File:Mehrfachspalt-Numerisch.png
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| Description |
Deutsch: Numerisch berechnete Intensitätsverteilung hinter einem Mehrfachspalt dargestellt als Hitzefeld. Nicht berücksichtigt wurde die Freiraumdämpfung. Deutlich zu erkennen die Hauptmaximas und dazu schwach die Nebenmaximas. Hier wurde zur weiteren Veranschaulichung kein endliches Gitter sondern eine Wellenfront mit begrenzter Weite eingezeichnet.
In der Nähe des Gitter treten Alias-Effekte auf, die wegen der begrenzten Auflösung entstehen. |
| Date | |
| Source | Own work |
| Author | Miessen |
| PNG development |  This diagram was created with MATLAB. config.ini
;
; Some nice values
;
dim_x = 4000
dim_y = 2700
free_space_loss = 0
; gap width as factor to grating_distance
gap_width = 0.2
grating_count = 10
; grating_distance approx 2000 nm
; scaling_meter_per_px * 3/gap_width
grating_distance = 2250.e-9
offset_x = 600
; igonre...; 30 px per wave = 700.e-9 / 30px
; calculate near field / far field
scaling_meter_per_px = 150e-9
slit_width = 0
slit_iterations = 0
; 700 nm
wave_length = 700.e-9
|
| Source code | diffraction_grating.m code#!/usr/bin/octave -qf
% \usr\bin\octave
%%%%%%%%%%%%%%%%%%%%%%%%%%
%
% Miessen 2014
%
%%%%%%%%%%%%%%%%%%%%%%%%%%
%%%%%%%%%%%%%%%%%%%%%%%%%%
%
% getParameters
%
%%%%%%%%%%%%%%%%%%%%%%%%%%
function setParameters(config)
global parameters;
% parameters.grating_distance = getConfigValue(config, "grating_width");
parameters.dim_x = int32(getConfigValue(config, "dim_x"));
parameters.dim_y = int32(getConfigValue(config, "dim_y"));
parameters.free_space_loss = getConfigValue(config, "free_space_loss");
parameters.gap_width = getConfigValue(config, "gap_width");
parameters.grating_count = int32(getConfigValue(config, "grating_count"));
parameters.grating_distance = getConfigValue(config, "grating_distance");
parameters.offset_x = int32(getConfigValue(config, "offset_x"));
parameters.scaling_meter_per_px = getConfigValue(config, "scaling_meter_per_px");
parameters.wave_length = getConfigValue(config, "wave_length");
endfunction
%%%%%%%%%%%%%%%%%%%%%%%%%%
%
% findGapPositions
%
%%%%%%%%%%%%%%%%%%%%%%%%%%
function gaps = findGapPositions(grating_distance, grating_count)
if (grating_count < 2)
error("grating_count too small");
endif
width = grating_distance * (double(grating_count)-1);
gaps = [];
for i = 0:(grating_count-1)
gaps = [gaps (i*grating_distance-width/2)];
endfor
endfunction
%%%%%%%%%%%%%%%%%%%%%%%%%%
%
% gratingSignalStrength
%
%%%%%%%%%%%%%%%%%%%%%%%%%%
function amplitude = gratingSignalStrength(x, y, gaps, wave_length, free_space_loss)
% grating {gaps, sub_steps, gap_width }
% free_space_loss not implemented
% calculate distances
distances = [];
for gap_pos = gaps
distances = [ distances sqrt((y-gap_pos)^2 + x^2) ];
endfor
% calculate amplitudes
c_amps = [];
base_distance = sqrt(x^2 + y^2);
for d = distances
% delay = d - base_distance;
% phase = 2. * pi * delay/wave_length;
% amplitude phasor = c_amp
residual = rem(d, wave_length);
phase = 2. * pi * residual/wave_length;
c_amp = complex(cos(phase), sin(phase));
c_amp = c_amp / d; % free_space_loss ?? check - Integrate a slit!
