Wright State University Lake Campus/2018-9/Phy2410/Notes

Quizbank/University Physics Semester 2(tests) and maybe Quizbank/Electricity_and_Magnetism_(calculus_based) (?)


 * 

Tue 28 Aug

 * QB/d cp2.5 Questions 1 and 2

Lab1: Mr Circuit inventory
Mr. Circuit inventory: Check off what's missing during daytime hours have Engineering replace (main office is waiting for you.) Report: What is (or what do you think is) each of the following:
 * 1) breadboard
 * 2) wire
 * 3) battery
 * 4) resistor
 * 5) diode
 * 6) potentiometer
 * 7) Transistor/SCR (Both have three leads).

Report is written, due at end of period. Can be very informal, but write good and clear (and honest) prose. If time permits, research the items on the internet, but write only what you understand. Include the symbol for each element

Tues 4 Sep 2018 T1 review
Almost finished with T1. Will finish during recitation

Lab2 PheT virtual ciruit
NEW SIMS: Circuit Construction Kit: DC

Abstract: This PhET virtual kit has an option for using wires with finite resistance, and voltage sources with internal resistance. Also,the battery "catches fire" if too much power is involved. We will use this to "verify" Ohm's law under conditions where it is not quite true.

Goal: To create a simple circuit, perhaps using lightbulbs and/or added impedances to create a situation where Ohm's law is a good approximation, but not so good that the graph of I versus V is not a perfect straight line. You will need to use either Excel or Matlab to make your graph.

Lab

 * 1) Calculating area of a circle using integration over dA
 * 2) Gauss Law: Concentric spheres

Recitation
Gauss law non-uniform but symmetric sphere


 * https://www.youtube.com/watch?v=Ehg9VUUFvGc


 * 3 part video: https://www.youtube.com/watch?v=00dl3hOu9eQ


 * words w/optional 30 minute video: https://pages.uncc.edu/phys2102/online-lectures/chapter-3-gauss-s-law/3-1-gausss-law/example-6-electric-field-of-a-non-uniform-charge-distribution/

Tues 18 Sep: Test 2*
* I removed our questions pending today's lab:

Lab: Gauss Law
Quizbank/Electricity_and_Magnetism:_Gauss'_Law Wright State University Lake Campus/2017-9/Phy2410/Help with Gauss' law

Recitation
Projects for Wikiversity. Explain 30 Watts * (1 J/s / 1W) { (V^-1) /  (Q/J) } 12 volts
 * Double sum for PE (work) N charges. We will 4x4 square. W_11 W_12 (after defining them) Equation 7.3
 * Example 7.5:

Tu 25 Sep: Start Test 3

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P=IV=(dq/dt)V=e(dN/dt)V relates power, voltage and e&minus;/sec
Easy way to do Example 7.4:

This is much easier if you know the equations: Later in the course, we will establish: $$U=qV$$ and $$Power = \tfrac{\Delta U}{\Delta t} = \tfrac{\Delta q}{\Delta t}V=IV=e\tfrac{\Delta N}{\Delta t}$$

Calculating Work with the 1/r potential
Example 7.1

$$Work = \int \vec F\cdot d\vec\ell = q\int \vec E\cdot d\vec\ell = kqQ\int_{r1}^{r2}\frac{d\tilde r}{\tilde r^2}=qQk\left(\frac{1}{r_1}-\frac{1}{r_2}\right)$$

Visualizing field lines and equipotentials
Look at these pictures to visualize electric field and potential I also like this one from the internet

But the best is [PhET


 * 2/4 from Special:Permalink/1893633 to QB/d_cp2.8 | Equations

Capacitors "add" in parallel and series opposite to resistors
$$\text{Series}:\; \tfrac{1}{C_S} = \sum\tfrac{1}{C_i}.$$  $$\text{ Parallel:}\;C_P=\sum C_i.$$

Lab
Force on plate of a charged capacitor (quiz question)
 * 3/5 from Special:Permalink/1863338 to QB/a19ElectricPotentialField_Capacitance | Equations

""We would be delighted if you send in your bill. However, if you don't, you will be.""
 * Van Der Graff generator
 * Recitation: The class "wrote a report" that applied Gauss' law to capacitor using a wonderful website sponsered by physics.lousville, which has a great quote they claim was put forth by an electric company:

Th 27 Sep Capacitors
See links in above Lab.
 * 2/4 from Special:Permalink/1863339 to QB/a19ElectricPotentialField_KE_PE | Equations

What to study for on Test 3
In the example quizzes (d_cp 2.7 and 2.8 series) 2.7 examples:
 * example 7.1: study?
 * example 7.2: not in study guide
 * example 7.3: not on test
 * example 7.4: know
 * example 7.5: know
 * example 7.6:easy
 * example 7.8:easy, but not on test

2.6
 * Study Examples 8.6 and 8.7. Both are on test, but on 8.7 you only need to find the charge (do so by finding the total capacitance and using the given voltage.)

