Computer Engineering as a Discipline PDF

Summary

This document provides a detailed overview of computer hardware, different types of computers, and their history. It covers a wide range of computer classifications, from personal computers to supercomputers, along with their associated characteristics and applications. The history section traces the key milestones and innovations in computer development, offering insights into the progression from early mechanical concepts to modern electronic devices.

Full Transcript

LESSON 1: COMPUTER HARDWARE
LEARNING OBJECTIVES
Define what is a computer
Explain the different types of computers
Know the different parts of computers and its peripheral devices
Know the history of development of computers

WHAT IS A COMPUTER

A computer is a machine or device that performs processes, calculations and operations based on
instructions provided by a software or hardware program. It is designed to execute applications and
provides a variety of solutions by combining integrated hardware and software components.

The term computer is derived from the Latin term ‗computare‘, this means to calculate or
programmable machine. Computer cannot do anything without a Program. It represents the decimal
numbers through a string of binary digits. The Word 'Computer' usually refers to the Center Processor Unit
Plus Internal memory.

The term "computer" was originally given to humans (human computers) who performed numerical
calculations using mechanical calculators, such as the abacus and slide rule. The term was later given to
a mechanical device as they began replacing the human computers. Today's computers are electronic
devices that accept data (input), process that data, produce output, and store (storage) the results.

COMPUTER TYPES

Computers are classified into five main categories which relies on the size and power of the unit:

1. Personal Computer (PC) - A small, single-user computer based on a microprocessor. Defined as
a small, relatively inexpensive computer designed for an individual user. In price, personal
computers range anywhere from a few hundred pounds to over five thousand pounds. All are based
on the microprocessor technology that enables manufacturers to put an entire CPU on one chip.
Businesses use personal computers for word processing, accounting, desktop publishing, and for
running spreadsheet and database management applications. At home, the most popular use for
personal computers is for playing games and recently for surfing the Internet. Furtherly classified
into its subtypes:
a. Tower Model - The term refers to a computer in which the power supply, motherboard,
and mass storage devices are stacked on top of each other in a cabinet. This is in contrast
to desktop models, in which these components are housed in a more compact box. The
main advantage of tower models is that there are fewer space constraints, which makes
installation of additional storage devices easier.
b. Desktop Model - A computer designed to fit comfortably on top of a desk, typically with
the monitor sitting on top of the computer. Desktop model computers are broad and low,
whereas tower model computers are narrow and tall. Because of their shape, desktop
model computers are generally limited to three internal mass storage devices. Desktop
models designed to be very small are sometimes referred to as slimline models.
 c. Notebook Computer - An extremely lightweight personal computer. Notebook computers
typically weigh less than 6 pounds and are small enough to fit easily in a briefcase. Aside
from size, the principal difference between a notebook computer and a personal computer
is the display screen. Notebook computers use a variety of techniques, known as flat panel
technologies, to produce a lightweight and non-bulky display screen. The quality of
notebook display screens varies considerably. In terms of computing power, modern
notebook computers are nearly equivalent to personal computers. They have the same
CPUs, memory capacity, and disk drives. However, all this power in a small package is
expensive. Notebook computers cost about twice as much as equivalent regular-sized
computers. Notebook computers come with battery packs that enable you to run them
without plugging them in. However, the batteries need to be recharged every few hours.
d. Laptop - A small, portable computer -- small enough that it can sit on your lap. Nowadays,
laptop computers are more frequently called notebook computers.

2. Workstation - A powerful, single-user computer. A workstation is like a personal computer, but it
has a more powerful microprocessor and, in general, a higher quality monitor. It is a type of
computer used for engineering applications (CAD/CAM), desktop publishing, software
development, and other types of applications that require a moderate amount of computing power
and relatively high quality graphics capabilities. Workstations generally come with a large, high-
resolution graphics screen, at large amount of RAM, built-in network support, and
a. graphical user interface. Most workstations also have a mass storage device such as a
disk drive, but a special type of workstation, called a diskless workstation, comes without
a disk drive. The most common operating systems for workstations are UNIX and Windows
NT. Like personal computers, most workstations are single-user computers. However,
workstations are typically linked together to form a local-area network, although they can
also be used as stand-alone systems.
3. Minicomputer - A multi-user computer capable of supporting up to hundreds of users
simultaneously. It is a midsize computer. In the past decade, the distinction between large
minicomputers and small mainframes has blurred, however, as has the distinction between small
minicomputers and workstations. But in general, a minicomputer is a multiprocessing system
capable of supporting from up to 200 users simultaneously.
4. Mainframe - A powerful multi-user computer capable of supporting many hundreds or thousands
of users simultaneously. Mainframe was a term originally referring to the cabinet containing the
central processor unit or "main frame" of a room-filling Stone Age batch machine. After the
emergence of smaller "minicomputer" designs in the early 1970s, the traditional big iron machines
were described as "mainframe computers" and eventually just as mainframes. Nowadays a
Mainframe is a very large and expensive computer capable of supporting hundreds, or even
thousands, of users simultaneously.
5. Supercomputer - An extremely fast computer that can perform hundreds of millions of instructions
per second. Supercomputer is a broad term for one of the fastest computers currently available.
Supercomputers are very expensive and are employed for specialized applications that require
immense amounts of mathematical calculations (number crunching). For example, weather
forecasting requires a supercomputer. Other uses of supercomputers scientific simulations,
(animated) graphics, fluid dynamic calculations, nuclear energy research, electronic design, and
analysis of geological data (e.g. in petrochemical prospecting).

HISTORY OF COMPUTERS
DATE EVENTS
1801 In France, Joseph Marie Jacquard invents a loom that uses punched wooden
cards to automatically weave fabric designs. Early computers would use similar
punch cards.

1890 Herman Hollerith designs a punch card system to calculate the 1880 census,
accomplishing the task in just three years and saving the government $5 million.
He establishes a company that would ultimately become IBM.

1936 Alan Turing presents the notion of a universal machine, later called the Turing
machine, capable of computing anything that is computable. The central concept
of the modern computer was based on his ideas.

1937 J.V. Atanasoff, a professor of physics and mathematics at Iowa State University, attempts to
build the first computer without gears, cams, belts or shafts.

Hewlett-Packard is founded by David Packard and Bill Hewlett in a Palo Alto, California,
garage, according to the Computer History Museum.

1941 Atanasoff and his graduate student, Clifford Berry, design a computer that can solve 29
equations simultaneously. This marks the first time a computer is able to store information on
its main memory.

1943-44 Two University of Pennsylvania professors, John Mauchly and J. Presper Eckert, build the
Electronic
Numerical Integrator and Calculator (ENIAC). Considered the grandfather of digital
computers, it fills a 20-foot by 40-foot room and has 18,000 vacuum tubes.

1946 Mauchly and Presper leave the University of Pennsylvania and receive funding from the
Census Bureau to build the UNIVAC, the first commercial computer for business and
government applications.

1947 William Shockley, John Bardeen and Walter
Brattain of Bell Laboratories invent the transistor. They discovered how to make an electric
switch with solid materials and no need for a vacuum.

1953 Grace Hopper develops the first computer language, which eventually becomes known as
COBOL. Thomas Johnson Watson Jr., son of IBM CEO Thomas Johnson Watson Sr.,
conceives the IBM 701 EDPM to help the United Nations keep tabs on Korea during the war.

1954 The FORTRAN programming language, an acronym for FORmula TRANslation, is developed
by a team of programmers at IBM led by John Backus, according to the University of Michigan

1958 Jack Kilby and Robert Noyce unveil the integrated circuit, known as the computer chip. Kilby
was awarded the Nobel Prize in Physics in 2000 for his work.

1964 Douglas Engelbart shows a prototype of the modern computer, with a mouse and a graphical
user interface (GUI). This marks the evolution of the cor from a specialized machine for
scientists and mathematicians to technology that is more accessible to the general public.
 1969 A group of developers at Bell Labs produce UNIX, an operating system that addressed
compatibility issues. Written in the C programming language, UNIX was portable across
multiple platforms and became the operating system of choice among mainframes at large
companies and government entities. Due to the slow nature of the system, it never quite
gained traction among home PC users.

1971 Alan Shugart leads a team of IBM engineers who invent the "floppy disk," allowing data to be
shared among computers.

1973 Robert Metcalfe, a member of the research staff for Xerox, develops Ethernet for connecting
multiple computers and other hardware.

1974-1977 A number of personal computers hit the market, including Scelbi & Mark-8 Altair, IBM 5100,
Radio Shack's TRS-80 — affectionately known as the "Trash 80" — and the Commodore
PET.

1975 The January issue of Popular Electronics magazine features the Altair 8080, described as
the "world's first minicomputer kit to rival commercial models." Two "computer geeks," Paul
Allen and Bill Gates, offer to write software for the Altair, using the new BASIC language.
On April 4, after the success of this first endeavor, the two childhood friends form their own
software company, Microsoft.

1976 Steve Jobs and Steve Wozniak start Apple Computers on April Fool's Day and roll out the
Apple I, the first computer with a single-circuit board, according to Stanford University.

1977 Radio Shack's initial production run of the TRS-80 was just 3,000. It sold like crazy. For the
first time, non-geeks could write programs and make a computer do what they wished.

1977 Jobs and Wozniak incorporate Apple and show the Apple II at the first West Coast Computer
Faire. It offers color graphics and incorporates an audio cassette drive for storage.

