Advancements in Simplex Communication: Harnessing Li-Fi Technology
Keywords:
Simplex Communication, Li-Fi Technology, LED, LCDAbstract
This paper explores the implementation of Li-Fi technology for data transmission, utilizing an Arduino microcontroller, LCD with I2C communication, and a photovoltaic cell for signal reception. Li-Fi leverages visible LED light as a medium to transmit data, offering an alternative to conventional wireless communication methods. The study aims to assess the feasibility and efficacy of Li-Fi in controlled environments, with a focus on reliability, security, and interference immunity. The research methodology involves designing a transmitting module with an Arduino board and LED, and a receiving module equipped with a photovoltaic cell. Data is encoded into binary format and modulated onto the LED light source for transmission. The receiving module captures and converts modulated light signals into electrical signals for decoding. Integration of the Arduino LCD with I2C communication streamlines data transfer between the microcontroller and display, simplifying system complexity. Results demonstrate the viability of Li-Fi for data transmission, highlighting its reliability and security while avoiding interference from conventional radio frequency signals. The successful implementation of a Li-Fi-based data transmission system underscores its potential as an alternative communication solution, particularly in environments with limited radio frequency spectrum or susceptible to radio signal interference. This research contributes to advancing Li-Fi technology and opens avenues for innovative wireless communication solutions across various domains, addressing challenges posed by limited radio frequency spectrum and offering a secure alternative to traditional wireless communication methods.
References
R. R. Sharma, R. Raunak, and A. Sangeanl, "Li-Fi Technology: Transmission of data through light," Li-Fi can be easily implemented on the existing communication system with the integrations with regular light bulb.
R. Karthika and S. Balakrishnan, "Wireless Communication using Li-Fi Technology," Li-Fi is ideal for high density wireless data coverage in confined area and for relieving radio interference issues.
M. Ayvash et al., "Coexistence of WiFi and LiFi Toward 5G: Concepts, Challenges, and Technologies," Wi-Fi is provided for mobile users and Li-Fi is provided for stationary users.
S. R. Mugunthan, "Concept of Li-Fi on Smart Communication between Vehicles and Traffic Signals," There is no universal Li-Fi transceiver that is suitable for all application.
A. Chakraborty et al., "Latest advancement in Li-Fi Technology," Li-Fi is predicted to get very famous and useful in the near future.
B. O. Sadiq et al., "Investigative Analysis Of Li-Fi Efficiency In 2D And 3D Image Transmission," The channel provides high security due to the fact that light rays do not penetrate walls as well as the reasonable bandwidth.
H. V. Kindarley et al., "Image and Data Transmission using Visible Light Communication (Li-Fi)," LED has high efficiency, durability, reliability and high data rate than any other source of light.
S. Gupta and K. Sharma, "Enhanced Security Mechanisms in Li-Fi Communication Systems," investigates advanced security measures for Li-Fi communication systems.
A. Patel et al., "Integration of Li-Fi with Internet of Things (IoT) for Smart Environments," explores the integration of Li-Fi technology with IoT devices.
N. Singh and M. Kumar, "Li-Fi Technology for Underwater Communication: Challenges and Opportunities," discusses the potential of Li-Fi technology for underwater communication.
P. Mehta and R. Jain, "Li-Fi-Based Indoor Localization Systems: Techniques and Performance Evaluation," evaluates indoor localization systems based on Li-Fi technology.
T. Das et al., "Li-Fi for Medical Applications: Advancements and Future Prospects," explores the use of Li-Fi technology in medical applications.
K. Mishra and S. Gupta, "Li-Fi for Vehicular Communication: Challenges and Solutions," examines the feasibility of using Li-Fi for communication between vehicles.
R. Patel and S. Shah, "Li-Fi Technology for Rural Connectivity: Opportunities and Challenges," investigates the potential of Li-Fi technology to provide connectivity in rural areas.
R. Sharma and S. Gupta, "Li-Fi Technology: A Comprehensive Review and Future Directions," provides an in-depth review of Li-Fi technology.
M. Patel et al., "Li-Fi-Based Smart Lighting Systems: Design and Implementation," focuses on the design and implementation of smart lighting systems using Li-Fi technology.
A. Kumar and N. Jain, "Li-Fi for Wearable Devices: Challenges and Opportunities," explores the use of Li-Fi technology in wearable devices.
S. Singh and P. Sharma, "Li-Fi in Education: Enhancing Classroom Connectivity and Collaboration," investigates the integration of Li-Fi technology in educational settings.
K. Gupta et al., "Li-Fi-Based Security Systems: Implementation and Performance Evaluation," focuses on the implementation and performance evaluation of Li-Fi-based security systems.
R. Mehta and S. Verma, "Li-Fi Technology for Smart Agriculture: Monitoring and Control Applications," examines the use of Li-Fi technology in smart agriculture systems.
A. Gupta et al., "Li-Fi Technology: Challenges and Opportunities in Industrial IoT Applications," investigates the challenges and opportunities of implementing Li-Fi technology in industrial IoT applications.
S. Mishra and R. Singh, "Li-Fi Technology for Indoor Localization and Navigation," explores the use of Li-Fi technology for indoor localization and navigation purposes.
N. Kumar et al., "Li-Fi-Based Healthcare Systems: Remote Monitoring and Telemedicine Applications," examines the implementation of Li-Fi technology in healthcare systems for remote patient monitoring, telemedicine, and medical data transmission.
P. Jain and M. Gupta, "Li-Fi Technology for Smart Cities: Infrastructure and Connectivity Solutions," focuses on the role of Li-Fi technology in building smart city infrastructure and providing connectivity solutions for urban environments.
R. Tiwari and S. Verma, "Li-Fi-Based Environmental Monitoring Systems: Applications and Deployment Challenges," investigates the use of Li-Fi technology in environmental monitoring systems for collecting data on air quality, water pollution, and climate parameters.
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