4 views (last 30 days)

I struggle with this generally and have come up against a barrier again.

I'm trying to create vibrational mode functions for a rectangular membrane. The equation is simple enough: -

W_n = sin(x*pi*i/L_x)*sin(y*pi*i/L_y)

Here's where I'm up to: -

L_x = 27.4e-3; %membrane width (m)

L_y = 27.4e-3; %membrane height (m)

N_x = 10; %no. of eigenfreqs considered in x dimension

N_y = 10; %no. of eigenfreqs considered in y dimension

N = N_x*N_y; %total no. of eigenfreqs considered

x = (linspace(0.5*L_x/N_x,L_x - 0.5*L_x/N_x,N_x))';

%membrane x-dimension mapping points

%each at the centre of an element

y = (linspace(0.5*L_y/N_y,L_y - 0.5*L_y/N_y,N_y));

%membrane y-dimension mapping points

%each at the centre of an element

x_ref = 1:length(x);

y_ref = 1:length(y);

W_n = zeros(N_x,N_y,N);

W_n(:,:,01) = (sin(x(x_ref,:,:)*1*pi/L_x)...

*sin(y(:,y_ref,:)*1*pi/L_y));

W_n(:,:,02) = (sin(x(x_ref,:,:)*1*pi/L_x)...

*sin(y(:,y_ref,:)*2*pi/L_y));

W_n(:,:,18) = (sin(x(x_ref,:,:)*2*pi/L_x)...

*sin(y(:,y_ref,:)*8*pi/L_y));

W_n(:,:,46) = (sin(x(x_ref,:,:)*5*pi/L_x)...

*sin(y(:,y_ref,:)*6*pi/L_y));

W_n(:,:,89) = (sin(x(x_ref,:,:)*9*pi/L_x)...

*sin(y(:,y_ref,:)*9*pi/L_y));

W_n(:,:,100) = (sin(x(x_ref,:,:)*10*pi/L_x)...

*sin(y(:,y_ref,:)*10*pi/L_y));

The numbers on the left hand side - 01, 02, 18, 46, 89, 100 - actually need to be 1,2,3,...,100, i.e.

n = 1:100; %mode number counting from 1 to 100

These refer to the mode numbers - although this is a bit odd - but still not too complicated. Basically if n = 01, then the mode is (1,1). If n = 59 the mode is (6,9), i.e. i = 6 & j = 9. I have solved this using the following: -

i = floor((n/10 - n/1000)) + 1;

%mode number from 1 to 10 in x dimension

j = n - 10*(floor((n/10 - n/1000)));

%mode number from 1 to 10 in y dimension

Now I just need to put n, i and j into my W_n equation, but I can't figure out how!

Any help would be greatly appreciated :)

Simon
on 19 Sep 2013

Hi!

I don't understand why the x and y spacing depends on the number of modes/frequencies.

Take a look at the following code:

L_x = 27.4e-3; %membrane width (m)

L_y = 27.4e-3; %membrane height (m)

N_x = 5; %no. of eigenfreqs considered in x dimension

N_y = 10; %no. of eigenfreqs considered in y dimension

N = N_x*N_y; %total no. of eigenfreqs considered

NumX = 50; % number of mapping points in x-direction

NumY = 50; % number of mapping points in y-direction

% create X and Y array in 2d

[X,Y] = meshgrid(...

(linspace(0.5*L_y/NumY, L_y - 0.5*L_y/NumY, NumY)), ...

(linspace(0.5*L_x/NumX, L_x - 0.5*L_x/NumX, NumX)));

% modify X and Y array for 3d

XFull = repmat(X, [1 1 N]);

YFull = repmat(Y, [1 1 N]);

% create mode array for X

Mx = ones(NumX, NumY, N_y);

MxFull = [];

for n = 1:N_x

MxFull = cat(3, MxFull, n*Mx);

end

% create mode array for Y

My = ones(NumX, NumY);

MyFull = [];

for n = 1:N_y

MyFull = cat(3, MyFull, n*My);

end

MyFull = repmat(MyFull, [1 1 N_x]);

% modes for each direction

Wx_n = arrayfun(@(x,mx) sin(x .* (mx *pi/L_x)), XFull, MxFull);

Wy_n = arrayfun(@(y,my) sin(y .* (my *pi/L_x)), YFull, MyFull);

% superposition of modes

W_n = Wx_n .* Wy_n;

% plot

figure(1); cla

surface(W_n(:,:,23));

Sign in to answer this question.

Opportunities for recent engineering grads.

Apply Today
## 0 Comments

Sign in to comment.