CN117369669B - Processing method and system for programming touch type energy switch panel - Google Patents

Abstract

The invention provides a processing method and a system for a programming touch type energy switch panel, which are applied to the field of panel data processing; according to the invention, the voltage difference between adjacent electrodes is acquired through differential measurement and mapped to screen coordinates to acquire the instruction content of a user again, so that the accuracy of the touch screen is improved, meanwhile, a dynamic calibration method is adopted, the calibration of the touch screen is realized through applying current and measuring voltage information, the performance of the touch screen can be continuously adjusted and optimized in the running process, the fault tolerance of the system is improved, a decentralization control and consensus mechanism is introduced, and the safety and stability of the system are improved by constructing node combinations.

Description

Processing method and system for programming touch type energy switch panel

Technical Field

The invention relates to the field of panel data processing, in particular to a processing method and a system for a programming touch type energy switch panel.

Background

The intelligent switch is a unit which utilizes the combination and programming of a control board and electronic components to realize circuit intelligent switch control, and the intelligent switch panel is more and more applied along with the continuous popularization of intelligent home in recent years.

Along with the daily accumulated touch point control of the user on the switch panel, the sensitivity of the switch panel can be gradually reduced, so that the switch panel can not reflect the touch control command of the user at the first time, and the recognition stability of the switch panel is affected.

Disclosure of Invention

The invention aims to solve the problem that the sensitivity of a switch panel is reduced after long-term use and the identification stability of the switch panel is affected, and provides a processing method and a processing system for a programmed touch type energy switch panel.

The invention adopts the following technical means for solving the technical problems:

the invention provides a processing method of a programmed touch type energy switch panel, which comprises the following steps:

detecting at least one key touch information of a user on a switch panel, feeding back a preset panel instruction to a corresponding processing unit based on the key touch information, and generating an electric signal of the switch panel;

judging whether the electric signal can execute the required content of the user or not;

if not, applying a preset milliamp of current to a touch screen azimuth preset by the switch panel, detecting voltage information existing in the touch screen azimuth, acquiring voltage differences between adjacent electrodes in the touch screen azimuth by adopting differential measurement, acquiring at least one resistance value at a touch point according to the voltage differences, mapping the resistance value to a corresponding screen coordinate at the touch point, generating each key touch coordinate point from the screen coordinate, and re-acquiring instruction content of the user to the switch panel by applying each key touch coordinate point;

Judging whether the execution process of the instruction content matches instruction information pre-input by the user;

if the key touch information is not matched, performing decentralization control on the key touch information, distributing the key touch coordinate points into node combinations according to a preset structure, and inputting preset common-knowledge mechanism content for the node combinations, wherein the node combinations are specifically composed of at least two or more key touch coordinate points, and the common-knowledge mechanism content specifically comprises workload evidence, bayesian fault tolerance and capacity evidence.

Further, the step of acquiring the voltage difference between adjacent electrodes in the touch screen azimuth by using differential measurement, acquiring at least one resistance value at a touch point according to the voltage difference, and mapping the resistance value to a corresponding screen coordinate at the touch point comprises the following steps:

arranging a group of electrodes on a touch screen based on a preset arrangement format, distributing the electrodes at all touch points on the touch screen, selecting two farthest electrodes from all touch points as a driving electrode and a measuring electrode respectively, measuring between the driving electrode and the measuring electrode by adopting a preset differential amplifier, and collecting voltage differences after amplified input;

Judging whether the voltage difference exceeds a voltage threshold preset by a voltage mapping table;

if not, carrying out error correction on the touch screen, and mapping a voltage coordinate on the screen coordinate on the touch screen according to the voltage difference, wherein the error correction specifically comprises multi-point touch correction, temperature compensation and displacement compensation.

Further, the step of performing the decentration control on the key touch information includes:

defining block elements of the switch panel based on a pre-designed block chain structure, wherein the block elements specifically comprise a block chain platform, transaction broadcasts and smart contracts;

judging whether the block element is non-tamper-resistant;

if yes, a preset blockchain platform is selected to develop an intelligent contract, the key touch information is used as a transaction to be broadcasted to a blockchain network, and the intelligent contract is applied to execute corresponding operation according to the received key touch information, wherein the corresponding operation is specifically that an authorized user can execute the corresponding operation after passing through an access control mechanism preset by the intelligent contract.

Further, before the step of re-acquiring the instruction content of the user to the switch panel by applying the touch coordinate points of the keys, the method further includes:

Outputting the key touch information to the switch panel by applying a test instruction of a preset calibration mode, and generating a test result of the switch panel;

judging whether the test result matches the test content of the test instruction;

if not, detecting interference factors in a preset range of the switch panel, and identifying the physical position of the switch panel, wherein the interference factors specifically comprise electromagnetic interference, temperature influence and ambient light induction.

Further, the step of determining whether the electrical signal can execute the content of the user's demand includes:

acquiring instruction content input by the user to the switch panel;

judging whether the instruction content matches with a preset execution instruction or not;

if not, defining the instruction content as an invalid instruction, and giving the user input permission for preset times through the switch panel, wherein the input permission is specifically permission for inputting complete instruction content to the switch panel.

Further, the step of determining whether the execution process of the instruction content matches the instruction information pre-input by the user includes:

acquiring voice content input by the user to the switch panel based on preset identity content;

Judging whether the voice content matches with a preset panel instruction or not;

if yes, the voice content is input into the switch panel, and the user is requested to output the instruction content which is the same as the panel instruction to the switch panel.

Further, the step of detecting at least one key touch information of the user to the switch panel and feeding back a preset panel instruction to the corresponding processing unit based on the key touch information includes:

a preset pressure sensor is applied to obtain the touch control force of the user on the keys;

judging whether the touch force is greater than the preset intensity of the switch panel or not;

if yes, synchronously acquiring multi-point touch information of the user on the switch panel, and generating the panel instruction based on the multi-point touch information.

