OPTICAL COMMUNICATION.pptx
- 1. OPTICAL COMMUNICATION INTRODUCTION TO OPTICAL FIBERS PART-1
- 2. INTRODUCTION • Fiber-optic communication is a method of transmitting information from one place to another by sending pulses of light through an optical fiber. The light forms an electromagnetic carrier wave that is modulated to carry information. Fiber is preferred over electrical cabling when high bandwidth, long distance, or immunity to electromagnetic interference are required. This type of communication can transmit voice, video, and telemetry through local area networks, computer networks, or across long distances.
- 3. PROCESS OF COMMUNICATING USING FIBER- OPTICS The process of communicating using fiber-optics involves the following basic steps: 1. Creating the optical signal involving the use of a transmitter, usually from an electrical signal 2. Relaying the signal along the fiber, ensuring that the signal does not become too distorted or weak 3. Receiving the optical signal 4. Converting it into an electrical signal
- 4. ADVANTAGES OF FIBER OPTIC TRANSMISSION • EXTREMELY HIGH BANDWIDTH: no other cable-based data transmission medium offers the bandwidth that fiber does. The volume of data that fiber optic cables transmit per unit time is far great than copper cables. • LONGER DISTANCE: in fiber optic transmission, optical cables are capable of providing low power loss, which enables signals can be transmitted to a longer distance than copper cables. • RESISTANCE TO ELECTROMAGNETIC INTERFERENCE: in practical cable deployment, it’s inevitable to meet environments like power substations, heating, ventilating and other industrial sources of interference. However, fiber has a very low rate of bit error (10 EXP- 13), as a result of fiber being so resistant to electromagnetic interference. Fiber optic transmission is virtually noise free. • LOW SECURITY RISK: the growth of the fiber optic communication market is mainly driven by increasing awareness about data security concerns and use of the alternative raw material. Data or signals are transmitted via light in fiber optic transmission. Therefore
- 5. • SMALL SIZE: fiber optic cable has a very small diameter. For instance, the cable diameter of a single OM3 multimode fiber is about 2mm, which is smaller than that of coaxial copper cable. Small size saves more space in fiber optic transmission. • LIGHT WEIGHT: fiber optic cables are made of glass or plastic, and they are thinner than copper cables. These make them lighter and easy to install. • EASY TO ACCOMMODATE INCREASING BANDWIDTH: with the use of fiber optic cable, new equipment can be added to existing cable infrastructure. Because optical cable can provide vastly expanded capacity over the originally laid cable. And WDM (wavelength division multiplexing) technology, including CWDM and DWDM, enables fiber cables the ability to accommodate more bandwidth
- 6. DISADVANTAGES OF FIBER OPTIC TRANSMISSION • FRAGILITY: usually optical fiber cables are made of glass, which lends to they are more fragile than electrical wires. In addition, glass can be affected by various chemicals including hydrogen gas (a problem in underwater cables), making them need more cares when deployed under ground. • DIFFICULT TO INSTALL: it’s not easy to splice fiber optic cable. And if you bend them too much, they will break. And fiber cable is highly susceptible to becoming cut or damaged during installation or construction activities. All these make it difficult to install. • ATTENUATION & DISPERSION: as transmission distance getting longer, light will be attenuated and dispersed, which requires extra optical components like edfa to be added.
- 7. • COST IS HIGHER THAN COPPER CABLE: despite the fact that fiber optic installation costs are dropping by as much as 60% a year, installing fiber optic cabling is still relatively higher than copper cables. Because copper cable installation does not need extra care like fiber cables. However, optical fiber is still moving into the local loop, and through technologies such as fttx (fiber to the home, premises, etc.) And pons (passive optical networks), enabling subscriber and end user broadband access. • SPECIAL EQUIPMENT IS OFTEN REQUIRED: to ensure the quality of fiber optic transmission, some special equipment is needed. For example, equipment such as OTDR (optical time-domain reflectometry) is required and expensive, specialized optical test equipment such as optical probes and power meter are needed at most fiber endpoints to properly provide testing of optical fiber.
- 8. APPLICATIONS OF OPTICAL FIBER COMMUNICATIONS • MEDICAL Used as light guides, imaging tools and also as lasers for surgeries • DEFENSE/GOVERNMENT Used as hydrophones for seismic waves and SONAR , as wiring in aircraft, submarines and other vehicles and also for field networking • DATA STORAGE Used for data transmission • TELECOMMUNICATIONS Fiber is laid and used for transmitting and receiving purposes • NETWORKING Used to connect users and servers in a variety of network settings and help increase the speed and accuracy of data transmission
- 9. • INDUSTRIAL/COMMERCIAL Used for imaging in hard to reach areas, as wiring where EMI is an issue, as sensory devices to make temperature, pressure and other measurements, and as wiring in automobiles and in industrial settings • BROADCAST/CATV Broadcast/cable companies are using fiber optic cables for wiring CATV, HDTV, internet, video on- demand and other applications Fiber optic cables are used for lighting and imaging and as sensors to measure and monitor a vast array of variables. Fiber optic cables are also used in research and development and testing across all the above mentioned industries
- 10. OTHER APPLICATIONS • Used in telephone systems • Used in sub-marine cable networks • Used in data link for computer networks, CATV systems • Used in CCTV surveillance cameras • Used for connecting fire, police, and other emergency services. • Used in hospitals, schools, and traffic management systems. • They have many industrial uses and also used for in heavy duty constructions
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