Just a fairly simple question (so it seems to me). If two variables (x)(x)
are alpha equivalent. Is (x1x2)(x2x1)
alpha equivalent?
1 Answer
Two terms are alphaequivalent iff one can be converted into the other purely by renaming bound variables.
A variable is considered to be a bound variable if it matches the parameter name of some enclosing lambda. Otherwise it's a free variable. Here are a few examples:
λx. x  x is bound
λx. y  y is free
λf. λx. f x y  f and x are bound, y is free
f (λf. f x)  the first f is free; the second is bound. x is free
z  z is free
Basically, "bound" and "free" roughly correspond to the notions of "in scope" and "out of scope" in procedural languages.
Alphaequivalence basically captures the idea that it's safe to rename a variable in a program if you also fix all the references to that variable. That is, when you change the parameter of a lambda term, you also have to go into the lambda's body and change the usages of that variable. (If the name is rebound by another lambda inside the first lambda, you'd better make sure not to perform the renaming inside the inner lambda.)
Here are some examples of alphaequivalent terms:
λx. x <> λy. y <> λberp. berp
λx. λf. f x <> λx. λg. g x <> λf. λx. x f <> λx1. λx2. x2 x1
λf. λf. f f <> λg. λf. f f <> λf. λg. g g
So is x x
alphaequivalent to x1x2 x1x2
? No! x
is free in the first term, because it's not bound by an enclosing lambda. (Perhaps it's a reference to a global variable.) So it's not safe to rename it to x1x2
.
I suspect your tutor really meant to say that λx. x x
is alphaequivalent to λx1x2. x1x2 x1x2
. Here the x
is bound by the lambda, so you can safely rename it.
Is x1 x2
alphaequivalent to x2 x1
? For the same reason, no.
And is λx1. λx2. x1 x2
equivalent to λx1. λx2. x2 x1
? Again, no, because this isn't just a renaming  the x1
and x2
variables moved around.
However, λx1. λx2. x1 x2
is alphaequivalent to λx2. λx1. x2 x1
:
 rename
x1
to some temporary name likez
:λz. λx2. z x2
 rename
x2
tox1
:λz. λx1. z x1
 rename
z
back tox2
:λx2. λx1. x2 x1
Getting renaming right in a language implementation is a fiddly enough problem that many compiler writers opt for a nameless representation of terms called de Bruijn indices. Rather than using text, variables are represented as a number measuring how many lambdas away the variable was bound. A nameless representation of λx2. λx1. x2 x1
would look like λ. λ. 2 1
. Note that that's exactly the same as the de Bruijn representation of λx1. λx2. x1 x2
. de Bruijn indices thoroughly solve the problem of alphaequivalence (although they are quite hard to read).

Thank you for that answer. The
λf. λf. f f <> λg. λf. f f <> λf. λg. g g
example is particularly interesting (for me, in any case.) Commented Jul 7 at 20:35
x1 x2
is alphaequivalent tox2 x1
?x
is equivalent tox
. Butx1 x2
is not alpha equivalent tox2 x1
. I'm not sure I get your point.