research paper on analog communication

• Corpus ID: 60992969

Analog and Digital Communication Systems

• Martin S. Roden
• Published 1979
• Engineering, Computer Science, Physics

67 Citations

Ofdm techniques for multimedia data transmission, high capacity optical transmission based on dispersion supported transmission with a binary signal at the receiver, chaotic frequency modulation, irregular sampling and local quantification scheme a-d converter, technique for achieving wideband 1/2 regenerative frequency division using lsb-ssb modulation, spectral efficiency and ber analysis in 802.16e standard, a dc-4 ghz logarithmic amplifier with fiber-optic applications, a signal conditioner for speech processing, chapter 5 – communications, pulsewidth modulation circuits using cmos otas, related papers.

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Noise in Analog Modulation

• First Online: 11 March 2023

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• Jerry D. Gibson 3  

Part of the book series: Synthesis Lectures on Communications ((SLC))

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When designing a communication system, the electrical engineer is usually confronted with limitations on transmitted power and available bandwidth. Required power and bandwidth figured prominently in our discussions of analog modulation techniques, AM, FM, and PM, in Chaps. 1 and 2 . In this chapter we consider the performance of these analog modulation methods in the presence of noise. Noise is an unavoidable aspect of any communication system. However, if we are willing (and able) to pay the price, say, in terms of excessive transmitted power or system complexity, the noise can be made to have a negligible impact on the performance of a communication system. In most instances, however, we are interested in designing the least expensive, most efficient, highest-performance system possible within the limits of our specifications. Of course, in these situations, analyses of the effects of noise on communication system performance are vitally important. Hence we are led to the purpose of this chapter.

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Department of Electrical and Computer Engineering, University of California, Santa Barbara, CA, USA

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Gibson, J.D. (2023). Noise in Analog Modulation. In: Analog Communications. Synthesis Lectures on Communications. Springer, Cham. https://doi.org/10.1007/978-3-031-19584-6_3

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DOI : https://doi.org/10.1007/978-3-031-19584-6_3

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• Investigating bioreactors for large-scale production of biological products.
• The role of biotechnology in developing vaccines for emerging diseases.
• Exploring bioinformatics tools for analyzing genetic data.
• Investigating the future of gene therapy in treating genetic disorders.
• The role of biotechnology in developing plant-based meat alternatives.
• Investigating microbial engineering for bioremediation applications.
• Exploring the use of 3D bioprinting in tissue engineering.
• Investigating bioengineering approaches to improving wound healing processes.
• The role of biotechnology in developing biodegradable plastics.
• Investigating the potential of algae as a sustainable energy source.
• Exploring the use of biosynthetic pathways for pharmaceutical production.
• The role of bioinformatics in advancing personalized medicine.
• Investigating the use of biotechnology in combating antibiotic resistance.
• Exploring advancements in stem cell engineering for regenerative therapies.
• Investigating biomaterials for use in medical implants.
• The role of biotechnology in improving water purification systems.
• Exploring bioengineering solutions for developing vaccines against cancer.
• Investigating gene editing technologies for improving agricultural sustainability.
• The future of DNA sequencing in understanding human evolution.
• The role of biotechnology in advancing drug discovery and development.
• Investigating biotechnology applications in environmental conservation.
• Exploring bioengineering solutions for reducing food waste.

Energy Engineering Thesis Topics

• Exploring advancements in solar energy harvesting and storage technologies.
• The role of wind energy in achieving global renewable energy targets.
• Investigating the impact of energy storage systems on grid stability.
• The future of hydrogen as a clean energy source: Challenges and opportunities.
• Exploring geothermal energy technologies for sustainable power generation.
• Investigating energy efficiency measures in large-scale industrial systems.
• The role of bioenergy in reducing dependence on fossil fuels.
• Investigating the integration of renewable energy sources into existing power grids.
• Exploring advancements in battery technologies for electric vehicles.
• The role of smart grids in optimizing energy distribution and consumption.
• Investigating the potential of wave and tidal energy for coastal regions.
• Exploring energy-efficient building designs for sustainable urban development.
• The impact of government policies on the adoption of renewable energy technologies.
• Investigating the role of artificial intelligence in energy management systems.
• Exploring the future of nuclear fusion as a long-term energy solution.
• The role of energy engineering in reducing carbon emissions from power plants.
• Exploring decentralized energy systems for rural electrification.
• Investigating smart metering technologies for improved energy efficiency.
• The role of thermal energy storage in renewable energy systems.
• Exploring the future of floating solar power plants.
• Investigating the potential of hybrid renewable energy systems for continuous power generation.
• The role of energy audits in optimizing industrial energy consumption.
• Exploring advancements in concentrated solar power (CSP) technologies.
• Investigating energy recovery systems for waste-to-energy plants.
• The role of blockchain technology in facilitating energy trading in decentralized grids.
• Exploring offshore wind farms: Engineering challenges and future potential.
• Investigating the use of AI in forecasting renewable energy generation.
• The role of energy-efficient transportation systems in reducing global emissions.
• Exploring energy policy frameworks for achieving net-zero carbon targets.
• Investigating the future of energy microgrids in sustainable urban environments.

