Informant (statistics)

For other uses, see Informant (disambiguation).

For other uses, see Score function.

"Score (statistics)" redirects here. Not to be confused with Raw score.

In statistics, the score (or informant ^[1] ) is the gradient of the log-likelihood function with respect to the parameter vector. Evaluated at a particular value of the parameter vector, the score indicates the steepness of the log-likelihood function and thereby the sensitivity to infinitesimal changes to the parameter values. If the log-likelihood function is continuous over the parameter space, the score will vanish at a local maximum or minimum; this fact is used in maximum likelihood estimation to find the parameter values that maximize the likelihood function.

Since the score is a function of the observations, which are subject to sampling error, it lends itself to a test statistic known as score test in which the parameter is held at a particular value. Further, the ratio of two likelihood functions evaluated at two distinct parameter values can be understood as a definite integral of the score function. ^[2]

Definition

The score is the gradient (the vector of partial derivatives) of ${\displaystyle \log {\mathcal {L}}(\theta ;x)}$, the natural logarithm of the likelihood function, with respect to an m-dimensional parameter vector ${\displaystyle \theta }$.

${\displaystyle s(\theta ;x)\equiv {\frac {\partial \log {\mathcal {L}}(\theta ;x)}{\partial \theta }}}$

This differentiation yields a ${\displaystyle (1\times m)}$ row vector at each value of ${\displaystyle \theta }$ and ${\displaystyle x}$, and indicates the sensitivity of the likelihood (its derivative normalized by its value).

In older literature,^{[ citation needed ]} "linear score" may refer to the score with respect to infinitesimal translation of a given density. This convention arises from a time when the primary parameter of interest was the mean or median of a distribution. In this case, the likelihood of an observation is given by a density of the form^{[ clarification needed ]}${\displaystyle {\mathcal {L}}(\theta ;X)=f(X+\theta )}$. The "linear score" is then defined as

${\displaystyle s_{\rm {linear}}={\frac {\partial }{\partial X}}\log f(X)}$

Properties

Mean

While the score is a function of ${\displaystyle \theta }$, it also depends on the observations ${\displaystyle \mathbf {x} =(x_{1},x_{2},\ldots ,x_{T})}$ at which the likelihood function is evaluated, and in view of the random character of sampling one may take its expected value over the sample space. Under certain regularity conditions on the density functions of the random variables, ^{[3] [4]} the expected value of the score, evaluated at the true parameter value ${\displaystyle \theta }$, is zero. To see this, rewrite the likelihood function ${\displaystyle {\mathcal {L}}}$ as a probability density function ${\displaystyle {\mathcal {L}}(\theta ;x)=f(x;\theta )}$, and denote the sample space ${\displaystyle {\mathcal {X}}}$. Then:

${\displaystyle {\begin{aligned}\operatorname {E} (s\mid \theta )&=\int _{\mathcal {X}}f(x;\theta ){\frac {\partial }{\partial \theta }}\log {\mathcal {L}}(\theta ;x)\,dx\\[6pt]&=\int _{\mathcal {X}}f(x;\theta ){\frac {1}{f(x;\theta )}}{\frac {\partial f(x;\theta )}{\partial \theta }}\,dx=\int _{\mathcal {X}}{\frac {\partial f(x;\theta )}{\partial \theta }}\,dx\end{aligned}}}$

The assumed regularity conditions allow the interchange of derivative and integral (see Leibniz integral rule), hence the above expression may be rewritten as^{[ clarification needed ]}

${\displaystyle {\frac {\partial }{\partial \theta }}\int _{\mathcal {X}}f(x;\theta )\,dx={\frac {\partial }{\partial \theta }}1=0.}$

It is worth restating the above result in words: the expected value of the score, at true parameter value ${\displaystyle \theta }$ is zero. Thus, if one were to repeatedly sample from some distribution, and repeatedly calculate the score, then the mean value of the scores would tend to zero asymptotically.

Variance

Main article: Fisher information

The variance of the score, ${\displaystyle \operatorname {Var} (s(\theta ))=\operatorname {E} (s(\theta )s(\theta )^{\mathsf {T}})}$, can be derived from the above expression for the expected value.