The invention also provides a processing system for programming the touch energy switch panel, which comprises:

the detection module is used for detecting at least one key touch information of a user on the switch panel, feeding back a preset panel instruction to a corresponding processing unit based on the key touch information, and generating an electric signal of the switch panel;

the judging module is used for judging whether the electric signal can execute the required content of the user or not;

The execution module is used for applying a preset milliamp of current to a touch screen azimuth preset by the switch panel, detecting voltage information existing in the touch screen azimuth, acquiring voltage difference between adjacent electrodes in the touch screen azimuth by adopting differential measurement, acquiring at least one resistance value at a touch point according to the voltage difference, mapping the resistance value to a screen coordinate corresponding to the touch point, generating each key touch coordinate point from the screen coordinate, and re-acquiring instruction content of the user to the switch panel by applying each key touch coordinate point;

the second judging module is used for judging whether the execution process of the instruction content matches the instruction information pre-input by the user;

and the second execution module is used for carrying out decentralization control on the key touch information if the key touch information is not matched, distributing the key touch coordinate points into node combinations according to a preset structure, and inputting preset consensus mechanism content for the node combinations, wherein the node combinations are specifically composed of at least two or more key touch coordinate points, and the consensus mechanism content specifically comprises workload evidence, bayesian fault tolerance and capacity evidence.

Further, the execution module further includes:

the acquisition unit is used for arranging a group of electrodes on the touch screen based on a preset arrangement format, distributing the electrodes at all touch points on the touch screen, selecting two electrodes farthest from each touch point as a driving electrode and a measuring electrode respectively, measuring the driving electrode and the measuring electrode by adopting a preset differential amplifier, and acquiring the voltage difference after amplifying the input;

the judging unit is used for judging whether the voltage difference exceeds a voltage threshold preset by the voltage mapping table;

and the execution unit is used for carrying out error correction on the touch screen if not, and mapping the voltage coordinate on the screen coordinate on the touch screen according to the voltage difference, wherein the error correction specifically comprises multi-point touch correction, temperature compensation and displacement compensation.

Further, the second execution module further includes:

a definition unit for defining block elements of the switch panel based on a pre-designed block chain structure, wherein the block elements specifically include a block chain platform, transaction broadcasting and smart contracts;

a second judging unit for judging whether the block element has non-tamper property;

And the second execution unit is used for selecting a preset blockchain platform to develop an intelligent contract if the intelligent contract is generated, broadcasting the key touch information to a blockchain network as a transaction, and executing corresponding operation by applying the intelligent contract according to the received key touch information, wherein the corresponding operation is specifically that an authorized user can execute the corresponding operation after passing through an access control mechanism preset by the intelligent contract.

The invention provides a processing method and a processing system for a programmed touch type energy switch panel, which have the following beneficial effects:

according to the invention, the voltage difference between adjacent electrodes is acquired through differential measurement and mapped to screen coordinates to acquire the instruction content of a user again, so that the accuracy of the touch screen is improved, meanwhile, a dynamic calibration method is adopted, the calibration of the touch screen is realized through applying current and measuring voltage information, the performance of the touch screen can be continuously adjusted and optimized in the running process, the fault tolerance of the system is improved, a decentralization control and consensus mechanism is introduced, and the safety and stability of the system are improved by constructing node combinations.

Drawings

FIG. 1 is a schematic flow chart of an embodiment of a method for programming a touch energy switch panel according to the present invention;

FIG. 2 is a block diagram illustrating an embodiment of a processing system for programming a touch energy switch panel according to the present invention.

Detailed Description

It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the present invention, as the achievement, functional features, and advantages of the present invention are further described with reference to the embodiments, with reference to the accompanying drawings.

The technical solutions of 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 apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1, a method for processing a programmed touch energy switch panel according to an embodiment of the invention includes:

s1: detecting at least one key touch information of a user on a switch panel, feeding back a preset panel instruction to a corresponding processing unit based on the key touch information, and generating an electric signal of the switch panel;

S2: judging whether the electric signal can execute the required content of the user or not;

s3: if not, applying a preset milliamp of current to a touch screen azimuth preset by the switch panel, detecting voltage information existing in the touch screen azimuth, acquiring voltage differences between adjacent electrodes in the touch screen azimuth by adopting differential measurement, acquiring at least one resistance value at a touch point according to the voltage differences, mapping the resistance value to a corresponding screen coordinate at the touch point, generating each key touch coordinate point from the screen coordinate, and re-acquiring instruction content of the user to the switch panel by applying each key touch coordinate point;

s4: judging whether the execution process of the instruction content matches instruction information pre-input by the user;

s5: if the key touch information is not matched, performing decentralization control on the key touch information, distributing the key touch coordinate points into node combinations according to a preset structure, and inputting preset common-knowledge mechanism content for the node combinations, wherein the node combinations are specifically composed of at least two or more key touch coordinate points, and the common-knowledge mechanism content specifically comprises workload evidence, bayesian fault tolerance and capacity evidence.

In this embodiment, the system detects key touch information output by the user to the switch panel, and the switch panel feeds back a preset panel instruction to the corresponding processing unit based on the key touch information, so as to generate an electric signal executed by the switch panel, and then the system judges whether the electric signal can execute the content required by the user to execute the corresponding step; for example, when the system determines that the electrical signal can execute the required content of the user, the system can consider that the switch panel successfully recognizes and processes the operation of the user, and the generated electrical signal contains effective instruction information which can be accurately interpreted and executed by the system, the system can provide feedback for the user to confirm that the operation of the system is successfully executed, the system can be realized by means of icons, text prompts, sound signals and the like on a touch screen, the perceptibility of the response of the user to the system is enhanced, and meanwhile, the operation information of the user can be recorded in a system log so as to facilitate the examination, analysis and fault investigation of the system at a later time, and the operation and maintenance of the system are facilitated; for example, when the system determines that the electrical signal cannot execute the required content of the user, the system considers that the switch panel has a touch defect and cannot identify key touch information of the user, voltage information existing in the touch screen azimuth is detected by applying preset milliamp current to the touch screen azimuth preset by the switch panel, voltage difference between adjacent electrodes in the touch screen azimuth is acquired by using a differential measurement method, resistance values at touch points are acquired according to the voltage difference, the resistance values are mapped to screen coordinates of the corresponding switch panel at the touch points, each key touch coordinate point is generated again from the screen coordinates, the system can better understand actual touch intention of the user by applying the command content input by the user on the switch panel and composed of each key touch coordinate point, potential problems caused by inaccuracy of the touch screen are reduced, meanwhile, accuracy of the touch screen is improved, and error touch is reduced and operation accuracy of the user on the switch panel is improved; then the system judges whether the instruction content input by the user matches instruction information input by the user in advance through voice so as to execute corresponding steps; for example, when the system determines that the instruction content can match instruction information input by the instruction user in advance through voice, the system can execute corresponding operations or functions according to the successfully matched voice instruction, for example, opening/closing equipment, adjusting settings, executing specific tasks and the like, wherein the specific operations depend on the instruction information input by the user through voice and are realized through voice prompts, screen prompts or other forms of feedback, the confidence of the user on the response of the system is enhanced, and the system can record the successfully matched voice instruction of the user so as to analyze, recommend personalized or provide history record inquiry later, thereby being beneficial to improving the learning and adaptability of the system; for example, when the system determines that the instruction content cannot be matched with the instruction information input in advance by the user through voice, the system performs decentralization control on the key touch information, distributes the key touch coordinate points into node combinations according to a preset structure, inputs preset consensus mechanism content for the node combinations, so that the probability of single-point faults of the whole system is reduced, meanwhile, the introduction of the consensus mechanism is helpful for ensuring that the nodes of the system agree on the processing of the touch information, the reliability of the system is improved, the system can respond to the input of the user more flexibly, the decision of a single node is not relied on any more, and the adaptability of the system is improved.

