Wright State University Lake Campus/2016-9/Phy2410/Study guide/Pdf

1) The temperature is -3 degrees Celsius, and you are standing 0.66 km from a cliff. What is the echo time?

a) 2.949 x 10⁰ seconds

b) 3.184 x 10⁰ seconds

c) 3.438 x 10⁰ seconds

d) 3.713 x 10⁰ seconds

e) 4.009 x 10⁰ seconds

2) While standing 0.76 km from a cliff, you measure the echo time to be 4.339 seconds. What is the temperature?

a) 2.83 x 10¹Celsius

b) 3.26 x 10¹Celsius

c) 3.77 x 10¹Celsius

d) 4.35 x 10¹Celsius

e) 5.03 x 10¹Celsius

3) What is the speed of a transverse wave on a string if the string is 1.19 m long, clamped at both ends, and harmonic number 6 has a frequency of 834 Hz?

a) 2.25 x 10² unit

b) 2.73 x 10² unit

c) 3.31 x 10² unit

d) 4.01 x 10² unit

e) 4.86 x 10² unit

4) Integrate the line integral of, ${\displaystyle {\vec {F}}=6.1xy{\hat {x}}+5.9y^{3}{\hat {y}}}$ , along the y axis from y = 6 to y = 12

a) 2.87E+04

b) 3.07E+04

c) 3.28E+04

d) 3.51E+04

e) 3.76E+04

5) Integrate the function, ${\displaystyle {\vec {F}}=r^{9}\theta ^{3}{\hat {r}}+r^{8}\theta ^{7}{\hat {\theta }}}$  , along the first quadrant of a circle of radius 4

a) 1.14E+06

b) 1.21E+06

c) 1.30E+06

d) 1.39E+06

e) 1.49E+06

6) Integrate the line integral of ${\displaystyle {\vec {F}}=3.8xy{\hat {x}}+5.1x{\hat {y}}}$  from the origin to the point at x = 2.5 and y = 3.2

a) 4.27E+01

b) 4.57E+01

c) 4.89E+01

d) 5.24E+01

e) 5.60E+01

7) Integrate the function, ${\displaystyle {\vec {F}}=-x^{3}y^{5}{\hat {x}}+x^{2}y^{3}{\hat {y}}}$ , as a line integral around a unit square with corners at (0,0),(1,0),(1,1),(0,1). Orient the path so its direction is out of the paper by the right hand rule

a) 3.81E-01

b) 4.08E-01

c) 4.37E-01

d) 4.67E-01

e) 5.00E-01

8) What is the magnitude of the electric field at the origin if a 1.7 nC charge is placed at x = 6.4 m, and a 3 nC charge is placed at y = 8 m?

a) 4.22 x 10^-1N/C

b) 4.87 x 10^-1N/C

c) 5.63 x 10^-1N/C

d) 6.5 x 10^-1N/C

e) 7.51 x 10^-1N/C

9) What angle does the electric field at the origin make with the x-axis if a 1.8 nC charge is placed at x = -6.9 m, and a 2.5 nC charge is placed at y = -7.5 m?

a) 2.79 x 10¹degrees

b) 3.22 x 10¹degrees

c) 3.72 x 10¹degrees

d) 4.3 x 10¹degrees

e) 4.96 x 10¹degrees

10) A dipole at the origin consists of charge Q placed at x = 0.5a, and charge of -Q placed at x = -0.5a. The absolute value of the x component of the electric field at (x,y) =( 4a, 6a) is βkQ/a², where β equals

a) 1.52 x 10^-4 unit

b) 1.85 x 10^-4 unit

c) 2.24 x 10^-4 unit

d) 2.71 x 10^-4 unit

e) 3.28 x 10^-4 unit

11) A dipole at the origin consists of charge Q placed at x = 0.5a, and charge of -Q placed at x = -0.5a. The absolute value of the y component of the electric field at (x,y) =( 1.1a, 1.2a) is βkQ/a², where β equals

a) 1.61 x 10^-1 unit

b) 1.95 x 10^-1 unit

c) 2.36 x 10^-1 unit

d) 2.86 x 10^-1 unit

e) 3.47 x 10^-1 unit

12) A line of charge density λ situated on the y axis extends from y = -3 to y = 2. What is the y component of the electric field at the point (3, 7)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {B}}=}$ 

a) 3

b) −3

c) −7

d) −3

e) 2

13) A line of charge density λ situated on the y axis extends from y = 4 to y = 6. What is the y component of the electric field at the point (5, 1)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {C}}=}$ :

a) s−1

b) 5

c) s−4

d) 1−s

e) 5−s

14) A line of charge density λ situated on the y axis extends from y = 4 to y = 6. What is the y component of the electric field at the point (5, 1)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {F}}=}$ :

a) 3

b) 2/3

c) 3/2

d) 1/2

e) 2

15) A line of charge density λ situated on the x axis extends from x = 3 to x = 7. What is the x component of the electric field at the point (7, 8)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {C}}=}$ :

a) s−3

b) s−7

c) 7−s

d) 3−s

e) 8

16) A line of charge density λ situated on the x axis extends from x = 3 to x = 7. What is the x component of the electric field at the point (7, 8)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {D}}^{2}+{\mathcal {E}}^{2}=}$ :

a) 7² + (3−s)²

b) 7² + 8²

c) (7-s)² + 8²

d) 3² + 8²

e) 7² + (8−s)²

17) A line of charge density λ situated on the y axis extends from y = -3 to y = 2. What is the y component of the electric field at the point (3, 7)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {C}}=}$ 

a) 3−s

b) 7−s

c) s−3

d) s−7

e) 3

18) A line of charge density λ situated on the y axis extends from y = -3 to y = 2. What is the y component of the electric field at the point (3, 7)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where${\displaystyle {\mathcal {F}}=}$ 

a) 3

b) 2

c) 3/2

d) 1/2

19) A line of charge density λ situated on the y axis extends from y = 2 to y = 7. What is the y component of the electric field at the point (2, 9)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {C}}=}$ :

a) 2 − s

b) 9 − s

c) s − 9

d) s − 2

e) 2

20) A line of charge density λ situated on the y axis extends from y = 2 to y = 7. What is the y component of the electric field at the point (2, 9)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {D}}^{2}+{\mathcal {E}}^{2}=}$ :

a) 7² + (2-s)²

b) 2² + (7-s)²

c) 9² + (2-s)²

d) 2² + (9-s)²

e) 9² + (7-s)²

21) A line of charge density λ situated on the x axis extends from x = 4 to x = 8. What is the y component of the electric field at the point (8, 4)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {A}}=}$ :

a) 8

b) 2

c) 1/2

d) 4

22) A line of charge density λ situated on the x axis extends from x = 4 to x = 8. What is the y component of the electric field at the point (8, 4)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {C}}=}$ :

a) s−8

b) s−4

c) 4−s

d) 4

e) 8−s

23) A line of charge density λ situated on the x axis extends from x = 4 to x = 8. What is the x component of the electric field at the point (8, 4)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {C}}=}$ :

a) 4−s

b) s−4

c) s−8

d) 8−s

e) 4

24) A line of charge density λ situated on the y axis extends from y = 4 to y = 6. What is the x component of the electric field at the point (5, 1)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {C}}=}$ :

a) 5

b) 1−s

c) 5−s

d) s−4

e) s−1

25) A cylinder of radius, R, and height H has a uniform charge density of ${\displaystyle \rho }$ . The height is much less than the radius: H << R. The electric field at the center vanishes. What formula describes the electric field at a distance, z, on axis from the center if z > H/2?

