Sliding motion along a frictionless circular incline - Revision history

Vipul at 19:03, 26 September 2014

2014-09-26T19:03:12Z

Vipul at 22:26, 22 November 2010

2010-11-22T22:26:11Z

← Older revision		Revision as of 22:26, 22 November 2010
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	If <math>\theta</math> denotes the angle that the radial line to the circular incline makes with the vertical, then <math>\theta</math> is also the angle made by the tangent line with the horizontal. Locally, the analysis when the block is at such a point on the circular incline looks very similar to the analysis of [[sliding motion along a frictionless inclined plane]] where the plane makes an angle of <math>\theta</math> with the horizontal. The key difference is that, since the motion is circular, the normal component of acceleration is not zero; rather, it is given by <math>v^2/r</math> where <math>v</math> is the speed and <math>r</math> is the radius.		If <math>\theta</math> denotes the angle that the radial line to the circular incline makes with the vertical, then <math>\theta</math> is also the angle made by the tangent line with the horizontal. Locally, the analysis when the block is at such a point on the circular incline looks very similar to the analysis of [[sliding motion along a frictionless inclined plane]] where the plane makes an angle of <math>\theta</math> with the horizontal. The key difference is that, since the motion is circular, the normal component of acceleration is not zero; rather, it is given by <math>v^2/r</math> where <math>v</math> is the speed and <math>r</math> is the radius.

			[[File:Blockoncircularincline.png\|thumb\|500px\|right]]

	==Basic components of force diagram==		==Basic components of force diagram==

Vipul: /* Basic components of force diagram */

2010-10-30T21:45:28Z

Basic components of force diagram

@@ Line 35: / Line 35: @@
 <math>\! N - mg \cos \theta = mv^2/r</math>
-where <math>N</math> is the normal force between the block and the inclined plane, <math>m</math> is the mass of the block, and <math>g</math> is the [[acceleration due to gravity]]. <math>N</math> acts inward on the inclined plane and outward on the block. Some observations:
+where <math>N</math> is the normal force between the block and the inclined plane, <math>m</math> is the mass of the block, and <math>g</math> is the [[acceleration due to gravity]]. <math>N</math> acts inward on the inclined plane and outward on the block.
 ===Component along (down) the inclined plane===
@@ Line 59: / Line 48: @@
 Note that if the block is sliding upward (for instance, if given an initial upward velocity) this acceleration functions as retardation, whereas if the block is sliding downward (which may happen if the block is placed at rest, or given an initial downward velocity, or of it turns back after sliding upward) then the acceleration increases the speed.

Vipul: Created page with "{{mechanics scenario}} This article describes the sliding motion of a small block placed on a frictionless circular incline. This is similar to the situation of [[sliding motion..."

2010-10-30T18:38:23Z

Created page with "{{mechanics scenario}} This article describes the sliding motion of a small block placed on a frictionless circular incline. This is similar to the situation of [[sliding motion..."

New page

{{mechanics scenario}}

This article describes the sliding motion of a small block placed on a frictionless circular incline. This is similar to the situation of [[sliding motion along an inclined plane]], except that the inclined plane has constant slop whereas in the case of the circular incline, the slope is constantly changing.

The more general version with friction is computationally much harder in terms of its kinematic evolution, and is discussed under [[sliding motion along a circular incline]].

If <math>\theta</math> denotes the angle that the radial line to the circular incline makes with the vertical, then <math>\theta</math> is also the angle made by the tangent line with the horizontal. Locally, the analysis when the block is at such a point on the circular incline looks very similar to the analysis of [[sliding motion along a frictionless inclined plane]] where the plane makes an angle of <math>\theta</math> with the horizontal. The key difference is that, since the motion is circular, the normal component of acceleration is not zero; rather, it is given by <math>v^2/r</math> where <math>v</math> is the speed and <math>r</math> is the radius.

==Basic components of force diagram==

A good way of understanding the force diagram is using the coordinate axes as the axis tangent to the circular incline and normal to the circular incline (which in this case is radial). For simplicity, we will assume a two-dimensional situation, with no forces acting along the horizontal axis that is part of the inclined plane (in our pictorial representation, this ''no action'' axis is the axis perpendicular to the plane).

