183_notes:examples:walking_in_a_boat

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183_notes:examples:walking_in_a_boat [2014/10/01 05:46] pwirving183_notes:examples:walking_in_a_boat [2014/10/01 05:51] (current) pwirving
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 $(M+m)x = mL$ $(M+m)x = mL$
 +
 +Therefore:
  
 $x = (\dfrac{m}{M+m})L$  $x = (\dfrac{m}{M+m})L$ 
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 Does this make sense? Does this make sense?
 +
 +If you want to check whether something makes sense a good start is to check the units:
  
 Units $(x) = m$  $(\dfrac{m}{M+m})$ = unitless Units $(x) = m$  $(\dfrac{m}{M+m})$ = unitless
  
-If M is really big then $x \equiv 0$, think oil thanker+Therefore m is the remaining unit. 
 + 
 +Another check is that we know that if M is really big then $x \equiv 0$, think of a similar scenario to one just discussed occurring on a oil thanker.
  
 $x = (\dfrac{m}{M+m})L  \equiv \dfrac{m}{M}L \equiv 0$ when $M>>m$ $x = (\dfrac{m}{M+m})L  \equiv \dfrac{m}{M}L \equiv 0$ when $M>>m$
  
-If M = 0 then x $\equiv L$, no boat limit+Another check would be to check what happens when M = 0 then x $\equiv L$, i.e. if there was no boat.
  
 $x = (\dfrac{m}{M+m})L  \equiv \dfrac{m}{M}L \equiv L$ when $m>>M$ $x = (\dfrac{m}{M+m})L  \equiv \dfrac{m}{M}L \equiv L$ when $m>>M$
  
 So the motion of the center of mass of a system is dictated by the net external force. So the motion of the center of mass of a system is dictated by the net external force.
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