(Part(a))
(Part(a))
 
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<math> P(B) = p + p(1-p)^4 + p(1-p)^8 + \dots + p(1-p)^{4(n-1)} </math>
 
<math> P(B) = p + p(1-p)^4 + p(1-p)^8 + \dots + p(1-p)^{4(n-1)} </math>
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Recall geometric series:
 
Recall geometric series:
  
<math> \sum_{\imath=0} </math>
 
  
for |x| < 1
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<math> \sum_{\imath=0}^{\infty} x^{\imath}= \frac{1}{1-x}</math>  for |x| < 1
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<math> P(B) = p\sum_{\imath=0}^{\infty} (1-p)^{4\imath} = \frac{p}{1-(1-p)} </math>
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Repeat this for Carol, Ted, and Alice to show that the order of your toss affects your probability of winning.

Latest revision as of 16:09, 9 September 2008

Part(a)

     Show that P(B) > P(C) > P(T) > P(A):

- P(H) = p , 0 < p < 1

$ P(B) = p + p(1-p)^4 + p(1-p)^8 + \dots + p(1-p)^{4(n-1)} $


Recall geometric series:


$ \sum_{\imath=0}^{\infty} x^{\imath}= \frac{1}{1-x} $ for |x| < 1


$ P(B) = p\sum_{\imath=0}^{\infty} (1-p)^{4\imath} = \frac{p}{1-(1-p)} $


Repeat this for Carol, Ted, and Alice to show that the order of your toss affects your probability of winning.

Alumni Liaison

Ph.D. 2007, working on developing cool imaging technologies for digital cameras, camera phones, and video surveillance cameras.

Buyue Zhang