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run_buck_dcdc_2_combine.m
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function run_buck_dcdc_2_combine()
% Run a Pareto optimization of a Buck DC-DC inductor and store the results
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% (c) 2021, T. Guillod, BSD License
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
close('all');
addpath(genpath('example_files'))
addpath('magnetic_toolbox')
add_path_mag_tb(false)
%% data
flag = get_spec_flag(); % converter specifications
sweep = {};
sweep{end+1} = struct('f_sw', logspace(log10(50e3), log10(250e3), 10)); % switching frequency
sweep{end+1} = struct('r_gap', logspace(log10(0.005), log10(0.2), 12)); % relative air gap length
sweep{end+1} = struct('A_core', logspace(log10(25e-6), log10(1000e-6), 15)); % core cross section
sweep{end+1} = struct('r_core', logspace(log10(1.0), log10(3.0), 6)); % core aspect ratio
sweep{end+1} = struct('A_litz', logspace(log10(5e-6), log10(20e-6), 8)); % wire copper area
sweep{end+1} = struct('n_winding', 2:16); % number of turns
n_split = 100; % number of data per chunk
%% fct for analyzing an inductor design
fct_solve = @(param) get_inductor_fct_solve(param, false);
%% run
data = get_sweep_combine('Buck DC-DC / combine', n_split, flag, sweep, fct_solve);
%% save
save('example_files/data_buck_dcdc.mat', '-struct', 'data', '-v7.3');
end