Engr. Pepugal & Engr. Largo

11/21/15

PHASORS

-A Phasor is a complex number that represents the amplitude and phase of a sinusoid.

Phasors provide a simple means of analyzing linear circuits excited by sinusoidal sources; solutions of such circuits would be intractable otherwise. The notion of solving ac circuits using phasors was first introduced by charles Steinmetz in 1893. Before we completely define phasors and apply them to circuit analysis, we need to be throughly familiar with complex numbers.

A complex number z can be written in rectangular form as:

z=x+jy

where j=√-1; x is the real part of z; y is the imaginary part of z. In this context, the variables x and y do not represent a location as in two-dimensional vector analysis but rather the real and imaginary parts of z in the complex plane. Nevertheless, we note that there are some resemblances between manipulating complex numbers and manipulating two-dimensional vectors.

The complex number z can also be written in polar or exponential form as:

z=r∠Φ
where r is the magnitude of z, and Φ is the phase of z. We notice that z can be represented in three ways:

z=x+jy z=r∠Φ z=re^jΦ

the relationship between the rectangular form and the polar form is shown in fig, 9.6, where the x axis represents the real part and the y axis represents the imaginary part of a complex number. Given x and y, we can get r amd Φ as

r=√󠄈x^2+y^2, Φ=tan^-1 (y/x)

On the other hand, if we know r and Φ, we can obtain x and y as

x=rcosΦ y=rsinΦ

Mathematical operations of complex numbers:

ADDITION

Z1+Z2=(X1+X2) + J(y1+y2)

SUBTRACTION

z1-z2=(x1-x2)+(y1-y2)

MULTIPLICATION

z1z2= r1r2∠Φ1+Φ2

DIVISION

z1/z2=r1/r2∠Φ1-Φ2

RECIPROCAL

1/z=1/r∠-Φ

SQUARE ROOT

square root of z=square root of r∠Φ/2

COMPLEX CONJUGATE

z*=x-jy=r∠-Φ

11/14/15

SINUSOIDS AND PHASORS

Sinusoids

- A Sinusoid is a signal that has the form of the sine and cosine function. Sinusoidal variables are of special importance in electrical and electronic systems, not only because the occur frequently in such systems but also because any periodical signal can be represented as a linear combination of a set of sinusoidal signals of different frequencies, amplitudes, and phase angles.

Sinusoidal variable can be written as:

v(t) = Vm sin(ωt + Ф)

Where;

Vm = the amplitude of the sinusoid

ω = the angular frequency in radians/s

Ф = the phase

Example 1:

Given a sinusoid, i=3sin(3t + 70) , calculate its amplitude, phase, angular frequency

Solution:

Amplitude = 3, phase =70,angular frequency = 3

Example 2:

A sinusoidal current with a frequency of 60 Hz reaches a positive maximum of 20A at . Give the expression of this current as a function of time .
Solution:
We have , , , . As cosine function reaches maximum when (or ), the phase angle should satisfy where and , i.e.,

The current is

Alternatively, the phase angle can be found as shown below:

Solving this we get , same as above.

Example 3:

Find the phase angle between i1=-4sin(377t + 25) and i2=5cos(377t – 40), does i1 lead or lag i2?

Solution:

Add 180 @ i1:

i1=-4sin(377t + 25 + 180)

i1=4cos(377t + 205)

Change: cos to sin (add 90)

Since sin(ωt + 90) = cosωt

i2=5cos(377t – 40+90)

i2=5cos(377t +50)

therefore, i1 leads i2 155o(Phase Angle)
Complex Numbers

The mathematics used in Electrical Engineering to add together resistances, currents or DC voltages uses what are called “real numbers”. But real numbers are not the only kind of numbers we need to use especially when dealing with frequency dependent sinusoidal sources and vectors. As well as using normal or real numbers, Complex Numbers were introduced to allow complex equations to be solved with numbers that are the square roots of negative numbers, √-1.

In electrical engineering this type of number is called an “imaginary number” and to distinguish an imaginary number from a real number the letter “ j ” known commonly in electrical engineering as the j-operator, is used. The letter j is placed in front of a real number to signify its imaginary number operation. Examples of imaginary numbers are: j3, j12, j100 etc. Then a complex number consists of two distinct but very much related parts, a “ Real Number ” plus an “ Imaginary Number ”.

10/3/15

CAPACITOR AND INDUCTOR

CAPACITOR
-A capacitor is a two-terminal, electrical component. Along with resistors and inductors, they are one of the most fundamental passive components we use. You would have to look very hard to find a circuit which didn’t have a capacitor in it.

A capacitor, we are familiar with this thing because we use to it into our power supply. We use capacitor to stored energy in our power supply.

INDUCTOR
-An inductor is a passive electronic component that storesenergy in the form of a magnetic field. In its simplest form, an inductor consistsof a wire loop or coil. The inductance is directly proportional to the number ofturns in the coil.

The standard unit of inductance is the henry.

In a capacitor, the formula is expressed as “the current in a circuit is in proportion to the time rate of change of the voltage across it.

written as:

i=c(dv/dt)

In series and parallel capacitors, they are combined in the same way as conductances.

An inductor formula states that the voltage across it is directly equitable to the rate of change of the current through the circuit.

The formula is written like this:

v=L(di/dt)

In solving inductors in series and parallel, it is the same as combining the resistors in the circuit, which is in series or parallel.

9/26/15

FIRST ORDER CIRCUITS: SOURCE FREE RC AND RL CIRCUIT

FIRST ORDER CIRCUIT
-A circuit that can be simplified to a Thevenin's or Norton's equivalent connected to either a single equivalent inductor or capacitor.

THE SOURCE-FREE RC CIRCUIT
-an electric circuit composed of resistors and capacitorsdriven by a voltage or current source. A first order RC circuit is composed of one resistor and one capacitor and is the simplest type of RC circuit.

IN SOLVING THE RC CIRCUIT

$V(t)=V_0 e^{-\frac{t}{RC}} \ ,$

The time required for the voltage to fall to

is called the RC time constant and is given by

SOURCE FREE RL CIRCUIT
-is an electric circuit composed of resistors and inductorsdriven by a voltage or current source. A first order RL circuit is composed of one resistor and one inductor and is the simplest type of RL circuit.

IN SOLVING THE RL CIRCUIT

$i(t) = i(0)e^{-\frac{R}{L} t} = i(0)e^{-\frac{1}{\tau} t}$

$\tau = {L \over R}$

SAMPLE RL CIRCUIT

9/19/15

MAXIMUM POWER TRANSFER

MAXIMUM POWER TRANSFER THEOREM

maximum power transfer theorem states that, to obtain maximum external power from a source with a finite internal resistance, the resistance of the load must equal the resistance of the source as viewed from its output terminals.

(RTH=RL)

PROVE THAT RL=RTH

Computing the Power Transfer is equal to V2/4(RL)