Optical communication is a wireless technology that can transmit a huge volume of data through optical fibres. In the era of wireless technologies, optical communication attains a significant position due to its ultra-high-speed wideband connection. By the by, it includes other core features such as enhanced channel security, very large bandwidth, lower mass (1/2 of RF systems), congestion-free bandwidth sharing, lower power (1/2 of RF), easy development, smaller sizer (1/10 of RF diameter). It is developed as a commercial alternative to replacing present RF communication. As well, it supports high gain and high data rates because of narrow beam deviation. It is eligible to transmit data bout 10 Gbps along with video/voice communication via free-air space.
From this page, you can code implementation details of optical communication projects with its new research updates!!!
How does optical communication work?
In general, the cables of optical fibers/fiber optics are thin elements of glass-like human hair and long. These elements are collectively called optical cables. Then, the optical fiber transmits the data / electric signals in the form of light pulses. Next, the light signals are received as original data at the receiver end. For your information, here we have given you the primary processes of fiber optic communication.
Steps for Optical Communication
- Optical signals are created from electrical signals through the transmitter
- Transmitting the optical signal with fiber to strengthen the signal against distortion
- Transforming optical signal back to an electrical signal
Due to tremendous advancements in optical communication, the imprints of optical communication are growing everywhere in the industrial and research sectors. Since it has created positive impacts by their original contribution to social developments. From our experience, we come with a crossed several applications based on real-world scenarios. Here, we have given you some mainstream optical communication applications. All these are collected from our repository of recent research directions of the optical-fiber network. Further, we also support you in other emerging applications/services.
Applications of Optical Communication
- GEO-to-Ground
- Ground Stations
- Ground-to-LEO
- Deep Space Examination
- LEO / GEO-to-Aircraft
- LEO-to-GEO/LEO-to-Ground
- High-Altitude Platforms (HAPs)
- Unmanned Aerial Vehicles (UAVs), etc.
Now, we can see two important types of optical communication in a wireless network. The current optical communication projects are surely come from any one of these types. Our experts from the resource team have recently analyzed different perceptions of optical communication in both of these types.
Based on the review information, we have framed an infinite number of research ideas in new dimensions. Are you curious to know those ideas? Then approach our team to handpick your inspired ideas from our latest project topics collections. We ensure you that we give guidance on both these types of communications.
Types of Wireless Optical Communication
- Outdoor System
- Space links
- Deep Space Links (DSL)
- Inter-Orbital Links (IOL)
- Inter-Satellite Links (ISL)
- Terrestrial Links
- Indoor System
- Diffused
- Directed LOS
- Tracked
- Non-Directed LOS
Transmission Types for Optical Communication
In optical communication, the optical wavelength has an influencing role to create impact due to dispersion and attenuation. Moreover, other windows/wavelength bands have the weakest impact to make transmission more beneficial. Our developers have developed optical communication projects in different transmission types (i.e., wavelength band). Here, we have given you some key defined wavelength bands which are more standardized from our development experience.
Wavelength Bands in Optical Communication
- Conventional “erbium window” (C) band
- Wavelength – From 1530 to 1565 nm
- Original (O) band –
- Wavelength – From 1260 to 1360 nm
- Ultra-long (U) band
- Wavelength – From 1625 to 1675 nm
- Long (L) band
- Wavelength – From 1565 to 1625 nm
- Short (S) band
- Wavelength – From 1460 to 1530 nm
- Extended (E) band
- Wavelength – From 1360 to 1460 nm
Overall, it is recognized as modern technology to fill the gaps of second as well as third windows which are formally separated. Now, we can see about different types of communication channels. Similar to transmission types, the mode of communication channels is also a more significant one to choose appropriately. Below, we have listed out few most important communication channels that are widely used in current optical communication projects. Based on the project requirements, we need to decide on the communication channel. When you connect with us, we help you to choose the right one for your project.
Types of Communication Channels for Optical Communication
- Free-Propagation Channels
- Mobile Radio Channels
- Satellite Channels
- Wireless Transmission Channels
- Guided Propagation Channels
- Optical Fiber Cable
- Telephone Cable
- Coaxial Cable
Next, we can see the various techniques of optical communication. All these techniques are essential to solve some primary research challenges of optical communication. When we suggest research solutions for your selected research issues, we undergo deep study on recent techniques to choose the best.
If we found that no one is well-efficient for your research issues. Then, we uniquely design a new algorithm/technique to solve those complex handpicked research issues. Let’s have quick look at the current demanding techniques of the optical communication field.