1978 Accountants rejoice at the introduction of VisiCalc, the first computerized spreadsheet
program.
1979 Word processing becomes a reality as MicroPro International releases WordStar. "The
defining change was to add margins and word wrap," said creator Rob Barnaby in email to
Mike Petrie in 2000. "Additional changes included getting rid of command mode and adding
a print function. I was the technical brains — I figured out how to do it, and did it, and
documented it. "
The first IBM personal computer, introduced on
Aug. 12, 1981, used the MS-DOS operating system.

1981 The first IBM personal computer, code-named "Acorn," is introduced. It uses Microsoft's MS-
DOS operating system. It has an Intel chip, two floppy disks and an optional color monitor.
Sears & Roebuck and Computerland sell the machines, marking the first time a computer is
available through outside distributors. It also popularizes the term PC.

1983 Apple's Lisa is the first personal computer with a GUI. It also features a drop-
down menu and icons. It flops but eventually evolves into the Macintosh. The
Gavilan SC is the first portable computer with the familiar flip form factor and the
first to be marketed as a "laptop."
1985 Microsoft announces Windows, according to Encyclopedia Britannica. This was
the company's response to Apple's GUI. Commodore unveils the Amiga 1000,
which features advanced audio and video capabilities.

1985 The first dot-com domain name is registered on March 15, years before the
World Wide Web would mark the formal beginning of Internet history. The
Symbolics Computer Company, a small
Massachusetts computer manufacturer, registers Symbolics.com. More than
two years later, only 100 dot-coms had been registered.

1986 Compaq brings the Deskpro 386 to market. Its 32bit architecture provides as
speed comparable to mainframes.
1990 Tim Berners-Lee, a researcher at CERN, the highenergy physics laboratory in
Geneva, develops HyperText Markup Language (HTML), giving rise to the
World Wide Web.

1993 The Pentium microprocessor advances the use of graphics and music on PCs.

1994 PCs become gaming machines as "Command & Conquer," "Alone in the Dark
2," "Theme Park," "Magic Carpet," "Descent" and "Little Big Adventure" are
among the games to hit the market.
1996 Sergey Brin and Larry Page develop the Google search engine at Stanford
University.

1997 Microsoft invests $150 million in Apple, which was struggling at the time, ending
Apple's court case against Microsoft in which it alleged that Microsoft copied the
"look and feel" of its operating system.

1999 The term Wi-Fi becomes part of the computing language and users begin
connecting to the
Internet without wires.

2001 Apple unveils the Mac OS X operating system, which provides protected
memory architecture and pre-emptive multi-tasking, among other benefits. Not
to be outdone, Microsoft rolls out Windows XP, which has a significantly
redesigned GUI.

2003 The first 64-bit processor, AMD's Athlon 64, becomes available to the consumer
market.

2004 Mozilla's Firefox 1.0 challenges Microsoft's Internet Explorer, the dominant Web
browser. Facebook, a social networking site, launches.

2005 YouTube, a video sharing service, is founded. Google acquires Android, a Linux-
based mobile phone operating system.

2006 Apple introduces the MacBook Pro, its first Intel based, dual-core mobile
computer, as well as an Intel-based iMac. Nintendo's Wii game console hits the
market.

2007 The iPhone brings many computer functions to the smartphone.
2009 Microsoft launches Windows 7, which offers the ability to pin applications to the
taskbar and advances in touch and handwriting recognition, among other
features.

2010 Apple unveils the iPad, changing the way consumers view media and
jumpstarting the dormant tablet computer segment

2011 Google releases the Chromebook, a laptop that runs the Google Chrome OS.

2015 Apple releases the Apple Watch. Microsoft releases Windows 10.

2016 The first reprogrammable quantum computer was created. "Until now, there
hasn't been any quantum-computing platform that had the capability to program
new algorithms into their system. They're usually each tailored to attack a
particular algorithm," said study lead author Shantanu Debnath, a quantum
physicist and optical engineer at the University of Maryland, College Park.

2017 The Defense Advanced Research Projects Agency (DARPA) is developing a
new "Molecular Informatics" program that uses molecules as computers.
"Chemistry offers a rich set of properties that we may be able to harness for
rapid, scalable information storage and processing," Anne Fischer, program
manager in DARPA's Defense Sciences Office, said in a statement. "Millions of
molecules exist, and each molecule has a unique three-dimensional atomic
structure as well as variables such as shape, size, or even color. This richness
provides a vast design space for exploring novel and multi-value ways to encode
and process data beyond the 0s and 1s of current logic-based, digital
architectures."

Activity 1. TRUE OR FALSE

Directions: Answer the following questions with True or False on the space provided.

1. In 1954 scientist were able to predict exactly what computers would like today.

2. Logging off the computer will close any open program

3. Search engines make it harder to find information on the internet.

4. John Lovelace created a machine called the Analytical Engine. His ideas were some of
the first that led to the creation of computers

5. Charles Babbage was created the first computer program. The program was made to
help the Analytical Engine calculate numbers.

6. Steve Jobs was known as inventor of the modern computer. He actually created the
first fully electronic computer.

7. The invention was 1,000 times faster than any machines built before it. It was big and
known as apple.
 8. The transistor replaced vacuum tubes and made computers much smaller and faster.

9. Al Gore invented the internet.

10. Resistor invented to helped make computer much smaller and faster

LESSON 2: COMPUTER PROCESSOR and AUTHENTICATION
IDENTIFICATION FUNCTIONS

LEARNING OBJECTIVES
Know what a Computer Processor is
Know the Types of Computer Processor
Know the history of development of computer processor

COMPUTER PROCESSOR
A processor, or "microprocessor," is a small chip that resides in computers and other electronic
devices. Its basic job is to receive input and provide the appropriate output. While this may seem like a
simple task, modern processors can handle trillions of calculations per second.

A computer processor is the part of a computer that analyzes, controls and disperses data.
Commonly referred to as the central processing unit or CPU, a computer processor acts as the brains of
the computer, telling which program and application to do what at a specific time and interval. Modern
computer processors operate with speeds of 2.6 to 3.66 gigahertz. The most advanced models are even
faster. It takes the form of a small microchip that fits into a series of sockets in the motherboard. The more
powerful the computer processor is on the computer, the faster and more efficient the machine will run.

Besides the central processing unit, most desktop and laptop computers also include a GPU. This
processor is specifically designed for rendering graphics that are output on a monitor. Desktop computers
often have a video card that contains the GPU, while mobile devices usually contain a graphics chip that is
integrated into the motherboard. By using separate processors for system and graphics processing,
computers are able to handle graphic-intensive applications more efficiently.

FUNCTION OF A COMPUTER PROCESSOR

A microprocessor is a silicon chip containing millions of microscopic transistors. This chip functions
as the computer's brain. It processes the instructions or operations contained within executable computer
programs. Instead of taking instructions directly off of the hard drive, the processor takes its instructions
from memory. This greatly increases the computer's speed.

TYPES OF COMPUTER PROCESSOR

A microprocessor is a silicon chip containing millions of microscopic transistors. This chip functions
as the computer's brain. It processes the instructions or operations contained within executable computer
programs. Instead of taking instructions directly off of the hard drive, the processor takes its instructions
from memory. This greatly increases the computer's speed.
 Modern processors are designed by two distinct companies: Intel and Advanced Micro Devices
(AMD). Intel processors are most commonly used in prefabricated computer systems, such as those from
Dell and HP. The company focuses on two different lines of processors: the Pentium and the Celeron.
Pentium processors are the larger microchip style that works on most desktop and some laptops. They can
handle high-demand processing, such as that found in 3D gaming, video editing and other multimedia-
intense applications. Celeron processors are more compact models with the ability to run a basic computer
efficiently and cost-effectively. AMD's line of computer processors can be found in prefabricated models,
however, are most commonplace with home-built systems or specially designed machines. AMD was the
first to build a 64-bit processor, capable of high-end applications use with graphic intensive operations. The
previous industry standard had been 32-bit processing. Some AMD processors offer built-in virus
protection.

FEATURES OF A COMPUTER PROCESSOR

Each processor has a clock speed which is measured in gigahertz (GHz). Also, a processor has a front
side bus which connects it with the system's random access memory (RAM.) CPUs also typically have two
or three levels of cache. Cache is a type of fast memory which serves as a buffer between RAM and the
processor. The processor's socket type determines the motherboard type where it can be installed.

When it comes to processors, size matters. Whether you're buying a new computer or upgrading your old
one, you must get the fastest processor you can afford. This is because the processor will become obsolete
very quickly. Choosing a 3.6 GHz processor over a 2 GHz today can buy you several years of cheap
computing time. Also check the speed of the front side bus (FSB) when purchasing your new computer or
CPU. A front side bus of 800 MHz or greater is essential for fast processing speeds. The processor's cache
is also important. Make sure it has at least 1 MB of last level cache if your computing needs are average.
If you're an extreme gamer or if you run intensive graphics programs, get the processor with the largest
cache that fits your budget. There can be hundreds of dollars' difference between the cheapest processors
and the most expensive ones. However, investing just a little extra cash can get you a much better
processor.

HISTORY OF DEVELOPMENT OF COMPUTER PROCESSOR

The earliest forms of computer processors were designed from vacuum tubes and electrical relays. By the
1950s, these had been replaced by the advent of the transistor. These transistors were built onto printed
circuit boards, copper that is etched onto a non-electrical board, and various components were added.
These computer processors were large and bulky, sometimes taking up whole rooms. During the
construction of the Apollo guidance computer for NASA, scientists were able construct integrated circuits
that allowed large numbers of transistors to be manufactured into a single semiconductor. This was found
to be more reliable that previous models and much more compact. The microprocessor was invented by
Intel in 1970. The 4004 was as fast as its larger cousins, but could be used in much smaller devices. With
the advent of the personal computer, the majority of processor technology uses the microprocessor model.

