Answer:
27
Step-by-step explanation:
You add 63 and 90 (90 being the right angle) and then subtract that from 180 which is the sum of all three angles and you get 27.
(1.4 x 10^18) / (1.1 x 10^12) = <u>1.27 x 10^6</u>
Roughly 1.27 million Earth's. That's a bunch.
Answer:
h(-3)=9
Step-by-step explanation:
hope this helps
Answer:
The probability that the demand will exceed 190 cfs during the early afternoon on a randomly selected day is
Step-by-step explanation:
Let Y be the water demand in the early afternoon.
If the random variable Y has density function f (y) and a < b, then the probability that Y falls in the interval [a, b] is
A random variable Y is said to have an exponential distribution with parameter if and only if the density function of Y is
If Y is an exponential random variable with parameter β, then
mean = β
To find the probability that the demand will exceed 190 cfs during the early afternoon on a randomly selected day, you must:
We are given the mean = β = 100 cubic feet per second
Compute the indefinite integral
Compute the boundaries
The probability that the demand will exceed 190 cfs during the early afternoon on a randomly selected day is