(New page: Starting this problem is similar to question 3 in homework 1. <math>Y = min(x_1, x_2)</math> <math>f(x_1) = c_1\cdot e^{-c_1x1}</math> <math>f(x_2) = c_2\cdot e^{-c_2x2}</math> From h...)
 
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I believe we can set the bounds from 0 to 1 since probabilities can not exceed this range.
 
I believe we can set the bounds from 0 to 1 since probabilities can not exceed this range.
  
<math>\int_0^1 \int_0^{x_2}  x_1 dx_1 dx_2 + \int_0^1 \int_{x_2}^1 x_2 dx_1 dx_2</math>
+
<math>\int_0^1 \int_0^{f(x_2)f(x_1) dx_1 dx_2 + \int_0^1 \int_{f(x_2)}^1 f(x_2) dx_1 dx_2</math>
  
 
This equation is derived through the property that if <math>x_1</math> is smaller than <math>x_2</math> then <math>x_1</math> will be equal to Y and vise-versa
 
This equation is derived through the property that if <math>x_1</math> is smaller than <math>x_2</math> then <math>x_1</math> will be equal to Y and vise-versa

Revision as of 09:21, 5 October 2008

Starting this problem is similar to question 3 in homework 1.

$ Y = min(x_1, x_2) $

$ f(x_1) = c_1\cdot e^{-c_1x1} $

$ f(x_2) = c_2\cdot e^{-c_2x2} $

From here we can use properties of integration to expand our min function into integrals.

$ \int_0^1 \int_0^1 min(x_1, x_2) $

I believe we can set the bounds from 0 to 1 since probabilities can not exceed this range.

$ \int_0^1 \int_0^{f(x_2)} f(x_1) dx_1 dx_2 + \int_0^1 \int_{f(x_2)}^1 f(x_2) dx_1 dx_2 $

This equation is derived through the property that if $ x_1 $ is smaller than $ x_2 $ then $ x_1 $ will be equal to Y and vise-versa

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Abstract algebra continues the conceptual developments of linear algebra, on an even grander scale.

Dr. Paul Garrett