a)b) ${\displaystyle \varepsilon _{0}E=H\rho }$ 

b)c) ${\displaystyle \varepsilon _{0}E=H\rho z}$ 

c)d) none of these are correct

d)e) ${\displaystyle \varepsilon _{0}E=H\rho /2}$ 

e) ${\displaystyle \varepsilon _{0}E=\rho z}$ 

26) A cylinder of radius, R, and height H has a uniform charge density of ${\displaystyle \rho }$ . The height is much less than the radius: H << R. The electric field at the center vanishes. What formula describes the electric field at a distance, z, on axis from the center if z < H/2?

a)b) none of these are correct

b)c) ${\displaystyle \varepsilon _{0}E=\rho z}$ 

c)e) ${\displaystyle \varepsilon _{0}E=H\rho z}$ 

d)d) ${\displaystyle \varepsilon _{0}E=H\rho }$ 

e) ${\displaystyle \varepsilon _{0}E=H\rho /2}$ 

27) A sphere has a uniform charge density of ${\displaystyle \rho }$ , and a radius or R. What formula describes the electric field at a distance r > R?

a)d) ${\displaystyle r^{2}\varepsilon _{0}E=r^{3}\rho /2}$ 

b)e) ${\displaystyle r^{2}\varepsilon _{0}E=R^{3}\rho /3}$ 

c)b) ${\displaystyle r^{2}\varepsilon _{0}E=R^{3}\rho /2}$ 

d) none of these are correct

e)c) ${\displaystyle r^{2}\varepsilon _{0}E=r^{3}\rho /3}$ 

28) A sphere has a uniform charge density of ${\displaystyle \rho }$ , and a radius equal to R. What formula describes the electric field at a distance r < R?

a)b) ${\displaystyle r^{2}\varepsilon _{0}E=R^{3}\rho /3}$ 

b)c) none of these are correct

c) ${\displaystyle r^{2}\varepsilon _{0}E=r^{3}\rho /2}$ 

d)e) ${\displaystyle r^{2}\varepsilon _{0}E=R^{3}\rho /2}$ 

e)d) ${\displaystyle r^{2}\varepsilon _{0}E=r^{3}\rho /3}$ 

29) A cylinder of radius, R, and height H has a uniform charge density of ${\displaystyle \rho }$ . The height is much greater than the radius: H >> R. The electric field at the center vanishes. What formula describes the electric field at a distance, r, radially from the center if r < R?

a)e) ${\displaystyle 2r^{2}\varepsilon _{0}E=R^{3}\rho }$ 

b)d) none of these are correct

c)c) ${\displaystyle 2\varepsilon _{0}E=r\rho }$ 

d) ${\displaystyle 2R\varepsilon _{0}E=r^{2}\rho }$ 

e)b) ${\displaystyle 2r\varepsilon _{0}E=R^{2}\rho }$ 

30) A cylinder of radius, R, and height H has a uniform charge density of ${\displaystyle \rho }$ . The height is much greater than the radius: H >> R. The electric field at the center vanishes. What formula describes the electric field at a distance, r, radially from the center if r > R?

a)e) ${\displaystyle 2r^{2}\varepsilon _{0}E=R^{3}\rho }$ 

b)b) ${\displaystyle 2\varepsilon _{0}E=r\rho }$ 

c)d) none of these are correct

d) ${\displaystyle 2R\varepsilon _{0}E=r^{2}\rho }$ 

e)c) ${\displaystyle 2r\varepsilon _{0}E=R^{2}\rho }$ 

31) A parallel plate capacitor has both plates with an area of 1.45 m². The separation between the plates is 1.53mm. Applied to the plates is a potential difference of 2.55 kV. What is the capacitance?

a) 8.39 nF.

b) 9.65 nF.

c) 11.1 nF.

d) 12.76 nF.

e) 14.68 nF.

32) The same parallel plate capacitor, with area 1.15 m², plate separation 0.63mm, and an applied voltage of 2.25 kV. How much charge is stored?

a) 23.91 μC.

b) 27.5 μC.

c) 31.62 μC.

d) 36.37 μC.

e) 41.82 μC.

33) A 1.4 Farad capacitor is charged with 1.1 Coulombs. What is the value of the electric field if the plates are 0.6 mm apart?

a) 0.86 kV/m.

b) 0.99 kV/m.

c) 1.14 kV/m.

d) 1.31 kV/m.

e) 1.51 kV/m.

34) A 0.8 Farad capacitor charged with 1.7 Coulombs. What is the energy stored in the capacitor if the plates are 0.5 mm apart?

a) 1.81 J.

b) 2.08 J.

c) 2.39 J.

d) 2.75 J.

e) 3.16 J.

35) A 1.3 Farad capacitor charged with 1.9 Coulombs. What is the force between the plates if they are 0.3 mm apart?

a) 4025 N.

b) 4628 N.

c) 5322 N.

d) 6121 N.

e) 7039 N.

36) How fast is a 2493 eV electron moving?

a) 1.3 x 10⁷ m/s.

b) 2 x 10⁷ m/s.

c) 3 x 10⁷ m/s.

d) 4.4 x 10⁷ m/s.

e) 6.7 x 10⁷ m/s.

37) A proton is accellerated (at rest) from a plate held at 767.8 volts to a plate at zero volts. What is the final speed?

a) 1.1 x 10⁵ m/s.

b) 1.7 x 10⁵ m/s.

c) 2.6 x 10⁵ m/s.

d) 3.8 x 10⁵ m/s.

e) 5.8 x 10⁵ m/s.

38) What voltage is required accelerate an electron at rest to a speed of 5.6 x 10⁴ m/s?

a) 5.9 x 10^-3 volts

b) 8.9 x 10^-3 volts

c) 1.3 x 10^-2 volts

d) 2 x 10^-2 volts

e) 3 x 10^-2 volts

39) What voltage is required to stop a proton moving at a speed of 5.2 x 10⁷ m/s?

a) 9.4 x 10⁶ volts

b) 1.4 x 10⁷ volts

c) 2.1 x 10⁷ volts

d) 3.2 x 10⁷ volts

e) 4.8 x 10⁷ volts

40) A cylinder of radius, r=3, and height, h=6, is centered at the origin and oriented along the z axis. A vector field can be expressed in cylindrical coordinates as,
 ${\displaystyle {\vec {\mathfrak {F}}}=(1.85+1.33z)\rho ^{3}{\hat {\rho }}+7.52z^{2}{\hat {z}}}$ 
Let ${\displaystyle {\hat {n}}}$  be the outward unit normal to this cylinder and evaluate ,
 ${\displaystyle \left|\int _{top}{\vec {\mathfrak {F}}}\cdot {\hat {n}}dA\right|\,}$ 
over the top surface of the cylinder.

a) 1.304E+03

b) 1.579E+03

c) 1.914E+03

d) 2.318E+03

e) 2.809E+03

41) A cylinder of radius, r=2, and height, h=4, is centered at the origin and oriented along the z axis. A vector field can be expressed in cylindrical coordinates as,
 ${\displaystyle {\vec {\mathfrak {F}}}=(2.14+2.8z)\rho ^{2}{\hat {\rho }}+9.94z^{2}{\hat {z}}}$ 
Let ${\displaystyle {\hat {n}}}$  be the outward unit normal to this cylinder and evaluate ,
 ${\displaystyle \left|\int _{side}{\vec {\mathfrak {F}}}\cdot {\hat {n}}dA\right|\,}$ 
over the curved side surface of the cylinder.

a) 2.420E+02

b) 2.931E+02

c) 3.551E+02

d) 4.303E+02

e) 5.213E+02

42) A cylinder of radius, r=2, and height, h=4, is centered at the origin and oriented along the z axis. A vector field can be expressed in cylindrical coordinates as,
 ${\displaystyle {\vec {\mathfrak {F}}}=(2.17+1.5z)\rho ^{2}{\hat {\rho }}+8.75z^{2}{\hat {z}}}$ 
Let ${\displaystyle {\hat {n}}}$  be the outward unit normal to this cylinder and evaluate ,
 ${\displaystyle \left|\oint {\vec {\mathfrak {F}}}\cdot {\hat {n}}dA\right|\,}$ 
over the entire surface of the cylinder.

a) 3.60E+02

b) 4.36E+02

c) 5.29E+02

d) 6.40E+02

e) 7.76E+02

43) A 3.9 volt battery moves 90 Coulombs of charge in 2.2 hours. What is the power?

a) 4.43 x 10^-2 W

b) 5.37 x 10^-2 W

c) 6.51 x 10^-2 W

d) 7.88 x 10^-2 W

e) 9.55 x 10^-2 W

44) The diameter of a copper wire is 7.4 mm, and it carries a current of 38 amps. What is the drift velocity if copper has a density of 8.8E3 kg/m³ and an atomic mass of 63.54 g/mol? (1 mol = 6.02E23 atoms, and copper has one free electron per atom.)

a) 3.07 x 10^-5m/s

b) 3.72 x 10^-5m/s

c) 4.5 x 10^-5m/s

d) 5.46 x 10^-5m/s

e) 6.61 x 10^-5m/s

45) A 171 Watt DC motor draws 0.47 amps of current. What is effective resistance?

a) 7.74 x 10² Ω

b) 9.38 x 10² Ω

c) 1.14 x 10³ Ω

d) 1.38 x 10³ Ω

e) 1.67 x 10³ Ω

46) A power supply delivers 169 watts of power to a 219 ohm resistor. What was the applied voltage?

a) 8.93 x 10¹ volts

b) 1.08 x 10² volts

c) 1.31 x 10² volts

d) 1.59 x 10² volts

e) 1.92 x 10² volts

47) 3 amps flow through a 1 Ohm resistor. What is the voltage?}

a) ${\displaystyle 3V}$ 

b) ${\displaystyle {\frac {1}{3}}V}$ 

c) ${\displaystyle 1V}$ 

d) None these are correct.

48) A 1 ohm resistor has 5 volts DC across its terminals. What is the current (I) and the power consumed?}

a) I = 5A & P = 25W.

b) I = 5A & P = 3W.

c) I = 5A & P = 5W.

d) I = 5A & P = 9W

49) The voltage across two resistors in series is 10 volts. One resistor is twice as large as the other. What is the voltage across the larger resistor? What is the voltage across the smaller one? }

a) ${\displaystyle V_{Big-Resistor}=6.67V}$  and ${\displaystyle V_{small-Resistor}=3.33V}$ .

b) ${\displaystyle V_{Big-Resistor}=3.33V}$  and${\displaystyle V_{small-Resistor}=6.67V}$ .

c) ${\displaystyle V_{small-Resistor}=5V}$  and ${\displaystyle V_{Big-Resistor}=5V}$ .

d) None of these are true.

50) A 1 ohm, 2 ohm, and 3 ohm resistor are connected in series. What is the total resistance?}

a) ${\displaystyle R_{Total}=0.5454\Omega }$ .

b) None of these are true.

c) ${\displaystyle R_{Total}=3\Omega }$ .

d) ${\displaystyle R_{Total}=6\Omega }$ .

51) Two identical resistors are connected in series. The voltage across both of them is 250 volts. What is the voltage across each one?}

a) ${\displaystyle R_{1}=250V}$  and ${\displaystyle R_{2}=0V}$ .

b) None of these are true.

c) ${\displaystyle R_{1}=125V}$  and ${\displaystyle R_{2}=125V}$ .

d) ${\displaystyle R_{1}=150V}$  and ${\displaystyle R_{2}=100V}$ .

52) A 1 ohm, 2 ohm, and 3 ohm resistor are connected in parallel. What is the total resistance?}

a) ${\displaystyle {\frac {6}{3}}\Omega }$ .

b) ${\displaystyle {\frac {3}{6}}\Omega }$ .

c) ${\displaystyle {\frac {11}{6}}\Omega }$ .

d) ${\displaystyle {\frac {6}{11}}\Omega }$ .

53) A 5 ohm and a 2 ohm resistor are connected in parallel. What is the total resistance?}

a) ${\displaystyle {\frac {10}{7}}\Omega }$ .

b) ${\displaystyle {\frac {6}{10}}\Omega }$ .

c) ${\displaystyle {\frac {7}{10}}\Omega }$ .

d) ${\displaystyle {\frac {10}{6}}\Omega }$ .

54) A 7 ohm and a 3 ohm resistor are connected in parallel. What is the total resistance?}

a) ${\displaystyle {\frac {21}{10}}\Omega }$ .

b) ${\displaystyle {\frac {10}{21}}\Omega }$ .

c) ${\displaystyle {\frac {11}{7}}\Omega }$ .

d) ${\displaystyle {\frac {7}{11}}\Omega }$ .

55) Three 1 ohm resistors are connected in parallel. What is the total resistance?}

a) ${\displaystyle {\frac {2}{3}}\Omega }$ .

b) ${\displaystyle {\frac {3}{2}}\Omega }$ .

c) ${\displaystyle 3\Omega }$ .

d) ${\displaystyle {\frac {1}{3}}\Omega }$ .

56) If you put an infinite number of resistors in parallel, what would the total resistance be?}

a) ${\displaystyle R_{total}}$  would approach Zero as The No. of Resistors In parallel Approaches Infinity.

b) None of these are true.

c) It is not possible to connect that Number of Resistors in parallel.

d) ${\displaystyle R_{total}}$  would approach 1 as The No. of Resistors In parallel Approaches Infinity

57) What is the current through R1 and R2 in the figure shown?

 

a) ${\displaystyle I_{1}=1A}$  and ${\displaystyle I_{2}=25A}$ .

b) ${\displaystyle I_{1}=10A}$  and ${\displaystyle I_{2}=16.67A}$ .

c) ${\displaystyle I_{1}=1A}$  and ${\displaystyle I_{2}=1.667A}$ .

d) ${\displaystyle I_{1}=0.1A}$  and ${\displaystyle I_{2}=0.1667A}$ .

58) Why do we say the "voltage across" or "the voltage with respect to?" Why can't we just say voltage?}

a) None these are correct

b) Voltage is a measure of Electric Potential difference between two electrical points.

c) It's an Electrical Cliche.

d) The other point could be Negative or positive.

59) What is the current through R1, R2, R3, and R4 in the figure shown?

