You need to use an undocumented trick with Excel's `LINEST`

function:

```
=LINEST(known_y's, [known_x's], [const], [stats])
```

## Background

A regular *linear* regression is calculated (with your data) as:

```
=LINEST(B2:B21,A2:A21)
```

which returns a single value, the linear slope (`m`

) according to the formula:

which for your data:

is:

## Undocumented trick Number 1

You can also use Excel to calculate a regression with a formula that uses an exponent for `x`

different from `1`

, e.g. x^{1.2}:

using the formula:

```
=LINEST(B2:B21, A2:A21^1.2)
```

which for you data:

is:

## You're not limited to one exponent

Excel's `LINEST`

function can also calculate multiple regressions, with different exponents on `x`

at the same time, e.g.:

```
=LINEST(B2:B21,A2:A21^{1,2})
```

**Note:** if locale is set to European (decimal symbol ","), then comma should be replaced by semicolon and backslash, i.e. `=LINEST(B2:B21;A2:A21^{1\2})`

Now Excel will calculate regressions using both x^{1} and x^{2} at the same time:

## How to actually do it

The impossibly tricky part there's no obvious way to *see* the other regression values. In order to do that you need to:

You will now see your 3 regression constants:

```
y = -0.01777539x^2 + 6.864151123x + -591.3531443
```

## Bonus Chatter

I had a function that I wanted to perform a regression using *some* exponent:

y = m×x^{k} + b

But I didn't **know** the exponent. So I changed the `LINEST`

function to use a cell reference instead:

```
=LINEST(B2:B21,A2:A21^F3, true, true)
```

With Excel then outputting full stats (the 4th paramter to `LINEST`

):

I tell the **Solver** to maximize R^{2}:

And it can figure out the best exponent. Which for you data:

is: