*If you're looking for a bijection from IRxIR -> [-1;1], I can suggest this:*

**bijection from IR to ]-a:a[**

First let's find a bijection from IR-> ]-1;1[ so we just need to find a bijection from IRxIR->IR

```
tan(x): ]-Pi/2;Pi/2[ -> IR
arctan(x) : IR -> ]-Pi/2;Pi/2[
1/Pi*arctan(x) + 1/2: IR -> ]0;1[
2*arctan(x) : IR->]-Pi:Pi[
```

and

```
ln(x) : IR + -> IR
exp(x): IR -> R+
```

**Bijection from ]0,1[ x ]0,1[ -> ]0,1[**

let's write:

```
(x,y) in ]0,1[ x ]0,1[
x= 0,x1x2x3x4...xn...etc where x1x2x3x4...xn represent the decimals of x in base 10
y=0,y1y2y3y4...ym...etc idem
Let's define z=0,x1y1x2y2xx3y3....xnyn...Oym in ]0,1[
```

Then by construction we can provethere that it is exact bijection from ]0,1[ x ]0,1[ to ]0,1[.
(i'm not sure it's is true for number zith infinite decimals..but it's at least a "very good" injection, tell me if i'm wrong)

let's name this function : CANTOR(x,y)

then **2*CANTOR-1 is a bijection from ]0,1[ x ]0,1[ -> ]-1,1[**

**Then combining all the above assertions:**

here you go, you get the bijection from IRxIR -> ]-1;1[...

You can combine with a bijection from IR-> ]0,1[

```
IRxIR -> ]-1;1[
(x,y) -> 2*CANTOR(1/Pi*arctan(x) + 1/2,1/Pi*arctan(y) + 1/2)-1
```

let's define the reciproque, we process the same way:

RCANTOR: z -> (x,y) (reciproque of CANTOR(x,y)

RCANTOR((z+1)/2): ]-1:1[ -> ]01[x ]0,1[

```
then 1/Pi*tan(RCANTOR((z+1)/2)) + 1/2 : z ->(x,y)
]-1;1[ -> IRxIR
```