Neyman–Pearson lemma

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In statistics, the Neyman-Pearson lemma states that when performing a hypothesis test between two point hypotheses H₀: θ = θ₀ and H₁: θ = θ₁, then the likelihood-ratio test which rejects H₀ in favour of H₁ when

${\displaystyle \Lambda(x)=\frac{ L( \theta _{0} \mid x)}{ L (\theta _{1} \mid x)} \leq \eta \text{ where } P(\Lambda(X)\leq \eta|H_0)=\alpha }$

is the most powerful test of size α for a threshold η. If the test is most powerful for all ${\displaystyle \theta_1 \in \Theta_1}$, it is said to be uniformly most powerful (UMP) for alternatives in the set ${\displaystyle \Theta_1 \, }$.

It is named for Jerzy Neyman and Egon Pearson.

In practice, the likelihood ratio is often used directly to construct tests — see Likelihood-ratio test. However it can also be used to suggest particular test-statistics that might be of interest or to suggest simplified tests — for this one considers algebraic manipulation of the ratio to see if there are key statistics in it is related to the size of the ratio (i.e. whether a large statistic corresponds to a small ratio or to a large one).

Proof

Define the rejection region of the null hypothesis for the NP test as

${\displaystyle R_{NP}=\left\{ X: \frac{L(\theta_{0},X)}{L(\theta_{1},X)} \leq \eta\right\} .}$

Any other test will have a different rejection region that we define as ${\displaystyle R_A}$. Furthermore define the function of region, and parameter

${\displaystyle P(R,\theta)=\int_R L(\theta|x)\, dx, }$

where this is the probability of the data falling in region R, given parameter ${\displaystyle \theta}$.

For both tests to have significance level ${\displaystyle \alpha}$, it must be true that

${\displaystyle \alpha= P(R_{NP}, \theta_0)=P(R_A, \theta_0) \,.}$

However it is useful to break these down into integrals over distinct regions, given by

${\displaystyle P(R_{NP} \cap R_A, \theta) + P(R_{NP} \cap R_A^c, \theta) = P(R_{NP},\theta) ,}$

and

${\displaystyle P(R_{NP} \cap R_A, \theta) + P(R_{NP}^c \cap R_A, \theta) = P(R_A,\theta).}$

Setting ${\displaystyle \theta=\theta_0}$ and equating the above two expression, yields that

${\displaystyle P(R_{NP} \cap R_A^c, \theta_0) = P(R_{NP}^c \cap R_A, \theta_0).}$

Comparing the powers of the two tests, which are ${\displaystyle P(R_{NP},\theta_1)}$ and ${\displaystyle P(R_A,\theta_1)}$, one can see that

${\displaystyle P(R_{NP},\theta_1) \geq P(R_A,\theta_1) \text{ if, and only if, } P(R_{NP} \cap R_A^c, \theta_1) \geq P(R_{NP}^c \cap R_A, \theta_1). }$

Now by the definition of ${\displaystyle R_{NP}}$ ,

${\displaystyle P(R_{NP} \cap R_A^c, \theta_1)= \int_{R_{NP}\cap R_A^c} L(\theta_{1}|x)\,dx \geq \frac{1}{\eta} \int_{R_{NP}\cap R_A^c} L(\theta_0|x)\,dx = \frac{1}{\eta}P(R_{NP} \cap R_A^c, \theta_0)}$

${\displaystyle = \frac{1}{\eta}P(R_{NP}^c \cap R_A, \theta_0) = \frac{1}{\eta}\int_{R_{NP}^c \cap R_A} L(\theta_{0}|x)\,dx \geq \int_{R_{NP}^c\cap R_A} L(\theta_{1}|x)dx = P(R_{NP}^c \cap R_A, \theta_1).}$

Hence the inequality holds.

Example

Let ${\displaystyle X_1, \dots, X_n}$ be a random sample from the ${\displaystyle \mathcal{N}(\mu,\sigma^2)}$ distribution where the mean ${\displaystyle \mu}$ is known, and suppose that we wish to test for ${\displaystyle H_0:\sigma^2=\sigma_0^2}$ against ${\displaystyle H_1:\sigma^2=\sigma_1^2}$. The likelihood for this set of normally distributed data is

${\displaystyle L\left(\sigma^2;\mathbf{x}\right)\propto \left(\sigma^2\right)^{-n/2} \exp\left\{-\frac{\sum_{i=1}^n \left(x_i-\mu\right)^2}{2\sigma^2}\right\}.}$

We can compute the likelihood ratio to find the key statistic in this test and its effect on the test's outcome:

${\displaystyle \Lambda(\mathbf{x}) = \frac{L\left(\sigma_1^2;\mathbf{x}\right)}{L\left(\sigma_0^2;\mathbf{x}\right)} = \left(\frac{\sigma_1^2}{\sigma_0^2}\right)^{-n/2}\exp\left\{-\frac{1}{2}(\sigma_1^{-2}-\sigma_0^{-2})\sum_{i=1}^n \left(x_i-\mu\right)^2\right\}.}$

This ratio only depends on the data through ${\displaystyle \sum_{i=1}^n \left(x_i-\mu\right)^2}$. Therefore, by the Neyman-Pearson lemma, the most powerful test of this type of hypothesis for this data will depend only on ${\displaystyle \sum_{i=1}^n \left(x_i-\mu\right)^2}$. Also, by inspection, we can see that if ${\displaystyle \sigma_1^2>\sigma_0^2}$, then ${\displaystyle \Lambda(\mathbf{x})}$ is an increasing function of ${\displaystyle \sum_{i=1}^n \left(x_i-\mu\right)^2}$. So we should reject ${\displaystyle H_0}$ if ${\displaystyle \sum_{i=1}^n \left(x_i-\mu\right)^2}$ is sufficiently large. The rejection threshold depends on the size of the test.

See also

• Statistical power
• Receiver operating characteristic

References

• Jerzy Neyman, Egon Pearson (1933). On the Problem of the Most Efficient Tests of Statistical Hypotheses. Philosophical Transactions of the Royal Society of London. Series A, Containing Papers of a Mathematical or Physical Character 231: 289–337.
• cnx.org: Neyman-Pearson criterion

External links

• MIT OpenCourseWare lecture notes: most powerful tests, uniformly most powerful tests

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