Thur 15:28, 4 October 2018 (UTC)

 * 1) Do you already know this?
 * A Mathematician's Lament for reference only
 * 842002338#Reform_curricula Why skepticism about "scientific expertise" is sometimes valid. See also Mathland
 * Mathematical beauty
 * 1) Amazing things I have seen in the classroomIllustration of distributive property with rectangles.svgStep-by-step geometric construction of the Pythagoras' branch of odd triples.jpg
 * 2) quality MIT lecture on circuits

Tues 9 October Kirchoff loop law problem
File:Kirchhoff loop w external current.svg

Test 5 is Tuesday 29 30 October

 * ../Equation sheet/

The important examples in QB/d cp2.11 are: Prob 1:Example 11.1 Prob 2:Example 11.2 Prob 3:Example 11.2 Prob 4:Example 11.4 Prob 5:Example 11.5 Prob 6:Example 11.7 Prob 7:Example 11.8 Prob 8:Example 11.9 Prob 9:Example 11.10

The important examples in QB/d cp2.12 are: Prob 1:12.2 Prob 2:Example 12.3 Prob 3:Example 12.3 Prob 4:Example 12.4 Prob 5:Example 12.5 Prob 6:Example 12.7 Prob 7:Example 12.6? Prob 8:Example 12.8 Prob 9:Example 12.8 Prob 10:Example 12.9 Prob 11:Example 12.10

Next

 * [Induction video (fun) https://www.youtube.com/watch?v=gfJG4M4wi1o ]
 * kahn euler

From Euler's formula
We begin with $$ e^{x} = 1 + x + \frac{(x)^2}{2!} + \frac{(x)^3}{3!} + \frac{(x)^4}{4!} + \frac{(x)^5}{5!} + \frac{(x)^6}{6!} + \frac{(x)^7}{7!} + \frac{(x)^8}{8!} + \cdots $$

d

 * $$\begin{align}

i^0 &= 1, & i^1 &= i, & i^2 &= -1, & i^3 &= -i, \\ i^4 &= 1, & i^5 &= i, & i^6 &= -1, & i^7 &= -i \\ &\vdots  & &\vdots   & &\vdots    & &\vdots \end{align}$$

For real values of $x$ we have:


 * $$\begin{align}

e^{ix} &= 1 + ix + \frac{(ix)^2}{2!} + \frac{(ix)^3}{3!} + \frac{(ix)^4}{4!} + \frac{(ix)^5}{5!} + \frac{(ix)^6}{6!} + \frac{(ix)^7}{7!} + \frac{(ix)^8}{8!} + \cdots \\[8pt] &= 1 + ix - \frac{x^2}{2!} - \frac{ix^3}{3!} + \frac{x^4}{4!} + \frac{ix^5}{5!} - \frac{x^6}{6!} - \frac{ix^7}{7!} + \frac{x^8}{8!} + \cdots \\[8pt] &= \left( 1 - \frac{x^2}{2!} + \frac{x^4}{4!} - \frac{x^6}{6!} + \frac{x^8}{8!} - \cdots \right) + i\left( x - \frac{x^3}{3!} + \frac{x^5}{5!} - \frac{x^7}{7!} + \cdots \right) \\[8pt] &= \cos x + i\sin x. \end{align}$$

But how can we verify that these infinite series expansions are valid?
 * 1) Use a spreadsheet
 * 2) Take derivatives: The series all match at x=0: $$e^0=1=\cos 0, \text{ and } \sin(0)=0$$. Term by term it is easy to show that $$de^x/dx = e^x$$ and also that the sine and cosine expansions also work out.  If a polynomial and a function match values at x=0 and if all their derivatives match, does that mean that the (infinite) polynomieal (i.e. expansion) EQUALS the function?  Not always.
 * 3) Go deep into the mathematical logic of the calculus of complex numbers (called "complex analysis")

Lab report due Tuesday 20 November
Full explanation based on Ampere's Law, Faraday's Law. I don't think you need Gauss's Law.
 * The lab will introduce a report due next Tuesday 20 November (on the three "bad" questions on a quiz).
 * See QB/d cp2.13 especially File:Quizbankqb_d_cp2.13.pdf or this page (Problems 7, 8, 9).

