File:Gradient descent.svg
Size of this PNG preview of this SVG file: 512 × 549 pixels. Other resolutions: 224 × 240 pixels | 448 × 480 pixels | 716 × 768 pixels | 955 × 1,024 pixels | 1,910 × 2,048 pixels.
Original file (SVG file, nominally 512 × 549 pixels, file size: 56 KB)
File information
Structured data
Captions
Summary
editDescriptionGradient descent.svg | An illustration of the gradient descent method. I graphed this with Matlab |
Date | (UTC) |
Source |
This file was derived from: Gradient descent.png: |
Author |
|
This is a retouched picture, which means that it has been digitally altered from its original version. Modifications: Vector version. The original can be viewed here: Gradient descent.png: . Modifications made by Zerodamage.
|
Licensing
editI, the copyright holder of this work, hereby publish it under the following license:
Public domainPublic domainfalsefalse |
I, the copyright holder of this work, release this work into the public domain. This applies worldwide. In some countries this may not be legally possible; if so: I grant anyone the right to use this work for any purpose, without any conditions, unless such conditions are required by law. |
Source code
edit% Illustration of gradient descent
function main()
% the ploting window
figure(1);
clf; hold on;
set(gcf, 'color', 'white');
set(gcf, 'InvertHardCopy', 'off');
axis equal; axis off;
% the box
Lx1=-2; Lx2=2; Ly1=-2; Ly2=2;
% the function whose contours will be plotted
N=60; h=1/N;
XX=Lx1:h:Lx2;
YY=Ly1:h:Ly2;
[X, Y]=meshgrid(XX, YY);
f=inline('-((y+1).^4/25+(x-1).^4/10+x.^2+y.^2-1)');
Z=f(X, Y);
% the contours
h=0.3; l0=-1; l1=20;
l0=h*floor(l0/h);
l1=h*floor(l1/h);
v=[l0:1.5*h:0 0:h:l1 0.8 0.888];
[c,h] = contour(X, Y, Z, v, 'b');
% graphing settings
small=0.08;
small_rad = 0.01;
thickness=1; arrowsize=0.06; arrow_type=2;
fontsize=13;
red = [1, 0, 0];
white = 0.99*[1, 1, 1];
% initial guess for gradient descent
x=-0.6498; y=-1.0212;
% run several iterations of gradient descent
for i=0:4
H=text(x-1.5*small, y+small/2, sprintf('x_%d', i));
set(H, 'fontsize', fontsize, 'color', 0*[1 1 1]);
% the derivatives in x and in y, the step size
u=-2/5*(x-1)^3-2*x;
v=-4/25*(y+1)^3-2*y;
alpha=0.11;
if i< 4
plot([x, x+alpha*u], [y, y+alpha*v]);
arrow([x, y], [x, y]+alpha*[u, v], thickness, arrowsize, pi/8, ...
arrow_type, [1, 0, 0])
x=x+alpha*u; y=y+alpha*v;
end
end
% some dummy text, to expand the saving window a bit
text(-0.9721, -1.5101, '*', 'color', white);
text(1.5235, 1.1824, '*', 'color', white);
% save to eps
saveas(gcf, 'Gradient_descent.eps', 'psc2')
function arrow(start, stop, thickness, arrow_size, sharpness, arrow_type, color)
% Function arguments:
% start, stop: start and end coordinates of arrow, vectors of size 2
% thickness: thickness of arrow stick
% arrow_size: the size of the two sides of the angle in this picture ->
% sharpness: angle between the arrow stick and arrow side, in radians
% arrow_type: 1 for filled arrow, otherwise the arrow will be just two segments
% color: arrow color, a vector of length three with values in [0, 1]
% convert to complex numbers
i=sqrt(-1);
start=start(1)+i*start(2); stop=stop(1)+i*stop(2);
rotate_angle=exp(i*sharpness);
% points making up the arrow tip (besides the "stop" point)
point1 = stop - (arrow_size*rotate_angle)*(stop-start)/abs(stop-start);
point2 = stop - (arrow_size/rotate_angle)*(stop-start)/abs(stop-start);
if arrow_type==1 % filled arrow
% plot the stick, but not till the end, looks bad
t=0.5*arrow_size*cos(sharpness)/abs(stop-start); stop1=t*start+(1-t)*stop;
plot(real([start, stop1]), imag([start, stop1]), 'LineWidth', thickness, 'Color', color);
% fill the arrow
H=fill(real([stop, point1, point2]), imag([stop, point1, point2]), color);
set(H, 'EdgeColor', 'none')
else % two-segment arrow
plot(real([start, stop]), imag([start, stop]), 'LineWidth', thickness, 'Color', color);
plot(real([stop, point1]), imag([stop, point1]), 'LineWidth', thickness, 'Color', color);
plot(real([stop, point2]), imag([stop, point2]), 'LineWidth', thickness, 'Color', color);
end
function ball(x, y, r, color)
Theta=0:0.1:2*pi;
X=r*cos(Theta)+x;
Y=r*sin(Theta)+y;
H=fill(X, Y, color);
set(H, 'EdgeColor', 'none');
%plot2svg must be retrieved from http://www.zhinst.com/blogs/schwizer/
plot2svg;
Original upload log
editThis image is a derivative work of the following images:
- File:Gradient_descent.png licensed with PD-self
- 2007-06-23T03:33:09Z Oleg Alexandrov 482x529 (25564 Bytes) {{Information |Description=An illustration of the gradient descent method. I graphed this with Matlab |Source=Originally from [http://en.wikipedia.org en.wikipedia]; description page is/was [http://en.wikipedia.org/w/index.ph
Uploaded with derivativeFX
File history
Click on a date/time to view the file as it appeared at that time.
Date/Time | Thumbnail | Dimensions | User | Comment | |
---|---|---|---|---|---|
current | 19:04, 7 August 2012 | 512 × 549 (56 KB) | Zerodamage (talk | contribs) | == {{int:filedesc}} == {{Information |Description=An illustration of the gradient descent method. I graphed this with Matlab |Source={{Derived from|Gradient_descent.png|display=50}} |Date=2012-08-07 19:02 (UTC) |Author=*File:Gradient_descent.png:... |
You cannot overwrite this file.
File usage on Commons
The following page uses this file:
File usage on other wikis
The following other wikis use this file:
- Usage on ar.wikipedia.org
- Usage on ca.wikipedia.org
- Usage on cs.wikipedia.org
- Usage on de.wikiversity.org
- Usage on en.wikipedia.org
- Usage on en.wikiversity.org
- Usage on he.wikipedia.org
- Usage on it.wikipedia.org
- Usage on pt.wikipedia.org
- Usage on sr.wikipedia.org
- Usage on sv.wikipedia.org
- Usage on uk.wikipedia.org
- Usage on vi.wikipedia.org
- Usage on zh-yue.wikipedia.org
Metadata
This file contains additional information such as Exif metadata which may have been added by the digital camera, scanner, or software program used to create or digitize it. If the file has been modified from its original state, some details such as the timestamp may not fully reflect those of the original file. The timestamp is only as accurate as the clock in the camera, and it may be completely wrong.
Image title | Matlab Figure Converted by PLOT2SVG written by Juerg Schwizer |
---|