{"title":"基于任务间隔数据交互模型的嵌入式系统","authors":"Qin Yang","doi":"10.1142/s0129156424400895","DOIUrl":null,"url":null,"abstract":"In the Internet of Things era, more intelligent systems can communicate with each other. Embedded system combined with network communication applications has become the basis for Internet of Things research. The programmable logic unit designed by ARM architecture has great advantages in running speed, power control and so on. In the paper, to solve the problems of common embedded MCU control resources occupying a large amount of memory and the slow speed of building engineering simulation model, it is necessary to use the queuing connection algorithm model to directly input the timing physical characteristics of the code stream in the embedded system to calculate and match the timing physical characteristics of the output code stream. The optimization algorithm of DTF-MARTE to detect the probability of timing deviation is used in the paper. It is to detect the problem of inaccurate timing information in the demand. We compare the expected physical characteristics of the timing sequence and obtain the timing deviation probability of the output data stream. The model developed in this paper has the characteristic of dynamic reconfiguration of the task interval. The design of monotonically decreasing data tasks can be realized, and the reconfigured task modules are used for interacting the data buffer area and dynamically reconstructing the instruction overhead and transmission. We analyze the performance comparison between the proposed model and the traditional communication connection model. It proves that the proposed model can further improve the priority queue and guide the data flow. According to that method, the problem of asynchronous spatial data interaction by controlling and combining different communication modes in a large scene can be solved. Data interaction can be triggered at a fixed time, and mutual interference of randomly triggered wireless communication and data acquisition modules can be avoided. It can solve the problem of insufficient computing power when future embedded devices need massive data encryption in the Internet of Things era, and provide a new way of thinking for fast, safe and efficient implementation.","PeriodicalId":35778,"journal":{"name":"International Journal of High Speed Electronics and Systems","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2024-07-17","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Embedded System Based on Task Interval Data Interaction Model\",\"authors\":\"Qin Yang\",\"doi\":\"10.1142/s0129156424400895\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"In the Internet of Things era, more intelligent systems can communicate with each other. 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The model developed in this paper has the characteristic of dynamic reconfiguration of the task interval. The design of monotonically decreasing data tasks can be realized, and the reconfigured task modules are used for interacting the data buffer area and dynamically reconstructing the instruction overhead and transmission. We analyze the performance comparison between the proposed model and the traditional communication connection model. It proves that the proposed model can further improve the priority queue and guide the data flow. According to that method, the problem of asynchronous spatial data interaction by controlling and combining different communication modes in a large scene can be solved. Data interaction can be triggered at a fixed time, and mutual interference of randomly triggered wireless communication and data acquisition modules can be avoided. 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引用次数: 0
摘要
在物联网时代,更多的智能系统可以相互通信。嵌入式系统结合网络通信应用已成为物联网研究的基础。采用 ARM 架构设计的可编程逻辑单元在运行速度、功耗控制等方面具有很大的优势。本文针对普通嵌入式单片机控制资源占用内存大、建立工程仿真模型速度慢等问题,采用队列连接算法模型,直接输入嵌入式系统中代码流的时序物理特性,计算并匹配输出代码流的时序物理特性。本文采用了 DTF-MARTE 检测时序偏差概率的优化算法。这是为了检测需求中时序信息不准确的问题。我们比较时序的预期物理特性,得出输出数据流的时序偏差概率。本文开发的模型具有动态重新配置任务间隔的特点。可以实现单调递减数据任务的设计,并利用重新配置后的任务模块交互数据缓冲区,动态重构指令开销和传输。我们分析了所提模型与传统通信连接模型的性能对比。结果证明,所提出的模型能进一步改善优先队列并引导数据流。根据该方法,通过控制和组合大场景中的不同通信模式,可以解决异步空间数据交互问题。数据交互可以在固定的时间触发,避免了随机触发的无线通信模块和数据采集模块之间的相互干扰。可以解决未来物联网时代嵌入式设备需要海量数据加密时计算能力不足的问题,为快速、安全、高效地实现提供了新的思路。
Embedded System Based on Task Interval Data Interaction Model
In the Internet of Things era, more intelligent systems can communicate with each other. Embedded system combined with network communication applications has become the basis for Internet of Things research. The programmable logic unit designed by ARM architecture has great advantages in running speed, power control and so on. In the paper, to solve the problems of common embedded MCU control resources occupying a large amount of memory and the slow speed of building engineering simulation model, it is necessary to use the queuing connection algorithm model to directly input the timing physical characteristics of the code stream in the embedded system to calculate and match the timing physical characteristics of the output code stream. The optimization algorithm of DTF-MARTE to detect the probability of timing deviation is used in the paper. It is to detect the problem of inaccurate timing information in the demand. We compare the expected physical characteristics of the timing sequence and obtain the timing deviation probability of the output data stream. The model developed in this paper has the characteristic of dynamic reconfiguration of the task interval. The design of monotonically decreasing data tasks can be realized, and the reconfigured task modules are used for interacting the data buffer area and dynamically reconstructing the instruction overhead and transmission. We analyze the performance comparison between the proposed model and the traditional communication connection model. It proves that the proposed model can further improve the priority queue and guide the data flow. According to that method, the problem of asynchronous spatial data interaction by controlling and combining different communication modes in a large scene can be solved. Data interaction can be triggered at a fixed time, and mutual interference of randomly triggered wireless communication and data acquisition modules can be avoided. It can solve the problem of insufficient computing power when future embedded devices need massive data encryption in the Internet of Things era, and provide a new way of thinking for fast, safe and efficient implementation.
期刊介绍:
Launched in 1990, the International Journal of High Speed Electronics and Systems (IJHSES) has served graduate students and those in R&D, managerial and marketing positions by giving state-of-the-art data, and the latest research trends. Its main charter is to promote engineering education by advancing interdisciplinary science between electronics and systems and to explore high speed technology in photonics and electronics. IJHSES, a quarterly journal, continues to feature a broad coverage of topics relating to high speed or high performance devices, circuits and systems.