c_amps = [c_amps c_amp];
endfor
% calculate amplitude
amplitude = abs(sum(c_amps))/length(gaps);
% eliminate free_space_loss
max_sum = sum(abs(c_amps))/length(gaps);
amplitude = amplitude/max_sum;
endfunction
%%%%%%%%%%%%%%%%%%%%%%%%%%
%
% slitSignalStrength
%
%%%%%%%%%%%%%%%%%%%%%%%%%%
function amplitude = slitSignalStrength(x, y, sub_steps, gap_width, wave_length, free_space_loss)
endfunction
%%%%%%%%%%%%%%%%%%%%%%%%%%
%
% calculateDiffraction
%
%%%%%%%%%%%%%%%%%%%%%%%%%%
function amplitudes = calculateDiffraction(gaps )
printf("Calculate Diffraction\n");
global parameters;
% Read globals
dim_y = parameters.dim_y;
dim_x = parameters.dim_x;
scaling_meter_per_px = parameters.scaling_meter_per_px;
offset_x = parameters.offset_x;
wave_length = parameters.wave_length;
free_space_loss = parameters.free_space_loss;
% Calculate dimensions
x_max = double(dim_x - offset_x - 1) * scaling_meter_per_px;
y_width = double(dim_y - 1) * scaling_meter_per_px;
y_max = y_width / 2.;
y_min = -1. * y_max;
% Initialize
amplitudes = zeros(dim_y, dim_x - offset_x);
for amp_pos_x = int32(1:(dim_x - offset_x))
printf("%3d%%", 100 * amp_pos_x/(dim_x - offset_x));
for amp_pos_y = int32(1:1:dim_y)
x = double(amp_pos_x) * scaling_meter_per_px;
y = y_min + double(amp_pos_y) * scaling_meter_per_px;
amp = gratingSignalStrength(x, y, gaps, wave_length, free_space_loss );
amplitudes(amp_pos_y, amp_pos_x) = amp; % row = y / column = x
endfor
printf("\b\b\b\b");
endfor
printf("Finished calculateDiffraction\n");
endfunction
%%%%%%%%%%%%%%%%%%%%
%
% generateGrating
%
%%%%%%%%%%%%%%%%%%%%
function rgb = generateGrating(rgb)
printf("Generate Grating\n");
global parameters;
dim_y = parameters.dim_y;
grating_count = parameters.grating_count;
grating_distance = parameters.grating_distance;
gap_width = parameters.gap_width;
offset_x = parameters.offset_x;
scaling_meter_per_px = parameters.scaling_meter_per_px;
%// gray = zeros(dim_y, offset_x);
y_width = double(dim_y - 1) * scaling_meter_per_px;
y_max = y_width / 2.;
% even or odd
if ( round(rem(grating_count, 2)) != 1. )
even_factor = 0.5; % grating_distance/2.;
else
even_factor = 0.;
endif
for y_px = int32(1:dim_y)
y = double(y_px) * scaling_meter_per_px;
stepper = y / grating_distance; % normalize
sub_stepper = stepper + even_factor - round(stepper);
% sub_stepper = rem(stepper,1);
% stepper
% odd: -0.5..+0.5
% even: 0.0..1.0
% Nachkommazahlen
% sub_stepper +/- 0.5 * grating_distance around gap
for x_px = offset_x-int32(double(offset_x)/40.):offset_x
if(abs(sub_stepper) <= gap_width)
rgb(y_px, x_px, :) = [0., 0., 0.];
else
rgb(y_px, x_px, :) = [0.8, 0.8, 0.8];
endif
endfor
endfor
endfunction
%%%%%%%%%%%%%%%%%%%
%
% generateLaser
%
%%%%%%%%%%%%%%%%%%%
function amplitudes = generateLaser()
printf("Generate Laser\n");
global parameters;
dim_y = parameters.dim_y;
grating_count = parameters.grating_count;
grating_distance = parameters.grating_distance;
offset_x = parameters.offset_x;
scaling_meter_per_px = parameters.scaling_meter_per_px;
y_width = double(dim_y - 1) * scaling_meter_per_px;
y_min = -1. * y_width / 2.;
laser_width = grating_distance * double(grating_count)
amplitudes = [];
for y_px = int32(1:dim_y)
y = y_min + double(y_px) * scaling_meter_per_px;
if (abs(y) <= laser_width / 2.)
