CN117675911A - Concentrator remote communication system and concentrator with self-adaptive signal optimization function - Google Patents

Abstract

The invention discloses a concentrator remote communication system with self-adaptive signal optimization, which comprises: the signal optimizing unit is used for receiving signals from a plurality of sources and automatically adjusting signal processing parameters to optimize signal quality so as to obtain optimized signals; the concentrator unit is used for converging the optimized signals from the signal optimizing module and integrating the optimized signals into a unified data stream; a remote communication unit for transmitting the data integrated by the concentrator module to a predetermined remote location through a wireless network; and the management unit is used for monitoring and managing the operation state of the remote communication system of the concentrator, wherein the operation state comprises signal quality, data flow and remote communication state. Integrating data from different sources simplifies the data processing flow and makes the system more efficient.

Description

Concentrator remote communication system and concentrator with self-adaptive signal optimization function

Technical Field

The invention relates to the technical field of communication, in particular to a concentrator remote communication system and a concentrator with self-adaptive signal optimization.

Background

At present, the concentrator remote communication system is widely applied in a plurality of industries, and particularly in the fields of data centers, communication networks, smart grids and the like. The primary purpose of such systems is to efficiently collect, process and transmit data.

Current telecommunication systems typically employ advanced signal processing techniques to improve transmission efficiency and signal quality, including using various coding, modulation, demodulation, and signal enhancement techniques to optimize the transmission process; concentrators play an important role in telecommunication systems, not only as a collection point for data, but also in handling and forwarding information, and in some systems, concentrators are also responsible for performing data analysis and management tasks. Although the prior art can alleviate signal interference and attenuation problems to some extent, challenges remain in high interference environments or long distance transmissions; the system has the problems of inflexibility and low transmission efficiency facing extreme network conditions and continuously changing data flow requirements; as the amount of data increases, ensuring security and privacy protection of data transmissions is becoming increasingly important. Existing systems need to be continually updated to cope with emerging security threats.

Therefore, there is an urgent need for a concentrator telecommunication system and concentrator with adaptive signal optimization.

Disclosure of Invention

The invention provides a concentrator remote communication system and a concentrator with self-adaptive signal optimization, which are used for solving the problems of signal interference and attenuation in the prior art, but still face challenges in a high-interference environment or long-distance transmission; the system has the problems of inflexibility and low transmission efficiency facing extreme network conditions and continuously changing data flow requirements; as the amount of data increases, ensuring the security and privacy protection of data transmission has also become increasingly important.

In order to achieve the above purpose, the present invention provides the following technical solutions:

a concentrator telecommunications system with adaptive signal optimization, comprising:

the signal optimizing unit is used for receiving signals from a plurality of sources and automatically adjusting signal processing parameters to optimize signal quality so as to obtain optimized signals;

the concentrator unit is used for converging the optimized signals from the signal optimizing module and integrating the optimized signals into a unified data stream;

a remote communication unit for transmitting the data integrated by the concentrator module to a predetermined remote location through a wireless network;

and the management unit is used for monitoring and managing the operation state of the remote communication system of the concentrator, wherein the operation state comprises signal quality, data flow and remote communication state.

Wherein the signal optimizing unit includes: the system comprises a signal receiving module, a signal analyzing module and a self-adaptive adjusting module;

a signal receiving module for receiving signals from a plurality of signal sources, the signal sources including a wireless network, a wired network, or a communication device;

the signal analysis module is connected with the signal receiving module and used for analyzing the received signal characteristics, wherein the signal characteristics comprise parameters of signal strength, signal interference and signal delay, and automatically adjusting signal processing parameters based on analysis results so as to optimize signal quality;

The self-adaptive adjustment module is used for dynamically adjusting a signal processing strategy according to the environmental change and the signal source characteristic, wherein the signal processing strategy comprises gain adjustment, noise suppression and frequency selection.

Wherein the concentrator unit comprises: the system comprises a data aggregation module, a data integration and distribution module and an adaptive communication interface module;

the data convergence module is used for receiving the optimized signals, processing the optimized signals with different frequencies and formats and converting the optimized signals into data streams with uniform formats;

the data integration and distribution module is used for further integrating the data streams and distributing the data streams to corresponding positions of the system according to the requirements, wherein the data integration and distribution module supports a plurality of data transmission protocols and network interfaces;

the self-adaptive communication interface module is used for automatically adjusting the communication mode by the concentrator according to the network conditions and the data transmission requirements and automatically selecting the corresponding communication mode according to the data quantity, the transmission distance and the network quality.

Wherein the remote communication unit includes: a wireless transmission module and a target positioning and configuration module;

the wireless transmission module is used for receiving the data stream from the concentrator unit, determining whether the data stream is encrypted by a mechanical energy key, if so, transmitting the data stream to a preset position, and then decrypting the data according to the encryption key;

And the target positioning and configuration module is used for setting and storing target position information of the remote received data and transmitting the data to a preset remote position.

Wherein the management unit includes:

the state monitoring module is used for monitoring the signal quality, the data flow and the communication state of the remote communication system in real time, including the signal strength, the data transmission rate and the communication continuity;

the data analysis module is connected with the state monitoring module and is used for analyzing the collected monitoring data and identifying potential operation problems or areas with low efficiency;

and the control module is used for adjusting and optimizing the operation parameters of the remote communication system based on the data analysis result so as to improve the overall performance and reliability of the system.

