Homework Section 1

Homework Section 1

1) Analytically prove the following. (Do this for arbitrary dimension)

a) The commutative law: A + B = B + A

b) The Associative Law: A + (B + C) = (A+B) + C

c) A + B = C if and only if B = C - A

d) A + 0 = A and A - A = 0

e) Scalar product is commutative [A•B=B•A] and

f) Scalar product is distributive [A•(B+C)=A•B+A•C].



2) Prove that the area of a parallelogram with sides A and B is |A x B|. Note that

the surface area has a direction associated with it.



3) Prove that the volume of a parallelepiped with side A, B and C is A•(B x C).



4) Find the magnitude of the following vectors.

g) (1, 4)

h) (4, 3, 0)

i) (0, -1, 1)

j) (6, 1, 0, -1, 2)



5) Which of the following vectors are unit vectors?

k) (1, 0)

l) (1, 1/2)

m) (1, -1)

n) (1/√2, -1/√2)

o) (1/2, 0, √3/2)

p) (1, 0, 0, 0)



6) Express the vector A = (2, 7) as a linear combination of the vectors:

q) B1 = (2, 4), B2 = (-1, 3).

r) C1 = (4, 4), C2 = (5, 5).

Express the vector A = (2, -1, 3) as a linear combination of the vectors:

s) B1 = (2, 4, 1), B2 = (3, 7, 1).

t) C1 = (1, 0, 0), C2 = (0, 1, 0), C3 = (0, 0, 1).

u) D1 = (2, 4, 1), D2 = (3, 7, 1), D3 = (-1, 2, 2).



7) Show that in a 3-dimensional space, a set of three vectors A, B and C are

linearly independent if and only if

a1 a2 a3

b1 b2 b3  0 ;

c1 c2 c3

(Linear independence requires that: a A + b B + c C = 0 if and only if a, b, c

= 0).

8) Determine if the vector R1 = (2, 4, 1), R2 = (0, 3, -1) and R3 = (2, 1, 1) are

linearly independent.



9) Consider a system of n electric charges, e1 through en. Let ri be the position

vector of charge ei. The dipole moment of the system of charges is defines as

n

p   ei ri

i 1

and the center of the charge of the system is

n



p e r i i

R n  i 1

n



e

i 1

i e

i 1

i





where

n



e

i 1

i 0

The system is called neutral is

n



e

i 1

i 0

v) Show that the dipole moment of a neutral system is independent of the origin.

w) Express this moment in terms of the centers of the systems of negative and

positive charges making up the original system.



10) Find the scalar product of the following vectors.

x) (2, 3)•(1, -1)

y) (4, 1)•(6, -5)

z) (1, 2, -3)•(-1, 1, 2)

aa) (2, 4)•(1, 5, 3)

bb) (0, sin, 1, 3)•(2, 4, -2, 1)

cc) (sin(t), cos(t))•( sin(t), cos(t))



11) Find the angles that the vector (2, 4, -5) makes with the coordinate axes.



12) Find the projection of the vector (2, 5, 1) on the vector (1, 1, 3).



13)

dd) Using the dot product, prove the law of cosines.

ee) Let U1 and U2 be two vectors in the x-y plane with angles  and  between U1

and x and U2 and x. Using the dot product show that cos(-) =

cos()cos()+sin()sin()



14) Determine the value of  such that A and B are perpendicular and C and D

are perpendicular.

ff) A = (2, 3, 1), B = (4, 2, 4)

gg) C = (2, 4, 3, 1), D = (, 2, -1, 2)

15) Let A = (-1, 2, 4), B = (3, 2, 7). Find the unit vector perpendicular to the

plane determined by A and B.



16) The force F = (2, 3, 1) is applied to an object which move along a vector r =

(1, 4, 1). What is the work done?



