Presentation is loading. Please wait.

Presentation is loading. Please wait.

Phy2005 Applied Physics II Spring 2016 Announcements: Test 2 Wednesday, March 23 2 practice tests posted on course Tests page Review session in class March.

Published byErika Hamilton Modified over 8 years ago

Similar presentations

Presentation on theme: "Phy2005 Applied Physics II Spring 2016 Announcements: Test 2 Wednesday, March 23 2 practice tests posted on course Tests page Review session in class March."— Presentation transcript:

1 Phy2005 Applied Physics II Spring 2016 Announcements: Test 2 Wednesday, March 23 2 practice tests posted on course Tests page Review session in class March 21 in class + March 21 6pm NPB 2205 PH travel next week APS Spring meeting; Prof. Lee subs

2 Science news page Link to NYT article American Meteor Society

3 Last time Use rms values of v and i for AC to evaluate average power. = v rms 2 /R = i rms 2 R = i rms v rms V ind = - n ℓ  /  t = - n ℓ A(  o n)  i/  t = - n 2  o A ℓ (  i / t) L: self inductance: V ind =-L  i / t geometrical quantity [L] = Henry

4 r = 1 cm ℓ = 2.5 cm n = 10 turns/cm = 0.01 m = 0.025 m = 1000 turns/m L = n 2  o A ℓ = (1000) 2 (4  x 10 -7 )(  x 0.01 2 )0.025 = 9.9 x 10 -6 H = 9.9  H Calculate L for a solenoid:

5 Ex 22-4 A steady current of 5.0 A is flowing through a coil with 2 H self inductance. The current is suddenly stopped in 0.01 s. How large an EMF would be induced in the coil? V ind = -L (  i/  t) = -(2)(-5/0.01) = 1000 V Connect and disconnect circuits with inductive elements especially carefully!!!!

6 Level Time

7 RC Circuit Q = C V - + - - + + - - - + + + V Constant I-source I Q V

8 V = 0 VcVc t = 0: V c = 0I 0 = (V – V c )/R = V/R t = t 1 : V c = V 1 (>0)I 1 = (V –V 1 )/R (< I 0 ) VcVc t t = t 2 : V c = V 2 (> V 1 >0) I 2 = (V – V 2 )/R (< I 1 < I 2 ) V

9 V VcVc t V c = V (1 – e -t/RC ) t c = RC V c = V (1 – e -1 ) = 0.63 V RC: time constant 0.63V e = 2.71828183 When a capacitor with a capacitance C is connected to a constant voltage source V o through a series resistor R, (i) The potential difference across the capacitor increases not linearly but exponentially. (ii) The potential difference reaches 63% of the maximum value (0.63Vo) at time t c = RC.

10 t V = V o e -t/RC 0.37 RC R C +Q -Q V c = Q/C + When a capacitor (C ) initially charged with Q is discharged through a series resistor R, (i)The amount of charge on the capacitor (voltage) decreases exponentially. (ii) 63% of the total charge (0.63Q) will be discharged at time t c = RC.

11 Ex 23-1 A 100  F capacitor is fully charged with 5 V DC source. This capacitor is discharged through 10 K  resistor for 1 s. How much of charge is left in the capacitor in C? Total amount of charge: Q = C V = (100 x 10 -6 F)(5 V) = 5 x 10 -4 C Time constant: t = RC = (100 x 10 -6 F)(10 x 10 3 Ohm) = 1 s Since Q is proportional to V, after one time constant (100 – 63)% of initial charge is left: Q = 0.37 (5 x 10 -4 ) C

12 ACADEMIC HONESTY Each student is expected to hold himself/herself to a high standard of academic honesty. Under the UF academic honesty policy. Violations of this policy will be dealt with severely. There will be no warnings or exceptions.UF academic honesty policy

13 Q1 (24.11) An uncharged 2-  F capacitor is connected in series with a switch, a 5x10 6  resistor, and a 12V battery. Find the current in the circuit just after switch is closed, and the time constant. (I) (  ) 1. 2.0 x 10 -6 A 10 s 2. 6.0 x 10 6 A 3.2 s 3. 2.0 x 10 -6 A 2.7 s 4. 4.0 A 1.41 s

14 Electromagnetic WAVES

15 y = sin(kx) Traveling sin(kx) with a velocity v: y = sin{k(x-vt)} x t Wavelength:  k period: T Frequency: f = 1/T v = f

