This question has been asked a million times, albeit in different forms. This is due to **floating point inaccuracy**. Also **here's another link** on floating point errors you may want to catch up on!

Try this to first see what's going on:

```
x <- seq(0, 20, 0.5)
sprintf("%.20f", x[30]) # convert value to string with 20 decimal places
# [1] "14.50000000000000000000"
x[30] == 14.5
# [1] TRUE
```

All is well so far. Now, try this:

```
x <- seq(0, 20, 0.05)
sprintf("%.20f", x[30]) # convert value to string with 20 decimal places
# [1] "1.45000000000000017764"
x[30] == 1.45
# [1] FALSE
```

You can see that the machine is able to *accurately* represent this number only up to certain digits. Here, up to 15 digits or so. So, by directly comparing the results, you get of course a FALSE. Instead what you could do is to use `all.equal`

which has a parameter for *tolerance* which equals `.Machine$double.eps ^ 0.5`

. On my machine this evaluates to `1.490116e-08`

. This means if the absolute difference between the numbers `x[30]`

and `1.45...`

is < this threshold, then `all.equal`

evaluates this to TRUE.

```
all.equal(x[30], 1.45)
[1] TRUE
```

Another way of doing this is to explicitly check with a specific threshold (as @eddi's answer shows it). Hope this helps.

`14.5`

not`1.45`

. I dint down-vote, but I think you should delete this question. – Arun May 1 '13 at 19:30floating point inaccuracy. Do this:`x <- seq(0, 20, 0.5); sprintf("%.20f", x[30])`

and now this:`x <- seq(0, 20, 0.05); sprintf("%.20f", x[30])`

. – Arun May 1 '13 at 19:34