Engineers and technicians routinely reach a point in processor design in which they face limits in
making the device faster. They have been challenged by size and materials. At one time, designers believed
they could not get passed the 1 gigahertz speed level, that was accomplished by the AMD Athlon in 2000.
The 64-bit barrier was broken by the same company in 2003. Processors have since become duo-core and
quad-core, meaning they are capable of executing nearly twice as much data transfers and flow as with a
single-core. Many motherboards are now coming equipped for two or more processors to work in unison.
The most advanced research being accomplished is that which uses new technologies to expand the speed
and capability of the processor. IBM has designed computer processor technology using lasers, much like
fiber optics. The Georgia Institute of Technology has developed biological computer processors using the
brain cells of leeches. Other scientists are developing ways to pass data along gaseous phenomena.

Other lines of processors are used in older models of computers. Macintosh computers specifically
used its own line for many years between 1984 and 2006. The company switched to Intel processors in all
its new machines after this period. During the early years of Apple Computers, 1984 to 1996, the company
used Motorola branded computer processors to handle its operating systems and data flow. These were
known as the 68000 series and featured processors with speeds between 16 and 33 megahertz. Following
1996, Apple used IBM-designed processors in nearly all of its machines. These ranged in speeds between
66 megahertz to 2.5 gigahertz by 2006.

AUTHENTICATION AND IDENTIFICATION FUNCTION
IDENTIFICATION
-the ability to identify uniquely a user of a system or an application that is running in the system.
AUTHENTICATION
-the ability to prove that a user or application is genuinely who that person or what that application claims to be.

For example, consider a user who logs on to a system by entering a user ID and password. The system uses
the user ID to identify the user. The system authenticates the user at the time of logon by checking that the
supplied password is correct
BIOMETRICS
Verifies an individual’s identity by analyzing a unique personal attribute or behavior
It is the most effective and accurate method for verifying identification. (also the most expensive)

TYPES OF BIOMETRICS
Fingerprint
are based on the ridge endings, bifurcation exhibited by the friction edges and some minutiae of the finger.
(most common)
Palm Scan
are based on the creases, ridges, and grooves that are unique in each individuals palm.
Hand geometry
are based on the shape (length, width) of a person’s hand and fingers.
Hand Topography
based on the different peaks, valleys, overall shape and curvature
of the hand.
Retina Scan
is based on the blood vessel pattern of the retina on the backside of the eyeball.
Iris Scan
is based on the colored portion of the eye that surrounds the pupil. The iris has unique patterns, rifts, colors,
rings, coronas and furrows
Facial Scan
based on the different bone structures, nose ridges, eye widths, forehead sizes and chin shapes of the face.
Voice Print
based on human voice
SIGNATURE DYNAMICS
is based on electrical signals generated due to physical motion of the hand during signing a document.
KEYBOARD DYNAMICS

is based on electrical signals generated while the user types in the keys (passphrase) on the keyboard.

PASSWORD
A password is a protected string of characters that is used to authenticate an individual. (most common
form of system identification and authentication mechanism)

TWO TYPES OF PASSWORD

Cognitive Passwords
-facts or opinion-based information used to verify an individual identity (e.g.: mothers maidens name).
One-Time or Dynamic Passwords
-a token based system used for authentication purposes where the service is used only once. (used in
environments that require a higher level of security)
PASSPHRASE
a sequence of characters that is longer than a password and in some cases, takes the place of a
password during an authentication process.
It is more secure than passwords
CRYPTOGRAPHIC KEYS
Uses private keys and Digital Signatures
Provides a higher level of security than passwords.
MEMORY CARDS
Holds information but cannot process them
More secure than passwords but costly
(Swipe cards, ATM cards
SMART CARDS
Holds information and has the capability to process information and can provide a two factor authentication
(knows and has)
Categories of Smart Cards:
Contact
Contactless

TIMELINE OF COMPUTER PROCESSOR DEVELOPMENT
Retrieved from:

Year Event

1823 Baron Jons Jackob Berzelius discovers silicon (Si), which today is the basic
component of processors.
1903 Nikola Tesla patented electrical logic circuits called "gates" or "switches" in 1903.

1947 John Bardeen, Walter Brattain, and William Shockley invent the first transistor at the
Bell Laboratories on December 23, 1947.

1948 John Bardeen, Walter Brattain, and William Shockley patent the first transistor in
1948.
1956 John Bardeen, Walter Brattain, and William Shockley were awarded the Nobel Prize
in physics for their work on the transistor.

1958 The first working integrated circuit was developed by Robert Noyce of Fairchild
Semiconductor and Jack Kilby of Texas Instruments. The first IC was demonstrated
on September 12, 1958. (Geoffrey Dummer is credited as being the first person to
conceptualize and build a protoType of the integrated circuit.)

1960 IBM developed the first automatic mass-production facility for transistors in New
York in 1960.
1968 Intel Corporation was founded by Robert Noyce and Gordon Moore in 1968.
1969 AMD (Advanced Micro Devices) was founded on May 1, 1969.

1971 Intel with the help of Ted Hoff introduced the first microprocessor, the Intel 4004 on
November 15, 1971. The 4004 had 2,300 transistors, performed 60,000 OPS
(operations per second), addressed 640 bytes of memory, and cost $200.00.

1972 Intel introduced the 8008 processor on April 1, 1972.

1974 Intel's improved microprocessor chip was introduced on
April 1, 1974; the 8080 became a standard in the computer
industry.
1976 Intel introduced the 8085 processor in March 1976.
1976 The Intel 8086 was introduced on June 8, 1976.

1979 The Intel 8088 was released on June 1, 1979.

1979 The Motorola 68000, a 16/32-bit processor was released and was later chosen as
the processor for the Apple Macintosh and Amiga computers.

1982 The Intel 80286 was introduced on February 1, 1982.

1985 Intel introduced the first 80386 in October 1985.

1987 The SPARC processor was first introduced by Sun.
1988 Intel 80386SX was introduced in 1988.
1989 Cyrix released their first coprocessors, the FasMath 83D87 and 83S87, in 1989. These
were x87 compatible and designed for 386 computers. The FasMath coprocessors
were up to 50% faster than the Intel 80387 processor.
1991 AMD introduced the AM386 microprocessor family in March 1991.

1991 Intel introduced the Intel 486SX chip in April in efforts to help bring a lower-cost
processor to the PC market selling for $258.00.

1992 Intel released the 486DX2 chip on March 2, 1992, with a clock doubling ability that
generates higher operating speeds.

1993 Intel released the Pentium processor on March 22, 1993. The processor was a 60 MHz
processor, incorporates 3.1 million transistors and sells for $878.00.
1994 Intel released the second generation of Intel Pentium processors on March 7, 1994.

1995 Cyrix released the Cx5x86 processor in 1995, in an attempt to compete with the Intel
Pentium processors.
1995 Intel introduced the Intel Pentium Pro in November 1995.

1996 Cyrix released their MediaGX processor in 1996. It combined a processor with sound
and video processing on one chip.
1996 Intel announced the availability of the Pentium 150 MHz with 60 MHz bus and 166 MHz
with 66 MHz bus on January 4, 1996.
1996 AMD introduced the K5 processor on March 27, 1996, with speeds of 75 MHz to 133
MHz and bus speeds of 50 MHz, 60 MHz, or 66 MHz The K5 was the first processor
developed completely in-house by AMD.

1997 AMD released their K6 processor line in April 1997, with speeds of 166 MHz to 300
MHz and a 66 MHz bus speed.
1997 Intel Pentium II was introduced on May 7, 1997.
1998 AMD introduced their new K6-2 processor line on May 28, 1998, with speeds of 266
MHz to 550 MHz and bus speeds of 66 MHz to 100 MHz The K6-2 processor was an
enhanced version of AMD's K6 processor.
1998 Intel released the first Xeon processor, the Pentium II Xeon 400 (512 K or 1 M cache,
400 MHz, 100 MHz FSB) in June 1998.
1999 Intel released the Celeron 366 MHz and 400 MHz processors on January 4, 1999.
1999 AMD released its K6-III processors on February 22, 1999, with speeds of 400 MHz or
450 MHz and bus speeds of 66 MHz to 100 MHz It also featured an on-die L2 cache.
1999 The Intel Pentium III 500 MHz was released on February 26, 1999.

1999 The Intel Pentium III 550 MHz was released on May 17, 1999.
1999 AMD introduced the Athlon processor series on June 23, 1999. The Athlon would be
produced for the next six years in speeds ranging from 500 MHz up to 2.33 GHz.
1999 The Intel Pentium III 600 MHz was released on August 2, 1999.
1999 The Intel Pentium III 533B and 600B MHz was released on September 27, 1999.
1999 The Intel Pentium III Coppermine series was first introduced on October 25, 1999.

2000 On January 5, 2000, AMD released the 800 MHz Athlon processor.
2000 Intel released the Celeron 533 MHz with a 66 MHz bus processor on January 4, 2000.

2000 AMD first released the Duron processor on June 19, 2000, with speeds of 600 MHz to
1.8 GHz and bus speeds of 200 MHz to 266 MHz The Duron was built on the same K7
architecture as the Athlon processor.
2000 Intel announces on August 28th that it will recall its 1.3 GHz Pentium III processors
due to a glitch. Users with these processors should contact their vendors for
additional information about the recall.
2001 On January 3, 2001, Intel released the 800 MHz Celeron processor with a 100 MHz bus.
2001 On January 3, 2001, Intel released the 1.3 GHz Pentium 4 processor.
2001 AMD announced a new branding scheme on October 9, 2001. Instead of identifying
processors by their clock speed, the AMD Athlon XP processors will bear monikers of
1500+, 1600+, 1700+, 1800+, 1900+, 2000+, etc. Each higher model number will
represent a higher clock speed.
2002 Intel released the Celeron 1.3 GHz with a 100 MHz bus and 256 kB of level 2 cache.

