1. Electrical Engineering Technology EE306
Lecture 1
Dr. Titik Khawa

2. Introduction
Chapter 1 of Hughes Electrical and Electronic Technology

3. International System of Units (SI)
The SI is based on the measures of six physical quantities:
Quantity
Symbol
Unit
Mass m
Kilogram (kg)
Length l
Meter (m)
Time t
Second (s)
Electric current I
Ampere (A)
Absolute temperature 
Kelvin (K)
Luminous intensity lv
Candela (cd)
All other units are derived units and are related to these base units by definition.

4. Unit of Work or Energy Symbol: W Unit: joule ( J)
The joule is the work done when a force of 1 N acts through a distance of 1 m in the direction of the force.
Work done = F [newtons] × l [metres] = Fl joules
W = Fl
Symbol: W Unit: joule ( J)
Energy is the capacity for doing work. Both energy and work are measured in similar terms.

5. If a body having mass m, in kilograms, is moving with velocity u, in m/s,
Kinetic energy = 0.5mu2 Joules ∴ W = 0.5mu2
If a body having mass m, in kilograms, is lifted vertically through height h (m), and if g is the gravitational acceleration (m/s2 ), in that region, the potential energy acquired by the body is the work done in lifting the body = mgh Joules
∴ W = 9.81mh

6. Unit of power
Power is the rate of doing work or the joule per second, or watt.
In practice, the watt is often found to be inconveniently small and so the kilowatt is frequently used.
Power Symbol: P Unit: watt (W)
In the case of a rotating electrical machine,
where Nr is measured in revolutions per minute (r/min).
In SI, the rotational speed is in revolutions per second (r/s).

7. There is another unit of energy which is used by electricity suppliers : the kilowatt hour (kW h).
It represents the work done by working at the rate of one kilowatt for a period of one hour.
1 kW h = 1000 watt hours
= 1000 × 3600 watt seconds or joules
= J = 3.6 MJ

8. Efficiency
It should be noted that when a device converts or transforms energy, some of the input energy is consumed to make the device operate. The efficiency of this operation is defined as

10. Temperature
Absolute temperature is measured in kelvin, but for most electrical purposes at an introductory stage it is sufficient to measure temperature in degrees Celsius.
It should be remembered that both degrees of temperature represent the same change in temperature – the difference lies in the reference zero.

11. Summary of important formulae

12. Terms and concepts
Force, when applied to a body, causes the body to accelerate.
Weight is the gravitational force exerted by the earth on a body.
Torque, when applied to a body, causes the body to rotationally accelerate.
Energy is the capacity to do work. When selling energy, it is measured in kilowatt hours rather than joules.
Power is the rate of working.
Efficiency is the ratio of output power to input power. The difference between output and input is usually due to wastage (losses as heat).

13. Chapter 2 of Hughes Electrical And Electronic Technology

14. An Electrical System
A basic electrical system has four constituent parts :-
The source. The function of the source is to provide the energy for the electrical system. A source may usually be thought of as a battery or a generator, although for simplicity we might even think of a socket outlet as a source.

15. The load. The function of the load is to absorb the electrical energy supplied by the source to do work . Most domestic electrical equipment constitutes loads. Common examples include lamps and heaters, all of which accept energy from the system.
The transmission system. This conducts the energy from the source to the load. Typically the transmission system consists of insulated wire.
The control apparatus. As the name suggests, its function is to control. The most simple control is a switch which permits the energy to flow or else interrupts the flow.

16. Electric Charge
Electric charge - An electrical system transmits energy due to the movement of electric charge.
An electron is an elementary particle charged with a small and constant quantity of negative electricity.
A proton is similarly defined but charged with positive electricity whereas the neutron is uncharged and is therefore neutral.
In an atom the number of electrons normally equals the number of protons; it is the number of protons that determines to which element type the atom belongs.
An atom can have one or more electrons added to it or taken away. If the atom has excess electrons, it is said to be negatively charged. A charged atom is called an ion.
A body containing a number of ionized atoms is also said to be electrically charged. It can be shown that positively and negatively charged bodies are mutually attracted to one another whereas similarly charged bodies repel one another.

17. Movement of Electrons
All electrons have a certain potential energy. They move freely from one energy level to another and this movement is termed an electric current flow.
Conventionally the current flows from a point of high energy level to a point of low energy level i.e from high potential (positive) to low potential respectively (negative).
Conventionally a current is said to flow from positive to negative (higher potential to lower potential).

18. Electrons move in the opposite direction from the current since the negatively charged electron is attracted to the positive potential.
The transfer of electrons takes place more readily in a medium in which atoms can readily release electrons, e.g. copper, aluminium, silver i.e conductor.
A material that does not readily permit electron flow is termed an insulator.
Semiconductor is a material which have certain characteristics that belong to neither of the other groups.

19. Electromotive force and Potential difference
The e.m.f. represents the driving influence that causes a current to flow.
The e.m.f. is not a force, but represents the energy used during the passing of a unit charge through the source; an e.m.f. is always connected with energy conversion.
The energy transferred due to the transfer/movement of unit charge between two points in a circuit is termed the potential difference (p.d.).

20. If all the energy is transferred to the load unit, the p. d
If all the energy is transferred to the load unit, the p.d. across the load unit is equal to the source e.m.f.
It will be observed that both e.m.f. and p.d. are similar quantities.
An e.m.f. is always active in that it tends to produce an electric current in a circuit.

21. Electrical Units
Current - The ampere is defined as that current which, if maintained in two straight parallel conductors of infinite length, of negligible circular cross-section, and placed 1 metre apart in a vacuum, would produce between these conductors a force of 2 × 10−7 newtons per metre of length.
Symbol: I Unit: ampere (A)

22. Quantity of electricity (charge)
The unit of electrical quantity is the coulomb, namely the quantity of electricity (charge) passing a given point in a circuit when a current of 1 ampere is maintained for 1 second.
1 ampere hour = 3600 coulombs
The rate of charge passing a point is the current but it has become common
practice to describe a flow of charge as a current.

23. The unit of potential difference is the volt, namely the difference of potential between two points of a conducting wire carrying a current of 1 ampere, when the power dissipated between these points is equal to 1 watt.
Electric potential Symbol: V Unit: volt (V)
Electromotive force has the symbol E but has the same unit.

25. The unit of electric resistance is the ohm, namely the resistance between two points of a conductor when a potential difference of 1 volt, applied between these points, produces in this conductor a current of 1 ampere.
Alternatively, the ohm can be defined as the resistance of a circuit in which a current of 1 ampere generates heat at the rate of 1 watt.
Electric resistance Symbol: R Unit: ohm (Ω)