Revision as of 15:11, 27 July 2009 edit LutzL (talk \| contribs) Extended confirmed users 1,187 edits →As a multidimensional Newton's method ← Previous edit		Revision as of 10:16, 3 August 2009 edit undo LutzL (talk \| contribs) Extended confirmed users 1,187 edits →What gives the algorithm its power? Next edit →
Line 51: The iteration uses the given ''P'' and <math>\scriptstyle P^{\prime}</math>. In contrast the third-stage of Jenkins-Traub :<math> :<math>s_{\lambda+1}=s_\lambda- \frac{P(s_\lambda)}{\bar H^{(\lambda+1)}(s_\lambda)}</math>▼ s_{\lambda+1} ▲~~:<math>s_{\lambda+1}~~ =s_\lambda- \frac{P(s_\lambda)}{\bar H^{(\lambda+1)}(s_\lambda)}~~</math>~~ =s_\lambda-\frac{W^\lambda(s_\lambda)}{W^\lambda'(s_\lambda)}</math> is precisely a Newton-Raphson iteration performed on certain [[rational functions]]. More precisely, Newton-Raphson is being performed on a sequence of rational functions :<math>W^\lambda(z)=\frac{P(z)/}{H^{(\lambda(z)}</math>. For <math>\lambda</math> sufficiently large, :<math>P(z)/\bar H^{(\lambda)}(z)</math> is as close as desired to a first degree polynomial Line 141 ⟶ 144: :<math>-\frac{P(s)}{\bar H^k(s)}</math> is a current approximation of the smallest eigenvalue of <math>(M_X-s\cdot id)</math> resp. :<math>s-\tfrac{P(s)}{\bar H^k(ss_k)}</math> is an improved approximation of the smallest root of ''P(X)''. Chosing instead :<math>s-\tfrac{P(s)}{\bar H^{k+1}(s_k)}</math> amounts to a second inverse power iteration with shift <math>s_k</math> ==Real coefficients==

Jenkins–Traub algorithm: Difference between revisions