# Lambda calculus reduction of functions

I'm very new to lambda calculus and while I was reading a tutorial , came across with this. Here is my equation.

``````Y = ƛf.( ƛx.f(xx)) ( ƛx.f(xx))
``````

Now if we apply another term, let's say F (YF), then how can we reduce this.If I'm correct according to beta reduction , we can replace all the f in ( ƛx.f(xx)) by ( ƛx.f(xx)), is this correct and if so how can we do that.

Thanks

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Reuction steps:

``````Y = ƛf.( ƛx.f(xx)) ( ƛx.f(xx)) = ƛf.( f ( ƛx.f(xx) ƛx.f(xx) ) )
= ƛf.( f ( f (ƛx.f(xx) ƛx.f(xx))))
= ƛf.( f ( f ( f (ƛx.f(xx) ƛx.f(xx))))
= ƛf.( f ( f ( f ( f (ƛx.f(xx) ƛx.f(xx))))) = ...
``````

So this Lambda term goes into an infinite loop...

Explanation:
Let's look on the term `( ƛx.f(xx) ƛx.f(xx) )` we substitute `ƛx.f(xx)` with `f'`
which means `(f' f')` => activating the term `f'` on itself.
It might be easier to look at like this:
`( ƛy.f(yy) ƛx.f(xx) )` now when you activate the `ƛy.f(yy)` and provide the input (which substitutes `y` with `ƛx.f(xx)` ) the outcome is: `f(ƛx.f(xx) ƛx.f(xx))` which in turn, can go over the same process again and again and the lambda-expression will only expend...

Remark:
It's wrong to write:
`Y = ƛf.( ƛx.f(xx)) ( ƛx.f(xx))` it should actually be: `Y = ƛf.(ƛx.f(xx) ƛx.f(xx))`
The difference between `ƛx.f(xx)` and `(ƛx.f(xx))` is that the latter is an activation of `ƛx.f(xx)` - it's meaningless to activate it like this `(ƛx.f(xx))` since we need an `x` (input) to activate it on.

Finally:
`Y = ƛf.( ƛx.f(xx)) ( ƛx.f(xx)) = ƛf.( f ( ƛx.f(xx) ƛx.f(xx) ) )`
meaning:
`YF = ( ƛx.F(xx)) ( ƛx.F(xx)) = F(ƛx.F(xx)) ( ƛx.F(xx)) = F(YF)`

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Could you please tell me the steps to follow or the techniques I may use –  Pradeep Jul 4 '12 at 2:22
I don't get how you got ƛf.( f ( ƛx.f(xx) ƛx.f(xx) ) ) Could you please tell the theorem used –  Pradeep Jul 4 '12 at 3:23
So if we write an activation like YF, is it equals to `( ƛx.F(xx)) ( ƛx.F(xx))` –  Pradeep Jul 4 '12 at 5:31
`( ƛx.F(xx))` is an activation of `ƛx.F(xx)` without parameters (which means nothing on our case cause it can be activated only on a parameter). Not sure what did you mean by YF though. –  alfasin Jul 4 '12 at 5:35
I came across this while trying to prove that Y is a first point combinator. So my goal is to prove that if F is any term then F(YF) = YF –  Pradeep Jul 4 '12 at 5:47