Physics Laboratory Manual
4th Edition
ISBN: 9781133950639
Author: David Loyd
Publisher: Cengage Learning
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Textbook Question
Chapter 6, Problem 1PLA
Assume that the projectile motion shown in Figure 6-1 is ideal with no friction. For that assumption, choose the correct statements about the motion in 1 and 2 below.
1. (a) The value of υx is always positive and decreases very slightly with time. (b) The value of υx changes from positive to negative with time. (c) The value of υx is always negative and increases very slightly with time. (d) The value of υx is always positive and is constant with time. (e) The value of υx changes from negative to positive with time.
Figure 6-1 Two-dimensional motion with acceleration in the negative y direction.
Expert Solution & Answer
To determine
The correct statement for the projectile motion with no friction.
Answer to Problem 1PLA
Option (d) the value of
Explanation of Solution
According to Newton’s first law of motion, a moving object continues to move in the same direction with constant velocity unless an unbalance force is acted upon it.
Assuming there is no friction in the projectile motion in Figure 6-1. No horizontal force is acting on the object. Therefore, the horizontal velocity of the object will be constant. And as the object is moving in positive x-direction, the horizontal velocity is positive.
Conclusion:
- (a) The projective motion is ideal with no friction and there are no horizontal force acting on the object. Therefore the velocity does not decrease with time. Option (a) is incorrect.
- (b) The horizontal velocity does not change from positive to negative with time. Option (b) is incorrect.
- (c) The
- (d) No horizontal force is acting on the object and the object is moving in positive x-direction. Option (d) is correct.
- (e) The horizontal velocity does not change from negative to positive with time. Option (e) is incorrect
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Students have asked these similar questions
I.
Fig. 4: Projectile Motion IV
Suppose that the motion of the projectile shown in the figure above is ideal without friction.
Choose the correct statements on the motion in 1 and 2 below for this assumption.
1.
(a) The value of vx is continuously positive and decreases only marginally over time.
(b) The value of Vx varies from positive to negative over time.
(c) The value of v, is always negative and increases marginally over time.
(d) The value of Vx is still positive and constant over time.
(e) The value of vx varies from negative to positive over time.
2.
(a) The value of vy is still positive and decreases only marginally over time.
(b) The value of vy is changed from positive to negative over time.
(c) The value of v, is always negative and increases only slowly over time.
(d) The value of vy is still positive and constant over time.
(e) The value of vy is changed from negative to positive over time.
Part A: Determine velocity of A after collision.
Express your answer in terms of v. Enter positive value if the velocity is directed to the right and negative value if the velocity is directed to the left.
Part B:
Determine velocity of B after collision.
Express your answer in terms of v. Enter positive value if the velocity is directed to the right and negative value if the velocity is directed to the left
Part C:
Determine velocity of C after collision.
Express your answer in terms of v. Enter positive value if the velocity is directed to the right and negative value if the velocity is directed to the left
Part D:
Determine velocity of D after collision.
Express your answer in terms of v. Enter positive value if the velocity is directed to the right and negative value if the velocity is directed to the left.
In the (Figure 1) the coefficient of static friction between mass mAmA and the table is 0.50, whereas the coefficient of kinetic friction is 0.10. Ignore masses of the cord and the (frictionless) pulley.
What minimum value of mAmA will keep the system from starting to move?
Express your answer to two significant figures and include the appropriate units.
What value of mAmA will keep the system moving at constant speed?
Express your answer to two significant figures and include the appropriate units.
Chapter 6 Solutions
Physics Laboratory Manual
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