Pls show neat and whole solution total [-1.8 +1.978-1.47845.47x108Total = 3.6x10Uniform current sheets are located in free space as follows: 8a, A/m at y = 0, -4 a, A/m at y = 1, and -4 a, A/m at y=-1.Find the vector force per meter length exerted on a current filament carrying 7 mA in the ar, direction if the filament isJocated at4.x=0, y=0.5, and aL = a.-35.2 by W/mb. y=0.5, z=0, and aL = axc. x=0, y = 1.5, and ai. = a.. dx ay2#x7-6 10 [3-2 in (2.5) JayT-1.5 105 ay N-mA solenoid is 25 cm long, 3 cm in diameter, and carries 4 A dc in its 400 turns. Its axis is perpendicular to a uniformmagnetic field of 0.8 Wb/m² in air. Using an origin at the center of the solenoid, calculate the torque acting on it.Calculate the vector torque on the square loop shown in the figure about an origin atA in the field B, givena. A(0, 0, 0) and B = 100ay mT

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Answered: total [-1.8 +1.978-1.47845.47x108 Total…

Introductory Circuit Analysis (13th Edition)

13th Edition

ISBN:9780133923605

Author:Robert L. Boylestad

Publisher:Robert L. Boylestad

Chapter1: Introduction

Section: Chapter Questions

Problem 1P: Visit your local library (at school or home) and describe the extent to which it provides literature...

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2) If the angle the displacement makes with the electric field is 0° it means the charge is moving along (or parallel to) the field vectors. Is work being done? How will the angle here affect the work done, explain your answer with a diagram? Last Revised 12/21/2015 Equipotential Surfaces – 3.1
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When the current in a long, straight, air-filled solenoid is changing at the rate of 2000 A/s, the voltage across the solenoid is 0.600 V. The solenoid has 1200 turns and uniform cross- sectional area 25.0 mm2 . Assume that the magnetic field is uniform inside the solenoid and zero outside, so the result L =M0AN2/l applies. What is the magnitude B of the magnetic field in the interior of the solenoid when the current in the solenoid is 3.00 A?
1. ELECTRIC FLUX. A rectangular flat surface with sides 0.200 m and 0.500 m is under the influence of a uniform electric field E = 85.0 Nc that is directed at 20.0° from the plane of the rectangular sheet. Find %3D the electric flux through the rectangular flat sheet.
A rod with mass m = 0.720 kg and radius r = 6.00 cm rests on two parallel rails, as shown in the figure. The rails are separated by a distance d = 12.0 cm and have length L = 45. cm.The rod carries a current I = 48.0 A in the direction shown in the figure and rolls on the rails without slipping. There is a uniform magnetic field of magnitude B = 0.240 T perpendicular to the rails and the rod. If the rod starts from rest, what is its speed when it leaves the rails?
The figure below shows a wire that forms a semicircle of radius R=10. 0 cm and two straight segments each of length 7.0 cm. The wire carries a current i = 42.0 mA.(a) What are the magnitude, and(b) direction of the magnetic field at point C?
Two long straight aluminum wires, each of diameter 0.40 mm, carry the same current but in opposite directions. They are suspended by 1.0-m-long strings as shown in the figure. If the suspension strings make an angle of 4.0° with the vertical and are hanging freely, what is the current in the wires? (density of aluminum = 2.7 g/cm³, g=9.80 m/s?) 80 The answer is integer. 1.0 m
A wire carrying a current /= 27.0 A is bent into the shape of an exponential spiral. Its polar coordinate is described by r = exp(0) from 0-0 to 0-2 as shown in the figure. dr ds B-x/4 To complete the loop, the ends of the spiral are connected by a straight wire along the x axis. Find the magnitude of the magnetic field B at the origin. Suggestions: Although this problem may look daunting at first, remember that the Biot-Savart law is a good starting point to find the magnetic field due to a given current distribution. The simple exponential dependence of the path on the angle should give rise to an integral that is easy to solve. Also, it may help to know that the angle ẞ between a radial line and its tangent line at any point on the curve r = f(0) is related to the function in the following way: tan(B) dr di Thus, in the case of r = exp(0), tan(B)=1 and ẞ=4. Therefore, the angle between the line element vector ds and the radial unit vector r^ is -ẞ=. Additionally, this gives: dr…
This is a practice problem from the Engineering Electromagnetics course in my Electrical Engineering program. Could you please walk me through the steps of solving it so that I can solve more complicated ones in the future? Thank you for your assistance.
Two infinitely long, parallel lines of charge with linear charge densities 9.0 µC/m and −9.0 µC/m are separated by a distance of 0.50 m. What is the net electric field at point C as shown in the figure below? (Express your answers in vector form.)
You are working at a company that manufactures solenoids for industrial and research use. A client has ordered a solenoid that will be operated by a 1 000-V power supply and must be of length ℓ = 25.0 cm. A cylindrical experimental package of radius rs = 1.00 cm must fit inside the solenoid. The client wants the largest possible magnetic field inside the solenoid. The thinnest copper wires allowed by your company are AWG 36, which corresponds to a wire diameter of dω = 0.127 mm. You determine the maximum magnitude of magnetic field that can be created in the solenoid to report to the client.
A long solenoid has 100 turns/cm and carries current i. An electron moves within the solenoid in a circle of radius 2.30 cm perpendicular to the solenoid axis. The speed of the electron is 1.38x107 m/s. Find the current i in the solenoid. Give your answer in A. (melectron=9.11x10-31 kg, e=1.602x10-19 C) Uzun bir solenoid 100 sarım/cm'ye sahiptir ve i akımı taşır. Bir elektron, solenoid içinde solenoid eksenine dik 2,30 cm yarıçaplı bir daire içinde hareket eder. Elektronun sürati 1.38x107 m/s olarak verilmiştir. Solenoiddeki i akımı A cinsinden nedir? (melektron-9.11x10-31 kg, e=1.602x10-19 C) Yanıtınız

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