Wherein automatically adjusting the signal processing parameters based on the analysis result includes:

receiving and analyzing signal characteristics from at least one signal source, the signal characteristics including signal strength, signal interference, and signal delay;

when a signal is received, activating a signal characteristic analysis model, wherein the signal characteristic analysis model is configured with an algorithm for analyzing the signal characteristic in real time;

parameters of signal intensity, signal interference and signal delay analyzed based on the signal characteristic analysis model, wherein the signal analysis module at least comprises one signal processing parameter;

The signal processing parameters include signal gain adjustment, signal frequency filtering, signal phase adjustment and signal amplitude adjustment; if the signal strength is found to be lower than the preset threshold value, automatically increasing the signal gain; if the detected signal interference exceeds the preset range, automatically adjusting signal frequency filtering parameters to reduce interference influence; if the signal delay exceeds the standard, the phase and amplitude of the signal are adjusted accordingly to compensate for the delay.

The method for automatically selecting the corresponding communication mode according to the data volume, the transmission distance and the network quality comprises the following steps:

monitoring current network conditions including network stability, network rate, and network delay;

meanwhile, the current data transmission requirements of the concentrator are acquired, wherein the requirements comprise data quantity, data transmission frequency and data transmission emergency degree;

based on a preset communication adjustment model, comprehensively analyzing network conditions and data transmission requirements, and determining a corresponding communication mode;

when the network condition and the data transmission requirement indicate that high-speed transmission is needed, selecting a corresponding high-speed communication mode;

when network conditions and data transmission requirements indicate that long-distance transmission is needed, selecting a corresponding long-distance communication mode;

when the network condition and the data transmission requirement indicate that stable transmission is needed, selecting a corresponding stable communication mode;

According to the selected communication mode, the communication parameters of the concentrator are adjusted, including frequency, power and modulation mode;

implementing the adjusted communication mode to finish the data transmission;

wherein the communication adjustment model includes: evaluating network quality metrics, including signal strength, interference level, and connection stability; classifying data transmission requirements, including real-time requirements, data concentration and transmission distance; based on network quality index and data transmission requirement, a preset algorithm is used for determining an optimal communication mode.

Wherein transmitting the data to the predetermined remote location comprises:

acquiring characteristic information of data, wherein the characteristic information comprises data type, size and format;

selecting a corresponding data transmission protocol and an encryption method according to the characteristic information of the data so as to ensure the safety and efficiency of data transmission;

setting target position information, including the address, port number and receiving path of the remote server;

storing target position information in a local system, and simultaneously setting a priority of data transmission and a retry strategy to cope with transmission failure;

based on a data transmission protocol and an encryption method, packaging data to form a transmission data packet;

Starting a data transmission process, and sending a transmission data packet to a target position;

monitoring a data transmission process, and acquiring a transmission state in real time, wherein the transmission state comprises a transmission speed, a transmitted data quantity and an expected residual time;

after the data transmission is completed, verifying the integrity and the correctness of the data received by the remote location, and if the verification is passed, confirming that the data transmission is successful;

if abnormality occurs in the data transmission process, retransmitting according to the set retry strategy until the data transmission is successful or the upper limit of the retry times is reached;

and recording a log of data transmission, wherein the log comprises transmission time, transmission results and error information generated by transmission, so that subsequent fault detection is facilitated.

Wherein, the concentrator includes:

a data collection module for receiving and aggregating information from a plurality of data sources;

the data analysis module is used for carrying out deep analysis on the data summarized by the collection module;

and the data transmission and interface module is used for transmitting the output of the data analysis module to a corresponding system or equipment and can interact with an external interface.

Wherein, include: the data transmission and interface module supports a variety of communication protocols and data formats, ensuring flexible integration of the concentrator with a variety of environments and devices.

Compared with the prior art, the invention has the following advantages:

a concentrator telecommunications system with adaptive signal optimization, comprising: the signal optimizing unit is used for receiving signals from a plurality of sources and automatically adjusting signal processing parameters to optimize signal quality so as to obtain optimized signals; the concentrator unit is used for converging the optimized signals from the signal optimizing module and integrating the optimized signals into a unified data stream; a remote communication unit for transmitting the data integrated by the concentrator module to a predetermined remote location through a wireless network; and the management unit is used for monitoring and managing the operation state of the remote communication system of the concentrator, wherein the operation state comprises signal quality, data flow and remote communication state. Integrating data from different sources simplifies the data processing flow and makes the system more efficient.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

The technical scheme of the invention is further described in detail through the drawings and the embodiments.

Drawings

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate the invention and together with the embodiments of the invention, serve to explain the invention. In the drawings:

FIG. 1 is a block diagram of a concentrator telecommunications system with adaptive signal optimization in accordance with an embodiment of the present invention;

FIG. 2 is a block diagram of a signal optimizing unit in an embodiment of the present invention;

fig. 3 is a block diagram of a concentrator unit in an embodiment of the present invention.

Detailed Description

The preferred embodiments of the present invention will be described below with reference to the accompanying drawings, it being understood that the preferred embodiments described herein are for illustration and explanation of the present invention only, and are not intended to limit the present invention.

The embodiment of the invention provides a concentrator remote communication system with self-adaptive signal optimization, which comprises the following steps: the signal optimizing unit is used for receiving signals from a plurality of sources and automatically adjusting signal processing parameters to optimize signal quality so as to obtain optimized signals;

the concentrator unit is used for converging the optimized signals from the signal optimizing module and integrating the optimized signals into a unified data stream;

a remote communication unit for transmitting the data integrated by the concentrator module to a predetermined remote location through a wireless network;

and the management unit is used for monitoring and managing the operation state of the remote communication system of the concentrator, wherein the operation state comprises signal quality, data flow and remote communication state.

The working principle of the technical scheme is as follows: the signal optimizing unit receives signals from a plurality of sources, including wireless sensors, devices or other data sources, and an internal algorithm of the signal optimizing unit can automatically adjust signal processing parameters so as to optimize signal quality and ensure that the signals acquired from the sources are all optimal; it is assumed that in an intelligent city project, the signal optimizing unit receives data from environmental monitoring sensors of different areas, including air quality, temperature and humidity, and according to characteristics of the different areas, the signal optimizing unit adjusts sampling frequency and sensitivity of the sensors to ensure accurate data is obtained under different environmental conditions.

