Effects of wavelength ratio on wave modelling

Abstract

The efficacy of perturbation approaches for short–long wave interactions is examined by considering a simple case of two interacting wave trains with different wavelengths. Frequency-domain solutions are derived up to third order in wave steepness using two different formulations: one employing conventional wave-mode functions only, and the other introducing a modulated wave-mode representation for the short-wavelength wave. For long-wavelength wave steepness and short-to-long wavelength ratio ε₁ and ε₃ respectively, the two results are shown to be identical for ε₁ [Lt ] ε₃ < 0.5. As ε₁ approaches ε₃, the conventional wave-mode approach converges slowly and eventually diverges for ε₁ [Gt ] ε₃. The loss of convergence is because the linear phase of conventional wave-mode functions is ineffective for modelling the modulated phase of the short wave. As expected, this difficulty can be removed by using a modulated wave-mode function for the short wave. On the other hand, for relatively large ε₃ ∼O(1), the conventional wave-mode approach converges rapidly while the slowly varying interaction between the two waves cannot be accurately predicted by the present modulated wave-mode approach. These findings have important implications to (time-domain) numerical simulations of the nonlinear evolution of ocean wave fields, and suggest that a hybrid wave model employing both conventional (for large-ε₃ interactions) and modulated (for small-ε₃ interactions) wave-mode functions should be particularly effective.