 

a) ${\displaystyle I_{1}=10A}$ ; ${\displaystyle I_{2}=50A}$ ; ${\displaystyle I_{3}=33A}$ ; ${\displaystyle I_{4}=25A}$ ..

b) ${\displaystyle I_{1}=1A}$ ; ${\displaystyle I_{2}=5A}$ ; ${\displaystyle I_{3}=3.3A}$ ; ${\displaystyle I_{4}=2.5A}$ .

c) ${\displaystyle I_{1}=1A}$ ; ${\displaystyle I_{2}=0.5A}$ ; ${\displaystyle I_{3}=0.33A}$ ; ${\displaystyle I_{4}=0.25A}$ .

d) ${\displaystyle I_{1}=0.25A}$ ; ${\displaystyle I_{2}=0.33A}$ ; ${\displaystyle I_{3}=0.5A}$ ; ${\displaystyle I_{4}=0.1A}$ .

60) Two resistors are in parallel with a voltage source. How do their voltages compare?}

a) The voltage across both resistors is half the voltage of the source.

b) The voltage across both resistors is the same as the source.

c) None of these are true.

d) One has full voltage, the other has none.

61) A resistor consumes 5 watts, and its current is 10 amps. What is its voltage?

a) 15V.

b) 2V.

c) 10V.

d) 0.5V.

62) A resistor has 10 volts across it and 4 amps going through it. What is its resistance?}

a) None of these are true.

b) ${\displaystyle 3.5\Omega .}$ 

c) ${\displaystyle 4.5\Omega .}$ 

d) ${\displaystyle 2.5\Omega .}$ 

63) If you plot voltage vs. current in a circuit, and you get a linear line, what is the significance of the slope? }

a) Resistance.

b) Discriminant.

c) Power.

d) None of these are true.

64) A resistor has 3 volts across it. Its resistance is 1.5 ohms. What is the current?}

a) 12A

b) 1.5A

c) 3A

d) 2A

65) A resistor has 8 volts across it and 3 Amps going through it. What is the power consumed?}

a) 8W

b) 2.2W

c) 3W

d) 24W

66) A resistor has a voltage of 5 volts and a resistance of 15 ohms. What is the power consumed? }

a) None of these are ture.

b) 11.67 Joules

c) 1.67 Watts

d) 2.5 Watts

67) A resistor is on for 5 seconds. It consumes power at a rate of 5 watts. How many joules are used?}

a) 3 Joules

b) None of these are true

c) 5 Joules

d) 25 Joules

68) An ideal 3.1 V voltage source is connected to two resistors in parallel. One is 1.5${\displaystyle k\Omega }$ , and the other is 2.2 ${\displaystyle k\Omega }$ . What is the current through the larger resistor?

a) 0.55 mA.

b) 0.63 mA.

c) 0.73 mA.

d) 0.84 mA.

e) 0.96 mA.

69) A 7 ohm resistor is connected in series to a pair of 3.4 ohm resistors that are in parallel. What is the net resistance?

a) 6.6 ohms.

b) 7.6 ohms.

c) 8.7 ohms.

d) 10 ohms.

e) 11.5 ohms.

70) Two 9.4 ohm resistors are connected in parallel. This combination is then connected in series to a 2.4 ohm resistor. What is the net resistance?

a) 5.4 ohms.

b) 6.2 ohms.

c) 7.1 ohms.

d) 8.2 ohms.

e) 9.4 ohms.

71) An ideal 7.5 volt battery is connected to a 0.084 ohm resistor. To measure the current an ammeter with a resistance of 14${\displaystyle m\Omega }$  is used. What current does the ammeter actually read?

a) 43.8 A.

b) 50.3 A.

c) 57.9 A.

d) 66.5 A.

e) 76.5 A.

72) A battery has an emf of 7 volts, and an internal resistance of 357 ${\displaystyle k\Omega }$ . It is connected to a 2.9 ${\displaystyle M\Omega }$  resistor. What power is developed in the 2.9 ${\displaystyle M\Omega }$  resistor?

a) 13.4 ${\displaystyle \mu }$ W.

b) 15.4 ${\displaystyle \mu }$ W.

c) 17.72 ${\displaystyle \mu }$ W.

d) 20.37 ${\displaystyle \mu }$ W.

e) 23.43 ${\displaystyle \mu }$ W.

73) A 819 mF capacitor is connected in series to a 798 kΩ resistor. If the capacitor is discharged, how long does it take to fall by a factor of e⁴? (where e =2.7...)

a) 8.27 x 10⁵ s.

b) 2.61 x 10⁶ s.

c) 8.27 x 10⁶ s.

d) 2.61 x 10⁷ s.

e) 8.27 x 10⁷ s.

74) A 65 μF capacitor is connected in series to a 414 kΩ resistor. If the capacitor is discharged, how long does it take to fall by a factor of e⁴? (where e =2.7...)

a) 1.08 x 10¹ s.

b) 3.4 x 10¹ s.

c) 1.08 x 10² s.

d) 3.4 x 10² s.

e) 1.08 x 10³ s.

75) A 727 mF capacitor is connected in series to a 860 MΩ resistor. If the capacitor is discharged, how long does it take to fall by a factor of e³? (where e =2.7...)

a) 1.88 x 10⁹ s.

b) 5.93 x 10⁹ s.

c) 1.88 x 10¹⁰ s.

d) 5.93 x 10¹⁰ s.

e) 1.88 x 10¹¹ s.

76) A 10 F capacitor is connected in series to a 10Ω resistor. If the capacitor is discharged, how long does it take to fall by a factor of e⁴? (where e =2.7...)

a) 4 x 10⁰ s.

b) 1.26 x 10¹ s.

c) 4 x 10¹ s.

d) 1.26 x 10² s.

e) 4 x 10² s.

77) A cosmic ray alpha particle encounters Earth's magnetic field at right angles to a field of 7.4 μT. The kinetic energy is 437 keV. What is the radius of particle's orbit?

a) 1.3 x 10² m.

b) 4.1 x 10² m.

c) 1.3 x 10³ m.

d) 4.1 x 10³ m.

e) 1.3 x 10⁴ m.

78) Two parallel wires are 7.5 meters long, and are separated by 4.4 mm. What is the force if both wires carry a current of 14.8 amps?

a) 2.36 x 10^-3 newtons

b) 7.47 x 10^-3 newtons

c) 2.36 x 10^-2 newtons

d) 7.47 x 10^-2 newtons

e) 2.36 x 10^-1 newtons

79) Blood is flowing at an average rate of 24.5 cm/s in an artery that has an inner diameter of 3.9 mm. What is the voltage across a hall probe placed across the inner diameter of the artery if the perpendicular magnetic field is 0.17 Tesla?

a) 5.14 x 10^-5 Volts

b) 1.62 x 10^-4 Volts

c) 5.14 x 10^-4 Volts

d) 1.62 x 10^-3 Volts

e) 5.14 x 10^-3 Volts

80) An electron tube on Earth's surface is oriented horizontally towards magnetic north. The electron is traveling at 0.06c, and Earth's magnetic field makes an angle of 48.5 degrees with respect to the horizontal. To counter the magnetic force, a voltage is applied between two large parallel plates that are 59 mm apart. What must be the applied voltage if the magnetic field is 45μT?

a) 1.1 x 10⁰ volts

b) 3.6 x 10⁰ volts

c) 1.1 x 10¹ volts

d) 3.6 x 10¹ volts

e) 1.1 x 10² volts

81) Two orbiting satellites are orbiting at a speed of 58 km/s perpendicular to a magnetic field of 46 μT. They are connected by a cable that is 22 km long. A voltmeter is attached between a satellite and one end of the cable. The voltmeter's internal impedance far exceeds the net resistance through the ionosphere that completes the circuit. What is the measured voltage?

a) 2.72 x 10⁴ volts.

b) 3.3 x 10⁴ volts.

c) 4 x 10⁴ volts.

d) 4.84 x 10⁴ volts.

e) 5.87 x 10⁴ volts.

