# Why is 24.0000 not equal to 24.0000 in MATLAB?

I am writing a program where I need to delete duplicate points stored in a matrix. The problem is that when it comes to check whether those points are in the matrix, MATLAB can't recognize them in the matrix although they exist.

In the following code, `intersections` function gets the intersection points:

``````[points(:,1), points(:,2)] = intersections(...
obj.modifiedVGVertices(1,:), obj.modifiedVGVertices(2,:), ...
[vertex1(1) vertex2(1)], [vertex1(2) vertex2(2)]);
``````

The result:

``````>> points
points =
12.0000   15.0000
33.0000   24.0000
33.0000   24.0000

>> vertex1
vertex1 =
12
15

>> vertex2
vertex2 =
33
24
``````

Two points (`vertex1` and `vertex2`) should be eliminated from the result. It should be done by the below commands:

``````points = points((points(:,1) ~= vertex1(1)) | (points(:,2) ~= vertex1(2)), :);
points = points((points(:,1) ~= vertex2(1)) | (points(:,2) ~= vertex2(2)), :);
``````

After doing that, we have this unexpected outcome:

``````>> points
points =
33.0000   24.0000
``````

The outcome should be an empty matrix. As you can see, the first (or second?) pair of `[33.0000 24.0000]` has been eliminated, but not the second one.

Then I checked these two expressions:

``````>> points(1) ~= vertex2(1)
ans =
0
>> points(2) ~= vertex2(2)
ans =
1   % <-- It means 24.0000 is not equal to 24.0000?
``````

What is the problem?

More surprisingly, I made a new script that has only these commands:

``````points = [12.0000   15.0000
33.0000   24.0000
33.0000   24.0000];

vertex1 = [12 ;  15];
vertex2 = [33 ;  24];

points = points((points(:,1) ~= vertex1(1)) | (points(:,2) ~= vertex1(2)), :);
points = points((points(:,1) ~= vertex2(1)) | (points(:,2) ~= vertex2(2)), :);
``````

The result as expected:

``````>> points
points =
Empty matrix: 0-by-2
``````
• This has also been addressed here
– ChrisF
Mar 26, 2009 at 16:28
• @Kamran: Sorry I didn't point out the perils of floating point comparison when you asked about comparing values in your other question. It didn't immediately occur to me you might run into that problem. Mar 26, 2009 at 16:43
• As a side note, compare `1.2 - 0.2 - 1 == 0` and `1.2 - 1 - 0.2 == 0`. Surprising, isn't it? When you're dealing with floating-point numbers, the order of operations matters. Oct 12, 2014 at 12:51
• @Tick Tock: As the author of the question, I could not even understand the title you chose for my question. Also it did not reflect the fact that MATLAB does not show the entire floating point part of the number when you print out the variable. Aug 18, 2016 at 22:34
• Possible duplicate of Best Practice for Float Comparison in Matlab May 4, 2017 at 15:20

The problem you're having relates to how floating-point numbers are represented on a computer. A more detailed discussion of floating-point representations appears towards the end of my answer (The "Floating-point representation" section). The TL;DR version: because computers have finite amounts of memory, numbers can only be represented with finite precision. Thus, the accuracy of floating-point numbers is limited to a certain number of decimal places (about 16 significant digits for double-precision values, the default used in MATLAB).

## Actual vs. displayed precision

Now to address the specific example in the question... while `24.0000` and `24.0000` are displayed in the same manner, it turns out that they actually differ by very small decimal amounts in this case. You don't see it because MATLAB only displays 4 significant digits by default, keeping the overall display neat and tidy. If you want to see the full precision, you should either issue the `format long` command or view a hexadecimal representation of the number:

``````>> pi
ans =
3.1416
>> format long
>> pi
ans =
3.141592653589793
>> num2hex(pi)
ans =
400921fb54442d18
``````

## Initialized values vs. computed values

Since there are only a finite number of values that can be represented for a floating-point number, it's possible for a computation to result in a value that falls between two of these representations. In such a case, the result has to be rounded off to one of them. This introduces a small machine-precision error. This also means that initializing a value directly or by some computation can give slightly different results. For example, the value `0.1` doesn't have an exact floating-point representation (i.e. it gets slightly rounded off), and so you end up with counter-intuitive results like this due to the way round-off errors accumulate:

``````>> a=sum([0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1]);  % Sum 10 0.1s
>> b=1;                                               % Initialize to 1
>> a == b
ans =
logical
0                % They are unequal!
>> num2hex(a)       % Let's check their hex representation to confirm
ans =
3fefffffffffffff
>> num2hex(b)
ans =
3ff0000000000000
``````

## How to correctly handle floating-point comparisons

Since floating-point values can differ by very small amounts, any comparisons should be done by checking that the values are within some range (i.e. tolerance) of one another, as opposed to exactly equal to each other. For example:

``````a = 24;
b = 24.000001;
tolerance = 0.001;
if abs(a-b) < tolerance, disp('Equal!'); end
``````

will display "Equal!".