2003 Intel Pentium M was introduced in March 2003.
2003 AMD released the first single-core Opteron processors, with speeds of 1.4 GHz to 2.4
GHz and 1024 KB L2 cache, on April 22, 2003.
2003 AMD released the first Athlon 64 processor, the 3200+ model, and the first Athlon 64
FX processor, the FX-51 model, on September 23, 2003.

2004 AMD released the first Sempron processor on July 28, 2004, with a 1.5 GHz to 2.0 GHz
clock speed and 166 MHz bus speed.
2005 AMD released their first dual-core processor, the Athlon 64 X2 3800+ (2.0 GHz, 512
KB L2 cache per core), on April 21, 2005.
2006 AMD released their new Athlon 64 FX-60 processor, featuring 2x 1024 KB L2 cache,
on January 9, 2006.
2006 Intel released the Core 2 Duo processor E6320 (4 M cache, 1.86 GHz, 1066 MHz FSB)
on April 22, 2006.
2006 Intel introduced the Intel Core 2 Duo processors with the Core 2 Duo processor
E6300 (2 M cache, 1.86 GHz, 1066 MHz FSB) on July 27, 2006.
2006 Intel introduced the Intel Core 2 Duo processor for the laptop computer with the Core
2 Duo processor T5500, as well as other Core 2 Duo T series processors, in August
2006.
2007 Intel released the Core 2 Quad processor Q6600 (8 M cache, 2.40 GHz, 1066 MHz FSB)
in January 2007.
2007 Intel released the Core 2 Duo processor E4300 (2 M cache, 1.80 GHz, 800 MHz FSB)
on January 21, 2007.
2007 Intel released the Core 2 Quad processor Q6700 (8 M cache, 2.67 GHz, 1066 MHz FSB)
in April 2007.
2007 Intel released the Core 2 Duo processor E4400 (2 M cache, 2.00 GHz, 800 MHz FSB)
on April 22, 2007.
2007 AMD renamed the Athlon 64 X2 processor line to Athlon X2 and released the first in
that line, the Brisbane series (1.9 to 2.6 GHz, 512 KB L2 cache) on June 1, 2007.
2007 Intel released the Core 2 Duo processor E4500 (2 M cache, 2.20 GHz, 800 MHz FSB)
on July 22, 2007.
2007 Intel released the Core 2 Duo processor E4600 (2 M cache, 2.40 GHz, 800 MHz FSB)
on October 21, 2007.
2007 AMD released the first Phenom X4 processors (2 M cache, 1.8 GHz to 2.6 GHz, 1066
MHz FSB) on November 19, 2007.
2008 Intel released the Core 2 Quad processor Q9300 and the Core 2 Quad processor
Q9450 in March 2008.
2008 Intel released the Core 2 Duo processor E4700 (2 M cache, 2.60 GHz, 800 MHz FSB)
on March 2, 2008.
2008 AMD released the first Phenom X3 processors (2 M cache, 2.1 GHz to 2.5 GHz, 1066
MHz FSB) on March 27, 2008.
2008 Intel released the first of the Intel Atom series of processors, the Z5xx series, in April
2008. They are single core processors with a 200 MHz GPU.
2008 Intel released the Core 2 Duo processor E7200 (3 M cache, 2.53 GHz, 1066 MHz FSB)
on April 20, 2008.
2008 Intel released the Core 2 Duo processor E7300 (3 M cache, 2.66 GHz, 1066 MHz FSB)
on August 10, 2008.
2008 Intel released several Core 2 Quad processors in August 2008: the Q8200, the Q9400,
and the Q9650.
2008 Intel released the Core 2 Duo processor E7400 (3 M cache, 2.80 GHz, 1066 MHz FSB)
on October 19, 2008.
2008 Intel released the first Core i7 desktop processors in November 2008: the i7-920, the
i7-940, and the i7965 Extreme Edition.
2009 AMD released the first Phenom II X4 (quad-core) processors (6 M cache, 2.5 to 3.7
GHz, 1066 MHz or 1333 MHz FSB) on January 8, 2009.
2009 AMD released the first Athlon Neo processor, the MV-40 model, (1.6 GHz and 512 KB
L2 cache) on January 8, 2009.
2009 Intel released the Core 2 Duo processor E7500 (3 M cache, 2.93 GHz, 1066 MHz FSB)
on January 18, 2009.
2009 AMD released the first Phenom II X3 (triple core) processors (6 M cache, 2.5 to 3.0
GHz, 1066 MHz or 1333 MHz FSB) on February 9, 2009.
2009 Intel released the Core 2 Quad processor Q8400 (4 M cache, 2.67 GHz, 1333 MHz FSB)
in April 2009.
2009 Intel released the Core 2 Duo processor E7600 (3 M cache, 3.06 GHz, 1066 MHz FSB)
on May 31, 2009.
2009 AMD released the first Athlon II X2 (dual-core) processors (1024KB L2 cache, 1.6 to
3.5 GHz, 1066 MHz or 1333 MHz FSB) in June 2009.

2009 AMD released the first Phenom II X2 (dual-core) processors (6 M cache, 3.0 to 3.5
GHz, 1066 MHz or 1333 MHz FSB) on June 1, 2009.

2009 AMD released the first Athlon II X4 (quad-core) processors (512 KB L2 cache, 2.2 to
3.1 GHz, 1066 MHz or 1333 MHz FSB) in September 2009.

2009 Intel released the first Core i7 mobile processor, the i7-720QM, in September 2009. It
uses the Socket G1 socket type, runs at 1.6 GHZ, and features 6 MB L3 cache.

2009 Intel released the first Core i5 desktop processor with four cores, the i5-750 (8 M
cache, 2.67 GHz, 1333 MHz FSB), on September 8, 2009.

2009 AMD released the first Athlon II X3 (triple core) processors in October 2009.

2010 Intel released the Core 2 Quad processor Q9500 (6 M cache, 2.83 GHz, 1333 MHz FSB)
in January 2010.
2010 Intel released the first Core i5 mobile processors, the i5-430M and the i5-520E in
January 2010.
2010 Intel released the first Core i5 desktop processor over 3.0 GHz, the i5-650 in January
2010.
2010 Intel released the first Core i3 desktop processors, the i3-530, and i3-540 on January
7, 2010.
 2010 Intel released the first Core i3 mobile processors, the i3-330M (3 M cache, 2.13 GHz,
1066 MHz FSB) and the i3-350M, on January 7, 2010.

2010 AMD released the first Phenom II X6 (hex/six core) processors on April 27, 2010.

2010 Intel released the first Core i7 desktop processor with six cores, the i3-970, in July
2010. It runs at 3.2 GHz and features 12 MB L3 cache.

2011 Intel released seven new Core i5 processors with four cores, the i5-2xxx series in
January 2011.
2017 Intel released the first desktop processor with 16 cores, the Core i9-7960X, in
September 2017. It runs at 2.8 GHZ and features 22 MB L3 cache.
2017 Intel released the first desktop processor with 18 cores, the Core i9-7980X, in
September 2017. It runs at 2.6 GHZ and features 24.75 MB L3 cache.
2018 Intel released the first Core i9 mobile processor, the i9-8950HK, in April 2018. It uses
the BGA 1440 socket, runs at 2.9 GHZ, has six cores, and features 12 MB L3 cache.

Activity 2: Identification
Directions: Identify the following. Write your answer on the space provided. Be ready for the submission

1. Refers to the industry technology who invented the graphical user interface.

2. Refers to the transfer rate of a standard USB 2.0 device.

3. The hyper transport have all but replaced this in current hardware, but what used to be the single most
important factor in overall system speed?

4. When was the first commercial microprocessor introduced?

5. It refers to the width of the smallest wire on a computer chip is typically measured in

6. The external system bus architecture is created using from _________ architecture

7.The accumulator based microprocessor example are _________________

8. Computer has a built-in system clock that emits millions of regularly spaced electric pulses per
__________ called clock cycles.

9. A circuitry that processes that responds to and processes the basic instructions that are
required to drive a computer system is _____________.

10. The CPU controls the transfer of data between ___________and other devices.

II. Answer the question: What can you say on the development of processor in terms of sizes, speed,
process and durability factor
 LESSON 3: COMPUTER COMPONENTS
LEARNING OBJECTIVES
Know what a Motherboard is
Know the different parts and ports of a Motherboard
Know the basic working principle of Motherboard.