It should be noted that, when the system determines that the instruction content does not match the instruction information that is input in advance by the instruction user through voice, the system may also consider that there may be some cases of misidentification, unclear voice input or that the system cannot correctly interpret the voice instruction, the system may attempt to confirm the instruction of the user again, by interacting with the user, inquiring whether to confirm the previous instruction or request the user to reform their requirements, so as to help eliminate possible misunderstanding, and at the same time, start man-machine interaction, by inquiring details or requesting more information, so as to better understand the intention of the user, so as to help clarify possible ambiguity or ambiguity.

The beneficial effects of three items of consensus mechanism content in the switch panel are exemplified as follows:

the workload proves that: the contribution of the nodes to the network is proved by requiring the nodes to complete certain calculation work, so that abuse is prevented, an attacker needs to spend a large amount of calculation resources to change the information on the blockchain, the attack difficulty is improved, the nodes in the distributed network are encouraged to complete calculation tasks together, the decentralization is promoted, and the control of the whole system by any single entity is prevented;

Bayesian fault tolerance: the mechanism allows the system to still normally operate under the condition that some malicious nodes or error nodes exist, ensures the safety of the system through the consistency of a plurality of nodes, does not influence the normal operation of the whole system even if a part of nodes have problems, can tolerate a certain number of Bayesian errors, and ensures that the system can still agree when communication problems or malicious attacks exist between the nodes;

capacity demonstration: allowing the node to prove its storage capacity rather than workload through computation can increase energy efficiency because a large amount of computation work is not required, and encouraging the node to fully utilize storage resources, participate in consensus by effectively using hard disk capacity, contributing to an increase in overall resource utilization efficiency of the network.

In this embodiment, the step S3 of acquiring the voltage difference between adjacent electrodes in the touch screen azimuth by using differential measurement, acquiring at least one resistance value at a touch point according to the voltage difference, and mapping the resistance value to the screen coordinates corresponding to the touch point includes:

s31: arranging a group of electrodes on a touch screen based on a preset arrangement format, distributing the electrodes at all touch points on the touch screen, selecting two farthest electrodes from all touch points as a driving electrode and a measuring electrode respectively, measuring between the driving electrode and the measuring electrode by adopting a preset differential amplifier, and collecting voltage differences after amplified input;

S32: judging whether the voltage difference exceeds a voltage threshold preset by a voltage mapping table;

s33: if not, carrying out error correction on the touch screen, and mapping a voltage coordinate on the screen coordinate on the touch screen according to the voltage difference, wherein the error correction specifically comprises multi-point touch correction, temperature compensation and displacement compensation.

In this embodiment, the system arranges a group of electrodes on the touch screen of the switch panel based on a preset arrangement format, the electrodes are fully distributed at each touch point of the touch screen, two electrodes farthest from each touch point are selected to be respectively used as a driving electrode and a measuring electrode, a preset differential amplifier is adopted to measure between the driving electrode and the measuring electrode so as to acquire the voltage difference after amplifying input, and then the system judges whether the voltage difference exceeds a voltage threshold preset by a voltage mapping table so as to execute corresponding steps; for example, when the system determines that the voltage difference exceeds a voltage threshold preset in the voltage difference table, the system considers that the signal of the touch screen is abnormal or the detection of a touch point is problematic, the system regards the situation as abnormal, records related error information and starts a corresponding abnormality processing mechanism, wherein the abnormality processing mechanism comprises providing error prompt for a user, triggering system alarm and logging, simultaneously attempting to recalibrate the touch screen, correcting possible errors through a calibration flow, providing related prompt for the user, and suggesting that the user check whether the touch screen works normally or take other operations; for example, when the system determines that the voltage difference does not exceed the voltage threshold value preset in the voltage mapping table, error correction may need to be performed due to non-ideality and external interference of the touch screen, that is, the system may perform error correction on the touch screen, map the voltage on the screen coordinates according to the voltage difference, for a touch screen supporting multi-touch, multi-touch correction needs to be performed to ensure that the system can accurately identify and track multiple touch points, and the performance of the touch screen may be affected by temperature change, so that the temperature sensor is introduced to perform correction by monitoring temperature change, ensure the accuracy of touch positions at different temperatures, and may cause deviation of touch positions due to physical displacement between the touch screen and the display screen, and error caused by physical deviation may be corrected by displacement compensation.

In this embodiment, the step S5 of performing the decentration control on the touch coordinate points of each key includes:

s51: defining block elements of the switch panel based on a pre-designed block chain structure, wherein the block elements specifically comprise a block chain platform, transaction broadcasts and smart contracts;

s52: judging whether the block element is non-tamper-resistant;

s53: if yes, a preset blockchain platform is selected to develop an intelligent contract, the key touch information is used as a transaction to be broadcasted to a blockchain network, and the intelligent contract is applied to execute corresponding operation according to the received key touch information, wherein the corresponding operation is specifically that an authorized user can execute the corresponding operation after passing through an access control mechanism preset by the intelligent contract.

