Tangent Vectors at a Point

Tangent vectors are a very important concept in differential geometry, and they’re one of the biggest stumbling blocks in comprehension. There are two major approaches: one more geometric, and one more algebraic. I find the algebraic approach a bit more satisfying, since it gets straight into the important properties of tangent vectors and how they are used, and it helps set the stage for tangent vectors in other contexts like algebraic geometry. Unfortunately, it’s not at all clear at first what this definition means geometrically, and why these things deserve being called “tangent vectors”. So I have to ask a little patience.

Now, we take a manifold $M$ with structure sheaf $\mathcal{O}$ . We pick some point $p\in M$ and get the stalk $\mathcal{O}_p$ of germs of functions at $p$ . This is a real algebra, and we define a “tangent vector at $p$ ” to be a “derivation at $p$ ” of this algebra. That is, $v$ is a function $v:\mathcal{O}_p\to\mathbb{R}$ satisfying

$\displaystyle\begin{aligned}v(cf+dg)&=cv(f)+dv(g)\\v(fg)&=v(f)g(p)+f(p)v(g)\end{aligned}$

The first of these conditions says that $v$ is a linear functional on $\mathcal{O}_p$ . It’s the second that’s special: it tells us that $v$ obeys something like the product rule.

Indeed, let’s take a point $x\in\mathbb{R}$ and consider the operation $D_x$ defined by $D_x(f)=f'(x)$ for any function $f$ that is differentiable at $x$ . This is linear, since both the derivative and evaluation operations are linear. The product rule tells us that

$\displaystyle\begin{aligned}D_x(fg)&=\left[fg\right]'(x)\\&=f'(x)g(x)+f(x)g'(x)\\&=D_x(f)g(x)+f(x)D_x(g)\end{aligned}$

So $D_x$ satisfies the definition of a “tangent vector at $x$ “. Indeed, as it turns out $D_x$ corresponds to what we might normally consider the vector based at $x$ pointing one unit in the positive direction.

It should immediately be clear that the tangent vectors at $p$ form a vector space. Indeed, the sum of two tangent vectors at $p$ is firstly the sum of two linear functionals, which is again a linear functional. To see that it also satisfies the “derivation” condition, let $v$ and $w$ be tangent vectors at $p$ and check

$\displaystyle\begin{aligned}\left[v+w\right](fg)&=v(fg)+w(fg)\\&=v(f)g(p)+f(p)v(g)+w(f)g(p)+f(p)w(g)\\&=\left(v(f)+w(f)\right)g(p)+f(p)\left(v(g)+w(g)\right)\\&=\left[v+w\right](f)g(p)+f(p)\left[v+w\right](g)\end{aligned}$

Checking that scalar multiples of tangent vectors at $p$ are again tangent vectors at $p$ is similar. We write $\mathcal{T}_pM$ to denote this vector space of tangent vectors at $p$ to the manifold $M$ .

I want to call attention to one point of notation here, and I won’t really bother with it again. We seem to be using each of $f$ and $g$ to refer to two different things: a germ in $\mathcal{O}_p$ — which is an equivalence class of sorts — and some actual function in $\mathcal{O}(U)$ for some neighborhood $U$ of $p$ which represents the germ. To an extent we are, and the usual excuse is that since we only ever evaluate the function at $p$ itself, it doesn’t really matter which representative of the germ we pick.

However, a more nuanced view will see that we’ve actually overloaded the notation $f(p)$ . Normally this would mean evaluating a function at a point, yes, but here we interpret it in terms of the local ring structure of $\mathcal{O}_p$ . Given a germ $f\in\mathcal{O}_p$ there is a projection $\mathcal{O}_p\to\mathbb{R}$ , which we write as $f\mapsto f(p)$ .

If all this seems complicated, don’t really worry about it. You can forget the whole last paragraph and get by on “sometimes we use a germ as if it’s an actual function defined in a neighborhood of $p$ , and it will never matter which specific representative function we use because we only ever ask what happens at $p$ itself.”

March 29, 2011 - Posted by John Armstrong | Differential Topology, Topology

13 Comments »

[…] « Previous | […]

Pingback by Tangent Vectors and Coordinates « The Unapologetic Mathematician | March 30, 2011 | Reply
[…] a point in an -dimensional manifold , we have the vector space of tangent vectors at . Given a coordinate patch around , we’ve constructed coordinate vectors at , and shown […]

Pingback by Coordinate Vectors Span Tangent Spaces « The Unapologetic Mathematician | March 31, 2011 | Reply
Should the second equation have $v(fg)(p)$ on its lhs?

Comment by Avery Andrews | April 1, 2011 | Reply
Or perhaps a $\lambda p.$ on its rhs

Comment by Avery Andrews | April 1, 2011 | Reply
No, I go into this down near the bottom. Since $f$ and $g$ are germs at $p$ , they each have a “value at $p$ “, which we write $f(p)$ and $g(p)$ .

Everything in sight is taking place “at” the single point $p$ here. A tangent vector $v$ at $p$ takes a germ $f$ at $p$ and gives a real number.

Comment by John Armstrong | April 1, 2011 | Reply
[…] of a point in an -dimensional manifold , we get coordinate vectors which form a basis for the tangent space . But this is true of any coordinate patch! If we have another patch , we can get another basis . […]

Pingback by Coordinate Transforms on Tangent Vectors « The Unapologetic Mathematician | April 1, 2011 | Reply
[…] far we’ve talked about tangent spaces one at a time. For each we get a tangent space at . But things get really interesting when we […]

Pingback by The Tangent Bundle « The Unapologetic Mathematician | April 4, 2011 | Reply
[…] any point of an open interval, the tangent space is one-dimensional. And, in fact, it comes equipped with a canonical vector to use as a basis: , […]

Pingback by Curves « The Unapologetic Mathematician | April 8, 2011 | Reply
There is an obvious typo in the first equation (you have a $c$ where you meant $d$ ).

Comment by Todd Trimble | April 9, 2011 | Reply
Thanks, fixed.

Comment by John Armstrong | April 9, 2011 | Reply
[…] another construct in differential topology and geometry that isn’t quite so obvious as a tangent vector, but which is every bit as useful: a cotangent vector. A cotangent vector at a point is just an […]

Pingback by Cotangent Vectors, Differentials, and the Cotangent Bundle « The Unapologetic Mathematician | April 13, 2011 | Reply
[…] manifolds, with the -dimensional product manifold. Given points and we want to investigate the tangent space of this product at the point […]

Pingback by The Tangent Space of a Product « The Unapologetic Mathematician | April 27, 2011 | Reply
[…] with boundary , then at all the interior points it looks just like a regular manifold, and so the tangent space is just the same as ever. But what happens when we consider a point […]

Pingback by The Tangent Space at the Boundary « The Unapologetic Mathematician | September 15, 2011 | Reply

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