===The two candidate forces===

Assuming no external forces are applied, there are two candidate forces on the block:

{| class="sortable" border="1"
! Force (letter) !! Nature of force !! Condition for existence !! Magnitude !! Direction
|-
| <math>mg</math> || [[gravitational force]] || unconditional|| <math>mg</math> where <math>m</math> is the [[mass]] and <math>g</math> is the [[acceleration due to gravity]] || vertically downward, hence an angle <math>\theta</math> with the normal to the incline and an angle <math>(\pi/2) - \theta</math> with the incline
|-
| <math>N</math> || [[normal force]] || unconditional|| adjusts so that there is no net acceleration perpendicular to the plane of the incline || outward normal to the incline
|}

[[File:mgcomponentsforincline.png|thumb|300px|right|Component-taking for the gravitational force.]]
===Taking components of the gravitational force===

The most important thing for the force diagram is understanding how the gravitational force, which acts vertically downward on the block, splits into components along and perpendicular to the incline. The component along the incline is <math>mg\sin \theta</math> and the component perpendicular to the incline is <math>mg\cos \theta</math>. The process of taking components is illustrated in the adjacent figure

===Component perpendicular to the inclined plane===
[[File:Blockoninclineforcediagramnormalcomponents.png|thumb|300px|right|Normal component <math>mg\cos \theta</math> of gravitational force <math>mg</math> should cancel out normal force.]]

In this case, assuming a stable surface of contact, and that the inclined plane does not break under the weight of the block, and no other external forces, we get the following equation from [[Newton's first law of motion]] applied to the axis perpendicular to the inclined plane:

<math>\! N - mg \cos \theta = mv^2/r</math>

where <math>N</math> is the normal force between the block and the inclined plane, <math>m</math> is the mass of the block, and <math>g</math> is the [[acceleration due to gravity]]. <math>N</math> acts inward on the inclined plane and outward on the block. Some observations:

{| class="sortable" border="1"
! Value/change in value of <math>\theta</math> !! Value of <math>N</math> !! Comments
|-
| <math>\theta = 0</math> (horizontal plane)|| <math>N = mg</math> || The normal force exerted on a horizontal surface equals the mass times the acceleration due to gravity, which we customarily call the [[weight]].
|-
| <math>\theta = \pi/2</math> (vertical plane) || <math>N = 0</math> || The block and the inclined plane are barely in contact and hardly pressed together.
|-
| <math>\theta</math> increases from <math>0</math> to <math>\pi/2</math> || <math>N</math> reduces from <math>mg</math> to <math>0</math>. The derivative <math>\frac{dN}{d\theta}</math> is <math>-mg\sin \theta</math> || The force pressing the block and the inclined plane reduces as the slope of the incline increases.
|}
For simplicity, we ignore the cases <math>\theta = 0</math> and <math>\theta = \pi/2</math> unless specifically dealing with them.

===Component along (down) the inclined plane===

For the axis ''down'' the inclined plane, the gravitational force component is <math>mg\sin \theta</math>. There are no other forces in this direction, so, if <math>a</math> denotes the tangential acceleration (which is also the change in ''speed'') measured positive in the downward direction, we get:

<math>ma = mg \sin \theta</math>

After cancellation of <math>m</math>, we get:

<math>a = g \sin \theta</math>

Note that if the block is sliding upward (for instance, if given an initial upward velocity) this acceleration functions as retardation, whereas if the block is sliding downward (which may happen if the block is placed at rest, or given an initial downward velocity, or of it turns back after sliding upward) then the acceleration increases the speed.

← Older revision		Revision as of 19:03, 26 September 2014
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	{{mechanics scenario}}		{{mechanics scenario}}

	This article describes the sliding motion of a small block placed on a frictionless circular incline. This is similar to the situation of [[sliding motion along an inclined plane]], except that the inclined plane has constant ~~slop~~ whereas in the case of the circular incline, the slope is constantly changing.		This article describes the sliding motion of a small block placed on a frictionless circular incline. This is similar to the situation of [[sliding motion along an inclined plane]], except that the inclined plane has constant slope whereas in the case of the circular incline, the slope is constantly changing.

