Your omments Pretty straightforward! The analogy to spring motion really helped. Is there any false comparison with it that we should watch out for? I think I got a lot of this, the pre-lecture confused me a little bit though with the phase angle and when it called omega the oscillation frequency= 1/sqrt() and then later it called that same omega the natural frequency and gave us a different equation for the oscillation frequency Seems interesting, but my mind is on the test right now. As soon as I heard the word "damping" my mind switched to Diff Equ. I love it when the things that I learn in one class matches up to what I learn in another class :) an we please have a review session tomorrow???? Spring break took a toll on all of us and it would mean so much to the student body if you guys pushed back lecture which you guys can and do a review session. Obviously you guys want everyone to do good, this review session will help everyone so much AND I can guarantee it will improve the test average. It's just one lecture and we would love you guys for doing it. If you say no to this, post this comment so you guys can see how upset the student body will be if you choose not to. Once more plesase!!!!!!!!!!! ome on, teacher!! Give me a break!!! Oscillations just after my amazing vacation? My brain hurts ever since the oscillatory frequency started popping into and out of the screen. Electricity & Magnetism ecture 19, Slide 1
Some Exam Stuff Exam Wed. night (April nd ) at 7:00 overs material in ectures 9 18 Bring your ID: ooms determined by discussion section (see link) onflict exam at 5:15 Don t forget: Worked examples in homeworks (the optional questions) Other old exams For most people, taking old exams is most beneficial» Take them like real exam (calculator and formula sheet)» omplete full exam, then grade (harshly)» eview problems got wrong (why did you get it wrong)» epeat
The Big Ideas 9-18 Kirchoff s ules Sum of voltages around a loop is zero Sum of currents into a node is zero Kirchoff s rules with capacitors and inductors In and circuits: charge and current involve exponential functions with time constant: charging and discharging E.g. apacitors and inductors store energy Magnetic fields I Generated by electric currents (no magnetic charges) Magnetic forces only on charges in motion Easiest to calculate with Ampere s aw hanging magnetic fields can generate electric fields! FAADAY S AW F mag qvxb Bd 0 I d d E d EMF BdA mag enclosed Physics 1 ecture 19, Slide 3
Physics 1 ecture 19 Today s oncepts: A) Oscillation Frequency B) Energy ) Damping Electricity & Magnetism ecture 19, Slide 4
ircuit I di di ircuit Equation: 0 I d d d where 1 Electricity & Magnetism ecture 19, Slide 5
heckpoint 1a At time t = 0 the capacitor is fully charged with and the current through the circuit is 0. What is the potential difference across the inductor at t = 0? A) = 0 B) = / ) = / since The two elements are in parallel, so ==/ Pendulum. Electricity & Magnetism ecture 19, Slide 6
ircuits analogous to mass on spring d 1 d x x k m k a m F = -kx x Same thing if we notice that k 1 and m Electricity & Magnetism ecture 19, Slide 7
Time Dependence I Electricity & Magnetism ecture 19, Slide 8
heckpoint 1b At time t = 0 the capacitor is fully charged with and the current through the circuit is 0. What is the potential difference across the inductor at when the current is imum? A) = 0 B) = / ) = / di/ is zero when current is imum Electricity & Magnetism ecture 19, Slide 9
heckpoint 1c At time t = 0 the capacitor is fully charged with and the current through the circuit is 0. How much energy is stored in the capacitor when the current is a imum? A) U /() B) U /(4) ) U 0 Total Energy is constant! U ½ I U / I when 0 Electricity & Magnetism ecture 19, Slide 10
heckpoint a The capacitor is charged such that the top plate has a charge 0 and the bottom plate 0. At time t 0, the switch is closed and the circuit oscillates with frequency 500 radians/s. = 4 x 10-3 H = 500 rad/s What is the value of the capacitor? A) = 1 x 10-3 F B) = x 10-3 F ) = 4 x 10-3 F 1 1 1 3 10 4 3 (510 )(410 ) Electricity & Magnetism ecture 19, Slide 11
