Lab 3 - Capacitors. Stony Brook Physics Laboratory Manuals. Equipment

Similar documents
PHY 134 Lab 3 - Capacitors

PHYSICS 122 Lab EXPERIMENT NO. 6 AC CIRCUITS

LAB 3: Capacitors & RC Circuits

( ) ( ) = q o. T 12 = τ ln 2. RC Circuits. 1 e t τ. q t

Capacitors GOAL. EQUIPMENT. CapacitorDecay.cmbl 1. Building a Capacitor

shown in Fig. 4, is initially uncharged. How much energy is stored in the two capacitors after the switch S is closed for long time?

Lab 4 CAPACITORS & RC CIRCUITS

1) Two lightbulbs, one rated 30 W at 120 V and another rated 40 W at 120 V, are arranged in two different circuits.

Experiment P43: RC Circuit (Power Amplifier, Voltage Sensor)

The RC Circuit INTRODUCTION. Part 1: Capacitor Discharging Through a Resistor. Part 2: The Series RC Circuit and the Oscilloscope

Experiment 4. RC Circuits. Observe and qualitatively describe the charging and discharging (decay) of the voltage on a capacitor.

Lab 4 RC Circuits. Name. Partner s Name. I. Introduction/Theory

Lab 10: DC RC circuits

PHY222 - Lab 7 RC Circuits: Charge Changing in Time Observing the way capacitors in RC circuits charge and discharge.

[1] (b) Fig. 1.1 shows a circuit consisting of a resistor and a capacitor of capacitance 4.5 μf. Fig. 1.1

July 11, Capacitor CBL 23. Name Date: Partners: CAPACITORS. TI-83 calculator with unit-tounit. Resistor (about 100 kω) Wavetek multimeter

Figure 1: Capacitor circuit

Lab 5 CAPACITORS & RC CIRCUITS

Induction_P1. 1. [1 mark]

On the axes of Fig. 4.1, carefully sketch a graph to show how the potential difference V across the capacitor varies with time t. Label this graph L.

Name Class Date. RC Circuit Lab

farads or 10 µf. The letter indicates the part tolerance (how close should the actual value be to the marking).

Electronics Capacitors

Lab 08 Capacitors 2. Figure 2 Series RC circuit with SPDT switch to charge and discharge capacitor.

Practical 1 RC Circuits

EXPERIMENT 5A RC Circuits

MasteringPhysics: Assignment Print View. Problem 30.50

Lab 5 - Capacitors and RC Circuits

Lab 5 - Capacitors and RC Circuits

Tactics Box 23.1 Using Kirchhoff's Loop Law

Experiment 8: Capacitance and the Oscilloscope

Physics 2135 Exam 2 March 22, 2016

The next two questions pertain to the situation described below. Consider a parallel plate capacitor with separation d:

Physics 2135 Exam 2 October 20, 2015

Simple circuits - 3 hr

How many electrons are transferred to the negative plate of the capacitor during this charging process? D (Total 1 mark)

CALIFORNIA STATE UNIVERSITY, BAKERSFIELD (CSUB) Laboratory 3

IMPORTANT Read these directions carefully:

ELECTRIC CURRENTS D R M A R T A S T A S I A K D E P A R T M E N T O F C Y T O B I O L O G Y A N D P R O T E O M I C S

Fundamentals of Circuits I: Current Models, Batteries & Bulbs

Experiment Guide for RC Circuits

Energy Conservation in Circuits Final Charge on a Capacitor. Recorder Manager Skeptic Energizer

MAGNETIC DEFLECTION. OBJECTIVE: To observe the effect of a magnetic field on an electron beam. To measure the Earth s magnetic field.

Lab 1: Background and Useful Information

PHYSICS 171 UNIVERSITY PHYSICS LAB II. Experiment 6. Transient Response of An RC Circuit

AP Physics C. Electric Circuits III.C

Chapter 26 Direct-Current Circuits

Old Dominion University Physics 112N/227N/232N Lab Manual, 13 th Edition

Kirchhoff s Rules and RC Circuits

Exam 3--PHYS 102--S14

physics 4/7/2016 Chapter 31 Lecture Chapter 31 Fundamentals of Circuits Chapter 31 Preview a strategic approach THIRD EDITION

PHY222 Lab 8 - Magnetic Fields and Right Hand Rules Magnetic forces on wires, electron beams, coils; direction of magnetic field in a coil

Figure 1. (a) An alternating current power supply provides a current that keeps switching direction.

