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    • 1.0: Lagrange Interpolation
      This page discusses the Lagrange interpolation polynomial on arbitrary time scales, covering its construction through the forward jump operator, delta differentiation, and the graininess function. It establishes the existence and uniqueness of these polynomials at distinct points, supported by numerical examples.
    • 1.1: Sigma-Lagrange Interpolation
      This page provides an in-depth overview of \(\sigma\)-Lagrange polynomials and their distinctions from traditional Lagrange interpolation. It covers definitions, conditions for \(\sigma\)-distinct points, and theorems ensuring existence and uniqueness of these polynomials.
    • 1.2: Hermite Interpolation
      This page covers Hermite interpolation, emphasizing its generalization of Lagrange interpolation by defining polynomials that satisfy both values and derivatives at distinct points. It discusses the uniqueness of the Hermite polynomial, its applications, error estimation, and bounds for the difference between a function and its polynomial approximation.
    • 1.3: Sigma-Hermite Interpolation
      This page covers \(\sigma\)-Hermite interpolation polynomials, detailing their construction, properties, and differentiation from traditional Hermite polynomials. It discusses conditions for existence and uniqueness, along with \(\Delta\)-differentiability on time scales. The text introduces the associated errors and provides illustrative examples to highlight differences in results between the two polynomial types.
    • 1.4: Delta Differentiation
      This page discusses a theoretical exploration of the error in approximating the delta derivative of a function with its interpolation polynomial, presenting a theorem that links the two and quantifies error within an interval. It also outlines the convergence of a sequence of functions, establishing bounds that illustrate how the deviation from polynomial approximation decreases to zero uniformly under certain conditions as the sequence progresses.

    Thumbnail: This image shows, for four points ((−9, 5), (−4, 2), (−1, −2), (7, 9)), the (cubic) interpolation polynomial L(x) (dashed, black), which is the sum of the scaled basis polynomials y1ℓ1(x), y2ℓ2(x), y3ℓ3(x) and y4ℓ4(x). (CC BY-SA 4.0; Glosser.ca via Wikipedia)

     

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