cloud platform, wherein the wireless identification module is used for identifying and matching the device models of first user equipment and second user equipment in multiple ways, the connection between the devices can be more convenient and faster through identifying the device models, the electric quantity analysis module is used for optimizing a charging scheme for the first user equipment, so that the charged device can supply power to the charging device as much as possible according to the condition of the device per se, the credit feedback module is used for initiatively carrying out point exchange reward on the first user equipment which supplies power to the first user equipment, so that a user can actively help the user needing charging, the mutual inductance type charging module is used for remotely supplying power to the first user equipment which is successfully matched when the second user equipment is charged, the intelligent cloud platform is used for automatically storing data, the wireless identification module is connected with the electric quantity analysis module, the electric quantity analysis module and the intelligent cloud platform are connected with the credit feedback module, and the electric quantity analysis module is connected with the mutual inductance charging module.

The wireless identification module comprises an equipment receiving unit and an equipment sending unit, the equipment receiving unit is used for identifying the model of first user equipment, the equipment sending unit is used for identifying second user equipment with the electric quantity larger than a preset value, the equipment can be matched in time through the models of the two types of equipment, and the output end of the equipment receiving unit is connected with the input end of the equipment sending unit.

Preferably, the electric quantity analysis module includes a remaining electric quantity detection unit, an optimal power supply unit and an electric quantity transaction unit, the remaining electric quantity detection unit is used for detecting electric quantities of the first user equipment and the second user equipment so as to supply power to the charged equipment, the optimal power supply unit is used for charging the first user equipment by using the optimized curve of the equipment so that the charged equipment can supply power to the charging equipment according to the optimized curve, so that the remaining electric quantity of the charged user can be ensured to maintain the usage quantity of the charged user, the electric quantity transaction unit displays the charging result among the user equipment on the intelligent cloud platform in a block chain mode so that the multi-party equipment can view related data on the platform, once it is determined that any party cannot modify the parameters and the privacy of the equipment is ensured, and an output end of the remaining electric quantity detection unit, The output end of the optimal power supply unit is connected with the input end of the electric quantity transaction unit.

Preferably, the credit feedback module includes an active power supply recording unit, an integral setting unit and a result determining unit, where the active power supply recording unit is configured to detect whether an electric quantity of the first user equipment is smaller than a first preset value, the second user equipment charges the first user equipment with the electric quantity smaller than the first preset value, so as to ensure that the electric quantity of the user equipment in a certain range can maintain their usage level, the integral setting unit is configured to actively perform integral setting on the first user equipment with the electric quantity smaller than the first preset value, so that each user can actively supply power to a user needing to be charged, the result determining unit is configured to increase an electric quantity transmission rate of equipment reserved until an integral value is Q, and an output end of the active power supply recording unit, an output end of the integral setting unit and an input end of the integral determining unit are connected.

Preferably, the mutual inductance charging module comprises a GPRS positioning unit, a device charging unit and a power transmission unit, the GPRS positioning unit is used for positioning a device within a radius of X kilometers, therefore, the charging device can be stably powered, the device charging unit is used for detecting that the electric quantity values of the second user equipment within the radius X kilometer are all lower than a second preset value by taking the first user equipment as the center of a circle, the second user equipment in charging can be identified and detected, the electric quantity transmission unit is used for giving part of the electric quantity obtained by the second user equipment in charging to the first user equipment by means of wireless mutual inductance, thereby, the remote wireless power supply is carried out, so that the second user equipment can supply power to the first user equipment in this way, and the output end of the GPRS positioning unit is connected with the output ends of the equipment charging unit and the electric quantity transmission unit.

