Instructions Need report for the abstract which was done earlier. Report must be written in own words using latex and own figures to be used. No AI platforms like chatgpt/gemini. Please use own words and own figures. Need this in 10 pages | single spaced | APA format/nThis is the link for project final report submission. The report can be a 10 to 20 pages writeup Please provide information of the project as follows: (1) It should have a title. (2) What is the project all about? (3) How much you have implemented already in this project? (4) What is left to be implemented that you could not do? (5) What are the difficulties and challenges you faced for this project? (6) Design and simulation figures and tables. (7) Formal references. Note: (1) The text and figures to be used should be your own. Draw the figures that you want to use Write in your own words. (2) Use latex for your writing as it is considered better for technical writing./n⚫ ELECTRONIC SYSTEM DESIGN Do a project by taking any of the IEEE paper related to Electronic System Design. • Create an abstract of 1-3 pages. Please provide information of the project as follows: • It should have a title. • What is the project all about? • Why do you want to do this specific as a project? What will you implement? What tools needed to implement it? Formal References. • No plagiarism. Topics related to Electronic System Design: (for reference) Integrated Circuits and Systems • Microprocessors Device Technology VLSI design Nanoelectronic based energy efficient design, high performance design, reliable system design, secure system design targeted for Internet of Things (IoT) and smart city components, etc/n Title: Real-Time Embedded System Design Using Microprocessor for Industrial Control Applications Abstract: In the pursuit of meeting the rising industrial emerging need for modern control systems, our project aims to develop a true-time embedded system that uses microprocessor technology. The industries that nowadays heavily rely on real time monitoring and control for both performance and safety optimization, have consequently generated increased demand for sophisticated control solutions. Microprocessor evolution turns out to be a critical input factor which ensures the implementation of super complicated control algorithms with high precision and adherence to fundamental timing constraints. The main stimulus for this project is the wide range of operational problems which the users encounter during real-time control of industrial systems. This dilemma varies in different areas like multi-processes coordination, timing synchronization that is precise, and working platforms that can handle various kinds of hardware and software units. Our intention is to design an intricate structure that is easy-to-use, state of the art, reliable and capable of operating with complex or simple algorithms and operations like that all with no efforts, but by the power of microchips. This project has the design and prototyping in the center of the development process. This process deals with the physical and software parts which constitute the embedded system. 2 The hardware side involve the process of a complete selection that involve the in depth study of microprocessor platforms to find the best one which is endowed with high computational ability as well as an array of peripherals essential for Sensing/metering functions, control (regulation), data acquisition, actuating and supervision in the control applications. Moreover, the Hardware design is also prioritized on critical issues such as robustness, durability, and ease of merger into previous industrial infrastructures securing interoperation in any industrial conditions. Additionally, the layout and design of printed circuit boards (PCBs) turns out to be a critical part of a hardware prototyping phase, and which will provide suitable signal integrity, power distribution, and thermal management to the microprocessor and peripheral components. Through the application of advanced technologies such as the SMT (surface-mount process) and the multi-layer PCB design, an increase in performance, reliability, and downsizing, which is necessary given the dimensions of the space restricted in industrial installations, is achieved. Through the severe test and verification of confirmation of quality, including the functional tests, the environmental stress tests, and reliability tests are performed to prove the performance, reliability, and durability of the software system running under different operation conditions. However, the real-time operating system (RTOS) application layer, the whole project is centered around a highly evolved precise real-time operating system meticulously developed by special requirements of the industrial control. This corresponds to the implementation of multiple control algorithms with an immense number of data acquisition routines, communication protocols and various fault detection systems and all this is coordinated precisely to ensure optimum output as operations change. Importantly, the software architecture revolves around principles of modularity and scalability making it a perfect base for the future modifications and customization of the industrial embedded system that will adapt to new industrial demands. 3 In order to implement this project successfully, we are going to apply a range of sophisticated tools and resources that are absolutely necessary for achieving planned outcomes. Microprocessor development kits are a key component for prototyping purposes as they help with hardware components integration and testing without hassle. Integrated development environments (IDE) are provided through which programmers can work effectively with ease of development, debugging and optimization. The simulation tools are very essential in the general testing and validation of the system to infer that the system will be performing optimally in all operating cases and conditions. Not only does access to huge documentation, technical resources, as well as the expert support of renowned industry veterans play a pivotal role in facing the complex challenges of designing and implementing the industrial embedded systems, but it also makes the job easier. Finally, this project is a real demonstration of how imagination can contribute to resolving the high-tech issues that arise due to the massive growth of time-critical control system applications in industry. This project attacks the issue of industrial automation by using microprocessor technology in order to create the way for additional descents in manufacturing and operation industries performance. We will be bringing a new era where production speed will be high, operation efficiency will be extremely elevated and the level of workers safety and wellbeing will be higher than ever. References: 1. IEEE Xplore. (2007). Real-time Embedded System Design Using Microprocessor for Industrial Control Applications. Retrieved from https://ieeexplore.ieee.org/document/4159109 2. Engpaper.com. (n.d.). Microprocessor IEEE Papers. Retrieved from https://www.engpaper.com/microprocessor-ieee-paper.html 3. IEEE Xplore. (n.d.). Definitions: IEEE Standard Dictionary of Electrical and Electronics Terms. Retrieved from https://ieeexplore.ieee.org/document/546563/definitions?ctx=definitions 4. Elprocus. (n.d.). Embedded Microprocessor: Importance and Its Real-Time Applications. Retrieved from https://www.elprocus.com/embedded-microprocessor-importance- and-its-real-time-applications/ 4

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