17) Determine the magnitude, phase angle, real and imaginary parts of the

following

3+i

3

3ei2/3

2(cos (/6) +i sin (/6))

345°



18) A Force F = 2i - 3j + k acts at the point (1, 5, 2). Find the torque due to F

about

The origin

The y axis

The line x/2=y/1=z/(-2)





Del operator questions

19) Find the gradient of w=x2y3z at (1, 2, -1)

20) Find the gradient of



Compute the divergence and the curl of each of the following Vector Fields.

21) r  z ˆ  y ˆ  x k

i j ˆ

22) r  x ˆ  y ˆ  z k

2 2 2 ˆ

i j



Calculate the Laplacian   of each of the following

2



2 2

23) x y

24) x2  y2  z 2 

1/ 2









 

1/2

25) For r  x 2  y2  z 2 , Prove

1 rˆ

  2

r r



 r

ˆ

26) For r  x ˆ  y ˆ  z k , evaluate        r .

i j ˆ

 r

Divergence, Stokes and Green’s Theorem Problems

 

27) Evaluate the integral  x 2  y2 dx  2xydy along each of the following

paths from (0,0) to (1,2)

hh) y = 2x2

ii) x = t2, y = 2t

jj) y = 0, for x = 0 -> 1 and then x = 1 for y = 0 -> 2.



28) Evaluate the integral  xydx  xdy along each of the following paths –

each path.

kk) a) (0,0) to (1,2)

ll) b) (0, 0) to (3, 0) to (1,2).



29) Determine if the following force fields are conservative. Then determine a

scalar potential for each field.

mm) F  ˆ   zˆ   yk

i j ˆ

nn) F  z sinh yˆ  2z coshy kˆ

2

j



30) Which, if either, of the following force fields is conservative? Calculate the

work done moving a particle around a circle of x = cos t, y = sin t in the x-y

plane.

oo) F   y ˆ  x ˆ  z k

i j ˆ

pp) F  yˆ  x ˆ  zk

i j ˆ

Explain why you have gotten these answers.



31) In spherical coordinates, show that the electric field E of a point charge is

conservative. Determine and write the electric potential  in rectangular

(cartesian) and cylindrical coordinates. Find E   using both cartesian

and cylindrical coordinates and show that the results are the same as in

spherical coordinates.



P(x, y)

32) Derive  P(x,y) dx  

y

dxdy using methods similar to that used in

c A

class.



 x dy  xydx , around the curve (1, 0) to (4, 0) to (4, .5) along

2

33) Evaluate

c

y  1 x to (1, 1).



34) For a simple closed curve C in a plane show by Green’s theorem that the area

enclosed is A  1  xdy  ydx.

2

c





35) Find the area inside the curve x  a cos, y  bsin , 0    2 .

Evaluate the following three problems using either a surface or a volume integral,

whichever is easier.



36)    Vd ; V  x 2

y

2

xˆ  yˆ, over the volume bounded by x2 + y2 ≤

i j

V

4, 0 ≤ z ≤ 5. (Remember the top and bottom!)



i j ˆ

37)  V  nd ; V  x ˆ  yˆ  zk , over the surface of the cone with base

A

x 2  y 2  16 and vertex at (0,0,3).

 

38)    Fd ; F  x 3  y2 y ˆ  y 3  2y 2  yx ˆ  z 2 1k , over the unit

i j ˆ

V

cube in the first octant.



Using either Stoke’s Theorem or the Divergence Theorem evaluate each of the

following.

39)  V  nd ; V  2xy ˆ  y 2 ˆ  z  xy  k , where  is a tin can defined by

i j ˆ

A

x2 + y2 ≤ 9, 0 ≤ z ≤ 5. (Remember the top and bottom!).



40)  (  V)  nd ; V  x  x 2z ˆ  yz 3  y 2  ˆ  x 2y  xz  k , where  is

i j ˆ

A

any surface with a bounding curve entirely in the x-y plane.



