Analytical Mechanics
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theoretical physics Theoretical physics is a branch of physics that employs mathematical models and abstractions of physical objects and systems to rationalize, explain and predict natural phenomena. This is in contrast to experimental physics, which uses experim ...
and
mathematical physics Mathematical physics refers to the development of mathematical methods for application to problems in physics. The '' Journal of Mathematical Physics'' defines the field as "the application of mathematics to problems in physics and the developme ...
, analytical mechanics, or theoretical mechanics is a collection of closely related alternative formulations of
classical mechanics Classical mechanics is a physical theory describing the motion of macroscopic objects, from projectiles to parts of machinery, and astronomical objects, such as spacecraft, planets, stars, and galaxies. For objects governed by classi ...
. It was developed by many scientists and mathematicians during the 18th century and onward, after Newtonian mechanics. Since Newtonian mechanics considers
vector Vector most often refers to: *Euclidean vector, a quantity with a magnitude and a direction *Vector (epidemiology), an agent that carries and transmits an infectious pathogen into another living organism Vector may also refer to: Mathematic ...
quantities of motion, particularly
acceleration In mechanics, acceleration is the rate of change of the velocity of an object with respect to time. Accelerations are vector quantities (in that they have magnitude and direction). The orientation of an object's acceleration is given by t ...
s, momenta, forces, of the constituents of the system, an alternative name for the mechanics governed by
Newton's laws Newton's laws of motion are three basic laws of classical mechanics that describe the relationship between the motion of an object and the forces acting on it. These laws can be paraphrased as follows: # A body remains at rest, or in motio ...
and
Euler's laws In classical mechanics, Euler's laws of motion are equations of motion which extend Newton's laws of motion for point particle to rigid body motion. They were formulated by Leonhard Euler about 50 years after Isaac Newton formulated his laws. O ...
is ''vectorial mechanics''. By contrast, analytical mechanics uses '' scalar'' properties of motion representing the system as a whole—usually its total
kinetic energy In physics, the kinetic energy of an object is the energy that it possesses due to its motion. It is defined as the work needed to accelerate a body of a given mass from rest to its stated velocity. Having gained this energy during its acc ...
and potential energy—not Newton's vectorial forces of individual particles. A scalar is a quantity, whereas a vector is represented by quantity and direction. The
equations of motion In physics, equations of motion are equations that describe the behavior of a physical system in terms of its motion as a function of time.''Encyclopaedia of Physics'' (second Edition), R.G. Lerner, G.L. Trigg, VHC Publishers, 1991, ISBN (Ver ...
are derived from the scalar quantity by some underlying principle about the scalar's variation. Analytical mechanics takes advantage of a system's ''constraints'' to solve problems. The constraints limit the degrees of freedom the system can have, and can be used to reduce the number of coordinates needed to solve for the motion. The formalism is well suited to arbitrary choices of coordinates, known in the context as
generalized coordinates In analytical mechanics, generalized coordinates are a set of parameters used to represent the state of a system in a configuration space. These parameters must uniquely define the configuration of the system relative to a reference state.,p. 39 ...
. The kinetic and potential energies of the system are expressed using these generalized coordinates or momenta, and the equations of motion can be readily set up, thus analytical mechanics allows numerous mechanical problems to be solved with greater efficiency than fully vectorial methods. It does not always work for non-
conservative force In physics, a conservative force is a force with the property that the total work done in moving a particle between two points is independent of the path taken. Equivalently, if a particle travels in a closed loop, the total work done (the sum ...
s or dissipative forces like
friction Friction is the force resisting the relative motion of solid surfaces, fluid layers, and material elements sliding against each other. There are several types of friction: *Dry friction is a force that opposes the relative lateral motion of ...
