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Physics 199BB The Physics of Baseball

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Assume over very short times, v and a are constant x = vx t vx = ax ... 3. Suppose a ball is dropped from 500 ft. How fast is it going when it hits the ground? ... – PowerPoint PPT presentation

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Title: Physics 199BB The Physics of Baseball


1
Physics 199BBThe Physics of Baseball
  • Fall 2007 Freshman Discovery Course
  • Alan M. Nathan
  • 403 Loomis
  • 333-0965
  • a-nathan_at_uiuc.edu
  • Week 3

2
The Flight of a Baseball
  • Recall from last time
  • The goal to develop an understanding of the
    trajectory of a baseball in flight
  • Pitched baseball
  • Batted baseball
  • Thrown baseball
  • We solved for projectile motion with gravity
  • by solving equations
  • by using Excel
  • We introduced the concept of drag

3
Reminders
  • To convert mph to ft/s, multiply by 1.467
  • To convert ft/s to mph, divide by 1.467
  • g 9.8 m/s2 32.2 ft/s2

4
Recall also how to use Excel to compute the
trajectory
  • divide up time into slices separate by dt
  • dt needs to be small
  • suppose x,y,vx,vy are known at time t
  • at time tdt
  • x(tdt)x(t)vx(t)dt
  • y(tdt)y(t)vy(t)dt
  • vx(tdt)vx(t)ax(t)dt
  • vy(tdt)vy(t)ay(t)dt
  • use values at t0 as starting point
  • x0,y0,v0x,v0y
  • ax0 ay-g

look at trajectory-v1.xls
5
Lets compare with exact calculation
  • Compare range D with exact
  • D v02sin(2?)/g
  • angle for maximum range
  • sin(2?) is maximum at ?45o

6
Baseball Trajectories with Drag
  • Fdrag ½ CD?Av2
  • ? is density of air
  • A is cross sectional area of ball
  • v speed of ball
  • CD is drag coefficient
  • Direction of force is exactly opposite velocity

7
Finally recall that we estimated the size of the
drag force
  • Let CD 0.5, v100 mph
  • FD ½CD?Av2
  • FD 0.574 lb
  • By comparison, weight of ball is 5.1 oz
  • mg 0.319 lb
  • We conclude that the drag is very important

this is where we left off last time
8
A useful numerical formula
FD ½CD?Av2 plug in know values of ? and A
9
Direction of the Drag Force
10
Using Excel to Compute the Trajectory
  • Acceleration is no longer constant
  • Divide into tiny time increments
  • Assume over very short times, v and a are
    constant
  • ?x vx?t ?vx ax?t
  • ?y vy?t ?vy ay?t
  • ay includes both gravity and drag
  • ay 1.67 x 10-4 Cdvvyg g
  • ax includes only drag
  • ax 1.67 x 10-4 Cdvvxg

look at trajectory-v2-class.xls
11
Some Observations
  • Drag reduces distance significantly
  • Drag reduces flight time
  • Drag reduces maximum height
  • Drag causes trajectory to be asymmetric
  • falling angle steeper than rising angle
  • Drag reduces angle for maximum distance

12
Lets add a scroll bar
  • http//www.rose-hulman.edu/moloney/BoiseSSWorksho
    p/Sliders/SlidersOnSpreadsheets.htm

13
Applications
  • Suppose Joel Zumaya tosses a pitch at 95 mph as
    it leaves his hand.
  • What is the speed as it crosses home plate?
  • What is the average speed?

14
Approximate solution
  • FD ½CD?Av2 ma m(vo-vf)/t
  • mvo(1-vf/v0)/t
  • t ? D/v0
  • Plug in... (1-vf/v0) ½CD?AD/m
  • Now put in numbers.
  • (1-vf/v0) 0.00538DCD
  • for D55 ft and CD0.35, (1-vf/v0) 0.10
  • vf 0.90v0
  • Excel gets 0.907vo

compare with Exceltrajectory-v2-class.xls
15
Applications
  • Suppose Joel Zumaya tosses a pitch at 95 mph as
    it leaves his hand.
  • What is the speed as it crosses home plate?
  • vf/vo ? 0.9
  • What is the average speed?
  • vave? 0.95 vo
  • What does radar gun report?

16
Applications
  • 2. Compare vertical drop and time of arrival of
    90 mph fastball with 85 mph changeup.

Exceltrajectory-v2-class.xls
17
Applications
  • Compare vertical drop and time of arrival of 90
    mph fastball with 85 mph changeup.
  • 85 mph drops 3 inches more and arrives 0.020 sec
    later
  • Batter will be way out in front

Exceltrajectory-v2-class.xls
18
Now we allow CD to vary
19
Now we allow CD to vary
look at cd-class.xls and trajectory-v3-class.xls
20
Applications
  • 3. Suppose a ball is dropped from 500 ft. How
    fast is it going when it hits the ground?

21
Applications
  • 3. Suppose a ball is dropped from 500 ft. How
    fast is it going when it hits the ground?
  • About 95 mph
  • FD W

FD
W
22
Homework
  • Set up Excel for calculating trajectories with
    drag and our model for CD
  • For v0 100 mph, find angle for maximum distance
  • For ?35o, plot maximum distance for v0 in the
    range 50-120 mph

23
Forces on a Baseball in Flight
  • Gravity
  • Already discussed
  • Drag (air resistance) Force
  • Already discussed
  • Magnus Force
  • Now we do this

24
First some definitions
  • ? is angular velocity
  • a measure of how fast the ball is spinning
  • units are rad/s or rev/min (rpm)
  • to convert from rad/s to rpm
  • multiply by 60/(2?)
  • to convert from rpm to rad/s
  • divide by 60/(2?)
  • ? has a direction

25
The spin axis is the line connecting the south to
north pole (right-hand rule)
spin axis
26
The Magnus Force
  • FM ½CL?Av2
  • CL is the lift coefficient
  • Force acts in the direction
  • another right-hand rule
  • force is perpendicular to both v and ?
  • force acts in the direction that the leading edge
    of the ball is turning

27
Magnus force causes ball to break in direction
that front edge of the ball is turning
Example straight overhand fastball as viewed by
batterupward break opposing gravity
deflection
spin axis
rotation
28
More examples, as seen by batter
deflection
spin axis
overhand FB upward break
spin axis
12-6 overhand CB downward break
deflection
spin axis
29
More examples, as seen by batter
Sidearm curveball by RPH breaks away from RHB
3/4 fastball by RHP breaks up and in to RHB
30
More examples, as seen by batterNote that spin
axis is tilted a bit forward.
cut fastball by RHP breaks up and away to RHB
Last slide
slider by RHP breaks down and away to RHB
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