ˆ

41)  (  V)  nd ; V  x 2 y ˆ  xz k , where  is the closed surface of the

i

A

ellipsoid 1 = x2/4 + y2/9 + z2/16.



Electro and Magneto static point source

42) Determine the electric potential of a point charge from the electric field

q r ˆ

E

4 r 2



43) Determine the magnetic potential of a current element.

 dI  rˆ

B

4 r 2







44) Need to add A cross B = magnitude times sin of angle

Homework Section 2

Static electric fields using Coulomb’s Law – notice that symmetry is

lacking in most of these problems.

Line charges

(These might approximate what you would find on a line if it were exposed to an

external charge. Also note that these represent – as best I can tell – all of the

possible problems of this form that one can solve analytically.)

1) Use cylindrical coordinates to calculate the electric field in the x-y plane for a line

charge where the charge density is

l  0



2) Use cylindrical coordinates to calculate the electric field in the x-y plane for a line

charge where the charge density is

 0 z a



l   1

 0 z z a





3) Use cylindrical coordinates to calculate the electric field in the x-y plane for a line

charge where the charge density is

 0 z a



l   1

 0 z 2 z a





4) Use cylindrical coordinates to calculate the electric field in the x-y plane for a line

charge where the charge density is

 0 z a



l   1

 0 z 3 z a





5) Use cylindrical coordinates to calculate the electric field in the x-y plane for a line

charge where the charge density is

 0 z a



l   1

 0 z m z a





6) Use cylindrical coordinates to calculate the electric field in the x-y plane for a line

charge where the charge density is

 z z a

l   0

 0 z a

7) Use cylindrical coordinates to calculate the electric field in the x-y plane for a line

charge where the charge density is

 z 2 z  a

l   0

 0

 z a



Surface charges

(These might approximate what you would find on a surface if it were exposed to an

external charge. Again note that these represent – as best I can tell – all of the

possible problems of this form that one can solve analytically.)

8) Use cylindrical coordinates to calculate the electric field on the z-axis for a surface of

charges on the x-y plane where the charge density is

 s  0



9) Use cylindrical coordinates to calculate the electric field on the z-axis for a surface of

charges on the x-y plane where the charge density is

 0 r  a



s   1

0 r r  a





10) Use cylindrical coordinates to calculate the electric field on the z-axis for a surface of

charges on the x-y plane where the charge density is

 0 ra



s   1

 0 r 2 r  a





11) Use cylindrical coordinates to calculate the electric field on the z-axis for a surface of

charges on the x-y plane where the charge density is

 0 ra



s   1

 0 r 3 r  a





12) Use cylindrical coordinates to calculate the electric field on the z-axis for a surface of

charges on the x-y plane where the charge density is

 0 ra



s   1

0 r m r  a





13) Use cylindrical coordinates to calculate the electric field on the z-axis for a surface of

charges on the x-y plane where the charge density is

 r r  a

s   0

 0 ra

14) Use cylindrical coordinates to calculate the electric field on the z-axis for a surface of

charges on the x-y plane where the charge density is

 0 r 2 r  a

s  

 0 ra



Static electric fields using Gauss’ Law – notice the symmetry in these

problems.

15) Use cylindrical coordinates to calculate the electric field in the x-y plane for a line

charge where the charge density is

l  0



16) Use cylindrical coordinates to calculate the electric field on the z-axis for a surface of

charges on the x-y plane where the charge density is

 s  0





Cylindrical Volume charges

(These might approximate what you would find in a volume of a material. Under

some conditions it might be an insulator with charges distributed around the

volume, in others it might be a wire (or two) with charge carriers near surfaces.)



17) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 r  a

v   0 - in cylindrical coordinates

0 ra



18) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 1

 ra

v   0 r - in cylindrical coordinates

 0

 ra



19) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 1

 ra

v   0 r 2 - in cylindrical coordinates

 0

 ra

20) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 1

 ra

v   0 r m - in cylindrical coordinates

 0

 ra



21) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 r r  a

v   0 - in cylindrical coordinates

 0 ra



22) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 0 r 2 r  a

v   - in cylindrical coordinates

 0 ra



23) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 r m r  a

v   0 - in cylindrical coordinates

 0 ra



24) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

0 ra



v   0 a  r  b - in cylindrical coordinates

0 br





25) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 0 ra



v   0 r a  r  b - in cylindrical coordinates

 0 br





26) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 0 ra

 m

v   0 r a  r  b - in cylindrical coordinates

 0 br



27) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 0 ra

 1



v   0 a  r  b - in cylindrical coordinates

 r

 0

 br



28) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 0 ra

 1



v   0 m a  r  b - in cylindrical coordinates

 r

 0

 br





Spherical Volume charges

(These might approximate what you would find in a volume of a material. Under

some conditions it might be an insulator with charges distributed around the

volume.)



29) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 r  a

v   0 - in spherical coordinates

0 ra



30) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 1

 ra

v   0 r - in spherical coordinates

 0

 ra



31) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 1

 ra

v   0 r 2 - in spherical coordinates

 0

 ra



32) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 1

 ra

v   0 r m - in spherical coordinates

 0

 ra

33) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 r r  a

v   0 - in spherical coordinates

 0 ra



34) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 r 2 r  a

v   0 - in spherical coordinates

 0 ra



35) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 0 r m r  a

v   - in spherical coordinates

 0 ra



36) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

0 ra



v   0 a  r  b - in spherical coordinates

0 br





37) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 0 ra



v   0 r a  r  b - in spherical coordinates

 0 br





38) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 0 ra

 m

v   0 r a  r  b - in spherical coordinates

 0 br





39) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 0 ra

 1



v   0 a  r  b - in spherical coordinates

 r

 0

 br

40) Calculate the electric field EVERYWHERE for a volume of charges where the charge

density is

 0 ra

 1



v   0 m a  r  b - in spherical coordinates

 r

 0

 br



Physically realistic systems



Need to add problems

Capacitors etc





Static Magnetic fields using Biot-Savart Law – notice that symmetry is

lacking in most of these problems.

Line currents

(These might approximate what you would find on a few loops of wire. There

perhaps a few more problems that can be solve analytically, but not many. )

41) Use Cartisean coordinates to calculate the magnetic field on the z-axis for a line

current where the charge density is

 I0y ˆ x  a; b  y  b

 I x a  x  a; y  b

 0ˆ

Il  

I 0 y x  a; b  y  b

ˆ

 I 0 x a  x  a; y  b

 ˆ

42) Use cylindrical coordinates to calculate the magnetic field on the x-y plane for a line

current where the charge density is

I0z r  0

ˆ

Il  

 0 r0

43) Use cylindrical coordinates to calculate the magnetic field on the z-axis for a line

current where the charge density is

 ˆ

 I 0 r  a

Il  

ˆ

I 0 r  b



44) Use cylindrical coordinates to calculate the magnetic field on the z-axis for a line

current where the charge density is

 I 0

 ˆ ra

Il  

ˆ

2I 0 r  2a



45) The magnetic field around a strip cable (2 parallel wires) can be examined if one

considers where the current is flowing. Assume that for the specific strip cable that

the wires are filamentary strands of metal (typically Cu) and that the net flow on one

wire is balanced by an opposite net flow on the other wire. First show that the surface

current density on the wires should be given by:

 I 0 x  a z

ˆ xa



I  I 0 x  a zˆ x  a - in cartisean coordinates

 0 elsewhere



Then calculate the magnetic field EVERYWHERE.



Static magnetic fields using Ampere’s Law – notice the symmetry in

these problems.

Cylindrical current densities

(These might approximate what you would find in a volume of a material carrying a

current.)