Environmental Engineering Thesis Topics

• The role of environmental engineering in addressing plastic pollution in oceans.
• Investigating advanced wastewater treatment technologies for industrial effluents.
• Exploring sustainable urban drainage systems for flood prevention.
• The role of bioengineering in ecosystem restoration projects.
• Investigating carbon capture and storage technologies for reducing greenhouse gas emissions.
• The impact of urbanization on freshwater ecosystems: Engineering solutions.
• Exploring the future of air quality monitoring technologies.
• The role of environmental engineering in sustainable landfills and waste management.
• Investigating water treatment processes for desalination plants in arid regions.
• Exploring sustainable agriculture practices for reducing environmental impact.
• The role of environmental impact assessments in large-scale infrastructure projects.
• Investigating biofiltration systems for improving air quality in industrial areas.
• Exploring the potential of green roofs for urban cooling and energy efficiency.
• The role of environmental engineering in managing coastal erosion.
• Investigating the environmental benefits of urban green spaces and reforestation projects.
• Exploring the role of nanotechnology in water purification systems.
• Investigating microbial bioremediation for oil spill cleanup.
• The impact of climate change on water resource management: Engineering approaches.
• Exploring zero-waste engineering solutions for sustainable urban living.
• The role of environmental engineering in mitigating the urban heat island effect.
• Investigating the future of bioplastics in reducing plastic waste pollution.
• Exploring energy-efficient technologies in wastewater treatment plants.
• Investigating the use of algae in carbon sequestration and biofuel production.
• The role of environmental engineering in designing eco-friendly transportation systems.
• Exploring innovations in soil remediation technologies for contaminated land.
• Investigating environmental monitoring technologies for real-time pollution tracking.
• Exploring sustainable stormwater management systems for urban environments.
• The role of environmental engineering in managing deforestation and biodiversity loss.
• Investigating low-impact development techniques for sustainable urban planning.
• Exploring advancements in renewable energy technologies for off-grid rural communities.

Automotive Engineering Thesis Topics

• Exploring advancements in electric vehicle battery technologies for extended range.
• Investigating the role of AI in autonomous vehicle navigation systems.
• The future of hydrogen fuel cell vehicles: Challenges and opportunities.
• Exploring lightweight materials for improving fuel efficiency in automotive design.
• Investigating the impact of vehicle-to-everything (V2X) communication on road safety.
• The role of automotive engineering in developing electric trucks for long-haul transportation.
• Exploring advancements in regenerative braking systems for hybrid vehicles.
• Investigating the future of self-healing materials in automotive manufacturing.
• The role of aerodynamics in enhancing the performance of electric vehicles.
• Exploring advancements in wireless charging technologies for electric vehicles.
• Investigating smart sensors for enhancing vehicle safety and collision avoidance.
• The role of automotive engineering in reducing the environmental impact of internal combustion engines.
• Exploring the future of electric motorsport: Engineering challenges and opportunities.
• Investigating the potential of solar-powered vehicles in reducing energy consumption.
• The role of automotive engineers in designing energy-efficient autonomous drones.
• Exploring smart infotainment systems and their impact on the driving experience.
• Investigating advancements in automotive cybersecurity for connected vehicles.
• The future of solid-state batteries in electric vehicle development.
• Exploring vehicle-to-grid (V2G) technology for energy storage and distribution.
• The role of electric vehicle charging infrastructure in accelerating EV adoption.
• Investigating the impact of 3D printing on automotive manufacturing processes.
• The future of biofuels in reducing emissions from conventional vehicles.
• Exploring advanced driver-assistance systems (ADAS) for improving road safety.
• Investigating the role of automotive engineering in developing smart tire technologies.
• The impact of vehicle electrification on global oil consumption.
• Exploring autonomous vehicle ethics: Decision-making algorithms and moral dilemmas.
• Investigating advancements in crash testing technologies for electric vehicles.
• The role of hybrid powertrains in reducing fuel consumption and emissions.
• Exploring advancements in noise reduction technologies for improving passenger comfort.
• Investigating the future of fully autonomous public transportation systems.

