Encoding Techniques Based on Reversible Quantum Dot Cellular Automata
الشريط الجانبي للمقالة
محتوى المقالة الرئيسي
الملخص
Line encoding technique is essential for data transfer in IoT. It entails encoding the unprocessed bit stream according to designated protocols before transmission. Diverse baseband encoding schemes, including Manchester, Miller, and FM0 codes, are employed to improve communication efficacy. These systems ensure the transmitted signal has zero mean, addressing the issue, of DC balance. These systems ensure the transmitted signal has zero mean, addressing the issue of DC balance. Each encoding strategy should be deployed without missing any of its parameters required. Employing quantum reversible gates can coordinate all encoding techniques, reducing area consumption. The circuit consists of the FM0, Manchester, and Miller encoding to overcome the limitations of current techniques. This derived layout of the FM0 and Manchester coding could promote the DSRC specifications. This paper evaluates the FM0, Manchester, and Miller encoding using QCA Designer, achieving notable reductions in cell count and area. FM0 encoding requires 188 cells, Manchester encoding utilizes 9 cells, and Miller needs 140 cells. The achieved areas (nm2) were 287512, 24072, and 194969, respectively.
تفاصيل المقالة
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