Problem 2: A wire, bent into a rectangle with sides a = 0.055 m and b = 0.045 m, is in amagnetic field B directed perpendicularly to the face of the wire, as shown. The perpendicularcomponent is a function of time as B(t) = Asin(@ot), where A = 0.75 T, o = 5 rad/s. In this problem,take the normal vector to the surface of the loop to be parallel to the magnetic field.ВabPart (a) Express the magnetic flux going through the wire, Ø, in terms of a, b, A, o, and t.cos(a)cos(ot)cos(o)789НОМЕcos(e)sin(a)sin(@)4sin(@t)sin(o)sin(e)*123aAb+ENDdoVOl BACKSPACEDEL CLEARtFeedbackI give up!SubmitHintPart (b) Express the the emf, E, induced in the loop in terms of the derivative of Ð.Part (c) Find the emf, &, induced in the loop in terms of a, b, A, o, and t.Part (d) Calculate the magnitude of the emf at t = 7.3 s in V.

Given,rectangle with side, a = 0.055 m and b = 0.045 mmagnetic field as a function of time, Bt = A…

Problem 2: A wire, bent into a rectangle with sides a = 0.055 m and b = 0.045 m, is in a magnetic field B directed perpendicularly to the face of the wire, as shown. The perpendicular component is a function of time as B(t) = Asin(cot), where A = 0.75 T, o = 5 rad/s. In this problem, take the normal vector to the surface of the loop to be parallel to the magnetic field. В b

Problem 2: A wire, bent into a rectangle with sides a = 0.055 m and b = 0.045 m, is in a magnetic field B directed perpendicularly to the face of the wire, as shown. The perpendicular component is a function of time as B(t) = Asin(cot), where A = 0.75 T, o = 5 rad/s. In this problem, take the normal vector to the surface of the loop to be parallel to the magnetic field. В b

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

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Question

Problem 2: A wire, bent into a rectangle with sides a = 0.055 m and b = 0.045 m, is in a
magnetic field B directed perpendicularly to the face of the wire, as shown. The perpendicular
component is a function of time as B(t) = Asin(@ot), where A = 0.75 T, o = 5 rad/s. In this problem,
take the normal vector to the surface of the loop to be parallel to the magnetic field.
В
a
b
Part (a) Express the magnetic flux going through the wire, Ø, in terms of a, b, A, o, and t.
cos(a)
cos(ot)
cos(o)
7
8
9
НОМЕ
cos(e)
sin(a)
sin(@)
4
sin(@t)
sin(o)
sin(e)
*
1
2
3
a
A
b
+
END
do
VOl BACKSPACE
DEL CLEAR
t
Feedback
I give up!
Submit
Hint
Part (b) Express the the emf, E, induced in the loop in terms of the derivative of Ð.
Part (c) Find the emf, &, induced in the loop in terms of a, b, A, o, and t.
Part (d) Calculate the magnitude of the emf at t = 7.3 s in V.

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