Revision as of 00:28, 11 April 2016 edit David9550 (talk \| contribs) 342 edits No edit summary ← Previous edit		Revision as of 00:43, 11 April 2016 edit undo David9550 (talk \| contribs) 342 edits not all elementary functions are Hardy L-functions (e.g. sin, cos) Next edit →
Line 6: for every ''C'' > 0.<ref>{{cite journal \|author=Alexander A. Razborov and Steven Rudich \|title=Natural Proofs \|journal=Journal of Computer and System Sciences \|volume=55 \|issue=1 \|date=August 1997 \|pages=24–35 \|doi=10.1006/jcss.1997.1494}}</ref> It has been proven that if a function ''ƒ'' is defined using the standard arithmetic operations, exponentials, logarithms, and ~~logarithms~~real-valued constants, then ''ƒ''(''ƒ''(''x'')) is either subexponential or superexponential.<ref>http://mathoverflow.net/questions/45477/closed-form-functions-with-half-exponential-growth</ref> <ref>{{cite web\|url=http://www.scottaaronson.com/blog/?p=263#comment-7283 \|title=Shtetl-Optimized » Blog Archive » My Favorite Growth Rates \|publisher=Scottaaronson.com \|date=2007-08-12 \|accessdate=2014-05-20}}</ref> Thus, ana [[~~elementary~~Hardy_field#Examples\|Hardy L-function]] cannot be half-exponential. There are infinitely many functions whose self-composition is the same exponential function as each other. In particular, for every <math>A</math> in the open interval <math>(0,1)</math> and for every [[continuous function\|continuous]] [[strictly increasing function]] ''g'' from <math>[0,A]</math> [[surjective function\|onto]] <math>[A,1]</math>, there is an extension of this function to a continuous monotonic function <math>f</math> on the real numbers such that <math>f(f(x))=\exp x</math>.<ref>{{cite journal

Half-exponential function: Difference between revisions