BASIC Electronics Reporters: Hannah Faith Martinez Candy Amor Uriarte Ma. Dores Virtudazo Mika Aisha Mimura.

Slides:



Advertisements
Similar presentations
Chapter 20 Electricity.
Advertisements

DYNAMIC ELECTRICITY.
Chapter 19 Flow of Electricity Useful electricity requires moving electric charges You must do work to move a charged particle against an electric field.
Static charges will move if potential difference and conducting path exists between two points Electric field due to potential difference creates force.
CSC 405 Lab 1 - Building a Simple Combinatorial Circuit In this laboratory exercise you will learn about the layout of some small-scale integrated circuits.
Electric Circuits Notes
Electricity Chapter 34.
Electric and Magnetic Phenomena
Preview Objectives Electrical Potential Energy Potential Difference Sample Problem Chapter 17 Section 1 Electric Potential.
I Q The electric current, I, is the rate of flow of charge Q through a given area in a given amount of time in an electric conductor. Units: Coulomb/second.
Unit 3 Simple Circuits. Electric current Voltage produces a flow of charge, or current, within a conductor. The flow is restrained by the resistance it.
Integrated Science I. Electrical conductors – a material that allows electrons to flow easily through it Ex) gold, silver, copper, etc. Electrical insulators.
Investigating Basic Circuits Pre-Activity Discussion
HOPE- Hands On Practical Electronics Lesson 1: Introduction and Voltage, Current, and Resistance.
Foundations of Physics
Science 9 : Introduction to Current Electricity
Electric Current and Circuits Review Current CURRENT: a flow of charged particles (electrons) through a conductor Current, I, is measured in amperes,
Current Electricity Electric Current Circuit – continuous conducting path between terminals of a battery (or other source of EMF) Electric Current.
Circuits Electric Circuit: a closed path along which charged particles move Electric Current: the rate at which a charge passes a given point in a circuit.
Electricity Chapter 20.
Electric Current And Power
Copyright © by Holt, Rinehart and Winston. All rights reserved. Section 1 Electrical Charge and Force  Indicate which pairs of charges will repel and.
Static Electricity Electrical Charge: Is a concentration of electricity.
Unit 7: Electricity and Magnetism
123 What do the following terms mean? Current Resistance Parallel Circuit Series Circuit.
Chapter 18 Direct Current Circuits. Chapter 18 Objectives Compare emf v potential difference Construct circuit diagrams Open v Closed circuits Potential.
Chapter 18 Electric Currents The Electric Battery Volta discovered that electricity could be created if dissimilar metals were connected by a conductive.
Electricity Part 2. Learning Objectives TLW know the impact of energy transfer and energy conversion in everyday life (TEKS 5) TLW evaluate, investigate.
ELECTRICITY.
 Water boy Water boy  Lightning Lightning  Team work Team work  Ac/Dc Charge Ac/Dc Charge.
Electrical Current Mr. Fleming.
Electrodynamics – Science of electric charges in motion Flow Electric Charges May Occur: 1. In a vacum 2. In a gas 3. In ionic solution 4. In a metallic.
Electricity. Electric Charge- property that causes subatomic particles such as protons and electrons to attract or repel each other An excess or shortage.
Part 1 Current & Energy Transfer Electric Current.
Electric Current and Resistance Physics. Potential Difference  Charges can “lose” potential energy by moving from a location at high potential (voltage)
35 Electric Circuits In a parallel circuit, each device operates independent of the other devices. A break in any one path does not interrupt the flow.
Current Electricity Chapter Current & Circuits Society has become very dependant upon electricity because of the ease in which electricity is.
Basic Electronics Irish Mae E. Santiago III-Newton.
Current of Electricity Electric Current Potential Difference Resistance and Resistivity Electromotive Force.
© 2002 University of North Carolina at Charlotte, ALL RIGHTS RESERVED Basic DC Circuits Review.
Unit G482: Electrons, Waves and Photons
Electric Current Chapter 7-2. Electric Circuit F A closed path through which electrons can flow F Electrons flow because of a difference in potential.
Electric Currents AP Physics Chapter 18. Electric Currents 18.1 The Electric Battery.
SOLUTION OF ELECTRIC CIRCUIT. ELECTRIC CIRCUIT AN ELECTRIC CIRCUIT IS A CONFIGURATION OF ELECTRONIC COMPONENTS THROUGH WHICH ELECTRICITY IS MADE TO FLOW.
Chapter 6: Electricity Section 1: Electric Charge
Mr. Gillis’ Science Class. What needs to happen to get the bulb to light?
Electricity on the Move. Current Electricity Unlike static electricity, which does not move except when discharged, current electricity is a continuous.
Chapter 16 Electricity.
Electrical Circuits Chapter 20 Section Three. Science Journal Entry #42 Expound upon Ohm’s Law and its relationship to current, resistance, and voltage.
CHAPTER 17: ELECTRICITY ELECTRIC CHARGE AND FORCE CHAPTER 17: ELECTRICITY.
Waterfalls and Electricity. Niagara (American side) and Horseshoe (Canadian side) Falls 176 feet high gallons per second.
Electric Current Chapter 17.2 Notes. Electrical Potential Energy Recall that gravitational potential energy depends on position—a ball at the top of a.
Electric Current Everything (water, heat, smells, …) flows from areas of high concentration to areas of lower concentration. Electricity is no different.
ELECTRICITY Chapter-16. DEFINITIONS COULOMB It is SI unit of electric charge. One coulomb (1C) of charge being that quantity of charge which when placed.
Chapter 6 & 7: Electricity. Electricity The flow of electric current. The flow of electric energy carried by electrons.
Electricity. The flow of electric current. The flow of electric energy carried by electrons.
FOR BHS PHYSICAL SCIENCE 9 TH GRADE Electronics Introduction.
The flow of charged particles charged particles ; through a conducting metal.
Chapter 18 Electric Currents. Units of Chapter 18 The Electric Battery Electric Current Ohm’s Law: Resistance and Resistors Resistivity Electric Power.
Current and Resistance El Paso Independent School District.
Circuits Electric Current Series vs. Parallel. Let’s Review 0 What is electricity?
Electricity. An electric current is a flow of ELECTRONS flowing through wires and electronic components.
L 25 Electricity and Magnetism [3]
through a conducting metal
OBJECTIVES After studying Chapter 4, the reader should be able to:
Electric Current Chapter 6-2.
Circuit Theory Laws Circuit Theory Laws Digital Electronics TM
Electric Circuits 20.3.
Circuit Theory Laws Circuit Theory Laws Digital Electronics TM
Presentation transcript:

