Exploring Motion in One Dimension: Understanding Ascent and Descent Times

In summary, the time of descent of an object thrown upwards is generally equal to the time of ascent, with any differences being caused by air resistance acting differently. However, the details of the object's shape and initial velocity can also affect the descent time.
  • #1
ranjitnepal
6
0
when we throw an object upwards why the time of descent is greater rhan time of ascent?
 
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  • #2
It's not.

The object's descent is just a time-reversed ascent, because total energy is conserved.
 
  • #3
ranjitnepal said:
when we throw an object upwards why the time of descent is greater rhan time of ascent?

What specific situation are you considering? In general, the two times will be about the same, with any difference being caused by air resistance acting differently on the ascent and the descent.
 
  • #4
in case we consider air resistance
 
  • #5
in case we consider air resistance
Don't you think it would have been a good idea to tell us that initially?

The speed coming down will be less than the speed going up because the potential energy will be the same at the same height but the total energy will be less because of energy lost to air resitance. So kinetic energy will be less at the same height coming down than going up.
 
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  • #6
ranjitnepal said:
in case we consider air resistance

Even then, the details matter. A dense sphere (think cannonball) with an initial speed of a few tens of meters per second will not be measurably affected by air resistance - and this is also the problem you'll most often encountered in introductory physics classes. On the other hand, a spin-stabilized projectile that tumbles on the the way down, or a projectile whose initial velocity exceeds its terminal velocity in air will behave very differently on ascent and descent.
 

FAQ: Exploring Motion in One Dimension: Understanding Ascent and Descent Times

What is motion in one dimension?

Motion in one dimension refers to the movement of an object along a single straight line. This can be described using concepts such as speed, distance, and time.

What is ascent and descent in terms of motion?

Ascent and descent refer to the upward and downward movement of an object, respectively. These terms are often used in relation to motion in one dimension, as an object can ascend and descend along a single straight line.

How is ascent and descent time calculated?

The ascent and descent times can be calculated by dividing the distance traveled by the object by its speed. This will give you the time it takes for the object to reach its highest point during ascent and its lowest point during descent.

What factors can affect ascent and descent times?

The speed and distance of the object are the main factors that can affect ascent and descent times. Other factors such as air resistance and external forces may also play a role in altering the times.

Why is understanding ascent and descent times important?

Understanding ascent and descent times can help us analyze and predict the motion of objects in one dimension. This can be useful in various fields such as physics, engineering, and sports training.

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