Einstein's Theory of General Relativity: Difference between revisions
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Einstein developed a generalized coordinate system and summation notation to simplify his work and create a much more elegant system to describe his ideas. There are four important quantities to understand before tackling the Einstein Field Equations: metric tensor, christoffel symbols, geodesic equation, and the reimann tensor. | Einstein developed a generalized coordinate system and summation notation to simplify his work and create a much more elegant system to describe his ideas. There are four important quantities to understand before tackling the Einstein Field Equations: metric tensor, christoffel symbols, geodesic equation, and the reimann tensor. | ||
Metric Tensor | '''Metric Tensor''' | ||
The metric tensor is a very important mathematical object in general relativity. Much of the information that describes a space is encoded in this | The metric tensor is a very important mathematical object in general relativity. Much of the information that describes a space is encoded in this object. | ||
Christoffel Symbols | A tensor is a multidimensional quantity that describes direction and magnitude in a much more detailed way than a vector. For example, stress in an object is complex and contains many directions of forces at one single point, but by using a stress tensor one may compactly describe a point or even a collection of points. Writing equations in terms of tensors provides a very important quality: a tensor equation that equals zero in one frame of reference will equal zero in all frames of reference. This property provides a means for the study of physical phenomena in any system of coordinates imaginable. | ||
The metric tensor is a subset of a tensor, in that the metric tensor is a generalization of the pythagorean theorem; a differential length is described by the metric tensor using generalized differential coordinates. | |||
A basic example of the metric tensor is the Schwarzschild metric, which was one of the first metrics to be solved from Einstein's equations. The metric describes a simple sphere in spacetime, but despite the relative simplicity of the metric, it presents an interesting topic to study. By using the Schwarzschild metric, one may arrive at singularities, or mathematical points that explode to infinity. At these singularities, black holes are created, and these such points are still the subject of intense research. | |||
'''Christoffel Symbols''' | |||
Christoffel symbols can be loosely thought of as a residual when taking the derivative in a nonlinear coordinate system. If the coordinate system itself depends on a set of parameters, then taking the derivative of a function will not result in a simple derivative. Because of the product rule, there remains a correction term that must be required, and such term is the christoffel symbol. With respect to the metric tensor, the christoffel symbol has a concrete description of the tensor, and represents the correction quantity that must be used to describe geodesics, or shortest paths. | Christoffel symbols can be loosely thought of as a residual when taking the derivative in a nonlinear coordinate system. If the coordinate system itself depends on a set of parameters, then taking the derivative of a function will not result in a simple derivative. Because of the product rule, there remains a correction term that must be required, and such term is the christoffel symbol. With respect to the metric tensor, the christoffel symbol has a concrete description of the tensor, and represents the correction quantity that must be used to describe geodesics, or shortest paths. | ||
Geodesic Equation | '''Geodesic Equation''' | ||
The geodesic equation describes the path a particle takes in a general coordinate system, and it is a generalization of acceleration equations. For flat space, or simple cartesian coordinates, if a particle moves then it must move in a straight line disregarding any external forces, and indeed the geodesic equation resembles newton's second law. However, for curved space, say for example a sphere, the shortest path between to points is actually curved. When massive objects distort spacetime, the geodesic equation is helpful in describing paths particles must take in the distorted coordinate frame. Within the mathematical framework, the geodesic equation employs the christoffel symbol to correct for distortions in spacetime. | The geodesic equation describes the path a particle takes in a general coordinate system, and it is a generalization of acceleration equations. For flat space, or simple cartesian coordinates, if a particle moves then it must move in a straight line disregarding any external forces, and indeed the geodesic equation resembles newton's second law. However, for curved space, say for example a sphere, the shortest path between to points is actually curved. When massive objects distort spacetime, the geodesic equation is helpful in describing paths particles must take in the distorted coordinate frame. Within the mathematical framework, the geodesic equation employs the christoffel symbol to correct for distortions in spacetime. | ||
'''Reimann Tensor''' | |||
Although the geodesic equation can describe motion in curved spacetime, the equation itself is insufficient in describing space. For such a description, one must turn to the Reimann Curvature Tensor. This tensor is one of the most common objects used to describe curved manifolds, and it plays a very important role in the Einstein Field Equations. The Einstein tensor itself contains a derivation of the reimann tensor, the ricci curvature tensor, and is what results from energy and mass tensor quantities. | |||
The tensor is constructed by taking covariant derivatives of the metric, but it can also be rewritten in terms of the christoffel symbol. | |||
===A Computational Model=== | ===A Computational Model=== |
Revision as of 13:39, 4 December 2015
(Created by William Xia)
Einstein's Theory of General Relativity described gravity in the most detailed and accurate way that has ever been described. Multiple observations of the theory has been tested and experimentally verified, and new predictions have been observed through solving the equations in this theory.
