9.5 *A Glimpse Beyond the Horizon 579such as C[a, b]. But there are other norms commonly in use on C[a, b] and its
subspaces; for example,
111111 =1: lfl, and111112=v1: 111
2
·
Each of these norms on C[a, b] is useful for certain purposes, such as in
Fourier analysis or approximation theory. You may wish to check for yourself
that these are indeed norms on [a, b]. It is fairly easy to understand why 11·11 1
might be useful as a norm, when you remember that the 111111 is intended to
indicate the distance of f from the 0 function, and that II! -gll is intended
to represent the distance between f and g. The area between their graphs is a
reasonable measure of the distance between two functions. See Figure 9.16.y
11/11 1 = total areaxllf-gll 1 =total area between curves.Figure 9.16The importance of the second norm, 11·1'2, can perhaps be best understood
when it is seen as more closely resembling the familiar "Euclidean" norm on
]Rn,
ll(x1,x2, · .. ,xn)ll = \/~ x;.
This norm, 11 · 112 , is commonly used in approximation theory and Fourier anal-
ysis, although it is not the only one.
Many of the concepts learned in this course generalize to normed vector
spaces. For example, a sequence { Vn} in a normed vector space V is said to
converge to an element v E V if
'tic> 0, :3 no E .N 3 n 2: no=} llvn - vii < c (i.e., llvn -vii -t 0).
A sequence { Vn} in a normed vector space V is said to be a Cauchy sequence
if
'tic> 0, :3 no E .N 3 m, n 2: no==} llvm - vnll < c.
Thus, a sequence Un} of functions in the space C[a, b] converges to a
function f by this definition iff fn __, f uniformly on [a,b]. Theorems 9.2.7 and