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Download Lab Briefing #2, Resistor Circuits - The University of Texas at Dallas
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Transcript
Th U The University i it off T Texas att D Dallas ll Erik Jonsson School of Engineering g g and Computer Science DC Resistor Circuits • Lab 2 deals with resistor circuits that have both DC and AC applied voltages. voltages • In solving electrical engineering problems, we usually have a circuit with applied voltages and we seek to discover the currents in the circuit (sometimes we have an applied current and we are solving for voltages, but not in thiss eexercise). e c se). • We will need to use three basic electrical engineering formulas today: Ohm’s Law, and Kirchoff’s Voltage and C Current tL Laws. 1 EE 1202 Lab Briefing #2 © N. B. Dodge 09/10 Th U The University i it off T Texas att D Dallas ll Erik Jonsson School of Engineering g g and Computer Science Circuit Symbols • • • • • • 2 Resistor DC battery or voltage source Capacitor p Polarized capacitor Inductor Signal generator EE 1202 Lab Briefing #2 © N. B. Dodge 09/10 Th U The University i it off T Texas att D Dallas ll Erik Jonsson School of Engineering g g and Computer Science Notational Conventions • Three notational conventions in electrical engineering: – Current flows from the positive side of a DC source to the negative side. A relic of early circuit theory before we understood that electrons, not positive charges, move. – A voltage drop (e.g., as through a resistor due to current flow) is considered positive. This is simply a convention. – A voltage rise (as that through a battery from the negative side to the positive) is negative. Also simply a convention. – Node: A point at which two or more circuit elements are connected together. – Most ggenerally, y, current entering g a node is labeled negative; g ; current leaving a node is labeled positive. Another convention. 3 EE 1202 Lab Briefing #2 © N. B. Dodge 09/10 Th U The University i it off T Texas att D Dallas ll Erik Jonsson School of Engineering g g and Computer Science Ohm’s Law • Ohm’s Law: The voltage across a resistor i is i equal to the current in the resistor times the resistance,, voltage g in Volts,, current in Amperes, resistance in Ohms: V=I·R + ‒ + I V R ‒ • Note: Amperes x Ohms = Volts 4 EE 1202 Lab Briefing #2 © N. B. Dodge 09/10 Erik Jonsson School of Engineering g g and Computer Science Th U The University i it off T Texas att D Dallas ll Analogy of Water Flow and Pressure Pressure Water Flow Current Flow ˗ + Voltage • 5 DC current flow is analogous to water flow in a pipe: – Pressure is similar voltage, g forcingg movement of water as voltage forces current flow in a conductor. – Pipe diameter is analogous to resistance; a smaller pipe diameter reduces water flow for a g given p pressure, jjust as a smaller conductance (larger resistance) reduces current flow. EE 1202 Lab Briefing #2 © N. B. Dodge 09/10 Th U The University i it off T Texas att D Dallas ll Erik Jonsson School of Engineering g g and Computer Science + ‒ + ‒ ‒ 6 EE 1202 Lab Briefing #2 ‒ I + + • KVL: The net voltage around a closed loop circuit is zero. • Another wayy to state this is that the voltage rises (sources) in a closed loop equal the voltage drops (caused by resistors). ‒ + Kirchoff’s Loop Voltage Law © N. B. Dodge 09/10 Th U The University i it off T Texas att D Dallas ll Erik Jonsson School of Engineering g g and Computer Science Kirchoff’s Node Current Law • KCL: The algebraic sum of currents in any node is zero. • Another way to say this is that the sum of currents entering the node is equal too thee sum su oof cu currents e s leaving the node. • Or: ‒I1 ‒ I2 + I3 + I4 = 0 7 EE 1202 Lab Briefing #2 ‒I2 ‒I1 +I3 +I4 © N. B. Dodge 09/10 Th U The University i it off T Texas att D Dallas ll Erik Jonsson School of Engineering g g and Computer Science AC Resistor Circuits • Resistor circuits with an applied AC voltage obey the same three laws as DC circuits. • Your AC circuits will be identical to the DC resistor es s o ccircuits cu s eexcept cep for replacing the DC power source with an AC signal generator. generator 8 ‒I1 ‒I2 +I3 +I4 V IR V=IR EE 1202 Lab Briefing #2 ΣIN =0 ΣVL =0 © N. B. Dodge 09/10 Th U The University i it off T Texas att D Dallas ll Erik Jonsson School of Engineering g g and Computer Science Measurement of AC Voltage g • We will be applying a sinusoidal AC voltage to a resistor, i that is i a voltage of the form v ( t ) V P cos( t ) , where VP is the maximum AC amplitude. • You will be able to see this sinusoidal waveform on the oscilloscope that you will use. • You will also use a digital multimeter (“DMM”) to measure the AC sinusoidal voltage. However, the DMM measures a constant value for this time-varying g Q Question: What does the DMM measure? voltage. 9 EE 1202 Lab Briefing #2 © N. B. Dodge 09/10 Th U The University i it off T Texas att D Dallas ll Erik Jonsson School of Engineering g g and Computer Science Measurement of AC Voltage (2) • The DMM measures “effective” AC voltage, the “RMS” ((root-mean-square) q ) AC voltage, g , which is equivalent q to a DC voltage in terms of delivering power to the circuit. • For the sinusoidal voltage v ( t ) V P cos( t ) discussed above, b th the peak k voltage lt iis clearly l l VP . The Th peak-to-peak kt k voltage swing, which you will see on the oscilloscope, is VPP (= 2 VP). Skipping a calculus derivation, the RMS value of any sinusoidal voltage is VP / 2, or VPP / (2 2). • We will use this definition of the RMS voltage in Experiment 5 as well. well 10 EE 1202 Lab Briefing #2 © N. B. Dodge 09/10 Th U The University i it off T Texas att D Dallas ll Erik Jonsson School of Engineering g g and Computer Science Instruments: DC Power Supply 11 EE 1202 Lab Briefing #2 © N. B. Dodge 09/10 Th U The University i it off T Texas att D Dallas ll Erik Jonsson School of Engineering g g and Computer Science Signal g Generator 12 EE 1202 Lab Briefing #2 © N. B. Dodge 09/10 Th U The University i it off T Texas att D Dallas ll Erik Jonsson School of Engineering g g and Computer Science Digital g Multimeter 13 EE 1202 Lab Briefing #2 © N. B. Dodge 09/10 Th U The University i it off T Texas att D Dallas ll Erik Jonsson School of Engineering g g and Computer Science Oscilloscope p 14 EE 1202 Lab Briefing #2 © N. B. Dodge 09/10 Th U The University i it off T Texas att D Dallas ll Erik Jonsson School of Engineering g g and Computer Science Circuit Prototyping yp g Board 15 EE 1202 Lab Briefing #2 © N. B. Dodge 09/10 Th U The University i it off T Texas att D Dallas ll Erik Jonsson School of Engineering g g and Computer Science Connectingg Leads BNC‐to‐Hook End Connecting Leads “Banana Plug” Connecting Leads BNC Cable g p g BNC Cable with Alligator Clip Leads. Alligator clips may also be attached to banana plug cables. 16 EE 1202 Lab Briefing #2 © N. B. Dodge 09/10 Th U The University i it off T Texas att D Dallas ll Erik Jonsson School of Engineering g g and Computer Science Oscilloscope p Probe BNC connector (goes into oscilloscope signal input) signal input). Ground end of probe. 1X/10X Switch 17 EE 1202 Lab Briefing #2 “Hook” end of probe. © N. B. Dodge 09/10