You could then change your code to something like:

``````points = points((abs(points(:,1)-vertex1(1)) > tolerance) | ...
(abs(points(:,2)-vertex1(2)) > tolerance),:)
``````

# Floating-point representation

A good overview of floating-point numbers (and specifically the IEEE 754 standard for floating-point arithmetic) is What Every Computer Scientist Should Know About Floating-Point Arithmetic by David Goldberg.

A binary floating-point number is actually represented by three integers: a sign bit `s`, a significand (or coefficient/fraction) `b`, and an exponent `e`. For double-precision floating-point format, each number is represented by 64 bits laid out in memory as follows:

The real value can then be found with the following formula:

This format allows for number representations in the range 10^-308 to 10^308. For MATLAB you can get these limits from `realmin` and `realmax`:

``````>> realmin
ans =
2.225073858507201e-308
>> realmax
ans =
1.797693134862316e+308
``````

Since there are a finite number of bits used to represent a floating-point number, there are only so many finite numbers that can be represented within the above given range. Computations will often result in a value that doesn't exactly match one of these finite representations, so the values must be rounded off. These machine-precision errors make themselves evident in different ways, as discussed in the above examples.

In order to better understand these round-off errors it's useful to look at the relative floating-point accuracy provided by the function `eps`, which quantifies the distance from a given number to the next largest floating-point representation:

``````>> eps(1)
ans =
2.220446049250313e-16
>> eps(1000)
ans =
1.136868377216160e-13
``````

Notice that the precision is relative to the size of a given number being represented; larger numbers will have larger distances between floating-point representations, and will thus have fewer digits of precision following the decimal point. This can be an important consideration with some calculations. Consider the following example:

``````>> format long              % Display full precision
>> x = rand(1, 10);         % Get 10 random values between 0 and 1
>> a = mean(x)              % Take the mean
a =
0.587307428244141
>> b = mean(x+10000)-10000  % Take the mean at a different scale, then shift back
b =
0.587307428244458
``````

Note that when we shift the values of `x` from the range `[0 1]` to the range `[10000 10001]`, compute a mean, then subtract the mean offset for comparison, we get a value that differs for the last 3 significant digits. This illustrates how an offset or scaling of data can change the accuracy of calculations performed on it, which is something that has to be accounted for with certain problems.

• why can't I see that small decimal amount? Mar 26, 2009 at 16:18
• you can see it if you view the variable in the matrix view. Right click on variable -> "View selection" or something? I don't have MATLAB here, so I can't check. Mar 26, 2009 at 16:20
• You can also see small differences by typing "format long" at the command prompt. Mar 26, 2009 at 16:23
• you are right: format long points = 12.000000000000000 15.000000000000000 33.000000000000000 23.999999999999996 33.000000000000000 24.000000000000000 Mar 26, 2009 at 20:02
• "format hex" can sometimes help even more than format long here. Oct 5, 2009 at 15:25

Type

``````format long g
``````

This command will show the FULL value of the number. It's likely to be something like 24.00000021321 != 24.00000123124.

Try writing

0.1 + 0.1 + 0.1 == 0.3.

Warning: You might be surprised about the result!

• I tried it and it returns 0. But I don't see what it has to do, with the problem above. Can you pls explain it to me?
– Max
Sep 16, 2015 at 8:46
• This is because 0.1 comes with some floating point error, and when you add three such terms together, the errors do not necessarily add up to 0. The same issue is causing (floating) 24 to not be exactly equal to (another floating) 24. Mar 4, 2016 at 11:14

Maybe the two numbers are really 24.0 and 24.000000001 but you're not seeing all the decimal places.

Check out the Matlab EPS function.

Matlab uses floating point math up to 16 digits of precision (only 5 are displayed).