The instance of `Numeric`

is not a number itself, but it is an object that offers operations to do the arithmetic. For example, an object `num`

of type `Numeric[Int]`

can add two integers like this: `num.plus(3, 5)`

The result of this operation is the integer 7.

For integers, this is very trivial. However, for all basic numerical types, there is one *implicit* instance of `Numeric`

available. And if you define your own numeric types, you can provide one.

Therefore, you should leave the bounds for `A`

open and add an implicit parameter of type `Numeric[A]`

, with which you do the calculations. Like this:

```
def **[A](l:List[A],m:List[A])(implicit num:Numeric[A])=l.zip(m).map({t=>num.times(t._1, t._2)})
```

Of course, `num.times(a,b)`

looks less elegant than `a*b`

. In most of the cases, one can live with that. However, you can wrap the value `a`

in an object of type `Ops`

that supports operators, like this:

```
// given are: num:Numeric[A], a:A and b:A
val a_ops = num.mkNumericOps(a)
val product = a_ops * b
```

Since the method `mkNumericOps`

is declared `implicit`

, you can also import it and use it implicitly:

```
// given are: num:Numeric[A], a:A and b:A
import num._
val product = a * b
```