The time (in seconds) it takes for an athlete to run 50 meters is an example of a continuous random variable.
True
False
answer is "TRUE"
Since,there are an infinite number of possible times that can be taken by athlete
The time (in seconds) it takes for an athlete to run 50 meters is an example...
A program with a quadratic run time takes t seconds to run, when given an input size n. If the same algorithm is given input of size 2n, then the program will take approximately how many seconds? a. 2t b. t c. 4t d. 6t
A simple pendulum of length 2 meters takes a time of 16 seconds to finish 8 oscillations. The acceleration due to gravity acting on this pendulum is given by A)19.72 m/s2 B)27.4 m/s2 C)9.8 m/s2 D)4.9 m/s2
A program takes 20 seconds to run on 1 processor and 5 seconds to run on 4 processors. Estimate Tseq. What is the maximum speedup?
are 15 meters from the hub. The c) Consider an Ethernet network time it takes for a bit to propagate from th ten times longer then for a 100 Mbps Ethernet. in which all nodes ub to a node for a 10 Mbps Ethernet is True False
Question 6 Given the following chart. 5 points Save Female Male Athlete 6 Non-Athlete 32 4 8 An individual from a group of 50 athletes and non-athletes is picked at random to get a price in the party. the probability that the one called is a male athlete is 3/25 : True False
Exercice 2: A biostatistician is interested in studying the time X (in seconds) it takes a hematology cell counter to complete a test on a blood sample. The probability density function of the aforementioned time is: cose if 0<x</2 f(x) = 0 elsewhere. 1. Find the cumulative distribution function and compute the median and 65-th percentile of the time to complete a test on a sample. 2. What is the percentage of tests require less than 7/3 seconds to complete?...
Exercice 2: A biostatistician is interested in studying the time X (in seconds) it takes a hematology cell counter to complete a test on a blood sample. The probability density function of the aforementioned time is: f(1) = cos z if 0 < x < 7/2 elsewhere. 1. Find the cumulative distribution function and compute the median and 65-th percentile of the time to complete a test on a sample. 2. What is the percentage of tests require less than...
A biostatistician is interested in studying the time X (in seconds) it takes a hematology cell counter to complete a test on a blood sample. The probability density function of the aforementioned time is: f(x) = ( cos x if 0 < x < π/2 0 elsewhere. 1. Find the cumulative distribution function and compute the median and 65-th percentile of the time to complete a test on a sample. 2. What is the percentage of tests require less than...
A biostatistician is interested in studying the time X (in seconds) it takes a hematology cell counter to complete a test on a blood sample. The probability density function of the aforementioned time is: f(x) = cos x if 0 < x < pi/2 0 elsewhere. 1. Find the cumulative distribution function and compute the median and 65-th percentile of the time to complete a test on a sample. 2. What is the percentage of tests require less than /3...
Exercice 2: A biostatistician is interested in studying the time X (in seconds) it takes a hematology cell counter to complete a test on a blood sample. The probability density function of the aforementioned time is: COST f(x) = = {* if 0 < x < 1/2 elsewhere. 0 1. Find the cumulative distribution function and compute the median and 65-th percentile of the time to complete a test on a sample. 2. What is the percentage of tests require...