Query 19

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course phy 201

019. `query 19

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Question: `qQuery class notes #20

Explain how we calculate the components of a vector given its magnitude and its angle with the positive x axis.

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Your solution:

The basic equation we can use is x component = L * cos (theta)

x = magnitude * cos(theta)

magni^2 = z^2 + y^2

since we have the x and magni we can solve for the y component

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Given Solution:

`a** STUDENT RESPONSE:

x component of the vector = magnitude * cos of the angle

y component of the vector = magnitude * sin of the angle

To get the magnitude and angle from components:

angle = arctan( y component / x component ); if the x component is less than 0 than we add 180 deg to the solution

To get the magnitude we take the `sqrt of ( x component^2 + y component^2) **

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Question: `qExplain what we mean when we say that the effect of a force is completely equivalent to the effect of two forces equal to its components.

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Your solution:

say someone pulled an object straight forward but two people could pull at at even angles to each other at a certain force and it will be the same as pulling it straight

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Given Solution:

`a** If one person pulls with the given force F in the given direction the effect is identical to what would happen if two people pulled, one in the x direction with force Fx and the other in the y direction with force Fy. **

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Question: `qExplain how we can calculate the magnitude and direction of the velocity of a projectile at a given point.

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Your solution:

well we can use the pythagorean theorem with the two side lengths to get the magnitude

direction can be gotten using arctan and the x and y values

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Given Solution:

`a** Using initial conditions and the equations of motion we can determine the x and y velocities vx and vy at a given point, using the usual procedures for projectiles.

The magnitude of the velocity is sqrt(vx^2 + vy^2) and the angle with the pos x axis is arctan(vy / vx), plus 180 deg if x is negative. **

STUDENT QUESTION

this says that there are the magnitude and the angle with respect to the positvie x aixs, I am not quite clear on this ar ethey added

together?

INSTRUCTOR RESPONSE

If an object is thrown straight up in the air, its initial velocity is all in the vertical direction. Its angle as measured from the horizontal x axis is 90 degrees. It has no horizontal velocity; the horizontal component of its velocity is zero. In this case our calculations would verify the obvious:

cos(90 deg) = 0, so the x component of the velocity is v_x = v cos(90 deg) = v * 0 = 0.

sin(90 deg) = 1, so the y component of the velocity is v_y = v sin(90 deg) = v * 1 = v.

If an object is thrown in the horizontal direction, its angle with the horizontal is 0 degrees. Its velocity is wholly in the horizontal direction. The vertical component of its velocity is zero. Our calculations again verify this:

cos(0 deg) = 0, so the x component of this velocity is v_x = v cos(0 deg) = v * 0 = 0.

sin(0 deg) = 1, so the y component of this velocity is v_y = v sin(0 deg) = v * 1 = v.

Now if an object is thrown at some nonzero angle with horizontal, as it typically the case, the magnitudes of its velocity components are less than the magnitude of its velocity.

For example an object thrown at angle 45 degrees, halfway between the direction of the x axis and that of the y axis, has equal x and y components. Our calculation verifies this

cos(45 deg) = .71, approx., so the x component of this velocity is v_x = v cos(45 deg) = v * .71 = .71 v.

sin(45 deg) = .71, so the y component of this velocity is v_y = v sin(45 deg) = v * .71 = .71 v.

An object thrown at 30 degrees, closer to the direction of the x axis that to that of the y axis, has a velocity component in the x direction which is greater than that in the y direction. Our calculation will verify this:

cos(30 deg) = .87, approx., so the x component of this velocity is v_x = v cos(30 deg) = v * .87 = .87 v.

sin(30 deg) = .50, so the y component of this velocity is v_y = v sin(30 deg) = v * .50 = .50 v.

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Question: `qExplain how we can calculate the initial velocities of a projectile in the horizontal and vertical directions given the magnitude and direction of the initial velocity.

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Your solution:

initial velocity in x is L cos(theta)

initial velocity in y is L sin(theta)

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Given Solution:

`a** Initial vel in the x direction is v cos(theta), where v and theta are the magnitude and the angle with respect to the positive x axis.

Initial vel in the y direction is v sin(theta). **

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Question: `qUniv. 8.63 (11th edition 8.58) (8.56 10th edition). 40 g, dropped from 2.00 m, rebounds to 1.60 m, .200 ms contact. Impulse? Ave. force?

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Your solution:

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Given Solution:

`a** You have to find the momentum of the ball immediately before and immediately after the encounter with the floor. This allows you to find change in momentum.

Using downward as positive direction throughout:

Dropped from 2 m the ball will attain velocity of about 6.3 m/s by the time it hits the floor (v0=0, a = 9.8 m/s^2, `ds = 2 m, etc.).

It rebounds with a velocity v0 such that `ds = -1.6 m, a = 9.8 m/s^2, vf = 0. This gives rebound velocity v0 = -5.6 m/s approx.

Change in velocity is -5.6 m/s - 6.3 m/s = -11.9 m/s, approx. So change in momentum is about .04 kg * -11.9 m/s = -.48 kg m/s.

In .2 millliseconds of contact we have F `dt = `dp or F = `dp / `dt = -.48 kg m/s / (.0002 s) = -2400 Newtons, approx. **

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&#Very good work. Let me know if you have questions. &#