# How change percision of float point in matlab treat 5.145556666 as 5.24

**updated I want treat float or double only with 2 digit in float section in matlab.as example

a=23.1234443434343434454545444;

I want if I use a it is equal

a=23.12;

any idea in matlab?

I want funcion like round(1.95583, 2);//return 1.95 (php function ) in matlab

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is it a matter of screen printing or you want it at the operation level? moreover sum, multiplication and subtraction are fine, what about division, you want it to be truncated too? –  Acorbe Nov 6 '12 at 14:19
Take a look on fixed-point toolbox. –  Danil Asotsky Nov 6 '12 at 14:33

If you want to just keep N digits, another formulation is:

>> d = 10^(-2)
>> round(pi/d)*d
ans =
3.1400

### Edit:

As per Rody's comment, round might not truncate properly, so use:

>> a = 3.146
>> fix(a/d)*d
ans =
3.1400
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+1, however, there's a subtle difference: casting to int drops all digits after the 2nd one indiscriminately, whereas round might also change the 2nd digit in case the 3rd digit is 5 or larger. –  Rody Oldenhuis Nov 6 '12 at 14:43
Whoops, daily vote limit reached...well, first thing tomorrow then :p –  Rody Oldenhuis Nov 6 '12 at 14:44
@Rody: You're right, but your edit does not work as intended. I think it can be fixed by also using fix (see edit)? –  sigma Nov 6 '12 at 14:50

If you want to display values with only 2 digits, you can do

>> format bank
>> pi
ans =
3.14
>> rand(4)
ans =
0.81    0.63    0.96    0.96
0.91    0.10    0.96    0.49
0.13    0.28    0.16    0.80
0.91    0.55    0.97    0.14

This does NOT mean calculations will be carried out with less precision.

If the latter is really what you want (why?!), you could use constructions like

ppi = single(pi)

for reduced precision, or

f = @(x) double(uint64(x*100))/100;

for guaranteed 2-digit precision. In the last case, you have to pass all values through the function f prior to using them:

>> ppi = f(pi)
ans =
3.140000000000000
>> f(rand(4))
ans =
0.280000000000000   0.690000000000000   0.440000000000000   0.190000000000000
0.050000000000000   0.320000000000000   0.380000000000000   0.490000000000000
0.100000000000000   0.950000000000000   0.770000000000000   0.450000000000000
0.820000000000000   0.030000000000000   0.800000000000000   0.650000000000000

If you're looking for a more elegant solution for this last case, use the fixed-point toolbox, as Danil suggested.

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Neat solution (+1). I've always used fix in the past (as per the answer of @sigma (also +1)). To answer the "why?!" part of your question, perhaps the OP is simulating systems that are subject to Quantization –  Colin T Bowers Nov 6 '12 at 23:30