Slika:Partial transmittance.gif
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Partial_transmittance.gif (367 × 161 točk, velikost datoteke: 67 KB, MIME-vrsta: image/gif, ponavljajoče, 53 sličic, 4,2 s)
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Povzetek
| Opis |
Русский: Показано классическое отражение/прохождение солитона гауссового импульса от/в более плотную среду. В реальности же, свет отражается не от поверхности, а от всех частиц тела (см. ru:КЭД). English: Illustration of partial reflection of a wave. A gaussian wave on a one-dimensional string strikes a boundary with transmission coefficient of 0.5. Half the wave is transmitted and half is reflected.
Français : Illustration de la réflection partielle d'une onde. Une onde gaussienne se déplaçant sur un ressort unidimensionnel est réfléchie/transmise au niveau d'une interface avec un coefficient de transmission de 0.5.
Español: Ilustración de una reflexión parcial de una onda. Una onda gaussiana sobre una cuerda de una dimensión choca contra un limite con un coeficiente de transmisión de 0.5. La mitad de la onda es transmitida y la otra mitad es reflejada. |
| Datum | |
| Vir | self-made with MATLAB, source code below |
| Avtor | Oleg Alexandrov |
Licenca
|
Jaz, imetnik avtorskih pravic na tem delu, izročam to delo v javno domeno. To velja po vsem svetu. V nekaterih državah to pravno morda ni mogoče. Če je tako, Vsakomur dajem (v okviru zakonskih omejitev) brezpogojno pravico, da gradivo uporablja v kateri koli namen. |
MATLAB source code
% Partial transmittance and reflectance of a wave
% Code is messed up, don't have time to clean it now
function main()
% KSmrq's colors
red = [0.867 0.06 0.14];
blue = [0, 129, 205]/256;
green = [0, 200, 70]/256;
yellow = [254, 194, 0]/256;
white = 0.99*[1, 1, 1];
black = [0, 0, 0];
% length of the string and the grid
L = 5;
N = 151;
X=linspace(0, L, N);
h = X(2)-X(1); % space grid size
c = 0.01; % speed of the wave
tau = 0.25*h/c; % time grid size
% form a medium with a discontinuous wave speed
C = 0*X+c;
D=L/2;
c_right = 0.5*c; % speed to the right of the disc
for i=1:N
if X(i) > D
C(i) = c_right;
end
end
% Now C = c for x < D, and C=c_right for x > D
K = 5; % steepness of the bump
S = 0; % shift the wave
f=inline('exp(-K*(x-S).^2)', 'x', 'S', 'K'); % a gaussian as an initial wave
df=inline('-2*K*(x-S).*exp(-K*(x-S).^2)', 'x', 'S', 'K'); % derivative of f
% wave at time 0 and tau
U0 = 0*f(X, S, K);
U1 = U0 - 2*tau*c*df(X, S, K);
U = 0*U0; % current U
% plot between Start and End
Start=130; End=500;
% hack to capture the first period of the wave
min_k = 2*N; k_old = min_k; turn_on = 0;
frame_no = 0;
for j=1:End
% fixed end points
U(1)=0; U(N)=0;
% finite difference discretization in time
for i=2:(N-1)
U(i) = (C(i)*tau/h)^2*(U1(i+1)-2*U1(i)+U1(i-1)) + 2*U1(i) - U0(i);
end
% update info, for the next iteration
U0 = U1; U1 = U;
spacing=7;
% plot the wave
if rem(j, spacing) == 1 & j > Start
figure(1); clf; hold on;
axis equal; axis off;
lw = 3; % linewidth
% size of the window
ys = 1.2;
low = -0.5*ys;
high = ys;
plot([D, D], [low, high], 'color', black, 'linewidth', 0.7*lw)
% fill([X(1), D, D, X(1)], [low, low, high, high], [0.9, 1, 1], 'edgealpha', 0);
% fill([D X(N), X(N), D], [low, low, high, high], [1, 1, 1], 'edgealpha', 0);
plot(X, U, 'color', red, 'linewidth', lw);
% plot the ends of the string
small_rad = 0.06;
axis([-small_rad, 0.82*L, -ys, ys]);
% small markers to keep the bounding box fixed when saving to eps
plot(-small_rad, ys, '*', 'color', white);
plot(L+small_rad, -ys, '*', 'color', white);
pause(0.1)
frame_no = frame_no + 1;
%frame=sprintf('Frame%d.eps', 1000+frame_no); saveas(gcf, frame, 'psc2');
frame=sprintf('Frame%d.png', 1000+frame_no);% saveas(gcf, frame);
disp(frame)
print (frame, '-dpng', '-r300');
end
end
% The gif image was creating with the command
% convert -antialias -loop 10000 -delay 8 -compress LZW -scale 20% Frame10*png Partial_transmittance.gif
% and was later cropped in Gimp
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| Datum in čas | Sličica | Velikost | Uporabnik | Komentar | |
|---|---|---|---|---|---|
| trenutno | 18:36, 9. april 2010 | | 367 × 161 (67 KB) | Aiyizo | optimized animation |
| 07:56, 26. november 2007 |  | 367 × 161 (86 KB) | Oleg Alexandrov | {{Information |Description=Illustration of en:Transmission coefficient (optics) |Source=self-made with MATLAB, source code below |Date=~~~~~ |Author= Oleg Alexandrov |Permission=PD-self, see below |other_versions= }} {{PD-se |
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