may be

```
(*data*)
nRow = 5; nCol = 5;
With[{$nRow = nRow, $nCol = nCol},
xnow = Table[RandomReal[{1, 3}], {$nRow}, {$nCol}];
cellactvA = cellactvB = cellactvC = Table[Random[], {$nRow}, {$nCol}]
];
limit = 2.0;
```

now do the replacement

```
pos = Position[xnow, x_ /; x > limit];
{cellactvA, cellactvB, cellactvC} =
Map[ReplacePart[#, pos -> 0.] &, {cellactvA, cellactvB, cellactvC}];
```

**edit(1)**

Here is a quick speed comparing the 4 methods above, the LOOP, and then Brett, me, and Verbeia. May be someone can double check them. I used the same data for all. created random data once, then used it for each test. Same limit (called L) I used matrix size of 2,000 by 2,000.

So speed Timing numbers below does not include data allocation.

I run the tests once.

This is what I see:

## For 2,000 by 2,000 matrices:

- Bill (loop): 16 seconds
- me (
`ReplacPart`

): 21 seconds
- Brett (
`SparseArray`

): 7.27 seconds
- Verbeia (
`MapThread`

): 32 seconds

## For 3,000 by 3,000 matrices:

- Bill (loop): 37 seconds
- me (
`ReplacPart`

): 48 seconds
- Brett (
`SparseArray`

): 16 seconds
- Verbeia (
`MapThread`

): 79 seconds

So, it seems to be that `SparseArray`

is the fastest. (but please check to make sure I did not break something)

code below:

**data generation**

```
(*data*)
nRow = 2000;
nCol = 2000;
With[{$nRow = nRow, $nCol = nCol},
$xnow = Table[RandomReal[{1, 3}], {$nRow}, {$nCol}];
$a = $b = $c = Table[Random[], {$nRow}, {$nCol}]
];
limit = 2.0;
```

**ReplacePart test**

```
xnow = $xnow;
a = $a;
b = $b;
c = $c;
Timing[
pos = Position[xnow, x_ /; x > limit];
{xnow, a, b, c} = Map[ReplacePart[#, pos -> 0.] &, {xnow, a, b, c}]][[1]]
```

**SparseArray test**

```
xnow = $xnow;
a = $a;
b = $b;
c = $c;
Timing[
matrixMask =
SparseArray[Thread[Position[xnow, _?(# > limit &)] -> 0.],
Dimensions[xnow], 1.]; xnow = xnow*matrixMask;
a = a*matrixMask;
b = b*matrixMask;
c = c*matrixMask
][[1]]
```

**MapThread test**

```
xnow = $xnow;
a = $a;
b = $b;
c = $c;
Timing[
{xnow, a, b, c} =
MapThread[Function[{x, y}, If[x > limit, 0, y]], {xnow, #},
2] & /@ {xnow, a, b, c}
][[1]]
```

**loop test**

```
xnow = $xnow;
a = $a;
b = $b;
c = $c;
Timing[
Do[If[xnow[[i, j]] > limit,
xnow[[i, j]] = 0.;
a[[i, j]] = 0.;
b[[i, j]] = 0.;
c[[i, j]] = 0.
],
{i, 1, nRow}, {j, 1, nCol}
]
][[1]]
```

**edit(2)**

There is something really bothering me with all of this. I do not understand how a loop can be faster that the specialized commands for this purpose?

I wrote a simple loop test in Matlab, like Bill had using R, and I getting much lower timings there also. I hope an expert can come up with a much faster method, because now I am not too happy with this.

For 3,000 by 3,000 matrix, I am getting

```
Elapsed time is 0.607026 seconds.
```

This is more than 20 times faster than the SparseArray method, and it is just a loop!

```
%test, on same machine, 4GB ram, timing uses cpu timing using tic/toc
%allocate data
nRow = 3000;
nCol = 3000;
%generate a random matrix of real values
%between 1 and 3
xnow = 1 + (3-1).*rand(nRow,nRow);
%allocate the other 3 matrices
a=zeros(nRow,nCol);
b=a;
c=b;
%set limit
limit=2;
%engine
tstart=tic;
for i=1:nRow
for j=1:nCol
if xnow(i,j) > limit
xnow(i,j) = 0;
a(i,j) = 0;
b(i,j) = 0;
c(i,j) = 0;
end
end
end
toc(tstart)
```

fyi: using cputime() gives similar values.as tic/toc.