${\displaystyle {\begin{aligned}0&={\frac {\partial }{\partial \theta ^{\mathsf {T}}}}\operatorname {E} (s\mid \theta )\\[6pt]&={\frac {\partial }{\partial \theta ^{\mathsf {T}}}}\int _{\mathcal {X}}{\frac {\partial \log {\mathcal {L}}(\theta ;X)}{\partial \theta }}f(x;\theta )\,dx\\[6pt]&=\int _{\mathcal {X}}{\frac {\partial }{\partial \theta ^{\mathsf {T}}}}\left\{{\frac {\partial \log {\mathcal {L}}(\theta ;X)}{\partial \theta }}f(x;\theta )\right\}\,dx\\[6pt]&=\int _{\mathcal {X}}\left\{{\frac {\partial ^{2}\log {\mathcal {L}}(\theta ;X)}{\partial \theta \,\partial \theta ^{\mathsf {T}}}}f(x;\theta )+{\frac {\partial \log {\mathcal {L}}(\theta ;X)}{\partial \theta }}{\frac {\partial f(x;\theta )}{\partial \theta ^{\mathsf {T}}}}\right\}\,dx\\[6pt]&=\int _{\mathcal {X}}{\frac {\partial ^{2}\log {\mathcal {L}}(\theta ;X)}{\partial \theta \partial \theta ^{\mathsf {T}}}}f(x;\theta )\,dx+\int _{\mathcal {X}}{\frac {\partial \log {\mathcal {L}}(\theta ;X)}{\partial \theta }}{\frac {\partial f(x;\theta )}{\partial \theta ^{\mathsf {T}}}}\,dx\\[6pt]&=\int _{\mathcal {X}}{\frac {\partial ^{2}\log {\mathcal {L}}(\theta ;X)}{\partial \theta \,\partial \theta ^{\mathsf {T}}}}f(x;\theta )\,dx+\int _{\mathcal {X}}{\frac {\partial \log {\mathcal {L}}(\theta ;X)}{\partial \theta }}{\frac {\partial \log {\mathcal {L}}(\theta ;X)}{\partial \theta ^{\mathsf {T}}}}f(x;\theta )\,dx\\[6pt]&=\operatorname {E} \left({\frac {\partial ^{2}\log {\mathcal {L}}(\theta ;X)}{\partial \theta \,\partial \theta ^{\mathsf {T}}}}\right)+\operatorname {E} \left({\frac {\partial \log {\mathcal {L}}(\theta ;X)}{\partial \theta }}\left[{\frac {\partial \log {\mathcal {L}}(\theta ;X)}{\partial \theta }}\right]^{\mathsf {T}}\right)\end{aligned}}}$

Hence the variance of the score is equal to the negative expected value of the Hessian matrix of the log-likelihood. ^[5]

${\displaystyle \operatorname {E} (s(\theta )s(\theta )^{\mathsf {T}})=-\operatorname {E} \left({\frac {\partial ^{2}\log {\mathcal {L}}}{\partial \theta \,\partial \theta ^{\mathsf {T}}}}\right)}$

The latter is known as the Fisher information and is written ${\displaystyle {\mathcal {I}}(\theta )}$. Note that the Fisher information is not a function of any particular observation, as the random variable ${\displaystyle X}$ has been averaged out. This concept of information is useful when comparing two methods of observation of some random process.

Examples

Bernoulli process

Consider observing the first n trials of a Bernoulli process, and seeing that A of them are successes and the remaining B are failures, where the probability of success is θ.

Then the likelihood ${\displaystyle {\mathcal {L}}}$ is

${\displaystyle {\mathcal {L}}(\theta ;A,B)={\frac {(A+B)!}{A!B!}}\theta ^{A}(1-\theta )^{B},}$

so the score s is

${\displaystyle s={\frac {\partial \log {\mathcal {L}}}{\partial \theta }}={\frac {1}{\mathcal {L}}}{\frac {\partial {\mathcal {L}}}{\partial \theta }}={\frac {A}{\theta }}-{\frac {B}{1-\theta }}.}$

We can now verify that the expectation of the score is zero. Noting that the expectation of A is nθ and the expectation of B is n(1 − θ) [recall that A and B are random variables], we can see that the expectation of s is

${\displaystyle E(s)={\frac {n\theta }{\theta }}-{\frac {n(1-\theta )}{1-\theta }}=n-n=0.}$

We can also check the variance of ${\displaystyle s}$. We know that A + B = n (so B = n − A) and the variance of A is nθ(1 − θ) so the variance of s is