The concentrator unit is responsible for gathering the optimized signals from the signal optimizing module and integrating the optimized signals into a unified data stream, which is helpful for simplifying data processing and transmission and improving the efficiency of the system; in an intelligent home system, a concentrator unit collects sensor data from various rooms, such as temperature, lighting and status of safety devices, and by integrating these data, the concentrator creates a comprehensive home status data stream for subsequent remote monitoring and control.

The remote communication unit is responsible for transmitting the data integrated by the concentrator modules to a predetermined remote location through a wireless network, which may be a cloud server, a central monitoring station or other designated location; in intelligent agricultural systems, remote communication units transmit soil humidity, temperature and illumination data from different farms to cloud servers, which can be accessed by farmers remotely, monitor farmland conditions in different areas in real time, and make timely decisions such as irrigation scheduling or greenhouse control.

The management unit is responsible for monitoring and managing the operational status of the concentrator telecommunications system, including the signal quality, data traffic and telecommunications status. This helps ensure that the system is operating properly and finds and solves problems in time; in an intelligent traffic management system, a management unit monitors the running state of a concentrator, including the state and flow data of each traffic signal lamp, and if a signal in a certain area fails or is in traffic jam, the management unit can send out an alarm and inform relevant maintenance personnel to process in time.

The beneficial effects of the technical scheme are as follows: by automatic adjustment of the signal optimization unit, the system can acquire high-quality and accurate data, and the monitoring and control effects are improved; the concentrator unit integrates data from different sources, so that the data processing flow is simplified, and the system is more efficient; the remote communication unit enables a user to access and manage system data through a wireless network at any time and any place so as to realize remote monitoring and control; the monitoring function of the management unit is helpful for finding and solving the problems in the running of the system in time, and improving the stability and reliability of the system.

In another embodiment, the signal optimizing unit includes: the system comprises a signal receiving module, a signal analyzing module and a self-adaptive adjusting module;

a signal receiving module for receiving signals from a plurality of signal sources, the signal sources including a wireless network, a wired network, or a communication device;

the signal analysis module is connected with the signal receiving module and used for analyzing the received signal characteristics, wherein the signal characteristics comprise parameters of signal strength, signal interference and signal delay, and automatically adjusting signal processing parameters based on analysis results so as to optimize signal quality;

the self-adaptive adjustment module is used for dynamically adjusting a signal processing strategy according to the environmental change and the signal source characteristic, wherein the signal processing strategy comprises gain adjustment, noise suppression and frequency selection.

The working principle of the technical scheme is as follows: the signal receiving module is responsible for receiving signals from a plurality of signal sources, wherein the signal sources comprise a wireless network, a wired network or other communication equipment, and through receiving by the plurality of signal sources, the system can obtain more comprehensive data, so that the coverage range and the reliability of the signals are improved; in an urban intelligent traffic system, the signal receiving module can receive information from a plurality of signal sources such as traffic lights, vehicle sensors, pedestrian movement sensors and the like, which is beneficial to monitoring traffic conditions in real time and performing intelligent traffic management.

The signal analysis module is connected with the signal receiving module and is responsible for analyzing the received signal characteristics, such as signal strength, signal interference, signal delay and other parameters, and according to the analysis result, the system can better know the current signal environment and take corresponding measures to optimize the signal processing parameters; in an industrial automation system, a signal analysis module analyzes data from various sensors, including temperature sensors, humidity sensors, and pressure sensors, by analyzing which the system can monitor the production environment in real time and adjust production parameters as needed to improve efficiency.

The self-adaptive adjustment module dynamically adjusts a signal processing strategy according to environmental changes and signal source characteristics, wherein the strategy comprises gain adjustment, noise suppression, frequency selection and the like so as to ensure that the best signal quality is obtained under different conditions; in a military communication system, the adaptive adjustment module can dynamically adjust the wireless communication frequency according to the terrain change and hostile interference conditions so as to maintain the safety and stability of communication.

Wherein dynamically adjusting the signal processing strategy according to the environmental change and the signal source characteristics comprises:

acquiring initial signal data of a signal source;

Based on a preset environment detection template, monitoring the current environment condition to obtain an environment characteristic value set;

analyzing the characteristics of a signal source based on a preset signal source characteristic analysis template to obtain a signal source characteristic value set;

synthesizing an environment characteristic value set and a signal source characteristic value set, adjusting a template based on a preset signal processing strategy, and dynamically generating the signal processing strategy;

the signal processing strategy comprises one or more measures of gain adjustment, noise suppression, frequency selection and the like;

processing the initial signal data by applying a signal processing strategy to obtain a processed signal;

evaluating the effect of the obtained processed signal based on a preset effect evaluation template;

if the obtained effect meets the preset standard, maintaining the current signal processing strategy; if not, adjusting the signal processing strategy according to the evaluation result, and repeating the steps until the signal processing effect meeting the preset standard is obtained.

The beneficial effects of the technical scheme are as follows: through the reception of multiple signal sources, the system can enhance the coverage range of signals and ensure that stable communication signals can be obtained in different areas; the signal analysis module is used for analyzing the signal characteristics, so that the system can adjust signal processing parameters according to actual conditions, optimize signal quality and improve the reliability and accuracy of communication; the self-adaptive adjustment module enables the system to flexibly cope with environmental changes such as weather changes, interference sources and the like, and ensures that the communication system can stably operate under various conditions; by comprehensively using the modules, the system can be better adapted to different working environments and signal conditions, so that the stability and reliability of the whole system are improved.

