Fichier:HarmonicDriveAni.gif

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Fichier d’origine (700 × 700 pixels, taille du fichier : 2,36 Mio, type MIME : image/gif, en boucle, 100 trames, 3,0 s)
Remarque : en raison de limitations techniques, les vignettes des images GIF en haute résolution telles que celle-ci ne seront pas animées.

Ce fichier provient de Wikimedia Commons et peut être utilisé par d'autres projets. Sa description sur sa page de description est affichée ci-dessous.

Description

Description
English: Harmonic-Drive Animation (strain wave gear (SWG)). (Colors in the drawing correspond to the Cross section File:Harmonic drive cross Legend.svg.)
Ncircular_spline = 42 (blue); Nflex_spline= 42-2 = 40 (red); Ratio = 40/(42-40) = 20
Deutsch: Harmonic-Drive Animation (Spannungswellengetriebe, Wellgetriebe oder Gleitkeilgetriebe). (Die Farbkodierung entspricht der Schnittzeichnung File:Harmonic drive cross Legend.svg.)
zInnenverzahnung = 42 (blue); zFlexspline= 42-2 = 40 (red); i = 40/(42-40) = 20
Date
Source Travail personnel
Auteur Jahobr
GIF information
InfoField
 Ce diagramme a été créé avec MATLAB par Jahobr
Code source
InfoField

MATLAB code

function HarmonicDriveAni()
% source code for drawing a HarmonicDrive
% this is by no means a "simulation". It is a hack job that produces a gif
%
% 2016-12-05 Jahobr (reworked 2017-09-16)
 
 
nTeethOutGear =  42;
nTeethFlex = nTeethOutGear-2;
modul = 0.1; % modul
 
colEdge = [0   0   0  ]; % Edge color
colFlex = [1   0.2 0.2]; % FlexSpline color
colWave = [0.1 0.7 0.1]; % WaveGen color
colGear = [0.2 0.2 1  ]; % static OuterGear color
 
nFrames = 100;
frameAngles = linspace(0,-pi,nFrames+1); % rotate clockwise
frameAngles = frameAngles(1:end-1); % delete redundant frame
 
[pathstr,fname] = fileparts(which(mfilename)); % save files under the same name and at file location
 
figHandle = figure(15674454);
clf
axesHandle = axes;
hold(axesHandle,'on')
axis equal
xlim([-3 3])
ylim([-3 3])
set(figHandle, 'Units','pixel');
set(figHandle, 'position',[1 1 700 700]); % [x y width height] 
set(axesHandle, 'position',[-0.05 -0.05 1.1 1.1]); % stretch axis bigger as figure, easy way to get rid of ticks [x y width height] 
set(figHandle,'GraphicsSmoothing','on') % requires at least version 2014b
 
for iFrame = 1:nFrames
    
    angleWaveGen = frameAngles(iFrame);
    angleFlexTeeth = angleWaveGen*(nTeethFlex-nTeethOutGear)/nTeethFlex; %  angle of the flexspline
    
    cla(axesHandle);
    
    %% %%%%%%%%    draw OuterGear (static)   %%%%%%%%
    %% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
    
    effectiveDiameter = modul*nTeethOutGear;
    toothTipDiameter = effectiveDiameter-1.4*modul;
    toothBottomDiameter = effectiveDiameter+1.6*modul;
    
    angleBetweenTeeth = 2*pi/nTeethOutGear; % angle between 2 teeth
    angleOffPoints = (0:angleBetweenTeeth/8:(2*pi));
    
    %% outerEdge
    maxDiameter = toothBottomDiameter*1.2; % definition of outer line
    maxXY = samplesEllipse(maxDiameter,maxDiameter,500);
    patch(maxXY(:,1),maxXY(:,2),colGear,'EdgeColor',colEdge,'LineWidth',0.5) % full outer disc
    
    %% inner teeth
    radiusOffPoints = angleOffPoints; % init
    
    radiusOffPoints(1:8:end) = toothBottomDiameter/2; % middle bottom
    radiusOffPoints(2:8:end) = toothBottomDiameter/2; % left bottom
    radiusOffPoints(3:8:end) = effectiveDiameter/2; % rising edge
    radiusOffPoints(4:8:end) = toothTipDiameter/2; % right top
    radiusOffPoints(5:8:end) = toothTipDiameter/2; % middle top
    radiusOffPoints(6:8:end) = toothTipDiameter/2; % left top
    radiusOffPoints(7:8:end) = effectiveDiameter/2; % falling edge
    radiusOffPoints(8:8:end) = toothBottomDiameter/2; % right bottom
    
    [X,Y] = pol2cart(angleOffPoints,radiusOffPoints);
    
    patch(X,Y,[1 1 1],'EdgeColor',colEdge,'LineWidth',0.5) % overlay white area for inner teeth
    
