Understanding Manifolds and Riemann Manifolds: Applications and Explanation

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In summary, manifolds are sets that can be mapped to Euclidean spaces, allowing for the use of operations such as differentiation and integration. Riemannian manifolds have a metric that allows for the measurement of distances on the manifold. They are commonly used in general relativity to represent curved spacetime. A topological manifold is a topological space with certain properties and a smooth atlas, which allows for the definition of smooth maps and objects such as tangent vectors and affine connections. A Riemannian metric assigns a metric to each tangent space, allowing for the measurement of distances and the definition of geodesics.
  • #1
umerfarooque
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Can anyone explain the concept of manifold and Reimanni manifold in plain language ?? And what are its applications??

Thanks
 
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  • #2
Uh, I'm not sure what you want to hear.

In the Euclidean spaces [itex]\mathbb{R}^n[/itex], you can do anything you want to. You can integrate, differentiate, measure lengths of curves, measure angles, measure surface areas, etc.

A Riemannian manifold is some kind of "curved space" which allows you to do all of the above. For example, you can have a sphere, or a torus. A Riemannian manifold structure allows you to do calculus on this sphere and on this torus. So you can measure lengths between two points of the torus. You can find the shortest path between two points. You can integrate integrals on the torus. Etc.

Of course, the space [itex]\mathbb{R}^n[/itex] canonically leads to a Riemannian manifold (as it should). But this manifold is flat. The sphere and the torus have some kind of curvature. A Riemannian manifold allows you to make precise what they mean with curvature.

This is the intuitive idea. That's all I can do right now. If you want more information, then you got to pick up a differential geometry book and read the rigorous definitions and theorems. Once you did that, we can talk further.
 
  • #3
If you have an equation in R^N that gives you a hypersurface. If you have k equations, then you have the intersection of k hypersurfaces which is a surface of dimension N-k. With a couple technical caveats that is what a manifold is (see Whitney and Nash embedding theorems).

A Riemannian manifold is a manifold equipped with a metric. A metric is a function that gives you distances between points. A Riemannian metric is an "infinitesimal" metric. Instead of directly telling you the distances between points, it tells you the lengths of vectors. To measure the length of a curve you integrate the lengths of its tangent vectors. To find the distance between two points you find the shortest curve connecting them. For example the dot product in R^n is an infinitesimal metric because you can calculate vector lengths with it.

There are purely geometric examples of Riemannian manifolds (which you would get in a book on the subject). Here is a physical example. There are lots of ways to measure distances between points. For example, in some medium, you could measure distances by how long it takes an acoustic wave to get from point A to point B. "Infinitesimally" this depends on the wave speed at each point in the medium. The Riemannian metric would be like the reciprocal of that wave speed (like the index of refraction for light). If the medium is isotropic and homogeneous (e.g. a body of water with uniform temperature), you would get a Euclidean metric. If you have a non homogeneous, non isotropic medium then you can get a more complicated metric.
 
  • #4
Manifolds are Sets which have functions that map the manifold to R^n, An example of a manifold could be a 2-sphere in R^3, you would then have a set of functions mapping the manifold to R^2 , essentially "flattening" the manifold. The idea of manifolds is that one can then use the same operations of a normal euclidean space on them. For example, differentiation and integration. Riemann manifolds have a Riemann metric which allows you to measure distance on the manifold. Manifolds and their metrics are used exstensively in general relativity, where they are used to represent curved spacetime, as you can see the metric comes in handy for measuring true distances in curved space.
 
  • #5
A topological manifold is just a topological space with certain required properties (depending on the author / context this could be Hausdorff and second countable for example) and the ubiquitous property of being locally euclidean i.e. every point has a neighborhood with a homeomorphism taking that neighborhood to an open subset of euclidean space; this pair is called a coordinate chart and the set of all coordinate charts on a topological manifold is called an atlas. Because of the locally euclidean property, amongst other things e.g. second countability, manifolds possesses many nice properties such as being locally path connected (which for manifolds is equivalent to being locally connected), sigma compact, and locally compact to name a few.

We can go can an extra mile and demand that the atlas be smooth in the sense that if two coordinate domains happen to over lap, the transition map taking the image of one coordinate domain to the image of the other is smooth in the usual sense of calculus. One usually requires that these smooth atlases be maximal. This then allows us to make unambiguous sense of smoothness of maps by looking at the local coordinate representations on coordinate charts and just talking about calculus in the usual sense in euclidean space. Of particular importance is that now we can make sense of a differentiable curve on a manifold and this is one way to then talk about tangent vectors. We can also go on to define vector fields, covector fields, and tensor fields all of which are, for example, crucially needed objects in physics.

