Novelty detection

Novelty detection is the mechanism by which an intelligent organism is able to identify an incoming sensory pattern as being hitherto unknown. If the pattern is sufficiently salient or associated with a high positive or strong negative utility, it will be given computational resources for effective future processing.

The principle is long known in neurophysiology, with roots in the orienting response research by E. N. Sokolov^[1] in the 1950s. The reverse phenomenon is habituation, i.e., the phenomenon that known patterns yield a less marked response. Early neural modeling attempts were by Yehuda Salu.^[2] An increasing body of knowledge has been collected concerning the corresponding mechanisms in the brain.^[3]^[4] In technology, the principle became important for radar detection methods during the Cold War, where unusual aircraft-reflection patterns could indicate an attack by a new type of aircraft. Today, the phenomenon plays an important role in machine learning and data science, where the corresponding methods are known as anomaly detection or outlier detection. An extensive methodological overview is given by Markou and Singh.^[5]^[6]

^ Sokolov, E.N. (1960). "Neuronal models and the orienting reflex". The Central Nervous System and Behavior. Josiah Macy, Jr. Foundation. pp. 187–276. OCLC 222201512.
^ Salu, Y. (1988). "Models of neural novelty detectors, with similarities to cerebral cortex". BioSystems. 21 (2): 99–113. Bibcode:1988BiSys..21...99S. doi:10.1016/0303-2647(88)90003-2. PMID 3355886.
^ Tiitinen, H.; May, P.; Reinikainen, K.; Näätänen, R. (1994). "Attentive novelty detection in humans is governed by pre-attentive sensory memory". Nature. 372 (6501): 90–92. Bibcode:1994Natur.372...90T. doi:10.1038/372090a0. PMID 7969425. S2CID 4255887.
^ Duncan, K.; Ketz, N.; Inati, S.J.; Davachi, L. (2012). "Evidence for area CA1 as a match/mismatch detector: A high-resolution fMRI study of the human hippocampus". Hippocampus. 22 (3): 389–398. doi:10.1002/hipo.20933. PMC 3529001. PMID 21484934.
^ Markou, M.; Singh, S. (2003). "Novelty detection: a review — Part 1: statistical approaches". Signal Processing. 83 (12): 2481–97. doi:10.1016/j.sigpro.2003.07.018. S2CID 17490415.
^ Markou, M.; Singh, S. (2003). "Novelty detection: a review — Part 2: neural network based approaches". Signal Processing. 83 (12): 2499–2521. doi:10.1016/j.sigpro.2003.07.019.

[Sokolov,_E.N_1960,_pp._187-1] Sokolov, E.N. (1960). "Neuronal models and the orienting reflex". The Central Nervous System and Behavior. Josiah Macy, Jr. Foundation. pp. 187–276. OCLC 222201512.

[Yehuda_Salu,_1988-2] Salu, Y. (1988). "Models of neural novelty detectors, with similarities to cerebral cortex". BioSystems. 21 (2): 99–113. Bibcode:1988BiSys..21...99S. doi:10.1016/0303-2647(88)90003-2. PMID 3355886.

[3] Tiitinen, H.; May, P.; Reinikainen, K.; Näätänen, R. (1994). "Attentive novelty detection in humans is governed by pre-attentive sensory memory". Nature. 372 (6501): 90–92. Bibcode:1994Natur.372...90T. doi:10.1038/372090a0. PMID 7969425. S2CID 4255887.

[4] Duncan, K.; Ketz, N.; Inati, S.J.; Davachi, L. (2012). "Evidence for area CA1 as a match/mismatch detector: A high-resolution fMRI study of the human hippocampus". Hippocampus. 22 (3): 389–398. doi:10.1002/hipo.20933. PMC 3529001. PMID 21484934.

[5] Markou, M.; Singh, S. (2003). "Novelty detection: a review — Part 1: statistical approaches". Signal Processing. 83 (12): 2481–97. doi:10.1016/j.sigpro.2003.07.018. S2CID 17490415.

[6] Markou, M.; Singh, S. (2003). "Novelty detection: a review — Part 2: neural network based approaches". Signal Processing. 83 (12): 2499–2521. doi:10.1016/j.sigpro.2003.07.019.

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