Title :
On error exponents in hypothesis testing
Author_Institution :
Dept. of Electr. Eng., Univ. of California, Riverside, CA
Abstract :
The classical result of Blahut, which characterizes achievable error exponents in binary hypothesis testing, is generalized in two different directions. First, in M-ary hypothesis testing, the tradeoff of all M(M-1) types of error exponents and corresponding optimal decision schemes are explored. Then, motivated by a power-constrained distributed detection scenario, binary hypothesis testing is revisited, and the tradeoff of power consumption versus error exponents is fully characterized. In the latter scenario, sensors are allowed to make random decisions as to whether they should remain silent and save power, or transmit and improve detection quality. It is then shown by an example that optimal sensor decisions may indeed be random
Keywords :
constraint theory; distributed sensors; exponential distribution; power consumption; power distribution; Neyman-Pearson test; Renyi alpha-divergence; binary M-ary hypothesis testing; error exponent; optimal decision scheme; power consumption; power-constrained distributed detection; Bayesian methods; Energy consumption; Error probability; Light rail systems; Sensor phenomena and characterization; Testing; Distributed detection; Neyman–Pearson test; RÉnyi´s; error exponents; large deviations;
Journal_Title :
Information Theory, IEEE Transactions on
DOI :
10.1109/TIT.2005.851769