There is another structure we can define on smooth manifolds and this is called an affine connection. Loosely put, it allows us to "relate" vectors at different points on a manifold because, unlike in euclidean space, one cannot simply parallel translate vectors to the same tangent space in a trivial way. Using affine connections, we can talk about a kind of directional derivative along the tangent vector at a point on a curve, called a covariant derivative; using this we can then make sense of what it means to parallel transport a vector along a curve from one tangent space to another. We can also then define an affine geodesics as a curve where the covariant derivative of the tangent vector along itself is zero at every point on the curve.

The final thing we would like to introduce is a riemannian metric. This is a map that assigns to each tangent space at every point an inner product. It is NOT, and I want to really stress NOT, the same thing as the metric from analysis which allows you to measure distances between points in a metric space. A riemannian metric gives you an inner product for each tangent space. Associated with every riemannian metric is a unique, torsion free (meaning covariant derivatives commute on scalar valued functions) connection called a levi - civita connection. Loosely put, the levi civita connection preserves the inner product of two vectors as you parallel transport them along some curve from one tangent space to another. We can use the riemannian metric (also called metric tensor) to define lengths of geodesics and the levi - civita connection to define the riemann curvature tensor (there are other kinds of curvatures we can employ such as Ricci curvature, the scalar curvature associated with the Ricci curvature, sectional curvature etc.).

Putting all these together gives you the framework that Einstein's theory of General Relativity is built on (which was a major, major application of riemannian geometry back in the day) wherein a space - time is a smooth manifold equipped with a pseudo - riemannian (we don't require positive definite) metric. Local experiments done by an observer should be able to recover the laws of special relativity and locally observers cannot detect gravity which manifests itself as the curvature of the manifold. Test particles in free fall (free from all non gravitational interactions) follow geodesics. Manifolds are also very important in classical mechanics where one describes the configuration space of a system by a smooth manifold with a symplectic 2 - form (that is related to the Hamiltonian of the system; the non degenaracy allows us to write down and solve Newton's 2nd law in terms of this Hamiltonian) and the cotangent bundle becomes the phase space. Anyways, I hope you enjoy the subject, it is very very cool! I only know the subject from a physics standpoint but it is all very elegant nonetheless. I'll stop rambling now =D.
 
  • #6
The Riemann metric gives the family of inner products at a point, and in turn gives you the notion of distance on the manifold.
 
  • #7
saminator910 said:
The Riemann metric gives the family of inner products at a point, and in turn gives you the notion of distance on the manifold.
How so? The riemannian metric allows you to calculate the arc lengths of differentiable curves; this is not the same thing that a metric equipped to a metric space does. What notion of distance are you alluding to?
 
  • #9
Yes, you can use the Riemann metric to find geodesics between points, or also lengths of curves, given by [itex]ds^{2}=\sum^{}_{}g_{ab}dx_{a}dx_{b}[/itex] gab is the metric tensor
 

What is a manifold?

A manifold is a mathematical object that is used to describe spaces that are curved, such as the surface of a sphere. It is a generalization of the concept of a plane or a space, and can have any number of dimensions.

What is a Riemannian manifold?

A Riemannian manifold is a type of manifold that is equipped with a Riemannian metric, which is a way of measuring distances and angles on the manifold. This metric allows for the calculation of geometric properties such as curvature and volume.

What is the significance of manifolds in mathematics?

Manifolds are important in mathematics because they provide a way to study and understand curved spaces, which are often encountered in physics and other natural sciences. They also have applications in areas such as differential geometry, topology, and dynamical systems.

How are manifolds different from Euclidean spaces?

Manifolds are different from Euclidean spaces in that they do not have a constant curvature or a well-defined notion of distance and angle. Instead, the properties of a manifold vary from point to point, and the geometry is described by a set of rules that apply locally.

What are some examples of manifolds?

Some examples of manifolds include the surface of a sphere, a torus, a cylinder, and the space we live in (which is a 3-dimensional manifold). Other examples can be found in nature, such as the shape of a DNA molecule or the trajectory of a planet around the sun.

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