194 METHODS OF MATHEMATICAL PROOF, PART II Chapter 6Solution Let A and B be given invertible n x n matrices. We must find a
matrix X, ., such that (AB)X = X(AB) = I,. Now since A is invertible,
there exists an n x n matrix C such that AC = CA = I,. Since B is in-
vertible, there corresponds an n x n matrix D such that BD = DB = I,.
We get the desired X from C and D, namely, by letting X = DC. Note
that (AB)X = (AB)(DC) = A(BD)C = A(I,)C = AC = I,. Verify that
X(AB) = I,. 0Obviously, the key to the preceding proof, once the setting-up is com-
pleted, is the choice X = DC of X in terms of D and C. If you had never
seen this proof before, how might you have discovered that X = DC was
the proper choice? Back in Chapter 1 we emphasized two main methods
of discovery that mathematicians use and that are worth recalling here.
One was drawing a picture (a method we will use in the next example);
the other was carrying out computations in specific examples. Assuming
that you have some computational familiarity with matrices, you mightlook at a particular pair of invertible matrices, say A =
(; :) andB = (-i
:). Computations yield
9
D=(-:, i), and X=(-! -- 8.After some experimentation, you might finally notice the relationship X =
DC, and this observation should lead to the speculation that the choice
X = DC of X will work in general.
In the next example we use geometric motivation for our selection of the
existentially quantified unknown, as we apply definitions from Example 4.' EXAMPLE 9 Suppose S and T are both open subsets of R. Prove that
S n T and S u T are both open.
Solution We deal first with intersection. Let S and T be arbitrary open
subsets of R. According to the definition of "open," in order to prove
that S n T is open, we must show that each point of S n T is an interior
point. So begin by letting x be an arbitrary point in S n T. (Note: We
are using here, almost unconsciously, proof-writing techniques over
which we labored hard in Article 5.2. In particular, we are setting up
our proof in terms of the desired conclusion, not the hypotheses.) To
prove that x is an interior point of S n T, we must produce a positive
real number 6 such that the 6 neighborhood N(x; 6) of x is a subset of