PARTS OF A COMPUTER

1. INPUT DEVICES - Data and instructions must enter the computer system before any computation
can be performed on the supplied data. The input unit that links the external environment with the
computer system performs this task. Data and instructions enter input units in forms that depend
upon the particular device used. For example, data is entered from a keyboard in a manner similar
to typing, and this differs from the way in which data is entered through a mouse, which is another
type of input device. However, regardless of the form in which they receive their inputs, all input
devices must provide a computer with data that are transformed into the binary codes that the
primary memory of the computer is designed to accept. This transformation is accomplished by
units that called input interfaces. Input interfaces are designed to match the unique physical or
electrical characteristics of input devices to the requirements of the computer system.
Keyboard is the most common and very popular input device
which helps to input data to the computer. The layout of the keyboard is like
that of traditional typewriter, although there are some additional keys provided
for performing additional functions
Mouse is the most popular pointing device. It is a very famous
cursor-control device having a small palm size box with a round ball at its base,
which senses the movement of the mouse and sends corresponding
signals to the CPU when the mouse buttons are pressed. Generally, it has two
buttons called the left and the right button and a wheel is present between the
buttons. A mouse can be used to control the position of the cursor on the
screen, but it cannot be used to enter text into the compute
Microphone is an input device to input sound that is then stored in
a digital form. The microphone is used for various applications such as adding
sound to a multimedia presentation or for mixing music.
Joystick is also a pointing device, which is used to move the cursor
position on a monitor screen. It is a stick having a spherical ball at its both
lower and upper ends. The lower spherical ball moves in a socket. The joystick
can be moved in all four directions. The function of the joystick is similar to that
of a mouse. It is mainly used in Computer Aided Designing (CAD) and playing
computer games.
Scanner is an input device, which works more like a photocopy machine. It is
used when some information is available on paper and it is to be transferred to
the hard disk of the computer for further manipulation. Scanner captures images
from the source which are then converted into a digital form that can be stored on
the disk. These images can be edited before they are printed.

2. OUTPUT DEVICES - The job of an output unit is just the reverse of that of an input unit. It supplied
information and results of computation to the outside world. Thus it links the computer with the
 external environment. As computers work with binary code, the results produced are also in the
binary form. Hence, before supplying the results to the outside world, it must be converted to human
acceptable (readable) form. This task is accomplished by units called output interfaces.
Monitors, commonly called as Visual Display Unit
(VDU), are the main output device of a computer. It forms images from tiny
dots, called pixels that are arranged in a rectangular form. The sharpness of
the image depends upon the number of pixels.
Printers are another common output device found in
homes in offices. In computing terms, they take electronic data stored on a
computer and generates a hard copy of it. Usually that means printing images
and text onto paper. There are numerous different types of printer, with Inkjet
and laser printers being two of the most common. Modern printers usually
connect to a computer with a USB cable or via Wi-Fi.
Computer speakers are hardware devices that
transform the signal from the computer's sound card into audio. Speakers are essential if you want a
louder sound, surround sound, fuller bass, or just a better quality of audio. External computer speakers
began to appear in stores in the early 1990's when computer gaming, digital music, and other forms of
media became popular. Some computer speakers are wireless nowadays, connecting to the computer
via Bluetooth.
3. STORAGE UNIT - The data and instructions that are entered into the computer system through
input units have to be stored inside the computer before the actual processing starts. Similarly, the
results produced by the computer after processing must also be kept somewhere inside the
computer system before being passed on to the output units. Moreover, the intermediate results
produced by the computer must also be preserved for ongoing processing. The Storage Unit or
the primary / main storage of a computer system is designed to do all these things. It provides
space for storing data and instructions, space for intermediate results and also space for the final
results.
Cache memory is a very high speed semiconductor memory which can speed up the CPU.
It acts as a buffer between the CPU and the main memory. It is used to hold those parts of
data and program which are most frequently used by the CPU. The parts of data and
programs are transferred from the disk to cache memory by the operating system, from
where the CPU can access them.

Primary memory holds only those data and instructions on which the computer is currently
working. It has a limited capacity and data is lost when power is switched off. It is generally
made up of semiconductor device. These memories are not as fast as registers. The data
and instruction required to be processed resides in the main memory. It is divided into two
subcategories RAM and ROM.
This type of memory is also known as external memory or non-volatile. It is slower than the
main memory. These are used for storing data/information permanently. CPU directly does
not access these memories, instead they are accessed via input-output routines. The
contents of secondary memories are first transferred to the main memory, and then the
CPU can access it. For example, disk, CD-ROM, DVD, etc.
4. CENTRAL PROCESSING UNIT - The main unit inside the computer is the CPU.
This unit is responsible for all events inside the computer. It controls all internal and external devices,
performs “Arithmetic and Logical operations”. The operations a Microprocessor performs are called
“instruction set” of this processor. The instruction set is ―hard wired‖ in the CPU and determines the
machine language for the CPU. The more complicated the instruction set is, the slower the CPU works.
Processors differed from one another by the instruction set. If the same program can run on two different
computer brands they are said to be compatible. Programs written for IBM compatible computers will not
run on Apple computers because these two architectures are not compatible.
The control Unit and the Arithmetic and Logic unit of a computer system are jointly known as the
Central Processing Unit (CPU). The CPU is the brain of any computer system. In a human body, all major
decisions are taken by the brain and the other parts of the body function as directed by the brain. Similarly,
in a computer system, all major calculations and comparisons are made inside the CPU and the CPU is
also responsible for activating and controlling the operations of other units of a computer system

Activity 3: TEST YOUR COMPREHENSION
Enumeration:

1. Example of Input Devices

2. Example of output devices

________________

3. 2 basic types of memory storage unit

_____

4. Mention briefly the steps involved in the execution of a program CPU

______
 LESSON 4: COMPUTER MOTHERBOARD
LEARNING OBJECTIVES
Know what a Motherboard is
Know the different parts and ports of a Motherboard
Know the basic working principle of Motherboard.

THE MOTHERBOARD

A computer has many components, each with their own roles and functions. The role of the
motherboard is to allow all these components to communicate with each other. Considering the fact that all
the other components are installed on the motherboard or connected to it, it is safe to say that the
motherboard is the central piece of a PC, the component that brings it all together.

DIFFERENT TYPES OF MOTHERBOARD

1. AT MOTHERBOARD - The oldest of the main boards, these motherboards were
used in earlier 286/386 or 486 computers. The AT means the board consists of advanced
technology(AT) power connectors. There are two power connectors of 6 pin each mounted on
the AT motherboards. The AT motherboards were available in the early 80‘s.

2. ATX MOTHERBOARDS - (Motherboard for P1/P2 processors)
The ATX motherboards started in 90‘s and are still available. The
ATX connector on the motherboard consists of a single connector. These boards are
used for P2/P3 or P/4 processors. COMPONENTS OF A MOTHERBOARD

1. EXPANSION SLOTS - Expansions have the role of letting you install additional components to enhance
or expand the functionality of your PC. You can install a TV tuner, a video capture card, a better
soundcard, etc. – you get the idea. These ports are located under the video card slot, and come in the
form of PCI slots (on older motherboards) or a scaled-down version of PCI-Express slots (on newer
motherboards). Some motherboards come with both types of expansion slots. The number of slots is
usually dependent on the format of the motherboard – larger motherboards (full ATX) have more, while
smaller formats (micro-ATX) have fewer, if any.

ISA slots. These were the oldest expansion slots in the history of motherboards. They were
found in AT boards and are identified by black color. Conventional display cards or sound cards were
installed in these slots. The full form of ISA is Industry Standard Architecture and is a 16- bit bus.
PCI Slots. The full form of PCI is Peripheral Component Interconnect. The PCI slot is one
of the important motherboard components today and is vastly used to install add-on cards
on the motherboard. The PCI supports 64-bit high-speed bus.
PCI express. Also known as PCIe, these are the latest and the fastest component of the
motherboard to support add-on cards. It supports full duplex serial bus.

AGP slot. Accelerated graphics port (AGP) is specifically used to install a latest graphics
card. AGP runs on a 32-bit bus and both PCIe and AGP can be used to install high-end
gaming display cards.
2. RAM (MEMORY) SLOTS - Located in the upper-right part of the motherboard, the memory slots are
used to house the computer ‘s memory modules. The number of slots can vary, depending on the
motherboard, from 2, in low-end motherboards, all the way up to 8 memory slots, on high-end and
gaming motherboards.

SIMM slots. The full form is a single in-line memory module. These slots were found in
older motherboards, up to 486-boards. The SIMM supports 32-bit bus.
DIMM slots. The full form of DIMM is a Double inline memory module. These are the latest
RAM slots which run on a faster 64-bit bus. The DIMM used on Laptop boards are called
SO-DIMM.

3. CENTRAL PROCESSING UNIT (CPU) SOCKET - Another vital motherboard component is the CPU
socket which is used to install the processor on the
motherboard. Some important sockets are explained below.
Socket7. It is a 321 pin socket that supported older processors like Intel Pentium 1/2/MMX,
AMD k5/K6, and Cyrix M2.
Socket370. It is a 370 pin socket that supports Celeron processors and Pentium-3
processors.
Socket 775. It is a 775-pin socket that supports Inter dual core, C2D, P-4 and Xeon
processors.
Socket 1156. Found on latest types of motherboards, it is an 1156-pin socket that supports
the latest Intel i-3, i-5 and i-7 processors.
Socket 1366. The socket is of 1366 pins and supports latest i-7 900 processors.
4. BASIC INPUT/OUTPUT SYSTEM (BIOS) - The full form of BIOS is Basic Input Output System. It is a
motherboard component in the form of an Integrated chip. This chip contains all the information and
settings of the motherboard which you can modify by entering the BIOS mode from your computer
5. COMPLEMENTARY METAL-OXIDE SEMICONDUCTOR (CMOS) BATTERY -
The battery is a 3.0-Volt lithium type cell. The cell is responsible for storing the information in BIOS.
6. POWER CONNECTORS - No computer component can operate without power, and a motherboard
is no exception. The power connector, commonly a 20 or 24-pin connector, can be situated either near the
right edge of the motherboard, or somewhere close to the processor socket on older motherboards. This is
where the power supply ‘s main connector gets attached, providing power to the motherboard and all the
other components.