46) Calculate the magnetic field EVERYWHERE where the current density is

J0z r  a

ˆ

J - in cylindrical coordinates

 0 ra

47) Calculate the magnetic field EVERYWHERE where the current density is

 J 0 rz r  a

ˆ

J - in cylindrical coordinates

 0 ra

48) Calculate the magnetic field EVERYWHERE where the current density is

J r 2z r  a

ˆ

J 0 - in cylindrical coordinates

 0 ra

49) Calculate the magnetic field EVERYWHERE where the current density is

J r mz r  a

ˆ

J 0 - in cylindrical coordinates

 0 ra

50) Calculate the magnetic field EVERYWHERE where the current density is

 0 ra

 1



J   J 0 z a  r  b - in cylindrical coordinates

ˆ

 r

 0

 rb

51) Calculate the magnetic field EVERYWHERE where the current density is

 0 ra

 1



J   J 0 2 z a  r  b - in cylindrical coordinates

ˆ

 r

 0

 rb

52) Calculate the magnetic field EVERYWHERE where the current density is

 0 ra

 1



J   J 0 m z a  r  b - in cylindrical coordinates

ˆ

 r

 0

 rb

53) Calculate the magnetic field EVERYWHERE where the current density is

ˆ

 J 0 rz ra

 0 arb



J 1 - in cylindrical coordinates

J 0 r z b  r  c

ˆ



 0

 rc

54) Calculate the magnetic field EVERYWHERE where the current density is

 J0r 2z ˆ ra



 0 arb



J 1 - in cylindrical coordinates

 J 0 2 z b  r  c

ˆ

 r

 0

 rc



Physically realistic systems

These problems are intended to approximate physically real situations. Use Ampere’s

Law to solve for the magnetic fields everywhere.



Need to add problems

Parallel wires, coaxial wires, electromagnets, speaker coils, (Long coils vs. short coils)

etc



55) The magnetic field around a strip cable (2 parallel wires) can be examined if one

considers where the current is flowing. Assume that for the specific strip cable that

the wires are filamentary strands of metal (typically Cu) and that the net flow on one

wire is balanced by an opposite net flow on the other wire. First show that the surface

current density on the wires should be given by:

 I 0 x  a z

ˆ xa



I  I 0 x  a zˆ x  a - in cartisean coordinates

 0 elsewhere



Then calculate the magnetic field EVERYWHERE.

56) The magnetic field around a coaxial cable can be examined if one considers where the

current is flowing. Assume that for the specific coaxial cable that the wires are made

from single strands of metal (typically Cu) and that the net flow on one wire is

balanced by an opposite net flow on the other wire. First show that the surface

current density on the wires should be given by:

 0 ra

 J  r  a zˆ ra

 s

 0 arb

J - in cylindrical coordinates

J a  r  b z ˆ rb

 sb

 0 br



Then calculate the magnetic field EVERYWHERE.

57) Speakers/microphone coils, transformers and inductors rely on the magnetic field

produced by or induced from coils. The simplest geometry is that of an infinitely

long coil. (In fact this is one of only a few geometries that can be solved

analytically.) Assume the coil has a radius of ‘a’ and N loops per length ‘l’. Calculate

the magnetic field EVERYWHERE.



Material issues

For more information look at:

http://www.matweb.com

http://www.nist.gov/srd/materials.htm

http://search.globalspec.com/Search/MaterialsSearch

http://home.san.rr.com/bushnell/Material%20Properties.htm

http://www.memsnet.org/material

http://www.kayelaby.npl.co.uk/general_physics/2_6/2_6_3.html



Material r () µr ()  (S/m)