In another embodiment, a concentrator unit includes: the system comprises a data aggregation module, a data integration and distribution module and an adaptive communication interface module;

the data convergence module is used for receiving the optimized signals, processing the optimized signals with different frequencies and formats and converting the optimized signals into data streams with uniform formats;

the data integration and distribution module is used for further integrating the data streams and distributing the data streams to corresponding positions of the system according to the requirements, wherein the data integration and distribution module supports a plurality of data transmission protocols and network interfaces;

the self-adaptive communication interface module is used for automatically adjusting the communication mode by the concentrator according to the network conditions and the data transmission requirements and automatically selecting the corresponding communication mode according to the data quantity, the transmission distance and the network quality.

The working principle of the technical scheme is as follows: the data aggregation module is responsible for receiving the optimized signals from the signal optimization module, processing signals with different frequencies and formats, and converting the signals into data streams with uniform formats, so that the data formats in the system are consistent, and the subsequent processing and distribution are convenient; in an industrial production monitoring system, a data aggregation module receives optimized signals from different production lines, which may include temperature, humidity, production rate, etc., and by converting these signals into a unified data format, the system can more easily perform comprehensive monitoring and analysis.

The data integration and distribution module receives the data flow from the data aggregation module, further integrates the data, distributes the data to corresponding positions according to the system requirements, supports different data transmission protocols and network interfaces, and ensures that the data can be distributed to different system components or external systems according to the requirements; in an intelligent city project, the data integrating and distributing module receives data from different fields including traffic, environment and energy consumption, integrates the data into a comprehensive city data stream, and distributes the comprehensive city data stream to a traffic management system, an environment monitoring system, an energy management system and the like.

The adaptive communication interface module allows the concentrator to automatically adjust the communication mode according to network conditions and data transmission requirements, which comprises automatically selecting a proper communication mode, such as wireless communication or wired communication, according to data quantity, transmission distance and network quality; in an intelligent agricultural system, the self-adaptive communication interface module can automatically select whether to use wireless transmission or wired transmission according to the distance between farmlands and the network quality, so that stable and reliable data transmission between farmlands can be ensured to the greatest extent.

The beneficial effects of the technical scheme are as follows: the data aggregation module ensures that signals collected from different sources are processed in a unified format, so that the consistency of data is improved, and the data processing and analysis are easier to carry out in the system; the data integration and distribution module supports various data transmission protocols and network interfaces, so that the system can distribute data to different system components or external systems according to the needs, and flexible data distribution is realized; the self-adaptive communication interface module enables the system to automatically adjust the communication mode according to different network conditions and data transmission requirements, and improves the adaptability and stability of communication; by comprehensively using the modules, the system can efficiently process, integrate and distribute data, ensure that the whole concentrator system can efficiently operate under different conditions, and provide powerful support for subsequent data analysis and decision.

In another embodiment, a remote communication unit includes: a wireless transmission module and a target positioning and configuration module;

the wireless transmission module is used for receiving the data stream from the concentrator unit, determining whether the data stream is encrypted by a mechanical energy key, if so, transmitting the data stream to a preset position, and then decrypting the data according to the encryption key;

And the target positioning and configuration module is used for setting and storing target position information of the remote received data and transmitting the data to a preset remote position.

The working principle of the technical scheme is as follows: the wireless transmission module is responsible for receiving the data stream from the concentrator unit, firstly determining whether the data stream is encrypted by a mechanical energy key, if so, transmitting the data stream to a preset position by the module, and then decrypting the data by using the encryption key; this step ensures the security and integrity of the data during transmission; in an industrial control system, a wireless transmission module receives data streams from sensors, including key production parameters, and if the data needs to be encrypted to protect industrial secrets, the wireless transmission module is responsible for transmitting the encrypted data to a designated server and decrypting the encrypted data at the server side by using a corresponding key.

The target positioning and configuration module is used for setting and storing target position information of remote received data, and once the data is transmitted to the concentrator through the transmission module, the target positioning and configuration module transmits the data to a preset remote position to ensure that the data reaches a correct receiving end; in an environment monitoring system, a target positioning and configuration module is responsible for transmitting collected environment data to a remote data center, and an administrator can preset the position information of the data center to ensure that the environment data is accurately transmitted to a designated position for centralized storage and analysis.

The beneficial effects of the technical scheme are as follows: by implementing mechanical energy key encryption and decryption in the wireless transmission module, confidentiality and integrity of data in the process of data transmission are ensured, and unauthorized access and tampering are effectively prevented; the target positioning and configuration module provides accurate target position information of remote received data, ensures that the data can be accurately and timely transmitted to a preset remote position, and improves the accuracy of data transmission; the existence of the target positioning and configuration module simplifies the configuration flow of the system, and an administrator only needs to preset target position information of remote received data, so that the system can automatically transmit the data according to the setting; by ensuring secure transmission and accurate transfer of data to a designated location, the synergy of the two modules improves the availability of the data so that the data is more readily utilized by remote systems or applications, enabling more efficient data processing and application.

In another embodiment, the management unit includes:

the state monitoring module is used for monitoring the signal quality, the data flow and the communication state of the remote communication system in real time, including the signal strength, the data transmission rate and the communication continuity;

The data analysis module is connected with the state monitoring module and is used for analyzing the collected monitoring data and identifying potential operation problems or areas with low efficiency;

and the control module is used for adjusting and optimizing the operation parameters of the remote communication system based on the data analysis result so as to improve the overall performance and reliability of the system.

