homework:ph320422questions:amperecylinderb

2015-10-16T14:33:05-08:00

Find the current flowing through Disk 2, a central (circular cross-section) portion of the wire out to a radius $r_2

homework:ph320422questions:amperecylinderc

2015-10-16T14:33:05-08:00

Use Amp\`ere's law to find the magnetic field at a distance $r_1$ outside the wire.\\

homework:ph320422questions:amperecylinderd

2015-10-16T14:33:05-08:00

Use Amp\`ere's law to find the magnetic field at a distance $r_2$ inside the wire.\\

homework:ph320422questions:amperelawdifferential

2019-04-21T22:13:33-08:00

Find the volume current density that produces the following magnetic field (expressed in cylindrical coordinates): \[ \vec{B}(\vec{r})=\begin{cases} \frac{\mu_0\,I\,s}{2\pi a^2}\hat{\phi}& s\leq a \\ \frac{\mu_0\,I}{2\pi s}\hat{\phi}& ab \\ \end{cases} \]

homework:ph320422questions:apracticea

2012-10-26T18:10:06-08:00

%Adapted from Colorado Clicker Questions For the following situation, what will the observer see for the direction of $\vec{A}$? For the direction of $\vec{B}$? \medskip \centerline{\includegraphics[scale=0.65]{\TOP Figures/vfapracticea}} \medskip

homework:ph320422questions:apracticeb

2012-10-26T18:10:06-08:00

%Adapted from Colorado Clicker Questions The arrows below represent the vector potential $\vec{A}$ (where $|\vec{A}|$ is the same everywhere). Is there a non-zero $\vec{B}$ in the dashed region? If so, what direction does it point? How do you know? \\

homework:ph320422questions:bdirection

2012-10-26T18:10:06-08:00

%Adapted from Colorado Clicker Questions What is $\vec{B}$ at the point $S$? \medskip \centerline{\includegraphics[scale=0.5]{\TOP Figures/vfbdirection}} \medskip

homework:ph320422questions:bfinitelinea

2016-04-05T10:47:39-08:00

Find the magnetic field for a finite segment of straight wire, carrying a uniform current $I$. Put the wire on the $z$ axis, from $z_1$ to $z_2$.

homework:ph320422questions:bfinitelineb

2016-04-05T10:47:39-08:00

Show that your answer to part (a) is the curl of the magnetic vector potential.

homework:ph320422questions:biotsavartchallenge

2012-10-26T18:10:06-08:00

In class, we found that the magnetic vector potential created by a rotating ring of charge (total charge $Q$, radius $R$, rotating with period $T$) everywhere in space is\\ \begin{equation*} \vec{A}(\vec{r}) =\frac{\mu_0}{4 \pi}\frac{Q\,R}{T}\,\hat{\phi}\int_0^{2 \pi} \dfrac{\cos\phi'\,d\phi'}{\sqrt{r^2+R^2-2 r R cos\phi'+z^2}} \end{equation*}\\

homework:ph320422questions:biotsavartcoils

2013-05-09T13:02:00-08:00

Two charged rings of radius $R$ spin in opposite directions, each with total current $I$. They are placed a distance $2L$ apart and oriented as shown below. \medskip \centerline{\includegraphics[scale=0.65]{\TOP Figures/vfbiotsavartcoils}} \medskip

homework:ph320422questions:biotsavartcoilsa

2013-05-09T13:02:00-08:00

What is the magnetic field on the $z$-axis due to Loop 1?

homework:ph320422questions:biotsavartcoilsb

2013-05-09T13:02:00-08:00

What is the magnetic field on the $z$-axis due to Loop 2?

homework:ph320422questions:biotsavartcoilsc

2013-05-09T13:02:00-08:00

What is the leading non-zero term for the total magnetic field on the $z$-axis near the midpoint between the coils ($z<

homework:ph320422questions:biotsavartlimitSJP

1969-12-31T16:00:00-08:00

homework:ph320422questions:biotsavartlimitaSJP

1969-12-31T16:00:00-08:00

homework:ph320422questions:biotsavartlimitambk

2012-10-31T17:31:12-08:00

Take the limit $r>>R$ in the plane of the ring, and simplify to find the {\it leading} non-zero term. Briefly describe any checks you did to validate your answer.\\

homework:ph320422questions:biotsavartlimitbSJP

1969-12-31T16:00:00-08:00

homework:ph320422questions:biotsavartlimitbmbk

2012-10-31T17:31:12-08:00

Find the \emph{leading} non-zero term for $|\vec{r}|<

homework:ph320422questions:biotsavartlimitchallenge

2012-10-26T18:10:06-08:00

In problem 1, you found the approximation for $\vec{B}$ from a spinning ring of charge when you are near and far away \emph{on the x-axis}. Now, find the \emph{leading} non-zero term for $r<

homework:ph320422questions:biotsavartlimitmbk

2015-10-16T14:31:48-08:00

In class we derived an expression, using the Biot-Savart law, for the magnetic field created by a rotating ring of charge (total charge $Q$, radius $R$, rotating with period $T$) everywhere in space.\\ \begin{eqnarray*} \vec{B}(\vec{r}) =\frac{\mu_0}{4 \pi} \frac{Q\,R}{T} \int_0^{2 \pi} \frac{z\,\cos\phi' \, \hat{r}+\left(R-r \cos\phi'\right)\hat{z}}{\left(r^2+R^2-2 r R \cos\phi'+z^2\right)^{3/2}}d\phi'\, \end{eqnarray*}\\

homework:ph320422questions:biotsavartsquare

2009-10-17T14:03:18-08:00

Consider a point a distance $z$ above the center of an infinitesimally thin, square sheet of current. The current is parallel to one of the square sides. (Obviously, since the current cannot just begin and end in the middle of nowhere, this current is just the building block for some larger current.)

homework:ph320422questions:biotsavartsquarea

2011-12-06T16:11:47-08:00

Use the Biot-Savart Law to find the magnetic field at the point $z$. You may use any symmetry arguments you like, but do not use Ampere's Law. Note: if you choose to use Mathematica or Maple to evaluate the integral, it may take you into complex number land, even though the integral is clearly real. To address this issue, you should be explicit about what assumptions you want the program to make (``Assume'' in Maple and ``Assumptions'' in Mathematica)

homework:ph320422questions:biotsavartsquareb

2011-12-06T16:11:47-08:00

Consider your previous answer in the limit that the square becomes infinitely large.

homework:ph320422questions:biotsavartsquarec

2011-12-06T16:11:47-08:00

Discuss your answer in the light of the magnetic field above an infinite sheet of current as found using Ampere's Law.

homework:ph320422questions:bmethod

2012-10-26T18:10:06-08:00

%Adapted from Colorado Clicker Questions An electron is moving in a straight line with constant speed v. What method would you use to calculate the B-field generated by this electron? \medskip \centerline{\includegraphics[scale=0.65]{\TOP Figures/vfbmethod}} \medskip

homework:ph320422questions:bsymmetry

2012-10-26T18:10:06-08:00

%Adapted from Colorado Clicker Questions Which of the below B-field components are not possible? How do you know? \medskip \centerline{\includegraphics[scale=0.5]{\TOP Figures/vfbsymmetry}} \medskip

homework:ph320422questions:capacitor

2012-10-12T23:47:58-08:00

We know that the electric field everywhere in space due to an infinite plane of charge with charge density located in the $xy$-plane at $z=0$ is \begin{equation*} \EE(z) = \begin{cases}\displaystyle +{\sigma\over2\epsilon_0}\>\zhat & z>0 \cr \noalign{\smallskip}\displaystyle -{\sigma\over2\epsilon_0}\>\zhat & z<0 \end{cases} \end{equation*}

homework:ph320422questions:capacitora

2009-10-17T13:40:34-08:00

Sketch the $z$-component of the electric field as a function of $z$.

homework:ph320422questions:capacitorb

2009-10-17T14:16:05-08:00

Draw a similar picture, and write a function that expresses the electric field everywhere in space, for an infinite conducting slab in the $xy$-plane, of thickness $d$ in the $z$-direction, that has a charge density $+|\sigma|$ on each surface.

homework:ph320422questions:capacitorc

2009-10-17T13:40:34-08:00

Repeat for a charge density $-|\sigma|$ on each surface.

homework:ph320422questions:capacitord

2009-10-17T13:40:34-08:00

Now imagine two {\bf conductors}, one each of the two types described above, separated by a distance $L$. Use the principle of superposition to find the electric field everywhere. Discuss whether your answer is reasonable. Does it agree with the known fact that the electric field inside a conductor is zero? Has superposition been correctly applied? Is Gauss' Law correct? Try to resolve any inconsistencies.

homework:ph320422questions:chargegraph

2016-08-25T13:33:07-08:00

The following graph represents the charge density on a thin piece of plastic (dielectric). Find the charge on the segment between centimeter 3 and centimeter 10. [Figure: cross section of wire]

homework:ph320422questions:circlevector

2012-09-23T14:04:57-08:00

Consider the geometry of $\vert \rr-\rrp\vert$.

homework:ph320422questions:circlevectora

2016-09-23T15:42:11-08:00

Make a sketch of the graph $$ \vert \Vec r - \Vec a \vert = 2 $$ for each of the following values of $\Vec a$: $$ \begin{eqnarray} \Vec a &=& \Vec 0\\ \Vec a &=& 2 \hat \imath- 3 \hat \jmath\\ \Vec a &=& \hbox{points due east and is 2 units long} \end{eqnarray} $$

homework:ph320422questions:circlevectorb

2010-10-17T09:18:54-08:00

Derive a more familiar equation equivalent to $$ \vert \Vec r - \Vec a \vert = 2 $$ for arbitrary $\Vec a$, by expanding $\Vec r$ and $\Vec a$ in rectangular coordinates. Simplify as much as possible. (Ok, ok, I know this is a terribly worded question. What do I mean by ``more familiar”? What do I mean by ``simplify as much as possible”? Why am I making you read my mind? Try it anyway. Real life is not full of carefully worded problems. Bonus points to anyone who can figure out a better…

homework:ph320422questions:circlevectorc

2010-10-17T09:18:54-08:00

Write a brief description of the geometric meaning of the equation $$ \vert \Vec r - \Vec a \vert = 2 $$

homework:ph320422questions:circlevectorpre

2018-03-30T09:54:38-08:00

Make sketches of the following functions, by hand, all on the same axes. Briefly describe, using good scientific writing that includes both words and equations, the role that the number 2 plays in the shape of the second graph: \begin{eqnarray} y &=& \sin x\\ y &=& \sin(2+x) \end{eqnarray}

homework:ph320422questions:complexnum

2015-09-23T18:12:15-08:00

For the following expressions, determine the complex conjugate, square, and norm. Plot and clearly label each on an Argand diagram.