${\displaystyle {\begin{aligned}\operatorname {var} (s)&=\operatorname {var} \left({\frac {A}{\theta }}-{\frac {n-A}{1-\theta }}\right)=\operatorname {var} \left(A\left({\frac {1}{\theta }}+{\frac {1}{1-\theta }}\right)\right)\\&=\left({\frac {1}{\theta }}+{\frac {1}{1-\theta }}\right)^{2}\operatorname {var} (A)={\frac {n}{\theta (1-\theta )}}.\end{aligned}}}$

Binary outcome model

For models with binary outcomes (Y = 1 or 0), the model can be scored with the logarithm of predictions

${\displaystyle S=Y\log(p)+(1-Y)(\log(1-p))}$

where p is the probability in the model to be estimated and S is the score. ^[6]

Applications

Scoring algorithm

Main article: Scoring algorithm

The scoring algorithm is an iterative method for numerically determining the maximum likelihood estimator.

Score test

Main article: Score test

Note that ${\displaystyle s}$ is a function of ${\displaystyle \theta }$ and the observation ${\displaystyle \mathbf {x} =(x_{1},x_{2},\ldots ,x_{T})}$, so that, in general, it is not a statistic. However, in certain applications, such as the score test, the score is evaluated at a specific value of ${\displaystyle \theta }$ (such as a null-hypothesis value), in which case the result is a statistic. Intuitively, if the restricted estimator is near the maximum of the likelihood function, the score should not differ from zero by more than sampling error. In 1948, C. R. Rao first proved that the square of the score divided by the information matrix follows an asymptotic χ²-distribution under the null hypothesis. ^[7]

Further note that the likelihood-ratio test is given by

${\displaystyle -2\left[\log {\mathcal {L}}(\theta _{0})-\log {\mathcal {L}}({\hat {\theta }})\right]=2\int _{\theta _{0}}^{\hat {\theta }}{\frac {d\,\log {\mathcal {L}}(\theta )}{d\theta }}\,d\theta =2\int _{\theta _{0}}^{\hat {\theta }}s(\theta )\,d\theta }$

which means that the likelihood-ratio test can be understood as the area under the score function between ${\displaystyle \theta _{0}}$ and ${\displaystyle {\hat {\theta }}}$. ^[8]

Score matching (machine learning)

See also: Diffusion model

For other uses, see Matching (statistics) and Propensity score matching.

Score matching describes the process of applying machine learning algorithms (commonly neural networks) to approximate the score function ${\displaystyle s_{\theta }\approx \nabla _{x}\log p(x)}$ of an unknown distribution ${\displaystyle \pi (x)}$ from finite samples. The learned function ${\displaystyle s_{\theta }}$ can then be used in generative modeling to draw new samples from ${\displaystyle \pi (x)}$. ^[9]

It might seem confusing that the word score has been used for ${\displaystyle \nabla _{x}\log p(x)}$, because it is not a likelihood function, neither it has a derivative with respect to the parameters. For more information about this definition, see the referenced paper. ^[10]

History

The term "score function" may initially seem unrelated to its contemporary meaning, which centers around the derivative of the log-likelihood function in statistical models. This apparent discrepancy can be traced back to the term's historical origins. The concept of the "score function" was first introduced by British statistician Ronald Fisher in his 1935 paper titled "The Detection of Linkage with 'Dominant' Abnormalities." ^[11] Fisher employed the term in the context of genetic analysis, specifically for families where a parent had a dominant genetic abnormality. Over time, the application and meaning of the "score function" have evolved, diverging from its original context but retaining its foundational principles. ^{[12] [13]}

Fisher's initial use of the term was in the context of analyzing genetic attributes in families with a parent possessing a genetic abnormality. He categorized the children of such parents into four classes based on two binary traits: whether they had inherited the abnormality or not, and their zygosity status as either homozygous or heterozygous. Fisher devised a method to assign each family a "score," calculated based on the number of children falling into each of the four categories. This score was used to estimate what he referred to as the "linkage parameter," which described the probability of the genetic abnormality being inherited. Fisher evaluated the efficacy of his scoring rule by comparing it with an alternative rule and against what he termed the "ideal score." The ideal score was defined as the derivative of the logarithm of the sampling density, as mentioned on page 193 of his work. ^[11]

The term "score" later evolved through subsequent research, notably expanding beyond the specific application in genetics that Fisher had initially addressed. Various authors adapted Fisher's original methodology to more generalized statistical contexts. In these broader applications, the term "score" or "efficient score" started to refer more commonly to the derivative of the log-likelihood function of the statistical model in question. This conceptual expansion was significantly influenced by a 1948 paper by C. R. Rao, which introduced "efficient score tests" that employed the derivative of the log-likelihood function. ^[14]

Thus, what began as a specialized term in the realm of genetic statistics has evolved to become a fundamental concept in broader statistical theory, often associated with the derivative of the log-likelihood function.

