characteristic equation

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§28.34(i) Characteristic Exponents

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§28.34(ii) Eigenvalues

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(f)

Asymptotic approximations by zeros of orthogonal polynomials of increasing degree. See Volkmer (2008). This method also applies to eigenvalues of the Whittaker–Hill equation (§28.31(i)) and eigenvalues of Lamé functions (§29.3(i)).

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… ►where ${\rho }_1,{\rho }_2$ are the roots of the characteristic equation … ►

§2.9(ii) Coincident Characteristic Values

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§28.29(ii) Floquet’s Theorem and the Characteristic Exponent

… ► ►This is the characteristic equation of (28.29.1), and $\cos \left(\pi \nu \right)$ is an entire function of $\lambda$. … ►For a given $\nu$, the characteristic equation $△(\lambda )-2\cos \left(\pi \nu \right)=0$ has infinitely many roots $\lambda$. …

§28.7 Analytic Continuation of Eigenvalues

… ►The normal values are simple roots of the corresponding equations (28.2.21) and (28.2.22). … ► … ►

… ►where ${\lambda }_1$, ${\lambda }_2$ are the roots of the characteristic equation … ►See §2.11(v) for other examples. … ►The transformed differential equation either has a regular singularity at $t=\mathrm{\infty }$, or its characteristic equation has unequal roots. …

… ► ►This is the characteristic equation of Mathieu’s equation (28.2.1). …If $\widehat{\nu }=0$ or $1$, or equivalently, $\nu =n$, then $\nu$ is a double root of the characteristic equation, otherwise it is a simple root. … ►

Distribution

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Change of Sign of $q$

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§28.15(i) Eigenvalues ${\lambda }_{\nu }\left(q\right)$

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§28.16 Asymptotic Expansions for Large $q$

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§28.12(i) Eigenvalues ${\lambda }_{\nu +2n}\left(q\right)$

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