This note
covers the following topics: Linear Algebra, Differentiability, integration,
Cotangent Space, Tangent and Cotangent bundles, Vector fields and 1 forms,
Multilinear Algebra, Tensor fields, Flows and vectorfields, Metrics.

This note explains the following
topics: From Kock–Lawvere axiom to microlinear spaces, Vector
bundles,Connections, Affine space, Differential forms, Axiomatic structure of
the real line, Coordinates and formal manifolds, Riemannian structure,
Well-adapted topos models.

This note
explains the following topics: Linear Transformations, Tangent Vectors, The
push-forward and the Jacobian, Differential One-forms and Metric Tensors, The
Pullback and Isometries, Hypersurfaces, Flows, Invariants and the Straightening
Lemma, The Lie Bracket and Killing Vectors, Hypersurfaces, Group actions and
Multi-parameter Groups, Connections and Curvature.

The purpose of this course note is the study of curves and surfaces ,
and those are in general, curved. The book mainly focus on geometric aspects of
methods borrowed from linear algebra; proofs will only be included for those
properties that are important for the future development.

This
note contains on the following subtopics of Differential Geometry,
Manifolds, Connections and curvature, Calculus on
manifolds and Special topics.

These notes are an attempt to
summarize some of the key mathematical aspects of differential geometry,as they
apply in particular to the geometry of surfaces in R3. Covered topics are: Some
fundamentals of the theory of surfaces, Some important parameterizations of
surfaces, Variation of a surface, Vesicles, Geodesics, parallel transport and
covariant differentiation.

This book covers the following topics: Smooth Manifolds, Plain curves, Submanifolds, Differentiable maps, immersions,
submersions and embeddings, Basic results from Differential Topology, Tangent
spaces and tensor calculus, Riemannian geometry.