An intelligent mutual inductance type equipment charging management method comprises the following steps:

when the situation that the electric quantity of the first user equipment is insufficient is detected, detecting the residual electric quantity of the second user equipment around in real time, and sending a matching signal;

when the second user equipment receives the matching signal of the first user equipment, the second user equipment presumes the use time of the residual electric quantity of the second user equipment according to the electric quantity optimization curve, and judges whether the first user equipment can be charged according to the use time of the residual electric quantity of the second user equipment, wherein the second user equipment supplies power to the first user equipment according to the optimization curve, so that the residual electric quantity of the second user equipment can be ensured to be used by a user of the second user equipment;

if the second user equipment can charge the first user equipment, matching, and after the two pieces of equipment are successfully matched, charging the first user equipment by the second user equipment and storing the electric quantity transaction information of the two pieces of equipment in the platform;

if the electric quantity values of the second user equipment around the first user equipment are lower than a second preset value, detecting and identifying whether the second user equipment which is being charged exists, if so, matching, after the two pieces of equipment are successfully matched, remotely transmitting part of electric quantity obtained by the second user equipment which is being charged to the first user equipment according to the distance and the angle between a specified base station and each piece of equipment, and after the second user equipment which is being charged is successfully matched with the plurality of first user equipment, remotely transmitting the electric quantity between the second user equipment and the plurality of first user equipment;

when the fact that the residual electric quantity of the first user equipment in the effective range is smaller than a first preset value and the residual electric quantity of the second user equipment is higher than a second preset value is detected, an integral is set for the first user equipment, the integral is rewarded when the second user equipment actively charges the first user equipment, the integral is ranked from large to small, and the first N second user equipment in the ranking are rewarded to improve the electric quantity transmission rate when the second user equipment needs to be charged.

The method comprises the following steps of lending the current electric quantity value Q of equipment, the total electric quantity value W consumed by the equipment per minute, the optimal electric quantity value E of the equipment and the supporting time T of the residual electric quantity value, recording the data in real time, fitting and predicting the data by using a hyperplane regression equation and an MATLAB curve fitting method, and according to a formula:

Z＝λ+λQ_i+λW_i+λE_i+λT；

wherein Z is a function optimization model and λ is a model coefficient;

and inputting data into the MATLAB through the model, and inferring an optimal electric quantity value and the use time of the residual electric quantity of the second user equipment according to the use parameters of the second user equipment.

The score result of each second user equipment is Y ═ Y₁,Y₂,Y₃…Y_mRanking the score result Y from large to small, selecting the first N second user equipment, and increasing the electric quantity charging rate of the selected second user equipment, wherein the second user equipment actively transmits electric quantity and transmits the electric quantity to the first user equipment, and the provided electric quantity epsilon is { epsilon ═ epsilon { (epsilon) }₁,ε₂,ε₃…ε_mThe corresponding score coefficient is f ═ f { (f)₁,f₂,f₃…f_m}；

According to the formula:

wherein: epsilon_{General assembly}Sum of amount of power supplied to active power transfer device, H_{General assembly}As a total score, f is a score coefficient.

The base station carries out communication transmission with each device, and all first user equipment collected by the second user equipment in the detection range is P ═ P { (P)₁,P₂,P₃…P_mAnd when the second user equipment and the first user equipment perform energy transmission, an included angle formed by electromagnetic waves formed according to the position of the second user equipment and electromagnetic waves sensed by the ground base station is theta-theta₁,θ₂,θ₃…θ_mAnd the second user equipment performs remote electric quantity transmission on the matched first user equipment according to the formed included angle.

The step of the second user equipment and the plurality of first user equipment for transmitting the remote electric quantity is as follows:

s1: obtaining the model of each second user equipment and each first user equipment;

s2: positioning each detected device to obtain the geographical position information of the first user device and a plurality of second user devices;

s3: detecting an included angle generated by electromagnetic wave signals transmitted by the two devices and the ground base station, and transmitting electric quantity according to the generated included angle.

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

1. the optimal power supply unit is utilized, parameters in the equipment can be fitted in a combined mode of a hyperplane regression equation and MATLAB according to various parameters in the equipment, so that the time for using the residual electric quantity and the electric quantity which can be maintained for the first user equipment at most can be estimated according to related parameters, a mutual winning method for charging and being charged for the first user equipment and the second user equipment can be realized, in the electric quantity transaction unit, a result of multi-party transaction electric quantity is published on a multi-party screen in a block chain mode, electric quantity transaction information cannot be changed by any party, and the safety of electric quantity recharging is guaranteed;