, in which case one may revert to Newtonian mechanics. Two dominant branches of analytical mechanics are
Lagrangian mechanics In physics, Lagrangian mechanics is a formulation of classical mechanics founded on the stationary-action principle (also known as the principle of least action). It was introduced by the Italian-French mathematician and astronomer Joseph- ...
(using generalized coordinates and corresponding generalized velocities in configuration space) and
Hamiltonian mechanics Hamiltonian mechanics emerged in 1833 as a reformulation of Lagrangian mechanics. Introduced by Sir William Rowan Hamilton, Hamiltonian mechanics replaces (generalized) velocities \dot q^i used in Lagrangian mechanics with (generalized) ''momenta ...
(using coordinates and corresponding momenta in phase space). Both formulations are equivalent by a
Legendre transformation In mathematics, the Legendre transformation (or Legendre transform), named after Adrien-Marie Legendre, is an involutive transformation on real-valued convex functions of one real variable. In physical problems, it is used to convert functions ...
on the generalized coordinates, velocities and momenta, therefore both contain the same information for describing the dynamics of a system. There are other formulations such as Hamilton–Jacobi theory,
Routhian mechanics alt= In classical mechanics, Routh's procedure or Routhian mechanics is a hybrid formulation of Lagrangian mechanics and Hamiltonian mechanics developed by Edward John Routh. Correspondingly, the Routhian is the function which replaces both the ...
, and
Appell's equation of motion In classical mechanics, Appell's equation of motion (aka the Gibbs–Appell equation of motion) is an alternative general formulation of classical mechanics described by Josiah Willard Gibbs in 1879 and Paul Émile Appell in 1900. Statement T ...
. All equations of motion for particles and fields, in any formalism, can be derived from the widely applicable result called the
principle of least action The stationary-action principle – also known as the principle of least action – is a variational principle that, when applied to the '' action'' of a mechanical system, yields the equations of motion for that system. The principle states tha ...
. One result is
Noether's theorem Noether's theorem or Noether's first theorem states that every differentiable symmetry of the action of a physical system with conservative forces has a corresponding conservation law. The theorem was proven by mathematician Emmy Noether ...
, a statement which connects conservation laws to their associated
symmetries Symmetry (from grc, συμμετρία "agreement in dimensions, due proportion, arrangement") in everyday language refers to a sense of harmonious and beautiful proportion and balance. In mathematics, "symmetry" has a more precise definiti ...
. Analytical mechanics does not introduce new physics and is not more general than Newtonian mechanics. Rather it is a collection of equivalent formalisms which have broad application. In fact the same principles and formalisms can be used in
relativistic mechanics In physics, relativistic mechanics refers to mechanics compatible with special relativity (SR) and general relativity (GR). It provides a non-quantum mechanical description of a system of particles, or of a fluid, in cases where the velocities of ...
and
general relativity General relativity, also known as the general theory of relativity and Einstein's theory of gravity, is the geometric theory of gravitation published by Albert Einstein in 1915 and is the current description of gravitation in modern physics ...
, and with some modifications,
quantum mechanics Quantum mechanics is a fundamental theory in physics that provides a description of the physical properties of nature at the scale of atoms and subatomic particles. It is the foundation of all quantum physics including quantum chemistr ...
and quantum field theory. Analytical mechanics is used widely, from fundamental physics to
applied mathematics Applied mathematics is the application of mathematical methods by different fields such as physics, engineering, medicine, biology, finance, business, computer science, and industry. Thus, applied mathematics is a combination of mathemati ...
, particularly chaos theory. The methods of analytical mechanics apply to discrete particles, each with a finite number of degrees of freedom. They can be modified to describe continuous fields or fluids, which have infinite degrees of freedom. The definitions and equations have a close analogy with those of mechanics.


