Number of dogs encounters per day, the number of customers entering a store per hour, the number of bacteria per liter of water, etc. are classically modelled using the Poisson distribution. With an exponential distribution, on the other hand, is used for modelling intervals of between events and how long a light bulb lasts, for example. After learning this, person P decides to model the observations in such a way that the corresponding random variables Y₁,...,Y for a random sample that is, n independent observation, of the exponential distribution Exp >0. The parameter > 0 is used as the statistical model parameter 1 which is the expected value of each observation random variable Y₁ a.) Derive the joint density function f(y; μ) specifying the model. b.) Derive the likelihood function L (μ) and the log likelihood function 1 (μ) c.) Define the maximum likelihood estimate ₁ (y) in the model for the parameter μ and form the maximum likelihood estimator (Y) in the model for the parameter μ. d.) Assume that n = 6 and the observed data (i.e., six dog encounter intervals (min)) is y = (Y1, Y2, ..., 35, 36) = (2.25, 8.40, 5.10, 11.85, 3.30, 8.10) .Use the data to calculate the ML estimate for the expected value μ of the intervals. Also consider what can be deduced from this: On the basis on this analysis of problem, do you think it is possible, i.e. likely, that expected value would actually be 3 (minutes). e.) Calculate the expected value EμM (Y) of the ML estimator ^ (Y) Tell using this (with justification) is the ML estimator unbiased? (Use the definition of unbiased estimator) f.) Calculate the variance varμ₁ (Y) of the ML estimator (Y)

Calculus For The Life Sciences
2nd Edition
ISBN:9780321964038
Author:GREENWELL, Raymond N., RITCHEY, Nathan P., Lial, Margaret L.
Publisher:GREENWELL, Raymond N., RITCHEY, Nathan P., Lial, Margaret L.
Chapter13: Probability And Calculus
Section13.CR: Chapter 13 Review
Problem 8CR
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Number of dogs encounters per day, the number of customers entering a store per hour, the number of bacteria per liter of
water, etc. are classically modelled using the Poisson distribution. With an exponential distribution, on the other hand, is used
for modelling intervals of between events and how long a light bulb lasts, for example.
After learning this, person P decides to model the observations in such a way that the corresponding random variables
Y₁....,Y, for a random sample that is, n independent observation, of the exponential distribution Exp (H)
μ > O
The parameter μ>0 is used as the statistical model parameter 1 which is the expected value of each
observation random variable Y₁.
a.) Derive the joint density function f(y; μ) specifying the model.
b.) Derive the likelihood function L (μ) and the log likelihood function 1(µ) .
c.) Define the maximum likelihood estimate ₁ (y) in the model for the parameter μ and form the maximum likelihood
estimator (Y) in the model for the parameter μ.
d.) Assume that n = 6 and the observed data (i.e., six dog encounter intervals (min)) is
y = (y1, Y2,
=
Y5, 96) (2.25, 8.40, 5.10, 11.85, 3.30, 8.10) .Use the data to calculate the ML estimate for the
expected value μ of the intervals. Also consider what can be deduced from this: On the basis on this analysis of problem,
you think it is possible, i.e. likely, that expected value would actually be 3 (minutes).
do
e.) Calculate the expected value E₁₁ (Y) of the ML estimator ^ (Y) . Tell using this (with justification) is the ML
estimator unbiased? (Use the definition of unbiased estimator)
f.) Calculate the variance varμ^ (Y) of the ML estimator ^ (Y) .
Transcribed Image Text:Number of dogs encounters per day, the number of customers entering a store per hour, the number of bacteria per liter of water, etc. are classically modelled using the Poisson distribution. With an exponential distribution, on the other hand, is used for modelling intervals of between events and how long a light bulb lasts, for example. After learning this, person P decides to model the observations in such a way that the corresponding random variables Y₁....,Y, for a random sample that is, n independent observation, of the exponential distribution Exp (H) μ > O The parameter μ>0 is used as the statistical model parameter 1 which is the expected value of each observation random variable Y₁. a.) Derive the joint density function f(y; μ) specifying the model. b.) Derive the likelihood function L (μ) and the log likelihood function 1(µ) . c.) Define the maximum likelihood estimate ₁ (y) in the model for the parameter μ and form the maximum likelihood estimator (Y) in the model for the parameter μ. d.) Assume that n = 6 and the observed data (i.e., six dog encounter intervals (min)) is y = (y1, Y2, = Y5, 96) (2.25, 8.40, 5.10, 11.85, 3.30, 8.10) .Use the data to calculate the ML estimate for the expected value μ of the intervals. Also consider what can be deduced from this: On the basis on this analysis of problem, you think it is possible, i.e. likely, that expected value would actually be 3 (minutes). do e.) Calculate the expected value E₁₁ (Y) of the ML estimator ^ (Y) . Tell using this (with justification) is the ML estimator unbiased? (Use the definition of unbiased estimator) f.) Calculate the variance varμ^ (Y) of the ML estimator ^ (Y) .
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