82) An loop of wire with 54 turns has a radius of 0.8 meters, and is oriented with its axis parallel to a magetic field of 0.86 Tesla. What is the induced voltage if this field is reduced to 46% of its original value in 2.4 seconds?

a) 1.43 x 10¹ volts

b) 1.73 x 10¹ volts

c) 2.1 x 10¹ volts

d) 2.55 x 10¹ volts

e) 3.08 x 10¹ volts

83)

 

Shown is a corrective lens by a person who needs glasses. This ray diagram illustrates

a) how a nearsighted person might see a distant object

b) how a farsighted person might see an object that is too close for comfort

c) how a nearsighted person might see an object that is too close for comfort

d) how a farsighted person might see a distant object

84)

 

Shown is a corrective lens by a person who needs glasses. This ray diagram illustrates

a) how a farsighted person might see a distant object

b) how a nearsighted person might see an object that is too close for comfort

c) how a farsighted person might see an object that is too close for comfort

d) how a nearsighted person might see a distant object

85) In optics, normal means

a) parallel to the surface

b) to the right of the optical axis

c) to the left of the optical axis

d) perpendicular to the surface

86) The law of reflection applies to

a) only light in a vacuum

b) flat surfaces

c) telescopes but not microscopes

d) curved surfaces

e) both flat and curved surfaces

87) When light passes from air to glass

a) the frequency decreases

b) the frequency increases

c) it bends away from the normal

d) it does not bend

e) it bends towards the normal

88) When light passes from glass to air

a) the frequency increases

b) it bends towards the normal

c) the frequency decreases

d) it does not bend

e) it bends away from the normal

89) An important principle that allows fiber optics to work is

a) total external refraction

b) the Doppler shift

c) partial internal absorption

d) the invariance of the speed of light

e) total internal reflection

90) The focal point is where

a) the center of the lens

b) rays meet whenever they are forming an image

c) rays meet whenever they pass through a lens

d) rays meet if they are parallel to each other

e) rays meet if they were parallel to the optical axis before striking a lens

91) An object is placed 8.6 cm to the left of a diverging lens with a focal length of 6.3 cm. How far is the image from the lens?

a) 3.64 x 10^-1 cm

b) 6.47 x 10^-1 cm

c) 1.15 x 10⁰ cm

d) 2.04 x 10⁰ cm

e) 3.64 x 10⁰ cm

92) An object is placed 6.55 cm to the left of a converging lens with a focal length of 5.4 cm. How far is the image from the lens?

a) 3.08 x 10⁰ cm

b) 5.47 x 10⁰ cm

c) 9.73 x 10⁰ cm

d) 1.73 x 10¹ cm

e) 3.08 x 10¹ cm

93) An object of height 0.67 cm is placed 107 cm behind a diverging lens with a focal length of 70 cm. What is the height of the image?

a) 2.65 x 10^-1 cm

b) 3.18 x 10^-1 cm

c) 3.82 x 10^-1 cm

d) 4.58 x 10^-1 cm

e) 5.49 x 10^-1 cm

94) An object is placed 10.8 cm to the left of a diverging lens with a focal length of 15.6 cm. On the side, at a distance of 5.7 cm from the diverging lens is a converging lens with focal length equal to 4 cm. How far is the final image from the converging lens?

a) 5.98 x 10^-1 cm

b) 1.89 x 10⁰ cm

c) 5.98 x 10⁰ cm

d) 1.89 x 10¹ cm

e) 5.98 x 10¹ cm

95) Which lens has the shorter focal length?

a)  

b)  

c) They have the same focal lengh.

96)   If this represents the eye looking at an object, where is this object?

a) very far away

b) One focal length in front of the eye

c) at infinity

d) directly in front of the eye (almost touching)

e) Two (of the other answers) are true

97) After passing through a the lens of a camera or the eye, the focal point is defined as where the rays meet.

a) true

b) false

98)   Mr. Smith is gazing at something as shown in the figure to the left. Suppose he does not refocus, but attempts to stare at the star shown in the figures below. Which diagram depicts how the rays from the star would travel if he does not refocus?

a)  

b)  

c)  

99) Amphere's law for magnetostatic currents is that ${\displaystyle \oint {\vec {H}}\cdot {\vec {d\ell }}=\int {\vec {J}}\cdot {\vec {dA}}}$  equals the current enclosed by the closed loop, and ${\displaystyle B=\mu _{0}H}$  is the magnetic field. A current of 7.3A flows upward along the z axis. Noting that for this geometry, ${\displaystyle \oint {\vec {B}}\cdot {\vec {d\ell }}=B\oint d\ell }$ , calculate the line integral ${\displaystyle \oint d\ell }$  for a circle of radius 8.3m.

a) 4.76E+01 m

b) 5.22E+01 m

c) 5.72E+01 m

d) 6.27E+01 m

e) 6.87E+01 m

100) If ${\displaystyle H=B/\mu _{0}}$ , where ${\displaystyle B}$  is magnetic field, what is ${\displaystyle H}$  at a distance of 8.8m from a wire carrying a current of 8.6A?

a) 1.56E-01 A/m

b) 1.71E-01 A/m

c) 1.87E-01 A/m

d) 2.05E-01 A/m

e) 2.25E-01 A/m

101) If ${\displaystyle H=B/\mu _{0}}$ , where ${\displaystyle B}$  is magnetic field, what is ${\displaystyle H_{y}}$  at the point (8.407,2.6006) if a current of 8.6A flows through a wire that runs along the z axis?

a) 1.13E-01 A/m

b) 1.24E-01 A/m

c) 1.36E-01 A/m

d) 1.49E-01 A/m

e) 1.63E-01 A/m

102) A very long and thin solenoid has 1982 turns and is 154 meters long. The wire carrys a current of 9.1A. What is the magnetic field in the center?

a) 1.12E-04 Tesla

b) 1.22E-04 Tesla

c) 1.34E-04 Tesla

d) 1.47E-04 Tesla

e) 1.61E-04 Tesla

103) A very long and thin solenoid has 1965 turns and is 136 meters long. The wire carrys a current of 7.6A. If this solenoid is sufficiently thin, what is the line integral of${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$  along an on-axis path that starts 43 meters from the center and stops 88 meters from the center?

a) 2.75E+03 A

b) 3.01E+03 A

c) 3.30E+03 A

d) 3.62E+03 A

e) 3.97E+03 A

104) What is the sum of 0.2 apples plus 57 apples?

a) 5.72E+01 apples

b) 6.27E+01 apples

c) 6.88E+01 apples

d) 7.54E+01 apples

e) 8.27E+01 apples

105) H is defined by, B=μ₀H, where B is magnetic field. A current of 54A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,5.4) to the point (5.4,0).

a) 9.34E+00 amps

b) 1.02E+01 amps

c) 1.12E+01 amps

d) 1.23E+01 amps

e) 1.35E+01 amps

106) H is defined by, B=μ₀H, where B is magnetic field. A current of 33A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-6.6, 6.6) to the point (6.6, 6.6).

a) 5.71E+00 amps

b) 6.26E+00 amps

c) 6.86E+00 amps

d) 7.52E+00 amps

e) 8.25E+00 amps

107) H is defined by, B=μ₀H, where B is magnetic field. A current of 49A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,9.8) to the point (9.8,9.8).

