*This question arose out of something strange that I noticed after investigating this question further...*

I always understood MATLAB variables to be double-precision by default. So, if I were to do something like declare a variable with 20 digits after the decimal point:

```
>> num = 2.71828182845904553488;
>> class(num) %# Display the variable type
ans =
double
```

I would expect the last 4 digits to be ignored, since the floating-point relative accuracy is on the order of 10^{-16}:

```
>> eps(num)
ans =
4.440892098500626e-016
```

If I try to display the number with more than 16 digits after the decimal point (using either FPRINTF or SPRINTF), I get what I expect to see:

```
>> fprintf('%0.20f\n',num)
2.71828182845904550000
>> sprintf('%0.20f',num)
ans =
2.71828182845904550000
```

In other words, digits 17 through 20 are all 0.

But things get weird when I pass `num`

to the variable precision arithmetic function in the Symbolic Toolbox, telling it to represent the number using 21 digits of precision:

```
>> vpa(num,21)
ans =
2.71828182845904553488
```

**WHAT?!** Those last 4 digits have reappeared! Shouldn't they have been lost when the original number I entered was stored as a double-precision variable `num`

? Since `num`

is a double-precision variable when it is passed to `vpa`

, how did `vpa`

know what they were?

My best guess as to what is happening is that MATLAB internally represents `num`

with more precision than a double since I initialized it to a number with more digits past the decimal point than a double-precision variable could handle. Is this really what is happening, or is something else going on?

**BONUS:** And here's an additional source of confusion if you don't already have a migraine from the above...

```
>> num = 2.71828182845904553488; %# Declare with 20 digits past the decimal
>> num = 2.718281828459045531; %# Re-declare with 18 digits past the decimal
>> vpa(num,21)
ans =
2.71828182845904553488 %# It's the original 20-digit number!!!
```