Contents
How is the ratio of likelihoods in the Neyman Pearson lemma?
The lemma tells us that, in order to be the most powerful test, the ratio of the likelihoods: should be small for sample points X inside the critical region C (“less than or equal to some constant k “) and large for sample points X outside of the critical region (“greater than or equal to some constant k “).
When do you use the nehman Pearson lemma?
Then, we can apply the Nehman Pearson Lemma when testing the simple null hypothesis H 0: μ = 3 against the simple alternative hypothesis H A: μ = 4. The lemma tells us that, in order to be the most powerful test, the ratio of the likelihoods:
Which is the best critical region of size α?
Then, C is a best critical region of size α if the power of the test at θ = θ a is the largest among all possible hypothesis tests. More formally, C is the best critical region of size α if, for every other critical region D of size α, we have:
How to test the nehman Pearson lemma for X?
Suppose X is a single observation (that’s one data point!) from a normal population with unknown mean μ and known standard deviation σ = 1 / 3. Then, we can apply the Nehman Pearson Lemma when testing the simple null hypothesis H 0: μ = 3 against the simple alternative hypothesis H A: μ = 4.
Which is the best Test of the null hypothesis h 0?
Consider the test of the simple null hypothesis H 0: θ = θ 0 against the simple alternative hypothesis H A: θ = θ a. Let C and D be critical regions of size α, that is, let: Then, C is a best critical region of size α if the power of the test at θ = θ a is the largest among all possible hypothesis tests.
Which is the p.d.f of a normal random variable?
Under the hypothesis H: μ = 12, the p.d.f. of a normal random variable is: for − ∞ < x < ∞ and σ > 0. In this case, the mean parameter μ = 12 is uniquely specified in the p.d.f., but the variance σ 2 is not.
How can we be sure that the t-test for a mean μ?
⌘ + ⇧ + F (Mac) As we learned from our work in the previous lesson, whenever we perform a hypothesis test, we should make sure that the test we are conducting has sufficient power to detect a meaningful difference from the null hypothesis. That said, how can we be sure that the T -test for a mean μ is the “most powerful” test we could use?