See also

• Fisher information  – Notion in statistics
• Information theory  – Scientific study of digital information
• Score test  – Statistical test based on the gradient of the likelihood function
• Scoring algorithm  – form of Newton's method used in statisticsPages displaying wikidata descriptions as a fallback
• Standard score  – How many standard deviations apart from the mean an observed datum is
• Support curve  – Function related to statistics and probability theoryPages displaying short descriptions of redirect targets

Notes

1. Informant in Encyclopaedia of Maths
2. Pickles, Andrew (1985). An Introduction to Likelihood Analysis. Norwich: W. H. Hutchins & Sons. pp.  24–29. ISBN   0-86094-190-6.
3. Serfling, Robert J. (1980). Approximation Theorems of Mathematical Statistics . New York: John Wiley & Sons. p.  145. ISBN   0-471-02403-1.
4. Greenberg, Edward; Webster, Charles E. Jr. (1983). Advanced Econometrics: A Bridge to the Literature. New York: John Wiley & Sons. p. 25. ISBN   0-471-09077-8.
5. Sargan, Denis (1988). Lectures on Advanced Econometrics. Oxford: Basil Blackwell. pp. 16–18. ISBN   0-631-14956-2.
6. Steyerberg, E. W.; Vickers, A. J.; Cook, N. R.; Gerds, T.; Gonen, M.; Obuchowski, N.; Pencina, M. J.; Kattan, M. W. (2010). "Assessing the performance of prediction models. A framework for traditional and novel measures". Epidemiology . 21 (1): 128–138. doi:10.1097/EDE.0b013e3181c30fb2. PMC   3575184 . PMID   20010215.
7. Rao, C. Radhakrishna (1948). "Large sample tests of statistical hypotheses concerning several parameters with applications to problems of estimation". Mathematical Proceedings of the Cambridge Philosophical Society . 44 (1): 50–57. Bibcode:1948PCPS...44...50R. doi:10.1017/S0305004100023987. S2CID   122382660.
8. Buse, A. (1982). "The Likelihood Ratio, Wald, and Lagrange Multiplier Tests: An Expository Note". The American Statistician . 36 (3a): 153–157. doi:10.1080/00031305.1982.10482817.
9. Yang Song; Jascha Sohl-Dickstein; Diederik P. Kingma; Abhishek Kumar; Stefano Ermon; Ben Poole (2020). "Score-Based Generative Modeling through Stochastic Differential Equations". arXiv: 2011.13456 [cs.LG].
10. https://www.jmlr.org/papers/volume6/hyvarinen05a/hyvarinen05a.pdf ^{[ bare URL PDF ]}
11. Fisher, Ronald Aylmer. "The detection of linkage with 'dominant' abnormalities." Annals of Eugenics 6.2 (1935): 187-201.
12. Ben (https://stats.stackexchange.com/users/173082/ben), Interpretation of "score", URL (version: 2019-04-17): https://stats.stackexchange.com/q/342374
13. Miller, Jeff. "Earliest Known Uses of Some of the Words of Mathematics (S)." Mathematics History Notes. Last revised on April 14, 2020. https://mathshistory.st-andrews.ac.uk/Miller/mathword/s/
14. Radhakrishna Rao, C. (1948). Large sample tests of statistical hypotheses concerning several parameters with applications to problems of estimation. Mathematical Proceedings of the Cambridge Philosophical Society, 44(1), 50-57. doi:10.1017/S0305004100023987

References

• Chentsov, N.N. (2001) [1994], "Informant", Encyclopedia of Mathematics , EMS Press
• Cox, D. R.; Hinkley, D. V. (1974). Theoretical Statistics. Chapman & Hall. ISBN   0-412-12420-3.
• Schervish, Mark J. (1995). Theory of Statistics. New York: Springer. Section 2.3.1. ISBN   0-387-94546-6.