homework:ph320422questions:complexnuma

2015-09-23T18:12:15-08:00

$z_1=4i-3$

homework:ph320422questions:complexnumb

2015-09-23T18:12:15-08:00

$z_2=5e^{-i\pi/3}$

homework:ph320422questions:complexnumc

2015-09-23T18:12:15-08:00

$z_3=-8$

homework:ph320422questions:complexnumd

2015-09-23T18:12:15-08:00

In a few full sentences, explain the geometric meaning of the complex conjugate and norm.

homework:ph320422questions:complexrectangularpractice

2015-10-01T11:38:26-08:00

If $z_1=5e^{7i\pi/4}$, $z_2=3e^{-i\pi/2}$, and $z_3=9e^{(1+i\pi)/3}$, express each of the following complex numbers in rectangular form, i.e. in the form $x+iy$ where $x$ and $y$ are real.

homework:ph320422questions:complexrectangularpractice2

2015-10-01T11:38:26-08:00

%Boas 2.9 (parts thereof) Express each of the following complex numbers in exponential form, i.e. in the form $r e^{i\phi}$ where $r$ and $\phi$ are real.

homework:ph320422questions:complexrectangularpracticea

2015-10-01T11:38:26-08:00

$z_1 +z_2$

homework:ph320422questions:complexrectangularpracticeb

2015-10-01T11:38:26-08:00

$z_1 z_2$

homework:ph320422questions:complexrectangularpracticec

2015-10-01T11:38:26-08:00

$\frac{z_2}{z_3}$

homework:ph320422questions:complexrectangularpracticed

2015-10-01T11:38:26-08:00

$\left(1+i\sqrt{3}\right)^{6}$

homework:ph320422questions:complexrectangularpracticee

2015-10-01T11:38:26-08:00

$\frac{2+3i}{1-i}$

homework:ph320422questions:conductorsgem235

2012-10-31T17:31:12-08:00

A metal sphere of radius $R$, carrying charge $q$ is surrounded by a thick concentric metal shell (inner radius $a$, outer radius $b$, as shown below). The shell carries no net charge. \medskip \centerline{\includegraphics[scale=1]{\TOP Figures/vfconductor}} \medskip

homework:ph320422questions:conductorsgem235a

2009-10-17T13:40:34-08:00

Find the surface charge density $\sigma$ at $R$, at $a$, and at $b$.

homework:ph320422questions:conductorsgem235b

2018-05-02T17:18:45-08:00

Find $E_r$, the radial component of the electric field and plot it as a function of $r$. Are the discontinuities in the electric field related to the charge density in the way you expect from previous problems?

homework:ph320422questions:conductorsgem235c

2009-10-17T13:40:34-08:00

Find the potential at the center of the sphere, using infinity as the reference point.

homework:ph320422questions:conductorsgem235d

2009-10-17T14:27:17-08:00

Now the outer surface is touched to a grounding wire, which lowers its potential to zero (the same as infinity). How do your answers to a), b), and c) change?

homework:ph320422questions:conductorsgem235modb

2015-10-16T11:05:06-08:00

Find $E_r$, the radial component of the electric field and plot it as a function of $r$. %Are the discontinuities in the electric field what you expect from our unit on boundary conditions? Explain.

homework:ph320422questions:conesurface

2009-08-21T07:20:50-08:00

Using integration, find the surface area of a cone.

homework:ph320422questions:contours

2016-10-07T12:07:55-08:00

Shown below is a contour plot of a scalar field, $\mu(x,y)$. Assume that $x$ and $y$ are measured in meters and that $\mu$ is measured in kilograms. Four points are indicated on the plot.\\ \medskip \centerline{\includegraphics[scale=1]{\TOP Figures/contoursfig1}} \medskip

homework:ph320422questions:contoursa

2020-01-24T19:13:42-08:00

Determine $\frac{\partial\mu}{\partial x}$ and $\frac{\partial\mu}{\partial y}$ at each of the four points.

homework:ph320422questions:contoursb

2016-10-07T12:07:55-08:00

On a printout of the figure, draw a qualitatively accurate vector at each point corresponding to the gradient of $\mu(x,y)$ using your answers to part a above. How did you choose a scale for your vectors?\\ \\ Describe how the direction of the gradient vector is related to the contours on the plot and what property of the contour map is related to the magnitude of the gradient vector.

homework:ph320422questions:contoursc

2016-10-10T12:49:10-08:00

Evaluate the gradient of $h(x,y)=(x+1)^2(\frac{x}{2}-\frac{y}{3})^3$ at the point $(x,y)=(3,-2)$.

homework:ph320422questions:contoursd

2016-10-10T12:49:10-08:00

\medskip \centerline{\includegraphics[scale=1]{\TOP Figures/contoursfig2}} \medskip A contour map for a different function is shown above. On a printout of this contour map, sketch a field vector map of the gradient of this function (sketch vectors for at least 10 different points). The direction and magnitude of your vectors should be qualitatively accurate, but do not calculate the gradient for this function.

homework:ph320422questions:cosmicasimov

2019-04-13T08:58:46-08:00

You are part of the team building Cosmic AC, Asimov's ultimate, universe-sized computer. Your job is to fabricate a charged disk, 10 meters in radius and 1 cm thick. The charge density on the disk should be: $$\rho=\alpha e^{-\beta s^2} \cos(\gamma z)$$

homework:ph320422questions:cosmicasimova

2009-08-22T13:50:48-08:00

What is the total charge on the disk, in terms of the parameters $\alpha$, $\beta$, and $\gamma$?

homework:ph320422questions:cosmicasimovb

2009-08-22T13:50:48-08:00

What are the dimensions of $\alpha$, $\beta$, and $\gamma$?

homework:ph320422questions:cosmicasimovc

2010-11-07T05:24:09-08:00

Design specifications indicate that: the maximum charge density should be $27 ~\frac{C}{cm^3}$, only one-half period of the $\cos(\gamma z)$ term spans the whole height of the disk, the upper and lower circular surfaces have zero charge density, and the maximum values of the charge density on the circumference of the disk should be 10 percent of the maximum in the center. Find values for $\alpha$, $\beta$, and $\gamma$.

homework:ph320422questions:cosmicasimovd

2009-08-22T13:50:48-08:00

What is the total charge on the disk?

homework:ph320422questions:cosmicasimove

2019-04-13T08:58:46-08:00

Estimate how much error your would make in your calculation of the total charge density if you assumed that the disk was infinitely wide. (Keep the same functional dependence for the charge density, i.e. do not change the values of $\alpha$, $\beta$, and $\gamma$.)

homework:ph320422questions:cosmicasimovf

2011-11-22T18:33:12-08:00

Given the relative sizes of the radius of the disk and the thickness of the disk, it might be reasonable to approximate the disk as infinitely thin. In this case, you might want to describe the charge density as a surface charge density $\sigma$ rather than as a volume charge density $\rho$. From the given volume charge density $\rho$, find an equivalent surface charge density.

homework:ph320422questions:crosstriangle

2011-02-22T11:24:02-08:00

Use the cross product to find the components of the unit vector $\hat n$ perpendicular to the plane shown in the figure below, i.e.~ the plane joining the points $\{(1,0,0),(0,1,0),(0,0,1)\}$. [Figure: a plane]

homework:ph320422questions:cubecharge

2010-09-19T10:50:55-08:00

Charge is distributed on the surface of a dielectric cube with charge density $\sigma=\alpha z$, where $z$ is the height from the bottom of the cube, and where each side of the cube has length $L$. What is the total charge on the cube? Don't forget about the top and bottom of the cube.

homework:ph320422questions:cubechargea

2015-10-01T11:38:26-08:00

Charge is distributed throughout the volume of a dielectric cube with charge density $\rho=\beta z^2$, where $z$ is the height from the bottom of the cube, and where each side of the cube has length $L$. What is the total charge inside the cube? Do this problem in two ways as both a single integral and as a triple integral.

homework:ph320422questions:cubechargeb

2015-10-01T11:38:26-08:00

homework:ph320422questions:curldivergencefree

2012-10-31T17:31:28-08:00

%Adapted from Colorado Clicker Questions 4 and 5 Below are cross-sections for several vector fields (assume each cross-section is the same). %For this problem, explanations will count for the majority of the points. \medskip \centerline{\includegraphics[scale=0.65]{\TOP Figures/vfefield} \includegraphics[scale=0.65]{\TOP Figures/vfbfield} \includegraphics[scale=0.65]{\TOP Figures/vfnofield}} \centerline{(I)\hspace{1.3in}(II)\hspace{1.3in}(III)} \medskip

homework:ph320422questions:curldivergencefreea

2012-10-31T17:31:28-08:00

If the above sketches represent an electric field, \begin{enumerate} \item Which \emph{violate} one of Maxwell's Equations within the region shown? \item For those that do not violate Maxwell's equations, what charge distribution would be needed to generate this field and where would it be located? \end{enumerate}

homework:ph320422questions:curldivergencefreeb

2012-10-31T17:31:28-08:00

If the above sketches represent a magnetic field, \begin{enumerate} \item Which \emph{violate} one of Maxwell's Equations within the region shown? \item For those that do not violate Maxwell's equations, what charge distribution would be needed to generate this field and where would it be located? \end{enumerate}

homework:ph320422questions:curlfree

2013-05-09T13:02:00-08:00

%Adapted from Colorado Clicker Questions 4 and 5 Below are two sketches of electric field lines. For this problem, explanations will count for the majority of the points. \medskip \centerline{\includegraphics[scale=0.65]{\TOP Figures/vfcurlfree}} \medskip

homework:ph320422questions:curlfreea

2013-05-09T13:02:00-08:00

Which of the above sketches show field lines that \emph{violate} one of Maxwell's Equations within the region bounded by the dashed lines? How do you know?

homework:ph320422questions:curlfreeb

2013-05-09T13:02:00-08:00

For those that do not violate Maxwell's Equations, what current would be needed to generate the field and where would it be located?

homework:ph320422questions:curlpractice2

2011-11-22T18:33:12-08:00

Choose some simple vector fields of your own and find the curl of them both by hand and using Mathematica or Maple. Choose some that are written in terms of rectangular coordinates and others in cylindrical and/or spherical.

homework:ph320422questions:curlpracticemmm

2013-10-29T20:12:27-08:00

Calculate the curl of each of the following vector fields. You may look up the formulas for curl in curvilinear coordinates.

homework:ph320422questions:curlpracticemmma

2012-10-12T23:47:58-08:00

$\FF=z^2\,\hat{x} + x^2 \,\hat{y} -y^2 \,\hat{z}$

homework:ph320422questions:curlpracticemmmb

2012-10-12T23:47:58-08:00

$\GG = e^{-x} \,\hat{x} + e^{-y} \,\hat{y} +e^{-z} \,\hat{z}$

homework:ph320422questions:curlpracticemmmc

2012-10-12T23:47:58-08:00

$\HH = yz\,\hat{x} + zx\,\hat{y} + xy\,\hat{z}$

homework:ph320422questions:curlpracticemmmd

2012-10-12T23:47:58-08:00

$\II = x^2\,\hat{x} + z^2\,\hat{y} + y^2\,\hat{z}$

homework:ph320422questions:curlpracticemmme

2012-10-12T23:47:58-08:00

$\JJ = xy\,\hat{x} + xz\,\hat{y} + yz\,\hat{z}$

homework:ph320422questions:curlpracticemmmend

2012-10-12T23:47:58-08:00

For each vector field in the preceding problems which have zero curl, find the corresponding potential function.