2. the integral setting unit is utilized to enable the second user equipment to actively provide power for the first user equipment with low electric quantity in the range, so that the first user equipment with low electric quantity can maintain the electric quantity for users to use, and the result judging unit is utilized to accelerate the charging rate of the second user equipment when the integral value of the second user equipment needs to be charged when the integral value of the second user equipment is accumulated to a certain range;

3. by using the electric quantity transmission unit, when the first user equipment is detected to be lower than the lowest value, the charged electric quantity is remotely transmitted to the first user equipment by using the second user equipment which is charging, so that the first user equipment which needs to be charged can obtain the corresponding electric quantity for emergency, and the convenience of remotely charging the equipment are realized.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a block diagram of an intelligent mutual inductance device charging management system and method according to the present invention;

fig. 2 is a flowchart illustrating an intelligent mutual inductance device charging management system and method according to the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-2, the present invention provides the following technical solutions:

the system comprises a wireless identification module, an electric quantity analysis module, a credit feedback module, a mutual inductance type charging module and an intelligent cloud platform, wherein the wireless identification module is used for identifying and matching the device models of first user equipment and second user equipment in multiple ways, the connection between the devices can be more convenient and faster through identifying the device models, the electric quantity analysis module is used for optimizing a charging scheme for the first user equipment, so that the charged device can supply power to the charging device as much as possible according to the condition of the device per se, the credit feedback module is used for initiatively carrying out point exchange reward on the first user equipment which supplies power to the first user equipment, so that a user can actively help the user needing charging, the mutual inductance type charging module is used for remotely supplying power to the first user equipment which is successfully matched when the second user equipment is charged, the intelligent cloud platform is used for automatically storing data, the wireless identification module is connected with the electric quantity analysis module, the electric quantity analysis module and the intelligent cloud platform are connected with the credit feedback module, and the electric quantity analysis module is connected with the mutual inductance charging module.

Z＝λ+λQ_i+λW_i+λE_i+λT；

wherein Z is a function optimization model and λ is a model coefficient;

According to the formula:

Example 1: according to the situation summary, the platform publishes the score results among the devices, the score result of each user device is Y ═ {15,14,25, 10,20,22,22,26,18,13}, the top 5 ranked users are selected, the charging rate of the electric quantity is improved for the selected users, the charged device actively transmits the electric quantity and transmits the electric quantity to the needed charging device, wherein the provided electric quantity is ═ { epsilon ═ epsilon { [ epsilon ] }₁,ε₂,ε₃…ε_mThe corresponding score coefficient is f ═ f { (f)₁,f₂,f₃…f_m}；

According to the above summary, the ranking distribution of the ranked results from large to small is {26,25, 22,22, 20,18,15,14,13, 10}, the ranks of the top five are {26,25, 22,22, 20}, the charged device actively transmits the electric quantity and transmits the electric quantity to the required charged device, wherein the supplied electric quantity epsilon is {0.5,1,1.2, 0.7,1.4}, and the corresponding score coefficient is {1, 1,1,1, 1.5}

H_{General assembly}＝ε_{General assembly}×f＝0.5×1+1×1+1.2×1+0.7×1+1.5×1.4＝5.5；

Summarized according to example 1: the sum of the amount of power provided was 4.8, and the total score obtained was 5.5, the first five of which could increase the charge rate.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. An intelligent mutual inductance type equipment charging management method is characterized in that: the charging management method comprises the following steps:

2. The method of claim 1, wherein the method comprises: the method comprises the following steps of lending the current electric quantity value Q of equipment, the total electric quantity value W consumed by the equipment per minute, the optimal electric quantity value E of the equipment and the supporting time T of the residual electric quantity value, recording the data in real time, fitting and predicting the data by using a hyperplane regression equation and an MATLAB curve fitting method, and according to a formula:

Z＝λ+λQ_i+λW_i+λE_i+λT；

wherein Z is a function optimization model and λ is a model coefficient;

