Difference between revisions of "Polya’s method for extremums"

(Created page with "==The segment of the shortest length== The segment <math>AB</math> has the ends on the sides of a right angle and contains a point <math>C(x_C, y_C).</math> Find the shortest...")
 
(The segment of the shortest length)
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==The segment of the shortest length==
 
==The segment of the shortest length==
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[[File:Shortest segment.png|400px|right]]
 
The segment <math>AB</math> has the ends on the sides of a right angle and contains a point <math>C(x_C, y_C).</math> Find the shortest length of such a segment.
 
The segment <math>AB</math> has the ends on the sides of a right angle and contains a point <math>C(x_C, y_C).</math> Find the shortest length of such a segment.
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<i><b>Solution</b></i>  
 
<i><b>Solution</b></i>  
  
 
Let's imagine that <math>AB</math> is a spring rod that cannot bend, but tends to shorten its length.  
 
Let's imagine that <math>AB</math> is a spring rod that cannot bend, but tends to shorten its length.  
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The rod is fixed at point <math>C</math> on a hinge without friction. The hinge allows the rod to rotate and slide.
 
The rod is fixed at point <math>C</math> on a hinge without friction. The hinge allows the rod to rotate and slide.
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The ends of the rod can slide without friction along the grooves - the sides of the corner.  
 
The ends of the rod can slide without friction along the grooves - the sides of the corner.  
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Let the rod be balanced, and the force pulling it together is equal to <math>T.</math> The grooves can create a force only along the normal, so they act on the rod with forces  
 
Let the rod be balanced, and the force pulling it together is equal to <math>T.</math> The grooves can create a force only along the normal, so they act on the rod with forces  
 
<cmath>F_B = \frac {T}{\sin \alpha}, F_A = \frac {T}{\cos \alpha}.</cmath>  
 
<cmath>F_B = \frac {T}{\sin \alpha}, F_A = \frac {T}{\cos \alpha}.</cmath>  

Revision as of 10:31, 22 February 2024

The segment of the shortest length

Shortest segment.png

The segment $AB$ has the ends on the sides of a right angle and contains a point $C(x_C, y_C).$ Find the shortest length of such a segment.

Solution

Let's imagine that $AB$ is a spring rod that cannot bend, but tends to shorten its length.

The rod is fixed at point $C$ on a hinge without friction. The hinge allows the rod to rotate and slide.

The ends of the rod can slide without friction along the grooves - the sides of the corner.

Let the rod be balanced, and the force pulling it together is equal to $T.$ The grooves can create a force only along the normal, so they act on the rod with forces \[F_B = \frac {T}{\sin \alpha}, F_A = \frac {T}{\cos \alpha}.\] For the rod to be balanced, it is required that the moments of the forces be equal relative to point $C.$ The moments of forces are: \[F_A \cdot AC \cdot \sin \alpha =  F_B \cdot BC \cdot \cos \alpha \implies \frac {BC}{AC} = \tan^2 \alpha,\] \[\frac {y_C}{x_C} = \frac {BC \cdot \sin \alpha}{AC \cdot \cos \alpha} = \tan^3 \alpha \implies\] \[AB = \left ( x_C^ {\frac {2}{3}} + y_C^ {\frac {2}{3}}\right ) ^{\frac {3}{2}}.\]