Design and implementation of embedded true parallelism jammer system using FGPA-SoC for low design complexity

The condition that drives a system to complete the processing of a number of functions within a given amount of time is called the real-time system. A projective missile system’s processing platforms face two major issues: high cost and structureal complexity. The system structure’s complexity is a...

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Format: Thesis
Language:English
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Online Access:http://dspace.unimap.edu.my:80/xmlui/bitstream/123456789/72440/1/Page%201-24.pdf
http://dspace.unimap.edu.my:80/xmlui/bitstream/123456789/72440/2/Full%20text.pdf
http://dspace.unimap.edu.my:80/xmlui/bitstream/123456789/72440/4/Hussein%20Ibrahim.pdf
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Summary:The condition that drives a system to complete the processing of a number of functions within a given amount of time is called the real-time system. A projective missile system’s processing platforms face two major issues: high cost and structureal complexity. The system structure’s complexity is a result of various reasons that include the mechanism utilised in the system in order to perform the system functionality. This mechanism can lead to delays in data processing because various factors, such as the synchronisation of the system modules’ signals, the processing unit’s architecture, and the unit’s computational power. In order to lessen system complexity and system cost, true parallelism mechanism is applied over the embedded system, along with a concurrent structure. The FPGA platform (DE1-SoC) was used as the implementation environment for this system. This led to an enriched implemented system that had low costs. Furthermore, the system complexity is lessened since the system uses a concurrent structure. Some of the modules that are closely related to the system are implemented to support main processing module. In this system, the signals covered were in four directions. The total logic element was (5032) and total registers was (5180). The Phase Locked Loop up to (1.6) GHz was manipulated in order to allow the system cover a wide spectrum of signals with high accuracy of computing process. Furthermore, the laser projective frequency jamming system is capable of processing multiple frequencies at a time. The implementation was able to obtain acceptable levels of throughput and it also lowered the complexity. Furthermore, the structural design methodology also makes it possible for the embedded concurrent computing architecture to be scalable while the entire system grows.