homework:ph320422questions:curlpracticemmmf

2012-10-12T23:47:58-08:00

Compare the curl to the divergence for each field (see Homework 2 Practice).

homework:ph320422questions:curlvisualizepractice

2012-10-12T23:47:58-08:00

If you need more practice visualizing curl, go through the Mathematica Notebook on the course website.

homework:ph320422questions:currentpractice

2019-07-10T15:55:00-08:00

%Adapted from Colorado Clicker Questions *Redraw the figure for this problem and reword the problem by labeling the width of the ribbon something other than a (which seems like area, not length) AND use the same font in the figure as in the text.* A ``ribbon'' (width $a$) of surface current flows with surface current density $\vec{K}$. Right next to it is a second identical ribbon of current.

homework:ph320422questions:currentpracticea

2019-07-10T15:55:00-08:00

Viewed collectively, what is the new total surface current density?

homework:ph320422questions:currentpracticeb

2019-07-10T15:55:00-08:00

Viewed collectively, what is the new total current in terms of the original current density?

homework:ph320422questions:dadtaumemorizea

2014-10-10T16:05:42-08:00

Write down $\vec{dA}$ for each of the surfaces of a rectangular prism, a finite cylinder, and a sphere.

homework:ph320422questions:dadtaumemorizeb

2014-10-10T16:05:42-08:00

Write down $d\tau$ in rectangular, cylindrical, and spherical coordinates.

homework:ph320422questions:delta

2009-09-30T08:49:24-08:00

The linear charge density from a series of charges along the $x$-axis is given by: $$\lambda(x) = \sum_{n=0}^{10} q_0 \, n^2 \delta\!\left(x-{n\over 10}\right)$$

homework:ph320422questions:deltaa

2019-04-13T08:58:46-08:00

Write a sentence or two indicating describing the dimensions of each term in this equation, including any constants (for which the dimensions have not been indicated).

homework:ph320422questions:deltab

2009-09-30T08:49:24-08:00

What is the total charge on the $x$-axis?

homework:ph320422questions:deltapractice

2012-10-12T23:47:58-08:00

You have a charge distribution composed of two point charges: one with charge $+3q$ located at $x=-d$ and the other with charge $-q$ located at $x=+d$.

homework:ph320422questions:deltapractice2

2012-10-12T23:47:58-08:00

Sketch the volume charge density: $\rho (x,y,z)=c\,\delta (x-3)$

homework:ph320422questions:deltapracticea

2012-10-12T23:47:58-08:00

Sketch the charge distribution.

homework:ph320422questions:deltapracticeb

2012-10-12T23:47:58-08:00

Write an expression for the \emph{volume} charge density $\rho (\vec{r})$ everywhere in space.

homework:ph320422questions:derivrules

2014-10-01T17:53:19-08:00

Make sure that you can find the derivative of all of the common transcendental functions: power, trig, exponential, logs.

homework:ph320422questions:dimensions

2010-10-17T09:18:54-08:00

When physicists calculate the value of a physical quantity from an equation, they pay particular attention to the units involved. A force of 2 is ill-defined, a force of 2 Newtons is clear. When physicists want to check the plausibility of an equation, without worrying exactly about which set of units will be used (e.g. Newtons vs. pounds vs. dynes), they often look at the ``dimensions” of the physical quantities involved. ``Dimension” refers to the powers of the basic physical quantities…

homework:ph320422questions:directionalderivative

2011-11-22T18:33:12-08:00

Imagine you're standing on a landscape with a local topology described by the function $f(x, y)= k x^{2}y$, where $k=20 \frac{m}{km^3}$ is a constant, $x$ and $y$ are east and north coordinates, respectively, with units of kilometers. You're standing at the spot (3 km,2 km) and there is a cottage located at (1 km, 2 km). At the spot you're standing, what is the slope of the ground in the direction of the cottage? Plot the function $f(x, y)$ in Mathematica. Does your result makes sense from the g…

homework:ph320422questions:distancecurvilinear

2016-10-07T11:35:03-08:00

The distance $\left\vert\Vec r -\Vec r\,{}'\right\vert$ between the point $\Vec r\,{}'=(x\,{}',y\,{}',z\,{}')$ and the point $\Vec r=(x,y,z)$ is a coordinate-independent, physical and geometric quantity. But, in practice, you will need to know how to express this quantity in different coordinate systems.

homework:ph320422questions:distancecurvilineara

2018-04-04T15:56:18-08:00

Find the distance $\left\vert\Vec r -\Vec r\,{}'\right\vert$ between the point $\Vec r\,{}'=(x\,{}',y\,{}',z\,{}')$ and the point $\Vec r=(x,y,z)$ in rectangular coordinates.

homework:ph320422questions:distancecurvilinearb

2018-04-04T15:56:18-08:00

Show that this same distance written in cylindrical coordinates is: $$ \left|\Vec r -\Vec r\,{}'\right| =\sqrt{s^2+s\,{}'^2-2ss\,{}'\cos(\phi\,{}'-\phi) +(z\,{}'-z)^2} $$

homework:ph320422questions:distancecurvilinearc

2018-04-12T09:15:17-08:00

Show that this same distance written in spherical coordinates is: $$ \left\vert\Vec r\,{}' -\Vec r\right\vert =\sqrt{r\,{}'^2+r^2-2rr\,{}' \left[\sin\theta\sin\theta\,{}'\cos(\phi\,{}'-\phi) +\cos\theta\,{}'\cos\theta\right]} $$

homework:ph320422questions:distancecurvilineard

2018-04-04T15:56:18-08:00

Now assume that $\Vec r\,{}'$ and $\Vec r$ are in the $x$-$y$ plane. Simplify the previous two formulas.

homework:ph320422questions:divergencefree

2013-05-09T13:02:00-08:00

%Adapted from Colorado Clicker Questions 4 and 5 Below are several sketches of magnetic field lines. For this problem, explanations will count for the majority of the points. \medskip \centerline{\includegraphics[scale=0.65]{\TOP Figures/vfdivergencefree}} \medskip

homework:ph320422questions:divergencefreea

2013-05-09T13:02:00-08:00

Which of the above sketches show field lines that \emph{violate} one of Maxwell's Equations within the region bounded by the dashed lines? How do you know?

homework:ph320422questions:divergencefreeb

2013-05-09T13:02:00-08:00

For those that do not violate Maxwell's Equations, what current would be needed to generate the field and where would it be located?

homework:ph320422questions:divergencepractice

2013-10-29T20:12:27-08:00

Calculate the divergence of each of the following vector fields. You may look up the formulas for divergence in curvilinear coordinates.

homework:ph320422questions:divergencepractice2

2012-10-12T23:47:58-08:00

Choose some simple vector fields of your own and find the divergence of them both by hand and using Mathematica or Maple. Choose some that are written in terms of rectangular coordinates and others in cylindrical and/or spherical.

homework:ph320422questions:divergencepracticea

2012-10-12T23:47:58-08:00

$\FF=z^2\,\hat{x} + x^2 \,\hat{y} -y^2 \,\hat{z}$

homework:ph320422questions:divergencepracticeb

2012-10-12T23:47:58-08:00

$\GG = e^{-x} \,\hat{x} + e^{-y} \,\hat{y} +e^{-z} \,\hat{z}$

homework:ph320422questions:divergencepracticec

2012-10-12T23:47:58-08:00

$\HH = yz\,\hat{x} + zx\,\hat{y} + xy\,\hat{z}$

homework:ph320422questions:divergencepracticed

2012-10-12T23:47:58-08:00

$\II = x^2\,\hat{x} + z^2\,\hat{y} + y^2\,\hat{z}$

homework:ph320422questions:divergencepracticee

2012-10-12T23:47:58-08:00

$\JJ = xy\,\hat{x} + xz\,\hat{y} + yz\,\hat{z}$

homework:ph320422questions:divergencepracticef

2013-10-29T20:12:27-08:00

$\KK = s^2\,\hat{s}$

homework:ph320422questions:divergencepracticeg

2013-10-29T20:12:27-08:00

$\LL = r^3\,\hat{\phi}$

homework:ph320422questions:divergencepracticeh

2013-10-29T20:12:27-08:00

$\MM = r^3 \cos{\phi}\,\hat{r} + \frac{1}{r^2} \sin^2{\theta}\,\hat{\phi}$

homework:ph320422questions:divergenceprism

2012-10-12T23:47:58-08:00

Consider the vector field $\Vec F=(x+2)\hat{x} +(z+2)\hat{z}$.

homework:ph320422questions:divergenceprisma

2010-10-17T09:18:54-08:00

Calculate the divergence of $\Vec F$.

homework:ph320422questions:divergenceprismb

2010-10-17T09:18:54-08:00

In which direction does the vector field $\Vec F$ point on the plane $z=x$? What is the value of $\Vec F\cdot \hat n$ on this plane where $\hat n$ is the unit normal to the plane?

homework:ph320422questions:divergenceprismc

2011-02-22T11:24:02-08:00

Verify the divergence theorem for this vector field where the volume involved is drawn below. [Figure: Volume for divergence %*theorem.]

homework:ph320422questions:divergencespherical

2019-04-21T22:13:33-08:00

The gravitational field due to a spherical shell of matter (or equivalently, the electric field due to a spherical shell of charge) is given by: \begin{equation} \Vec g = \begin{cases} 0&\textrm{for } r

homework:ph320422questions:divergencesphericala

2009-10-01T08:03:54-08:00

Using the given value of the gravitational field, find the divergence of the gravitational field everywhere in space. You will need to divide this question up into three parts: $rb$.

homework:ph320422questions:divergencesphericalb

2009-10-01T08:03:54-08:00

Discuss the physical meaning of the divergence in this particular example.

homework:ph320422questions:divergencesphericalc

2009-10-01T08:03:54-08:00

For this gravitational field, verify the divergence theorem on a sphere, concentric with the shell, with radius $Q$, where $a

homework:ph320422questions:divergencesphericald

2009-10-01T08:03:54-08:00

Discuss how this example would change if you were discussing the electric field of a uniformly charged spherical shell.

homework:ph320422questions:divergencevisualizepractice

2012-10-12T23:47:58-08:00

If you need more practice visualizing divergence, go through the Mathematica notebook on the course website.

homework:ph320422questions:drvecmemorize

2014-10-08T15:44:19-08:00

Give the expression for $d\vec{r}$ in rectangular, cylindrical, and spherical coordinates.

homework:ph320422questions:efiniteline

2018-04-18T11:07:48-08:00

Consider the finite line with a uniform charge density from class.