Al 1.000021 3.5E7

Al2O3 4.5-8.4 0.999963 1e-16

Au (gold) 0.99996 4.1E7

Ag (silver) 0.9999976 6.1E7

Ag2O 0.999866

Cu 0.99999 5.7E7

CuO 1.000250

W 1.00008 1.8E7

WO2 1.000057

Teflon 2.1 ~1 1E-20

Wax (paraffin) 2.0-2.5 0.99999942 1E-17

Sea water 70 0.9999901 4

Distilled H2O 81 0.999987 1E-4

Mica 5.4 1E-15

Air 1.006 ~1

Mineral Oil <1E-10

Si (pure) 0.9999961 3.9E-4

Quartz (SiO2) 3.8 0.9999704 1e-16

Glass 4-10 ~” 1E-12

Pyrex 4-6 ~” 5E-12

Dry Earth 7

Wet Earth 30 1e-3

Nickel 600 1.6E8

Cobalt 250 1.6E8

Mild Steel 2000 6.3E7

Iron 5000 1.1E7



58) Calculate the E and D fields for a parallel plate capacitor assuming

a) Air filled gap

b) Quartz filled gap

c) Mica filled gap

d) Mineral oil filled gap

e) Wax filled gap



Assume that the capacitor has a gap of ‘d’ and is made of two infinitely large planes

(Thus, you are ignoring fringing fields.)



59) Calculate the E and D fields and surface charge densities for a parallel plate capacitor

assuming that the capacitor has a structure of









where a1 and a2 are areas and d is the gap. (Ignore fringing fields.)



60) Calculate the E and D fields and surface charge densities for a parallel plate capacitor

assuming that the capacitor has a structure of

where a is the area and d1 and d2 are the dielectric thicknesses. (Ignore fringing

fields.) HINT REMEMBER TO GET ALL OF THE SURFACE CHARGES.



61) Calculate the E and D fields resulting from a surface charge at the interface between

two semi-infinite slabs of dielectric materials. Thus a structure of

62) Calculate the B and H fields resulting from a surface current at the interface between

two semi-infinite slabs of magnetic materials. Thus a structure of









63) Calculate the B and H fields resulting from currents coaxial wire with a series of

different magnetic materials. Thus a structure of









Assume that the current on the inner and outer wires are balanced and that the radii of

the wires are a (inner) and b (outer).

a) Teflon

b) Quartz

c) Mineral Oil

d) Mica



64) Calculate the B and H fields resulting from currents coaxial wire with a series of

different magnetic materials. Thus a structure of

Assume that the current on the inner and outer wires are balanced and that the radii of

the wires are a (inner) and b (outer) and the inner magnetic material, µ1, has a radius

of c.



65) Calculate the conductivity for the following materials

a) Au (There is no AuOx)

b) Ag and Ag2O

c) Cu and CuO

d) Al and Al2O3

e) Explain why cooper is used in household wires.



66) Assuming an electric field of 1 V/m, calculate the terminal velocity of electrons in the

following materials

a) Au

b) Ag

c) Cu

d) Al

e) Explain why Au is used for ‘expensive’ connectors in electronics applications.



67) Assuming an electric field of 1 V/m, calculate the current density for the following

materials

a) Au (There is no AuOx)

b) Ag and Ag2O

c) Cu and CuO

d) Al and Al2O3

e) Explain why cooper is used in household wires.



Boundary problems

68) Calculate the electric fields (E and D) everywhere assuming that you have two semi-

infinite dielectric materials such that

E1  2 x  3y  5 z

ˆ ˆ ˆ

 1  2 0 x0



 2  4  0 x0

 s  0 0

69) Calculate the electric fields (E and D) everywhere assuming that you have two semi-

infinite dielectric materials such that

D1  2 0 x  3 0 y  5 0 z

ˆ ˆ ˆ

 1  4  0 x0



 2  2  0 x0

s  3 0



70) Calculate the electric fields (E and D) everywhere assuming that you have two semi-

infinite dielectric materials such that

E1  4 x  8 y  10 z

ˆ ˆ ˆ

   1 0 y0

 1

 2  3 0 y0

 s  2 0



71) Calculate the electric fields (E and D) everywhere assuming that you have two semi-

