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Ideal observer analysis

From Wikipedia, the free encyclopedia

Ideal observer analysis is a method for investigating how information is processed in a perceptual system.[1][2][3] It is also a basic principle that guides modern research in perception.[4][5]

The ideal observer is a theoretical system that performs a specific task in an optimal way. If there is uncertainty in the task, then perfect performance is impossible and the ideal observer will make errors.

Ideal performance is the theoretical upper limit of performance. It is theoretically impossible for a real system to perform better than ideal. Typically, real systems are only capable of sub-ideal performance.

This technique is useful for analyzing psychophysical data (see psychophysics).

Definition

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Many definitions of this term have been offered.

Geisler (2003)[6] (slightly reworded): The central concept in ideal observer analysis is the ideal observer, a theoretical device that performs a given task in an optimal fashion given the available information and some specified constraints. This is not to say that ideal observers perform without error, but rather that they perform at the physical limit of what is possible in the situation. The fundamental role of uncertainty and noise implies that ideal observers must be defined in probabilistic (statistical) terms. Ideal observer analysis involves determining the performance of the ideal observer in a given task and then comparing its performance to that of a real perceptual system, which (depending on the application) might be the system as a whole, a subsystem, or an elementary component of the system (e.g. a neuron).

Sequential ideal observer analysis

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In sequential ideal observer analysis,[7] the goal is to measure a real system's performance deficit (relative to ideal) at different processing stages. Such an approach is useful when studying systems that process information in discrete (or semi-discrete) stages or modules.

Natural and pseudo-natural tasks

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To facilitate experimental design in the laboratory, an artificial task may be designed so that the system's performance in the task may be studied. If the task is too artificial, the system may be pushed away from a natural mode of operation. Depending on the goals of the experiment, this may diminish its external validity.

In such cases, it may be important to keep the system operating naturally (or almost naturally) by designing a pseudo-natural task. Such tasks are still artificial, but they attempt to mimic the natural demands placed on a system. For example, the task might employ stimuli that resemble natural scenes and might test the system's ability to make potentially useful judgments about these stimuli.

Natural scene statistics are the basis for calculating ideal performance in natural and pseudo-natural tasks. This calculation tends to incorporate elements of signal detection theory, information theory, or estimation theory.

Normally distributed stimuli

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Das and Geisler [8] described and computed the detection and classification performance of ideal observers when the stimuli are normally distributed. These include the error rate and confusion matrix for ideal observers when the stimuli come from two or more univariate or multivariate normal distributions (i.e. yes/no, two-interval, multi-interval tasks and general multi-category classification tasks), the discriminability index of the ideal observer (Bayes discriminability index) and its relation to the receiver operating characteristic.

Notes

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  1. ^ Tanner Jr, Wilson P.; Birdsall, T. G. (1958). "Definitions of d′ and η as Psychophysical Measures". Journal of the Acoustical Society of America. 30 (10): 922–928. doi:10.1121/1.1909408. Archived from the original on February 26, 2013. Retrieved August 19, 2012.
  2. ^ Tanner Jr, W. P.; Jones, R. Clark (1960). "The ideal sensor system as approached through statistical decision theory and the theory of signal detectability". Visual search techniques: proceedings of a symposium, held in the Smithsonian Auditorium, Washington, D. C., April 7 and 8, 1959. United States National Academies. pp. 59–68. Retrieved August 19, 2012.
  3. ^ W. P. Tanner Jr. (1961). "Physiological implications of psychophysical data" (PDF). Annals of the New York Academy of Sciences. 89 (5): 752–65. doi:10.1111/j.1749-6632.1961.tb20176.x. hdl:2027.42/73966. PMID 13775211. S2CID 7135400.
  4. ^ Knill, David C.; Whitman, Richards (1996). Perception as Bayesian Inference. Cambridge University Press. ISBN 9780521461092. Retrieved August 19, 2012.
  5. ^ Pelli, D. G. (1993). "The quantum efficiency of vision". In Blakemore, Colin (ed.). Vision: Coding and Efficiency. Cambridge University Press. pp. 3–24. ISBN 9780521447690. Retrieved August 19, 2012.
  6. ^ Geisler, Wilson S. (2003). "Ideal Observer Analysis". In Chalupa, Leo M.; Werner, John S. (eds.). The Visual Neurosciences. MIT Press. pp. 825–837. ISBN 9780262033084. Retrieved August 19, 2012.
  7. ^ W. S. Geisler (1989). "Sequential ideal-observer analysis of visual discriminations". Psychological Review. 96 (2): 267–314. doi:10.1037/0033-295x.96.2.267. PMID 2652171.
  8. ^ Das, Abhranil; Geisler, Wilson (2020). "A method to integrate and classify normal distributions". arXiv:2012.14331 [stat.ML].