Physics 24 Exam 2 March 18, 2014

Name: Lab Partner: Section:

first name (print) last name (print) brock id (ab17cd) (lab date)

Version 001 CIRCUITS holland (1290) 1

Switch. R 5 V Capacitor. ower upply. Voltmete. Goals. Introduction

Laboratory 7: Charging and Discharging a Capacitor Prelab

Switch. R 5 V Capacitor. ower upply. Voltmete. Goals. Introduction

3.14 mv ma. Objectives. Overview

UNIT 102-2: ELECTRIC POTENTIAL AND CAPACITANCE Approximate time two 100-minute sessions

RC Circuit (Power amplifier, Voltage Sensor)

Physics 1051 Laboratory #10 Simple DC Motor The Simple DC Motor

Lab 6: Capacitors and Resistor-Capacitor Circuits Phy208 Spr 2008 Name Section

Physics Investigation 10 Teacher Manual

Physics 6B. Practice Final Solutions

Study of Resistance Components

Physics 2135 Exam 2 October 18, 2016

RC Studies Relaxation Oscillator

Chapter 2: Capacitor And Dielectrics

RC Circuits. 1. Designing a time delay circuit. Introduction. In this lab you will explore RC circuits. Introduction

Capacitors and a Galvanometer

P114 University of Rochester NAME S. Manly Spring 2010

Laboratory Manual. Physics 166, 167, 168, 169. Lab manual, part 2 For PHY 167 and 169 students

University of TN Chattanooga Physics 1040L 8/18/2012 PHYSICS 1040L LAB LAB 4: R.C. TIME CONSTANT LAB

MAGNETIC DEFLECTION. OBJECTIVE: To observe the effect of a magnetic field on an electron beam. To measure the Earth s magnetic field.

Today s agenda: Capacitors and Capacitance. You must be able to apply the equation C=Q/V.

Physics 212. Lecture 8. Today's Concept: Capacitors. Capacitors in a circuits, Dielectrics, Energy in capacitors. Physics 212 Lecture 8, Slide 1

General Physics II Lab EM2 Capacitance and Electrostatic Energy

MASSACHUSETTS INSTITUTE OF TECHNOLOGY Department of Physics 8.02 Spring 2003 Experiment 17: RLC Circuit (modified 4/15/2003) OBJECTIVES

2005 AP PHYSICS C: ELECTRICITY AND MAGNETISM FREE-RESPONSE QUESTIONS

Energy Stored in Capacitors

LABORATORY 4 ELECTRIC CIRCUITS I. Objectives

P202 Practice Exam 2 Spring 2004 Instructor: Prof. Sinova

PHY222 Lab 10 - Magnetic Fields: Magnetic Flux and. Lenz's Law Currents induced in coils by magnets and by other coils

Physics 15b PSI Week 2: Capacitance

Switch. R 5 V Capacitor. ower upply. Voltmete. Goals. Introduction

Experiment ES Estimating a Second

Question 1. The figure shows four pairs of charged particles. For each pair, let V = 0 at infinity and consider V net at points on the x axis.

Experiment FT1: Measurement of Dielectric Constant

Laboratory 3 Measuring Capacitor Discharge with the MicroBLIP

RC Circuits. Equipment: Capstone with 850 interface, RLC circuit board, 2 voltage sensors (no alligator clips), 3 leads V C = 1

Physics 2220 Fall 2010 George Williams SECOND MIDTERM - REVIEW PROBLEMS

Experiment 4: Resistances in Circuits

iclicker A metal ball of radius R has a charge q. Charge is changed q -> - 2q. How does it s capacitance changed?