a) 6.13E+00 amps

b) 6.72E+00 amps

c) 7.36E+00 amps

d) 8.07E+00 amps

e) 8.85E+00 amps

108) H is defined by, B=μ₀H, where B is magnetic field. A current of 88A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,8.7) to (+∞,8.7).

a) 4.01E+01 amps

b) 4.40E+01 amps

c) 4.82E+01 amps

d) 5.29E+01 amps

e) 5.80E+01 amps

109) A circlular capactitor of radius 4.2 m has a gap of 12 mm, and a charge of 94 μC. What is the electric field between the plates?

a) 1.92E+05 N/C (or V/m)

b) 2.32E+05 N/C (or V/m)

c) 2.81E+05 N/C (or V/m)

d) 3.41E+05 N/C (or V/m)

e) 4.13E+05 N/C (or V/m)

110) A circlular capactitor of radius 4.3 m has a gap of 14 mm, and a charge of 15 μC. Compute the surface integral ${\displaystyle c^{-2}\oint {\vec {E}}\cdot d{\vec {A}}}$  over an inner face of the capacitor.

a) 8.75E-12 Vs²m^-1

b) 1.06E-11 Vs²m^-1

c) 1.28E-11 Vs²m^-1

d) 1.56E-11 Vs²m^-1

e) 1.88E-11 Vs²m^-1

111) A circlular capactitor of radius 3.3 m has a gap of 12 mm, and a charge of 63 μC. The capacitor is discharged through a 7 kΩ resistor. What is the decay time?

a) 9.94E-05 s

b) 1.20E-04 s

c) 1.46E-04 s

d) 1.77E-04 s

e) 2.14E-04 s

112) A circlular capactitor of radius 4.3 m has a gap of 10 mm, and a charge of 46 μC. The capacitor is discharged through a 5 kΩ resistor. What is what is the maximum magnetic field at the edge of the capacitor? (There are two ways to do this; you should know both.)

a) 8.32E-09 Tesla

b) 1.05E-08 Tesla

c) 1.32E-08 Tesla

d) 1.66E-08 Tesla

e) 2.09E-08 Tesla

1) The temperature is -1.4 degrees Celsius, and you are standing 0.94 km from a cliff. What is the echo time?

-a) 4.883 x 10⁰ seconds

-b) 5.272 x 10⁰ seconds

+c) 5.693 x 10⁰ seconds

-d) 6.147 x 10⁰ seconds

-e) 6.637 x 10⁰ seconds

2) While standing 0.77 km from a cliff, you measure the echo time to be 4.442 seconds. What is the temperature?

-a) 1.48 x 10¹Celsius

-b) 1.71 x 10¹Celsius

-c) 1.98 x 10¹Celsius

-d) 2.28 x 10¹Celsius

+e) 2.63 x 10¹Celsius

3) What is the speed of a transverse wave on a string if the string is 0.58 m long, clamped at both ends, and harmonic number 4 has a frequency of 543 Hz?

-a) 8.86 x 10¹ unit

-b) 1.07 x 10² unit

-c) 1.3 x 10² unit

+d) 1.57 x 10² unit

-e) 1.91 x 10² unit

4) Integrate the line integral of, ${\displaystyle {\vec {F}}=7.3xy{\hat {x}}+5.2y^{3}{\hat {y}}}$ , along the y axis from y = 5 to y = 11

+ a) 1.82E+04

- b) 1.95E+04

- c) 2.09E+04

- d) 2.23E+04

- e) 2.39E+04

5) Integrate the function, ${\displaystyle {\vec {F}}=r^{7}\theta ^{8}{\hat {r}}+r^{9}\theta ^{4}{\hat {\theta }}}$  , along the first quadrant of a circle of radius 8

- a) 1.68E+09

- b) 1.79E+09

- c) 1.92E+09

+ d) 2.05E+09

- e) 2.20E+09

6) Integrate the line integral of ${\displaystyle {\vec {F}}=4xy{\hat {x}}+9.8x{\hat {y}}}$  from the origin to the point at x = 2.6 and y = 3.9

- a) 7.93E+01

+ b) 8.48E+01

- c) 9.08E+01

- d) 9.71E+01

- e) 1.04E+02

7) Integrate the function, ${\displaystyle {\vec {F}}=-x^{3}y^{5}{\hat {x}}+x^{2}y^{3}{\hat {y}}}$ , as a line integral around a unit square with corners at (0,0),(1,0),(1,1),(0,1). Orient the path so its direction is out of the paper by the right hand rule

- a) 3.81E-01

- b) 4.08E-01

- c) 4.37E-01

- d) 4.67E-01

+ e) 5.00E-01

8) What is the magnitude of the electric field at the origin if a 1.8 nC charge is placed at x = 9.6 m, and a 2 nC charge is placed at y = 8.7 m?

+a) 2.95 x 10^-1N/C

-b) 3.41 x 10^-1N/C

-c) 3.94 x 10^-1N/C

-d) 4.55 x 10^-1N/C

-e) 5.25 x 10^-1N/C

9) What angle does the electric field at the origin make with the x-axis if a 1.4 nC charge is placed at x = -8.7 m, and a 2.7 nC charge is placed at y = -8.3 m?

-a) 4.85 x 10¹degrees

-b) 5.61 x 10¹degrees

+c) 6.47 x 10¹degrees

-d) 7.48 x 10¹degrees

-e) 8.63 x 10¹degrees

10) A dipole at the origin consists of charge Q placed at x = 0.5a, and charge of -Q placed at x = -0.5a. The absolute value of the x component of the electric field at (x,y) =( 6a, 5a) is βkQ/a², where β equals

-a) 1.09 x 10^-3 unit

-b) 1.33 x 10^-3 unit

+c) 1.61 x 10^-3 unit

-d) 1.95 x 10^-3 unit

-e) 2.36 x 10^-3 unit

11) A dipole at the origin consists of charge Q placed at x = 0.5a, and charge of -Q placed at x = -0.5a. The absolute value of the y component of the electric field at (x,y) =( 1.1a, 1.2a) is βkQ/a², where β equals

-a) 1.61 x 10^-1 unit

-b) 1.95 x 10^-1 unit

-c) 2.36 x 10^-1 unit

-d) 2.86 x 10^-1 unit

+e) 3.47 x 10^-1 unit

12) A line of charge density λ situated on the y axis extends from y = -3 to y = 2. What is the y component of the electric field at the point (3, 7)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {B}}=}$ 

-a) 3

-b) −7

-c) −3

-d) −3

+e) 2

13) A line of charge density λ situated on the y axis extends from y = 4 to y = 6. What is the y component of the electric field at the point (5, 1)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {C}}=}$ :

-a) 5−s

-b) s−4

+c) 1−s

-d) s−1

-e) 5

14) A line of charge density λ situated on the y axis extends from y = 4 to y = 6. What is the y component of the electric field at the point (5, 1)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {F}}=}$ :

+a) 3/2

-b) 1/2

-c) 2

-d) 2/3

-e) 3

15) A line of charge density λ situated on the x axis extends from x = 3 to x = 7. What is the x component of the electric field at the point (7, 8)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {C}}=}$ :

-a) 3−s

-b) 8

-c) s−3

+d) 7−s

-e) s−7

16) A line of charge density λ situated on the x axis extends from x = 3 to x = 7. What is the x component of the electric field at the point (7, 8)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {D}}^{2}+{\mathcal {E}}^{2}=}$ :

