A New Approach for Optimizing Highly Nonlinear Problems Based on the Observer Effect Concept
This addresses optimization challenges in specific engineering domains with complex nonlinearities, but appears incremental as it builds on existing meta-heuristic approaches.
The authors tackled the problem of optimizing highly nonlinear, multi-modal engineering problems by proposing a new meta-heuristic algorithm based on the Observer Effect concept, which showed utility in applications like EEG feature learning and distributed generator tuning, though no concrete performance numbers were provided.
A lot of real-world engineering problems represent dynamicity with nests of nonlinearities due to highly complex network of exponential functions or large number of differential equations interacting together. Such search spaces are provided with multiple convex regions peaked with diverse nonlinear slopes and in non-homogenous ways. To find global optima, a new meta-heuristic algorithm is proposed based on Observer Effect concepts for controlling memory usage per localities without pursuing Tabu-like cut-off approaches. Observer effect in physics (or psychology) regards bias in measurement (or perception) due to the interference of instrument (or knowledge). Performance analysis of the proposed algorithms is sought in two real-world engineering applications, i.e., Electroencephalogram feature learning and Distributed Generator parameter tuning, each of which having nonlinearity and complex multi-modal peaks distributions as their characteristics. In addition, the effect of version improvement has been assessed. The performance comparison with other optimizers in the same context suggests that proposed algorithm is useful both solely and in hybrid Gradient Descent settings where problem's search space is nonhomogeneous in terms of local peaks density.