Polar Coordinates - IIT G

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Polar Coordinates

Transcript of Polar Coordinates - IIT G

Page 1: Polar Coordinates - IIT G

Polar Coordinates

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Unit Vectors in Polar coordinates

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Unit Vectors in Polar coordinates

Unit vectors only depend on θ

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Motion in Plane Polar Coordinates

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Velocity and acceleration in polar coordinates

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Velocity in polar coordinate:

The position vector in polar coordinate is given by : r ˆr rr

ˆˆ ˆ ˆ ˆˆ cos sin & sin cosr i j i j And the unit vectors are:

Since the unit vectors are not constant and changes with time, they should have finite time derivatives:

ˆ ˆˆ ˆ ˆ ˆˆ ˆsin cos and cos sinr i j i j r

ˆˆ ˆ ˆdr

v rr rr rr rdt

Therefore the velocity is given by:

Ƹ𝑟

θ

r

Radial velocity + tangential velocity

In Cartesian coordinates

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Example-1: Uniform Circular Motion

d

dt

0

dRr

dt Since and

ˆˆv rr r

Since is along it must be perpendicular to the radius vector and it can be shown easily

v r

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Example-2:

:

:

Symmetry is important.

Why polar coordinates?

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Acceleration in Polar coordinate:

ˆ ˆˆ ˆ,r r

Usually, Coriolis force appears as a fictitious force in a rotating coordinate system. However, the Coriolis acceleration we are discussing here is a real acceleration and which is present when r and both change with time.

Finally, the Coriolis acceleration ˆ2r

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Example-1: Circular motion

2

ˆˆ

, 2

r

r

a a r a

a r r a r r

Therefore, an object traveling in a circular orbit with a constant speed isalways accelerating towards the center. Though the magnitude of thevelocity is a constant, the direction of it is constantly varying. Because thevelocity changes direction, the object has a nonzero acceleration.

2

For a circular motion, , the radius of the circle.

Hence, 0

So, and r

r R

r r

a R a R

For uniform circular motion, constant. Hence, 0

For non-uniform circular motion, is function of time. Hence, ,

where is the angular acceleration.

da R

dt

da R R

dt

d

dt

However, the radial acceleration is always 2 2

ra R R

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Example-2:

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Though the magnitude of radial velocity is constant there is a radial acceleration.

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Motion: Kinematics in 1D

Example

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velo

city

Example

time

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Kinematics in 2D

The instantaneous acceleration is given by:

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Kinematics in 2D

Example

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Charge particle in a magnetic field

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Equation of motion of a chain

A uniform chain of length ‘a’ is placed on a

horizontal frictionless table, so that a length

‘b’ of the chain dangles over the side. How

long will it take for the chain to slide off the

table?