-a) 7² + 8²

-b) 3² + 8²

+c) (7-s)² + 8²

-d) 7² + (3−s)²

-e) 7² + (8−s)²

17) A line of charge density λ situated on the y axis extends from y = -3 to y = 2. What is the y component of the electric field at the point (3, 7)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {C}}=}$ 

-a) s−3

-b) 3

-c) s−7

-d) 3−s

+e) 7−s

18) A line of charge density λ situated on the y axis extends from y = -3 to y = 2. What is the y component of the electric field at the point (3, 7)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where${\displaystyle {\mathcal {F}}=}$ 

-a) 2

-b) 3

+c) 3/2

-d) 1/2

19) A line of charge density λ situated on the y axis extends from y = 2 to y = 7. What is the y component of the electric field at the point (2, 9)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {C}}=}$ :

-a) 2

-b) s − 9

-c) 2 − s

-d) s − 2

+e) 9 − s

20) A line of charge density λ situated on the y axis extends from y = 2 to y = 7. What is the y component of the electric field at the point (2, 9)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {D}}^{2}+{\mathcal {E}}^{2}=}$ :

-a) 9² + (2-s)²

+b) 2² + (9-s)²

-c) 2² + (7-s)²

-d) 9² + (7-s)²

-e) 7² + (2-s)²

21) A line of charge density λ situated on the x axis extends from x = 4 to x = 8. What is the y component of the electric field at the point (8, 4)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {A}}=}$ :

+a) 4

-b) 2

-c) 1/2

-d) 8

22) A line of charge density λ situated on the x axis extends from x = 4 to x = 8. What is the y component of the electric field at the point (8, 4)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {C}}=}$ :

-a) s−4

-b) 4−s

-c) 8−s

-d) s−8

+e) 4

23) A line of charge density λ situated on the x axis extends from x = 4 to x = 8. What is the x component of the electric field at the point (8, 4)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {C}}=}$ :

+a) 8−s

-b) 4−s

-c) s−8

-d) s−4

-e) 4

24) A line of charge density λ situated on the y axis extends from y = 4 to y = 6. What is the x component of the electric field at the point (5, 1)?
${\displaystyle Answer}$  (assuming ${\displaystyle {\mathcal {B}}>{\mathcal {A}}}$ ) ${\displaystyle is:{\frac {1}{4\pi \epsilon _{0}}}\int _{\mathcal {A}}^{\mathcal {B}}{\frac {{\mathcal {C}}\;\lambda ds}{\left[{\mathcal {D}}^{2}+{\mathcal {E}}^{2}\right]^{\mathcal {F}}\;}}}$ , where ${\displaystyle {\mathcal {C}}=}$ :

-a) s−1

-b) 5−s

-c) s−4

+d) 5

-e) 1−s

25) A cylinder of radius, R, and height H has a uniform charge density of ${\displaystyle \rho }$ . The height is much less than the radius: H << R. The electric field at the center vanishes. What formula describes the electric field at a distance, z, on axis from the center if z > H/2?

-a)c) ${\displaystyle \varepsilon _{0}E=H\rho z}$ 

+b)e) ${\displaystyle \varepsilon _{0}E=H\rho /2}$ 

-c)d) none of these are correct

-d) ${\displaystyle \varepsilon _{0}E=\rho z}$ 

-e)b) ${\displaystyle \varepsilon _{0}E=H\rho }$ 

26) A cylinder of radius, R, and height H has a uniform charge density of ${\displaystyle \rho }$ . The height is much less than the radius: H << R. The electric field at the center vanishes. What formula describes the electric field at a distance, z, on axis from the center if z < H/2?

+a)c) ${\displaystyle \varepsilon _{0}E=\rho z}$ 

-b) ${\displaystyle \varepsilon _{0}E=H\rho /2}$ 

-c)e) ${\displaystyle \varepsilon _{0}E=H\rho z}$ 

-d)d) ${\displaystyle \varepsilon _{0}E=H\rho }$ 

-e)b) none of these are correct

27) A sphere has a uniform charge density of ${\displaystyle \rho }$ , and a radius or R. What formula describes the electric field at a distance r > R?

-a)d) ${\displaystyle r^{2}\varepsilon _{0}E=r^{3}\rho /2}$ 

-b) none of these are correct

-c)b) ${\displaystyle r^{2}\varepsilon _{0}E=R^{3}\rho /2}$ 

-d)c) ${\displaystyle r^{2}\varepsilon _{0}E=r^{3}\rho /3}$ 

+e)e) ${\displaystyle r^{2}\varepsilon _{0}E=R^{3}\rho /3}$ 

28) A sphere has a uniform charge density of ${\displaystyle \rho }$ , and a radius equal to R. What formula describes the electric field at a distance r < R?

+a)d) ${\displaystyle r^{2}\varepsilon _{0}E=r^{3}\rho /3}$ 

-b)b) ${\displaystyle r^{2}\varepsilon _{0}E=R^{3}\rho /3}$ 

-c) ${\displaystyle r^{2}\varepsilon _{0}E=r^{3}\rho /2}$ 

-d)e) ${\displaystyle r^{2}\varepsilon _{0}E=R^{3}\rho /2}$ 

-e)c) none of these are correct

29) A cylinder of radius, R, and height H has a uniform charge density of ${\displaystyle \rho }$ . The height is much greater than the radius: H >> R. The electric field at the center vanishes. What formula describes the electric field at a distance, r, radially from the center if r < R?

+a)c) ${\displaystyle 2\varepsilon _{0}E=r\rho }$ 

-b) ${\displaystyle 2R\varepsilon _{0}E=r^{2}\rho }$ 

-c)e) ${\displaystyle 2r^{2}\varepsilon _{0}E=R^{3}\rho }$ 

-d)b) ${\displaystyle 2r\varepsilon _{0}E=R^{2}\rho }$ 

-e)d) none of these are correct

30) A cylinder of radius, R, and height H has a uniform charge density of ${\displaystyle \rho }$ . The height is much greater than the radius: H >> R. The electric field at the center vanishes. What formula describes the electric field at a distance, r, radially from the center if r > R?

-a)e) ${\displaystyle 2r^{2}\varepsilon _{0}E=R^{3}\rho }$ 

-b)d) none of these are correct

-c) ${\displaystyle 2R\varepsilon _{0}E=r^{2}\rho }$ 

+d)c) ${\displaystyle 2r\varepsilon _{0}E=R^{2}\rho }$ 

-e)b) ${\displaystyle 2\varepsilon _{0}E=r\rho }$ 

31) A parallel plate capacitor has both plates with an area of 1.45 m². The separation between the plates is 1.53mm. Applied to the plates is a potential difference of 2.55 kV. What is the capacitance?

+a) 8.39 nF.

-b) 9.65 nF.

-c) 11.1 nF.

-d) 12.76 nF.

-e) 14.68 nF.

32) The same parallel plate capacitor, with area 1.45 m², plate separation 1.53mm, and an applied voltage of 2.55 kV. How much charge is stored?

-a) 12.23 μC.

-b) 14.07 μC.

-c) 16.18 μC.

-d) 18.61 μC.

+e) 21.4 μC.

33) A 0.5 Farad capacitor is charged with 1.6 Coulombs. What is the value of the electric field if the plates are 0.7 mm apart?

-a) 3.46 kV/m.

-b) 3.98 kV/m.

+c) 4.57 kV/m.

-d) 5.26 kV/m.

-e) 6.05 kV/m.