homework:ph320422questions:efinitelinea

2018-04-18T11:07:48-08:00

Write an integral expression for the electric field at any point in space due to the finite line. In addition to your usual physics sense-making, you must include a clearly labeled figure and discuss what happens to the direction of the unit vectors as you integrate.

homework:ph320422questions:efinitelineb

2018-04-18T11:07:48-08:00

Perform the integral to find the $z$-component of the electric field. In addition to your usual physics sense-making, you must compare your result to the gradient of the electric potential we found in class. (If you want to challenge yourself, do the $s$-component as well!)

homework:ph320422questions:energygem231

2011-12-06T13:04:26-08:00

Three charges are situated at the corners of a square (side $s$). Two have charge $-q$ and are located on opposite corners. The third has charge $+q$ and is opposite an empty corner.

homework:ph320422questions:energygem231a

2011-12-06T13:04:26-08:00

How much work does it take to bring in another charge, $+q$, from far away and place it at the fourth corner?

homework:ph320422questions:energygem231b

2011-12-06T13:04:26-08:00

How much work does it take to assemble the whole configuration of four charges?

homework:ph320422questions:energygem234

2011-12-06T14:57:34-08:00

Consider two concentric spherical shells, of radii $a$ and $b$. Suppose the inner one carries a charge $q$, and the outer one a charge $-q$ (both of them uniformly distributed over the surface). Calculate the energy of this configuration.

homework:ph320422questions:energygem234a

2011-12-06T14:57:34-08:00

Starting from: $$W= {\epsilon_0\over 2}\int_{\hbox{all space}}E^2 \, d\tau$$

homework:ph320422questions:energygem234b

2016-04-05T10:42:36-08:00

Starting from: $$W= W_1 + W_2 + \epsilon_0\int_{\hbox{all space}}\left(\vec E_1\cdot\vec E_2\right)\, d\tau$$ and using the result that the total energy of a uniformly charged spherical shell of total charge $q$ and radius $R$ is: $$W_{total}={1 \over 8 \pi\epsilon_0}{q^2 \over R}$$

homework:ph320422questions:etov

2018-04-20T16:55:28-08:00

Consider the electric field $\vec{E} = \alpha\left( \frac{3\cos\theta}{r^4}\hat{r} + \frac{\sin\theta}{r^4}\hat{\theta}\right)$.

homework:ph320422questions:etova

2018-04-20T16:55:28-08:00

Find the electric potential. In addition to your usual sense-making, include a reasonable graph.

homework:ph320422questions:etovb

2018-04-20T16:55:28-08:00

Find the charge density. In addition to your usual sense-making, include a reasonable graph.

homework:ph320422questions:etoz

2015-10-01T11:38:26-08:00

Use \textsl{Mathematica} to plot the real and imaginary parts of $e^z$ for $z=x+iy$, $x$ and $y$ real.

homework:ph320422questions:euler

2015-09-27T17:09:28-08:00

Use Euler's formula $e^{i\theta}=\cos\theta+i\sin\theta$ and its complex conjugate to find formulas for $\sin\theta$ and $\cos\theta$. In your physics career, you will often need to read these formula ``backwards,'' i.e. notice one of these combinations of exponentials in a sea of other symbols and say, ``Ah ha! that is $\cos\theta$.'' So, pay attention to the result of the homework problem!

homework:ph320422questions:expformpractice

2015-09-27T17:09:28-08:00

For each of the following complex numbers $z$, find $z^2$, $\vert z\vert^2$, and rewrite $z$ in exponential form, i.e. as a magnitude times a complex exponential phase: \begin{description} \item $z_1=i$, \item $z_2=2+2i$, \item $z_3=3-4i$. \end{description}

homework:ph320422questions:factorexp

2015-09-23T18:12:15-08:00

Express $e^{i\omega t/2}-e^{-i3\omega t/2}$ in rectangular ($x+iy$) and exponential ($re^{i\theta}$) forms. ($\omega t$ is real \& $\sin(\omega t)>0$)

homework:ph320422questions:finitediska

2009-09-22T09:20:47-08:00

Starting with the integral expression for the electrostatic potential due to a ring of charge, find the value of the potential everywhere along the axis of symmetry.

homework:ph320422questions:finitediskb

2009-09-22T09:20:47-08:00

Find the electrostatic potential everywhere along the axis of symmetry due to a finite disk of charge with uniform (surface) charge density $\sigma$. Start with your answer to part (a)

homework:ph320422questions:finitediskc

2009-09-22T09:20:47-08:00

Find two nonzero terms in a series expansion of your answer to part (b) for the value of the potential very far away from the disk.

homework:ph320422questions:fluxcube

2013-10-29T20:12:27-08:00

A charge $q$ sits at the corner of a cube. Find the flux of $\EE$ through each side of the cube. Do not do a long calculation (either by hand or by computer)!

homework:ph320422questions:fluxcylinder

2011-02-22T11:24:02-08:00

What do you think will be the flux through the cylindrical surface that is placed as shown in the constant vector field in the figure on the left? What if the cylinder is placed upright, as shown in the figure on the right? Explain. [Figure: first cylinder] [Figure: second cylinder]

homework:ph320422questions:fluxparaboloid

2019-04-21T22:13:33-08:00

Find the upward pointing flux of the electric field $\Vec E =E_0\, z\, \hat z$ through the part of the surface $z=-3 r^2 +12$ (cylindrical coordinates) that sits above the $(x, y)$--plane.

homework:ph320422questions:gausslaw

2018-04-20T16:55:28-08:00

A positively charged dielectric cylindrical shell of inner radius $a$ and outer radius $b$ has a cylindrically symmetric internal charge density $$\rho = 3\,\alpha \; \sin\left(\frac{\pi(s-a)}{b-a}\right)$$ where $\alpha$ is a constant with appropriate dimensions.

homework:ph320422questions:gausslawa

2009-11-11T09:05:37-08:00

Sketch the charge density and find the total charge on the shell.

homework:ph320422questions:gausslawb

2009-09-30T11:28:48-08:00

Write the volume charge density everywhere in space as a single function.

homework:ph320422questions:gausslawc

2018-04-20T16:55:28-08:00

Use Gauss's Law and symmetry arguments to find the electric field in each of the regions given below: (i) $s < a$ (ii) $a < s < b$ (iii) $s > b$

homework:ph320422questions:gausslawd

2018-04-20T16:55:28-08:00

Sketch the $s$-component of the electric field as a function of $s$.

homework:ph320422questions:gausslawdifferential

2019-04-26T17:06:52-08:00

For an infinitesimally thin cylindrical shell of radius $b$ with uniform surface charge density $\sigma$, the electric field is zero for $s b$. Use Gauss' Law to find the charge density everywhere in space.

homework:ph320422questions:gausslawlimit

2018-04-20T16:55:28-08:00

Referring to the charge distribution in the Gauss's Law problem which you have solved above, take the limit as $a\to b$ so that the shell becomes infinitely thin, but keeping the total charge on a unit length of the cylinder constant. Redo each part of the previous problem for this situation.

homework:ph320422questions:gausslawlimita

2012-10-26T18:10:50-08:00

Find the surface charge density on the shell.

homework:ph320422questions:gausslawlimitb

2012-10-12T23:47:58-08:00

Write the volume charge density everywhere in space as a single function. Be careful: Integrate your charge density to get the total charge as a check.

homework:ph320422questions:gausslawlimitc

2018-04-20T16:55:28-08:00

Use Gauss's Law and symmetry arguments to find the electric field at each region given below: (i) $s < b$ (ii) $s > b$

homework:ph320422questions:gausslawlimitchallenge

2009-09-30T11:28:48-08:00

Take the limits of the shell in the previous problem as $a\to b$ and then $b\to0$, so that the shell becomes a charged line, but keeping the total charge on a unit length of the cylinder constant.

homework:ph320422questions:gausslawlimitchallengea

2009-09-30T11:28:48-08:00

Find the charge density on the line.

homework:ph320422questions:gausslawlimitchallengeb

2009-09-30T11:28:48-08:00

Give a formula for the charge density everywhere in space. Be careful: Integrate your charge density to get the total charge as a check.

homework:ph320422questions:gausslawlimitchallengec

2009-09-30T11:28:48-08:00

Use Gauss's Law and symmetry arguments to find the electric field for $r>0$.

homework:ph320422questions:gausslawlimitd

2018-04-20T16:55:28-08:00

Sketch the $s$-component of the electric field as a function of $s$.

homework:ph320422questions:gausslawlimite

2018-04-20T16:55:28-08:00

Compare the surface charge density on the shell to the discontinuity in the $s$-component of the electric field.

homework:ph320422questions:gausslawsymmetry

2012-10-12T23:47:58-08:00

%Adapted from Colorado Clicker Questions 4 and 5 Below are 4 surfaces (I, II, III, and IV) that are coaxial with an infinitely long line of charge with uniform charge density $\lambda$.\\ For this problem, explanations will count for the majority of the points.

homework:ph320422questions:gausslawsymmetrya

2015-10-16T14:31:48-08:00

Which of these surfaces have $\Phi_E=\frac{\lambda L}{\epsilon_0}$? How do you know?

homework:ph320422questions:gausslawsymmetryb

2012-10-12T23:47:58-08:00

For which of these Gaussian surfaces will Gauss' Law in help us to calculate $\vec{E}$ at point $P$ due to the line of charge. (Point $P$ is at the top center of each Gaussian surface)? How do you know?

homework:ph320422questions:graddivcurldescription

2014-10-16T09:06:31-08:00

What comes to mind when you think about divergence? Write down everything you know which includes various notations, formulas, properties, definitions, representations, and physics examples.

homework:ph320422questions:gradientpractice

2014-10-10T16:05:42-08:00

Find the gradient of each of the following functions:

homework:ph320422questions:gradientpracticea

2014-10-10T16:05:42-08:00

$$f(x,y,z)=e^{(x+y)}+x^2 y^3 \ln \frac{x}{z}$$

homework:ph320422questions:gradientpracticeb

2014-10-10T16:05:42-08:00

$$\sigma(\theta,\phi)=\cos\theta \sin^2\phi$$

homework:ph320422questions:gradientpracticec

2014-10-10T16:05:42-08:00

$$\rho(s,\phi,z)=(s+3z)^2\cos\phi$$

homework:ph320422questions:gradientptcharge

2012-09-23T14:04:57-08:00

Consider the fields at a point $\rr$ due to a point charge located at $\rr'$.

homework:ph320422questions:gradientptchargea

2011-11-22T18:33:12-08:00

Write down an expression for the electrostatic potential $V(\rr)$ at a point $\rr$ due to a point charge located at $\rr'$. (There is nothing to calculate here.)

homework:ph320422questions:gradientptchargeb

2011-11-22T18:33:12-08:00

Write down an expression for the electric field $\EE(\rr)$ at a point $\rr$ due to a point charge located at~$\rr'$. (There is nothing to calculate here.)

