The Physics of Baseball (or…Just How Did McGwire Hit 70?)
Alan M. Nathan University of Illinois February 5, 1999
Introduction Hitting the Baseball
The Flight of the Baseball Pitching the Baseball Summary
Physics of Baseball: Page 1
�REFERENCES
The Physics of Baseball, Robert K. Adair (Harper
Collins, New York, 1990), ISBN 0-06-096461-8
The Sporting Life, Davis and Stephens (Henry Holt and Company, New York, 1997), ISBN 0-8050-4540-6 http://www.exploratorium.edu/sports ME!
» a-nathan@uiuc.edu » www.npl.uiuc.edu/~nathan
Physics of Baseball: Page 2
�Hitting the Baseball
“...the most difficult thing to do in sports” --Ted Williams, Professor Emeritus of Hitting
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�Speed of Hit Ball: What does it depend on?
Speed is important: 105 mph gives 400 ft each mph is worth 5 ft
The basic stuff (“kinematics”)
speed of pitched ball speed of bat weight of bat
The really interesting stuff (“dynamics”)
“bounciness” of ball and bat
weight distribution of bat
vibrations of bat
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�What Determines Batted Ball Speed?
How does batted ball speed depend on ... pitched ball speed? bat speed? V = 0.25 Vball + 1.25 Vbat
Conclusion: Bat Speed Matters More!
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�What Determines Batted Ball Speed?
Mass of bat
Conclusion: mass of bat matters ...but not a lot
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�Dynamics of Ball-Bat Collision
Ball compresses kinetic energy stored in “spring” Ball expands kinetic energy restored but... 70% of energy is lost!
(heat, deformation,vibrations,...)
Forces are large (>5000 lbs!)
Time is short (<1/1000 sec!)
The hands don’t matter!
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�Dynamics of Ball-Bat Collision
afte r during before
Ball compresses kinetic energy stored in “spring” Ball expands kinetic energy restored but... 70% of energy is lost!
(heat, deformation,vibrations,...)
Forces are large (>5000 lbs!)
Time is short (<1/1000 sec!)
The hands don’t matter!
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�The Coefficient of Restitution
COR measures “bounciness” of ball Final speed/Initial speed For baseball, COR=.52-.58 Changing COR by .05 changes V by 7 mph (35 ft!)
How to measure?
This is square of COR------->
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�What About the Bat? (or, it takes two to tango!)
Wood Bat
Efficiently restores energy
But only 2% energy stored
Bat Performance Factor (BPF) ~1 .02
Aluminum Bat Stores ~ 20% energy Efficiently restores energy Result: “trampoline effect” » BPF ~ 1.2 » Ball flies off the bat!
A more efficient bat and/or ball
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�Properties of Bats
length, diameter weight position of center of gravity where does it balance?
distribution of weight “moment of inertia” center of percussion
stiffness and elasticity vibrational nodes and frequencies
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�Sweet Spot #1: Center of Percussion
When ball strikes bat... Linear recoil » conservation of momentum Rotation about center of mass » conservation of angular momentum When CP hit The two motions cancel at handle No reaction force felt at handle
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�Sweet Spot #2: Maximum Energy Transfer
Barrel end of bat maximizes bat speed
Center of Mass minimizes angular impulse MET must be in between Not on COP!
CM COP
Aluminum bat more effective for inside pitches
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�Sweet Spot #3: “Node” of Vibration
Collision excites bending vibrations in bat Ouch!!
Energy lost ==>lower COR Sometimes broken bat
Reduced considerably if collision is a node of fundamental mode Fundamental node easy to find For an interesting discussion, see www.physics.usyd.edu.au/~cross
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�So you think bats cannot bend…..
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�So you think bats cannot bend…..
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�How Would a Physicist Design a Bat?
Wood Bat already optimally designed » highly constrained by rules! a marvel of evolution!