34) A 0.5 Farad capacitor charged with 1.3 Coulombs. What is the energy stored in the capacitor if the plates are 0.7 mm apart?

-a) 1.28 J.

-b) 1.47 J.

+c) 1.69 J.

-d) 1.94 J.

-e) 2.24 J.

35) A 1.3 Farad capacitor charged with 1.9 Coulombs. What is the force between the plates if they are 0.3 mm apart?

-a) 4025 N.

+b) 4628 N.

-c) 5322 N.

-d) 6121 N.

-e) 7039 N.

36) How fast is a 2663 eV electron moving?

+a) 3.1 x 10⁷ m/s.

-b) 4.6 x 10⁷ m/s.

-c) 6.9 x 10⁷ m/s.

-d) 1 x 10⁸ m/s.

-e) 1.5 x 10⁸ m/s.

37) A proton is accellerated (at rest) from a plate held at 39.7 volts to a plate at zero volts. What is the final speed?

-a) 3.9 x 10⁴ m/s.

-b) 5.8 x 10⁴ m/s.

+c) 8.7 x 10⁴ m/s.

-d) 1.3 x 10⁵ m/s.

-e) 2 x 10⁵ m/s.

38) What voltage is required accelerate an electron at rest to a speed of 3 x 10⁵ m/s?

-a) 1.7 x 10^-1 volts

+b) 2.6 x 10^-1 volts

-c) 3.8 x 10^-1 volts

-d) 5.8 x 10^-1 volts

-e) 8.6 x 10^-1 volts

39) What voltage is required to stop a proton moving at a speed of 1.6 x 10⁴ m/s?

-a) 4 x 10^-1 volts

-b) 5.9 x 10^-1 volts

-c) 8.9 x 10^-1 volts

+d) 1.3 x 10⁰ volts

-e) 2 x 10⁰ volts

40) A cylinder of radius, r=3, and height, h=6, is centered at the origin and oriented along the z axis. A vector field can be expressed in cylindrical coordinates as,
 ${\displaystyle {\vec {\mathfrak {F}}}=(2.12+1.68z)\rho ^{2}{\hat {\rho }}+8.83z^{3}{\hat {z}}}$ 
Let ${\displaystyle {\hat {n}}}$  be the outward unit normal to this cylinder and evaluate ,
 ${\displaystyle \left|\int _{top}{\vec {\mathfrak {F}}}\cdot {\hat {n}}dA\right|\,}$ 
over the top surface of the cylinder.

-a) 4.593E+03

-b) 5.564E+03

+c) 6.741E+03

-d) 8.167E+03

-e) 9.894E+03

41) A cylinder of radius, r=2, and height, h=6, is centered at the origin and oriented along the z axis. A vector field can be expressed in cylindrical coordinates as,
 ${\displaystyle {\vec {\mathfrak {F}}}=(1.86+2.43z)\rho ^{2}{\hat {\rho }}+9.75z^{2}{\hat {z}}}$ 
Let ${\displaystyle {\hat {n}}}$  be the outward unit normal to this cylinder and evaluate ,
 ${\displaystyle \left|\int _{side}{\vec {\mathfrak {F}}}\cdot {\hat {n}}dA\right|\,}$ 
over the curved side surface of the cylinder.

+a) 5.610E+02

-b) 6.796E+02

-c) 8.234E+02

-d) 9.975E+02

-e) 1.209E+03

42) A cylinder of radius, r=2, and height, h=4, is centered at the origin and oriented along the z axis. A vector field can be expressed in cylindrical coordinates as,
 ${\displaystyle {\vec {\mathfrak {F}}}=(2.14+2.8z)\rho ^{2}{\hat {\rho }}+9.94z^{2}{\hat {z}}}$ 
Let ${\displaystyle {\hat {n}}}$  be the outward unit normal to this cylinder and evaluate ,
 ${\displaystyle \left|\oint {\vec {\mathfrak {F}}}\cdot {\hat {n}}dA\right|\,}$ 
over the entire surface of the cylinder.

-a) 2.93E+02

-b) 3.55E+02

+c) 4.30E+02

-d) 5.21E+02

-e) 6.32E+02

43) A 5.1 volt battery moves 43 Coulombs of charge in 1.5 hours. What is the power?

+a) 4.06 x 10^-2 W

-b) 4.92 x 10^-2 W

-c) 5.96 x 10^-2 W

-d) 7.22 x 10^-2 W

-e) 8.75 x 10^-2 W

44) The diameter of a copper wire is 8.3 mm, and it carries a current of 87 amps. What is the drift velocity if copper has a density of 8.8E3 kg/m³ and an atomic mass of 63.54 g/mol? (1 mol = 6.02E23 atoms, and copper has one free electron per atom.)

-a) 6.77 x 10^-5m/s

-b) 8.2 x 10^-5m/s

-c) 9.93 x 10^-5m/s

+d) 1.2 x 10^-4m/s

-e) 1.46 x 10^-4m/s

45) A 196 Watt DC motor draws 0.35 amps of current. What is effective resistance?

+a) 1.6 x 10³ Ω

-b) 1.94 x 10³ Ω

-c) 2.35 x 10³ Ω

-d) 2.85 x 10³ Ω

-e) 3.45 x 10³ Ω

46) A power supply delivers 101 watts of power to a 219 ohm resistor. What was the applied voltage?

+a) 1.49 x 10² volts

-b) 1.8 x 10² volts

-c) 2.18 x 10² volts

-d) 2.64 x 10² volts

-e) 3.2 x 10² volts

47) 3 amps flow through a 1 Ohm resistor. What is the voltage?}

-a) None these are correct.

+b) ${\displaystyle 3V}$ 

-c) ${\displaystyle 1V}$ 

-d) ${\displaystyle {\frac {1}{3}}V}$ 

48) A 1 ohm resistor has 5 volts DC across its terminals. What is the current (I) and the power consumed?}

-a) I = 5A & P = 5W.

-b) I = 5A & P = 3W.

+c) I = 5A & P = 25W.

-d) I = 5A & P = 9W

49) The voltage across two resistors in series is 10 volts. One resistor is twice as large as the other. What is the voltage across the larger resistor? What is the voltage across the smaller one? }

-a) ${\displaystyle V_{small-Resistor}=5V}$  and ${\displaystyle V_{Big-Resistor}=5V}$ .

+b) ${\displaystyle V_{Big-Resistor}=6.67V}$  and ${\displaystyle V_{small-Resistor}=3.33V}$ .

-c) None of these are true.

-d) ${\displaystyle V_{Big-Resistor}=3.33V}$  and${\displaystyle V_{small-Resistor}=6.67V}$ .

50) A 1 ohm, 2 ohm, and 3 ohm resistor are connected in series. What is the total resistance?}

+a) ${\displaystyle R_{Total}=6\Omega }$ .

-b) ${\displaystyle R_{Total}=3\Omega }$ .

-c) ${\displaystyle R_{Total}=0.5454\Omega }$ .

-d) None of these are true.

51) Two identical resistors are connected in series. The voltage across both of them is 250 volts. What is the voltage across each one?}

-a) ${\displaystyle R_{1}=250V}$  and ${\displaystyle R_{2}=0V}$ .

-b) ${\displaystyle R_{1}=150V}$  and ${\displaystyle R_{2}=100V}$ .

+c) ${\displaystyle R_{1}=125V}$  and ${\displaystyle R_{2}=125V}$ .

-d) None of these are true.