EXPERIMENT NUMBER 8 CAPACITOR CURRENT-VOLTAGE RELATIONSHIP



Similar documents
EXPERIMENT NUMBER 5 BASIC OSCILLOSCOPE OPERATIONS

RC Circuits and The Oscilloscope Physics Lab X

RC & RL Transient Response

ε: Voltage output of Signal Generator (also called the Source voltage or Applied

AC CIRCUITS - CAPACITORS AND INDUCTORS

Step Response of RC Circuits

Electrical Resonance

MATERIALS. Multisim screen shots sent to TA.

EE 1202 Experiment #4 Capacitors, Inductors, and Transient Circuits

DIODE CIRCUITS LABORATORY. Fig. 8.1a Fig 8.1b

Experiment #11: LRC Circuit (Power Amplifier, Voltage Sensor)

EDEXCEL NATIONAL CERTIFICATE/DIPLOMA UNIT 5 - ELECTRICAL AND ELECTRONIC PRINCIPLES NQF LEVEL 3 OUTCOME 4 - ALTERNATING CURRENT

The Time Constant of an RC Circuit

Oscilloscope, Function Generator, and Voltage Division

Inductors in AC Circuits

1. Oscilloscope is basically a graph-displaying device-it draws a graph of an electrical signal.

AC Measurements Using the Oscilloscope and Multimeter by Mr. David Fritz

Lab E1: Introduction to Circuits

= V peak 2 = 0.707V peak

Lab 1: The Digital Oscilloscope

Experiment 2 Diode Applications: Rectifiers

Step response of an RLC series circuit

Lab 5 Operational Amplifiers

SERIES-PARALLEL DC CIRCUITS

Lab 3 Rectifier Circuits

Operational Amplifier - IC 741

PHYSICS LAB #2 Passive Low-pass and High-pass Filter Circuits and Integrator and Differentiator Circuits

Lab #4 Thevenin s Theorem

LABORATORY 10 TIME AVERAGES, RMS VALUES AND THE BRIDGE RECTIFIER. Bridge Rectifier

Reading assignment: All students should read the Appendix about using oscilloscopes.

LAB 7 MOSFET CHARACTERISTICS AND APPLICATIONS

Beginners Guide to the TDS 210 and TDS 220 Oscilloscopes

ANALYTICAL METHODS FOR ENGINEERS

Fundamentals of Signature Analysis

Basic Op Amp Circuits

Lab #9: AC Steady State Analysis

CIRCUITS LABORATORY EXPERIMENT 3. AC Circuit Analysis

Frequency Response of Filters

INTERFERENCE OF SOUND WAVES

Electronic WorkBench tutorial

RLC Series Resonance

Op-Amp Simulation EE/CS 5720/6720. Read Chapter 5 in Johns & Martin before you begin this assignment.

ANADOLU UNIVERSITY DEPARTMENT OF ELECTRICAL AND ELECTRONICS ENGINEERING

LM 358 Op Amp. If you have small signals and need a more useful reading we could amplify it using the op amp, this is commonly used in sensors.

Q1. The graph below shows how a sinusoidal alternating voltage varies with time when connected across a resistor, R.

Using an Oscilloscope

Lecture - 4 Diode Rectifier Circuits

Properties of electrical signals

The 2N3393 Bipolar Junction Transistor

PHASOR DIAGRAMS HANDS-ON RELAY SCHOOL WSU PULLMAN, WA. RON ALEXANDER - BPA

EXPERIMENT 3: TTL AND CMOS CHARACTERISTICS

Constructing a precision SWR meter and antenna analyzer. Mike Brink HNF, Design Technologist.

Basic oscilloscope operation

First Order Circuits. EENG223 Circuit Theory I

INTERFERENCE OF SOUND WAVES

Pulse Width Modulation (PWM) LED Dimmer Circuit. Using a 555 Timer Chip

Electricity & Electronics 5: Alternating Current and Voltage

More Op-Amp Circuits; Temperature Sensing

Operational Amplifier as mono stable multi vibrator

ES250: Electrical Science. HW7: Energy Storage Elements

ENGINEERING COMMITTEE Interface Practices Subcommittee AMERICAN NATIONAL STANDARD ANSI/SCTE Test Method for AC to DC Power Supplies

Transistor Amplifiers

Measurement of Capacitance

Precision Diode Rectifiers

Unit2: Resistor/Capacitor-Filters

Episode 126: Capacitance and the equation C =Q/V

Positive Feedback and Oscillators

ELECTRON SPIN RESONANCE Last Revised: July 2007

Bipolar Transistor Amplifiers

See Horenstein 4.3 and 4.4

E. K. A. ADVANCED PHYSICS LABORATORY PHYSICS 3081, 4051 NUCLEAR MAGNETIC RESONANCE

Analog and Digital Signals, Time and Frequency Representation of Signals

Measuring Impedance and Frequency Response of Guitar Pickups

Instruction Manual and Experiment Guide for the PASCO scientific Model WA-9307A D 6/94 FOURIER SYNTHESIZER PASCO scientific $7.

