What question did this study set out to answer?

The aim is to explore a classical search method that matches the efficiency of quantum algorithms without requiring quantum principles.

March 24, 2026Open Access

Classical Search by Wave Resonance: √N Scaling from Coupled Oscillators Without Quantum Postulates

Key Points

The aim is to explore a classical search method that matches the efficiency of quantum algorithms without requiring quantum principles.
Utilized coupled harmonic oscillators arranged on a complete graph
Analyzed the performance of the search algorithm over a range of N from 4 to 512
Conducted control experiments to assess the role of the resonant oracle in achieving amplitude concentration
Achieved a search time proportional to √N, similar to Grover's quantum algorithm
Found a flat performance measure of t/√N between 316–325 steps for various sizes
Demonstrated that the resonant oracle lowers the marked node's frequency, enabling energy gap-based search efficiency

Abstract

Classical coupled harmonic oscillators on a complete graph locate a marked node in time proportional to √N — the same scaling as Grover's quantum search algorithm. No quantum postulates are required. The power-law exponent b = 0.4950 (theory: 0.5000) holds over N = 4..512, with t/√N flat at 316–325 steps across all sizes. The mechanism is Rabi oscillation between two collective modes: the resonant oracle lowers the marked node's spring frequency, creating an energy gap g = K/√N that drives amplitude concentration in time π/g ∝ √N. Control experiments confirm that without the oracle, no concentration occurs. Grover speedup is a wave phenomenon.

Classical Search by Wave Resonance: √N Scaling from Coupled Oscillators Without Quantum Postulates

Key Points

Abstract

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