Capacitors. Chapter How capacitors work Inside a capacitor

Physics Tutorial - Currents and Circuits

Chapter 7 Direct-Current Circuits

Exercise 1: Capacitors

Transcription:

3/20/2017 Lab 3 Capacitors [Stony Brook Physics Laboratory Manuals] Stony Brook Physics Laboratory Manuals Lab 3 - Capacitors In this experiment we will determine the capacitance of an unknown capacitor by observing the change in potential difference between its plates when, after being initially charged, it is connected in parallel with a known capacitor. We will also study the behavior of capacitors connected in series. Equipment Oscilloscope (you should review what you learned about the oscilloscope in Lab 2) Unknown capacitor C1 Capacitor box to provide C2 in 1μF (one microfarad) steps between 0-10μF Double-pole double-throw (DPDT) switch test leads with banana plugs at each end alligator clips (their tube ends slide over the banana plugs their teeth grip a terminal) Dry cell with potential difference (voltage) V0 Figure 1 shows the same closeup picture of an oscilloscope you had for Lab 2. Once again, it may be the same model as the one you will use or it may be a slightly different model that looks nearly the same. It doesn't make any difference which oscilloscope you actually use during the lab. What's important is that you use it correctly. Note that the two (vertical) inputs are labeled CH1<color white/gray>x</color>. and CH2<color white/gray>y</color> in Fig. 1. Just pay attention to the label CH1, which is the channel you will be using in this experiment. Note in Fig. 1 that the 3-position lever switch to the left of the VOLTS/DIV know for CH1 is set to AC. This means AC coupling, which is what you do NOT want for this experiment. This places a capacitor (inside the oscilloscope) in series with the signal entering CH1, and this capacitor blocks the DC value, which is what you want to measure. Therefore, move the lever switch for CH1 to DC, the lowest position. Make sure the VERT MODE lever switch is on CH1 (the top-most position), just as it's shown in Fig. 1. Also make sure that the red VAR knob for CH1 (do the same for CH2, also) is full clockwise, the calibrated position as you learned in Lab 2. While you're at it, make sure the VAR SWEEP knob is also full clockwise, and make sure that the white <color white/gray>x-y</color> switch is out so that the oscilloscope is not in the XY mode of operation. (You used that mode to see the Lissajous figures in Lab 2.) Rule of thumb for using oscilloscopes: Always use DC coupling unless you have a specific reason not to! http://skipper.physics.sunysb.edu/~physlab/doku.php?id=phy134:lab3 1/6

3/20/2017 Lab 3 Capacitors [Stony Brook Physics Laboratory Manuals] Figure 2 shows two capacitor boxes. We don't have enough of one type to provide all 24 work stations in the two lab rooms with the same type. However, they're functionally equivalent so it doesn't make any difference which one you use. Each one has two banana sockets for making connections to its two plates and one knob on a rotary switch that selects the value of C2. In Fig. 2, each knob is set for 1μF (one microfarad). Figure 3 shows the unknown capacitor C1. You know it's a capacitor, but you don't know its value. That's why you're going to measure it! There are two terminals at the top with each one connected to one of the plates inside. (You can see that each terminal has two metal prongs sticking out which prong you connect to (with an alligator clip at the end of a test lead ) at a given terminal is not important.) Method In Part I, a capacitor C1 is charged to potential V0 by using a double-pole-double-throw (DPDT) switch (learn about electrical switches here) to connect one of its two ends (terminals) to one terminal of a dry cell battery and its other end (terminal) to the other terminal of the dry cell battery. This is frequently called connecting the capacitor across the dry cell. Is the resulting circuit consisting of the battery and the capacitor C1 a series circuit? Or is it a parallel circuit? http://skipper.physics.sunysb.edu/~physlab/doku.php?id=phy134:lab3 2/6