Newer motherboards have an additional 4-pin or 8-pin connector near the processor, used to supply additional
power directly to the processor.

7. IDE AND SATA PORTS - IDE and SATA ports are used to provide connectivity for the storage
devices and optical drives. The IDE interface is somewhat outdated, so you shouldn’t ‘t be surprised if you
see a lot of new motherboards coming without this type of port. It was replaced by the smaller and much
faster SATA interface, which currently reached its 3rd revision, being able to achieve maximum speeds of
up to 600 MB/s, as opposed to the IDE interface, which can reach a maximum of 133 MB/s.

8. PROCESSOR SOCKET - The processor socket is the central piece of a motherboard, usually
being located near the center of the motherboard. It’s also the central piece because it holds the processor
– the brain of your computer.

9. NORTHBRIDGE AND SOUTHBRIDGE - If you have a look at your motherboard, chances are you
‘ll see a square metal component somewhere in the lower-right part of the board. This metal component is
actually a heatsink, and its role is to provide thermal protection for the Northbridge – one of the most
important components of a motherboard. The northbridge is responsible for coordinating the data flow
between the memory, the video card and the processor. A secondary chip, known as Southbridge, has a
similar function, coordinating the data flow between the processor and peripherals such as sound cards or
network cards.

10. CABINET CONNECTIONS - The cabinet in which the motherboard is installed has many buttons
that connect to the motherboard. Some of the common connectors are Power Switch, Reset Switch, Front
USB, Front Audio, Power indicator (LED) and HDD LED.

11. INPUT/OUTPUT INTERFACE CONNECTORS - The input–output interface
connects the computer to the outside world. It decodes the address and identifies the unique computer
peripheral with which a data transfer operation is to be executed. The interface also has to interpret the
command on the control bus so that the timing of data transfer is correct. One further very important
function of the input–output interface is to provide a physical electronic highway for the flow of data
between the computer data bus and the external peripheral

Activity 4: Specs Design Challenge.
Prepare a matrix design (table format) of complete computer system unit specification is up to you what kind of
processor that you want to put on the table.

LESSON 5: E-WASTE

LEARNING OBJECTIVES
Learn about Technological Disposal
Know what are E-Waste
Know the impacts of E-Waste to the Society

What is E-waste?
Electronic waste, also called e-waste, various forms of electric and electronic equipment that have ceased to be
of value to their users or no longer satisfy their original purpose.
Electronic waste (e-waste) products have exhausted their utility value through either redundancy,
replacement, or breakage and include both ―white goods‖ such as refrigerators, washing machines, and
microwaves and ―brown goods‖ such as televisions, radios, computers, and cell phones. Given that the
information and technology revolution has exponentially increased the use of new electronic equipment, it
has also produced growing volumes of obsolete products; e-waste is one of the fastest-growing waste
streams. Although e-waste contains complex combinations of highly toxic substances that pose a danger
to health and the environment, many of the products also contain recoverable precious materials, making
it a different kind of waste compared with traditional municipal waste.

Electronic system Waste product

Globally, e-waste constitutes more than 5 percent of all municipal solid waste and is increasing with the
rise of sales of electronic products in developing countries. The majority of the world ‘s e-waste is recycled
in developing countries, where informal and hazardous setups for the extraction and sale of metals are
common. Recycling companies in developed countries face strict environmental regulatory regimes and an
increasing cost of waste disposal and thus may find exportation to small traders in developing countries
more profitable than recycling in their own countries. There is also significant illegal transboundary
movement of e-waste in the form of donations and charity from rich industrialized nations to developing
countries. E-waste profiteers can harvest substantial profits owing to lax environmental laws, corrupt
officials, and poorly paid workers, and there is an urgent need to develop policies and strategies to dispose
of and recycle e-waste safely in order to achieve a sustainable future.

Impacts On Human Health

The complex composition and improper handling of e-waste adversely affect human health. A growing body
of epidemiological and clinical evidence has led to increased concern about the potential threat of e-waste
to human health, especially in developing countries such as India and China. The primitive methods used
by unregulated backyard operators to reclaim, reprocess, and recycle e-waste materials expose the
workers to a number of toxic substances. Processes such as dismantling components, wet chemical
processing, and incineration are used and result in direct exposure and inhalation of harmful chemicals.
Safety equipment such as gloves, face masks, and ventilation fans are virtually unknown, and workers
often have little idea of what they are handling.

For instance, in terms of health hazards, open burning of printed wiring boards increases the concentration
of dioxins in the surrounding areas. These toxins cause an increased risk of cancer if inhaled by workers
and residents. Toxic metals and poison can also enter the bloodstream during the manual extraction and
collection of tiny quantities of precious metals, and workers are continuously exposed to poisonous
chemicals and fumes of highly concentrated acids. Recovering resalable copper by burning insulated wires
causes neurological disorders, and acute exposure to cadmium, found in semiconductors and chip
resistors, can damage the kidneys and liver and cause bone loss. Long-term exposure to lead on printed
circuit boards and computer and television screens can damage the central and peripheral nervous system
and kidneys, and children are more susceptible to these harmful effects.

Environmental Impacts

Although electronics constitute an indispensable part of everyday life, their hazardous effects on the
environment cannot be overlooked or underestimated. The interface between electrical and electronic
equipment and the environment takes place during the manufacturing, reprocessing, and disposal of these
products. The emission of fumes, gases, and particulate matter into the air, the discharge of liquid waste
into water and drainage systems, and the disposal of hazardous wastes contribute to environmental
degradation. In addition to tighter regulation of e-waste recycling and disposal, there is a need for policies
that extend the responsibility of all stakeholders, particularly the producer.

Activity 5: Critical Thinking Analysis
Answer the question at short bond paper printed output 2 slides of power point/captured picture for non-
internet connection. The third page will be your explanation using msword.

Develop the best idea to present the E-waste

Question: Why is it important to recycle e-waste
 LESSON 6: SOFTWARE CONCEPTS
LEARNING OBJECTIVES

To understand fundamental software concepts
To understand and identify different kinds of software
To know the importance of debugging in computer systems and software development
Understand the usage of CAPTCHA
Identify and understand the various computer components
To understand and identify security threats and the importance of security

Software

Software is a set of instructions, data or programs used to operate computers and execute
specific tasks. Opposite of hardware, which describes the physical aspects of a computer, software
is a generic term used to refer to applications, scripts and programs that run on a device. Software
can be thought of as the variable part of a computer and hardware the invariable part.

Software is often divided into application software, or user downloaded programs that fulfill
a want or need, and system software, which includes operating systems and any program that
supports application software. The term middleware is sometimes used to describe programming
that mediates between application and system software or between two different kinds of
application software. For example, middleware could be used to send a remote work request from
an application in a computer that has one kind of operating system to an application in a computer
with a different operating system.

An additional category of software is the utility, which is a small, useful program with limited
capability. Some utilities come with operating systems. Like applications, utilities tend to be
separately installable and capable of being used independently from the rest of the operating
system.

Similarly, applets are small applications that sometimes come with the operating system
as accessories. They can also be created independently using the Java or other programming
languages.

Software can be purchased or acquired in the following ways:

Shareware- usually distributed on a free or trial basis with the intention of sale when the
period is over.

Lite ware- a type of shareware with some capabilities disabled until the full version is
purchased.

Freeware- can be downloaded for free but with copyright restrictions.

Public domain software- can be downloaded for free without restrictions.

Open source- a type of software where the source code is furnished and users agree not
to limit the distribution of improvements.

Today, much of the purchased software, shareware and freeware is directly downloaded
over the Internet. In these cases, software can be found on specific vendor websites or application
 service providers. However, software can also be packaged on CD-ROMs or diskettes and sold
physically to a consumer.

Some general kinds of application software include:

Productivity software, which includes tools such as word processors and spreadsheets.

Presentation software, also known as slideware.

Graphics software.

CAD/CAM.

Vertical market or industry-specific software, for example, banking, insurance and retail
applications.

Examples and types of software

Below is a list of the different kinds of software a computer may have installed with examples of
related programs. Click any of the links below for additional information.

It should be noted that although application software is thought of as a program, it can be anything
that runs on a computer. The table below also includes a program column to clarify any software
that is not a program.

A specialized type of software that allows hardware to run is firmware. This is a type of
programming that is embedded onto a special area of the hardware's nonvolatile memory, such as
a microprocessor or read-only memory, on a one-time or infrequent basis so that thereafter it seems
to be part of the hardware.

Software can be purchased at a retail computer store or online and come in a box containing all
the disks (floppy diskette, CD, DVD, or Blu-ray), manuals, warranty, and other documentation.

Software can also be downloaded to a computer over the Internet. Once downloaded, setup files
are run to start the installation process on your computer.

Free software

There are also a lot of free software programs available that are separated into different categories.

Shareware or trial software is software that gives you a few days to try the software before you
have to buy the program. After the trial time expires, you'll be asked to enter a code or register
the product before you can continue to use it.

Freeware is completely free software that never requires payment, as long as it is not modified.

Open source software is similar to freeware. Not only is the program given away for free, but
the source code used to make the program is as well, allowing anyone to modify the program
or view how it was created.
How do you use computer software?

Once the software is installed on the computer hard drive, the program can be used anytime by
finding the program on the computer. On a Windows computer, a program icon is added to the Start
menu or Start screen, depending on your version of Windows.

How to maintain software

After the software is installed on your computer, it may need to be updated to fix any found
errors. Updating a program can be done using software patches. Once updates are installed, any
problems may that may have been experienced in the program will no longer occur.

How is software created and how does it work?