The working principle of the technical scheme is as follows: the state monitoring module monitors the signal quality, data flow and communication state of the remote communication system in real time, including parameters such as signal strength, data transmission rate and communication continuity, and by monitoring the parameters, the system can timely sense any potential communication problem or performance degradation; in a remote monitoring system of an intelligent city, a state monitoring module can monitor the signal intensity and the data transmission rate of a wireless sensor network in real time, and if the signal intensity of a certain area is reduced or the data transmission rate is reduced, the system can rapidly respond and take corresponding measures, such as adjusting a signal amplifier or optimizing a data compression algorithm.

The data analysis module is connected with the state monitoring module and is responsible for analyzing the collected monitoring data, and the system can predict possible faults in advance and perform corresponding preventive maintenance by identifying potential operation problems or areas with low efficiency; in a remote monitoring system of an industrial production line, a data analysis module can analyze production data collected by a sensor, and if the data analysis module finds that the production efficiency of a certain device is reduced or abnormal, the system can timely send out an alarm and inform maintenance personnel to overhaul so as to prevent the production interruption caused by the equipment failure.

The control module adjusts and optimizes the operation parameters of the remote communication system according to the data analysis result, which comprises dynamically adjusting a signal amplifier, a data compression algorithm, a communication protocol and the like so as to improve the overall performance and the reliability of the system; in a remote agricultural monitoring system, the control module can dynamically adjust the communication frequency between the sensor nodes according to the data analysis result so as to adapt to different farmland environments. This helps to optimize the energy consumption of the system, extending the battery life of the sensor node.

Wherein adjusting and optimizing the operating parameters of the telecommunications system comprises:

extracting the communication event and performance index from the monitoring data;

determining a time interval corresponding to a communication event and a performance index from a preset time interval library;

at intervals, the following operations are performed:

determining the type of the communication event, the system performance parameter when the communication event occurs, and the network environment parameter when the communication event occurs from the monitoring data;

based on a preset analysis template, carrying out characterization processing on the type of the communication event, the system performance parameter and the network environment parameter to obtain a plurality of first features;

continuously matching the first feature with a second feature in the performance problem detection library; acquiring a time point at which the second feature is matched and met with the first feature in the latest preset time, and corresponding characterization problems and characterization degrees of the matched and met second feature in a performance problem detection library; the time points, the characterization problems and the characterization degree are in one-to-one correspondence;

Setting the corresponding characterization problem and the characterization degree at corresponding time nodes on a preset time axis according to the time points;

attempting to screen the characterization clusters meeting the characterization cluster conditions from the time axis;

when screening, using the corresponding communication event and performance index as potential operation problem or low-efficiency area;

based on the analysis result of the characterization cluster, the operation parameters of the remote communication system, including signal power, frequency allocation, coding scheme, modulation mode, transmission protocol, route selection, bandwidth allocation, buffer size and error correction strategy, are adjusted and optimized to improve the overall performance and reliability of the system;

the adjustment and optimization are based on the matching degree between the characterization problem and the characterization degree and strategies in a preset performance optimization strategy library, and the corresponding strategies are selected to execute optimization, so that the communication system can maintain the optimal running state under different network environments.

The beneficial effects of the technical scheme are as follows: the system parameters are monitored in real time through the state monitoring module, so that the system can diagnose potential communication problems in time, and the reliability and stability of the system are improved; the data analysis module enables the system to predict possible faults of equipment by analyzing historical data and perform preventive maintenance, so that the occurrence probability of sudden faults is reduced; the control module dynamically adjusts the system operation parameters according to the data analysis result, so that the dynamic optimization of the system is realized, and the overall performance and efficiency are improved; through real-time problem diagnosis and predictive maintenance, the system can process problems in time, reduce maintenance cost and risk of production interruption, and improve maintainability of the system.

In another embodiment, automatically adjusting the signal processing parameters based on the analysis results includes:

receiving and analyzing signal characteristics from at least one signal source, the signal characteristics including signal strength, signal interference, and signal delay;

when a signal is received, activating a signal characteristic analysis model, wherein the signal characteristic analysis model is configured with an algorithm for analyzing the signal characteristic in real time;

parameters of signal intensity, signal interference and signal delay analyzed based on the signal characteristic analysis model, wherein the signal analysis module at least comprises one signal processing parameter;

the signal processing parameters include signal gain adjustment, signal frequency filtering, signal phase adjustment and signal amplitude adjustment; if the signal strength is found to be lower than the preset threshold value, automatically increasing the signal gain; if the detected signal interference exceeds the preset range, automatically adjusting signal frequency filtering parameters to reduce interference influence; if the signal delay exceeds the standard, the phase and amplitude of the signal are adjusted accordingly to compensate for the delay.

The working principle of the technical scheme is as follows: when a signal is received, the system activates a signal characteristic analysis model, the model is configured with an algorithm for analyzing signal characteristics in real time, the signal characteristics comprise signal strength, signal interference and signal delay, and the system can know the quality condition and delay condition of the signal by analyzing the received signal; the signal characteristic analysis model analyzes the received signal characteristics by using a preset algorithm, wherein the signal characteristic analysis model at least comprises one signal processing parameter, and the signal processing parameter comprises signal gain adjustment, signal frequency filtration, signal phase adjustment and signal amplitude adjustment.

The system can automatically adjust signal processing parameters based on the parameters of signal intensity, signal interference and signal delay analyzed by the signal characteristic analysis model; for example, if the signal strength is detected to be below a preset threshold, the system automatically increases the signal gain; if the signal interference is found to exceed the preset range, the system automatically adjusts the signal frequency filtering parameters to reduce the interference influence; if the signal delay exceeds the standard, the system adjusts the phase and amplitude of the signal accordingly to compensate for the delay.