homework:ph320422questions:gradientptchargec

2011-11-22T18:33:12-08:00

Working in rectangular coordinates, compute the gradient of $V$.

homework:ph320422questions:gradientptcharged

2009-08-21T17:29:03-08:00

Write several sentences comparing your answers to the last two questions.

homework:ph320422questions:gradientptchargeorigin

2014-10-10T16:05:42-08:00

The electrostatic potential due to a point charge at the origin is given by: $$V=\frac{1}{4\pi\epsilon_0} \frac{q}{r}$$

homework:ph320422questions:gradientptchargeorigina

2014-10-10T16:05:42-08:00

Find the electric field due to a point charge at the origin as a gradient in rectangular coordinates.

homework:ph320422questions:gradientptchargeoriginb

2014-10-10T16:05:42-08:00

Find the electric field due to a point charge at the origin as a gradient in spherical coordinates.

homework:ph320422questions:gradientptchargeoriginc

2014-10-10T16:05:42-08:00

Find the electric field due to a point charge at the origin as a gradient in cylindrical coordinates.

homework:ph320422questions:helix

2010-11-07T05:24:09-08:00

A helix with 17 turns has height $H$ and radius $R$. Charge is distributed on the helix so that the charge density increases like the square of the distance up the helix. At the bottom of the helix the linear charge density is $0~{\hbox{C}\over\hbox{m}}$. At the top of the helix, the linear charge density is $13~{\hbox{C}\over\hbox{m}}$. What is the total charge on the helix?

homework:ph320422questions:icecreammass

2009-08-21T07:20:50-08:00

Use integration to find the total mass of ice cream in a packed cone (both cone and hemisphere of ice cream on top).

homework:ph320422questions:infinitedisk

2009-09-22T09:20:47-08:00

Find the electrostatic potential due to an infinite disk, using your results from the finite disk problem.

homework:ph320422questions:integrategravpotential

2016-08-25T16:41:34-08:00

The change in gravitational potential energy can be found by integrating $$\Delta U=\int_{r_i}^{r_f}{G\frac{m_1m_2}{r^2}dr}$$ where $G$ is the gravitational constant, $m_1$ and $m_2$ are masses, and $r$ is the distance between the two masses.

homework:ph320422questions:integrategravpotentiala

2018-03-30T09:54:38-08:00

Perform the integration, showing all steps.

homework:ph320422questions:integrategravpotentialb

2014-09-20T13:50:43-08:00

Plot the potential energy, $\Delta U$, as the mass, $m_1$, varies. Label significant points on the plot and describe (in words) the behavior.

homework:ph320422questions:integrategravpotentialc

2014-09-20T13:50:43-08:00

Plot the potential energy, $\Delta U$, as the final distance, $r_f$, varies. Label significant points on the plot and describe the behavior.

homework:ph320422questions:laplace

2018-05-02T17:18:45-08:00

Consider the bounded two-dimensional region from class. Three sides are metal and held at $V = 0$ while one is an insulator on which the potential is known to be: $V(x, b) = V_0\left(\sin\left(\frac{\pi x}{a}\right) + \sin\left(\frac{2\pi x}{a}\right) - \sin\left(\frac{3\pi x}{a}\right) \right)$

homework:ph320422questions:laplacea

2018-05-02T17:18:45-08:00

Starting from the general solution from the practice problem, find a symbolic expression for the potential $V(x, y)$.

homework:ph320422questions:laplaceb

2018-05-02T17:18:45-08:00

Make several plots of your solution and discuss any interesting features you find. (I particularly recommend both surface plots and plots of $x$- and $y$-cross sections at several different values.)

homework:ph320422questions:laplacec

2018-05-02T17:18:45-08:00

Suppose that the fourth side of the region is also a conductor at constant potential $V_0$. Find a symbolic expression for $V(x, y)$, graph your solution, and discuss its features.

homework:ph320422questions:laplacepractice

2018-05-02T17:18:45-08:00

Laplace's equation in two dimensions is: $\frac{\partial^2 V}{\partial x^2} + \frac{\partial^2 V}{\partial y^2} = 0$. Assume the region if interest is a rectangle of width $a$ and height $b$.

homework:ph320422questions:laplacepracticea

2018-05-02T17:18:45-08:00

Use separation of variables to find the general solution to Laplace's equation in two dimensions.

homework:ph320422questions:laplacepracticeb

2018-05-02T17:18:45-08:00

Suppose three of the boundaries ($x=0$, $x=a$, and $y=0$) are known to have $V=0$. Find the general solution in this case.

homework:ph320422questions:laplacepracticec

2018-05-02T17:18:45-08:00

Suppose only one boundary ($y=0$) is known to have $V=0$, and that two boundaries ($x=0$ and $x=a$) are known to have $\frac{\partial V}{\partial x} = 0$. Find the general solution in this case.

homework:ph320422questions:linesources

2012-10-12T23:47:58-08:00

Consider the fields around both finite and infinite uniformly charged, straight wires.

homework:ph320422questions:linesourcesa

2011-11-22T18:33:12-08:00

Find the electric field around an infinite, uniformly charged, straight wire, starting from the expression for the electrostatic potential that we found in class: $$V(\Vec r)={2\lambda\over 4\pi\epsilon_0}\, \ln{ r_0\over r}$$ Compare your result to the solution found from Coulomb's law. Which method is easier?

homework:ph320422questions:linesourcesb

2011-11-22T18:33:12-08:00

Find the electric field around a finite, uniformly charged, straight wire, at a point a distance $r$ straight out from the midpoint, starting from the expression for the electrostatic potential that we found in class: $$V(\Vec r)={\lambda\over 4\pi\epsilon_0} \left[\ln{\left(L + \sqrt{L^2+r^2}\right)}- \ln{\left(-L + \sqrt{L^2+r^2}\right)}\right]$$

homework:ph320422questions:linesourcesc

2009-08-22T08:26:57-08:00

Find the electric field around an infinite, uniformly charged, straight wire, starting from Coulomb's Law.

homework:ph320422questions:linesourcesd

2019-04-21T22:13:33-08:00

Find the electric field around a finite, uniformly charged, straight wire, at a point a distance $s$ straight out from the midpoint, starting from Coulomb's Law.

homework:ph320422questions:linesourcesgradonlya

2014-10-10T16:05:42-08:00

Find the electric field around an infinite, uniformly charged, straight wire, starting from the following expression for the electrostatic potential: $$V(\Vec r)={2\lambda\over 4\pi\epsilon_0}\, \ln{ s_0\over s}$$ %Compare your result to the solution found from Coulomb's law. Which method is easier?

homework:ph320422questions:mathematicaintegrals

2018-03-30T09:56:07-08:00

Use Mathematica to find the following integrals. \begin{eqnarray*} I_1&=&\int_0^{\sqrt{2\pi}}\sin\left(x^2\right)dx\\ I_2&=&\int_{-1}^1\int_0^{1-x^2}{\sin\left(xy\right)dy}dx\\ I_3&=&\int\sinh\left(kx\right)dx\\ I_4&=&\int_0^{2\pi}\frac{dx}{\sqrt{1-A\cos\left(x\right)}}\\ \end{eqnarray*}

homework:ph320422questions:mathematicaplot

2018-03-30T09:54:38-08:00

Use Mathematica to plot (and print out) each of the following functions: \begin{eqnarray*} f_1(x)&=&\sin\left(x^3\right)\\ f_2(x)&=&\frac{e^x}{x^3}\\ f_3(x,y)&=&\sinh\left(y\right)\\ f_4(x,y)&=&\sin\left(x+y\right)^3 \end{eqnarray*} Make sure you use best practices for creating plots: all plots should have a title, labeled axes (with units, when appropriate), and a domain and range that include the interesting behaviors of the function.

homework:ph320422questions:mathematicapractice

2018-03-30T09:54:38-08:00

If you are unfamiliar with Mathematica and you have not already done so, go through the following tutorials: More detailed information can be found at:

homework:ph320422questions:moremathematica

2019-04-05T17:13:18-08:00

Use Mathematica to make a contour plot of the electric potential in the $xy$-plane due to a single point charge located at the origin. Make sure to label your plot in a sensible way, including indicating the values you used for any unknown parameters (make sure you choose reasonable values).

homework:ph320422questions:multipole

2009-09-21T21:33:08-08:00

Find the distance $\left\vert\rr -\rr'\right\vert$ between the point $\rr$ and the point $\rr'$ in terms of the magnitudes of $\rr$ and $\rr'$ and $\gamma$, the angle between them. (Do not choose a coordinate system.) Then assuming that $\rr>>\rr'$, find a series expansion for $\left\vert\rr -\rr'\right\vert$, correct to fourth order. This expansion is the basis of multipole expansions, used in both electromagnetic theory and quantum mechanics.

homework:ph320422questions:murdermystery

2019-04-21T22:13:33-08:00

(Throughout this problem, assume all of the constants-including invisible factors of 1-carry the necessary dimensions so that the fields in this problem are dimensionally correct.) Consider the vector field in rectangular coordinates: $$\vec{E} = \frac{q}{4 \pi \epsilon_{0}} [(2 x y^3z+z)\hat{x} + (3x^2 y^2 z) \hat{y}+(x^2 y^3+x)\hat{z}]$$

homework:ph320422questions:murdermysterya

2018-04-20T16:55:28-08:00

Using only the $x$-component of $\vec{E}$, find as much information as possible about the potential from which this electric field might have come.

homework:ph320422questions:murdermysteryb

2018-04-20T16:55:28-08:00

Repeat this exercise for the $y$- and $z$-components of $\vec{E}$. Does this field come from a potential?

homework:ph320422questions:murdermysteryc

2018-04-20T16:55:28-08:00

Consider the different vector field: $$\vec{E} = \frac{q}{4 \pi \epsilon_{0}} (-y \hat{x} + x \hat{y})$$ Does this field come from a potential?

homework:ph320422questions:murdermysteryd

2018-04-20T16:55:28-08:00

Consider the different vector field: $$\vec{E}=\frac{q}{4 \pi \epsilon_{0}} \left(s \hat{\phi}\right)$$ Does this field come from a potential?

