Sensitivity index
The sensitivity index or discriminability index or detectability index d′ (pronounced 'dee-prime') is a statistic used in signal detection theory. It provides the separation between the means of the signal and the noise distributions, in units of the standard deviation of the signal or noise distribution. When both distributions are univariate normal distributions with the same standard deviation,
- .
When the distributions are multivariate normal distributions with the same covariance matrix, is the Mahalanobis distance between them:
When they have different standard deviations and (or different covariance matrices and in more than one dimension), the effective can be defined as the normalized mean separation of two equal-variance normals that corresponds to the same classification error rate. This does not have a closed-form expression, but can be computed using numerical methods[1] (Matlab code). When variances are unequal, a common approximation is to take them to be equal to their average, which leads to[2]:
in higher dimensions, it is the Mahalanobis distance with the average covariance matrix.
d′ can also be estimated from the observed hit rate and false-alarm rate, as follows:[2]:7
- d′ = Z(hit rate) − Z(false alarm rate),
where function Z(p), p ∈ [0,1], is the inverse of the cumulative distribution function of the Gaussian distribution.
d′ can be related to the area under the receiver operating characteristic curve, or AUC, via:[3]
d′ is a dimensionless statistic. A higher d′ indicates that the signal can be more readily detected.
See also
References
- Das, Abhranil (2020). "A method to integrate and classify normal distributions". arXiv:2012.14331.
- MacMillan, N.; Creelman, C. (2005). Detection Theory: A User's Guide. Lawrence Erlbaum Associates. ISBN 9781410611147.
- Simpson, A. J.; Fitter, M. J. (1973). "What is the best index of detectability?". Psychological Bulletin. 80 (6): 481–488. doi:10.1037/h0035203.
- Wickens, Thomas D. (2001). Elementary Signal Detection Theory. OUP USA. ch. 2, p. 20. ISBN 0-19-509250-3.