The beneficial effects of the technical scheme are as follows: by analyzing in real time and automatically adjusting signal processing parameters, the system can optimize the received signals in real time, ensure the signal quality and stability and improve the reliability of the system; the requirement for manual intervention is reduced by automatically adjusting the signal processing parameters, the system can automatically cope with the signal quality problem, and the workload of operators is reduced; by automatically adjusting the signal processing parameters, the system can optimize signal processing according to actual conditions, so that the performance and adaptability of the system are improved, and the system can be better adapted to different environments and working conditions; by automatically adjusting the phase and amplitude of the signal to compensate for the delay, the system can effectively reduce the signal delay and improve the instantaneity and responsiveness.

In another embodiment, the automatic selection of the corresponding communication mode according to the data volume, the transmission distance and the network quality includes:

monitoring current network conditions including network stability, network rate, and network delay;

meanwhile, the current data transmission requirements of the concentrator are acquired, wherein the requirements comprise data quantity, data transmission frequency and data transmission emergency degree;

based on a preset communication adjustment model, comprehensively analyzing network conditions and data transmission requirements, and determining a corresponding communication mode;

when the network condition and the data transmission requirement indicate that high-speed transmission is needed, selecting a corresponding high-speed communication mode;

when network conditions and data transmission requirements indicate that long-distance transmission is needed, selecting a corresponding long-distance communication mode;

when the network condition and the data transmission requirement indicate that stable transmission is needed, selecting a corresponding stable communication mode;

according to the selected communication mode, the communication parameters of the concentrator are adjusted, including frequency, power and modulation mode;

implementing the adjusted communication mode to finish the data transmission;

wherein the communication adjustment model includes: evaluating network quality metrics, including signal strength, interference level, and connection stability; classifying data transmission requirements, including real-time requirements, data concentration and transmission distance; based on network quality index and data transmission requirement, a preset algorithm is used for determining an optimal communication mode.

The working principle of the technical scheme is as follows: the system firstly monitors the current network conditions including network stability, network rate and network delay, and acquires the current data transmission requirements of the concentrator including data quantity, data transmission frequency and data transmission emergency degree; based on a preset communication adjustment model, the system comprehensively analyzes network conditions and data transmission requirements, and determines corresponding communication modes, wherein the communication modes comprise high-speed transmission, long-distance transmission or stable transmission are selected according to network conditions and data transmission requirement indications; according to the selected communication mode, the system adjusts the communication parameters of the concentrator, including frequency, power and modulation mode, to adapt to the requirements of the selected communication mode.

The system implements the adjusted communication mode to complete data transmission and ensure that the data can be transmitted at high speed, long distance or stably according to the requirement.

The beneficial effects of the technical scheme are as follows: by comprehensively analyzing network conditions and data transmission requirements, the system can select the most suitable communication mode, and ensure that the data transmission can adapt to different environments and requirements; according to the selected communication mode, the system adjusts the communication parameters of the concentrator, optimizes the efficiency and stability of data transmission, and improves the success rate of data transmission; by selecting a proper communication mode and adjusting communication parameters according to requirements, the system can improve the quality of data transmission, including speed, stability and coverage area; the communication adjustment model enables the system to automatically select a communication mode and adjust parameters according to a preset algorithm, reduces the requirement for manual intervention, and improves the automation level of the system.

In another embodiment, transmitting data to a predetermined remote location includes:

acquiring characteristic information of data, wherein the characteristic information comprises data type, size and format;

selecting a corresponding data transmission protocol and an encryption method according to the characteristic information of the data so as to ensure the safety and efficiency of data transmission;

setting target position information, including the address, port number and receiving path of the remote server;

storing target position information in a local system, and simultaneously setting a priority of data transmission and a retry strategy to cope with transmission failure;

based on a data transmission protocol and an encryption method, packaging data to form a transmission data packet;

starting a data transmission process, and sending a transmission data packet to a target position;

monitoring a data transmission process, and acquiring a transmission state in real time, wherein the transmission state comprises a transmission speed, a transmitted data quantity and an expected residual time;

after the data transmission is completed, verifying the integrity and the correctness of the data received by the remote location, and if the verification is passed, confirming that the data transmission is successful;

if abnormality occurs in the data transmission process, retransmitting according to the set retry strategy until the data transmission is successful or the upper limit of the retry times is reached;

And recording a log of data transmission, wherein the log comprises transmission time, transmission results and error information generated by transmission, so that subsequent fault detection is facilitated.

The working principle of the technical scheme is as follows: the system firstly acquires characteristic information of data, including data type, size and format, and the information is the basis for determining a data transmission mode and an encryption method; according to the characteristic information of the data, the system selects a corresponding data transmission protocol and an encryption method to ensure the safety and efficiency of the data in the transmission process, for example, for sensitive information, the system may select to use the encryption method to ensure the safety of the data transmission; the user sets target location information including the address, port number and receiving path of the remote server, which is key information to ensure data transmission to a designated location; the system stores the target position information locally, sets the priority and retry strategy of data transmission at the same time, and sets transmission parameters to cope with the possible transmission failure condition, so as to ensure that the data can be transmitted according to the set priority and strategy; based on the selected data transmission protocol and encryption method, the system packs the data to form a transmission data packet, starts the data transmission process and sends the transmission data packet to the target position; in the data transmission process, the system monitors the transmission state in real time, including the transmission speed, the transmitted data quantity and the predicted remaining time, which is helpful for users to know the progress and efficiency of data transmission; after the data transmission is completed, the system verifies the integrity and the correctness of the data received by the remote location, and if the verification is passed, the system confirms that the data transmission is successful; if abnormality occurs in the data transmission process, the system retransmits according to a set retry strategy until the data transmission is successful or the retry times reaches the upper limit, which ensures the timely treatment of the transmission failure condition; the system records a log of data transmissions, including transmission time, transmission results, and error information generated by the transmissions. These logs facilitate subsequent troubleshooting and performance optimization.