Later I might do this

 * E due to rho of x in a slab: https://www.youtube.com/watch?v=H72xpjt24UE
 * See also https://www.chegg.com/homework-help/calc-nonuniformly-charged-slab-repeat-problem-2254-let-charg-chapter-22-problem-55p-solution-9780321973610-exc

15 Nov Ray Diagrams

 * Snell's law
 * 1) derivation
 * 2) lifeguard analogy
 * 3) even dogs and ants do it
 * 4) thin lens approximation
 * 5) lab

2.11
2/9 from Special:Permalink/1902372 to QB/d_cp2.11 | Equations
 * 1) 11.1
 * 2) 11.2
 * 3) 11.2
 * 4) 11.4
 * 5) 11.5
 * 6) 11.7
 * 7) 11.8
 * 8) 11.9

2.12
2/11 from Special:Permalink/1892310 to QB/d_cp2.12 | Equations

2.13
1/9 from Special:Permalink/1893631 to QB/d_cp2.13 | Equations
 * 1) Example 13.1 from OpenStax University Physics2: https://cnx.org/contents/eg-XcBxE@9.7:BTZF6vX4@2/131-Faradays-Law_1
 * 2) Example 13.2 from OpenStax University Physics2: https://cnx.org/contents/eg-XcBxE@9.7:ZNcjduzK@4/132-Lenzs-Law_1
 * 3) Example 13.3 from OpenStax University Physics2: https://cnx.org/contents/eg-XcBxE@9.7:ZNcjduzK@4/132-Lenzs-Law_1
 * 4) Example 13.3 from OpenStax University Physics2: https://cnx.org/contents/eg-XcBxE@9.7:ZNcjduzK@4/132-Lenzs-Law_1
 * 5) Example 13.5 from OpenStax University Physics2: https://cnx.org/contents/eg-XcBxE@9.7:UbKygyP4@2/133-Motional-Emf_1
 * 6) Example 13.6 from OpenStax University Physics2: https://cnx.org/contents/eg-XcBxE@9.7:UbKygyP4@2/133-Motional-Emf_1
 * 7) Example 13.7 from OpenStax University Physics2: https://cnx.org/contents/eg-XcBxE@9.7:F-UkvfQz@3/134-Induced-Electric-Fields_1
 * 8) Example 13.8 from OpenStax University Physics2: https://cnx.org/contents/eg-XcBxE@9.7:F-UkvfQz@3/134-Induced-Electric-Fields_1
 * 9) Example 13.8 from OpenStax University Physics2: https://cnx.org/contents/eg-XcBxE@9.7:F-UkvfQz@3/134-Induced-Electric-Fields_1

2.14
1/6 from Special:Permalink/1892308 to QB/d_cp2.14 | Equations
 * 1) Example 14.1 from OpenStax University Physics 2: https://cnx.org/contents/eg-XcBxE@9.7:H8S6dNUY@2/141-Mutual-Inductance_1
 * 2) Example 14.2 OpenStax University Physics 2: https://cnx.org/contents/eg-XcBxE@9.7:9IPDyGBX@2/142-Self-Inductance-and-Induct_1
 * 3) Example 14.6 from OpenStax University Physics 2: https://cnx.org/contents/eg-XcBxE@9.7:gPV9xl9u@2/143-Energy-in-a-Magnetic-Field_1
 * 4) Example 14.4 from OpenStax University Physics 2: https://cnx.org/contents/eg-XcBxE@9.7:vsb1s41R@3/144-RL-Circuits_1
 * 5) Example 14.5 from OpenStax University Physics 2: https://cnx.org/contents/eg-XcBxE@9.7:vsb1s41R@3/144-RL-Circuits_1
 * 6) Example 14.6 from OpenStax University Physics 2: https://cnx.org/contents/eg-XcBxE@9.7:tIlYnK5w@2/145-Oscillations-in-an-LC-Circ_1

2.15
1/8 from Special:Permalink/1894891 to QB/d_cp2.15 | Equations


 * 1) Example 15.1 from OpenStax University Physics2: http://cnx.org/content/col12074/1.3_1
 * 2) Example 15.1 from OpenStax University Physics2: http://cnx.org/content/col12074/1.3_1
 * 3) Example 15.1 from OpenStax University Physics2: http://cnx.org/content/col12074/1.3_1
 * 4) Example 15.2 from OpenStax University Physics2: https://cnx.org/contents/eg-XcBxE@14.10:JOs6racw@8/15-3-RLC-Series-Circuits-with-AC
 * 5) Example 15.4 from OpenStax University Physics2: http://cnx.org/content/col12074/1.3_1
 * 6) Example 15.5 from OpenStax University Physics2: http://cnx.org/content/col12074/1.3_1
 * 7) Example 7.15 from OpenStax University Physics2: https://cnx.org/contents/eg-XcBxE@9.8:z70YwVma@4/156-Transformers_1

2.16
2/6 from Special:Permalink/1895295 to QB/d_cp2.16 | Equations

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