Things to Remember 1

Updated 2-20-08

Things to Remember 1
OEES 135, OEET 210

Ohm's Law and Power Formulas

I = current, V = voltage, R = resistance

I = V/R
V = IR
R = V/I

Note: Some people use E for voltage, instead of V. In fact the author of our book does so. Most people, however, use V for voltage. I recommend that you do so also. Things will be a lot less confusing for you as you use other books and work with other people.

P = Power

P = IV
P = V²/R
P = I² R

Metric Prefixes

Name	Abbreviation	Meaning	Number	Power of 12
Pico	p	Trillionth	0.000,000,000,001	10^-12
Nano	n	Billionth	.000,000,001	10^-9
Micro	μ	Millionth	.000,001	10^-6
Milli	m	Thousandth	.001	10^-3
Kilo	k	Thousand	1000	10³
Mega	M	Million	1,000,000	10⁶
Giga	G	Billion	1,000,000,000	10⁹
Tera	T	Trillion	1,000,000,000,000	10¹²

Math, Part 1

Pythagorean Theorem: c² = a² + b²,
where c = hypotenuse, and a and b are the other sides of a right triangle.

The square root of x² is x

ELI the ICE man.

E means voltage (electromotive force).

L = inductance

I = current

C = capacitance

The voltage across an inductor leads the current through the inductor by 90 degrees.

The current through a capacitor leads the voltage across the capacitor by 90 degrees.

No power is used in an ideal inductor or an ideal capacitor.

The true power dissipated in a circuit containing resistors, inductors, and capacitors is equal to the power dissipated in the resistors.

True power is given by the formula P = IV * p.f.

Apparent power is given by the formula P = IV.

Thus, true power is apparent power times the power factor.

L = inductance

C = capacitance

X_L = 2πfL

X_C = 1/2πfC

P = IV * p.f.

p.f. = cos θ

X = reactance

Z = impedance

The unit for reactance and impedance is ohms.

High-frequency current has difficulty passing through an inductor.
Low-frequency current has difficulty passing through a capacitor.
A capacitor and an inductor can be used to create a resonant circuit . A resonant circuit can be used to either pass or block currents of a certain frequency, depending upon whether the two components are connected in series or in parallel.

Math, Part 2

sin θ = opposite/hypotenuse cos θ = adjacent/hypotenuse tan θ = opposite/adjacent	sin^-1 (sin θ ) = θ cos^-1 (cos θ ) = θ tan^-1 (tan θ ) = θ
sin^-1 (opposite/hypotenuse) = θ cos^-1 (adjacent/hypotenuse) = θ tan^-1 (opposite/adjacent) = θ	x^ax^b = x^a+b x^a/x^b = x^a-b

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