homework:ph320422questions:nonuniformdiskQE

1969-12-31T16:00:00-08:00

homework:ph320422questions:nonuniformdiskQEa

1969-12-31T16:00:00-08:00

homework:ph320422questions:nonuniformdiskQEb

1969-12-31T16:00:00-08:00

homework:ph320422questions:onions

2014-10-01T17:53:19-08:00

Find the derivative of the following functions (and make sure that you can do similar problems with different combinations of the common transcendental functions): \begin{eqnarray*} f(x)&=&\sin\left(x^3\right)\\ f(x)&=&\frac{e^x}{x^3} \end{eqnarray*}

homework:ph320422questions:pathindependence

2019-04-21T22:13:33-08:00

The gravitational field due to a spherical shell of mass is given by: %/* \[ \Vec g =\begin{cases} 0&r

homework:ph320422questions:pathindependencea

2012-10-31T17:31:12-08:00

Using an explicit line integral, calculate the work required to bring a test mass, of mass $m_0$, from infinity to a point $P$, which is a distance $c$ (where $c>a$) from the center of the shell. [Figure: integration paths for parts a), b), and c)]

homework:ph320422questions:pathindependenceb

2009-10-01T21:06:22-08:00

Using an explicit line integral, calculate the work required to bring the test mass along the same path, from infinity to the point $Q$ a distance $d$ (where $b

homework:ph320422questions:pathindependencec

2009-10-01T21:06:22-08:00

Using an explicit line integral, calculate the work required to bring the test mass along the same radial path from infinity all the way to the center of the shell.

homework:ph320422questions:pathindependenced

2012-10-31T17:31:12-08:00

Using an explicit line integral, calculate the work required to bring in the test mass along the path drawn below, to the point $P$ of question a. Compare the work to your answer from question a. [Figure: integration path for parts d)]

homework:ph320422questions:pathindependencee

2012-10-31T17:31:12-08:00

What is the work required to bring the test mass from infinity along the path drawn below to the point $P$ of question a. Explain your reasoning. [Figure: integration paths for part e)]

homework:ph320422questions:pdm1d

2014-09-20T13:50:43-08:00

From your data collected in class using the ``Derivative Machine”, calculate the internal energy at five points. Show calculations and draw a graphical representation of the data. Include a brief discussion (using strong scientific writing) on the chosen step size in your data and the dependency of your variables. Briefly describe another procedure which could be used to measure the same integral with your machine.

homework:ph320422questions:pdm1dderivlab

2014-10-01T17:53:19-08:00

For the data you collected from the derivatives machine, write a short but clear report finding the derivative $$\frac{dx}{dF}$$ Decide for yourself what sections you need in your report. At a minimum, include a clear statement of the problem you are trying to solve, a description of how you collected your data, the data itself, a clear description of how you analyzed the data, and a clear statement of what you can conclude from your analysis. Use a combination of words interlaced with other…

homework:ph320422questions:pdm1dintlab

2016-08-25T13:33:07-08:00

For the data you collected from the integration machine, or you can use our data listed below, write a short but clear report finding the potential energy stored in the machine. Decide for yourself what sections you need in your report. At a minimum, include a clear statement of the problem you are trying to solve, a description of the apparatus, a description of how you collected your data, the data itself, a clear description of how you analyzed the data, and a clear statement of what you c…

homework:ph320422questions:potentialconegem227

2011-11-22T18:33:12-08:00

A conical surface (an empty ice-cream cone) carries a uniform charge density $\sigma$. The height of the cone is $a$, as is the radius of the top. Find the potential at point $P$ (in the center of the opening of the cone), letting the potential at infinity be zero.

homework:ph320422questions:potentialvsenergy

2009-08-19T15:35:04-08:00

In this course, two of the primary examples we will be using are the force due to gravity and the force due to an electric charge. Both of these forces vary like $1/r^2$, so they will have many, many similarities. Most of the calculations we do for the one case will be true for the other. But there are some extremely important differences:

homework:ph320422questions:potentialvsenergya

2009-08-19T15:35:04-08:00

Find the value of the electric potential energy of a system consisting of a hydrogen nucleus and an electron separated by the Bohr radius. Find the value of the gravitational potential energy of the same two particles at the same radius. Use the same system of units in both cases. Compare and the contrast the two answers.

homework:ph320422questions:potentialvsenergyb

2009-08-19T15:35:04-08:00

Find the value of the electric potential due to the nucleus of a hydrogen atom at the Bohr radius. Find the gravitational potential due to the nucleus at the same radius. Use the same system of units in both cases. Compare and contrast the two answers.

homework:ph320422questions:potentialvsenergyc

2009-08-19T15:35:04-08:00

Think of and briefly discuss at least one other fundamental difference between electromagnetic and gravitational systems. Hint: Why are we bound to the earth gravitationally, but not electromagnetically?

homework:ph320422questions:quadrupole

2009-08-20T14:50:36-08:00

Consider a series of three charges arranged in a line along the $z$-axis, charges $+Q$ at $z=\pm D$ and charge $-2Q$ at $z=0$.

homework:ph320422questions:quadrupolea

2019-04-10T20:38:12-08:00

Find the electrostatic potential at a point $P$ in the $xy$-plane at a distance $s$ from the center of the quadrupole.

homework:ph320422questions:quadrupoleb

2019-04-10T20:38:12-08:00

Assume $s>>D$. Find the first two non-zero terms of a power series expansion to the electrostatic potential you found in the first part of this problem.

homework:ph320422questions:quadrupolec

2009-08-20T14:50:36-08:00

Is it possible to find the electric field at $P$ from your answer to the first part of the problem? If you answered that it is possible, find the electric field. If you answered that it is not possible, explain your answer.

homework:ph320422questions:quadrupoled

2009-08-20T14:50:36-08:00

A series of charges arranged in this way is called a linear quadrupole. Why?

homework:ph320422questions:quizangle

2015-09-28T16:09:01-08:00

Find the location of the point in both rectangular and polar coordinates. (Similarly be able to find the sine and cosine of any angle which is a multiple of $\frac{\pi}{4}$ or $\frac{\pi}{6}$). \begin{tikzpicture} \begin{axis}[width=3.5in, xtick={-2,-1,...,1}, ytick={-1,0,...,2},

homework:ph320422questions:quizarea

2019-04-13T08:58:46-08:00

Find the area element $dA$ on a surface of high symmetry such as the top or side of a cylinder or the curved or flat surface of a hemisphere.

homework:ph320422questions:quizcrossproduct

2012-10-12T23:47:58-08:00

Are the following equalities true or false? Why?

homework:ph320422questions:quizcrossproducta

2012-10-12T23:47:58-08:00

\begin{equation*} \hat{y} \cdot \hat{z}=\hat{x} \end{equation*}

homework:ph320422questions:quizcrossproductb

2020-01-24T19:13:42-08:00

\begin{equation*} \hat{r}_{\text{cyl}} \times \hat{z}=-\hat{\phi} \end{equation*}

homework:ph320422questions:quizcrossproductc

2020-01-24T19:13:42-08:00

\begin{equation*} \hat{r}_{\text{sph}} \times \hat{\phi}=\hat{\theta} \end{equation*}

homework:ph320422questions:quizcrossproductd

2012-10-12T23:47:58-08:00

\begin{equation*} \hat{r}\cdot \hat{\theta}=1 \end{equation*}

homework:ph320422questions:quizdel

2012-10-12T23:47:58-08:00

Which of the following are valid operations? How do you know?

homework:ph320422questions:quizdela

2012-10-12T23:47:58-08:00

\begin{equation*} \vec{\nabla}\cdot\left(\vec{\nabla}F\right) \end{equation*}

homework:ph320422questions:quizdelb

2012-10-12T23:47:58-08:00

\begin{equation*} \vec{\nabla}\left(\vec{\nabla}\times \vec{F}\right) \end{equation*}

homework:ph320422questions:quizdelc

2012-10-12T23:47:58-08:00

\begin{equation*} \vec{\nabla}\times \left(\vec{\nabla}\cdot \vec{F}\right) \end{equation*}

homework:ph320422questions:quizdeld

2012-10-12T23:47:58-08:00

\begin{equation*} \vec{\nabla}\cdot\left(\vec{\nabla}\times \vec{F}\right) \end{equation*}

homework:ph320422questions:quizdele

2012-10-12T23:47:58-08:00

\begin{equation*} \vec{\nabla}\times \left(\vec{\nabla}\times \vec{F}\right) \end{equation*}

homework:ph320422questions:quizdelta

2012-10-12T23:47:58-08:00

Are the following equalities true or false? Why?

homework:ph320422questions:quizdeltaa

2014-09-20T12:30:40-08:00

$\frac{d}{dx} \Theta(x-a)=\delta(x-a)$

homework:ph320422questions:quizdeltab

2012-10-12T23:47:58-08:00

\begin{equation*} \int_{-\infty}^{+\infty}\delta(x)\,dx=0 \end{equation*}

homework:ph320422questions:quizdeltac

2012-10-12T23:47:58-08:00

\begin{equation*} x\,\delta(x)=0 \end{equation*}

homework:ph320422questions:quizdeltad

2012-10-12T23:47:58-08:00

\begin{equation*} \Theta(x-a)=\int_{-\infty}^{x}\delta(u-a)\,du \end{equation*}\\

homework:ph320422questions:quizdifferential

2012-10-26T18:10:50-08:00

Find the total differential $df$ for each of the following functions.

homework:ph320422questions:quizdifferentiala

2012-10-26T18:10:06-08:00

\begin{equation*} f=xyz \end{equation*}

homework:ph320422questions:quizdifferentialb

2012-10-26T18:10:06-08:00

\begin{equation*} f=\sqrt{x^2+y^2+z^2} \end{equation*}

homework:ph320422questions:quizdifferentialc

2012-10-26T18:10:06-08:00

\begin{equation*} f=r\,\tan(2\theta) \end{equation*}

homework:ph320422questions:quizdifferentiald

2012-10-26T18:10:06-08:00

\begin{equation*} f=z\,e^{(x^2+y^2)/a^2} \end{equation*}

homework:ph320422questions:quizdifferentiale

2012-10-26T18:10:06-08:00

\begin{equation*} f=Nk\ln\left[\frac{(V-Nb)T^{3/2}}{N\Phi}\right]+\frac{5}{2}Nk \end{equation*}

homework:ph320422questions:quizdotproduct

2012-10-12T23:47:58-08:00

Are the following equalities true or false? Why?

homework:ph320422questions:quizdotproducta

2012-10-12T23:47:58-08:00

\begin{equation*} \left(\hat{x}-\hat{z} \right)\cdot \hat{x}=-1 \end{equation*}

homework:ph320422questions:quizdotproductb

2012-10-12T23:47:58-08:00

\begin{equation*} \left(\hat{x}-\hat{z} \right)\times \hat{x}=-\hat{y} \end{equation*}

homework:ph320422questions:quizdotproductc

2012-10-12T23:47:58-08:00

\begin{equation*} \left(\hat{x}+\hat{y} \right)\cdot \hat{z}=0 \end{equation*}

homework:ph320422questions:quizdotproductd

2012-10-12T23:47:58-08:00

\begin{equation*} \left(\hat{x}+\hat{y} \right)\times \hat{z}=\hat{x}+\hat{y} \end{equation*}

homework:ph320422questions:quizdr

2012-10-12T23:47:58-08:00

Write $\vec{dr}$ in rectangular, cylindrical, and spherical coordinates. \begin{enumerate} \item Rectangular: $\vec{dr}=$\\ \item Cylindrical: $\vec{dr}=$\\ \item Spherical: $\vec{dr}=$\\ \end{enumerate}

homework:ph320422questions:quizintegrals

2012-10-12T23:47:58-08:00

Evaluate the following indefinite integrals.

