Simulación de nano sistemas de comunicaciones en NS3 en función a los componentes comunicacionales establecidos por el estándar IEEE 1906.1
ABSTRACT: Molecular Communication (MC) over the past five years has emerged as a promising information transmission and receiving technique for applications primarily related to medicine. The MC started as an area of interdisciplinary research in which nanotechnology, biology and communications engi...
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| Format: | bachelorThesis |
| Language: | spa |
| Published: |
2021
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| Subjects: | |
| Online Access: | http://dspace.unach.edu.ec/handle/51000/7805 |
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Add Tag | Summary: | ABSTRACT: Molecular Communication (MC) over the past five years has emerged as a promising information transmission and receiving technique for applications primarily related to medicine. The MC started as an area of interdisciplinary research in which nanotechnology, biology and communications engineering interact. For this new paradigm, molecules are used as a transport of information between nanodevices in small dimensions and specific environments. In this context, this thesis work aims to analyze and simulate in the discrete event simulator (NS3) the molecular communication scenario proposed by the IEEE 1906.1 standard. In addition, through the analysis, it reports the operation and detailing each of the communication components involved in an MC, making use of theoretical and practical definitions of the IEEE 1906.1 standard. In addition, it is intended to report the challenges of this type of communications. Chapter 1 details the problem that motivated the development of this investigation and sets out its objectives. Chapter 2 describes molecular communications theoretically based on books, journals and scientific publications related to the subject, so that it is intended to be an initial analysis of the proposed topic. Chapter 3 performs a methodological analysis of the IEEE 1906.1 standard and details the role of each one of the standard components and entities involved in the transmission and reception of molecular information in the simulator, detailing the classes, methods and functions that are implemented in each of the standard components. Chapter 4 shows the results obtained from simulations of molecular communication in NS3 software and analyses how they work, and measures performance based on the modification of variables influencing communication. Chapter 5 provides conclusions to the research work carried out and recommendations that could assist future research on the subject proposed in this thesis work. |
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