Adding uneven matrices

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B T
B T el 6 de Mzo. de 2012
Comentada: Walter Roberson el 14 de Feb. de 2018
Hey guys,
is there a method(aka function) by which I can add two matrices that aren't the same size and make it so that the matrices become of equivalent size by being filled with zeros in the remaining space?
Thanks
[Merged information from Answer]
It would be like ..
a=ones(150,91)*2
b=ones(141,100)*3
a+b
So, is there a way to make the matrices even but filling them with zeros? (adding 0 more rows to b, and 9 more columns to a of value=0) ...
Thanks!
  2 comentarios
Andrei Bobrov
Andrei Bobrov el 6 de Mzo. de 2012
please get the your example
Walter Roberson
Walter Roberson el 6 de Mzo. de 2012
There are over 100,000 different possible results for that calculation. You need to be very specific about which elements are to be added to which elements.

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Respuestas (2)

Jan
Jan el 6 de Mzo. de 2012
a = ones(150,91)*2
b = ones(141,100)*3
c = AddFill(a, b);
function c = AddFill(a, b);
sa = size(a);
sb = size(b);
c = zeros(max(sa, sb)); % Pre-allocate
c(1:sa(1), 1:sa(2)) = a; % Assign a
c(1:sb(1), 1:sb(2)) = c(1:sb(1), 1:sb(2)) + b; % Add b
  2 comentarios
Ismail Qeshta
Ismail Qeshta el 14 de Feb. de 2018
Hi Jan. Can you please let me know how to modify your code for three unequal matrices instead of two? Thank you.
Walter Roberson
Walter Roberson el 14 de Feb. de 2018
function d = AddFill(a, b, c);
sa = size(a);
sb = size(b);
sc = size(c);
d = zeros(max([sa; sb; sc])); % Pre-allocate
d(1:sa(1), 1:sa(2)) = a; % Assign a
d(1:sb(1), 1:sb(2)) = d(1:sb(1), 1:sb(2)) + b; % Add b
d(1:sc(1), 1:sc(2)) = d(1:sc(1), 1:sc(2)) + c; % Add c

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Andrei Bobrov
Andrei Bobrov el 6 de Mzo. de 2012
variant (one of 100000) :)
function out = addiffmatrix(varargin)
n = cellfun('ndims',varargin);
N = max(n);
sz = cell2mat(cellfun(@(x)[size(x) ones(1,N - numel(size(x)))],varargin(:),'un',0));
mm = arrayfun(@(i1)1:i1,sz,'un',0);
m1 = zeros(max(sz));
out = m1;
M = m1;
for j1 = 1:numel(varargin)
M(mm{j1,:}) = varargin{j1};
out = out + M;
M = m1;
end
using
a = ones(3,4)
b = 2*ones(5,3)
out = addiffmatrix(a,b)
out =
3 3 3 1
3 3 3 1
3 3 3 1
2 2 2 0
2 2 2 0
ADD
variant with "general point"
function out = addiffmatrix(cp,varargin)
% cp - coordinates of the general point in every matrix
% varargin - matrices
n = cellfun('ndims',varargin);
N = max(n);
sz = cell2mat(cellfun(@(x)[size(x) ones(1,N - numel(size(x)))],...
varargin(:),'un',0));
C = max(cp);
ij1 = bsxfun(@minus,C,cp);
mm = arrayfun(@(i1,j1)(1:i1)+j1,sz,ij1,'un',0);
out = zeros(C+max(sz-cp));
for j1 = 1:numel(varargin)
out(mm{j1,:}) = out(mm{j1,:}) + varargin{j1};
end
using
>> a
a =
1 1 1 1
1 1 1 1
>> b
b =
1.5 1.5 1.5
1.5 1.5 1.5
1.5 1.5 1.5
>> c
c =
2 2
2 2
2 2
2 2
2 2
>> cp
cp =
1 1
1 3
5 2
>> out = addiffmatrix(cp,a,b,c)
out =
0 2 2 0 0 0
0 2 2 0 0 0
0 2 2 0 0 0
0 2 2 0 0 0
1.5 3.5 4.5 1 1 1
1.5 1.5 2.5 1 1 1
1.5 1.5 1.5 0 0 0
>>

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