From [1, proposition 14] (or [7, proposition 1.4.5]), A is the
linear span of its unitary elements (i.e.
Next, for any sequence {[x'.sub.n]} of non-zero vectors in X whose
linear span is dense in X, we shall prove N(C)\ D [member of] [LAMBDA]({[x'.sub.n]}).
For instances, in [3], Figiel proved that for an isometry T : X [right arrow] Y between real normed spaces X and Y, there exists a linear map S : Y [right arrow] X such that S(T(x)) = x for all x [member of] X and moreover the restriction of S to the
linear span of T(X) has norm 1.
We recall that an operator T [member of] L(X) is said to be cyclic if there is some x [member of] X such that its orbit has dense
linear span (i.e., [absolute value of span{Orb(T, x)}] = X) and it is said to be supercyclic if there exists a vector x [member of] X such that the set of scalar multiples of the orbit is dense (i.e., [absolute value of {[lambda][T.sup.n]x : [lambda] [member of] K, n [member of] [N.sub.0]}] = X).
Let [W.sub.n] [subset] C[[x.sub.1], ..., [x.sub.n+1]] be the C-
linear span of all sub-staircase monomials.
The faces include a central, primary image about 33 feet wide, and two side walls each about 11 feet wide, creating a
linear span of about 55 feet.
The notation span {[PSI]} is used to denote the
linear span of [([[psi].sub.k]).sup.[infinity].sub.k=1] and [bar.span] {[PSI]} denotes the closed
linear span of [([[psi].sub.k]).sup.[infinity].sub.k=1].
Claim 1: The
linear span of [[~.T].sub.2](X) is dense in Y.
the generalized Walsh system is not a quasi-greedy basis in its
linear span [L.sup.1][0, 1].
In contrast to other ancient Near Eastern peoples, (49) Israel came to understand time as a
linear span (50) and developed a historical consciousness that arose out of their sense- that Yahweh journeyed with them (51) and acts in time.
If u([lambda])v([lambda]) [not equal to] 0, by (12) and (17), we have that {cos([lambda]v)} [union] {sin([lambda]v)} is in the closed
linear span of {cos([[mu].sub.n]x)} [union] {sin([[??].sub.n])}.