A computer programmer (or several computer programmers) write the instructions using a
programming language, defining how the software should operate on structured data. The program
then be interpreted, or compiled into machine code.

When I save a document, is that file also considered software?

When you create or edit a file using your software — a Microsoft Word document, for instance, or
a Photoshop image — that file is considered a "resource" or "asset" used by the software. However,
the file itself is not considered "software" even though it is an essential part of what your software
is doing

What was the first piece of computer software?

The first software program that was held in electronic memory was written by Tom Kilburn. The
program calculated the highest factor of the integer 218 = 262,144, and was successfully executed
on June 21, 1948, at the University of Manchester, England. The computer that held that program
was called the SSEM (Small Scale Experimental Machine), otherwise known as the "Manchester
Baby." This event is widely celebrated as the birth of software.

SYSTEM SOFTWARE

[21-24] This type of software allows the direct interaction between the user and the hardware
components of the computer system. Humans compared to the machine speaks and understand
different language, there must be an interface that will allow the end user to interact with the
computer system. System Software is also called as the main or alpha software of a computer
system because it handles the major operations of the running hardware. This System Software is
further divided into four major types:

1. The Operating System (OS) – It is a major program that is responsible in the governance and
maintenance of the inner-cooperation of components of the computer system. eg., Microsoft
Windows, Linux, Mac OS etc.
2. The Language Processor – The hardware components of a computer system’s language are
not understandable by humans. These are the three languages involved in human-machine
interaction:

o Machine-level Language: the machines can only understand the digital signals or the
binary codes of 0’s and 1’s. This language is a machine dependent language. o Assembly-
level Language: this language is also referred to as the Low-level Language (LLL), That
forms a correspondence between machine level instruction and general assembly level
statement. Mnemonics are used to represent each low-level machine instructions or
operation codes (op-codes). e.g., ADD for adding two entities, HALT for stopping a process
etc. It is also a machine dependent and it varies among processor to processor.
o High-level Language: this is the language understandable by humans, this is used to
program and code. It is to read and understand. Examples of this language is Java, C,
C++, Python etc.

Machine Level Language is very complex, therefore the users choose the High-level Language
more often, because of its convenience in terms of coding. The codes will be converted to machine
language so the computer system will understand it. This conversion process is performed by the
Language Processor which is made up of three components: o Assembler: Language processor
that converts assembly language into a machine language. [Assembler language Machine
Language]
o Compiler: This language processor converts High-Level Language into a machine-level
Language in one go and the execution is fast. It checks the error of the whole program;
thus the error detection is difficult. Languages like C, C++ and Scala use compiler. o
Interpreter: This language processor also converts High-Level Language into a machine-
level Language line-by-line thus the execution tie is longer. But, the error detection is easier
because it returns the line where the error occurred. Programming languages such as
Python, Ruby and Java uses interpreter.
3. The Device Drivers – this acts an interface between various Input-Output device and the users
or the operating systems. This includes Printers, External web Cameras come with driver disk
for the installation to the system before it can be used in the system.
4. The BIOS- stands for Basic Input Output System, it a small firmware, that controls the peripheral
or the input-output device attached to the system, this

is also responsible for the starting the OS or initiating booting process or the POST (Power On
Self-Test)
Application Software

These are the basic software used to run to accomplish a particular action and task. These are the
dedicated software, dedicated to performing simple and single tasks. For e.g., a single software
cannot serve to both the reservation system and banking system. These are divided into two types:

1. The General Purpose Application Software: These are the types of application software
that comes in-built and ready to use, manufactures by some company or someone. For e.g.,
Microsoft Excel – Used to prepare excel sheets.
VLC Media Player – Used to play audio/video files.
Adobe Photoshop – Used for designing and animation and many more.
2. The Specific Purpose Application Software: These are the type of software that is
customizable and mostly used in real-time or business environment. For e.g.,
Ticket Reservation System
 Healthcare Management System
Hotel Management System
Payroll Management System
WHAT IS A WORD PROCESSOR?

Sometimes abbreviated as WP, a word processor is a software program capable of creating,
storing, and printing typed documents. Today, the word processor is one of the most frequently
used software programs on a computer, with Microsoft Word being the most popular word
processor.

Word processors can be used to create multiple types of files, including text files (.txt), rich text
files (.rtf), HTML files (.htm &.html), and Word files (.doc &.docx). Some word processors can also
be used to create XML files (.xml).

OVERVIEW OF A WORD PROCESSOR

In a word processor, you are presented with a blank white sheet as shown below. The text is
added to the document area and after it has been inserted formatted or adjusted to your preference.
Below is an example of a blank Microsoft Word window with areas of the window highlighted.

FEATURE OF A WORD PROCESSOR

A word processor offers dozens of additional features that can give your document or other text a
more professional appearance. Below is a listing of some of the most popular features of a word
processor.

Résumé - Create or maintain your résumé.

WHAT IS A PRESENTATION TOOL?

A presentation tool is a software package used to display information in the form of a slide
show. It has three major functions: an editor that allows text to be inserted and formatted, a method
for inserting and manipulating graphic images, and a slide-show system to display the content.
Presentation software can be viewed as enabling a functionally-specific category of electronic
media, with its own distinct culture and practices as compared to traditional presentation media.

OVERVIEW OF A PRESENTATION TOOL

In a presentation tool, you are presented with a blank white sheet as shown below. The text is
added to the document area and after it has been inserted formatted or adjusted to your preference.
Below is an example of a blank Microsoft PowerPoint window.

FEATURES OF A PRESENTATION TOOL

PowerPoint is the presentation software of the Microsoft Office software suite. One of the
most widely used office programs, PowerPoint has applications for personal use, academics and
business. Below are five features you should be using – if you aren't already. Learn everything
about these tips: they will improve your presentation skills and allow you to communicate your
message
successfully.
 ADDING SMART ART
SmartArt is a comprehensive and flexible business diagram tool that greatly improves upon
the ‘Diagram Gallery’ feature found in previous versions of Office. SmartArt can be used to create
professional diagrams that include pictures and text or combinations of the two. An obvious use of
SmartArt would be to create an organization chart but it can be used for many different kinds of
diagrams and even to provide some variety to slides using text bullet points.

INSERTING SHAPES
If you need to include some sort of diagram in your presentation, then the quickest and easiest way
is probably to use SmartArt. However, it is important to be able to include shapes independently of
SmartArt and worth being familiar with the various Drawing Tool format options.

Not only will they be useful if you do need to manually draw a diagram (and SmartArt doesn’t suit
all diagrams), but they can also be applied to objects on a slide that you might not immediately think
of as shapes.

As you can see, the gallery of available shapes is very extensive. Once you have selected your
chosen shape, you can just click in your slide to insert a default version of the shape or, to set a
particular size and position, click and drag with the mouse to create the shape and size you want.

INSERTING AN IMAGE

Here are two content type icons which appear in new content Placeholders for inserting pictures.
You can Insert Picture from File or Insert Clip Art. Alternatively, the Illustrations group of the Insert
ribbon tab includes the same two tools.

Insert Picture from File allows you to browse to an image file saved somewhere on your system
whereas Clip Art is held in an indexed gallery of different media types. Clip Art is not limited to
pictures it also includes the following:

Illustrations
Photographs
Video
Audio

Once you have found the image you want to use, click on it to insert it into the current slide. You
can now re-size and move the image accordingly with further editing options available when you
right click the desired image.

SLIDE TRANSITIONS
Properly used, slide transitions can make your presentations clearer and more interesting and,
when appropriate, more fun. Badly used, the effect of slide transitions can be closer to irritating or
even nauseating. Simple animation effects are often used to add interest to bullet point text. Much
more extreme animation effects are available but, in most cases, should be used sparingly if at all.

Two main kinds of animation are available in a PowerPoint presentation: the transition from one
slide to the next and the animation of images/text on a specific slide.

In PowerPoint 2010 & 2013 there is also a separate Transitions ribbon tab that includes a gallery
of different transition effects. These can be applied to selected slides or all slides. If you want to
apply different transition effects to different groups of slides, then you might want to choose ‘Slide
Sorter’ view from the Presentation Views group of the View ribbon.

ADDING ANIMATION
Whereas the transition effects are limited to a single event per slide, animations can be applied to
every object on a slide – including titles and other text boxes. Many objects can even have
animation applied to different components, for example each shape in a SmartArt graphic, each
paragraph in a text box and each column in a chart. Animations can be applied to three separate
‘events’ for each object:

Entrance – how the object arrives on the slide
Emphasis – an effect to focus attention on an object while it is visible
Exit – how the object disappears from the slide

To apply an animation effect, choose the object or objects to be animated, then choose Animation
Styles or Add Animation from the Animations toolbar.

Where an animation is applied to an object with different components (for instance a SmartArt
graphic made up of several boxes), the Effect Options tool becomes available to control how each
component will be animated. So for example, your animation can be used to introduce elements of
an organization chart to your slide one by one.