Subject of analytical mechanics

The most obvious goal of mechanical theory is to solve mechanical problems which arise in physics or astronomy. Starting from a physical concept, such as a mechanism or a star system, a mathematical concept, or
model A model is an informative representation of an object, person or system. The term originally denoted the plans of a building in late 16th-century English, and derived via French and Italian ultimately from Latin ''modulus'', a measure. Models c ...
, is developed in the form of a differential equation or equations and then an attempt is made to solve them. The vectorial approach to mechanics, as founded by Newton, is based on the Newton's laws which describe motion with the help of
vector Vector most often refers to: *Euclidean vector, a quantity with a magnitude and a direction *Vector (epidemiology), an agent that carries and transmits an infectious pathogen into another living organism Vector may also refer to: Mathematic ...
quantities such as force,
velocity Velocity is the directional speed of an object in motion as an indication of its rate of change in position as observed from a particular frame of reference and as measured by a particular standard of time (e.g. northbound). Velocity i ...
,
acceleration In mechanics, acceleration is the rate of change of the velocity of an object with respect to time. Accelerations are vector quantities (in that they have magnitude and direction). The orientation of an object's acceleration is given by t ...
. These quantities characterise the
motion In physics, motion is the phenomenon in which an object changes its position with respect to time. Motion is mathematically described in terms of displacement, distance, velocity, acceleration, speed and frame of reference to an observer and mea ...
of a body which is idealised as a "mass point" or a "
particle In the physical sciences, a particle (or corpuscule in older texts) is a small localized object which can be described by several physical or chemical properties, such as volume, density, or mass. They vary greatly in size or quantity, from ...
" understood as a single point to which a mass is attached. Newton's method was successful and was applied to a wide range of physical problems, starting from the motion of a particle in the gravitational field of
Earth Earth is the third planet from the Sun and the only astronomical object known to harbor life. While large volumes of water can be found throughout the Solar System, only Earth sustains liquid surface water. About 71% of Earth's surfa ...
and then extended to the motion of planets under the action of the sun. In this approach, Newton's laws describe the motion by a differential equation and then the problem is reduced to the solving of that equation. When the particle is a part of a system of particles, such as a solid body or a fluid, in which particles do not move freely but interact with each other, the Newton's approach is still applicable under proper precautions such as isolating each single particle from the others, and determining all the forces acting on it: those acting on the system as a whole as well as the forces of interaction of each particle with all other particles in the system. Such analysis can become cumbersome even in relatively simple systems. As a rule, interaction forces are unknown or hard to determine making it necessary to introduce new postulates. Newton thought that his third law "action equals reaction" would take care of all complications. This is not the case even for such simple system as rotations of a solid body. In more complicated systems, the vectorial approach cannot give an adequate description. The analytical approach to the problem of motion views the particle not as an isolated unit but as a part of a mechanical system understood as an assembly of particles that interact with each other. As the whole system comes into consideration, the single particle loses its significance; the dynamical problem involves the entire system without breaking it in parts. This significantly simplifies the calculation because in the vectorial approach the forces have to be determined individually for each particle while in the analytical approach it is enough to know one single function which contains implicitly all the forces acting on and in the system. Such simplification is often done using certain kinematical conditions which are stated a priori; they are pre-existing and are due to the action of some strong forces. However, the analytical treatment does not require the knowledge of these forces and takes these kinematic conditions for granted. Considering how much simpler are these conditions in comparison with the multitude of forces that maintain them, the superiority of the analytical approach over the vectorial one becomes apparent. Still, the equations of motion of a complicated mechanical system require a great number of separate differential equations which cannot be derived without some unifying basis from which they follow. This basis are the
variational principle In science and especially in mathematical studies, a variational principle is one that enables a problem to be solved using calculus of variations, which concerns finding functions that optimize the values of quantities that depend on those funct ...
