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Motion in 1 Dimension.

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Presentation on theme: "Motion in 1 Dimension."— Presentation transcript:

1 Motion in 1 Dimension

2 Kinematics The branch of mechanics that studies the motion of a body without regard for what caused the motion.

3 Particle Has position and mass. Has NO size or volume.
Located at one point in space.

4 Displacement Represented by x. x = x2 - x1 where x2 = final position
x1= initial position

5 Distance vs Displacement
B 100 m distance 50 m displacement

6 Average Velocity vave = ∆x ∆t Where: vave = average velocity
∆x = displacement (x2-x1) ∆t = change in time(t2-t1)

7 Velocity vs Speed Average speed is always positive.
Average velocity can be positive or negative depending direction. Absolute value of velocity can be used for speed if the object is not changing direction.

8 Average Velocity B x Dx A Dt t
Vave = Dx/Dt, or the slope of the line connecting A and B.

9 Average Velocity A x B Dx Dt t
Vave = Dx/Dt; still determined by the slope of the line connecting A and B.

10 Instantaneous Velocity
x B Determined by the slope of the tangent to a curve at a single point.

11 Acceleration A change in velocity is called acceleration.
Acceleration can be speeding up slowing down turning

12 Uniformly Accelerated Motion
In Physics B, we will generally assume that acceleration is constant. With this assumption we are free to use this equation: a = ∆v ∆t

13 Units of Acceleration The SI unit for acceleration is m/s2.

14 Sign of Acceleration Acceleration can be positive or negative.
The sign indicates direction. .

15 General Rule If the sign of the velocity and the sign of the acceleration is the same, the object speeds up. If the sign of the velocity and the sign of the acceleration are different, the object slows down.

16 Accelerating objects…
Note: each of these curves has many different slopes (many different velocities)! x t

17 Pick the constant velocity graph(s)…
x v A C t t x v B D t t

18 Another accelerating object.
x Another tangent. Another instantaneous velocity! t The tangent touches the curve at one point. Its slope gives the instantaneous velocity at that point.

19 Summary: Constant position graphs
x t Position vs time v t Velocity vs time a t Acceleration vs time

20 Summary: Constant velocity graphs
x t Position vs time v t Velocity vs time a t Acceleration vs time

21 Summary: Constant acceleration graphs
x t Position vs time v t Velocity vs time a t Acceleration vs time

22 Summary v = vo + at x = xo + vot + 1/2 at2 v2 = vo2 + 2a(∆x)

23 Today Graphing Motion Investigation

24 Free Fall Occurs when an object falls unimpeded.
Gravity accelerates the object toward the earth.

25 Acceleration due to gravity
g = 9.8 m/s2 downward. a = -g if up is positive. acceleration is down when ball is thrown up EVERYWHERE in the balls flight.

26 Summary v = vo - gt x = xo + vot - 1/2 gt2 v2 = vo2 – 2g(∆x)

27 Symmetry When something is thrown upward and returns to the thrower, this is very symmetric. The object spends half its time traveling up; half traveling down. Velocity when it returns to the ground is the opposite of the velocity it was thrown upward with. Acceleration is –9.8 m/s2 everywhere!

28 Determination of Your Reaction Time!
Get in lab groups. Drop meter stick between forefinger and thumb of another person. See where the person grabs the stick. Calculate reaction time!

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