Foam::tmp<Foam::vectorField> Foam::waveSuperposition::velocity ( const scalar t, const vectorField& xyz ) const { vectorField result(xyz.size(), vector::zero); forAll(waveModels_, wavei) { const vector2D d(cos(waveAngles_[wavei]), sin(waveAngles_[wavei])); const vector2DField xz ( zip ( d & zip(xyz.component(0), xyz.component(1)), tmp<scalarField>(xyz.component(2)) ) ); const vector2DField uw ( waveModels_[wavei].velocity(t, xz) ); result += zip ( d.x()*uw.component(0), d.y()*uw.component(0), uw.component(1) ); } tmp<scalarField> s = scale(zip(xyz.component(0), xyz.component(1))); return s*result; }
Foam::tmp<Foam::vector2DField> Foam::waveModels::solitary::velocity ( const scalar t, const scalar u, const vector2DField& xz ) const { const scalar A = alpha(t); const scalarField Z(max(scalar(0), 1 - mag(xz.component(1)/depth()))); const scalarField P(Pi(t, u, xz.component(0))); return celerity(t) *zip ( A/4 *( (4 + 2*A - 6*A*sqr(Z))*P + (- 7*A + 9*A*sqr(Z))*sqr(P) ), - A*Z*depth()*k(t)*tanh(parameter(t, u, xz.component(0))) *( (2 + A - A*sqr(Z))*P + (- 7*A + 3*A*sqr(Z))*sqr(P) ) ); }
Foam::tmp<Foam::scalarField> Foam::waveSuperposition::scale ( const vector2DField& xy ) const { tmp<scalarField> tResult(new scalarField(xy.size(), 1)); scalarField& result = tResult.ref(); if (scale_.valid()) { const scalarField x(xy.component(0)); forAll(result, i) { result[i] *= scale_->value(x[i]); } }