2.6. In-Laboratory Session QICii Modelling Module. Modelling Module Description

Lecture 18: Common Emitter Amplifier. Maximum Efficiency of Class A Amplifiers. Transformer Coupled Loads.

COMMON-SOURCE JFET AMPLIFIER

User s Guide DDS-3X25 USB ARBITRARY FUNCTION GENERATOR

Laboratory Manual and Supplementary Notes. CoE 494: Communication Laboratory. Version 1.2

Experiment 8 : Pulse Width Modulation

PCM Encoding and Decoding:

Reading: HH Sections , (pgs , )

WHY DIFFERENTIAL? instruments connected to the circuit under test and results in V COMMON.

Lock - in Amplifier and Applications

Experiment1: Introduction to laboratory equipment and basic components.

Electronics. Basic Concepts. Yrd. Doç. Dr. Aytaç GÖREN Yrd. Doç. Dr. Levent ÇETİN

The D.C Power Supply

Tutorial 2: Using Excel in Data Analysis

Maximum value. resistance. 1. Connect the Current Probe to Channel 1 and the Differential Voltage Probe to Channel 2 of the interface.

Rectifier circuits & DC power supplies

Homework Assignment 03

Annex: VISIR Remote Laboratory

Experiment: Series and Parallel Circuits

Transistor Characteristics and Single Transistor Amplifier Sept. 8, 1997

Output Ripple and Noise Measurement Methods for Ericsson Power Modules

Basic Electrical Technology Dr. L. Umanand Department of Electrical Engineering Indian Institute of Science, Bangalore. Lecture phase System 4

Content Map For Career & Technology

Circuits with inductors and alternating currents. Chapter 20 #45, 46, 47, 49

Experiment 3: Double Sideband Modulation (DSB)

Transcription:

1 EXPERIMENT NUMBER 8 CAPACITOR CURRENT-VOLTAGE RELATIONSHIP Purpose: To demonstrate the relationship between the voltage and current of a capacitor. Theory: A capacitor is a linear circuit element whose voltage and current are related by a differential equation. For a capacitor, the relationship between current and voltage is [1]: i v(t) it ()= C dv In order to experimentally determine the current, a series resistor, R, must be added to the circuit. Also, the function generator resistance, R g (its Thévenin equivalent resistance), contributes additional resistance to the circuit. The entire resistancecapacitance circuit is: i v g R g R s C v where v g is the Thévenin equivalent voltage of the function generator. The first order differential equation relating the voltage across the capacitor, v, to the source voltage, v g, is: v g = ( R g R s )i v = Ri v = RC dv where R = R g R s. Thus, dv v RC = v g RC v, since i = C dv The complete solution for v consists of two parts,

2 v = v n v p, where v n is the natural response (complementary response) and v p is the particular response. The natural response, v n, is the response that occurs when the forcing term, v g, is zero, dv n v n RC = 0 v n = Ae t RC, where A is an arbitrary constant of integration. The particular response depends on v g. In this experiment, we will consider v g that is a square wave signal. Suppose v g has been V m for a long time and is suddenly switched from V m to V m, V m V m t For convenience, assume the switching occurs at time, t, equal to zero. It can be shown that the particular response is, v p = V m. So, the complete solution for t > 0 is v = Ae t RC V m The constant, A, can be determined by considering what happens to the capacitor voltage, v, when v g changes from V m to V m. Just prior to the voltage change in v g, v( 0 ) =V m. Since the voltage across a capacitance cannot change instantaneously, this is also the voltage the instant after the change in v g, v 0 v 0 ()=V m = A V m. So, the complete solution is ( ) = V m. So,

3 v =2V m e t RC V m. The general shape of the response of the capacitor voltage is, V m v.632(2v m ) RC t -V m At the time equal to RC (which is called the time constant), the exponent has a value of - 1. So, the value of the response at this point is, vt= ( RC) = 2V m e 1 V m =2V m ( 0.368) V m =2V m ( 0.368) V m V m V m =V m 2V m ( 1 0.368) =V m 2V m ( 0.632) Therefore, at a time equal to the time constant, RC, the capacitor voltage, v, has made 0.632, or 63.2% of the total change. Experimental Procedure: NOTE: Read through the calculations section prior to beginning the experimental procedure. 1. Connect the oscilloscope directly to the signal generator. Use DC coupling throughout this experiment. Set up the signal generator to produce a 1 khz, 5v. p- p, square wave with 0 DC offset as measured on the oscilloscope. 2. Connect the circuit as shown. Display both channels (1 and 2) at 2 V/div. Use the math menu to display a third trace that is equal to channel 1 minus channel 2. You may wish to move traces 1 and 2 vertically so that they do not overlap.

