Marcinkiewicz interpolation theorem: Difference between revisions

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Line 1: {{Short description\|~~mathematical~~Mathematical theory by discovered by Józef Marcinkiewicz}} In [[mathematics]], particularly in [[functional analysis]], the '''Marcinkiewicz interpolation theorem''', discovered by {{harvs\|txt\|authorlink=Józef Marcinkiewicz\|first=Józef \|last=Marcinkiewicz\|year=1939}}, is a result bounding the norms of non-linear operators acting on [[lp space\|''L''<sup>p</sup> spaces]]. Marcinkiewicz' theorem is similar to the [[Riesz–Thorin theorem]] about [[linear operators]], but also applies to non-linear operators. Line 38: :'''Theorem.''' Let ''T'' be a [[bounded linear operator]] from <math>L^p</math> to <math>L^{p,w}</math> and at the same time from <math>L^q</math> to <math>L^{q,w}</math>. Then ''T'' is also a bounded operator from <math>L^r</math> to <math>L^r</math> for any ''r'' between ''p'' and ''q''. In other words, even if ~~you~~one only ~~require~~requires weak boundedness on the extremes ''p'' and ''q'', ~~you still get~~ regular boundedness ~~inside~~still holds. To make this more formal, one has to explain that ''T'' is bounded only on a [[Dense set\|dense]] subset and can be completed. See [[Riesz-Thorin theorem]] for these details. Where Marcinkiewicz's theorem is weaker than the Riesz-Thorin theorem is in the estimates of the norm. The theorem gives bounds for the <math>L^r</math> norm of ''T'' but this bound increases to infinity as ''r'' converges to either ''p'' or ''q''. Specifically {{harv\|DiBenedetto\|2002\|loc=Theorem VIII.9.2}}, suppose that Line 92: ==References== ~~<references/>~~ {{reflist}} * {{citation \| last=DiBenedetto\|first=Emmanuele\|title=Real analysis\|publisher=Birkhäuser\|year=2002\|isbn=3-7643-4231-5}}. * {{citation\|title=Elliptic partial differential equations of second order\|first1=David\|last1=Gilbarg\|authorlink1=David Gilbarg\|first2=Neil S.\|last2=Trudinger\|authorlink2=Neil Trudinger\|publisher=Springer-Verlag\|year=2001\|isbn=3-540-41160-7\| url=https://books.google.com/books~~/about/Elliptic_Partial_Differential_Equations.html~~?id=eoiGTf4cmhwC}}. {{Citation \| last1=Marcinkiewicz \| first1=J. \| title=Sur l'interpolation d'operations \| year=1939 \|url=https://gallica.bnf.fr/ark:/12148/bpt6k6238835z/f16.item#\| journal=C. R. Acad. Sci. Paris \| volume=208 \| pages=1272–1273}} {{citation\|title=Introduction to Fourier analysis on Euclidean spaces\|first1=Elias\|last1=Stein\|authorlink1=Elias Stein\|first2=Guido\|last2=Weiss\|publisher=Princeton University Press\|year=1971\|isbn=0-691-08078-X\|url-access=registration\|url=https://archive.org/details/introductiontofo0000stei}}. *{{Citation \| last1=Zygmund \| first1=A. \| title=On a theorem of Marcinkiewicz concerning interpolation of operations \|mr=0080887 \| year=1956 \| journal=[[Journal de Mathématiques Pures et Appliquées]]\|series= Neuvième Série \| issn=0021-7824 \| volume=35 \| pages=223–248}} {{Lp spaces}} {{Functional analysis}} [[Category:Fourier analysis]] [[Category:Theorems in functional analysis]] [[Category:Lp spaces]]