Universal hypothesis testing

In statistics, universal hypothesis testing is a special case of binary simple hypothesis testing. The universal problem is to distinguish between a simple null hypothesis $H_{0}:Q=P$ , and the most general composite alternative $H_{1}:Q\neq P$ , using independent and identically distributed samples from $Q$ . The setting is sometimes referred to as goodness of fit testing, or one-sample testing.

A simple binary hypothesis testing problem involves distinguishing between $H_{0}:Q=P_{0}$ and $H_{1}:Q=P_{1}$ , using samples $X_{1},\dots ,X_{n}{\overset {\text{i.i.d.}}{\sim }}Q$ . In the traditional setting of hypothesis testing $P_{0},P_{1}$ are known apriori. A composite version of this problem involves sets of probability distributions $\Omega _{0},\Omega _{1}$ , and asks to distinguish between $H_{0}:Q\in \Omega _{0}$ and $H_{1}:Q\in \Omega _{1}$ . In contrast, the universal setting corresponds to the special case of composite hypothesis testing, where the null hypothesis is simple, $\Omega _{0}=P$ and the alternative hypothesis is the set of all distributions other than $P$ , $\Omega _{1}=\{F:F\neq P\}$ . For example, someone might want to know if a particular coin was fair, i.e. $\mathbb {P} [X=H]={\frac {1}{2}}=\mathbb {P} [X=T]$ or not, i.e. $\mathbb {P} [X=H]\neq \mathbb {P} [X=T]$ , where $H,T$ denote the coin coming up heads or tails.

The asymptotics of universal hypothesis testing were first discussed in Hoeffding's work on optimal tests for multinomial distributions^[1]. There have been many subsequent works on the topic^[2]^[3]^[4] in many directions. While Hoeffding's initial results were restricted to distributions with finite supports, later results developed solutions for continuous distributions using extensions of the Kullback-Leibler Divergence^[5], or kernel methods^[6]^[7].

References

↑ Hoeffding, Wassily (April 1965). "Asymptotically Optimal Tests for Multinomial Distributions". The Annals of Mathematical Statistics. 36 (2): 369–401. doi:10.1214/aoms/1177700150. ISSN 0003-4851.
↑ Levitan, E.; Merhav, N. (August 2002). "A competitive Neyman-Pearson approach to universal hypothesis testing with applications". IEEE Transactions on Information Theory. 48 (8): 2215–2229. doi:10.1109/TIT.2002.800478. ISSN 0018-9448.
↑ Zeitouni, O.; Gutman, M. (March 1991). "On universal hypotheses testing via large deviations". IEEE Transactions on Information Theory. 37 (2): 285–290. doi:10.1109/18.75244.
↑ Li, Yun; Nitinawarat, Sirin; Veeravalli, Venugopal V. (July 2014). "Universal Outlier Hypothesis Testing". IEEE Transactions on Information Theory. 60 (7): 4066–4082. arXiv:1302.4776. doi:10.1109/TIT.2014.2317691. ISSN 0018-9448.
↑ Yang, Pengfei; Chen, Biao (April 2019). "Robust Kullback-Leibler Divergence and Universal Hypothesis Testing for Continuous Distributions". IEEE Transactions on Information Theory. 65 (4): 2360–2373. arXiv:1711.04238. doi:10.1109/TIT.2018.2879057. ISSN 0018-9448.
↑ Zhu, Shengyu; Chen, Biao; Chen, Zhitang; Yang, Pengfei (April 2021). "Asymptotically Optimal One- and Two-Sample Testing With Kernels". IEEE Transactions on Information Theory. 67 (4): 2074–2092. arXiv:1908.10037. doi:10.1109/TIT.2021.3059267. ISSN 0018-9448.
↑ Zhu, Shengyu; Chen, Biao; Yang, Pengfei; Chen, Zhitang (2019-04-11). "Universal Hypothesis Testing with Kernels: Asymptotically Optimal Tests for Goodness of Fit". Proceedings of the Twenty-Second International Conference on Artificial Intelligence and Statistics. PMLR: 1544–1553. arXiv:1802.07581.

[1] Hoeffding, Wassily (April 1965). "Asymptotically Optimal Tests for Multinomial Distributions". The Annals of Mathematical Statistics. 36 (2): 369–401. doi:10.1214/aoms/1177700150. ISSN 0003-4851.

[2] Levitan, E.; Merhav, N. (August 2002). "A competitive Neyman-Pearson approach to universal hypothesis testing with applications". IEEE Transactions on Information Theory. 48 (8): 2215–2229. doi:10.1109/TIT.2002.800478. ISSN 0018-9448.

[3] Zeitouni, O.; Gutman, M. (March 1991). "On universal hypotheses testing via large deviations". IEEE Transactions on Information Theory. 37 (2): 285–290. doi:10.1109/18.75244.

[4] Li, Yun; Nitinawarat, Sirin; Veeravalli, Venugopal V. (July 2014). "Universal Outlier Hypothesis Testing". IEEE Transactions on Information Theory. 60 (7): 4066–4082. arXiv:1302.4776. doi:10.1109/TIT.2014.2317691. ISSN 0018-9448.

[5] Yang, Pengfei; Chen, Biao (April 2019). "Robust Kullback-Leibler Divergence and Universal Hypothesis Testing for Continuous Distributions". IEEE Transactions on Information Theory. 65 (4): 2360–2373. arXiv:1711.04238. doi:10.1109/TIT.2018.2879057. ISSN 0018-9448.

[6] Zhu, Shengyu; Chen, Biao; Chen, Zhitang; Yang, Pengfei (April 2021). "Asymptotically Optimal One- and Two-Sample Testing With Kernels". IEEE Transactions on Information Theory. 67 (4): 2074–2092. arXiv:1908.10037. doi:10.1109/TIT.2021.3059267. ISSN 0018-9448.

[7] Zhu, Shengyu; Chen, Biao; Yang, Pengfei; Chen, Zhitang (2019-04-11). "Universal Hypothesis Testing with Kernels: Asymptotically Optimal Tests for Goodness of Fit". Proceedings of the Twenty-Second International Conference on Artificial Intelligence and Statistics. PMLR: 1544–1553. arXiv:1802.07581.

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Universal hypothesis testing

See also

References