# How are the TI operating systems coded not to have floating point error?

I ran a test on my graphing calculator to check for floating point error, and after forty eight hours of complete and utter randomness, the calculator had not lost a single digit of precision.

How does TI pull this off?

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Can you give an example of "complete and utter randomness"? What are you comparing against? – Oliver Charlesworth Feb 29 '12 at 0:50
It's not a literal statement. Sorry if everything on here is meant to be taken exactly literally; I didn't intend to impair the point of the question with a little bit of silliness, nor did it. – Emrakul Feb 29 '12 at 1:00
I'm asking for an example of what you were trying; at the moment your question has zero information content. How can we possibly answer without knowing the context? – Oliver Charlesworth Feb 29 '12 at 1:03
I quote: "I ran a test on my graphing calculator to check for floating point error, and after forty-eight hours..." Isn't that enough? That tells you that: 1) I ran a test for floating point error. 2) It lasted for 48 hours. Now, let's look at the question: "How are the TI operating systems coded not to have floating point error?" Isn't it answerable now? – Emrakul Feb 29 '12 at 1:09
No, because you haven't told us anything about that test, i.e. what operations it consisted of, nor how you were verifying the results. – Oliver Charlesworth Feb 29 '12 at 1:10

For example, if you enter the expression `1/3*3-1` on a TI-89 in "approx" mode, you get the answer `⁻1.ᴇ⁻14` instead of the `0` you get in exact mode. Internally, the calculation is done as follows:
• `1/3` gives `0.33333333333333`, rounded to 14 significant digits.
• Multiplying by 3 gives `0.99999999999999`. Because of rounding, this displays as `1.`
• Subtracting 1 gives `-0.00000000000001`, or -1e-14.