4 v g R g a i v R s = 100 Ω Oscilloscope Channel 1 C = 0.01 µ f b Function Generator Oscilloscope Channel 2 Figure 2. 1. Turn off the math button. Set the time base to 200 usec/div. Change the signal generator to produce a sine wave but leave the amplitude, offset, frequency, etc. controls alone. Center both traces vertically so that the ground symbol for each trace lines up with the centerline on the oscilloscope. Temporarily turn off channel 2 and measure the Peak-peak, Average, and Period for the waveform on Channel 1. Please use the quick measure menu to do this because this menu will cause the measurements to be displayed on the screen. Save this screen and include it in your report. Now turn off Channel 1 and turn on Channel 2. Measure the same three quantities for Channel 2, save the screen, and include it in your report. Finally display both channels simultaneously and use quick measure to determine the phase difference between channels 1 and 2. Save this screen and include it in your report. You will need some of these measured values and recorded traces for calculations described in the next section. 2. Change the signal generator to produce a triangle wave and repeat all of the measurements you made in part 3. Save both screens (one screen for channel 1 and one screen for channel 2) including the displayed measurements of peakpeak, average and include them in your report. You do not need to save the screen for the phase measurement in the triangular waveform case. You will need some of these measured values and recorded traces for calculations described in the next section. 3. Change the signal generator back to "square wave". Adjust the signal generator's amplitude so that the waveform across the capacitor (channel 1) is 10 Volts peak to peak with 0 DC offset. The waveform across the capacitor should look like a square wave with rounded corners. Notice how the rounded corners in channel 1 line up with the current spikes (corresponding to voltage spikes across the resistor) on channel 2. Now turn off channel 2 so that you are only looking at the capacitor voltage waveform. Set the horizontal sweep, vertical amplification, and horizontal position to make the transition from -5 Volts to 5 volts (approximately) fill as much of the screen as possible. Using the cursors, determine the time constant (as described in the theory section which you studied carefully before coming to lab, right?) You will need this time constant to perform some of the calculations required in the next section. 4. Display both channels 1 and 2 at 5 V/div with a horizontal setting of 100 usec/div. Turn off channel 1 and display channel 2 at the smallest number of volts/div and the smallest number of usec/division that will allow you to see both the positive

5 and negative spikes filling up as much of the screen as possible. You may have to adjust the horizontal position to get both spikes displayed at the same time. Save this screen as you will need the waveform to perform calculations described in the next section. 5. Using an LCR meter, measure the actual values of the capacitance, C, and series resistance, R s. Calculations: 1. In part 2 of the experimental procedure, the voltage across the capacitor was a sinusoidal signal. a) Did the current of the capacitor lead or lag the voltage (that is, was the current waveform ahead of or behind the voltage waveform in time)? b) What is the phase difference (in degrees) between the voltage and the current? c) Using the actual capacitance value, calculate the (peak-to-peak) value of the current that would be expected for the observed voltage across the capacitor. Compare this value with the peak-to-peak current observed experimentally. 2. In part 3 of the experimental procedure, the voltage across the capacitor was a triangular waveform. a) Using the actual capacitance value, calculate the theoretical capacitor current corresponding to the positive and negative slopes of the triangular waveform. b) Do these currents agree with the values experimentally observed? If not, why not? 3. In part 4 of the experimental procedure, the signal generator produced a square wave voltage. However, because of the large currents that occur immediately after the voltage transition of the voltage generator, the voltage of the capacitor differed from a true square waveform. In the theory section of this experiment, it was shown that the voltage transitions for the capacitor were exponentially dependent on time. a) What was the effective time constant, RC, of the circuit? b) Using the time constant and the actual capacitance value, what was the overall resistance of the circuit? c) Is this the value of resistance one would expect? Why? 4. In part 5 of the experimental procedure, the current pulse associated with the voltage transition for a v g with a square waveform was observed and sketched. The voltage across a capacitor depends on the charge, q, resting on the plates,

6 q = Cv. If the voltage changes by a certain amount, v, the charge must also change accordingly, q = C v. The change in charge is equal to the integral of the current of the capacitor over the interval corresponding to the voltage change, q = i References: For the square waveform voltage, the overall change was 10 volts. Therefore, the area under the current pulse should be 10C, where C is the capacitance. a) Using graphical integration, determine the area under the experimentally observed current pulse, in coulombs. b) Compare the value calculated in (a) with the expected value, based on the actual capacitance and the actual voltage change. Explain any discrepancies. 1. D.R. Cunningham and J.A. Stuller, Circuit Analysis, 2nd ed., Houghton Mifflin, Boston, 1995, p. 40.

2026 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information