    
    %% %%%%%%%%%     draw Flexspline        %%%%%%%%%
    %% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
    
    % % deform estimation based on tooth distance (using the circumferences); could be automated!
    % U1 = 42*pi % Circumference of OuterGear
    % U1 =
    %   131.9469
    %
    % U2 = pi*sqrt(2*((42/2)^2+(0.9022*42/2)^2))  * 42/40 % Circumference of Flexspline * 42/40
    % U2 =
    %   131.9435
    deform = 0.9022;
    
    deformedDiameter = effectiveDiameter*deform; % scale down, but teeth must still have the same distance
    
    rootEffectiveDia = effectiveDiameter-1.6*modul; % fixed offset
    rootDeformedDia  = deformedDiameter-1.6*modul;  % fixed offset
    
    topEffectiveDia = effectiveDiameter+1.4*modul; % fixed offset
    topDeformedDia  = deformedDiameter+1.4*modul;  % fixed offset
    
    % % an equidistant sampled ellipse is needed, to keep the tooth distance constant all the way around
    offsetOnCircumference = (-angleWaveGen+angleFlexTeeth)/2/pi; % compensation + own_rotation  ,  normalization to "circumference"
    equiEffeXY = equidistantSamplesEllipse(effectiveDiameter,deformedDiameter,nTeethFlex*8, offsetOnCircumference); % points on effective diameter
    equiRootXY = equidistantSamplesEllipse(rootEffectiveDia, rootDeformedDia, nTeethFlex*8, offsetOnCircumference); % points with inwards offset
    equiOutXY  = equidistantSamplesEllipse(topEffectiveDia,  topDeformedDia,  nTeethFlex*8, offsetOnCircumference); % points with outwards offset
    
    toothXY = equiEffeXY; % intit
    
    toothXY(1:8:end,:) = equiOutXY(1:8:end,:); % middle top        I######I
    toothXY(2:8:end,:) = equiOutXY(2:8:end,:); % left top          I######+
    % toothXY(3:8:end) init did it                                 I####/
    toothXY(4:8:end,:) = equiRootXY(4:8:end,:); % right bottom     I##+
    toothXY(5:8:end,:) = equiRootXY(5:8:end,:); % middle bottom    I##I
    toothXY(6:8:end,:) = equiRootXY(6:8:end,:); % left bottom      I##+
    % toothXY(7:8:end) init did it                                 I####\
    toothXY(8:8:end,:) = equiOutXY(8:8:end,:); % right top         I######+
    
    [toothXY] = rotateCordiantes(toothXY,angleWaveGen);
    
    patch(toothXY(:,1),toothXY(:,2),colFlex,'EdgeColor',colEdge,'LineWidth',0.5) %draw flexspline with teeth
    
    
    %% hole
    holeEffectiveDia = effectiveDiameter-5*modul; % fixed inwards offset
    holeDeformedDia  = deformedDiameter-5*modul;  % fixed inwards offset
    
    holePathXY = samplesEllipse(holeEffectiveDia,holeDeformedDia,500);
    holePathXY = rotateCordiantes(holePathXY,angleWaveGen);
    patch(holePathXY(:,1),holePathXY(:,2),[1 1 1],'EdgeColor',colEdge,'LineWidth',0.5) % draw hole of deformed ring
    
    
    %% %%%%%%%%%   draw wave generator      %%%%%%%%%
    %% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
    
    waveEffectiveDia = holeEffectiveDia; % touch flex spline
    waveDeformedDia  = holeDeformedDia-5*modul; % extra air gap to spline, to make it more obvious
    
    wavePathXY = samplesEllipse(waveEffectiveDia,waveDeformedDia,500);
    [wavePathXY] = rotateCordiantes(wavePathXY,angleWaveGen);
    patch(wavePathXY(:,1),wavePathXY(:,2),colWave,'EdgeColor',colEdge,'LineWidth',0.5) % draw wave generator
    
    %% central shaft
    shaftPathXY = samplesEllipse(effectiveDiameter/2.5,effectiveDiameter/2.5,500);
    plot(axesHandle,shaftPathXY(:,1),shaftPathXY(:,2),'LineWidth',0.8,'color',colEdge); % draw central shaft outline
    
