Inside a rhombus E with sides 10 unit and one interior angle less than 90 degree , there are 2 parallel (with E) parallelograms A and B, both can move freely and uniformly inside E but must keep parallel with E in moving. A is with base 8 unit and adjacent side 6 unit ; while B is with base 5 unit and adjacent side 9 unit. If a point is chosen randomly in E, find the probability that the point lies inside A and B at the same time.

Bierlehre59

Bierlehre59

Open question

2022-08-18

Geometric probability - parallelograms
Inside a rhombus E with sides 10 unit and one interior angle less than 90 degree, there are 2 parallel (with E) parallelograms A and B, both can move freely and uniformly inside E but must keep parallel with E in moving. A is with base 8 unit and adjacent side 6 unit; while B is with base 5 unit and adjacent side 9 unit. If a point is chosen randomly in E, find the probability that the point lies inside A and B at the same time.

Answer & Explanation

Izabella Fisher

Izabella Fisher

Beginner2022-08-19Added 14 answers

Step 1
We can either impose oblique (x,y) coordinates on the plane of the three paralellograms, with the x- and y-axes parallel to the sides of all the parallelograms, or we can transform the plane linearly (preserving relative areas) so that the rhombus becomes a square. Either way, it is convenient to place the axes so that the bottom and left sides of the rhombus lie along the x- and y-axes, respectively.
Taking the random variables X A , Y A , X A , Y A as the coordinates of the lower left corner of parallelogram A, X B , Y B as the coordinates of the lower left corner of parallelogram B, and X P , Y P as the coordinates of a random point P within the rhombus, let the variables have pairwise independent distributions
X A U ( 0 , 2 ) Y A U ( 0 , 4 ) X B U ( 0 , 5 ) Y B U ( 0 , 1 ) X P U ( 0 , 10 ) Y P U ( 0 , 10 )
where U (a, b) is the uniform distribution on the interval [a,b].
Step 2
Now, P is (strictly) inside A B if and only if (Q) min { X A , X B } < X P < max { X A + 8 , X B + 5 }
and (R) min { Y A , Y B } < Y P < max { Y A + 6 , Y B + 1 } .
(If a point on the boundary of A B counts as "inside both A and B" then change < to ≤ in the previous statement.)
Since the variables are pairwise independent, so are the events Q and R described by equations (Q) and (R), respectively, and the answer to the question, P ( Q R ), obeys the equation P ( Q R ) = P ( Q ) P ( R ) ..
So consider equation Q. For given values X A = x A and X B = x B , let u = min { X A , X B } and v = max { X A + 8 , X B + 5 }; then
P ( Q X A = x A , X B = x B ) = P ( u < X P < v ) = 1 10 ( v u )
(since 0 u v 10). So the unconditional probability P(Q) is just 1 10 of the mean size of the interval [ min { X A , X B } , max { X A + 8 , X B + 5 } ]. I figure the mean of max { X A + 8 , X B + 5 } min { X A , X B } is 71 15 , so P ( Q ) = 71 150 , and by similar reasoning P ( R ) = 71 120 , so I find that
P ( Q R ) = ( 71 150 ) ( 71 120 ) = 5041 / 18000 0.2800555 .
Dillan Valenzuela

Dillan Valenzuela

Beginner2022-08-20Added 3 answers

Step 1
We may assume that everything happens in the unit square [ 0 , 1 ] 2 .
Begin with the following one-dimensional problem: We have a movable subinterval J [ 0 , 1 ] leaving free space of length 0 < 1 2 , whose position is uniformly distributed within the given limits. Denote by p(x) the probability that the point x [ 0 , 1 ] is covered by J. Then p ( 1 x ) = p ( x ), by symmetry. For 0 x 1 2 it is easy to see that p ( x ) = { x ( ( 0 x ) , 1 ( x 1 2 ) . .
Step 2
If we now have two such intervals J 1 , J 2 such that 1 < 2 1 2 , distributed independently, then the probability q(x) that x is covered by both intervals computes to
q ( x ) = { x 2 ( 1 2 ( 0 x 1 ) , ( x ( 2 ( 1 x 2 ) , 1 ( 2 x 1 2 ) .
Step 3
In the case at hand we have 1 = 1 5 , 2 = 1 2 for the x-direction. If we now assume that x is uniformly distributed in [0,1] as well the overall probability P x that the random point x is covered by both intervals becomes
P x = 2 0 1 / 2 p ( x ) d x = 2 0 1 / 5 10 x 2 d x + 2 1 / 5 1 / 2 2 x d x = 71 150   .
Similarly for the y-direction: Here 1 = 1 10 , 2 = 2 5 . The overall probability P y that a random point y is covered by both intervals becomes
P y = 2 0 1 / 10 25 x 2 d x + 2 1 / 10 2 / 5 5 x 2 d x + 2 2 / 5 1 / 2 1 d x = 71 120   .
The probability P that a uniformly distributed random point ( x , y ) [ 0 , 1 ] 2 is covered by both random rectangles at the same time is therefore given by
P = P x P y = 5041 18 000 0.280056   ,.

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