infinite dielectric materials such that

D1  5 0 x  3 0 y  2 0 z

ˆ ˆ ˆ

 1  2  0 y0



 2  3 0 y0

 s  5 0



72) Calculate the electric fields (E and D) everywhere assuming that you have two semi-

infinite dielectric materials such that

E1  2 x  5 y  6 z

ˆ ˆ ˆ

 1  2  0 z0



  2  1 0 z0

s  3 0



73) Calculate the electric fields (E and D) everywhere assuming that you have two semi-

infinite dielectric materials such that

D1  7 0 x  2 0 y  3 0 z

ˆ ˆ ˆ

 1  4  0 z0



  2  1 0 z0

 s  2 0

74) Calculate the magnetic fields (B and H) everywhere assuming that you have two

semi-infinite magnetic materials such that

B1  7  0 x  2  0 y  3 0 z

ˆ ˆ ˆ

 1  4  0 z0



  2  1 0 z0

Js  2yˆ



75) Calculate the magnetic fields (B and H) everywhere assuming that you have two

semi-infinite magnetic materials such that

H1  7 x  2 y  3z

ˆ ˆ ˆ

 1  4  0 z0



  2  1 0 z0

Js  2yˆ



76) Calculate the magnetic fields (B and H) everywhere assuming that you have two

semi-infinite magnetic materials such that

B1  7  0 x  2  0 y  3 0 z

ˆ ˆ ˆ

 1  4  0 x0



  2  1 0 x0

Js  2yˆ



77) Calculate the magnetic fields (B and H) everywhere assuming that you have two

semi-infinite magnetic materials such that

H1  2 x  6 y  3z

ˆ ˆ ˆ

 1  3 0 x0



 2  5 0 x0

J s  5zˆ



78) Calculate the magnetic fields (B and H) everywhere assuming that you have two

semi-infinite magnetic materials such that

B1  2  0 x  5  0 y  6  0 z

ˆ ˆ ˆ

 1  2 0 y0



 2  3 0 y0

J s  1z

ˆ

79) Calculate the magnetic fields (B and H) everywhere assuming that you have two

semi-infinite magnetic materials such that

B1  3 0 x  5  0 y  6  0 z

ˆ ˆ ˆ

 1  5  0 z0



 2  2 0 z0

J s  2 x  3y

ˆ ˆ



80) Calculate the magnetic fields (B and H) everywhere assuming that you have two

semi-infinite magnetic materials such that

H1  4 x  3y  2 z

ˆ ˆ ˆ

 1  3 0 z0



 2  2 0 z0

J s  1x  2 y

ˆ ˆ





Homework Section 3

Motors and rails

1) Assume that you have a single turn square coil that rotates around the z-axis at 60

Hz. The side of the coil is 10 cm. The coil passes through a magnetic field of

B  100x G

ˆ

How many loops would you need to have in order for you to use this as an AC

generator (120 V RMS) ?



2) Assume that you have a single turn square coil that rotates around the z-axis at 60

Hz. The side of the coil is 100 cm. The coil passes through a magnetic field of

B  100x G

ˆ

How many loops would you need to have in order for you to use this as an AC

generator (120 V RMS) ?



3) Assume that you have a single turn square coil that rotates around the z-axis at 60

Hz. The side of the coil is 100 cm. The coil passes through a magnetic field of

B  10x G

ˆ

How many loops would you need to have in order for you to use this as an AC

generator (120 V RMS) ?



4) Assume that you have a single turn square coil that rotates around the x-axis at 60

Hz. The side of the coil is 50 cm. The coil passes through a magnetic field of

B  50z G

ˆ

How many loops would you need to have in order for you to use this as an AC

generator (120 V RMS) ?



5) Assume that you have a single turn square coil that rotates around the y-axis at 60

Hz. The coil passes through a magnetic field of

B  50x G

ˆ

How big (area) would the coil have to be in order for you to use this as an AC

generator (120 V RMS) ?