Current Techniques for Optical Communication Projects
- Receiver Improvement Approaches
- Interference Cancellation
- Maximum Likelihood Decoding
- Signal Reconstruction
- Signal Conversion Approaches
- Threshold
- Phase Modulation
- Hold and Sample
- Transmitter Improvement Approaches
- Power Amplifier Linearization
- Non-distortion less
- Peak Windowing and Cancellation
- Clipping
- Distortion less
- Constellation Extension
- Selected Mapping
- Tone Injection / Reservation
- Partial Transmit Sequences
- Coding
To the continuation, here we also shared the popular machine learning techniques by our expert’s suggestion. Similar to other fields, machine learning techniques spread their presence as a core technology in optical communication. Further, we also support you in other emerging technologies to produce the best result for your optical communication projects. Since our developers have handled bot the complex and simple research problems. To know your research solutions for your project, communicate with us.
Machine Learning Techniques for Optical Communication
- Unsupervised (Clustering)
- Probability Soft-clustering
- Fuzzy Logic
- Deterministic Hard-clustering
- K-Means
- Supervised (Regression and Classification)
- SVR
- FCNN
- ANN
- SVM
Now, we can see about the latest research project ideas of optical communication. All these ideas are assured to give the highest degree of future scope which enables you to do further study on the same areas. By the by, we have collected these ideas from current research areas of optical communication projects. If you want to know top-demanding research areas of optical communication then communicate with us using optical network simulator. We are here to provide your requested information in desired areas with elaborate elucidation.
Top 8 Project Topics in Optical Communication
- Design of New Optical Amplifiers, Transmitters and Receivers
- Enhanced Techniques of Signal Processing in Optical Communication
- Intelligible Optical Data Transmission at High Speed
- Assessment of Different Scenarios in Optical Access / Metro Communication
- Free-space Multimedia Communication over Optic Networks
- Multicore / Few-Mode Fibers for Spatial Division Multiplexing (SDM) Models
- Development of Short and Medium Reach Services using Diverse Modulation
- Cost and Energy-Aware Photonics Technologies for Metro / Access Networks
In addition, we have also given you some interesting research technologies of optical communication. To give you advanced research information, we collect more details about the latest research activities of current scholars in the optical communication field through research articles/magazines. In this way, we have recognized so many exciting research areas and technologies that are waiting to create a masterpiece in the optical communication research profession. For your reference, here we have given you only two technologies.
Optical Fiber Impact on IoT
IoT based Optical Fiber Architecture
- Layer of Terminal / End-user
- Intelligent Gadgets, RTU, Smart Meter, and Smart Electronic Peripherals
- Layer of Field Network (Wireless and Wired)
- Zigbee, Optical Fiber, Wi-Fi, and RFID
- Layer of Remote Communication (Wired and Wireless)
- 5G, LTE, 3G, 2G, and Optical Fiber
- Layer of Master Station System
- Consumption, Production, Distribution, and Transmission
Next, we can see the different taxonomy of optical fiber sensors that are broadly used in the internet of things (IoT) environment. Due to the several advantages of optical sensors, IoT projects majorly prefer different types of optical sensors.
Our developers are skilled enough to model and simulate personalized optical sensors for efficient data sensing and transmission. Further, we also suggest an appropriate optical sensor for your proposed application by analysing your project requirements. Since we have familiarity in all these sensor classifications with their functional needs.
Classification of Optical Sensors in IoT
- Application
- Bio-medical
- Chemical
- Physical
- Location
- Extrinsic (point-based)
- Intrinsic (distributed / point-based)
- Operating Principle
- Polarization (V, B, I)
- Phase-Interferometry (Sagnac, Michelson, Mach-zegnder, and Fabry-Perot)
- Frequency (Inflexible scattering/grating)
- Intensity (Evanescence, Bend loss, and Discontinuity)
Further, the impact of the internet of things on optical fiber communication is recently increasing more. As well, the main reasons behind these huge demands are given in the followings,
- Data Security
- No Data Loss while Interference Occurrences
- Fast Communication Media
LED in Fiber Optic Communication
One of the prime components in optical fiber communication is Light-Emitting Diodes (LED). This component is aimed to perform conversion of the electrical signal to an equivalent light signal. Then, this converted signal is injected into an optic fiber cable. By the by, the default features of LED are great to create an effect on system performance.
LED is considered a complex semiconductor due to its functionality of converting current from electrical energy to light energy. Although this process increases the speed of data transmission, it is required to generate less heat rather than incandescent lights. Further, LED is enriched with different key characteristics.
- Higher reliability
- Smaller size
- Larger radiance
- Variation at ultra-high speeds
- Smaller emitting area which is close to optical fiber
On the whole, we are here to provide the fullest research service in optical communication projects with coding support. Further, we also share our latest research ideas with you if you are curious about knowing new technologies in various research aspects. Also, we have a native writer team to give dissertation/thesis writing support. In simple words, we are here to give all necessary reliable research services from topic selection to manuscript submission. We hope that you won’t miss this opportunity of holding our hands to hit your targeted research aim.