homework:ph320422questions:quizintegralsa

2012-10-12T23:47:58-08:00

\begin{equation*} \int \sin(x)\, dx \end{equation*}

homework:ph320422questions:quizintegralsb

2012-10-12T23:47:58-08:00

\begin{equation*} \int \frac{1}{x}\, dx \end{equation*}

homework:ph320422questions:quizintegralsc

2012-10-12T23:47:58-08:00

\begin{equation*} \int e^{kx}\, dx \end{equation*}

homework:ph320422questions:quizintegralsd

2012-10-12T23:47:58-08:00

\begin{equation*} \int \left(x^2+\frac{y}{x^2}\right)\, dx \end{equation*}\\

homework:ph320422questions:quizpotential

2012-10-26T18:10:06-08:00

You have a charge distribution composed of two point charges along the $z$-axis: one with charge $+3q$ located at $z=-a$ and the other with charge $-q$ located at $z=+b$. Write down the electrostatic potential at every point in space due to these two charges in rectangular, cylindrical, and spherical coordinates.

homework:ph320422questions:quizpotentiala

2012-10-26T18:10:06-08:00

Rectangular: $V(\vec{r})=$\\

homework:ph320422questions:quizpotentialb

2012-10-26T18:10:06-08:00

Cylindrical: $V(\vec{r})=$\\

homework:ph320422questions:quizpotentialc

2012-10-26T18:10:06-08:00

Spherical: $V(\vec{r})=$\\

homework:ph320422questions:quizproductrules

2012-10-12T23:47:58-08:00

Are the following equalities true or false? Why?

homework:ph320422questions:quizproductrulesa

2012-10-12T23:47:58-08:00

\begin{equation*} \hat{y} \times \hat{z}=\hat{x} \end{equation*}

homework:ph320422questions:quizproductrulesb

2012-10-12T23:47:58-08:00

\begin{equation*} \hat{y} \times \hat{z}=\hat{x} \end{equation*}

homework:ph320422questions:quizproductrulesc

2012-10-12T23:47:58-08:00

\begin{equation*} \hat{y} \times \hat{z}=\hat{x} \end{equation*}

homework:ph320422questions:quizseriesmemorize

2016-08-25T16:44:39-08:00

Be able to give the first four nonzero terms of the power series for $\sin z$, $\cos z$, $e^z$, $\ln(1+z)$, and $(1+z)^p$.

homework:ph320422questions:quizusewhatyouknow

2012-10-12T23:47:58-08:00

What is $\vec{dr}$ along the path $y=x^3$?

homework:ph320422questions:quizvolume

2019-04-13T08:58:46-08:00

Write the volume element $d\tau$ in rectangular, cylindrical, and spherical coordinates. \begin{enumerate} \item Rectangular: $d\tau=$\\ \item Cylindrical: $d\tau=$\\ \item Spherical: $d\tau=$\\ \end{enumerate}

homework:ph320422questions:remember

2011-11-22T18:33:12-08:00

Briefly describe in words something you learned from doing this problem that you would like to remember for the future. Make your statement using good scientific writing, as you would in a research paper.

homework:ph320422questions:repulsionns

2011-12-06T10:17:51-08:00

A metal sphere of radius $R$ carries a total charge $Q$. What is the force of repulsion between the ``northern” hemisphere and the ``southern” hemisphere?

homework:ph320422questions:sensemaking

2011-10-16T20:18:41-08:00

Use some form of sensemaking to evaluate your answer, e.g.\ check the units or dimensions, check the size of your answer, check a limiting case, compare to other known cases, etc.

homework:ph320422questions:seriesconvergence

2020-01-22T09:21:18-08:00

Recall that, if you take an infinite number of terms, the series for $\sin z$ and the function itself $f(z)=\sin z$ are equivalent representations of the same thing for all real numbers $z$, (in fact, for all complex numbers $z$). This is not always true. More commonly, a series is only a valid, equivalent representation of a function for some more restricted values of $z$. The technical name for this idea is convergence--the series only “converges” to the value of the function on some res…

homework:ph320422questions:seriesconvergenceMaple

1969-12-31T16:00:00-08:00

homework:ph320422questions:seriesnotation1

2009-08-19T21:30:41-08:00

Write out the first four nonzero terms in the series:

homework:ph320422questions:seriesnotation1a

2009-08-19T21:30:41-08:00

$$\sum\limits_{n=0}^\infty {1\over n!}$$

homework:ph320422questions:seriesnotation1b

2009-08-19T21:30:41-08:00

$$\sum\limits_{n=1}^\infty {(-1)^n\over n!}$$

homework:ph320422questions:seriesnotation2

2009-08-19T21:30:41-08:00

Write the following series using sigma $\left(\sum\right)$ notation.

homework:ph320422questions:seriesnotation2a

2009-08-19T21:30:41-08:00

$$1 - 2\,\theta^2 + 4\,\theta^4 - 8\,\theta^6 +\,\dots$$

homework:ph320422questions:seriesnotation2b

2009-08-19T21:30:41-08:00

$${1\over4} - {1\over9} + {1\over16} - {1\over 25}+\,\dots$$

homework:ph320422questions:seriesnotation3

2009-08-19T21:30:41-08:00

If you need more practice with sigma $\left(\sum\right)$ notation, you can get really good practice by going back and forth between the two representations of the standard power series on the memorization page. Power series are used everywhere in physics and it is very important to be able to translate back and forth between the two representations.

homework:ph320422questions:slabmass

2009-09-30T08:49:24-08:00

Determine the total mass of each of the slabs below.

homework:ph320422questions:slabmassa

2009-09-30T08:49:24-08:00

A square slab of side length $L$ with thickness $h$, resting on a table top at $z=0$, whose mass density is given by $\rho=A\pi\sin(\pi z/h)$.

homework:ph320422questions:slabmassb

2009-09-30T08:49:24-08:00

A square slab of side length $L$ with thickness $h$, resting on a table top at $z=0$, whose mass density is given by \begin{equation} \rho = 2A \Big( \Theta(z)-\Theta(z-h) \Big) \end{equation}

homework:ph320422questions:slabmassc

2009-09-30T08:49:24-08:00

An infinitesimally thin square sheet of side length $L$, resting on a table top at $z=0$, whose surface density is given by $\sigma=2Ah$.

homework:ph320422questions:slabmassd

2009-09-30T08:49:24-08:00

An infinitesimally thin square sheet of side length $L$, resting on a table top at $z=0$, whose mass density is given by $\rho=2Ah\,\delta(z)$.

homework:ph320422questions:slabmasse

2011-10-25T16:55:50-08:00

What are the dimensions of $A$?

homework:ph320422questions:slabmassf

2011-10-25T16:55:50-08:00

Write several sentences comparing your answers to the different cases above.

homework:ph320422questions:squarehoopgem24

2018-05-02T17:18:45-08:00

Consider a square loop with each side length $a$ carrying a uniform linear charge density $\lambda$.

homework:ph320422questions:squarehoopgem24a

2009-08-22T08:57:21-08:00

Find the electric field a distance $z$ above the center of the square. (You may start with the electric field due to a single finite line of charge).

homework:ph320422questions:squarehoopgem24b

2009-08-22T08:57:21-08:00

Find the work needed to bring a charge in from infinity along the $z$-axis.

homework:ph320422questions:squarehoopgem24c

2018-05-02T17:18:45-08:00

Use two different methods to find the value of the electric potential a distance $z$ above the center of the square.

homework:ph320422questions:stokes

2018-05-21T11:06:57-08:00

In this problem, you will be investigating, from several different points of view, a cylindrical wire of finite thickness $R$, carrying a non-uniform current density $J=\kappa s$, where $\kappa$ is a constant and $s$ is the distance from the axis of the cylinder.\\

homework:ph320422questions:stokesa

2012-10-31T17:31:12-08:00

Find the total current flowing through the wire.\\

homework:ph320422questions:stokesb

2012-10-31T17:31:12-08:00

Find the current flowing through Disk 2, a central (circular cross-section) portion of the wire out to a radius $r_2

homework:ph320422questions:stokesc

2012-10-31T17:31:12-08:00

Use Amp\`ere's law in integral form to find the magnetic field at a distance $r_1$ outside the wire.\\

homework:ph320422questions:stokesd

2012-10-31T17:31:12-08:00

Use Amp\`ere's law in integral form to find the magnetic field at a distance $r_2$ inside the wire.\\

homework:ph320422questions:stokese

2012-10-31T17:31:12-08:00

Use theta functions to write the magnetic field everywhere (both inside and outside of the wire) as a single function.\\

homework:ph320422questions:stokesf

2012-10-31T17:31:12-08:00

Evaluate $$\int \left(\grad\times\BB\right)\cdot d\AA$$ for Disk 2, a circular disk of radius $r_2

homework:ph320422questions:stokesg

2012-10-31T17:31:12-08:00

Evaluate $$\int \left(\grad\times\BB\right)\cdot d\AA$$ for Disk 1, a circular disk of radius $r_1>R$. Use this result and part c) to verify Stokes' theorem on this surface.\\

homework:ph320422questions:stokesverify

2012-10-12T23:47:58-08:00

Verify Stokes' Theorem for $\FF( r, \theta, \phi)=e^{r^2} \hat{r} + {1\over 2}\sin\theta \,\hat{\phi}$ where the butterfly net surface is the hemisphere of radius 5 centered at the origin with $z\ge 0$.

homework:ph320422questions:symmetry

2013-05-09T13:02:00-08:00

For each of the following situations, can you use Gauss' Law to find the electric field at an arbitrary point, $P$, located outside of the charge distribution? \begin{itemize} \item If no, explain why not. \item If yes, \begin{itemize} \item draw the Gaussian surface you would use and describe why you chose that shape and orientation (\emph{i.e.} make explicit symmetry arguments), and \item use Gauss' Law to find the electric field at point $P$. \end{itemize} \end{itemize}

homework:ph320422questions:symmetrya

2013-05-09T13:02:00-08:00

A charged, insulating sphere of radius, $R$, with charge density $\rho (\vec{r})=C\,\sin\theta$. \medskip \centerline{\includegraphics[scale=0.55]{\TOP Figures/vfsymmetrya}} \medskip

homework:ph320422questions:symmetryb

2013-05-09T13:02:00-08:00

A neutral, infinitely long cylindrical metal shell with inner radius $a$ and outer radius $b$, with a charged wire of uniform charge density $\lambda$ at a distance $a/2$ out from the center of the cylinder, parallel to the cylinder's axis. \bigskip \centerline{\includegraphics[scale=0.55]{\TOP Figures/vfsymmetryb}} \bigskip

homework:ph320422questions:symmetryc

2015-10-16T14:31:48-08:00

A charged, insulating sphere of radius $R$ with charge density $\rho (\vec{r})=\frac{C}{r^2}$. \bigskip \centerline{\includegraphics[scale=0.55]{\TOP Figures/vfsymmetryc}} \bigskip

homework:ph320422questions:symmetryd

2013-05-09T13:02:00-08:00

An finite slab of width and length $L$, height $h$, and charge density $\rho(\vec{r})=C \,x^2$. \bigskip \centerline{\includegraphics[scale=0.55]{\TOP Figures/vfsymmetryd}} \bigskip

homework:ph320422questions:tetrahedron

2018-03-30T09:54:38-08:00

Using a dot product, find the angle between any two line segments that join the center of a regular tetrahedron to its vertices. Hint: Think of the vertices of the tetrahedron as sitting at the vertices of a cube (at coordinates (0,0,0), (1,1,0), (1,0,1) and (0,1,1)---you may need to build a model and play with it to see how this works!)