The Main Idea
Gravity is the result of energy and matter distorting spacetime. The reason why one follows a curved trajectory when encountering an object in space is because the trajectory follows a least energy path through spacetime. In other words, if the smallest distance between two points in a plane is a straight line, then the smallest distance between two points in spacetime is described by how the object bends spacetime.
Mathematical Framework
Einstein developed a generalized coordinate system and summation notation to simplify his work and create a much more elegant system to describe his ideas. There are four important quantities to understand before tackling the Einstein Field Equations: metric tensor, christoffel symbols, geodesic equation, and the reimann tensor.
Metric Tensor
The metric tensor is a very important mathematical object in general relativity. Much of the information that describes a space is encoded in this object.
A tensor is a multidimensional quantity that describes direction and magnitude in a much more detailed way than a vector. For example, stress in an object is complex and contains many directions of forces at one single point, but by using a stress tensor one may compactly describe a point or even a collection of points. Writing equations in terms of tensors provides a very important quality: a tensor equation that equals zero in one frame of reference will equal zero in all frames of reference. This property provides a means for the study of physical phenomena in any system of coordinates imaginable.
The metric tensor is a subset of a tensor, in that the metric tensor is a generalization of the pythagorean theorem; a differential length is described by the metric tensor using generalized differential coordinates.
A basic example of the metric tensor is the Schwarzschild metric, which was one of the first metrics to be solved from Einstein's equations. The metric describes a simple sphere in spacetime, but despite the relative simplicity of the metric, it presents an interesting topic to study. By using the Schwarzschild metric, one may arrive at singularities, or mathematical points that explode to infinity. At these singularities, black holes are created, and these such points are still the subject of intense research.
Christoffel Symbols
Christoffel symbols can be loosely thought of as a residual when taking the derivative in a nonlinear coordinate system. If the coordinate system itself depends on a set of parameters, then taking the derivative of a function will not result in a simple derivative. Because of the product rule, there remains a correction term that must be required, and such term is the christoffel symbol. With respect to the metric tensor, the christoffel symbol has a concrete description of the tensor, and represents the correction quantity that must be used to describe geodesics, or shortest paths.
Geodesic Equation
The geodesic equation describes the path a particle takes in a general coordinate system, and it is a generalization of acceleration equations. For flat space, or simple cartesian coordinates, if a particle moves then it must move in a straight line disregarding any external forces, and indeed the geodesic equation resembles newton's second law. However, for curved space, say for example a sphere, the shortest path between to points is actually curved. When massive objects distort spacetime, the geodesic equation is helpful in describing paths particles must take in the distorted coordinate frame. Within the mathematical framework, the geodesic equation employs the christoffel symbol to correct for distortions in spacetime.
Reimann Tensor
Although the geodesic equation can describe motion in curved spacetime, the equation itself is insufficient in describing space. For such a description, one must turn to the Reimann Curvature Tensor. This tensor is one of the most common objects used to describe curved manifolds, and it plays a very important role in the Einstein Field Equations. The Einstein tensor itself contains a derivation of the reimann tensor, the ricci curvature tensor, and is what results from energy and mass tensor quantities.
The tensor is constructed by taking covariant derivatives of the metric, but it can also be rewritten in terms of the christoffel symbol.
A Computational Model
Examples
Simple
Middling
Difficult
Connectedness
How is this topic connected to something that you are interested in?
I have always been fascinated by how gravity can be described in a rigorous mathematical sense, and the revolutionary nature of Einstein's work.
How is it connected to your major?
Electrical Engineers, when designing satellites, have to take into account the effects of GR in order to produce accurate time measurements. Recent experiments have also sought to measure minuscule changes in length and time due to gravitational waves and high velocities.
Is there an interesting industrial application?
For now, GR is restricted to mostly space applications. Away from the Earth's gravity, residents or machines orbiting the earth or traveling through space experience different effects on time and space due to fluctuating gravitational fields.
History
Einstein spent nearly 10 years refining his theory before he published his work. 1907,1912
See also
Further reading
External links
References
Einstein, Albert. Relativity: The Special and General Theory. Methuen & Co Ltd, 1916. Print.