EXAMPLE AND TOP USE OF PRESENTATION TOOL

Presenting a topic
Business presentations Teaching

SOME OTHER EXAMPLE OF PRESENTATION TOOLS

These are some of the other presentation tools that are available:

VISME- is a cloud-based presentation tool that allows you to create highly visual
presentations to engage viewers and communicate your ideas. It features an intuitive, drag-
and-drop design method for creating presentations. The business version also prioritizes
brand consistency and company-wide image storage. When you or your employees create
a presentation, it will feature colors, logos and images that are on brand for your
organization.
HAIKU DECK-is a platform that prioritizes simplicity. Business owners can create elegant,
basic presentations with high-quality images. The spartan approach allows for connecting
with audiences instead of losing them in information overload due to text-heavy slides.
PITCHERIFIC-is not only a presentation solution, but also a platform for building and
practicing your presentation. It's a template-based program that guides you through the
presentation creation process. Instead of drafting a few slides, Pitcherific prompts you to
write out the areas of each part of your speech. The outline for an elevator pitch, for
example, includes a hook, problem, solution and closing.
CANVA-is an online platform that provides templates for a wide range of business-related
publications, like resumes, newsletters, business cards, media kits, brochures and
infographics. You can also use it to construct presentations.
SLIDECAMP- provide slide templates for creating company presentations. You can adjust
color schemes, add company logos, import charts and data, build infographics, and
 organize presentations into sections with Slide Camp. This is a great solution for
maintaining presentation consistency across multiple presentations from your organization.
POWTOON-is an animated presentation and video platform for creating short informational
videos and presentations about your brand or product. Explainer videos are an important
part of a brand's message, and Powtoon is an affordable tool for creating animated videos
and presentations to educate consumers and clients about your business. You can easily
edit presentations and videos, add voiceover, and build a professional experience for your
customers.
VIDEOSCRIBE-is a whiteboard video presentation platform that allows small businesses
to customize their presentations to fit their needs. These videos, which feature a whiteboard
and hand that "draws" different objects and slides in the presentation, are ideal for quick
explainers and marketing videos on your business or product. You can easily place objects,
insert text, and even draw your own objects or text with VideoScribe's platform.

PREZI- is another template-based presentation solution that you can use to create
persuasive and engaging presentations with unique movement between "slides" and key
points. Prezi maps out your whole presentation on an overall track that you decide. When
you switch slides, it doesn't simply advance to the next one; it takes the viewer through the
track to the point that needs to be made. This allows your audience to visualize the
progression of your presentation. You can arrange content under different sections and
create an overview so your audience can see your entire presentation plan. This method
keeps the presentation organized and your audience engaged. You can also navigate
freely through your presentation – your track is not locked in and you can adjust when you
address which points as you're presenting.

WHAT IS A SPREADSHEET?

A spreadsheet or worksheet is a file made of rows and columns that help sort data,
arrange data easily, and calculate numerical data. What makes a spreadsheet software program
unique is its ability to calculate values using mathematical formulas and the data in cells. A good
example of how a spreadsheet may be utilized is creating an overview of your bank's balance.

OVERVIEW OF A SPREADSHEET

Below is a basic example of what a Microsoft Excel spreadsheet looks like, as well as all the
important features of a spreadsheet highlighted.

In the above example, this spreadsheet is listing three different checks, the date, their description,
and the value of each check. These values are then added together to get the total of $162.00 in
cell D6. That value is subtracted from the check balance to give an available $361.00 in cell D8.

Difference between a workbook, worksheet, and spreadsheet

Because the terms spreadsheet, workbook, and worksheet are so similar, there can be a
lot of confusion when trying to understand their differences. When you open Microsoft Excel (a
spreadsheet program), you're opening a workbook. A workbook can contain one or more different
worksheets that can be accessed through the tabs at the bottom of the worksheet you’re currently
viewing. What's often most confusing is that a worksheet is synonymous with a spreadsheet. In
other words, a spreadsheet and worksheet mean the same thing. However, most people only refer
to the program as a spreadsheet program and the files it creates as spreadsheet files or worksheets.
Although spreadsheets are most often used with anything containing numbers, the uses of a
spreadsheet are almost endless. Below are some other popular uses of spreadsheets.

Finance- Spreadsheets are ideal for financial data, such as your checking account
information, budgets, taxes, transactions, billing, invoices, receipts, forecasts, and any
payment system.
Forms- Form templates can be created to handle inventory, evaluations, performance
reviews, quizzes, time sheets, patient information, and surveys.

School and grades- Teachers can use spreadsheets to track students, calculate grades,
and identify relevant data, such as high and low scores, missing tests, and students who
are struggling.

Lists- Managing a list in a spreadsheet is a great example of data that does not contain
numbers, but still can be used in a spreadsheet. Great examples of spreadsheet lists
include telephone, to-do, and grocery lists.
Sports- Spreadsheets can keep track of your favorite player stats or stats on the whole
team. With the collected data, you can also find averages, high scores, and statistical data.
Spreadsheets can even be used to create tournament brackets.

What is an active worksheet?

An active worksheet is the worksheet that is currently open. For example, in the Excel picture
above, the sheet tabs at the bottom of the window show "Sheet1," "Sheet2," and "Sheet3," with
Sheet1 being the active worksheet. The active tab usually has a white background behind the tab
name.

How many worksheets open by default?

In Microsoft Excel 2016 and earlier and OpenOffice Calc, by default, there are three sheet tabs
that open (Sheet1, Sheet2, and Sheet3). In Google Sheets, your spreadsheets start with one sheet
(Sheet1).

In Microsoft Excel 365, by default, there is only one sheet tab that opens (Sheet1).

What is the length limit of a worksheet name?

Not to be confused with the file name, in Microsoft Excel, there is a 31 character limit for each
worksheet name.

How are rows and columns labeled?

In all spreadsheet programs, including Microsoft Excel, rows are labeled using numbers (e.g., 1 to
1,048,576). All columns are labeled with letters from A to Z, then with two letters. For example, after
the letter Z, the next column is AA, AB, AC,..., AZ and then incrementing to BA, BB, BC, etc., to
the last column XFD.

When working with a cell, you combine the column with the row. For example, the very first cell is
in column A and on row 1, so the cell is labeled as A1.
 Why not use a word processor instead of a spreadsheet?

While it may be true that some of the things mentioned above could be done in a wordprocessor,
spreadsheets have a huge advantage over word processors when it comes to numbers. It would
be impossible to calculate multiple numbers in a word processor and have the value of the
calculation immediately appear. Spreadsheets are also much more dynamic with the data and can
hide, show, and sort information to make processing lots of information easier.

WHAT IS A LIBRARY MANAGEMENT?

Library Management Software is an application that allows automation of libraries and
book databases. The software is commonly used by libraries and librarians to be able to manage
and access their library resources through a single, computer-based platform. Such applications
make it easy for library staff to manage books and records. Self-service or web-based library
management applications allow users to efficiently search online libraries for desired book or
material and read it online.

FEATURES OF A LIBRARY MANAGEMENT SOFTWARE

In a library management software, it gives you a lot of option and features that you can use
in order to have a more accessible system.

Acquisition management: helping a library keep track of new print and digital additions to
the collection
Barcode scanning: simply being able to check items in and out
Barcoding: the capacity to add a barcode to a new or damaged acquisition
Catalog management: keeping track digitally of what is available in the collection or, when
interlibrary loan is relevant, in the broader available system
Circulation management: tracking who has what and when items are due
Fee collection: keeping track of fines owed to the library
OPAC: access to an online public access catalogue of various public libraries

Patron management: keeping track of information about patrons and their records
Periodicals management: managing journals and magazines available digitally in print
Reserve shelf management: for libraries that allow teachers to keep items on reserve
Search functions: allows patrons and librarians to complete a catalog search on various
levels
Self check-in/check-out: allowing patrons to check their own items in and out
Serials management: keeping track of the serials in the library.

Activity 6 (ASSIGNMENT)
Directions: Self-Assessment Write your answer on the SEPARATE PAPER determine the possible
answers.

1. What are the examples of applications software

2. How do I pass a software engineer interview?
3. What is the most useful application software for you?

Note:

After this chapter review for a while and take the midterm
exam

LESSON 7: UTILITY SOFTWARE
LEARNING OBJECTIVES
Know what is the utility software
Know the types of utility software and the uses
Know the basic principle and strategies of software utilities

Utility Software

Utility software, often referred as utility is a system software that is designed to help analyze,
configure, optimize or maintain a computer and enhance the computer’s performance. It is a
program that performs a specific task, which is usually related to managing the system resources.
Utilities are sometimes also installed as memory-resident programs. Utility software usually focuses
on how the computer infrastructure that includes computer hardware, application software,
operating system and data storage programs operates. These utilities could range from the small
and simple to the large and complex that can perform either a single task or a multiple task. Some
of the functions performed by these utilities are data compression, disk defragmentation, data
recovery, management of computer resources and files, system diagnosis, virus detection, and
many more. Utility software has been designed specifically to help in management and tuning of
operating system, computer hardware and application software of a system.

It performs a specific and useful function to maintain and increase the efficiency of a computer
system

Aids in keeping the computer free from unwanted software threats such as viruses or spyware

Adds functionality that allow the user to customize your desktop and user interface

Manages computer memory and enhances performance in general, these programs assist the
user to make in general, these programs assist the user to make and run their computer better.
They are also used for password protection, memory management, virus protection, and file
compression in order to manage all the computer functions, resources and files efficiency

Types of Utility Software

These are the different types of utility software.

Application Launchers – is a computer program that helps a user to locate and start other
computer programs.... In the comparison of desktop application
launchers that follows, each section is devoted to a different desktop environment.
Antivirus software -Antivirus software, or anti-virus software (abbreviated to AV software), also
known as anti-malware, is a computer program used to prevent, detect, and remove malware.
Antivirus software was originally developed to detect and remove computer viruses, hence the
name. However, with the proliferation of other kinds of malware, antivirus software started to
provide protection from other computer threats.

Backup software – Backup software are computer programs used to perform backup; they create
supplementary exact copies of files, databases or entire computers. These programs may later
use the supplementary copies to restore the original contents in the eve