In this embodiment, the system defines block elements of the switch panel based on a block chain structure which is designed in advance, and then the system determines whether the block elements have non-tamper property so as to execute corresponding steps; for example, when the system determines that the blockchain element does not have non-tamperability, the system considers that the security of the blockchain system is threatened, the risk of tampering or malicious modification exists for the data, and related operations on the blockchain element are immediately stopped by suspending related intelligent contracts, suspending transactions or freezing and settling accounts so as to prevent further malicious tampering, meanwhile, specific tampered contents are identified, measures can be taken to repair and restore the tampered data, and a tracing mechanism is introduced into the blockchain system to record the source and operators of each transaction, thereby being beneficial to tracing the occurrence point of a tampered event more easily; for example, when the system determines that the block element has non-tamperability, the system can select a preset block chain platform to develop an intelligent contract, key touch information is used as a transaction to be broadcast to the block chain network, the intelligent contract is applied to execute corresponding operation according to the key touch information input by a user on the switch panel, the user needs to be authorized by the system to perform the operation before the operation is executed, the intelligent contract is executed on the block chain, the security and the reliability of the system touch information are ensured, the key touch information is used as the transaction to be broadcast to the block chain network, the distributed storage of the information is ensured, the consistency of data is ensured through a consensus mechanism of the block chain, and meanwhile, only the authorized user can execute related key touch operation by utilizing an access control mechanism in the intelligent contract, so that the security of the system is improved.

In this embodiment, before the step S3 of re-obtaining the instruction content of the user to the switch panel by applying the touch coordinate points of each key, the method further includes:

s301: outputting the key touch information to the switch panel by applying a test instruction of a preset calibration mode, and generating a test result of the switch panel;

s302: judging whether the test result matches the test content of the test instruction;

s303: if not, detecting interference factors in a preset range of the switch panel, and identifying the physical position of the switch panel, wherein the interference factors specifically comprise electromagnetic interference, temperature influence and ambient light induction.

In this embodiment, the system outputs virtual key touch information to the switch panel by applying a preset calibration mode test instruction to generate a test result for the switch panel, and then the system judges whether the test result matches the test content of the test instruction to execute a corresponding step; for example, when the system determines that the test result can be matched with the test content of the test instruction, the system records the result of passing the test in a test log or a test report, which is helpful for establishing a test history record so as to analyze and track the test performance later, and simultaneously generates a detailed test report including the test environment information, the executed test case, the test result, the found problem, etc., which is helpful for comprehensively knowing the test condition and ensuring the accuracy and consistency of the test environment so as to improve the reliability of the test result to the maximum extent; for example, when the system determines that the test result cannot match the test content of the test instruction, the system detects an interference factor within a preset range of the switch panel, identifies a physical position of the switch panel, and checks whether electromagnetic interference exists in the surrounding environment, because the accuracy of the touch screen is affected, the touch screen is prevented from being used near equipment with strong electromagnetic fields, meanwhile, temperature change may affect the performance of the touch screen, the equipment is ensured to operate in a proper temperature range, or the touch screen with a temperature compensation function is considered to be replaced, and a light sensor may be affected by ambient light, so that the performance of the touch screen is affected, an attempt is required to perform calibration under different illumination conditions, or the setting of the light sensor is considered to be adjusted, finally, the physical position of the equipment is ensured not to change, and the movement or inclination of the equipment may cause a calibration problem.

In this embodiment, the step S2 of determining whether the electrical signal can execute the content of the user' S requirement includes:

s21: acquiring instruction content input by the user to the switch panel;

s22: judging whether the instruction content matches with a preset execution instruction or not;

s23: if not, defining the instruction content as an invalid instruction, and giving the user input permission for preset times through the switch panel, wherein the input permission is specifically permission for inputting complete instruction content to the switch panel.

In this embodiment, the system acquires the instruction content input by the user to the switch panel, and then determines whether the instruction content matches the execution instruction preset by the switch panel to execute the corresponding step; for example, when the system determines that the instruction content can match the execution instruction preset by the switch panel, the system can immediately execute the corresponding operation according to the matched execution instruction, and simultaneously provide explicit feedback for the user, confirm that the system has correctly understood and executed their input instruction, and further provide relevant information or prompts according to the instruction content input by the user, so as to meet the possible additional requirements of the user; for example, when the system determines that the instruction content cannot match with the preset execution instruction, the system defines the instruction content as an invalid instruction, gives the preset times of input permission to the user through the switch panel, increases the fault tolerance of the system by giving the user multiple input permission, gives multiple attempts to the user the possibility that the instruction cannot be correctly identified due to accent, inaccurate pronunciation or other reasons, reduces the risk of misoperation, and simultaneously helps the user learn how to effectively interact with the system by prompting or feeding back how to provide the instruction more accurately, and helps to reduce the fatigue of the user and improve the endurance of the user by reducing the times that the user needs to restart the whole interaction flow after one unsuccessful input.

In this embodiment, the step S4 of determining whether the execution process of the instruction content matches the instruction information pre-input by the user includes:

s41: acquiring voice content input by the user to the switch panel based on preset identity content;

s42: judging whether the voice content matches with a preset panel instruction or not;

s43: if yes, the voice content is input into the switch panel, and the user is requested to output the instruction content which is the same as the panel instruction to the switch panel.

In this embodiment, the system acquires voice contents input by the user to the switch panel based on preset identity contents, and then the system judges whether the voice contents match with a panel voice instruction preset on the switch panel to execute corresponding steps; for example, when the system determines that the voice content cannot match the panel voice command, the system prompts the user to retry sending a clear and accurate voice command, gives the user guidance such as changing the expression, adjusting the speech speed, increasing the volume, etc. to improve the accuracy of voice recognition, and simultaneously, through the context understanding of the user's possible intention, performs automatic correction or provides correction advice to improve the accuracy of the voice command, and provides the user with a list of alternative voice commands, from which the user selects; for example, when the system determines that the voice content can match the preset panel instruction, the system inputs the voice content into the switch panel at this time, and requests the user to output the instruction content identical to the panel instruction to the switch panel, so as to obtain double verification of the switch panel to the user input instruction, after the user inputs the instruction through voice, the system can ensure that the actual intention of the user is consistent with the understanding of the system through double verification, so as to help avoid misunderstanding or misoperation, improve the accuracy of user input, meanwhile, double verification reduces the risk of misoperation caused by voice recognition errors, the accent, pronunciation or environmental noise of the user can cause the inaccuracy of voice recognition, the probability of misoperation can be reduced by requiring user confirmation, and the safety of the system is increased by double verification, if a malicious attacker tries to perform operation by mimicking voice input, unauthorized access can be reduced by requiring user confirmation.

