Linear Operators, Part 1 |
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Page 151
m , 1-1 m , n- > Self ( s ) ' p z ( yu , ds ) < 0 and lim Se \ n ( s ) — 1 ( s ) | po ( 41 , ds
) = 0 follow easily from Corollary 13 ( b ) and Theorem 3.6 . Consequently , lim
sup \ In – Iml Slim sup ( St. 1 , ( s ) —fm ( s ) polu , ds ) " " + 2el'n Slim sup [ { St . \ .
m , 1-1 m , n- > Self ( s ) ' p z ( yu , ds ) < 0 and lim Se \ n ( s ) — 1 ( s ) | po ( 41 , ds
) = 0 follow easily from Corollary 13 ( b ) and Theorem 3.6 . Consequently , lim
sup \ In – Iml Slim sup ( St. 1 , ( s ) —fm ( s ) polu , ds ) " " + 2el'n Slim sup [ { St . \ .
Page 557
Sx , then R ( T ) x ; = 0 , and consequently R ( T ) x = 0 for all x e X. Thus a non -
zero polynomial R exists such that R ( T ) Let R be factored as R ( 2 ) = B119–1 (
2–2 ; ) . If his o ( T ) , then ( T - 2 ; 1 ) x = 0 implies x = 0. Consequently , the
product ...
Sx , then R ( T ) x ; = 0 , and consequently R ( T ) x = 0 for all x e X. Thus a non -
zero polynomial R exists such that R ( T ) Let R be factored as R ( 2 ) = B119–1 (
2–2 ; ) . If his o ( T ) , then ( T - 2 ; 1 ) x = 0 implies x = 0. Consequently , the
product ...
Page 615
Thus , 1 / nU ( t ) = U ( t / n ) for each t with 0 St Sɛ , and consequently U ( t ) = mU
( t / n ) = U ( mt / n ) n for each rational number m / n with o 5 mins 1 , and each t in
the interval 0 st Se . In particular , min U ( E ) = U ( em / n ) , so that , by ...
Thus , 1 / nU ( t ) = U ( t / n ) for each t with 0 St Sɛ , and consequently U ( t ) = mU
( t / n ) = U ( mt / n ) n for each rational number m / n with o 5 mins 1 , and each t in
the interval 0 st Se . In particular , min U ( E ) = U ( em / n ) , so that , by ...
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Contents
Preliminary Concepts | 1 |
The VitaliHahnSaks Theorem and Spaces of Measures | 7 |
B Topological Preliminaries | 10 |
Copyright | |
87 other sections not shown
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