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Line 100: Roughly speaking, '''Euler's homogeneous function theorem''' asserts that the positively homogeneous functions of a given degree are exactly the solution of a specific [[partial differential equation]]. More precisely: {{Math theorem {{Math theorem\|name=Euler's homogeneous function theorem \|math_statement=If {{mvar\|f}} is a [[partial function\|(partial) function]] of {{mvar\|n}} real variables that is positively homogeneous of degree {{mvar\|k}}, and [[continuously differentiable]] in some open subset of <math>\R^n,</math> then it satisfies in this open set the [[partial differential equation]]▼ \| name = Euler's homogeneous function theorem ▲~~{{Math theorem~~\|~~name=Euler's~~ ~~homogeneous~~math_statement ~~function~~= ~~theorem \|math_statement=~~If {{mvar\|f}} is a [[partial function\|(partial) function]] of {{mvar\|n}} real variables that is positively homogeneous of degree {{mvar\|k}}, and [[continuously differentiable]] in some open subset of <math>\R^n,</math> then it satisfies in this open set the [[partial differential equation]] <math display="block">k\,f(x_1, \ldots,x_n)=\sum_{i=1}^n x_i\frac{\partial f}{\partial x_i}(x_1, \ldots,x_n).</math> Conversely, every maximal continuously differentiable solution of this partial differentiable equation is a positively homogeneous function of degree {{mvar\|k}}, defined on a positive cone (here, ''maximal'' means that the solution cannot be prolongated to a function with a larger ___domain). }}

Homogeneous function: Difference between revisions