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Physics 121: Electricity & Magnetism – Lecture 13 E-M Oscillations and AC Current Dale E. Gary Wenda Cao NJIT Physics Department Electromagnetic Oscillations 2 q 1 2 UUB E 2Li 2 C December 5, 2007 Oscillating Quantities We will write oscillating quantities with a lower-case symbol, and the corresponding amplitude of the oscillation with upper case. Oscillating Quantity Amplitude Voltage v V Current i I Charge q Q Examples: q Q cos(t ) q2 Q2 cos 2 (t ) 2C 2C di d cos(t ) I dt dt December 5, 2007 Derivation of Oscillation Frequency We have shown qualitatively that LC circuits act like an oscillator. We can discover the frequency of oscillation by looking at the equations governing the total energy. q2 1 2 U UE UB Li 2C 2 Since the total energy is constant, the time derivative should be zero: dU q dq di Li 0 dt C dt dt dq di d 2 q d 2q q i 2 , so making these substitutions: L 2 0 But and dt dt dt dt C This is a second-order, homogeneous differential equation, whose solution is q Q cos(t ) i.e. the charge varies according to a cosine wave with amplitude Q and 2 frequency . Check by taking dq d q Q sin( t ) Q 2 cos(t ) 2 two time derivatives of charge: dt dt Plug into original equation: 1 1 d 2q q Q 2 2 L 0 L 2 LQ cos(t ) cos(t ) 0 LC C dt C C December 5, 2007 Which Current is Greatest? 1. The expressions below give the charge on a capacitor in an LC circuit. Choose the one that will have the greatest maximum current? A. q = 2 cos 4t q = 2 cos(4t+p/2) q = 2 sin t q = 4 cos 4t q = 2 sin 5t B. C. D. E. December 5, 2007 Time to Discharge Capacitor 2. The three circuits below have identical inductors and capacitors. Rank the circuits according to the time taken to fully discharge the capacitor during an oscillation, greatest first. A. I, II, III. II, I, III. III, I, II. III, II, I. II, III, I. B. C. D. E. I. II. III. December 5, 2007 Charge, Current & Energy Oscillations 2 d The solution to the equation L q q 0 is q Q cos(t ) , which dt 2 C gives the charge oscillation. From this, we can determine the corresponding oscillation of current: dq i Q sin( t ) dt 1 2 1 q2 Q2 2 2 2 And energy UE cos 2 (t ) U B Li LQ sin (t ) 2 2 2C 2C Q2 But recall that 1 , so . UB sin 2 (t ) LC 2C That is why our graph for the energy oscillation had the same amplitude for both UE and UB. Note that Q2 Q2 2 2 UE UB [cos (t ) sin (t )] 2C 2C Constant December 5, 2007 Damped Oscillations Recall that all circuits have at least a little bit of resistance. In this general case, we really have an RLC circuit, where the oscillations get smaller with time. They are said to be “damped oscillations.” Then the power equation becomes dU q dq di Li i 2 R dt C dt dt Power lost due to resistive heating dq di d 2 q 2 As before, substituting i and dt dt dt gives the differential equation for q 2 L d q dq q R 0 2 dt dt C Solution: e Rt / 2 L Damped Oscillations q Qe Rt / 2 L cos(t ) 2 ( R / 2 L) 2 December 5, 2007 Resonant Frequency 3. How does the resonant frequency for an ideal LC circuit (no resistance) compare with ’ for a non-ideal one where resistance cannot be ignored? A. The resonant frequency for the non-ideal circuit is higher than for the ideal one (’ > ). The resonant frequency for the non-ideal circuit is lower than for the ideal one (’ < ). The resistance in the circuit does not affect the resonant frequency—they are the same (’ = ). B. C. December 5, 2007 Alternating Current The electric power out of a home or office power socket is in the form of alternating current (AC), as opposed to the direct current (DC) of a battery. Alternating current is used because it is easier to transport, and easier to “transform” from one voltage to another using a transformer. In the U.S., the frequency of oscillation of AC is 60 Hz. In most other countries it is 50 Hz. The figure at right shows one way to make an alternating current by rotating a coil of wire in a magnetic field. The slip rings and brushes allow the coil to rotate without twisting the connecting wires. Such a device is called a generator. It takes power to rotate the coil, but that power can come from moving water (a water turbine), or air (windmill), or a m sin d t i I sin( d t ) gasoline motor (as in your car), or steam (as in a nuclear power plant). December 5, 2007 RLC Circuits with AC Power When an RLC circuit is driven with an AC power source, the “driving” frequency d is the frequency of the power source, while the circuit can have a different “resonant” frequency 1 / LC ( R / 2 L) 2 . Let’s look at three different circuits driven by an AC EMF. The device connected to the EMF is called the “load.” What we are interested in is how the voltage oscillations across