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PP_AdvectiveAccel.m
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PP_AdvectiveAccel.m
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% %
% POST-PROCESSING %
% ADVECTIVE ACCELERATION VECTOR FIELD %
% %
%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%
% %
% Giuseppe Di Labbio %
% Department of Mechanical, Industrial & Aerospace Engineering %
% Concordia University Montréal, Canada %
% %
% Last Update: October 3rd, 2018 by Giuseppe Di Labbio %
% %
%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%
% %
% Copyright (C) 2018 Giuseppe Di Labbio %
% %
% This program is free software: you can redistribute it and/or modify it %
% under the terms of the GNU General Public License as published by the %
% Free Software Foundation, either version 3 of the License, or (at your %
% option) any later version. %
% %
% This program is distributed in the hope that it will be useful, but %
% WITHOUT ANY WARRANTY; without even the implied warranty of %
% MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU %
% General Public License for more details. %
% %
% You should have received a copy of the GNU General Public License along %
% with this program. If not, see <https://www.gnu.org/licenses/>. %
% %
%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%
% %
% SYNTAX %
% %
% ACC = PP_AdvectiveAccel(VEC, VGT); %
% %
% DESCRIPTION %
% %
% This function computes the advective acceleration vector field of a %
% velocity field given its velocity gradient tensor. The function detects %
% if the calculation is two or three dimensional. %
% %
% References: %
% N/A %
% %
% ----------------------------------------------------------------------- %
% Variables: %
% ----------------------------------------------------------------------- %
% 'ACC' - STRUCT %
% - Advective acceleration vector field in the form of a %
% struct. The struct contains the vector components of the %
% acceleration field ('x' and 'y' in two dimensions). In %
% three dimensions, the struct ought to contain the %
% components 'x', 'y' and 'z'. %
% ----------------------------------------------------------------------- %
% 'VEC' - STRUCT %
% - Velocity vector field in the form of a struct. The %
% struct contains the mask ('C'), Cartesian coordinates %
% ('X' and 'Y') and velocity vector components ('U' and %
% 'V'). In three dimensions, the struct ought to contain %
% the Cartesian coordinates 'X', 'Y', and 'Z' and the %
% velocity components 'U', 'V', and 'W'. %
% ----------------------------------------------------------------------- %
% 'VGT' - STRUCT %
% - Velocity gradient tensor containing the four components %
% 'UX', 'UY', 'VX' and 'VY' in 2D or the nine components %
% 'UX', 'UY', 'UZ', 'VX', 'VY', 'VZ', 'WX', 'WY' and 'WZ' %
% in 3D. %
% ----------------------------------------------------------------------- %
% %
% EXAMPLE %
% %
% Calculate the advective acceleration vector field of a time-dependent %
% double gyre on the domain (x,y) = [0,2]x[0,1] with a constant grid %
% spacing of 0.01 over the time interval [0,20] with time-step size 0.1. %
% Use A = 0.1, epsilon = 0.25, and omega = 2*pi/10. %
% %
% >> x = linspace(0, 2, 201).'; %
% >> y = linspace(0, 1, 101).'; %
% >> t = linspace(0, 20, 21).'; %
% >> A = 0.1; %
% >> epsn = 0.25; %
% >> omga = 2*pi/10; %
% >> [VEC, VGT] = GEN_DoubleGyre(x, y, t, A, epsn, omga); %
% >> ACC = cell(length(t),1); %
% >> Amag = cell(length(t),1); %
% >> for k = 1:length(t) %
% ACC{k} = PP_AdvectiveAccel(VEC{k}, VGT{k}); %
% Amag{k} = sqrt(ACC{k}.x.^2 + ACC{k}.y.^2); %
% end %
% >> for k = 1:length(t) %
% contourf(VEC{k}.X, VEC{k}.Y, Amag{k}, 'EdgeColor', 'None'); %
% colormap jet; %
% hold on; %
% quiver(VEC{k}.X(1:4:end,1:4:end), VEC{k}.Y(1:4:end,1:4:end), ... %
% VEC{k}.U(1:4:end,1:4:end), VEC{k}.V(1:4:end,1:4:end), 'k'); %
% hold off; %
% pause(0.25); %
% end %
% >> clear k; %
% %
% DEPENDENCIES %
% %
% Requires: %
% N/A %
% %
% Called in: %
% N/A %
% %
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% PP_AdvectiveAccel
function [ACC] = PP_AdvectiveAccel(VEC, VGT)
if length(fieldnames(VEC)) == 5
ACC = struct('x', 0, 'y', 0);
ACC.x = VEC.U.*VGT.UX + VEC.V.*VGT.UY;
ACC.y = VEC.U.*VGT.VX + VEC.V.*VGT.VY;
elseif length(fieldnames(VEC)) == 7
ACC = struct('x', 0, 'y', 0, 'z', 0);
ACC.x = VEC.U.*VGT.UX + VEC.V.*VGT.UY + VEC.W.*VGT.UZ;
ACC.y = VEC.U.*VGT.VX + VEC.V.*VGT.VY + VEC.W.*VGT.VZ;
ACC.z = VEC.U.*VGT.WX + VEC.V.*VGT.WY + VEC.W.*VGT.WZ;
end
%% %%%%%%%%%%%%%%%%%%%%%%%%% SUPPRESS MESSAGES %%%%%%%%%%%%%%%%%%%%%%%%% %%
%#ok<*N/A>
% Line(s) N/A
% Message(s)
% * N/A
% Reason(s)
% * N/A
%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% NOTES %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%
% %
% Line(s) N/A %
% * N/A. %
% %
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%