amplitudes = [amplitudes; ones(1,offset_x)];
else
amplitudes = [amplitudes; zeros(1,offset_x)];
endif
endfor
endfunction
%%%%%%%%%%%%%
% %
% M A I N %
% %
%%%%%%%%%%%%%
global parameters
begin_cputime = cputime();
printf("Including CSV library\n");
echo_csv_lib = 0;
source ("./lib/csv_lib.m");
printf("Including config library\n");
global echo_config_lib = 0;
source ("./lib/load_config_lib.m");
printf("Starting\n");
arg_list = argv ();
if (rows(arg_list) != 2);
printf("wrong parameters, config file and output file needed.\n");
exit();
endif
config_filename = arg_list{1};
output_filename = arg_list{2};
config = loadConfig(config_filename);
% config
setParameters(config);
gaps = findGapPositions(parameters.grating_distance, parameters.grating_count);
gaps
% dim
% step
% wavelength
%
printf("Dimensions:\n");
% Debug
%x_width = parameters.scaling_meter_per_px * double(parameters.dim_x)
%y_width = parameters.scaling_meter_per_px * double(parameters.dim_y)
%amp = gratingSignalStrength(x_width, 0, gaps, parameters.wave_length, parameters.free_space_loss );
%amp
diffractionMap = calculateDiffraction(gaps);
max(max(diffractionMap))
diffractionPowerMap = diffractionMap.^2;
laserMap = generateLaser();
laserPowerMap = laserMap.^2;
map = jet();
diffractionInd = gray2ind(diffractionPowerMap);
diffractionRgb = ind2rgb (diffractionInd, map);
laserInd = gray2ind(laserPowerMap);
laserRgb = ind2rgb (laserInd, map);
offsetRgb = generateGrating(laserRgb);
finalRgb = [offsetRgb diffractionRgb];
%finalRgb = [offsetRgb]; % debug
imwrite(finalRgb, output_filename, "png");
printf("Total cpu time: %f seconds\n", cputime()-begin_cputime);
printf("Finished\n");
Lib/csv_lib.m code%
% GNU Octave library to write results to a csv file
%
1; % not a function file
%
% Add header to CSV file
%
function csvFile = addCsvFileHeader(csvFile, header)
if (isfield(csvFile, "headerList") == true)
csvFile.headerList = [csvFile.headerList; header];
else
csvFile.headerList = [header];
endif
endfunction
%
% Add record to a structure CsvLine based on existing header
%
function csvLine = addCsvLineRecord(csvLine, header, value)
csvLine.(header) = value;
endfunction
%
% Close CSV file
%
function csvFile = closeCsvFile(csvFile)
fclose(csvFile.fid);
csvFile.isOpened = false;
endfunction
%
% Create a CSV line for this file
%
function csvLine = createCsvFileLine(csvFile)
csvLine.headerList = csvFile.headerList;
for header = csvLine.headerList'
csvLine.(strtrim(header')) = "";
endfor
endfunction
%
% Output values of a csv line
%
function csvLine = printCsvLine(csvLine)
csvLine
endfunction
%
% Open CSV file
%
function csvFile = openCsvFile(filename)
csvFile.filename = filename;
% test if already exists
csvFile.fid = fopen(csvFile.filename, "w");
csvFile.isOpened = true;
endfunction
%
%
%
function csvLine = writeCsvFileHeader(csvFile)
line = "";
for header = csvFile.headerList'
line = [line, strtrim(header')];
line = [line, ","];
endfor
line = substr(line, 1, length(line)-1);
fprintf(csvFile.fid, "%s\r\n", line);
endfunction
%
%
%
function csvLine = writeCsvLine(csvFile, csvLine)
line = "";
for header = csvLine.headerList'
line = [line, csvLine.(strtrim(header'))];
line = [line, ","];
endfor
line = substr(line, 1, length(line)-1); % remove last comma
fprintf(csvFile.fid, "%s\r\n", line);
endfunction
Lib/load_config_lib.m code%
% GNU Octave library to load values from a config file
%
if(exist("echo_config_lib", "var") == 0)
global echo_config_lib = 1;
endif
%
%
%
function value = getConfigValue(config, var_name)
if (isfield(config, var_name) == false)
printf("Error: \"%s\" missing in config file\n", var_name);