s: behind each set of equations there is a principle that expresses the meaning of the entire set. Given a fundamental and universal quantity called 'action', the principle that this action be stationary under small variation of some other mechanical quantity generates the required set of differential equations. The statement of the principle does not require any special coordinate system, and all results are expressed in
generalized coordinates In analytical mechanics, generalized coordinates are a set of parameters used to represent the state of a system in a configuration space. These parameters must uniquely define the configuration of the system relative to a reference state.,p. 39 ...
. This means that the analytical equations of motion do not change upon a
coordinate transformation In geometry, a coordinate system is a system that uses one or more numbers, or coordinates, to uniquely determine the position of the points or other geometric elements on a manifold such as Euclidean space. The order of the coordinates is sign ...
, an invariance property that is lacking in the vectorial equations of motion. It is not altogether clear what is meant by 'solving' a set of differential equations. A problem is regarded as solved when the particles coordinates at time ''t'' are expressed as simple functions of ''t'' and of parameters defining the initial positions and velocities. However, 'simple function' is not a
well-defined In mathematics, a well-defined expression or unambiguous expression is an expression whose definition assigns it a unique interpretation or value. Otherwise, the expression is said to be ''not well defined'', ill defined or ''ambiguous''. A func ...
concept: nowadays, a
function Function or functionality may refer to: Computing * Function key, a type of key on computer keyboards * Function model, a structured representation of processes in a system * Function object or functor or functionoid, a concept of object-oriente ...
''f''(''t'') is not regarded as a formal expression in ''t'' (
elementary function In mathematics, an elementary function is a function of a single variable (typically real or complex) that is defined as taking sums, products, roots and compositions of finitely many polynomial, rational, trigonometric, hyperbolic, and ...
) as in the time of Newton but most generally as a quantity determined by ''t'', and it is not possible to draw a sharp line between 'simple' and 'not simple' functions. If one speaks merely of 'functions', then every mechanical problem is solved as soon as it has been well stated in differential equations, because given the initial conditions and ''t'' determine the coordinates at ''t''. This is a fact especially at present with the modern methods of
computer modelling Computer simulation is the process of mathematical modelling, performed on a computer, which is designed to predict the behaviour of, or the outcome of, a real-world or physical system. The reliability of some mathematical models can be det ...
which provide arithmetical solutions to mechanical problems to any desired degree of accuracy, the
differential equation In mathematics, a differential equation is an equation that relates one or more unknown functions and their derivatives. In applications, the functions generally represent physical quantities, the derivatives represent their rates of change, an ...
s being replaced by difference equations. Still, though lacking precise definitions, it is obvious that the
two-body problem In classical mechanics, the two-body problem is to predict the motion of two massive objects which are abstractly viewed as point particles. The problem assumes that the two objects interact only with one another; the only force affecting each ...
has a simple solution, whereas the
three-body problem In physics and classical mechanics, the three-body problem is the problem of taking the initial positions and velocities (or momenta) of three point masses and solving for their subsequent motion according to Newton's laws of motion and Newton's ...
has not. The two-body problem is solved by formulas involving parameters; their values can be changed to study the class of all solutions, that is, the mathematical structure of the problem. Moreover, an accurate mental or drawn picture can be made for the motion of two bodies, and it can be as real and accurate as the real bodies moving and interacting. In the three-body problem, parameters can also be assigned specific values; however, the solution at these assigned values or a collection of such solutions does not reveal the mathematical structure of the problem. As in many other problems, the mathematical structure can be elucidated only by examining the differential equations themselves. Analytical mechanics aims at even more: not at understanding the mathematical structure of a single mechanical problem, but that of a class of problems so wide that they encompass most of mechanics. It concentrates on systems to which Lagrangian or Hamiltonian equations of motion are applicable and that include a very wide range of problems indeed. Development of analytical mechanics has two objectives: (i) increase the range of solvable problems by developing standard techniques with a wide range of applicability, and (ii) understand the mathematical structure of mechanics. In the long run, however, (ii) can help (i) more than a concentration on specific problems for which methods have already been designed.


