MASSACHUSETTS INSTITUTE OF TECHNOLOGY Department of Physics 8.02 Spring 2005 Experiment 10: LR and Undriven LRC Circuits OBJECTIVES 1. To determine the inductance L and internal resistance RLof a coil, both with and without an iron core, on the AC/DC Electronics Lab circuit board. 2. To observe electrical oscillations, measure their frequencies, and verify energy relationships in an LRC circuit. INTRODUCTION (Note: For these lab instructions, and most other uses, the terms “RLC” and “LRC” are entirely interchangeable. The other four permutations are not as popular.) Free Oscillations in LR and RLC circuits (For purposes of clarity, these experiment instructions will use lower-case letters, qt(() and it ) to denote time-varying circuit quantities.) Consider a series RLC circuit shown in Figure 15.1. Figure 15.1 RLC Circuit with external voltage removed Applying the Kirchhoff’s voltage rule, the circuit equation for the RLC circuit without any external voltage is 2d q dq0 = L + q (10.1)dt 2 + Rdt C . E10-1In this experiment, the internal resistance RLof the inductor is the only resistance. In such cases, when the resistance and inductance are “lumped,” a circuit diagram similar to Figure 1 is used for clarity; for our purposes, will use the “total resistance” RT = RL . For the situation where the capacitance is not part of the circuit, the current in an LR circuit is derived in the 8.02 Course Notes, Section 11.4, and given in Equations (11.4.7) and (11.4.13); () = E (1−e−t /τ)it RT for an increasing current and it() = E e−t /τ ,RT /for a decreasing current, where the time constant is τ= LR .TFor a circuit with capacitance, with appropriately small resistance (“underdamped”), the current can be represented as −γtit )= I e cos ωt( 0 RTwhere γ= RT/ 2L , ω2= 1 −2 (see the 8.02 Course Notes, Section 11.6 for a derivation). ALC 4L2 plot of () for a typical underdamped circuit is shown in Figure 1. itFigure 1 Exponential decay of current oscillations in a typical RLC circuit Since the coefficient of exponential decay, γ= RT2L , is proportional to the resistance, we see that the current will fall off more rapidly as the resistance increases. E10-2Energy Relationships in RLC circuits As the current oscillates in such circuits, energy may be stored in both the magnetic field of the inductor UB =1 L i 2 (10.2)2 and in the electric field of the capacitor 1UE = CVC 2 =1 q2 . (10.3)2 2 C The energy stored in the electric and magnetic fields is simply the sum: 12U = L i 2 +1 C VC (10.4)2 2 2However, this energy is gradually being lost as heat in the resistor at the rate iRT. Over one period of oscillation T, the dissipated energy is 2∆U =−(U t (() −U t = 0))=∫Ti RT dt . (10.5)0 EXPERIMENTAL SETUP A. Computer If it is not done already, connect the Science Workshop 750 Interface to the computer using the SCSI cable. Connect the power supply to the 750 Interface and turn on the interface power. Always turn on the interface before powering up the computer. Turn on your computer. B. AC/DC Electronics Lab circuit board Connect the black banana plug cord from the OUTPUT ground port of the 750 Interface to the banana jack located in the lower right corner on the AC/DC Electronics Lab circuit board. Connect the red banana jack with alligator clip to the positive OUTPUT port of the 750 Interface. In a later part of the experiment, you will also connect the Voltage Sensor to measure the capacitor voltage. For this experiment, in which all of the circuit elements are in series, you will be able to measure and record the Output Current from the 750, so the Current Sensor is not part of this experiment. E10-3MEASUREMENTS Part 1. Resistance and Inductance of the Coil Resistance: Circuit Diagram: Connect the red alligator clip to the right side of your coil. Using a wire, connect the left side of your coil to the banana jack that is connected to the OUTPUT ground port (black) of the 750 Interface (see Figure 2). Figure 2 Circuit diagram for measuring the resistance of the coil DataStudio File: Download and open the Data Studio file exp10.ds. There are more display windows than usual for this experiment; you’ll want to minimize or display the windows as you choose. Resize the windows as desired. Not all windows are needed for all parts. If the following settings have not been made, you will have to change them: The Signal Generator should be set to a Positive Square Wave with a frequency of 20 Hz and amplitude of 1 volt . The Sample Rate should be 10000 Hz . • A graph has been set up to display the Signal Generator Voltage and Output Current. • Click Start. The Output Current graph displays the familiar behavior of an LR circuit (see Figure 3). The maximum voltage and maximum current are recorded internally, and their ratio is given in a Coil Resistance display window. Figure 3 Exponential decay of current in LR circuit E10-4Question 1: Record the resistance R of your coil on the tearoff sheet.LInductance (with and without an iron core) DATA ANALYSIS When the Positive Square Wave voltage switches to 0 volts , the total resistance is RT =RL . The current in the circuit decays exponentially and is given by /it 0 (LRT)t() = i e− , (10.6) / Rwhere i0 = ET is the current in the inductor at the time when the voltage drops to zero. Taking the natural logarithm of both sides of the above equation gives ln(i) =−(R L t + ln(i ) , (10.7)T ) 0 which means that a graph of ln(i) vs. t has a slope equal to −(R L).TA display window which shows the logarithm of the current as a function of time is part of the DataStudio activity. • Bring up this window and identify the part of the plot that is linear. Bring up the Coil Inductance window. • Use the Zoom Select tool (fourth button from the left) to analyze the linear part of the logarithm plot and then select Linear Fit from the Fit menu option (this may already be done). Move the boundary of the selected region until the best-fit line matches the data as well as possible The slope of this fit line is determined by DataStudio and the calculation of the inductance, using the value of RT calculated by DataStudio, is done internally and displayed in the Coil Inductance window. You should see that as you vary the selected data, the displayed calculated value of the inductance changes. When this value changes only slightly as you change the selected data, you will have
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