16 Any traveling wave satisfies this equation. Sound Wave Sound is a longitudinal mechanical wave that travels through an elastic medium. The speed of sound in air at 27  C is 347 m/s. The middle A note (A4) has 440 Hz frequency. We can use the above equation to calculate the wavelength of the middle A note sound wave.  = v/f = (347/440) m

17 From quantities present in his equations Maxwell was able to calculate the speed with which electromagnetism moves Turned out to be c, the speed of light (known from Romer astronomical expts. in 17 th century.) “We can scarcely avoid the inference that light consists of the transverse undulations of the same medium which is the cause of magnetic and electric phenomena” -- Maxwell Light was known to be a wave (Young experiment 1801)

18 c=2.9986 x 10 8 m/s Fiat Lux! Velocity of the wave solutions to Maxwell equations Note  0,  0 come from laboratory measurements of electricity and magnetism

Download ppt "Phy2005 Applied Physics II Spring 2016 Announcements: Test 2 Wednesday, March 23 2 practice tests posted on course Tests page Review session in class March."

Similar presentations

Alternating Current Circuits

Alternating Current Circuits
Unit 3 Day 11: RC Circuits RC Circuit Introduction RC Circuit Analysis

Unit 3 Day 11: RC Circuits RC Circuit Introduction RC Circuit Analysis
Chapter 31B - Transient Currents and Inductance

Chapter 31B - Transient Currents and Inductance
RC Circuits.

RC Circuits.
The current through the inductor can be considered a sum of the current in the circuit and the induced current. The current in the circuit will be constant,

The current through the inductor can be considered a sum of the current in the circuit and the induced current. The current in the circuit will be constant,
Fundamentals of Circuits: Direct Current (DC)

Fundamentals of Circuits: Direct Current (DC)
Physics 1402: Lecture 21 Today’s Agenda Announcements: –Induction, RL circuits Homework 06: due next MondayHomework 06: due next Monday Induction / AC.

Physics 1402: Lecture 21 Today’s Agenda Announcements: –Induction, RL circuits Homework 06: due next MondayHomework 06: due next Monday Induction / AC.
Alternating Current Physics 102 Professor Lee Carkner Lecture 23.

Alternating Current Physics 102 Professor Lee Carkner Lecture 23.
AC Circuits PH 203 Professor Lee Carkner Lecture 23.

AC Circuits PH 203 Professor Lee Carkner Lecture 23.
Alternating Current Physics 102 Professor Lee Carkner Lecture 22.

Alternating Current Physics 102 Professor Lee Carkner Lecture 22.
W12D1: RC and LR Circuits Reading Course Notes: Sections , , , ,

W12D1: RC and LR Circuits Reading Course Notes: Sections , , , ,
Chapter 20: Circuits Current and EMF Ohm’s Law and Resistance

Chapter 20: Circuits Current and EMF Ohm’s Law and Resistance
Physics 2102 Lecture 19 Ch 30: Inductors and RL Circuits Physics 2102 Jonathan Dowling Nikolai Tesla.

Physics 2102 Lecture 19 Ch 30: Inductors and RL Circuits Physics 2102 Jonathan Dowling Nikolai Tesla.
-Self Inductance -Inductance of a Solenoid -RL Circuit -Energy Stored in an Inductor AP Physics C Mrs. Coyle.

-Self Inductance -Inductance of a Solenoid -RL Circuit -Energy Stored in an Inductor AP Physics C Mrs. Coyle.
Engineering Science EAB_S_127 Electricity Chapter 4.

Engineering Science EAB_S_127 Electricity Chapter 4.
AP Physics C Montwood High School R. Casao

AP Physics C Montwood High School R. Casao
Lecture 18 RLC circuits Transformer Maxwell Electromagnetic Waves.

Lecture 18 RLC circuits Transformer Maxwell Electromagnetic Waves.
ARRDEKTA INSTITUTE OF TECHNOLOGY GUIDED BY GUIDED BY Prof. R.H.Chaudhary Prof. R.H.Chaudhary Asst.prof in electrical Asst.prof in electrical Department.

ARRDEKTA INSTITUTE OF TECHNOLOGY GUIDED BY GUIDED BY Prof. R.H.Chaudhary Prof. R.H.Chaudhary Asst.prof in electrical Asst.prof in electrical Department.
1 Chapter 16 Capacitors and Inductors in Circuits.

1 Chapter 16 Capacitors and Inductors in Circuits.
1 Faraday’s Law Chapter 31. 2 Ampere’s law Magnetic field is produced by time variation of electric field.

1 Faraday’s Law Chapter Ampere’s law Magnetic field is produced by time variation of electric field.

Similar presentations

Ads by Google