i had a problem where i was trying to reconstruct the the formula used in an existing system, a fairly simple formula of one input and one output:

```
y = f(x)
```

After a lot of puzzling, we managed to figure out the formula that fit our observed data points:

And as you can see our theoretical model fit observed data very well:

Except when we plot residual errors (i.e. `y = f(x) - actualY`

), we see some lines appear in the residuals:

It was obvious that these lines were the result of applying some intermediate rounding in our formula, but it was not obvious *where*. Eventually it was realized that the **original** system (the one we're trying to reverse engineer) is storing values in an intermediate ** Decimal** data type:

- with
**8-bit precision**of the fraction - using the
**0.5 round-up**rounding model:

We could *simulate* this 8-bit precision in the fraction by:

```
multiply by 128 (i.e. 2^8)
apply the round
divide by 128 (i.e. 2^8)
```

Changing our equation above into:

This reduces the residual errors *significantly*:

Now, all of that above has no relevance to my question except:

- To show that simulating the numerical representation in the computer can help the model
- To get people's attention with pretty pictures and colors
- Silence critics who would refuse to contribute until i explain
*why*i'm asking my question

Now i want to simulate ** Single Precision** floating point numbers, inside a programming language (and Excel) which use

**floating point numbers. i want to do this because**

`Double Precision`

*i*it is what's needed.

**think**In the above example i **thought** the original system was using a * Decimal data type with fixed 8-bit fractional precision using 0.5 round-up rules*. i then had to find a way to simulate that computation model with

`Double`

math. Now i *think*the original system is using

`Single`

precision math, that i want to simulate using `Double`

.How do i simulate single-precision rounding using doubles?

In my current model, i once again have residuals that fall into the regular linear patterns - that are a tell-tale sign of rounding:

The problem is that the error becomes larger, and only visible, as my input variables become larger. i realized this is likely caused by the fact that all floating point numbers are normalized into IEEE 754 "scientific notation".

And even if i'm wrong, i still want to try it.

And even if i don't want to trying it, i'm still asking the question

How do i simulate

`Single`

precision rounding using`Doubles`

?

It seems to me i could still apply the concept of *"rounding after 8 fractional bits"* (although 24 bits for `Single`

precision floating point), as long as i can first *"normalize"* the value. e.g.

```
1234567898.76543
```

needs to be converted into (something similar to):

```
1.23456789876543 E-09
```

Then i could apply my "round to the 24th bit" (i.e. 2^24 = 16,777,216)

```
floor(1.23456789876543E-09 * 16777216 + 0.5) / 16777216;
```

The problem, then, is what combination of `sign`

, `abs`

, `ln`

, `exp`

(or other functions) can i possible apply so that i can "normalize" my value, round it to the n-th binary place, then "denormalize" it?

**Note**: i realize IEEE representation keeps a binary `1`

as the most significant bit. i might not need to duplicate that behavior in order to get correct results. So it's not a deal-breaker, nor is it cause to suggest that the entire approach is a failure.