Lectures on Tensor Calculus and Differential Geometry

angle arc length basis bivector called Christoffel symbols conditions of integrability congruence consider constant Riemannian curvature coordinate vector corresponding cosē covariant components covariant differentiation curve x(s denote differential equations dimension eigenvalues eigenvector expression finite dimensional follows geodesic curve given curve given point h h+1 h=1 h h Hence hyperplane hypersphere hypersurface identically line of curvature linear operator linearly independent metric space metric tensor metric vector space multilinear form multiplying both members n-dimensional normal number space obtained orthogonal orthonormal frame osculating parameter point space principal curvatures principal directions prove replace respect Riccian Riemannian curvature scalar invariant second fundamental tensor subspace symmetric taking account tangent space tangent vector tensor of valency theorem transformation Transvecting uniquely determined unit vector values vanishes vector function vector space zero vector βλ βλμ βμ Καβλμ νμ Σ σ Χλμ