{"id":723,"date":"2007-08-04T02:34:10","date_gmt":"2007-08-04T02:34:10","guid":{"rendered":"http:\/\/www.intmath.com\/blog\/?p=723"},"modified":"2014-01-15T20:21:38","modified_gmt":"2014-01-15T12:21:38","slug":"baseball-bat-math","status":"publish","type":"post","link":"https:\/\/www.intmath.com\/blog\/mathematics\/baseball-bat-math-723","title":{"rendered":"Baseball bat math"},"content":{"rendered":"

There is some interesting mathematics behind baseball bats. <\/p>\n

In a paper on baseball bat physics<\/a> by Larry Noble, it says:<\/p>\n

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During the swing, the maximum linear (COP) and rotational velocity of the bat is approximately 33 m\/s and 36 r\/s, respectively, for college females and 38 m\/s and 44 r\/s, respectively, for college males.<\/p>\n<\/blockquote>\n

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Some explanations:<\/p>\n

\"COP\" means \"center of percussion\".
\nm\/s is meters\/second
\nr\/s is radians per second<\/p>\n

[You can read about linear and rotational (or angular) velocity at Applications of Radian Measure<\/a>.]<\/p>\n

The COP is important because:<\/p>\n

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When the ball hits the bat at the center of percussion (COP), there is no reaction impulse (shock) at the axis. The impact axis for bats has been shown to be the point under the first knuckle of the top hand.<\/p>\n<\/blockquote>\n

The paper goes on to describe differences in resonant frequency characteristics between wooden bats and hollow-wall aluminium (aka \"aluminum\") bats. There is also an analysis of the overtones set up in the bat during the swing:<\/p>\n

baseball bat<\/p>\n

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During impact, the vibration behavior of the bat corresponds to that of a free, non-supported bat [...] irregardless of the firmness of the grip.<\/p>\n<\/blockquote>\n

One of the problems identified in the paper:<\/p>\n

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Because the primary goal of the power swing is to maximize bat velocity on impact, it is somewhat surprising that maximum bat velocity has repeatedly been found at from .01 to .05 s prior to impact<\/p>\n<\/blockquote>\n

The paper's conclusion:<\/p>\n

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The most important mechanical properties of the bat are: (1) mass, (2) moment of inertia, (3) coefficient of restitution (COR), (4) vibrational properties, (5) center of percussion location (COP), and (6) maximum power point location.<\/p>\n<\/blockquote>\n

The paper involves other applications of mathematics, including:<\/p>\n