	The more general version with friction is computationally much harder in terms of its kinematic evolution, and is discussed under [[sliding motion along a circular incline]].		The more general version with friction is computationally much harder in terms of its kinematic evolution, and is discussed under [[sliding motion along a circular incline]].
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	==Basic components of force diagram==		==Basic components of force diagram==

	A good way of understanding the force diagram is using the coordinate axes as the axis tangent to the circular incline and normal to the circular incline (which in this case is radial). For simplicity, we will assume a two-dimensional situation, with no forces acting along the horizontal axis that is part of the ~~inclined plane~~ (in our pictorial representation, this ''no action'' axis is the axis perpendicular to the plane).		A good way of understanding the force diagram is using the coordinate axes as the axis tangent to the circular incline and normal to the circular incline (which in this case is radial). For simplicity, we will assume a two-dimensional situation, with no forces acting along the horizontal axis that is part of the circular incline (in our pictorial representation, this ''no action'' axis is the axis perpendicular to the plane).

	===The two candidate forces===		===The two candidate forces===
Line 30:		Line 30:
	The most important thing for the force diagram is understanding how the gravitational force, which acts vertically downward on the block, splits into components along and perpendicular to the incline. The component along the incline is <math>mg\sin \theta</math> and the component perpendicular to the incline is <math>mg\cos \theta</math>. The process of taking components is illustrated in the adjacent figure		The most important thing for the force diagram is understanding how the gravitational force, which acts vertically downward on the block, splits into components along and perpendicular to the incline. The component along the incline is <math>mg\sin \theta</math> and the component perpendicular to the incline is <math>mg\cos \theta</math>. The process of taking components is illustrated in the adjacent figure

	===Component perpendicular to the ~~inclined plane~~===		===Component perpendicular to the circular incline===
	[[File:Blockoninclineforcediagramnormalcomponents.png\|thumb\|300px\|right\|Normal component <math>mg\cos \theta</math> of gravitational force <math>mg</math> should cancel out normal force.]]		[[File:Blockoninclineforcediagramnormalcomponents.png\|thumb\|300px\|right\|Normal component <math>mg\cos \theta</math> of gravitational force <math>mg</math> should cancel out normal force.]]

	In this case, assuming a stable surface of contact, and that the ~~inclined plane~~ does not break under the weight of the block, and no other external forces, we get the following equation from [[Newton's first law of motion]] applied to the axis perpendicular to the ~~inclined plane~~:		In this case, assuming a stable surface of contact, and that the circular incline does not break under the weight of the block, and no other external forces, we get the following equation from [[Newton's first law of motion]] applied to the axis perpendicular to the circular incline:

	<math>\! N - mg \cos \theta = mv^2/r</math>		<math>\! N - mg \cos \theta = mv^2/r</math>

	where <math>N</math> is the normal force between the block and the ~~inclined plane~~, <math>m</math> is the mass of the block, and <math>g</math> is the [[acceleration due to gravity]]. <math>N</math> acts inward on the ~~inclined plane~~ and outward on the block.		where <math>N</math> is the normal force between the block and the circular incline, <math>m</math> is the mass of the block, and <math>g</math> is the [[acceleration due to gravity]]. <math>N</math> acts inward on the circular incline and outward on the block.

	===Component along (down) the ~~inclined plane~~===		===Component along (down) the circular incline===

	For the axis ''down'' the ~~inclined plane~~, the gravitational force component is <math>mg\sin \theta</math>. There are no other forces in this direction, so, if <math>a</math> denotes the tangential acceleration (which is also the change in ''speed'') measured positive in the downward direction, we get:		For the axis ''down'' the circular incline, the gravitational force component is <math>mg\sin \theta</math>. There are no other forces in this direction, so, if <math>a</math> denotes the tangential acceleration (which is also the change in ''speed'') measured positive in the downward direction, we get:

	<math>ma = mg \sin \theta</math>		<math>ma = mg \sin \theta</math>