The theory of manifolds Lecture 3. Tf : TR n TR m

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The theory of manifolds Lecture 3 Definition 1. The tangent space of an open set U R n, TU is the set of pairs (x, v) U R n. This should be thought of as a vector v based at the point x U. Denote by T p U TU the vector space consisting of all vectors (p, v) based at the point p. If f : R n R m the tangent map of f is defined by We also define the linear map Tf : TR n TR m Tf(x, v) := (f(x), Df(x)v) T p f : T p R n T f(p) R m T p f(p, v) := (f(p), Df(p)v) Recall that the chain theorem tells us that T(f g) = Tf Tg We recall that a subset, X, of R N is an n-dimensional manifold, if, for every p X, there exists an open set, U R n, a neighborhood, V, of p in R N and a C -diffeomorphism, ϕ : U X X. Definition 2. We will call ϕ a parameterization of X at p. Our goal in this lecture is to define the notion of the tangent space, T p X, to X at p and describe some of its properties. Before giving our official definition we ll discuss some simple examples. Example 1. Let f : R R be a C function and let X = graphf. 1

l X = graph f p 0 x Then in this figure above the tangent line, l, to X at p 0 = (x 0, y 0 ) is defined by the equation y y 0 = a(x x 0 ) where a = f (x 0 ) In other words if p is a point on l then p = p 0 +λv 0 where v 0 = (1, a) and λ R n. We would, however, like the tangent space to X at p 0 to be a subspace of the tangent space to R 2 at p 0, i.e., to be the subspace of the space: T p0 R 2 = {p 0 } R 2, and this we ll achieve by defining Example 2. T p0 X = {(p 0, λv 0 ), λ R}. Let S 2 be the unit 2-sphere in R 3. The tangent plane to S 2 at p 0 is usually defined to be the plane {p 0 + v ; v R 3, v p 0 }. However, this tangent plane is easily converted into a subspace of T p R 3 via the map, p 0 + v (p 0, v) and the image of this map {(p 0, v) ; v R 3, v p 0 } will be our definition of T p0 S 2. Let s now turn to the general definition. As above let X be an n-dimensional submanifold of R N, p a point of X, V a neighborhood of p in R N, U an open set in R n and ϕ : (U, q) (X V, p) a parameterization of X. We can think of ϕ as a C map ϕ : (U, q) (V, p) 2

whose image happens to lie in X V and we proved last time that its derivative at q is injective. T q ϕ : T q R n T p R N (1) Definition 3. The tangent space, T p X, to X at p is the image of the linear map (1). In other words, w T p R N is in T p X if and only if w = T q ϕ(v) for some v T q R n. More succinctly, T p X = Tϕ(T q R n ). (2) (Since T q ϕ is injective this space is an n-dimensional vector subspace of T p R N.) One problem with this definition is that it appears to depend on the choice of ϕ. To get around this problem, we ll give an alternative definition of T p X. Last time we showed that there exists a neighborhood, V, of p in R N (which we can without loss of generality take to be the same as V above) and a C map f : (V, p) (R k, 0), k = N n, (3) such that X V = f 1 (0) and such that f is a submersion at all points of X V, and in particular at p. Thus T p f : T p R N T 0 R k is surjective, and hence the kernel of T p f has dimension n. Our alternative definition of T p X is T p X = kernel T p f. (4) The spaces (2) and (4) are both n-dimensional subspaces of T p R N, and we claim that these spaces are the same. (Notice that the definition (4) of T p X doesn t depend on ϕ, so if we can show that these spaces are the same, the definitions (2) and (4) will depend neither on ϕ nor on f.) Proof. Since ϕ(u) is contained in X V and X V is contained in f 1 (0), f ϕ = 0, so by the chain rule T p f T q f = T q (f ϕ) = 0. (5) Hence if v T p R n and w = Tϕ(v), T p f(w) = 0. This shows that the space (2) is contained in the space (4). However, these two spaces are n-dimensional so the coincide. From the proof above one can extract a slightly stronger result: 3

Theorem 1. Let W be an open subset of R l and h : (W, q) (R N, p) a C map. Suppose h(w) is contained in X. Then the image of the map is contained in T p X. T q h : T q R l T p R N Proof. Let f be the map (3). We can assume without loss of generality that h(w) is contained in V, and so, by assumption, h(w) X V. Therefore, as above, f h = 0, and hence T q h(t q R l ) is contained in the kernel of T p f. Definition 4. Define the tangent space to a manifold X R N, to be the subset TX TR N given by {(x, v) TR N so that (x, v) T x X for some x X} Theorem 2. If X R N is a smooth sub manifold of R N, then TX TR N is a smooth sub manifold. The proof of this is left as an exercise. We shall now define the tangent map or derivative of a mapping between manifolds. Explicitly: Let X be a submanifold of R N, Y a submanifold of R m and g : (X, p) (Y, y 0 ) a C map. There exists a neighborhood, O, of X in R N and a C map, g : O R m extending to g. We will define to be the restriction of the map to T(X O) T O to be the restriction of the map Tg : TX TY T g (T p g) : T p X T y0 Y (6) T p g : T p R N T y0 R m (7) to T p X. There are two obvious problems with this definition: 1. Is the space contained in T y0 Y? T p g(t p X) 2. Does the definition depend on g? 4

To show that the answer to 1. is yes and the answer to 2. is no, let ϕ : (U, x 0 ) (X V, p) be a parameterization of X, and let h = g ϕ. Since ϕ(u) X, h(u) Y and hence by Theorem 2 T x0 h(t x0 R n ) T y0 Y. But by the chain rule so by (2) T x0 h = T p g T x0 ϕ, (8) and (T p g)(t p X) T p Y (9) (T p g)(t p X) = T x0 h(t x0 R n ) (10) Thus the answer to 1. is yes, and since h = g ϕ = g ϕ, the answer to 2. is no. From (5) and (6) one easily deduces Theorem 3 (Chain rule for mappings between manifolds). Let Z be a submanifold of R l and ψ : (Y, y 0 ) (Z, z 0 ) a C map. Then T q ψ T p g = T p (ψ g). Problem set 1. What is the tangent space to the quadric, x 2 n = x2 1 + + x2 n 1, at the point, (1, 0,..., 0, 1)? 2. Show that the tangent space to the (n 1)-sphere, S n 1, at p, is the space of vectors, (p, v) T p R n satisfying p v = 0. 3. Let f : R n R k be a C map and let X = graphf. What is the tangent space to X at (a, f(a))? 4. Let σ : S n 1 S n 1 be the anti-podal map, σ(x) = x. What is the derivative of σ at p S n 1? 5. Let X i R N i, i = 1, 2, be an n i -dimensional manifold and let p i X i. Define X to be the Cartesian product X 1 X 2 R N 1 R N 2 and let p = (p 1, p 2 ). Describe T p X in terms of T p1 X 1 and T p2 X 2. 5

6. Let X R N be an n-dimensional manifold and ϕ i : U i X V i, i = 1, 2. From these two parameterizations one gets an overlap diagram ϕ 1 X V ϕ 2 W ψ 1 W 2 (11) where V = V 1 V 2, W i = ϕ 1 i (X V ) and ψ = ϕ 1 2 ϕ 1. (a) Let p X V and let q i = ϕ 1 i (p). Derive from the overlap diagram (10) an overlap diagram of linear maps T p R N (Tϕ 1 ) (Tϕ 2 ) (Tψ) T q1 R n T q2 R n (12) (b) Use overlap diagrams to give another proof that T p X is intrinsically defined. 6

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