Materials Engineering Thesis Topics

• Investigating the role of nanomaterials in enhancing the strength of structural composites.
• Exploring advancements in 3D printing materials for industrial applications.
• The impact of smart materials on the future of robotics and automation.
• Investigating the role of graphene in improving battery efficiency.
• Exploring biodegradable polymers for sustainable packaging solutions.
• Investigating the use of shape-memory alloys in aerospace engineering.
• The future of carbon fiber composites in lightweight vehicle design.
• Exploring advancements in high-temperature superconducting materials.
• Investigating biomaterials for medical implants and tissue engineering.
• The role of phase-change materials in enhancing energy efficiency in buildings.
• Exploring the impact of self-healing materials on the durability of infrastructure.
• Investigating corrosion-resistant materials for marine engineering applications.
• The role of advanced ceramics in high-performance engine components.
• Exploring smart textiles for wearable technology applications.
• Investigating advancements in materials for energy-efficient windows and insulation.
• The role of piezoelectric materials in energy harvesting technologies.
• Exploring biocompatible materials for use in drug delivery systems.
• Investigating the use of nanomaterials in improving the performance of solar cells.
• The future of eco-friendly construction materials in sustainable building design.
• Exploring advancements in composite materials for aerospace structures.
• Investigating materials for next-generation flexible electronics.
• The role of quantum dots in improving display technologies.
• Exploring the use of biomaterials for developing artificial organs.
• Investigating high-strength alloys for automotive and aerospace industries.
• The impact of materials engineering on the future of electric vehicle design.
• Exploring the role of polymers in reducing the environmental impact of packaging.
• Investigating sustainable materials for use in green building projects.
• The role of materials science in developing new catalysts for energy storage.
• Exploring advancements in thermal barrier coatings for gas turbines.
• Investigating the future of materials engineering in space exploration.

Robotics Engineering Thesis Topics

• Investigating the role of AI in enhancing robotic perception and decision-making.
• Exploring the future of humanoid robots in healthcare applications.
• The role of swarm robotics in optimizing complex tasks in industrial settings.
• Investigating advancements in soft robotics for medical and surgical applications.
• Exploring autonomous underwater robots for deep-sea exploration.
• The role of robotics in agriculture: Precision farming and crop monitoring.
• Investigating the future of robotics in space exploration missions.
• Exploring advancements in robotic exoskeletons for physical rehabilitation.
• The role of collaborative robots (cobots) in enhancing workplace safety.
• Investigating the use of biomimicry in robotics design for improved mobility.
• Exploring the impact of autonomous drones on logistics and delivery systems.
• The role of robotics in disaster response and search-and-rescue operations.
• Investigating sensor fusion techniques for improving robotic navigation.
• Exploring advancements in robotic vision systems for object recognition.
• The role of wearable robotics in assisting the elderly and disabled populations.
• Investigating advancements in autonomous robots for manufacturing industries.
• Exploring the future of AI-driven robots in smart cities.
• The role of robotic surgery in enhancing precision and reducing recovery times.
• Investigating the ethical implications of fully autonomous robots in warfare.
• Exploring the future of robotics in autonomous driving systems.
• Investigating tactile sensing technologies for improving robot-human interactions.
• The role of swarm intelligence in coordinating large-scale robotic systems.
• Exploring advancements in robotic grippers for delicate object handling.
• Investigating human-robot collaboration in industrial automation.
• The role of AI in improving the efficiency of robotic vacuum systems.
• Exploring the future of robotics in educational tools and learning environments.
• Investigating advancements in autonomous cleaning robots for commercial spaces.
• The role of robotics in environmental monitoring and conservation efforts.
• Exploring haptic feedback systems for enhancing the control of robotic arms.
• Investigating the future of modular robotics for adaptive manufacturing systems.

This comprehensive list of 600 engineering thesis topics highlights the breadth and depth of research possibilities available in various fields of engineering. From addressing current issues like sustainability and digital transformation to exploring future technologies such as quantum computing and AI, these topics provide students with an array of opportunities to engage in meaningful research. By selecting a topic that resonates with your academic interests and career aspirations, you can contribute valuable insights to the ever-evolving world of engineering.

The Range of Engineering Thesis Topics

Engineering is a dynamic and evolving field that plays a crucial role in shaping the future of technology, infrastructure, and innovation. With a wide array of disciplines, from civil engineering to robotics, students pursuing a degree in engineering have the opportunity to explore diverse and impactful topics for their thesis. This article provides an overview of the various directions students can take when selecting engineering thesis topics, focusing on current issues, recent trends, and future opportunities. By understanding these aspects, students can choose topics that not only align with their interests but also contribute to advancing the field of engineering.

Current Issues in Engineering

The engineering world is constantly responding to global challenges that affect industries, societies, and the environment. Many of these challenges provide excellent opportunities for thesis research.

