Answer:
The distribution of R=Asinθ is P(θ<arcsin (t/A)) = (arcsin (t/A))π+ ½
Step-by-step explanation:
Given
To find the distribution of R=Asinθ
θ is uniformly distributed on (−π/2,π/2)
R=(v²/g)sin2α
g = 980 cm/s²
Since R=Asinθ
Divide Through by A
R/A = Asinθ/A
R/A = sinθ
So, P(R<t) = P(Asinθ<t) this is equivalent to
P(sinθ<t/A)
For t > A; P(sinθ<t/A) = 1
For |t| ≤ A; P(sinθ<t/A) = P(θ<arcsin (t/A))
For t < A; P(sinθ<t/A) = 0
So, we have
P(sinθ<t/A) = P(θ<arcsin (t/A))
P(θ<arcsin (t/A)) = (arcsin (t/A) + π/2)/π
P(θ<arcsin (t/A)) = (arcsin (t/A))/π + (π/2)/π
P(θ<arcsin (t/A)) = (arcsin (t/A))π+ ½
Hence, the distribution of R=Asinθ is P(θ<arcsin (t/A)) = (arcsin (t/A))π+ ½
Answer:
The distribution of the random variable R is derived as;
[(1/π)(sin^(-1) (t/A))] + (1/2)
Step-by-step explanation:
From the question,
Random variable, R=Asinθ
So, the distribution of this variable can be represented as;
P(R < t) = P(A sin θ < t)
So let's apply conditions to it to obtain;
P(R < t) = P(A sin θ < t) {1, P(θ < sin^(-1) (t/A)), 0
At conditions of, t > A ; |t| ≤ A ; t < A; respectively.
Therefore, since uniformly distributed on (−π/2,π/2), we finally arrive at;
P(θ < sin^(-1) (t/A)) = [(sin^(-1) (t/A)) + (π/2)]/π
= [(1/π)(sin^(-1) (t/A))] + (1/2)
