Instead of iterating over all 2^p combinations, one way you could generate such binary matrices is by performing repeated row- and column-wise operations based on the given constraints you have. As an example, I'll post some code that will generate a matrix based on the three constraints you have listed above:

- A minimum number of zeroes per column
- A minimum sum for each row
- A minimum sequential length of ones per column

## Initializations:

First start by initializing a few parameters:

```
nRows = 10; % Row size of matrix
nColumns = 10; % Column size of matrix
minZeroes = 5; % Constraint 1 (for columns)
minRowSum = 5; % Constraint 2 (for rows)
minLengthOnes = 3; % Constraint 3 (for columns)
```

## Helper functions:

Next, create a couple of functions for generating column vectors that match constraints 1 and 3 from above:

```
function vector = make_column
vector = [false(minZeroes,1); true(nRows-minZeroes,1)]; % Create vector
[vector,maxLength] = randomize_column(vector); % Randomize order
while maxLength < minLengthOnes, % Loop while constraint 3 is not met
[vector,maxLength] = randomize_column(vector); % Randomize order
end
end
function [vector,maxLength] = randomize_column(vector)
vector = vector(randperm(nRows)); % Randomize order
edges = diff([false; vector; false]); % Find rising and falling edges
maxLength = max(find(edges == -1)-find(edges == 1)); % Find longest
% sequence of ones
end
```

The function **make_column** will first create a logical column vector with the minimum number of 0 elements and the remaining elements set to 1 (using the functions TRUE and FALSE). This vector will undergo random reordering of its elements until it contains a sequence of ones greater than or equal to the desired minimum length of ones. This is done using the **randomize_column** function. The vector is randomly reordered using the RANDPERM function to generate a random index order. The edges where the sequence switches between 0 and 1 are detected using the DIFF function. The indices of the edges are then used to find the length of the longest sequence of ones (using FIND and MAX).

## Generate matrix columns:

With the above two functions we can now generate an initial binary matrix that will at least satisfy constraints 1 and 3:

```
binMat = false(nRows,nColumns); % Initialize matrix
for iColumn = 1:nColumns,
binMat(:,iColumn) = make_column; % Create each column
end
```

## Satisfy the row sum constraint:

Of course, now we have to ensure that constraint 2 is satisfied. We can sum across each row using the SUM function:

```
rowSum = sum(binMat,2);
```

If any elements of **rowSum** are less than the minimum row sum we want, we will have to adjust some column values to compensate. There are a number of different ways you could go about modifying column values. I'll give one example here:

```
while any(rowSum < minRowSum), % Loop while constraint 2 is not met
[minValue,rowIndex] = min(rowSum); % Find row with lowest sum
zeroIndex = find(~binMat(rowIndex,:)); % Find zeroes in that row
randIndex = round(1+rand.*(numel(zeroIndex)-1));
columnIndex = zeroIndex(randIndex); % Choose a zero at random
column = binMat(:,columnIndex);
while ~column(rowIndex), % Loop until zero changes to one
column = make_column; % Make new column vector
end
binMat(:,columnIndex) = column; % Update binary matrix
rowSum = sum(binMat,2); % Update row sum vector
end
```

This code will loop until all the row sums are greater than or equal to the minimum sum we want. First, the index of the row with the smallest sum (**rowIndex**) is found using MIN. Next, the indices of the zeroes in that row are found and one of them is randomly chosen as the index of a column to modify (**columnIndex**). Using **make_column**, a new column vector is continuously generated until the 0 in the given row becomes a 1. That column in the binary matrix is then updated and the new row sum is computed.

## Summary:

For a relatively small 10-by-10 binary matrix, and the given constraints, the above code usually completes in no more than a few seconds. With more constraints, things will of course get more complicated. Depending on how you choose your constraints, there may be no possible solution (for example, setting **minRowSum** to 6 will cause the above code to *never* converge to a solution).

Hopefully this will give you a starting point to begin generating the sorts of matrices you want using vectorized operations.