Electrical Circuits 1 Reviewer PDF

Summary

This document provides an introductory overview of electrical circuits. It describes terms such as electricity, atomic structure, static electricity, and lightning. It also introduces the concepts of AC and DC sources and their applications.

Full Transcript

ELECTRICAL CIRCUITS 1 If this 29th electron gains sufficient energy from the
surrounding medium to leave the parent atom, it is called a
REVIEWER free electron. In 1 cubic inch of copper at room
temperature, there are approximately 1.4 x1024 free
electrons.
INTRODUCTION
ELECTRIC CHARGE
An electron is the smallest particle with a negative
ELECTRICITY charge, equal in magnitude to a proton’s positive charge.
Form of energy resulting from the existence of Electrical charge (Q) arises from an imbalance of
charged particles (such as electrons or protons), either electrons: excess electrons create a negative charge, while
statically as an accumulation of charge or dynamically as a deficiency results in a positive charge. Static electricity is
a current. the presence of a net charge in a material.

ATOMIC STRUCTURE STATIC ELECTRICITY
An atom is the smallest unit of an element, Rubbing a balloon on a pullover transfers
retaining its properties. All matter consists of atoms made electrons to the balloon, making it negatively charged,
up of electrons, protons, and neutrons. Understanding while the pullover becomes positively charged. The
current and voltage starts with knowing an atom's opposite charges attract, causing them to stick.
structure.
LIGHTNING
The orbiting electron carries a negative charge
Heavier, negatively charged particles sink to the
equal in magnitude to the positive charge of the proton. In
general, the atomic structure of any stable atom has an bottom of the cloud. When the positive and negative
equal number of electrons and protons. charges grow large enough, a giant spark - lightning -
occurs between the two charges within the cloud. This is
like a static electricity sparks you see, but much bigger

AC AND DC SOURCES

AC (Alternating Current) changes direction
periodically and operates at a specific frequency (e.g., 50
Hz or 60 Hz). It is generated by alternators, suitable for
long-distance transmission due to low energy loss, and
Copper is the most commonly used metal in the commonly used for household power and industrial
electrical/electronics industry. systems.
DC (Direct Current) flows in one constant
direction with a steady voltage. It is produced by batteries
or solar panels, ideal for low-voltage applications like
electronics, but inefficient for long-distance transmission.
GENERATION OF AC VOLTAGE
An ac voltage is one that continually changes in
magnitude and periodically reverses in polarity. An AC
voltage can be produced by a generator called alternator.
It came form the theory of electromagnetic
induction, “Whenever the flux linking a coil changes an
emf is included.”.

DC GENERATOR
 MAGNETISM
DEFINITION: In physics, magnetism is one of the
phenomena by which materials exert attractive or
repulsive forces on other materials.
Magnets produce magnetic forces and have
magnetic field lines and have two ends or poles, called
north and south poles. At the poles of a magnet, the
magnetic field lines are closer together.

ELECTRICITY AND MAGNETISM
On 21 April 1820, during a lecture, Hans Christian
Oersted, a Danish physicist and chemist, and a professor
noticed a compass needle deflected from magnetic north
when an electric current from a battery was switched on
and off, confirming a direct relationship between
electricity and magnetism.

ELECTROMAGNETISM a magnetic field that is produced
by a current of electricity
 GALVANOMETER is an electromagnet that
interacts with a permanent magnet. The stronger the
electric current passing through the electromagnet, the
more is interacts with the permanent magnet.

ELECTROMAGNETIC INDUCTION
Electromagnetic induction is the process where a
conductor in a changing magnetic field (or moving through
a stationary field) produces a voltage, which induces an
electrical current. Discovered by Michael Faraday in 1831
and independently by Joseph Henry in 1832.

