As shown in the figure, a rectangular loop with a length f of 20.0 cm and a width w of 15.0 cm has 20 turns and carries a current of 0.13 A counterclockwise around the loop when viewed from the positive x-axis. A horizontal (parallel to the x-z plane) magnetic field of magnitude 0.021 T is oriented at an angle of 65° relative to the perpendicular to the loop (the positive x-axis). (Assume the length and width are measured along the z and y-axes, respectively.) x-z plane (a) Find the components of the magnetic force acting on each side of the loop. Components of the magnetic force acting on the top section of the loop. Frop, x= 0 Frop, y= Frop, z= Components of the magnetic force acting on the bottom section of the loop. FBottom, x= 0 FBottom, y= FBottom, z Components of the magnetic force acting on the left section of the loop. FLeft, x= FLeft, y = 0 FLeft, z= N
Displacement, Velocity and Acceleration
In classical mechanics, kinematics deals with the motion of a particle. It deals only with the position, velocity, acceleration, and displacement of a particle. It has no concern about the source of motion.
Linear Displacement
The term "displacement" refers to when something shifts away from its original "location," and "linear" refers to a straight line. As a result, “Linear Displacement” can be described as the movement of an object in a straight line along a single axis, for example, from side to side or up and down. Non-contact sensors such as LVDTs and other linear location sensors can calculate linear displacement. Non-contact sensors such as LVDTs and other linear location sensors can calculate linear displacement. Linear displacement is usually measured in millimeters or inches and may be positive or negative.
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