DC Circuits Lab

DC Circuits Lab ECE 002 Professor Ahmadi

Outline Basic Components of a Circuit Series Circuit Parallel Circuit Ohm’s Law Lab Overview

Basic Circuit Components 1.5 V 1.5V We represent real electrical components with symbols A Battery… …can be represented with this symbol …called a “DC voltage source” • A DC Voltage Source • Provides Power for our circuit • Battery or Lab ‘power supply’ is an example • DC voltage is supplied across the two terminals • Its voltage is VOLTS (V)

Basic Circuit Components A Light Bulb…or any ‘device’… RΩ • A Resistor • Represents any device that requires power to operate • Could be a light bulb, your computer, a toaster, etc. • Each device has a certain amount of ‘resistance’, R, in • the unit called: OHMS (Ω) We represent real electrical components with symbols …can be represented with this symbol …called a “resistor”

Basic Circuit Components • The Ground • Represents 0 volts • We use it as a ‘reference’ voltage…to measure other • voltages against it • The ‘Earth’ is at 0 volts, so we call this ground We represent real electrical components with symbols The Earth… …can be represented with this symbol …called the “ground” symbol

Building a Circuit… We wish to ‘power’ our flashlight’s light bulb… 1.5 V • We need a battery… • We need to attach the light bulb to the battery… • We use wires to connect the light bulb to the battery… Instead…let's represent the real components with their symbols

Building a Circuit… Replace the battery with a ‘DC Voltage Source’ symbol 1.5 V 1.5V creating a schematic • Replace the light bulb with a ‘Resistor’ symbol .5Ω • Mark the symbol’s values (V=, R=, etc.) Since this “node” is at GND (OV) this node must be 1.5Volts higher • Add the Ground reference 0V Instead…let's represent the real components with their symbols

Analyzing the Circuit…using Ohm’s Law Ohm’s Law (V=IR) ->Describes the relationship between the voltage (V), current (I), and resistance (R) in a circuit 1.5V • When we attach the resistor to the DC voltage source, current begins to flow • How much current will flow? .5Ω • Using Ohm’s Law, we can determine how much current is flowing through our circuit 0V

Analyzing the Circuit…using Ohm’s Law Use Ohm’s Law: V = I x R 1.5V = Ix .5 Ω Solve for I: I = 1.5V / .5 Ω = 3 Amps I = 3 Amps 1.5V • How much current will flow? .5Ω 0V So, 3 Amps will flow through the .5 Ohm resistor, when 1.5 Volts are across it

Resistors in Series 1.5V • Resistors connected by only 1 terminal, back-to-back, are considered to be in ‘series’ R1 = .5Ω • We can replace the two series resistors with 1 single resistor, we call Req • The value of Req is the SUM of R1 & R2: Req=R1+R2=.5 Ω + .5 Ω = 1Ω Req = 1Ω R2 = .5Ω 0V

Resistors in Series Use Ohm’s Law: V = I x Req 1.5V = Ix 1 Ω Solve for I: I = 1.5V / 1 Ω = 1.5 Amps I = 1.5 Amps 1.5V • Now we can find the current through the circuit using Ohm’s Law Req = 1Ω 0V The bigger the resistance in the circuit, the harder it is for current to flow

Resistors in Series I = 1.5 Amps 1.5V • Back to our original series circuit, with R1 and R2 • The current is the SAME through each resistor R1 = .5Ω • Current flows like water through the circuit, notice how the 1.5 Amp ‘stream of current’ flows through both resistors equally R2 = .5Ω • Ohm’s Law shows us voltage across each resistor: V(R1) = 1.5Amps x .5 Ω = .75V V(R2) = 1.5Amps x .5 Ω = .75V 0V

Resistors in Parallel 1.5V Req = .25 Ω • Resistors connected at 2 terminals, sharing the same node on each side, are considered to be in ‘parallel’ • Unlike before, we cannot just add them. We must add their inverses to find Req: R1 = .5Ω R2 = .5Ω 0V

Resistors in Parallel Use Ohm’s Law, we find the current through Req: V = I x Req 1.5V = Ix .25 Ω Solve for I: I = 1.5V / .25 Ω = 6 Amps I = 6 Amps 1.5V • This is the equivalent circuit Req = .25Ω 0V The small the resistance in the circuit, the easier it is for current to flow

Resistors in Parallel 1.5V • Back to our original series circuit, with R1 and R2 • The current is NOT the SAME through all parts of the circuit • Current flows like water through the circuit, notice how the 6 Amp ‘stream of current’ splits to flow into the two resistors R1 = .5Ω R2 = .5Ω • The Voltage across each resistor is equal when they are in parallel 0V

Resistors in Parallel I = 6 Amps I = 3 A I = 3 A 1.5V • The voltage is 1.5 V across each resistor • Ohm’s Law tells us the current through each: I(R1)= V / R = 1.5V / .5 Ω = 3A I(R2)= V / R = 1.5V / .5 Ω = 3A • The 6Amps of current has split down the two legs of our circuit • It split equally between the two legs, because the resistors have the same value R1 = .5Ω R2 = .5Ω 0V The current will split differently if the resistors are not equal…

In Summary… Ohm’s Law: V=IR Describes the relationship between the voltage (V), current (I), and resistance (R) in a circuit Current is equal through two resistors in series Voltage drops across each resistor Req = R1 + R2 + . . . Voltage is equal across two resistors in parallel Current splits through branches of parallel circuits 1/Req = 1/R1 + 1/R2

In Lab Today You will build series circuits Build parallel circuits Work with a breadboard Verify Ohm’s Law by measuring voltage using a multimeter And yes, there is HW!

DC Circuits Lab

DC Circuits Lab

Presentation Transcript

DC Circuits Lab

DC Circuits

DC Circuits

DC Circuits Lab

DC Circuits

DC circuits

DC Circuits

DC Circuits

DC Circuits

DC Circuits

DC Circuits

DC Circuits

DC Circuits

DC circuits

DC Circuits Lab

DC circuits

DC Circuits Lab

DC CIRCUITS:

DC Circuits Lab

DC Circuits