3. The method of claim 1, wherein the method comprises: the score result of each second user equipment is Y ═ Y₁,Y₂,Y₃…Y_mRanking the score result Y from large to small, selecting the first N second user equipment, and increasing the electric quantity charging rate of the selected second user equipment, wherein the second user equipment actively transmits electric quantity and transmits the electric quantity to the first user equipment, and the provided electric quantity epsilon is { epsilon ═ epsilon { (epsilon) }₁,ε₂,ε₃…ε_mThe corresponding score coefficient is f ═ f { (f)₁,f₂,f₃…f_m}；

According to the formula:

4. The method of claim 1, wherein the method comprises: the base station carries out communication transmission with each device, and all first user equipment collected by the second user equipment in the detection range is P ═ P { (P)₁,P₂,P₃…P_mAnd when the second user equipment and the first user equipment perform energy transmission, an included angle formed by electromagnetic waves formed according to the position of the second user equipment and electromagnetic waves sensed by the ground base station is theta-theta₁,θ₂,θ₃…θ_mAnd the second user equipment performs remote electric quantity transmission on the matched first user equipment according to the formed included angle.

5. The method of claim 1, wherein the method comprises: the step of the second user equipment and the plurality of first user equipment for transmitting the remote electric quantity is as follows:

6. A system of intelligent mutual inductance type device charging management method as claimed in claim 1, characterized in that: the system comprises a wireless identification module, an electric quantity analysis module, a credit feedback module, a mutual inductance type charging module and an intelligent cloud platform, the wireless identification module is used for identifying and matching the device models of a plurality of first user devices and second user devices, the electric quantity analysis module is used for optimizing a charging scheme for the first user equipment, the credit feedback module is used for actively exchanging points for rewards for the first user equipment which supplies power to the first user equipment, the mutual inductance type charging module is used for remotely supplying power to the first user equipment which is successfully matched when the second user equipment is charged, the intelligent cloud platform is used for automatically storing data, the wireless identification module is connected with the electric quantity analysis module, the electric quantity analysis module and the intelligent cloud platform are connected with the credit feedback module, and the electric quantity analysis module is connected with the mutual inductance charging module.

7. The system of claim 6, wherein the system comprises: the wireless identification module comprises an equipment receiving unit and an equipment sending unit, the equipment receiving unit is used for identifying the model of first user equipment, the equipment sending unit is used for identifying second user equipment with the electric quantity larger than a preset value, and the output end of the equipment receiving unit is connected with the input end of the equipment sending unit.

8. The system of claim 6, wherein the system comprises: the electric quantity analysis module comprises a residual electric quantity detection unit, an optimal power supply unit and an electric quantity transaction unit, the residual electric quantity detection unit is used for detecting the electric quantity of the first user equipment and the second user equipment, the optimal power supply unit is used for charging the first user equipment through an optimization curve of the equipment, the electric quantity transaction unit displays the charging result among the user equipment on the intelligent cloud platform in a block chain mode, and the output end of the residual electric quantity detection unit, the output end of the optimal power supply unit and the input end of the electric quantity transaction unit are connected.

9. The system of claim 6, wherein the system comprises: the credit feedback module comprises an active power supply recording unit, an integral setting unit and a result judging unit, wherein the active power supply recording unit is used for detecting whether the electric quantity of first user equipment is smaller than a first preset value, second user equipment charges the first user equipment with the electric quantity smaller than the first preset value, the integral setting unit is used for actively setting the integral of the first user equipment with the electric quantity smaller than the first preset value, the result judging unit is used for improving the transmission rate of the electric quantity of equipment with the stored integral value of Q, and the output ends of the active power supply recording unit and the integral setting unit are connected with the input end of the integral judging unit.

10. The system of claim 6, wherein the system comprises: mutual inductance formula module of charging includes GPRS positioning unit, equipment charging unit and electric quantity transmission unit, GPRS positioning unit is used for fixing a position the equipment with radius X kilometer scope, equipment charging unit is used for when detecting to use first user equipment as the centre of a circle, and radius X kilometer interior second user equipment electric quantity value all is less than the second default, can discern the detection to the second user equipment who is charging well, electric quantity transmission unit is used for utilizing wireless mutual inductance's mode to give first user equipment with the electric quantity part that the second user equipment that is charging obtained, GPRS positioning unit's output is connected with equipment charging unit and electric quantity transmission unit's output.