6) The permanent magnet in a stereo speaker has a strength of

B  10z G

ˆ

XXXX ?



7) Rail gun

B  10z G

ˆ

XXXX ?



8) Rail gun

B  10z G

ˆ

XXXX ?



9) What are the wavelength, frequency and speed of light for wave in free space the

following

H  H 0 cos 0.2cm x  3.14 kHz t z

ˆ



10) What are the wavelength, frequency and speed of light for wave in free space the

following

H  H 0 cos 0.1 cm x  0.9 GHz t z

ˆ



11) What are the wavelength, frequency and speed of light for wave in free space the

following

H  H 0 cos 1.5 mm x  3 MHz t z

ˆ





12) Assuming r  1 , what is the dielectric constant of the material through the

following wave in free space is traveling

H  H 0 cos 0.2 m x  3.14 MHz t z ˆ



13) Can the following

H  H 0 cos 0.5 km x  5 GHz t z

ˆ

describe an electromagnetic wave in free space? Why or why not?



14) Can the following

H  H 0 cos 1 cm x  1 GHz t x

ˆ

describe an electromagnetic wave in free space? Why or why not?



15) Calculate the related field (E or H) for

H  5 cos 0.4 cm x  6 GHz t z ˆ



16) Calculate the related field (E or H) for

E  5 cos 2 cm x  1 GHz t y ˆ

17) Calculate the related field (E or H) for

H  5cos 150 cm r  0.5 MHz t  ˆ



18) Determine the skin depth of 1 MHz radiation in water. What implications does

this have for communications with submarines?



19) Determine the skin depth of 633 nm radiation in sea water. What implications does

this have for being able to see in the sea?



20) Determine the skin depth of 1500 nm radiation in glass and in quartz. What

implications does this have for communications in fiber optics?



21) Determine the skin depth of 1 MHz radiation in Teflon. As Teflon is sometimes

used in coax cables, what implications does this have for communications along

coax?



22) Is this wave propagating in a perfect dielectric, good dielectric, good conductor or

perfect conductor

H  H 0 cos 0.1 cm x  0.9 GHz t zˆ

  3.4E5(S/m)



23) Is this wave propagating in a perfect dielectric, good dielectric, good conductor or

perfect conductor

H  H 0 cos 1.5 mm x  3 MHz t z ˆ

  7E3(S/m)



24) Is this wave propagating in a perfect dielectric, good dielectric, good conductor or

perfect conductor

H  H 0 cos 0.2 m x  3.14 MHz t z ˆ

  3E2(S/m)



25) Is this wave propagating in a perfect dielectric, good dielectric, good conductor or

perfect conductor

H  H 0 cos 1 cm x  1 GHz t xˆ

  3E8(S/m)



26) Is this wave propagating in a perfect dielectric, good dielectric, good conductor or

perfect conductor

H  5 cos 0.4 cm x  6 GHz t z ˆ

  3E3(S/m)

27) Is this wave propagating in a perfect dielectric, good dielectric, good conductor or

perfect conductor

E  5 cos 2 cm x  1 GHz t yˆ

  8E6(S/m)



28) Determine the Poynting vector for

H  H 0 cos 0.2 m x  3.14 MHz t z

ˆ



29) Determine the Poynting vector for

H  H 0 cos 0.1 cm x  0.9 GHz t z

ˆ



30) Determine the Poynting vector for

H  H 0 cos 1.5 mm x  3 MHz t zˆ



31) Determine the Poynting vector for

H  H 0 cos 0.2 m x  3.14 MHz t z

ˆ



32) Determine the Poynting vector for

H  5 cos 0.4 cm x  6 GHz t z

ˆ



33) Determine the Poynting vector for

E  5 cos 2 cm x  1 GHz t y

ˆ



34) Determine the Poynting vector for

H  5cos 150 cm r  0.5 MHz t  ˆ



35) Determine the Poynting vector for