In this embodiment, detecting at least one key touch information of a user to a switch panel, and feeding back a preset panel instruction to a corresponding processing unit based on the key touch information, where step S1 includes:

s11: a preset pressure sensor is applied to obtain the touch control force of the user on the keys;

s12: judging whether the touch force is greater than the preset intensity of the switch panel or not;

s13: if yes, synchronously acquiring multi-point touch information of the user on the switch panel, and generating the panel instruction based on the multi-point touch information.

In this embodiment, the system uses a preset pressure sensor to obtain the touch force of the user on the key, and then the system judges whether the touch force is greater than the preset intensity of the switch panel to execute the corresponding steps; for example, when the system determines that the touch strength is not greater than the strength of the switch panel, the system provides explicit feedback to the user, indicating that the touch strength is insufficient to trigger the operation, by using a screen prompt, a voice prompt or other feedback modes, so as to guide the user to take appropriate measures, and dynamically adjust the sensitivity of the touch panel according to the feedback or habit of the user, so as to be beneficial to adapting to the touch habits of different users, and prompt the user to increase the touch strength, so as to ensure that the touch can be effectively identified and triggered, and guiding by means of voice guidance, screen prompt or vibration feedback; for example, when the system determines that the touch strength is greater than the preset strength of the switch panel, the system synchronously collects multi-touch information of the user on the switch panel, generates a panel instruction based on the multi-touch information, and allows the user to simultaneously perform a plurality of touch operations, thereby improving the operation efficiency. The user can execute a plurality of instructions at one time without completing the instructions in sequence, so that the time cost of operation is reduced, and meanwhile, the multi-point touch control can provide more accurate positioning information, so that the system can more accurately identify the touch position of the user, and the multi-point touch control method is important for executing fine operation or selecting in a small area.

Referring to fig. 2, a processing system for programming a touch energy switch panel in accordance with an embodiment of the present invention comprises:

the detection module 10 is configured to detect at least one key touch information of a user on a switch panel, and feed back a preset panel instruction to a corresponding processing unit based on the key touch information, so as to generate an electrical signal of the switch panel;

a judging module 20, configured to judge whether the electrical signal can execute the content required by the user;

the execution module 30 is configured to apply a current of a preset milliamp to a touch screen orientation preset on the switch panel, detect voltage information existing in the touch screen orientation, acquire a voltage difference between adjacent electrodes in the touch screen orientation by using differential measurement, acquire at least one resistance value at a touch point according to the voltage difference, map the resistance value to a screen coordinate corresponding to the touch point, generate each key touch coordinate point location from the screen coordinate, and re-acquire instruction content of the user to the switch panel by applying each key touch coordinate point location;

a second judging module 40, configured to judge whether the execution process of the instruction content matches the instruction information pre-input by the user;

The second execution module 50 is configured to perform decentralizing control on the key touch information if the key touch information is not matched, distribute the key touch coordinate points into node combinations according to a preset structure, and input preset consensus mechanism content for the node combinations, where the node combinations specifically include at least two or more key touch coordinate points, and the consensus mechanism content specifically includes workload evidence, bayer fault tolerance and capacity evidence.

In this embodiment, the detection module 10 detects the key touch information output by the user to the switch panel, and the switch panel feeds back the preset panel instruction to the corresponding processing unit based on the key touch information, so as to generate an electrical signal executed by the switch panel, and then the judgment module 20 judges whether the electrical signal can execute the content required by the user to execute the corresponding steps; for example, when the system determines that the electrical signal can execute the required content of the user, the system can consider that the switch panel successfully recognizes and processes the operation of the user, and the generated electrical signal contains effective instruction information which can be accurately interpreted and executed by the system, the system can provide feedback for the user to confirm that the operation of the system is successfully executed, the system can be realized by means of icons, text prompts, sound signals and the like on a touch screen, the perceptibility of the response of the user to the system is enhanced, and meanwhile, the operation information of the user can be recorded in a system log so as to facilitate the examination, analysis and fault investigation of the system at a later time, and the operation and maintenance of the system are facilitated; for example, when the system determines that the electrical signal cannot execute the required content of the user, the execution module 30 considers that the switch panel has a touch defect and cannot identify the key touch information of the user, and applies a preset milliamp current to a touch screen azimuth preset on the switch panel to detect voltage information existing in the touch screen azimuth, acquires a voltage difference between adjacent electrodes in the touch screen azimuth by using a differential measurement method, acquires resistance values at touch points according to the voltage difference, maps the resistance values to screen coordinates of the corresponding switch panel at the touch points, and re-generates each key touch coordinate point from the screen coordinates, and re-acquires instruction content input by the user on the switch panel by using each key touch coordinate point, so that the system can better understand the actual touch intention of the user through a calibration process, reduce potential problems caused by inaccuracy of the touch screen, and simultaneously improve the accuracy of the touch screen, thereby being beneficial to reducing false touches and improving the operation accuracy of the user on the switch panel; the second judging module 40 then executes the corresponding steps by judging whether the instruction content input by the user matches the instruction information input by the user in advance through voice; for example, when the system determines that the instruction content can match instruction information input by the instruction user in advance through voice, the system can execute corresponding operations or functions according to the successfully matched voice instruction, for example, opening/closing equipment, adjusting settings, executing specific tasks and the like, wherein the specific operations depend on the instruction information input by the user through voice and are realized through voice prompts, screen prompts or other forms of feedback, the confidence of the user on the response of the system is enhanced, and the system can record the successfully matched voice instruction of the user so as to analyze, recommend personalized or provide history record inquiry later, thereby being beneficial to improving the learning and adaptability of the system; for example, when the system determines that the instruction content cannot match the instruction information input in advance by the user through voice, the second execution module 50 performs the decentralization control on the key touch information, distributes the key touch coordinate points into node combinations according to the preset structure, and inputs preset consensus mechanism content for the node combinations, so that the probability of single-point failure of the whole system is reduced, meanwhile, the introduction of the consensus mechanism is helpful to ensure that the nodes of the system agree on the processing of the touch information, the reliability of the system is improved, the system can respond to the input of the user more flexibly, the decision of a single node is not relied on, and the adaptability of the system is improved.