homework:ph320422questions:thetadeltaSJP

1969-12-31T16:00:00-08:00

homework:ph320422questions:thetadeltaSJPa

1969-12-31T16:00:00-08:00

homework:ph320422questions:thetadeltaSJPb

1969-12-31T16:00:00-08:00

homework:ph320422questions:thetaparameters

2009-10-01T21:28:20-08:00

The function $\theta(x)$ (the Heaviside or unit step function) is a defined as: \begin{eqnarray*} \theta(x) = \left\{ \begin{array}{l l} 1 & \quad \mbox{for $x>0$}\\ 0 & \quad \mbox{for $x<0$}\\ \end{array} \right. \end{eqnarray*} This function is discontinuous at $x=0$ and is generally taken to have a value of $\theta(0)=1/2$.

homework:ph320422questions:totalcharge

2009-08-21T07:20:50-08:00

For each case below, find the total charge.

homework:ph320422questions:totalchargea

2009-08-21T07:20:50-08:00

A positively charged (dielectric) spherical shell of inner radius $a$ and outer radius $b$ with a spherically symmetric internal charge density $\rho(\rr)=\alpha\, 3e^{(kr)^3}$

homework:ph320422questions:totalchargeb

2019-04-10T20:38:12-08:00

A positively charged (dielectric) cylindrical shell of inner radius $a$ and outer radius $b$ with a cylindrically symmetric internal charge density $\rho(\rr)=\alpha\, {1\over s}\, e^{ks}$.

homework:ph320422questions:totalcurrentchallenge

2012-10-26T18:10:06-08:00

For the surface current you found in Problem 1.a, find the magnetic vector potential at a distance $r$ from the center of the wire with length of $2L$.

homework:ph320422questions:totalcurrentgem55

2009-10-01T21:28:20-08:00

A current $I$ flows down a wire of radius $a$.

homework:ph320422questions:totalcurrentgem55a

2010-10-17T09:18:54-08:00

If it is uniformly distributed over the surface, give a formula for the surface current density $\Vec K$.

homework:ph320422questions:totalcurrentgem55b

2012-10-26T18:10:50-08:00

If it is distributed in such a way that the volume current density, $|\Vec J|$, is inversely proportional to the distance from the axis, give a formula for $\Vec J$.

homework:ph320422questions:totalcurrentpracticea

2012-10-26T18:10:06-08:00

Current $I$ flows down a wire (length $L$) with square cross-section (side $a$). If it is uniformly distributed over the entire area, what is the magnitudes of the volume current density $\vec{J}$?

homework:ph320422questions:totalcurrentpracticeb

2019-04-26T17:06:52-08:00

If it is uniformly distributed over the outer surfaces only, what is the magnitude of the surface current density $\vec{K}$?

homework:ph320422questions:triangleparameters

2009-09-30T08:49:24-08:00

Consider the function: \begin{eqnarray*} f(x) = 3x\,\theta(x)\,\theta(1-x)+(6-3x)\,\theta(x-1)\,\theta(2-x) \end{eqnarray*} Make sketches of the following functions, by hand, on the axes with the same scale and domain. Briefly describe, using good scientific writing that includes both words and equations, the role that the number two plays in the shape of each graph: \begin{eqnarray} y &=& f(x)\\ y &=& 2+f(x)\\ y &=& f(2+x)\\ y &=& 2f(x)\\ y &=& f(2x) \end{eqnarray}

homework:ph320422questions:trigparameters

2009-09-30T08:49:24-08:00

Make sketches of the following functions, by hand, all on the same axes. Briefly describe, using good scientific writing that includes both words and equations, the role that the number two plays in the shape of each graph: \begin{eqnarray} y &=& \sin x\\ y &=& 2+\sin x\\ y &=& \sin(2+x)\\ y &=& 2\sin x\\ y&=& \sin 2x \end{eqnarray}

homework:ph320422questions:v4chargessquare

2018-03-30T09:54:38-08:00

Four point charges sit at the corners of a square in the $xy$-plane. A positive point charge is located at $(a,a,0)$ and another is located at $(-a,a,0)$. A negative charge is located at $(-a,-a,0)$ and another is located at $(a,-a,0)$.

homework:ph320422questions:v4chargessquarea

2016-09-23T16:33:57-08:00

Find the electric potential at any point $(x,y,z)$.

homework:ph320422questions:v4chargessquareb

2018-03-30T09:54:38-08:00

Is the $yz$-plane an equipotential surface? Explain. If so, what is the value of the potential?

homework:ph320422questions:v4chargessquarec

2018-03-30T09:54:38-08:00

Is the $xz$-plane an equipotential surface? Explain. If so, what is the value of the potential?

homework:ph320422questions:v4chargessquared

2016-09-23T16:33:57-08:00

Do you expect any other equipotential surfaces to exist? Explain. If you do expect one or more equipotential surfaces, use the Mathematica function ContourPlot3D to plot one. All plots should include a title, axis labels and a legend if appropriate. Note: providing a plot does not count as an explanation for why you would expect an equipotential surface to exist.

homework:ph320422questions:vectorpotential

2018-05-02T17:18:45-08:00

Find the magnetic vector potential for a finite segment of straight wire, carrying a uniform current $I$. Put the wire on the $z$ axis, from $z_1$ to $z_2$. In addition to your usual sense-making, show the behavior of the vector potential using vector field maps.

homework:ph320422questions:vpsheet

2018-05-02T17:18:45-08:00

Find the magnetic vector potential for an infinite sheet of current (you may want to perform your integral by comparing it to the electric potential due to an infinite sheet of charge). In addition to your usual sense-making, show the behavior of the vector potential using vector field maps.

homework:ph320422questions:website

2019-04-05T17:13:18-08:00

Find the course website at \~{} corinne/COURSES/ph422. Read through it carefully and bring your questions to class. Don't forget to check out the Syllabus. Find the paradigms website at . Read through it carefully and bring your questions to class.

homework:ph320422questions:writingi

2010-10-17T20:45:29-08:00

Using the handout ``Guiding Questions for Science Writing” to suggest topics that you should address, write up your analysis of the activity entitled Electrostatic Potential From Two Charges. You do not need to do the calculations from every case, but your analysis should include some comparison of different cases, as we discussed in class after the activity. To help us with the grading process, please turn in this writing assignment stapled separately from your other homework.

homework:ph320422questions:writingii

2009-08-22T13:50:48-08:00

Using the handout ``Guiding Questions for Science Writing” as a guide, write up your solution for finding the electrostatic potential everywhere in space due to a uniform ring of charge. Be sure to include a series expansion along one of the axes of interest.

Portfolios Wiki homework:ph320422questions

homework:ph320422questions:DivCurl

homework:ph320422questions:DivCurla

homework:ph320422questions:DivCurlb

homework:ph320422questions:affirmation

homework:ph320422questions:amperecylinder

homework:ph320422questions:amperecylindera

homework:ph320422questions:amperecylinderb

homework:ph320422questions:amperecylinderc

homework:ph320422questions:amperecylinderd

homework:ph320422questions:amperelawdifferential

homework:ph320422questions:apracticea

homework:ph320422questions:apracticeb

homework:ph320422questions:bdirection

homework:ph320422questions:bfinitelinea

homework:ph320422questions:bfinitelineb

homework:ph320422questions:biotsavartchallenge

homework:ph320422questions:biotsavartcoils

homework:ph320422questions:biotsavartcoilsa

homework:ph320422questions:biotsavartcoilsb

homework:ph320422questions:biotsavartcoilsc

homework:ph320422questions:biotsavartlimitSJP

homework:ph320422questions:biotsavartlimitaSJP

homework:ph320422questions:biotsavartlimitambk

homework:ph320422questions:biotsavartlimitbSJP

homework:ph320422questions:biotsavartlimitbmbk

homework:ph320422questions:biotsavartlimitchallenge

homework:ph320422questions:biotsavartlimitmbk

homework:ph320422questions:biotsavartsquare

homework:ph320422questions:biotsavartsquarea

homework:ph320422questions:biotsavartsquareb

homework:ph320422questions:biotsavartsquarec

homework:ph320422questions:bmethod

homework:ph320422questions:bsymmetry

homework:ph320422questions:capacitor

homework:ph320422questions:capacitora

homework:ph320422questions:capacitorb

homework:ph320422questions:capacitorc

homework:ph320422questions:capacitord

homework:ph320422questions:chargegraph

homework:ph320422questions:circlevector

homework:ph320422questions:circlevectora

homework:ph320422questions:circlevectorb

homework:ph320422questions:circlevectorc

homework:ph320422questions:circlevectorpre

homework:ph320422questions:complexnum

homework:ph320422questions:complexnuma

homework:ph320422questions:complexnumb

homework:ph320422questions:complexnumc

homework:ph320422questions:complexnumd

homework:ph320422questions:complexrectangularpractice

homework:ph320422questions:complexrectangularpractice2

homework:ph320422questions:complexrectangularpracticea

homework:ph320422questions:complexrectangularpracticeb

homework:ph320422questions:complexrectangularpracticec

homework:ph320422questions:complexrectangularpracticed

homework:ph320422questions:complexrectangularpracticee

homework:ph320422questions:conductorsgem235

homework:ph320422questions:conductorsgem235a

homework:ph320422questions:conductorsgem235b

homework:ph320422questions:conductorsgem235c

homework:ph320422questions:conductorsgem235d

homework:ph320422questions:conductorsgem235modb

homework:ph320422questions:conesurface

homework:ph320422questions:contours

homework:ph320422questions:contoursa

homework:ph320422questions:contoursb

homework:ph320422questions:contoursc

homework:ph320422questions:contoursd

homework:ph320422questions:cosmicasimov

homework:ph320422questions:cosmicasimova

homework:ph320422questions:cosmicasimovb

homework:ph320422questions:cosmicasimovc

homework:ph320422questions:cosmicasimovd

homework:ph320422questions:cosmicasimove

homework:ph320422questions:cosmicasimovf

homework:ph320422questions:crosstriangle

homework:ph320422questions:cubecharge

homework:ph320422questions:cubechargea

homework:ph320422questions:cubechargeb