Supplement to Frege's Logic, Theorem, and Foundations for Arithmetic
Proof of the Lemma for Hume's Principle
[Note: We use εF to denote the extension of the concept F.]
Let P,Q be arbitrarily chosen concepts. We want to show:
εQ ∈ #P ≡ Q ≈ P
So, by definition of #F, we have to show:
εQ ∈ εP≈ ≡ Q ≈ P
We prove this by appealing to the Law of Extensions, which yields the following Fact:
Fact: εQ ∈ εP≈ ≡ P≈(εQ)
(→) Assume εQ ∈ εP≈ (to show: Q ≈ P). Then, by the above Fact, we know P≈(εQ), i.e.,
[λx ∃H(x = εH & H ≈ P)](εQ)
By λ-conversion, this implies:
∃H(εQ = εH & H ≈ P)
Let R be such a concept:
εQ = εR & R≈ P (1)
But, by Basic Law V, the first conjunct implies ∀x(Qx ≡ Rx). Since the material equivalence of two concepts implies their equinumerosity (this was noted as Fact 1 in the subsection on Equinumerosity in the main part of the entry), it follows that Q ≈ R. So from this result and the second conjunct of (1), it follows that Q ≈ P, by the transitivity of equinumerosity (Fact 4 in the subsection on Equinumerosity).
(←) Assume Q ≈ P (to show: εQ ∈ εP≈). Then, by identity introduction, we know: εQ = εQ & Q ≈ P. So, by existential generalization:
∃H(εQ = εH & H ≈ P)
And by λ-Conversion:
[λx ∃H(x = εH & H ≈ P)](εQ)
So, by the Law of Extensions, εQ ∈ εP≈.