2005
DOI: 10.1007/s10107-005-0672-6
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Minimizing Polynomials via Sum of Squares over the Gradient Ideal

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Cited by 145 publications
(159 citation statements)
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“…they lie in V R (I grad p ), the (real) gradient variety of p, the unconstrained minimization problem (1.3) can be p − p min is a sum of squares modulo I grad p . Summarizing, the above results of Nie et al [99] show that the parameter p grad can be approximated via converging moment/SOS bounds; when p has a minimum, then p min = p grad and thus p min too can be approximated.…”
Section: Sums Of Squares Moments and Polynomial Optimization 77mentioning
confidence: 73%
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“…they lie in V R (I grad p ), the (real) gradient variety of p, the unconstrained minimization problem (1.3) can be p − p min is a sum of squares modulo I grad p . Summarizing, the above results of Nie et al [99] show that the parameter p grad can be approximated via converging moment/SOS bounds; when p has a minimum, then p min = p grad and thus p min too can be approximated.…”
Section: Sums Of Squares Moments and Polynomial Optimization 77mentioning
confidence: 73%
“…Yet asymptotic convergence does hold and sometimes even finite convergence. Nie et al [99] show the representation results from Theorems 7.15-7.16 below, for positive (nonnegative) polynomials on their gradient variety as sums of squares modulo their gradient ideal. As an immediate application, there is asymptotic convergence (moreover, finite convergence when I grad p is radical) of the moment/SOS bounds from the programs (6.3), (6.2) (applied to the polynomial constraints ∂p/∂x i = 0 (i = 1, .…”
Section: Sums Of Squares Moments and Polynomial Optimization 69mentioning
confidence: 94%
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