The beneficial effects of the technical scheme are as follows: by selecting a proper transmission protocol and an encryption method, the system ensures the safety of data transmission and prevents data from being accessed or tampered maliciously in the transmission process; according to the data characteristic information, a proper transmission protocol is selected, so that the transmission efficiency can be improved, and the data can be transmitted to a target position at the highest speed; setting target position information, transmission parameters and retry strategies, the system realizes automatic management of the data transmission process, and reduces the operation burden of users; recording the transmission log is helpful for finding and solving the problems in the transmission process in time, improving the stability of the system and providing useful information for subsequent performance optimization.

In another embodiment, a concentrator comprises:

a data collection module for receiving and aggregating information from a plurality of data sources;

the data analysis module is used for carrying out deep analysis on the data summarized by the collection module;

and the data transmission and interface module is used for transmitting the output of the data analysis module to a corresponding system or equipment and can interact with an external interface.

The working principle of the technical scheme is as follows: the data collection module is responsible for receiving and summarizing information from a plurality of data sources, such as sensors, databases, log files and the like, and the system can acquire various types of data including real-time data, historical data and the like through the collection module; the collected data is transmitted to a data analysis module through a data transmission module, the data analysis module performs deep analysis, which can include data mining, pattern recognition, statistical analysis and the like, so that useful information can be extracted from mass data, patterns or trends can be recognized, and decision making can be supported; the output of the data analysis module needs to be transmitted to a corresponding system or equipment, and meanwhile interaction with an external interface is possibly needed, and the data transmission and interface module is responsible for the process, so that the analysis result can be transmitted to a needed place in time and can be cooperated with other systems.

The beneficial effects of the technical scheme are as follows: the data collection module can acquire information from a plurality of data sources, so that the system is ensured to have comprehensive data sources, a more comprehensive information base is provided, and more accurate analysis and decision are supported; the data analysis module can reveal patterns, associations and trends behind the data by performing in-depth analysis of the collected data. This helps to discover the value information hidden in the data, providing more insight for business decisions; the data transmission and interface module ensures that the output of data analysis can be timely transmitted to a required system or equipment, and realizes quick response to real-time information. This is very important for scenarios requiring immediate decision making; the data transmission and interface module not only can transmit data to the target system, but also can interact with an external interface, so that integration and cooperative work among the systems are realized. This improves the intelligence and efficiency of the overall system; by integrating data collection, analysis and transmission, the system can more rapidly convert data into useful information, improving the decision-making efficiency. This is particularly important for organizations that need to respond quickly to market changes or business needs.

In another embodiment, the data transmission and interface module supports multiple communication protocols and data formats, ensuring that the concentrator is flexibly integrated with a variety of environments and devices.

The working principle of the technical scheme is as follows: the data transmission and interface module supports various communication protocols, such as TCP/IP, UDP, HTTP, MQTT, etc., and such a design ensures that the concentrator can communicate with different devices and systems, whether within a local area network or via an Internet connection; the module also supports a plurality of data formats, including JSON, XML, CSV, protocol Buffers and the like, and the design can meet the requirements of different devices and systems on the data formats, so that the data can be correctly analyzed and processed; by supporting multiple communication protocols and data formats, the data transfer and interface module ensures flexibility of the concentrator, which can be integrated with a variety of environments and devices, whether in communication with sensors, controllers, databases, or other systems, and which can accommodate and exchange data with.

The beneficial effects of the technical scheme are as follows: the concentrator can adapt to various environments by supporting various communication protocols and data formats, including different manufacturers, different devices and different network architectures, so that the difficulty and cost of integration are reduced; through supporting various communication protocols and data formats, the concentrator can better interoperate with other devices and systems, so that data sharing and exchange are realized, and cooperative work among the systems is promoted; the concentrator has higher flexibility and expandability by supporting various communication protocols and data formats, can meet new requirements and new scenes possibly appearing in the future, and keeps the competitiveness and sustainable development capability of the system; because the concentrator can directly communicate with various devices and systems without additional middleware or conversion equipment, the cost and complexity of integration can be reduced, and the overall efficiency and reliability are improved.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present invention without departing from the spirit or scope of the invention. Thus, it is intended that the present invention also include such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.

Claims (10)

1. A concentrator telecommunications system with adaptive signal optimization, comprising:

the signal optimizing unit is used for receiving signals from a plurality of sources and automatically adjusting signal processing parameters to optimize signal quality so as to obtain optimized signals;

the concentrator unit is used for converging the optimized signals from the signal optimizing module and integrating the optimized signals into a unified data stream;

a remote communication unit for transmitting the data integrated by the concentrator module to a predetermined remote location through a wireless network;

and the management unit is used for monitoring and managing the operation state of the remote communication system of the concentrator, wherein the operation state comprises signal quality, data flow and remote communication state.

2. An adaptive signal-optimizing concentrator telecommunications system according to claim 1, wherein the signal-optimizing unit comprises: the system comprises a signal receiving module, a signal analyzing module and a self-adaptive adjusting module;

A signal receiving module for receiving signals from a plurality of signal sources, the signal sources including a wireless network, a wired network, or a communication device;

the signal analysis module is connected with the signal receiving module and used for analyzing the received signal characteristics, wherein the signal characteristics comprise parameters of signal strength, signal interference and signal delay, and automatically adjusting signal processing parameters based on analysis results so as to optimize signal quality;

the self-adaptive adjustment module is used for dynamically adjusting a signal processing strategy according to the environmental change and the signal source characteristic, wherein the signal processing strategy comprises gain adjustment, noise suppression and frequency selection.