▪ Current is only produced if the magnet is moving
because a changing magnetic field is what creates
current.
▪ If the magnetic field does not change, such as
when the magnet is stationary, the current is zero.
 BASIC ELECTRICAL QUANTITIES AMPERE One ampere (1 A) is the amount of current that
exists when a number of electrons having a total charge of
one coulomb (1 C) move through a given cross-sectional
VOLTAGE
area in one second (1 s).
Voltage, symbolized by V, is defined as energy or
work per unit charge.
𝑉 = 𝑊/𝑄
Where: V is voltage in volts (V),
W is energy in joules (J),
Q is charge in coulombs
(C) Some sources use E instead of V to symbolize voltage.
CURRENT SOURCE
Voltage provides energy to electrons, allowing An ideal current source provides a constant
them to move through a circuit. This movement of current for any load, similar to how an ideal voltage source
electrons is the current, which results in work being done
provides constant voltage. While an ideal current source
in an electrical circuit.
doesn't exist, it can be approximated in practice.
One VOLT is the potential difference (voltage)
between two points when one joule of energy is used to
move one coulomb of charge from one point to the other. Resistance is the opposition to current flow, symbolized
as R and measured in ohms (Ω). One ohm of resistance
VOLTAGE SOURCE allows one ampere of current when one volt is applied
A voltage source provides electrical energy or across the material.
electromotive force (emf), more commonly known as
voltage. Voltage is produced by means of chemical energy, RESISTOR
light energy, and magnetic energy combined with A resistor is a component designed to provide a specific
mechanical motion. resistance. It is used to limit current, divide voltage, or
generate heat. Resistors are categorized as either fixed or
variable.

FIXED RESISTORS
Fixed resistors have predetermined resistance values set
during manufacturing and cannot be easily adjusted.

CURRENT
Electrical current is the rate of flow of charge.
Current in a conductive material is determined by the
number of electrons (amount of charge) that flow pass a
point in a unit of time.
𝑰=𝑸/ t
Where: I is current in amperes (A)
(A), Q is charge in coulombs
(C), t is time in seconds (s).

Electrical current is the rate of flow of charge.
 RESISTANCE AND RESISTIVITY TEMPERATURE EFFECT
Inferred Absolute Temperature
For good conductors, increase in temperature results in an
Resistance of any material is due primarily to the
following factors: increase in the resistance level. For Copper(and most
1. Material other metallic conductors), the resistance increases
2. Length almost linearly.
3. Cross-sectional area
4. Temperature
The first three elements are related by the
following basic equation for resistance:

WHERE: 𝜌 =resistivity, 10.37 CM-Ω/ft at 20⁰C for copper
𝑙 =length, ft
A = area in Circular Mils, CM

CIRCULAR MILS (CM)

Temperature Coefficient of Resistance
The temperature coefficient of resistance is the
rise in the resistance of a material per degree rise in
temperature to the original resistance.

Where: T1 = lower value temperature
T2 = Higher value temperature
R1 = resistance at T1
R2 = resistance at R2
𝛼1 = temperature coeff. of resistance at T1

EXAMPLES
 Temperature Coefficient of POWER AND ENERGY
Resistance POWER - rate of doing work
- rate at which energy is used

WHERE: P = power, watts
W = energy, joules
t = time, seconds

WHERE: P = power, watts
V = voltage, volts
I = current, amperes

Variation of Resistance with given temperature

OHM’S LAW
Ohm’s law states that current is directly
proportional to voltage and inversely proportional to
resistance. In formula,
VOLTAGE DIVIDER RULE
States that the voltage across a resistor in a series
circuit is equal to the value of that resistor times the total
applied voltage divided by the total resistance of the series
configuration.

KIRCHHOFF’S CURRENT LAW
The law states that the algebraic sum of the
CURRENT DIVIDER RULE
currents entering and leaving a junction (or region) of
States that the current through any branch of a
a network is zero.
parallel resistive network is equal to the total resistance of
the parallel network divided by the resistor of interest and
multiplied by the total current entering the parallel
where Σ represents summation
I the currents entering and leaving the
junction

The law can also be stated in the following
way: The sum of the currents entering a junction (or
region) of a network must equal the sum of the
currents leaving the same junction (or region). In
equation form,

KIRCHHOFF’S LAWS
specifies that the algebraic sum of the potential rises
and drops around a closed path (or closed loop) is
zero. In symbolic form it can be written as

Where: Σ represents summation;
⟳the closed loop
V the potential drops and rises.
 METHODS OF ANALYSIS NODAL ANALYSIS

CURRENT SOURCES
The current source is often described as the dual
of the voltage source. The term dual is applied to any two
elements in which the traits of one variable can be
interchanged with the traits of another.
A current source determines the direction and
magnitude of the current in the branch where it is located.
The magnitude and the polarity of the voltage
across a current source are each a function of the network
to which the voltage is applied.

BRANCH CURRENT METHOD

LOOP CURRENT METHOD