heckpoint b closed at t = 0 0 0 Which plot best represents the energy in the inductor as a function of time starting just after the switch is closed? U 1 I Energy proportional to I U cannot be negative urrent is changing U is not constant Initial current is zero Electricity & Magnetism ecture 19, Slide 1
heckpoint c When the energy stored in the capacitor reaches its imum again for the first time after t 0, how much charge is stored on the top plate of the capacitor? closed at t = 0 0 0 A) 0 B) 0 / ) 0 D) 0 / E) 0 is imum when current goes to zero d I urrent goes to zero twice during one cycle Electricity & Magnetism ecture 19, Slide 13
Add : Damping Just like circuit but energy but the oscillations get smaller because of oncept makes sense but answer looks kind of complicated Electricity & Magnetism ecture 19, Slide 14
Physics Truth #1: Even though the answer sometimes looks complicated ( t) cos( t ) o the physics under the hood is still very simple! d Electricity & Magnetism ecture 19, Slide 15
The elements of a circuit are very simple: di d I I This is all we need to know to solve for anything! Electricity & Magnetism ecture 19, Slide 16
The switch in the circuit shown has been closed for a long time. At t 0, the switch is opened. What is MAX, the imum charge on the capacitor? alculation onceptual Analysis Once switch is opened, we have an circuit urrent will oscillate with natural frequency 0 Strategic Analysis Determine initial current Determine oscillation frequency 0 Find imum charge on capacitor Electricity & Magnetism ecture 19, Slide 18
alculation The switch in the circuit shown has been closed for a long time. At t = 0, the switch is opened. I What is I, the current in the inductor, immediately after the switch is opened? Take positive direction as shown. A) I < 0 B) I 0 ) I > 0 urrent through inductor immediately after switch is opened is the same as the current through inductor immediately before switch is opened before switch is opened: all current goes through inductor in direction shown Electricity & Magnetism ecture 19, Slide 19
alculation The switch in the circuit shown has been closed for a long time. At t = 0, the switch is opened. I 0 I (t 0 ) > 0 The energy stored in the capacitor immediately after the switch is opened is zero. A) TUE B) FASE before switch is opened: di / ~ 0 0 BUT: since they are in parallel 0 after switch is opened: cannot change abruptly 0 U ½ 0! IMPOTANT: NOTE DIFFEENT ONSTAINTS AFTE SWITH OPENED UENT through INDUTO cannot change abruptly OTAGE across APAITO cannot change abruptly Electricity & Magnetism ecture 19, Slide 0
alculation The switch in the circuit shown has been closed for a long time. At t = 0, the switch is opened. I I (t 0 ) > 0 (t 0 ) 0 What is the direction of the current immediately after the switch is opened? A) clockwise B) counterclockwise urrent through inductor immediately after switch is opened is the same as the current through inductor immediately before switch is opened Before switch is opened: urrent moves down through After switch is opened: urrent continues to move down through Electricity & Magnetism ecture 19, Slide 1
alculation The switch in the circuit shown has been closed for a long time. At t = 0, the switch is opened. I (t 0 ) > 0 (t 0 ) 0 What is the magnitude of the current right after the switch is opened? A) I o B) I o ) I D) o I o urrent through inductor immediately after switch is opened is the same as the current through inductor immediately before switch is opened Before switch is opened: I I 0 0 I I Electricity & Magnetism ecture 19, Slide
alculation The switch in the circuit shown has been closed for a long time. At t = 0, the switch is opened. Hint: Energy is conserved I (t 0 ) / (t 0 ) 0 I What is, the imum charge on the capacitor during the oscillations? 1 A) B) ) D) I When I is (and is 0) 1 U I When is (and I is 0) 1 U 1 I I 1 Electricity & Magnetism ecture 19, Slide 3
Follow-Up The switch in the circuit shown has been closed for a long time. At t = 0, the switch is opened. I Is it possible for the imum voltage on the capacitor to be greater than? A) YES B) NO I / can be greater than IF: > We can rewrite this condition in terms of the resonant frequency: 0 > O 1 0 > We will see these forms again when we study A circuits! Electricity & Magnetism ecture 19, Slide 4