Intrinsic motion


Generalized coordinates In analytical mechanics, generalized coordinates are a set of parameters used to represent the state of a system in a configuration space. These parameters must uniquely define the configuration of the system relative to a reference state.,p. 39 ...
and constraints

In Newtonian mechanics, one customarily uses all three Cartesian coordinates, or other 3D coordinate system, to refer to a body's
position Position often refers to: * Position (geometry), the spatial location (rather than orientation) of an entity * Position, a job or occupation Position may also refer to: Games and recreation * Position (poker), location relative to the dealer * ...
during its motion. In physical systems, however, some structure or other system usually constrains the body's motion from taking certain directions and pathways. So a full set of Cartesian coordinates is often unneeded, as the constraints determine the evolving relations among the coordinates, which relations can be modeled by equations corresponding to the constraints. In the Lagrangian and Hamiltonian formalisms, the constraints are incorporated into the motion's geometry, reducing the number of coordinates to the minimum needed to model the motion. These are known as ''generalized coordinates'', denoted ''qi'' (''i'' = 1, 2, 3...).


Difference between curvillinear and

generalized coordinates In analytical mechanics, generalized coordinates are a set of parameters used to represent the state of a system in a configuration space. These parameters must uniquely define the configuration of the system relative to a reference state.,p. 39 ...

Generalized coordinates incorporate constraints on the system. There is one generalized coordinate ''qi'' for each
degree of freedom Degrees of freedom (often abbreviated df or DOF) refers to the number of independent variables or parameters of a thermodynamic system. In various scientific fields, the word "freedom" is used to describe the limits to which physical movement or ...
(for convenience labelled by an index ''i'' = 1, 2...''N''), i.e. each way the system can change its configuration; as curvilinear lengths or angles of rotation. Generalized coordinates are not the same as curvilinear coordinates. The number of ''curvilinear'' coordinates equals the
dimension In physics and mathematics, the dimension of a mathematical space (or object) is informally defined as the minimum number of coordinates needed to specify any point within it. Thus, a line has a dimension of one (1D) because only one coor ...
of the position space in question (usually 3 for 3d space), while the number of ''generalized'' coordinates is not necessarily equal to this dimension; constraints can reduce the number of degrees of freedom (hence the number of generalized coordinates required to define the configuration of the system), following the general rule:''Analytical Mechanics'', L.N. Hand, J.D. Finch, Cambridge University Press, 2008, For a system with ''N'' degrees of freedom, the generalized coordinates can be collected into an ''N''-
tuple In mathematics, a tuple is a finite ordered list (sequence) of elements. An -tuple is a sequence (or ordered list) of elements, where is a non-negative integer. There is only one 0-tuple, referred to as ''the empty tuple''. An -tuple is defi ...
: \mathbf = (q_1, q_2, \dots, q_N) and the
time derivative A time derivative is a derivative of a function with respect to time, usually interpreted as the rate of change of the value of the function. The variable denoting time is usually written as t. Notation A variety of notations are used to denote th ...
(here denoted by an overdot) of this tuple give the ''generalized velocities'': \frac = \left(\frac, \frac, \dots, \frac\right) \equiv \mathbf = (\dot_1, \dot_2, \dots, \dot_N) .


D'Alembert's principle D'Alembert's principle, also known as the Lagrange–d'Alembert principle, is a statement of the fundamental classical laws of motion. It is named after its discoverer, the French physicist and mathematician Jean le Rond d'Alembert. D'Alembert ...

The foundation which the subject is built on is ''D'Alembert's principle''. This principle states that infinitesimal ''
virtual work In mechanics, virtual work arises in the application of the ''principle of least action'' to the study of forces and movement of a mechanical system. The work of a force acting on a particle as it moves along a displacement is different for ...
'' done by a force across reversible displacements is zero, which is the work done by a force consistent with ideal constraints of the system. The idea of a constraint is useful - since this limits what the system can do, and can provide steps to solving for the motion of the system. The equation for D'Alembert's principle is: \delta W = \boldsymbol \cdot \delta\mathbf = 0 \,, where \boldsymbol\mathcal = (\mathcal_1, \mathcal_2, \dots, \mathcal_N) are the
generalized forces Generalized forces find use in Lagrangian mechanics, where they play a role conjugate to generalized coordinates. They are obtained from the applied forces, Fi, i=1,..., n, acting on a system that has its configuration defined in terms of generaliz ...
(script Q instead of ordinary Q is used here to prevent conflict with canonical transformations below) and are the generalized coordinates. This leads to the generalized form of
Newton's laws Newton's laws of motion are three basic laws of classical mechanics that describe the relationship between the motion of an object and the forces acting on it. These laws can be paraphrased as follows: # A body remains at rest, or in motio ...
in the language of analytical mechanics: \boldsymbol\mathcal = \frac \left ( \frac \right ) - \frac \,, where ''T'' is the total
kinetic energy In physics, the kinetic energy of an object is the energy that it possesses due to its motion. It is defined as the work needed to accelerate a body of a given mass from rest to its stated velocity. Having gained this energy during its acc ...
of the system, and the notation \frac = \left(\frac, \frac, \dots, \frac\right) is a useful shorthand (see
matrix calculus In mathematics, matrix calculus is a specialized notation for doing multivariable calculus, especially over spaces of matrices. It collects the various partial derivatives of a single function with respect to many variables, and/or of a ...
for this notation).