In this embodiment, the execution module further includes:

the acquisition unit is used for arranging a group of electrodes on the touch screen based on a preset arrangement format, distributing the electrodes at all touch points on the touch screen, selecting two electrodes farthest from each touch point as a driving electrode and a measuring electrode respectively, measuring the driving electrode and the measuring electrode by adopting a preset differential amplifier, and acquiring the voltage difference after amplifying the input;

the judging unit is used for judging whether the voltage difference exceeds a voltage threshold preset by the voltage mapping table;

and the execution unit is used for carrying out error correction on the touch screen if not, and mapping the voltage coordinate on the screen coordinate on the touch screen according to the voltage difference, wherein the error correction specifically comprises multi-point touch correction, temperature compensation and displacement compensation.

In this embodiment, the system arranges a group of electrodes on the touch screen of the switch panel based on a preset arrangement format, the electrodes are fully distributed at each touch point of the touch screen, two electrodes farthest from each touch point are selected to be respectively used as a driving electrode and a measuring electrode, a preset differential amplifier is adopted to measure between the driving electrode and the measuring electrode so as to acquire the voltage difference after amplifying input, and then the system judges whether the voltage difference exceeds a voltage threshold preset by a voltage mapping table so as to execute corresponding steps; for example, when the system determines that the voltage difference exceeds a voltage threshold preset in the voltage difference table, the system considers that the signal of the touch screen is abnormal or the detection of a touch point is problematic, the system regards the situation as abnormal, records related error information and starts a corresponding abnormality processing mechanism, wherein the abnormality processing mechanism comprises providing error prompt for a user, triggering system alarm and logging, simultaneously attempting to recalibrate the touch screen, correcting possible errors through a calibration flow, providing related prompt for the user, and suggesting that the user check whether the touch screen works normally or take other operations; for example, when the system determines that the voltage difference does not exceed the voltage threshold value preset in the voltage mapping table, error correction may need to be performed due to non-ideality and external interference of the touch screen, that is, the system may perform error correction on the touch screen, map the voltage on the screen coordinates according to the voltage difference, for a touch screen supporting multi-touch, multi-touch correction needs to be performed to ensure that the system can accurately identify and track multiple touch points, and the performance of the touch screen may be affected by temperature change, so that the temperature sensor is introduced to perform correction by monitoring temperature change, ensure the accuracy of touch positions at different temperatures, and may cause deviation of touch positions due to physical displacement between the touch screen and the display screen, and error caused by physical deviation may be corrected by displacement compensation.

In this embodiment, the second execution module further includes:

a definition unit for defining block elements of the switch panel based on a pre-designed block chain structure, wherein the block elements specifically include a block chain platform, transaction broadcasting and smart contracts;

a second judging unit for judging whether the block element has non-tamper property;

and the second execution unit is used for selecting a preset blockchain platform to develop an intelligent contract if the intelligent contract is generated, broadcasting the key touch information to a blockchain network as a transaction, and executing corresponding operation by applying the intelligent contract according to the received key touch information, wherein the corresponding operation is specifically that an authorized user can execute the corresponding operation after passing through an access control mechanism preset by the intelligent contract.

In this embodiment, the system defines block elements of the switch panel based on a block chain structure which is designed in advance, and then the system determines whether the block elements have non-tamper property so as to execute corresponding steps; for example, when the system determines that the blockchain element does not have non-tamperability, the system considers that the security of the blockchain system is threatened, the risk of tampering or malicious modification exists for the data, and related operations on the blockchain element are immediately stopped by suspending related intelligent contracts, suspending transactions or freezing and settling accounts so as to prevent further malicious tampering, meanwhile, specific tampered contents are identified, measures can be taken to repair and restore the tampered data, and a tracing mechanism is introduced into the blockchain system to record the source and operators of each transaction, thereby being beneficial to tracing the occurrence point of a tampered event more easily; for example, when the system determines that the block element has non-tamperability, the system can select a preset block chain platform to develop an intelligent contract, key touch information is used as a transaction to be broadcast to the block chain network, the intelligent contract is applied to execute corresponding operation according to the key touch information input by a user on the switch panel, the user needs to be authorized by the system to perform the operation before the operation is executed, the intelligent contract is executed on the block chain, the security and the reliability of the system touch information are ensured, the key touch information is used as the transaction to be broadcast to the block chain network, the distributed storage of the information is ensured, the consistency of data is ensured through a consensus mechanism of the block chain, and meanwhile, only the authorized user can execute related key touch operation by utilizing an access control mechanism in the intelligent contract, so that the security of the system is improved.

In this embodiment, further comprising:

the testing module is used for outputting the key touch information to the switch panel by applying a testing instruction of a preset calibration mode and generating a testing result of the switch panel;

the third judging module is used for judging whether the test result is matched with the test content of the test instruction;

and the third execution module is used for detecting interference factors in a preset range of the switch panel and identifying the physical position of the switch panel if the interference factors are not, wherein the interference factors specifically comprise electromagnetic interference, temperature influence and ambient light induction.

In this embodiment, the system outputs virtual key touch information to the switch panel by applying a preset calibration mode test instruction to generate a test result for the switch panel, and then the system judges whether the test result matches the test content of the test instruction to execute a corresponding step; for example, when the system determines that the test result can be matched with the test content of the test instruction, the system records the result of passing the test in a test log or a test report, which is helpful for establishing a test history record so as to analyze and track the test performance later, and simultaneously generates a detailed test report including the test environment information, the executed test case, the test result, the found problem, etc., which is helpful for comprehensively knowing the test condition and ensuring the accuracy and consistency of the test environment so as to improve the reliability of the test result to the maximum extent; for example, when the system determines that the test result cannot match the test content of the test instruction, the system detects an interference factor within a preset range of the switch panel, identifies a physical position of the switch panel, and checks whether electromagnetic interference exists in the surrounding environment, because the accuracy of the touch screen is affected, the touch screen is prevented from being used near equipment with strong electromagnetic fields, meanwhile, temperature change may affect the performance of the touch screen, the equipment is ensured to operate in a proper temperature range, or the touch screen with a temperature compensation function is considered to be replaced, and a light sensor may be affected by ambient light, so that the performance of the touch screen is affected, an attempt is required to perform calibration under different illumination conditions, or the setting of the light sensor is considered to be adjusted, finally, the physical position of the equipment is ensured not to change, and the movement or inclination of the equipment may cause a calibration problem.