the load relate to the current oscillations. We will find that the “phase” relationships change, depending on the type of load (resistive, capacitive, or inductive). December 5, 2007 A Resistive Load Phasor Diagram: shows the instantaneous phase of either voltage or current. For a resistor, the current follows the voltage, so the voltage and current are in phase ( 0). If vR VR sin d t Then iR I R sin d t VR sin d t R December 5, 2007 Power in a Resistive Circuit 4. A. B. C. D. E. The plot below shows the current and voltage oscillations in a purely resistive circuit. Below that are four curves. Which color curve best represents the power dissipated in the resistor? The green curve (straight line). The blue curve. The black curve. The red curve. PR None are correct. t December 5, 2007 A Capacitive Load For a capacitive load, the voltage across the capacitor is proportional to the charge q Q vC sin d t C C But the current is the time derivative of the charge dq iC d CVC cos d t dt In analogy to the resistance, which is the proportionality constant between current and voltage, we define the “capacitive reactance” as 1 XC d C VC So that iC cos d t . XC The phase relationship is that 90º, and current leads voltage. December 5, 2007 An Inductive Load For an inductive load, the voltage across the inductor is proportional to the time derivative of the current di vL L L dt But the current is the time derivative of the charge VL VL cos d t iL sin d t dt L d L Again in analogy to the resistance, which is the proportionality constant between current and voltage, we define the “inductive reactance” as X L d L So that iL The phase relationship is that 90º, and current lags voltage. VL cos d .t XL December 5, 2007 Units of Reactance XC 1 d C 5. We just learned that capacitive reactance is and X L . What inductive reactance is are the units of dL reactance? A. Seconds per coulomb. Henry-seconds. Ohms. Volts per Amp. The two reactances have different units. B. C. D. E. December 5, 2007 Summary Table Circuit Element Symbol Resistance or Reactance Phase of Current Phase Constant Amplitude Relation Resistor R R In phase with vR 0º (0 rad) VR=IRR Capacitor C XC=1/dC Leads vR by 90º 90º (p/2) VC=ICXC Inductor L XL=dL Lags vR by 90º 90º (p/2) VL=ILXL December 5, 2007 Summary Energy in inductor: U B q2 1 2 LC circuits: total electric + magnetic energy is conserved U U E U B Li 2C 2 LC circuit: Charge equation Current equation Oscillation frequency q Q cos(t ) 1 2 Li Energy in magnetic field 2 i Q sin( t ) 1 LC LRC circuit: Charge equation Oscillation frequency q Qe Rt / 2 L cos(t ) 2 ( R / 2 L) 2 Reactances: Resistive, X R R V iR I R sin d t R sin d t R XC capacitive, V iC C cos d t XC 1 d C inductive X L d L V iL L cos d t XL December 5, 2007 Thoughts on Clickers 6. How did you like using the clickers in this class? A. Great! It had its moments. I could take it or leave it. I would rather leave it. It was the worst! B. C. D. E. December 5, 2007 Thoughts on Clickers 7. Which answer describes the most important way that the clicker aided you in learning the material? A. It helped me to think about the material presented just before each question. It broke up the lecture and kept me awake. It tested my understanding. It provided immediate feedback. It showed me what others were thinking. B. C. D. E. December 5, 2007 Thoughts on Clickers 8. Which answer describes the second most important way that the clicker aided you in learning the material? A. It helped me to think about the material presented just before each question. It broke up the lecture and kept me awake. It tested my understanding. It provided immediate feedback. It showed me what others were thinking. B. C. D. E. December 5, 2007 Thoughts on Clickers 9. How would you react to clickers being used in other classes at NJIT? A. I I I I I B. C. D. E. think it would be excellent. think it is a good idea. wouldn’t mind. would rather not. definitely hope not. December 5, 2007 Thoughts on Clickers 10. What problems did you have with your clicker? A. I had no problems with my clicker. It was too big or bulky, a pain to carry around. I had trouble remembering to bring it to class. My clicker had mechanical problems. I lost or misplaced it (for all or part of the semester). B. C. D. E. December 5, 2007 Thoughts on Clickers 11. If you had the choice between using a clicker versus having a lecture quiz where you had to fill in a scantron, which would you prefer? A. I would prefer the clicker. I would prefer the scantron quiz. B. December 5, 2007 Have a Nice Day 12. Please click any button on your clicker as you turn your clicker in. This will register your name as having turned in your clicker. December 5, 2007