exit();
endif
[value, success] = str2num(config.(var_name));
if(success != true)
printf("Error: Converting \"%s\" failed!\n", var_name);
exit();
endif
endfunction
%
%
%
function value = getConfigInt32(config, var_name)
if (isfield(config, var_name) == false)
printf("Error: \"%s\" missing in config file\n", var_name);
exit();
endif
[value, success] = str2double(config.(var_name));
if(success != true)
printf("Error: Converting \"%s\" failed!\n", var_name);
exit();
endif
endfunction
%
%
%
function value = getConfigString(config, var_name)
if (isfield(config, var_name) == false)
printf("Error: \"%s\" missing in config file\n", var_name);
exit();
endif
value = config.(var_name);
endfunction
%
%
%
function arrayKeyValuePair = loadConfig(filename)
% open file
% while has next line
% skip if blank
% skip if comment
% add key value pair to array
global echo_config_lib;
file = fopen (filename, "r");
line = fgetl(file);
lineNum = 1;
while (ischar(line));
if (echo_config_lib != 0)
printf("Line %i: %s\n",lineNum, line);
endif
if (strcmp(line, "") == 0);
if (strcmp(substr(line,1,1), ";") == 0);
if(length(findstr(line, "="))== 0)
printf("Error: Invalid line!\n");
exit();
endif
key = substr(line, 1, findstr(line, "=")(1)-1);
key = strtrim(key);
value = substr(line
, findstr(line, "=")(1)+1
, length(line)-findstr(line, "=")(1) );
value = strtrim(value);
printf("key = %s\n", key);
printf("value = %s\n", value);
if(strcmp(key, "") != 0)
printf("Error: Invalid key!\n");
exit();
endif
if(isfield("arrayKeyValuePair", "key") != 0)
printf("Error: Duplicate key!\n");
exit();
endif
arrayKeyValuePair.(key) = value;
else
if (echo_config_lib != 0);
printf("Comment\n");
endif
endif
else
if (echo_config_lib != 0);
printf("Blank line\n");
endif
endif
line = fgetl(file);
lineNum += 1;
endwhile
fclose(file);
endfunction
% INI format
% no white space at the beginning of a line
% empty lines allowed
% comment lines start with a semicolon
% key an value are seperated by a "="
% ascending white spaces are trimed from key
% prepending and ascending white spaces are trimed from values
% in case of duplicate values the first is valid
% crlf prefered, see RFC
%
|
Licensing edit
I, the copyright holder of this work, hereby publish it under the following license:
 
|
This file is made available under the Creative Commons CC0 1.0 Universal Public Domain Dedication. |
| The person who associated a work with this deed has dedicated the work to the public domain by waiving all of their rights to the work worldwide under copyright law, including all related and neighboring rights, to the extent allowed by law. You can copy, modify, distribute and perform the work, even for commercial purposes, all without asking permission.
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File history
Click on a date/time to view the file as it appeared at that time.
| Date/Time | Thumbnail | Dimensions | User | Comment | |
|---|---|---|---|---|---|
| current | 19:45, 26 September 2016 | | 3,600 × 2,700 (278 KB) | Cmdrjameson (talk | contribs) | Compressed with pngout. Reduced by 100kB (26% decrease). |
| 09:36, 19 April 2014 |  | 3,600 × 2,700 (378 KB) | Miessen (talk | contribs) | found a bug | |
| 14:58, 13 April 2014 |  | 4,000 × 2,700 (393 KB) | Miessen (talk | contribs) | super fine resolution to avoid aliasing | |
| 09:27, 28 March 2014 |  | 1,100 × 900 (64 KB) | Miessen (talk | contribs) | final version | |
| 17:03, 15 March 2014 |  | 450 × 450 (22 KB) | Miessen (talk | contribs) | User created page with UploadWizard |
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