BASIC Electronics Reporters: Hannah Faith Martinez Candy Amor Uriarte Ma. Dores Virtudazo Mika Aisha Mimura

Objectives of this Chapter 1)Understand basic electronic terms like current, voltage, resistance and power 2)Solve circuits using Ohm’s Law 3)Learn how to read schematic diagrams 4)Become familiar with the usage of electronic devices 5)Enumerate the usage of the following electronic devices: resistors, voltage sources, capacitors, switches, diodes and transistors 6)Apply the knowledge of electronic circuits to practical applications 7)Introduce you to digital electronics by using logic gates learning how to read integrated circuit packages 8)Realize the importance of safety when handling electronic equipment and other electronic devices

Introduction So far we have only looked at electric charges sitting still and static discharges. When we count on the charges moving through circuits, we start looking at electrical currents, voltages, resistances and capacitances, and how they behave in some materials. Electronics comes from the word electron. This involves the flow of electrons across a material. From this we can define electronics.

Electronics – study of the properties and behavior of electrons in various materials. By knowing how these particles behave, we would be able to determine the effect of a material, either by itself or as part of an entire circuit.

current It is the rate of the flow of charges, measured in amperes (A). The unit of measurement for current is the Ampere, or Amp for short, and abbreviated as A. The name Ampere comes from Andre Marie Ampere who played with electricity as a small boy in Vermont. Q t i =

One ampere (A) is equal to one coulomb (C) of charge passing a point in a circuit in one second. (1A = 1C/s.). 1C = 6 x 10^18 electrons. Since we use positive values as our reference, the arrow indicating current is actually the direction of flow of positive charge, which is exactly opposite the direction of the flow of electrons. [The coulomb (named after Charles-Augustin de Coulomb, unit symbol: C) is a fundamental unit of electrical charge, and is also the SI derived unit of electric charge (symbol: Q or q). It is equal to the charge of approximately 6.241×10 18 electrons.]

Currents in the ampere range are very fast. Although this is the standard unit, actual circuits, especially small devices use current lower than 1 Ampere. So in some cases, we use the milliampere or mA to measure current. The milli means divided by 1000, so Amps equals 1 milliAmp (1 mA) since 1 / 1000 = Also, 0.5 Amps equals 500 milliAmps (500mA) since 500 / 1000 = 0.5.

Mathematically, V = W/Q One volt is equal to one joule of work per coulomb of charge. (1V = 1J/C). Just as heat flows through a heat conductor until there is no longer a temperature difference, charge wants to flow through an electrical conductor until there is no more potential difference (voltage). A measurement of voltage is much like a measurement of height. It gives you the difference in voltage between those two points. If point A is at 10 volts and point B is at 2 volts then the voltage measured between A and B is 8 volts (10 - 2).

When we measure voltage, our reference point is usually called ground or GND. This is because in some voltage sources, you really get the “voltage of the ground” by connecting a metal pipe or other conductor to the ground. This is our zero (0) volts, the ground.

capacitance It is a measure of the ability to store charge and energy in electric fields. – To measure capacitance of a material, if a voltage V is attached to the material, the capacitance C depends on this equation: Where Q is the charge in coulombs, C is the capacitance in farads and V is the voltage of the battery in volts. [The farad (symbol: F) is the SI derived unit of electrical capacitance. It is named after the English physicist Michael Faraday.] Q V C =

The energy in joules stored in a capacitor when it is charged up to a voltage V is 1 2 CV²E =

RESISTIVITY, RESISTANCE, AND LOADS Resistivity is the property of a material that is a measure of the ability to resist the flow of charges. This is dependent on the temperature o the material. Resistance is the characteristic of a material of a given dimension, a measure of the ability to resist the flow of charges. – In equation form,

If conductivity is the inverse of resistance, the inverse of resistance is conductance. Resistance (R) is measured in ohms ( Ω ). The Ohm is named after a German physicist, Georg Simon Ohm, who tested different wires in circuits to see what effect the wire’s resistance had on the current that would flow. Resistivity, on the other hand has the unit ohms-m or ohm- centimeters.