• Sustainability and Renewable Energy One of the most pressing issues in modern engineering is the global demand for sustainable energy solutions. As the effects of climate change become more apparent, engineers are tasked with developing technologies that reduce carbon emissions and promote cleaner energy sources. Thesis topics in this area could include advancements in solar and wind energy, innovations in energy storage systems, or the integration of renewable energy into existing grids. These topics are critical as governments and industries push for decarbonization and energy efficiency in response to environmental concerns.
• Infrastructure and Urbanization Rapid urbanization and the growing population have placed immense pressure on infrastructure systems, leading to a range of engineering challenges. Civil engineers, in particular, are focusing on sustainable urban development, resilient infrastructure, and smart city technologies to address these concerns. Students can explore topics related to flood prevention, transportation systems, and the development of sustainable materials for construction. The demand for safer, more efficient, and environmentally friendly infrastructure is driving innovation in this sector.
• Cybersecurity and Data Protection With the increasing digitalization of industries, cybersecurity has emerged as a critical issue in the engineering world, particularly in fields such as computer engineering and electronics. Protecting sensitive data, securing communication systems, and safeguarding industrial control systems are significant challenges. Topics like cybersecurity protocols for IoT devices, secure communication in smart grids, and encryption technologies for industrial systems are crucial areas of research, especially as industries continue to digitize operations.

Recent Trends in Engineering

In addition to tackling ongoing global issues, engineers are also at the forefront of developing and integrating new technologies that are transforming industries and shaping the future.

• Autonomous Systems and Artificial Intelligence (AI) One of the most exciting trends in engineering is the rise of autonomous systems and AI. From self-driving cars to robotic assistants, these technologies are revolutionizing industries such as transportation, healthcare, and manufacturing. Robotics engineering and AI integration in various fields present a broad range of thesis topics, such as autonomous vehicle navigation, AI-driven robotics for medical applications, and ethical considerations in the deployment of autonomous systems. As these technologies continue to advance, they will redefine how we interact with machines and how businesses operate.
• Digital Twin and Simulation Technologies Digital twins and simulation technologies are gaining traction in sectors like manufacturing, aerospace, and energy. A digital twin is a virtual representation of a physical system that allows for real-time monitoring, predictive maintenance, and process optimization. Thesis topics in this area could explore the application of digital twin technology in smart manufacturing, its role in optimizing energy systems, or its use in predictive maintenance for complex infrastructure. This trend represents a shift towards more efficient, data-driven engineering processes that improve both productivity and sustainability.
• Advances in Materials Science Materials engineering is another area where recent trends are creating opportunities for innovation. The development of smart materials, nanomaterials, and biodegradable polymers is opening up new possibilities in fields such as healthcare, construction, and aerospace. Students interested in materials science can explore topics like the use of nanomaterials in medical devices, self-healing materials for infrastructure, or the development of eco-friendly packaging solutions. These advancements have the potential to transform industries by enhancing product performance and sustainability.

Future Directions in Engineering

As the field of engineering continues to evolve, emerging technologies and innovative approaches will shape its future. Students looking to push the boundaries of what’s possible should consider future-focused thesis topics that address upcoming challenges and opportunities.

• Quantum Computing and Quantum Engineering Quantum computing is poised to revolutionize industries by solving problems that are currently beyond the reach of classical computers. This cutting-edge field has the potential to transform areas such as cryptography, material science, and artificial intelligence. Engineering students interested in this area can focus on topics like the development of quantum algorithms, quantum communication technologies, or the integration of quantum computing with traditional systems. As quantum computing moves closer to practical application, engineers will play a critical role in its development and deployment.
• Sustainable Engineering and Circular Economies As environmental concerns continue to grow, the shift towards sustainable engineering practices and circular economies is gaining momentum. Circular economies focus on minimizing waste and maximizing the use of resources by reusing, recycling, and regenerating materials. Thesis topics could explore sustainable engineering solutions for waste management, energy recovery from waste, or the design of eco-friendly products that align with circular economy principles. These topics will become increasingly important as industries seek to reduce their environmental footprint.
• Space Exploration and Off-Earth Engineering The renewed focus on space exploration presents exciting opportunities for engineers to contribute to the development of off-Earth habitats, space travel, and resource utilization on other planets. With missions to Mars and the Moon on the horizon, thesis topics could include the development of space habitats, autonomous systems for extraterrestrial resource extraction, or the engineering of sustainable life support systems. As humanity ventures further into space, engineering will be at the forefront of solving the technical challenges involved.

Engineering offers a vast and diverse range of thesis topics that reflect the current challenges, recent trends, and future opportunities in the field. Whether you are interested in sustainability, robotics, or quantum computing, there is a wealth of possibilities for students to explore and contribute meaningful research. By focusing on areas that are driving innovation and addressing global issues, students can ensure their thesis projects have a lasting impact on both the engineering community and society as a whole. With the rapid pace of technological advancement, the future of engineering promises to be filled with new discoveries, challenges, and opportunities.

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