3. An adaptive signal optimizing concentrator telecommunications system according to claim 1, wherein the concentrator unit comprises: the system comprises a data aggregation module, a data integration and distribution module and an adaptive communication interface module;

the data convergence module is used for receiving the optimized signals, processing the optimized signals with different frequencies and formats and converting the optimized signals into data streams with uniform formats;

the data integration and distribution module is used for further integrating the data streams and distributing the data streams to corresponding positions of the system according to the requirements, wherein the data integration and distribution module supports a plurality of data transmission protocols and network interfaces;

The self-adaptive communication interface module is used for automatically adjusting the communication mode by the concentrator according to the network conditions and the data transmission requirements and automatically selecting the corresponding communication mode according to the data quantity, the transmission distance and the network quality.

4. An adaptive signal optimizing concentrator telecommunications system according to claim 1, wherein the telecommunications unit comprises: a wireless transmission module and a target positioning and configuration module;

the wireless transmission module is used for receiving the data stream from the concentrator unit, determining whether the data stream is encrypted by a mechanical energy key, if so, transmitting the data stream to a preset position, and then decrypting the data according to the encryption key;

and the target positioning and configuration module is used for setting and storing target position information of the remote received data and transmitting the data to a preset remote position.

5. An adaptive signal optimizing concentrator telecommunications system according to claim 1, wherein the management unit comprises:

the state monitoring module is used for monitoring the signal quality, the data flow and the communication state of the remote communication system in real time, including the signal strength, the data transmission rate and the communication continuity;

the data analysis module is connected with the state monitoring module and is used for analyzing the collected monitoring data and identifying potential operation problems or areas with low efficiency;

And the control module is used for adjusting and optimizing the operation parameters of the remote communication system based on the data analysis result so as to improve the overall performance and reliability of the system.

6. An adaptive signal-optimized concentrator telecommunications system in accordance with claim 2, wherein automatically adjusting signal processing parameters based on the analysis results comprises:

receiving and analyzing signal characteristics from at least one signal source, the signal characteristics including signal strength, signal interference, and signal delay;

when a signal is received, activating a signal characteristic analysis model, wherein the signal characteristic analysis model is configured with an algorithm for analyzing the signal characteristic in real time;

parameters of signal intensity, signal interference and signal delay analyzed based on the signal characteristic analysis model, wherein the signal analysis module at least comprises one signal processing parameter;

the signal processing parameters include signal gain adjustment, signal frequency filtering, signal phase adjustment and signal amplitude adjustment; if the signal strength is found to be lower than the preset threshold value, automatically increasing the signal gain; if the detected signal interference exceeds the preset range, automatically adjusting signal frequency filtering parameters to reduce interference influence; if the signal delay exceeds the standard, the phase and amplitude of the signal are adjusted accordingly to compensate for the delay.

7. An adaptive signal optimizing concentrator telecommunications system according to claim 3, wherein automatically selecting the corresponding communication mode based on the amount of data, transmission distance, and network quality comprises:

monitoring current network conditions including network stability, network rate, and network delay;

meanwhile, the current data transmission requirements of the concentrator are acquired, wherein the requirements comprise data quantity, data transmission frequency and data transmission emergency degree;

based on a preset communication adjustment model, comprehensively analyzing network conditions and data transmission requirements, and determining a corresponding communication mode;

when the network condition and the data transmission requirement indicate that high-speed transmission is needed, selecting a corresponding high-speed communication mode;

when network conditions and data transmission requirements indicate that long-distance transmission is needed, selecting a corresponding long-distance communication mode;

when the network condition and the data transmission requirement indicate that stable transmission is needed, selecting a corresponding stable communication mode;

according to the selected communication mode, the communication parameters of the concentrator are adjusted, including frequency, power and modulation mode;

implementing the adjusted communication mode to finish the data transmission;

wherein the communication adjustment model includes: evaluating network quality metrics, including signal strength, interference level, and connection stability; classifying data transmission requirements, including real-time requirements, data concentration and transmission distance; based on network quality index and data transmission requirement, a preset algorithm is used for determining an optimal communication mode.

8. An adaptive signal optimizing concentrator telecommunications system according to claim 4, wherein transmitting data to a predetermined remote location comprises:

acquiring characteristic information of data, wherein the characteristic information comprises data type, size and format;

selecting a corresponding data transmission protocol and an encryption method according to the characteristic information of the data so as to ensure the safety and efficiency of data transmission;

setting target position information, including the address, port number and receiving path of the remote server;

storing target position information in a local system, and simultaneously setting a priority of data transmission and a retry strategy to cope with transmission failure;

based on a data transmission protocol and an encryption method, packaging data to form a transmission data packet;

starting a data transmission process, and sending a transmission data packet to a target position;

monitoring a data transmission process, and acquiring a transmission state in real time, wherein the transmission state comprises a transmission speed, a transmitted data quantity and an expected residual time;

after the data transmission is completed, verifying the integrity and the correctness of the data received by the remote location, and if the verification is passed, confirming that the data transmission is successful;

if abnormality occurs in the data transmission process, retransmitting according to the set retry strategy until the data transmission is successful or the upper limit of the retry times is reached;

And recording a log of data transmission, wherein the log comprises transmission time, transmission results and error information generated by transmission, so that subsequent fault detection is facilitated.

9. Concentrator, characterized in that it is applied to an adaptive signal-optimized concentrator telecommunication system according to claim 1, comprising:

a data collection module for receiving and aggregating information from a plurality of data sources;

the data analysis module is used for carrying out deep analysis on the data summarized by the collection module;

and the data transmission and interface module is used for transmitting the output of the data analysis module to a corresponding system or equipment and can interact with an external interface.

10. The concentrator of claim 9, comprising: the data transmission and interface module supports a variety of communication protocols and data formats, ensuring flexible integration of the concentrator with a variety of environments and devices.