If the `nan`

density is high enough, then a double loop will be the fastest method. This is because the search of a row can be discarded as soon as the first `nan`

is found. For example, consider the following speed test:

```
%# Preallocate some parameters
T = 5000; %# Number of rows
N = 500; %# Number of columns
X = randi(5, T, N); %# Sample data matrix
M = 100; %# Number of simulation iterations
X(X == 1) = nan; %# Randomly set some elements of X to nan
%# Your first method
tic
for m = 1:M
Soln1 = find(~isnan(sum(X, 2)));
end
toc
%# Your second method
tic
for m = 1:M
Soln2 = find(all(~isnan(X), 2));
end
toc
%# A double loop
tic
for m = 1:M
Soln3 = ones(T, 1);
for t = 1:T
for n = 1:N
if isnan(X(t, n))
Soln3(t) = 0;
break
end
end
end
Soln3 = find(Soln3);
end
toc
```

The results are:

```
Elapsed time is 0.164880 seconds.
Elapsed time is 0.218950 seconds.
Elapsed time is 0.068168 seconds. %# The double loop method
```

Of course, the `nan`

density is so high in this simulation that none of the rows are `nan`

free. But you never said anything about the `nan`

density of your matrix, so I figured I'd post this answer for general consumption and contemplation :-)