In this embodiment, the judging module further includes:

the acquisition unit is used for acquiring instruction content input by the user to the switch panel;

the third judging unit is used for judging whether the instruction content matches with a preset execution instruction;

and the third execution unit is used for defining the instruction content as an invalid instruction if not, and giving the user input permission for preset times through the switch panel, wherein the input permission is specifically permission for inputting complete instruction content to the switch panel.

In this embodiment, the system acquires the instruction content input by the user to the switch panel, and then determines whether the instruction content matches the execution instruction preset by the switch panel to execute the corresponding step; for example, when the system determines that the instruction content can match the execution instruction preset by the switch panel, the system can immediately execute the corresponding operation according to the matched execution instruction, and simultaneously provide explicit feedback for the user, confirm that the system has correctly understood and executed their input instruction, and further provide relevant information or prompts according to the instruction content input by the user, so as to meet the possible additional requirements of the user; for example, when the system determines that the instruction content cannot match with the preset execution instruction, the system defines the instruction content as an invalid instruction, gives the preset times of input permission to the user through the switch panel, increases the fault tolerance of the system by giving the user multiple input permission, gives multiple attempts to the user the possibility that the instruction cannot be correctly identified due to accent, inaccurate pronunciation or other reasons, reduces the risk of misoperation, and simultaneously helps the user learn how to effectively interact with the system by prompting or feeding back how to provide the instruction more accurately, and helps to reduce the fatigue of the user and improve the endurance of the user by reducing the times that the user needs to restart the whole interaction flow after one unsuccessful input.

In this embodiment, the second judging module further includes:

the acquisition unit is used for acquiring voice content input by the user to the switch panel based on preset identity content;

a fourth judging unit, configured to judge whether the voice content matches a preset panel instruction;

and the fourth execution unit is used for inputting the voice content into the switch panel if the voice content is yes, and requesting the user to output the instruction content which is the same as the panel instruction to the switch panel.

In this embodiment, the system acquires voice contents input by the user to the switch panel based on preset identity contents, and then the system judges whether the voice contents match with a panel voice instruction preset on the switch panel to execute corresponding steps; for example, when the system determines that the voice content cannot match the panel voice command, the system prompts the user to retry sending a clear and accurate voice command, gives the user guidance such as changing the expression, adjusting the speech speed, increasing the volume, etc. to improve the accuracy of voice recognition, and simultaneously, through the context understanding of the user's possible intention, performs automatic correction or provides correction advice to improve the accuracy of the voice command, and provides the user with a list of alternative voice commands, from which the user selects; for example, when the system determines that the voice content can match the preset panel instruction, the system inputs the voice content into the switch panel at this time, and requests the user to output the instruction content identical to the panel instruction to the switch panel, so as to obtain double verification of the switch panel to the user input instruction, after the user inputs the instruction through voice, the system can ensure that the actual intention of the user is consistent with the understanding of the system through double verification, so as to help avoid misunderstanding or misoperation, improve the accuracy of user input, meanwhile, double verification reduces the risk of misoperation caused by voice recognition errors, the accent, pronunciation or environmental noise of the user can cause the inaccuracy of voice recognition, the probability of misoperation can be reduced by requiring user confirmation, and the safety of the system is increased by double verification, if a malicious attacker tries to perform operation by mimicking voice input, unauthorized access can be reduced by requiring user confirmation.

In this embodiment, the detection module further includes:

the second acquisition unit is used for acquiring the touch control force of the user on the keys by applying a preset pressure sensor;

a fifth judging unit, configured to judge whether the touch force is greater than a preset intensity of the switch panel;

and the fifth execution unit is used for synchronously acquiring the multi-touch information of the user on the switch panel if yes, and generating the panel instruction based on the multi-touch information.

In this embodiment, the system uses a preset pressure sensor to obtain the touch force of the user on the key, and then the system judges whether the touch force is greater than the preset intensity of the switch panel to execute the corresponding steps; for example, when the system determines that the touch strength is not greater than the strength of the switch panel, the system provides explicit feedback to the user, indicating that the touch strength is insufficient to trigger the operation, by using a screen prompt, a voice prompt or other feedback modes, so as to guide the user to take appropriate measures, and dynamically adjust the sensitivity of the touch panel according to the feedback or habit of the user, so as to be beneficial to adapting to the touch habits of different users, and prompt the user to increase the touch strength, so as to ensure that the touch can be effectively identified and triggered, and guiding by means of voice guidance, screen prompt or vibration feedback; for example, when the system determines that the touch strength is greater than the preset strength of the switch panel, the system synchronously collects multi-touch information of the user on the switch panel, generates a panel instruction based on the multi-touch information, and allows the user to simultaneously perform a plurality of touch operations, thereby improving the operation efficiency. The user can execute a plurality of instructions at one time without completing the instructions in sequence, so that the time cost of operation is reduced, and meanwhile, the multi-point touch control can provide more accurate positioning information, so that the system can more accurately identify the touch position of the user, and the multi-point touch control method is important for executing fine operation or selecting in a small area.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The processing method of the programming touch type energy switch panel is characterized by comprising the following steps of:

detecting at least one key touch information of a user on a switch panel, feeding back a preset panel instruction to a corresponding processing unit based on the key touch information, and generating an electric signal of the switch panel;

judging whether the electric signal can execute the required content of the user or not;

if not, applying a preset milliamp of current to a touch screen azimuth preset by the switch panel, detecting voltage information existing in the touch screen azimuth, acquiring voltage differences between adjacent electrodes in the touch screen azimuth by adopting differential measurement, acquiring at least one resistance value at a touch point according to the voltage differences, mapping the resistance value to a corresponding screen coordinate at the touch point, generating each key touch coordinate point from the screen coordinate, and re-acquiring instruction content of the user to the switch panel by applying each key touch coordinate point;