From the equation of Resistance, it is proportional to the length of the conductor L, inversely proportional to the cross-sectional area A of the conductor, and depends on the material used for the conductor (its resistivity ). Gold is the best conductor and has the lowest resistance, closely followed by copper which has a bit higher resistance. Resistance is also a measure of how much of the energy of the current is converted into heat during the process of flowing.

Ohm’s law There is a simple relationship between current, voltage and resistance. This relationship is called Ohm’s Law. In equation form, Voltage = Current x Resistance V = i x R Where i is the current in Ampere (A) V is the voltage in Volts (V) R is the resistance in Ohms ()

Example 1 What is the voltage across a material if the current flowing through it is 2 amperes and the resistance is 100 ohms? Given : current i : 2A resistance : R 100 Ω Find : Voltage (V) Solution : Using Ohm’s Law, V = iR = 2A ( 100 Ω ) = 200 Volts

Example 2 How much current is flowing through a material whose resistance is 1000 Ohms and the voltage across is 10 Volts? Given : Voltage V = 10 V resistance = R 1000 Ω Find : Current (i)

Solution: From Ohm’s Law, V = iR When solving for i, i = V/R. So, i = V/R = 10 V/(1000 Ω ) =.01 A or 10 milliAmperes (mA)

Example 3 What is the resistance of a material in kiloohms if the voltage across is 5 Volts and the current flowing through it is 20 mA? Given : Voltage V = 5 V current i= 20 mA Find : Resistance in kiloohms If the current is in milliamperes and the voltage is in volts, the resistance will be in kiloohms (k Ω )

Solution : From Ohm’s Law, V = iR. When solving for R, R = V/i. So R =V/I = 5 V /(20 mA ) = 0.25k Ω If you want it in ohms, just multiply by 1000, so R = 250 Ω

Electric power From the previous chapters, we have defined power as P = W/t – Where P is the power in watts, W is the work in joules and t is the time in s. Since we defined voltage as V = W/Q, we can replace W with VQ P = W/t = VQ/t But Q/t is just the current i, so our equation for current becomes any of the following: P = Vi = i²R = V²/R

EXAMPLE How much power is consumed by a material if the voltage across is 5 V and the current flowing through it is 2 A ? Given: Voltage V = 5 V current i = 2 A Find: Power

Solution Since what is given is V and i. To solve for P, we will use equation: P = Vi = 5V (2A) = 10 W The material consumes 10 Watts of Power.

energy Since by definition, Work equals energy, then W = E = Pt Substituting this equation : P = Vi for P, we can also express the energy as E = V i t

The electric circuit

Open Circuit An open circuit is when two points are not connected by anything. No current flows and noting happens. If a wire in your vacuum cleaner breaks it can cause an open circuit and no current can flow so it does not do anything. There may be a voltage between those two points but the current ca not flow without a connection. An open circuit provides no path. It is equivalent to an infinitely large resistance in the circuit and no current flows.

Short Circuit A short circuit (or short) occurs when two points with different voltage levels are connected with no resistance between two points. This can cause a large amount of current to flow. You will quickly know a short when you accidentally connect your fingers with a battery through a wire. The wire will heat up and burn your fingers, and the battery will quickly wear out. If a short circuit happens in your house, it will usually cause a circuit breaker to break or a fuse to blow up. If there is no device to limit the current, the wires may melt and cause a fire. When a person is electrocuted, it doesn’t just harm the person, it also causes a short circuit.

Using the breadboard (socket board) The breadboard is a gadget that allows you to connect different electronic components easily and safely. This is also called a prototype board, where you test the electronic design and make refinements before putting the components in a circuit board. The breadboard has many strips of metal (copper usually ), which run underneath the board.

These strips connect the holes on the top of the board. This makes it easy to connect components together to build circuits. To use the breadboard, the legs of components are placed in the holes (the sockets). The holes are made so that they will hold the component in place. Each hole is connected to one of the metal strips running underneath the board. Each wire forms a node. A node is a point in a circuit where two components are connected. Connections between two different components are formed by putting their legs in a common ode. On the breadboard, a node is the row of holes that are connected by the strip of metal underneath.

The long top and bottom row of holes are usually used for power supply connections. The rest of the circuit is built by placing components into the holes and connecting them together with jumper wires. Then, when a path is formed by wire and components from the positive supply node to the negative supply node, we can turn on the power ad current flows through the path and the circuit comes alive. For chips with many legs (ICs), place them in the middle of the board so that half of the legs are on one side of the middle line and half are on the other side.