The dry cell is then disconnected, and an initially uncharged capacitor C 2 is connected (by moving the handle on the DPDT switch to the other position) to C 1 as follows: one of the two ends (terminals) of one capacitor is connected to one of the two ends (terminals) of the other capacitor, and the two other ends (terminals) are connected to each other. (Note that this makes a circuit with the shape (topology) of a ring. Is it a series circuit or a parallel circuit?) Charge will flow from C 1 to C 2 until the potential differences across the two capacitors equalize. (Why does this happen?) The voltage across the two connected capacitors (which you can think of as one equivalent capacitor C eq is given by: V = V 0 C 1 /( C 1 + C 2 ) (1) Derive Eq. (1) in your lab notebook. Rearranging Eq. (1) gives V 0 / V = C 2 / C 1 + 1 (2) C 2 is an adjustable capacitor. As C 2 is changed, the final voltage V will vary according to Eqs. (1) and (2). In Part II, a similar procedure using the double-pole-double-throw switch connects the two capacitors together. How is the connection different this time? Does this way of connecting them make a series circuit or a parallel circuit? Note that in all figures below, there is more than just capacitors and just capacitors and a battery and a DPDT switch in the electrical circuits. There is also a measuring instrument the oscilloscope! that must become part of the circuit for you to be able to measure the voltage differences that show you what's going on. Note further that some of the figures do NOT show the DPDT switch. Instead one figure shows you the circuit that's created for one position of the DPDT switch handle; a second figure shows you the circuit that's created for the other position of the DPDT switch handle. Procedure 1. Capacitors in Parallel C 1 is a fixed capacitor whose capacitance is to be measured. C 2 is a capacitance box with capacitance variable from 0 to 10 microfarads ( μf) in 1 μf steps. With the DPDT switch in position (1), C 2 is discharged and out of the circuit and C 1 is charged to the voltage of the battery V 0 and in the circuit. This voltage can be read on the oscilloscope, in the same way as the battery http://skipper.physics.sunysb.edu/~physlab/doku.php?id=phy134:lab3 3/6

voltage was measured in Lab 2. Note: you need to insert a wire in the place of the switch (2) position, depicted by the red oval in the picture above. With the DPDT switch in position (1), the battery is connected and charges C 1, see above. With the DPDT switch in position (2), the battery is disconnected, C 1 and C 2 are connected in parallel, and the voltage across the parallel combination can be read on the oscilloscope. 1. Connect the circuit as shown. 2. Move the DPDT switch to position (1) to discharge C 2 and charge C 1. Then move the DPDT switch to position (2) and record the voltage V immediately appearing on the oscilloscope. This voltage will decay to zero as time passes; its value immediately after the DPDT switch is thrown is what you must record. Repeat the measurements several times so that you can estimate the uncertainty in this voltage. Why does the voltage decay? 3. Repeat the above procedure using at least 5 other values of C 2. For each value of C 2 you should have a value of V and an estimate of the uncertainty in its value. 4. Make a plot of V 0 /V vs. C 2. Determine C 1, the unknown capacitance, from this plot by referring to Eq. (2). 2. Capacitors in Series http://skipper.physics.sunysb.edu/~physlab/doku.php?id=phy134:lab3 4/6

In this arrangement, DPDT switch in position 1, two capacitors connected in series are initially uncharged. This makes the circuit like that below. When the DPDT switch is thrown to position (2), the series combination is connected to a potential difference V 0 and the oscilloscope measures the voltage across C 1. The circuit, therefore, is as shown below. 1. Connect the circuit as shown. http://skipper.physics.sunysb.edu/~physlab/doku.php?id=phy134:lab3 5/6

μf 2. Set C 2 to 5, flip the DPDT switch from position (1) to position (2), and record the voltage V 1 appearing across C 1 immediately after switching. Repeat the measurement a few times to get a good estimate of its uncertainty. Now change the position of the oscilloscope leads so that they measure the voltage V 2 appearing across C 2 immediately after switching. (We don't show you a figure for this, but by now you shouldn't need another one!) Follow the same procedure as with C 1. 3. Derive an equation giving V 1 and V 2 as a function of C 1, C 2, and V 0. 4. Using the value for C 1 obtained in Part I, does your equation correctly predict the observed voltages? 5. In this circuit, what is the relationship between V 1, V 2, and V 0? phy134/lab3.txt Last modified: 2015/09/17 22:27 (external edit) http://skipper.physics.sunysb.edu/~physlab/doku.php?id=phy134:lab3 6/6

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback