Practical Applications of EM Spectrum PDF

Summary

This document provides an overview of the practical applications of the electromagnetic spectrum. It covers various types of electromagnetic waves, their properties, and uses, such as radio waves for communication, microwaves for cooking and radar, and X-rays for medical imaging.

Full Transcript

 Practical
Applications of EM
Spectrum
The Electromagnetic Spectrum
v.

Visible
Microwave
Light
RADIO
WAVES
RADIO WAVES
v Radio waves have the
longest wavelengths in
the electromagnetic
spectrum.
v They are used to transmit
radio and television
signal.
RADIO WAVES
v The transmission and reception
of radio waves is dependent on
oscillating charges.
v When these radio waves
encounter the antenna system
of a radio receiver, small electric
oscillations are set up in the
antenna in synchronization with
their own vibrations.
RADIO WAVES
v Radio development began as a wireless telegraphy, a
historical term for early radio telegraph communications
techniques and practices, particularly those used during
the first three decades of radio (1887 to 1920).

v As early as 1790s, the first fixed semaphore system (visual
telegraphy) was developed in Europe, but it was not until
the 1830s that electrical communication system has
started to appear.
RADIO WAVES
v One of the early experiments in electrical
telegraphy was an electrochemical telegraph
created by Samuel Thomas von Sommering in
1809.
v Sir Charles Wheatstone and Sir William
Fothergill Cook constructed the first
commercial electrical telegraph in England,
while Samuel Morse was also doing his own
version of the same technology on the other
side of the Atlantic Ocean.
RADIO WAVES
v James Clerk Maxwell who showed
mathematically that electromagnetic waves
could propagate through free space.
v Heinrich Rudolf Hertz and many others
demonstrated, on a laboratory scale, radio
wave propagation.
v Nikola Tesla experimented on the transmission
and radiation of radio frequency energy and
proposed for the telecommunication of
information.
RADIO WAVES
v In 1876, the conventional telephone was
invented by Alexander Graham Bell. Years
after its patent to Bell, the technology grew
quickly, enabling telephone exchanges in every
major city of the United States by the mid-
1880s.
v In terms of radio and television, James Lindsay
demonstrated wireless telegraphy within a
two-mile distance using water as a
transmission medium in 1854.
RADIO WAVES
v Around the turn of the century, the Slaby-Arco Wireless System
was developed by Adolf Slaby and Georg von Arco.
v In 1900, Reginald Fessenden made a weak transmission of voice
over the airwaves.
v Guglielmo Marconi was the first to demonstrate the application
of radio in commercial, military, and marine communications and
started a company for the development and propagation of radio
communication services and equipment. In 1901, he conducted
the first successful transatlantic experimental radio
communications, which gave him the patent for the invention of
radio and Nobel Prize in Physics in 1909.
RADIO WAVES
v In October 1925, Scottish inventor, John
Logie Baird, was able to obtain moving
pictures with halftone shades, which were,
by most accounts, the first true television
pictures. His device was known as the
mechanical television, which was the basis
of semi-experimental broadcasts done by
the British Broadcasting Corporation
beginning September 30, 1929
MICROWAVES
Microwaves
v Microwaves are basically
extremely high frequency
radio waves.
v They have very short
wavelengths ranging from
approximately one
millimeter to 30
centimeters.
Microwaves
v Microwaves are used in telecommunication,
such as mobile phones.
v They are also used by fixed traffic speed
camera, in cooking food, and in radar to
determine the range, altitude, direction, or
speed of both moving and fixed objects, such
as aircraft, ships, spacecraft, missiles, motor
vehicles, and weather formations.
INFRARED
Infrared
v Sir William Herschel
discovered in 1800
the existence of
infrared by passing
sunlight through a
prism.
Infrared
v Sir William Herschel
discovered in 1800
the existence of
infrared by passing
sunlight through a
prism.
Infrared
v Infrared is the EM radiation
with a wavelength longer than
that of visible light.
v Microscopically, infrared light
is typically emitted or
absorbed by molecules when
they change their rotational-
vibrational movements.
Infrared
v Infrared is the EM radiation
with a wavelength longer than
that of visible light.
v Microscopically, infrared light
is typically emitted or
absorbed by molecules when
they change their rotational-
vibrational movements.
Infrared
VISIBLE LIGHT
Visible Light
v Visible light is the portion of EM radiation
that is visible to the human eye. Light
waves are given off by anything that is hot
enough to glow. We see the light waves as
the colors of the rainbow.
v Red has the longest wavelength and violet
has the shortest. The other colors we see
have frequencies and wavelengths
intermediate between these two extremes.
When all the waves are seen together, they
make white light.
ULTRAVIOLE
T
Ultraviolet
v Ultraviolet is an EM radiation
with a wavelength shorter than
that of visible light, but longer
than x-rays.
v It is named because the spectrum
consists of electromagnetic waves
with frequencies higher than
those that humans identify as the
color violet.
Ultraviolet
v UV rays are used to prevent counterfeiters. Sensitive
documents, such as credit cards and passports, include a
UV watermark that is only seen under UV-emitting light.
Visa stamps also contain large detailed seals which are
invisible under the normal light but strongly visible under
UV illumination.
v UV is also helpful in crime scenes. Investigators can detect
and locate semen, saliva, and other bodily fluids using
high UV rays. Overexposure to UV may lead to skin cancer,
melanoma, and eye problems, such as photokeratitis or
sunburn of the cornea.
X-RAYS
X-rays
v X-rays are high-energy waves which
have great penetrating power and are
used extensively in medical
applications and in inspecting welds.

v In many languages, X-radiation is
called Röntgen radiation, after
Wilhelm Conrad Röntgen, who named
it as such in 1895, to signify an
unknown type of radiation.
X-rays
v X-rays are high-energy waves which
have great penetrating power and are
used extensively in medical
applications and in inspecting welds.

v In many languages, X-radiation is
called Röntgen radiation, after
Wilhelm Conrad Röntgen, who named
it as such in 1895, to signify an
unknown type of radiation.
X-rays
v Overexposure to x-rays may lead to
cancer such as leukemia. But the
harmful side effects of x-ray scanning
have also introduced radiotherapy, a
medical procedure that is often used
with chemotherapy, which uses very
high frequency x-rays to destroy
cancer cells.
GAMMA
RAYS
Gamma Rays
v Gamma rays are generated by
radioactive atoms and in nuclear
explosions, and are used in many
medical applications.

v They are more penetrating than x-
rays.
Gamma Rays
v In spite of their cancer-causing properties, gamma
rays are also used to treat some types of cancer. In
the procedure called Gammта Knife Surgery,
multiple concentrated beams of gamma rays are
directed on the growth in order to kill the cancerous
cells. The beams are aimed from different angles to
focus the radiation on the growth while minimizing
damage to the surrounding tissues.
The Electromagnetic Spectrum
v.
The Electromagnetic Spectrum
v.

Visible
Microwave
Light
The Electromagnetic Spectrum
v.
REVIEW
ACTIVITY 2:
3 Es
Activity 2: The 3Es
Directions: Use the 3’s to complete the table.
Types of EM Explain Examples Essence
Waves
1. Radio Waves
2. Microwaves
3. Infrared
4. Visible Light
4. Ultraviolet
5. X-rays
6. Gamma Rays
THANK YOU!