Revision as of 04:55, 25 April 2018 edit Plusk01 (talk \| contribs) 8 edits →External links ← Previous edit		Revision as of 10:15, 12 August 2018 edit undo 109.41.65.155 (talk) →Lie derivative: the d in the derivate shoud always be \mathrm{d} not \operatorname{d} to prevent the spacing Next edit →
Line 26: :<math>\begin{align} \dot{y} = \frac{\~~operatorname~~mathrm{d}h(x)}{\~~operatorname~~mathrm{d}t} &=\frac{\~~operatorname~~mathrm{d}h(x)}{\~~operatorname~~mathrm{d}x}\dot{x}\\ &= \frac{\~~operatorname~~mathrm{d}h(x)}{\~~operatorname~~mathrm{d}x}f(x) + \frac{\~~operatorname~~mathrm{d}h(x)}{\~~operatorname~~mathrm{d}x}g(x)u \end{align}</math> Now we can define the Lie derivative of <math>h(x)</math> along <math>f(x)</math> as, :<math>L_{f}h(x) = \frac{\~~operatorname~~mathrm{d}h(x)}{\~~operatorname~~mathrm{d}x}f(x),</math> and similarly, the Lie derivative of <math>h(x)</math> along <math>g(x)</math> as, :<math>L_{g}h(x) = \frac{\~~operatorname~~mathrm{d}h(x)}{\~~operatorname~~mathrm{d}x}g(x).</math> With this new notation, we may express <math>\dot{y}</math> as, Line 44: Note that the notation of Lie derivatives is convenient when we take multiple derivatives with respect to either the same vector field, or a different one. For example, :<math>L_{f}^{2}h(x) = L_{f}L_{f}h(x) = \frac{\~~operatorname~~mathrm{d}(L_{f}h(x))}{\~~operatorname~~mathrm{d}x}f(x),</math> and :<math>L_{g}L_{f}h(x) = \frac{\~~operatorname~~mathrm{d}(L_{f}h(x))}{\~~operatorname~~mathrm{d}x}g(x).</math> === Relative degree ===

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