Lectures related to Application of Taylor's approximation formula

Covers differentiable functions, extreme points, and the Lagrange multiplier method for optimization.

Covers functions, differentiability, Taylor expansions, and integrals, providing fundamental concepts and practical applications.

Explores Taylor series, function properties, inflection points, and critical points in graphical and mathematical contexts.

Covers Taylor's formula, developments, and extrema of functions, discussing convexity and concavity.

Explores Taylor's formula, polynomials, functions, and series applications.

Covers the conditions for finding absolute extrema in multivariable functions.

Covers the study of local functions, behavior analysis, and Taylor series development.

Covers parametric functions, integrals, and the origin of plasticity in metals.

Explores functions, limits, continuity, differentiability, and important notions of limits and divergence.

Explores the theory and application of Taylor polynomials for function approximation and limit calculations.

Explores trigonometric derivatives, composition of functions, and inflection points in differential calculation.

Discusses optimization techniques, focusing on local and global extrema in functions.

Covers the optimization of functions, focusing on finding the maximum and minimum values over a given domain.

Explores the Local Inversion Theorem and extremum points in functions.

Explores Taylor polynomials, odd orders, simplification, residues, and special cases of zero polynomials.

Focuses on determining local extremum points of functions through various examples.

Explores derivatives, local extrema, and convexity in functions, including Taylor's formula and function compositions.

Covers derivatives and continuity in multivariable functions, emphasizing the importance of partial derivatives.

Covers the properties of functions, including symmetry, continuity, and limits.

Covers Taylor's approximation theorem, differentiability, error control, and function expansions.