Aluminum Bat lots of possibilities exist but not much scientific research a great opportunity for ... » fame » fortune
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�Advantages of Aluminum
Length and weight “decoupled”
Can adjust shell thickness More compressible => “springier”
Trampoline effect
More of weight closer to hands Easier to swing
Less rotational energy transferred to bat
More forgiving on inside pitches
Stiffer for bending
Less energy lost due to vibrations
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�Aerodynamics of a Baseball
Forces on Moving Baseball
No Spin Boundary layer separation DRAG! Grows with v2
With Spin Ball deflects wake
action/reaction==>Magnus force
» Force grows with rpm
Pop Pbo t to m
» Force in direction front of ball is turning
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�The Flight of the Balll
Role of Drag Role of Spin
Atmospheric conditions
Temperature Humidity Altitude Air pressure Wind
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�The Home Run Swing
• Ball arrives on 100 downward trajectory • Big Mac swings up at 250 • Ball takes off at 350
•The optimum home run angle!
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�Physics of Baseball: Page 22
�The Role of Friction
Friction induces spin for oblique collisions Spin => Magnus force
Results
Balls hit to left/right break toward foul line Backspin keeps fly ball in air longer Topspin gives tricky bounces in infield Pop fouls behind the plate curve back toward field
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�Pitching the Baseball
“Hitting is timing. Pitching is upsetting timing” ---Warren Spahn
Don Larsen, 1956 World Series Last pitch of perfect game
vary speeds manipulate air flow orient stitches
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�Let’s Get Quantitative! I. How Large are the Forces?
D ra g /W e ig h t o r M a g n u s /W e ig h t
2
1.5
Drag/Weight
1 Magnus/Weight
0.5
0
0
25
50
75
100
125
150
Speed in mph
• Drag is comparable to weight • Magnus force < 1/4 weight)
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�Let’s Get Quantitative! II. How Much Does the Ball Break?
D ra g /W e ig h t o r M a g n u s /W e ig h t
Depends on… Magnitude and direction of force Time over which force acts Calibration 90 mph fastball drops 3.5’ due to gravity alone Ball reaches home plate in ~0.45 seconds Half of deflection occurs in last 15’ Drag reduces fastball by about 8 mph Examples: Hop of 90 mph fastball: ~4” Break of 70 mph curveball ~16” » slower » force larger
2
1.5
Drag/Weight
1 Magnus/Weight
0.5
0
0
25
50
75
100
125
150
Speed in mph
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�Example 1: Fastball
85-95 mph 1600 rpm (back) 12 revolutions 0.46 sec M/W~0.1
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�Example 2: Split-Finger Fastball
85-90 mph 1300 rpm (top) 12 revolutions 0.46 sec M/W~0.1
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�Example 3: Curveball
70-80 mph 1900 rpm (top and side) 17 revolutions 0.55 sec M/W~0.25
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�Example 4: Slider
75-85 mph 1700 rpm (side) 14 revolutions 0.51 sec M/W~0.15
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�Examples of Trajectories
Vertical Position of Ball (feet)
7
6
5
90 mph Fastball
4
3 0 10 20 30 40 50 60
Distance from Pitcher (feet)
Horizontal Deflection of Ball (feet)
1.2
1
75 mph Curveball
0.8 0.6 0.4 0.2 0 0 10 20 30 40 50 60
Distance from Pitcher (feet)
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�Effect of the Stitches
Obstructions cause turbulance
Turbulance reduces drag Dimples on golf ball Stitches on baseball
Asymmetric obstructions Knuckleball Two-seam vs. four-seam delivery
Scuffball and “juiced” ball
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�Summary
Much of baseball can be understood with basic principles of physics Conservation of momentum, angular momentum, energy
Dynamics of collisions Trajectories under influence of forces
» gravity, drag, Magnus,….
There is probably much more that we don’t understand
Don’t let either of these interfere with your enjoyment of the game!
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