Dados Gerais do Componente Curricular
| Tipo do Componente Curricular: |
DISCIPLINA |
| Tipo de Disciplina: |
|
| Forma de Participação: |
|
| Unidade Responsável: |
COORDENAÇÃO DE CURSO DE PÓS-GRADUAÇÃO DE ENGENHARIA ELÉTRICA (11.45.15) |
| Código: |
EM612E |
| Nome: |
OPTICAL SYSTEMS AND APPLICATIONS |
| Carga Horária Teórica: |
45 h. |
| Carga Horária Prática: |
0 h. |
| Carga Horária Total: |
45 h. |
| Pré-Requisitos: |
|
| Co-Requisitos: |
|
| Equivalências: |
|
| Excluir da Avaliação Institucional: |
Não |
| Matriculável On-Line: |
Sim |
| Horário Flexível da Turma: |
Não |
| Horário Flexível do Docente: |
Sim |
| Obrigatoriedade de Nota Final: |
Sim |
| Pode Criar Turma Sem Solicitação: |
Não |
| Necessita de Orientador: |
Não |
| Exige Horário: |
Sim |
| Permite CH Compartilhada: |
Não |
| Quantidade de Avaliações: |
1 |
| Ementa/Descrição: |
Introduction to optical communications: Introduces the main concepts and fundamentals of the optical communications.
Optical measurements: techniques and equipment to deal with optical measurements.
Linear and nonlinear effects: linear and nonlinear effects that may occur over fiber-optic transmission.
Optical devices: different types of optical devices, e.g. laser, photodetector, amplifier, polarization controller, modulator, attenuator, circulator, splitter, filter.
Optical systems: topologies and standards/generations for optical networks and their typical applications.
Fiber-based long-range links: Covers the fiber-optic use for long-range and high-capacity
communications.
Optics for Smart Grid: optical technology for Smart Grid applications.
Optics for IoT and 5G: optical technology for IoT and 5G applications.
Introduction to photonics: Introduces the photonic technology and potential applications.
Objectives:
Upon completion of the course, students will be able to perform the following tasks:
Describe the fundamentals of optical communications, advantages and drawbacks, usage
scenarios, types of fiber, types of connection and optical measurement procedures.
Describe the linear and nonlinear effects, how they can affect the fiber-optic communication and
how they can be avoided or exploited for taking benefits.
Describe the function, main characteristics and technical specifications of several optical
devices, as well as the point in which these devices are commonly employed in the optical
communication systems.
Describe how an optical network can be designed, differentiate topologies and standards, in
addition to associate topologies with promising applications.
Explain how the optical technology can be used to provide solutions in long-range
communication, smart grid, IoT and 5G applications.
Propose innovative optical-based solutions for different segments of electrical engineering.
Describe how photonics may favor engineering applications. |
| Referências: |
1. RIBEIRO, José Antônio Justino. Comunicações ópticas. São Paulo: Érica, 2009.
2. AGRAWAL, G. P. Fiber-optic communication systems. Hoboken: John Wiley & Sons, 2010.
3. SENIOR, J. M. Optical fiber communications: principles and practice. London: Prentice Hall, 2009.
4. KEISER, G. Optical communications essentials. New York: McGraw-Hill, 2003.
5. SALEH, B. E. A.; TEICH, M. C. Fundamentals of photonics. Hoboken: John Wiley & Sons, 2007.
6. AGRAWAL, G. P. Lightwave technology: telecommunication systems. Hoboken: John Wiley & Sons,
2005.
7. BASS, Michael. Handbook of optics. New York: Mc Graw Hill, 2010.
8. BERGER, L. T.; INIEWSKI, K. Smart grid: applications, communications, and security. Hoboken: John
Wiley & Sons, 2012. |
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