Judging whether the execution process of the instruction content matches instruction information pre-input by the user;

if the key touch information is not matched, performing decentralization control on the key touch information, distributing the key touch coordinate points into node combinations according to a preset structure, and inputting preset common-knowledge mechanism content for the node combinations, wherein the node combinations are specifically composed of at least two or more key touch coordinate points, and the common-knowledge mechanism content specifically comprises workload evidence, bayesian fault tolerance and capacity evidence;

the step of acquiring the voltage difference between adjacent electrodes in the touch screen azimuth by adopting differential measurement, acquiring at least one resistance value at a touch point according to the voltage difference, and mapping the resistance value to a corresponding screen coordinate at the touch point comprises the following steps:

arranging a group of electrodes on a touch screen based on a preset arrangement format, distributing the electrodes at all touch points on the touch screen, selecting two farthest electrodes from all touch points as a driving electrode and a measuring electrode respectively, measuring between the driving electrode and the measuring electrode by adopting a preset differential amplifier, and collecting voltage differences after amplified input;

Judging whether the voltage difference exceeds a voltage threshold preset by a voltage mapping table;

if not, carrying out error correction on the touch screen, and mapping a voltage coordinate on the screen coordinate on the touch screen according to the voltage difference, wherein the error correction specifically comprises multi-point touch correction, temperature compensation and displacement compensation.

2. The method for processing a programmed touch energy switch panel according to claim 1, wherein the step of performing the decentralization control on the key touch information comprises:

defining block elements of the switch panel based on a pre-designed block chain structure, wherein the block elements specifically comprise a block chain platform, transaction broadcasts and smart contracts;

judging whether the block element is non-tamper-resistant;

if yes, a preset blockchain platform is selected to develop an intelligent contract, the key touch information is used as a transaction to be broadcasted to a blockchain network, and the intelligent contract is applied to execute corresponding operation according to the received key touch information, wherein the corresponding operation is specifically that an authorized user can execute the corresponding operation after passing through an access control mechanism preset by the intelligent contract.

3. The method for processing a programmed touch energy switch panel according to claim 1, wherein before the step of re-acquiring the instruction content of the user to the switch panel by applying the touch coordinate points of each key, the method further comprises:

outputting the key touch information to the switch panel by applying a test instruction of a preset calibration mode, and generating a test result of the switch panel;

judging whether the test result matches the test content of the test instruction;

if not, detecting interference factors in a preset range of the switch panel, and identifying the physical position of the switch panel, wherein the interference factors specifically comprise electromagnetic interference, temperature influence and ambient light induction.

4. The method of claim 1, wherein the step of determining whether the electrical signal is capable of executing the user's desired content comprises:

acquiring instruction content input by the user to the switch panel;

judging whether the instruction content matches with a preset execution instruction or not;

if not, defining the instruction content as an invalid instruction, and giving the user input permission for preset times through the switch panel, wherein the input permission is specifically permission for inputting complete instruction content to the switch panel.

5. The method according to claim 1, wherein the step of determining whether the execution process of the instruction content matches the instruction information pre-input by the user comprises:

acquiring voice content input by the user to the switch panel based on preset identity content;

judging whether the voice content matches with a preset panel instruction or not;

if yes, the voice content is input into the switch panel, and the user is requested to output the instruction content which is the same as the panel instruction to the switch panel.

6. The method for processing a programmed touch energy switch panel according to claim 1, wherein the step of detecting at least one key touch information of a user to the switch panel and feeding back a preset panel instruction to a corresponding processing unit based on the key touch information comprises:

a preset pressure sensor is applied to obtain the touch control force of the user on the keys;

judging whether the touch force is greater than the preset intensity of the switch panel or not;

if yes, synchronously acquiring multi-point touch information of the user on the switch panel, and generating the panel instruction based on the multi-point touch information.

7. A processing system for programming a touch energy switch panel, comprising:

the detection module is used for detecting at least one key touch information of a user on the switch panel, feeding back a preset panel instruction to a corresponding processing unit based on the key touch information, and generating an electric signal of the switch panel;

the judging module is used for judging whether the electric signal can execute the required content of the user or not;

the execution module is used for applying a preset milliamp of current to a touch screen azimuth preset by the switch panel, detecting voltage information existing in the touch screen azimuth, acquiring voltage difference between adjacent electrodes in the touch screen azimuth by adopting differential measurement, acquiring at least one resistance value at a touch point according to the voltage difference, mapping the resistance value to a screen coordinate corresponding to the touch point, generating each key touch coordinate point from the screen coordinate, and re-acquiring instruction content of the user to the switch panel by applying each key touch coordinate point;

the second judging module is used for judging whether the execution process of the instruction content matches the instruction information pre-input by the user;

The second execution module is used for carrying out decentralization control on the key touch information if the key touch information is not matched, distributing the key touch coordinate points into node combinations according to a preset structure, and inputting preset consensus mechanism content for the node combinations, wherein the node combinations are specifically composed of at least two or more key touch coordinate points, and the consensus mechanism content specifically comprises workload evidence, bayesian fault tolerance and capacity evidence;

wherein the execution module further comprises:

the acquisition unit is used for arranging a group of electrodes on the touch screen based on a preset arrangement format, distributing the electrodes at all touch points on the touch screen, selecting two electrodes farthest from each touch point as a driving electrode and a measuring electrode respectively, measuring the driving electrode and the measuring electrode by adopting a preset differential amplifier, and acquiring the voltage difference after amplifying the input;

the judging unit is used for judging whether the voltage difference exceeds a voltage threshold preset by the voltage mapping table;

and the execution unit is used for carrying out error correction on the touch screen if not, and mapping the voltage coordinate on the screen coordinate on the touch screen according to the voltage difference, wherein the error correction specifically comprises multi-point touch correction, temperature compensation and displacement compensation.

8. The system of claim 7, wherein the second execution module further comprises:

a definition unit for defining block elements of the switch panel based on a pre-designed block chain structure, wherein the block elements specifically include a block chain platform, transaction broadcasting and smart contracts;

a second judging unit for judging whether the block element has non-tamper property;

and the second execution unit is used for selecting a preset blockchain platform to develop an intelligent contract if the intelligent contract is generated, broadcasting the key touch information to a blockchain network as a transaction, and executing corresponding operation by applying the intelligent contract according to the received key touch information, wherein the corresponding operation is specifically that an authorized user can execute the corresponding operation after passing through an access control mechanism preset by the intelligent contract.