ECE 3121 Optoelectronic Devices Lecture Notes PDF

Summary

These are lecture notes for an undergraduate course on optoelectronic devices. The document covers optoelectronics, applications, and working principles.It also describes various optoelectronic devices such as photoresistors, photovoltaic cells, photodiodes, photofets, LASCRs, and LEDs.

Full Transcript

ECE 3121
LECTURE 2: Optoelectronic Devices
Optoelectronics
The term optoelectronics means the interaction of light or optics
with electrons
Optoelectronic devices and optical fiber sensors have bought a
revolution in the field of communication, signal processing,
industrial instrumentation and measurement.
Photosensitive devices (photoconductive cells, photovoltaic cells,
photoresistors, photodiodes, light—activated SCR 's, photofets,
photo— transistors) convert the energy in light into electrical energy.
PHOTOEMISSIVE devices (light—emitting diodes) convert electrical
energy into light energy.
Applications of Optoelectronics
Telecommunications: Fiber optic communication systems rely on lasers,
modulators, and photodetectors to transmit data over long distances.
Displays: LEDs and OLEDs are used in various types of displays, such as
TVs, smartphones, and digital signage.
Medical Imaging: Lasers are used in medical imaging techniques like
laser scanning microscopy and laser therapy.
Sensing: Optical sensors are employed in environmental monitoring,
biometric identification, and industrial process control.
Data Storage: Laser diodes are used in optical storage devices like DVDs
and Blu-ray discs.
Defense and Security: Optoelectronic devices are used in night vision
systems, laser rangefinders, and missile guidance systems.
Optical Communication System
Working Principle
Information source gives the measurand to be
measured of the information to be transmitted, which is
electrical in nature

Electrical Transmitter/modulator modulates some
parameter or characteristic of light wave such as
wavelength, frequency or amplitude with respect to the
information

Optical Source converts electrical signal into optical
signal. Ex. LED, LASER etc.
Working Principle
Optical Fiber Cable carries the modulated light wave
through multiple total internal reflections to the
destination.

Optical detector re-converts the incoming light signal
into electrical signal. Ex. Photodiodes, photomultipliers,
photoconductors, photovoltaic cells etc.

Electrical Receiver/Demodulator demodulates/extracts
the original modulated information carrying content
from the signal and sends it to the required destination.
Advantages of Optoelectronic Devices
High Immunity to noise and electromagnetic
interference
High speed and bandwidth
Non-interference of light/optical signals
Easy integration of light and electrons
Optical fibers are of small size and occupy less space as
compared to their metallic counterparts.
Power loss and transmission loss is less in fiber cables as
compared to their metallic cables.
Optical communication has high degree of signal
security
Disadvantages of Optoelectronic Devices
Optoelectronics Sensors, devices and optical fibers are
very expensive
Optoelectronic devices are very fragile and delicate
It requires trained and skilled personnel to handle and
operate these systems.
Photosensitive Devices
1. Photoresistor - a device in which the internal resistance changes according
to the intensity of the light striking it.

Applications
Automatic Lighting Control
Burglar Alarms
Automated Blinds and Curtains
Display Brightness Control
Photosensitive Devices
2. Photovoltaic cell - The photovoltaic device is also known as a SOLAR CELL.
because it has a PN junction, it directly converts light energy into electrical
energy.

Applications
Residential Solar Energy Systems
Remote Power Supply:
Portable Electronic Devices
Agricultural Applications
Space Applications
Photosensitive Devices
3. Photodiode
A PN-junction diode that consumes light energy to produce an electric current.
They are also called a photo-detector, a light detector, and a photo-sensor.
Photodiodes are designed to work in reverse bias condition.

Applications
Optical Communication Systems
Light Sensors
Barcode Scanners and QR Code Readers
Industrial Automation
Smoke and Fire Detection
Photosensitive Devices
5. Photofets - The combination of light detection and signal amplification
makes photofets versatile devices that find applications in diverse fields,
including telecommunications, sensing, medical imaging, and scientific
research.

Applications
Optical Communication Receivers
Light Detection and Ranging (LiDAR):
Photosensitive Devices
6. LASCR - is an optoelectronic device that combines the properties of a
thyristor with light sensitivity. LASCRs can be triggered into conduction by
light, making them useful in various applications where light control of
electrical switching is required.

Applications
Light-Activated Switching
Remote Control Systems
Photoemissive Devices
1. Light-Emitting Diode - A Light Emitting Diode (LED) is a semiconductor
device, which can emit light when an electric current passes through it.

Applications
Illumination
Automotive Lighting
Decoration and Architectural Lighting
Traffic and Transportation
Photoemissive Devices
2. Optical Coupler - devices used to split or combine optical signals in
optical fiber communication systems. They play a crucial role in various
applications that involve transmitting, distributing, or combining optical
signals.