    
    %% %%%%%%%%%   save animation     %%%%%%%%%
    %% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
    
    drawnow;
    
    f = getframe(figHandle);
    if iFrame == 1 % create colormap
        [im,map] = rgb2ind(f.cdata,32,'nodither'); % 32 colors % create color map %% THE FIRST FRAME MUST INCLUDE ALL COLORES !!!
        % FIX WHITE, rgb2ind sets white to [0.9961    0.9961    0.9961], which is annoying
        [~,wIndex] = max(sum(map,2)); % find "white"
        map(wIndex,:) = 1; % make it truly white
        im(1,1,1,nFrames) = 0; % allocate
        
        if ~isempty(which('plot2svg'))
            plot2svg(fullfile(pathstr, [fname '_Frame1.svg']),figHandle) % by Juerg Schwizer
        else
            disp('plot2svg.m not available; see http://www.zhinst.com/blogs/schwizer/');
        end
    end
    
    imtemp = rgb2ind(f.cdata,map,'nodither');
    im(:,:,1,iFrame) = imtemp;
    
end
imwrite(im,map,fullfile(pathstr, [fname '.gif']),'DelayTime',1/30,'LoopCount',inf) % save gif
disp([fname '.gif  has ' num2str(numel(im)/10^6 ,4) ' Megapixels']) % Category:Animated GIF files exceeding the 50 MP limit
 
%%% equidistantSamplesEllipse test code
% figure(455467);clf;hold on;
% 
% equidistantXY = equidistantSamplesEllipse(1.5,0.5,40,0.1);
% plot(equidistantXY(:,1),equidistantXY(:,2),'bx-')
% 
% 
% equidistantXY = equidistantSamplesEllipse(2,1,40,1);
% plot(equidistantXY(:,1),equidistantXY(:,2),'bx-')
% 
% equidistantXY = equidistantSamplesEllipse(3,2,40,0.5);
% plot(equidistantXY(:,1),equidistantXY(:,2),'bx-')
% 
% equidistantXY = equidistantSamplesEllipse(4,3,40,0);
% plot(equidistantXY(:,1),equidistantXY(:,2),'bx-')
% pathXY = samplesEllipse(4,3,41);
% plot(pathXY(1:end-1,1),pathXY(1:end-1,2),'ro-')
% 
% plot([4 -4]/2,[0 0],'-k')
 
 
function equidistantXY = equidistantSamplesEllipse(diameterH,diameterV,nPoints,offset)
% Inputs:
%   diameterH  horizontal diameter
%   diameterV  vertical diameter
%   nPoints    number of resampled points
%   offsetFraction between 0 and 1 in circumference of ellipse
 
pathXY = samplesEllipse(diameterH,diameterV,1000); % create ellipse
stepLengths = sqrt(sum(diff(pathXY,[],1).^2,2)); % distance between the points
stepLengths = [0; stepLengths]; % add the starting point
cumulativeLen = cumsum(stepLengths); % cumulative sum
circumference = cumulativeLen(end);
finalStepLocs = linspace(0,1, nPoints+1)+offset; % equidistant distribution
finalStepLocs = finalStepLocs(1:end-1); % remove redundant point
finalStepLocs = mod(finalStepLocs,1)*circumference; % unwrap and scale to circumference
equidistantXY = interp1(cumulativeLen, pathXY, finalStepLocs);
 
 
function pathXY = samplesEllipse(diameterH,diameterV,nPoints)
% point of ellipse; points start on the right, counterclockwise 
% first and last points are the same
%
% Inputs:
%   diameterH  horizontal diameter
%   diameterV  vertical diameter
%   nPoints    number of points
 
p = linspace(0,2*pi,nPoints)';
pathXY = [cos(p)*diameterH/2 sin(p)*diameterV/2]; % create ellipse
 
 
function [xy] = rotateCordiantes(xy,anglee)
% [x1 y1; x2 y2; x3 y3; ...] coordinates to rotate
% anglee angle of rotation in [rad]
rotM = [cos(anglee) -sin(anglee); sin(anglee) cos(anglee)];
xy = (rotM*xy')';

Conditions d’utilisation

Moi, en tant que détenteur des droits d’auteur sur cette œuvre, je la publie sous la licence suivante :
Creative Commons CC-Zero Ce fichier est dans le domaine public selon les termes de la licence Creative Commons CC0 1.0 Universel.
La personne qui a associé une œuvre avec cet acte l’a placée dans le domaine public en renonçant mondialement à tous ses droits sur cette œuvre en vertu des lois relatives au droit d’auteur, ainsi qu’à tous les droits juridiques connexes et voisins qu’elle possédait sur l’œuvre, sans autre limite que celles imposées par la loi. Vous pouvez copier, modifier, distribuer et utiliser cette œuvre, y compris à des fins commerciales, sans qu’il soit nécessaire d’en demander la permission.

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Historique du fichier

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Date et heureVignetteDimensionsUtilisateurCommentaire
actuel29 avril 2023 à 15:20Vignette pour la version du 29 avril 2023 à 15:20700 × 700 (2,36 Mio)wikimediacommons>JahobrReverted to version as of 15:09, 17 November 2020 (UTC)

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