Holonomic constraints In classical mechanics, holonomic constraints are relations between the position variables (and possibly time) that can be expressed in the following form: :f(u_1, u_2, u_3,\ldots, u_n, t) = 0 where \ are the ''n'' generalized coordinates that d ...

If the curvilinear coordinate system is defined by the standard position vector , and if the position vector can be written in terms of the generalized coordinates and time in the form: \mathbf = \mathbf(\mathbf(t),t) and this relation holds for all times , then are called ''Holonomic constraints''. Vector is explicitly dependent on in cases when the constraints vary with time, not just because of . For time-independent situations, the constraints are also called
scleronomic A mechanical system is scleronomous if the equations of constraints do not contain the time as an explicit variable and the equation of constraints can be described by generalized coordinates. Such constraints are called scleronomic constraints. ...
, for time-dependent cases they are called rheonomic.


Lagrangian mechanics

Lagrangian Lagrangian may refer to: Mathematics * Lagrangian function, used to solve constrained minimization problems in optimization theory; see Lagrange multiplier ** Lagrangian relaxation, the method of approximating a difficult constrained problem with ...
and Euler–Lagrange equations The introduction of generalized coordinates and the fundamental Lagrangian function: :L(\mathbf,\mathbf,t) = T(\mathbf,\mathbf,t) - V(\mathbf,\mathbf,t) where ''T'' is the total
kinetic energy In physics, the kinetic energy of an object is the energy that it possesses due to its motion. It is defined as the work needed to accelerate a body of a given mass from rest to its stated velocity. Having gained this energy during its acc ...
and ''V'' is the total potential energy of the entire system, then either following the calculus of variations or using the above formula - lead to the Euler–Lagrange equations; :\frac\left(\frac\right) = \frac \,, which are a set of ''N'' second-order
ordinary differential equation In mathematics, an ordinary differential equation (ODE) is a differential equation whose unknown(s) consists of one (or more) function(s) of one variable and involves the derivatives of those functions. The term ''ordinary'' is used in contrast ...
s, one for each ''qi''(''t''). This formulation identifies the actual path followed by the motion as a selection of the path over which the
time integral In mathematics, an integral assigns numbers to functions in a way that describes displacement, area, volume, and other concepts that arise by combining infinitesimal data. The process of finding integrals is called integration. Along with d ...
of
kinetic energy In physics, the kinetic energy of an object is the energy that it possesses due to its motion. It is defined as the work needed to accelerate a body of a given mass from rest to its stated velocity. Having gained this energy during its acc ...
is least, assuming the total energy to be fixed, and imposing no conditions on the time of transit. Configuration space The Lagrangian formulation uses the configuration space of the system, the
set Set, The Set, SET or SETS may refer to: Science, technology, and mathematics Mathematics *Set (mathematics), a collection of elements *Category of sets, the category whose objects and morphisms are sets and total functions, respectively Electro ...
of all possible generalized coordinates: :\mathcal = \\,, where \mathbb^N is ''N''-dimensional
real Real may refer to: Currencies * Brazilian real (R$) * Central American Republic real * Mexican real * Portuguese real * Spanish real * Spanish colonial real Music Albums * ''Real'' (L'Arc-en-Ciel album) (2000) * ''Real'' (Bright album) (2010) ...
space (see also set-builder notation). The particular solution to the Euler–Lagrange equations is called a ''(configuration) path or trajectory'', i.e. one particular q(''t'') subject to the required
initial conditions In mathematics and particularly in dynamic systems, an initial condition, in some contexts called a seed value, is a value of an evolving variable at some point in time designated as the initial time (typically denoted ''t'' = 0). For ...
. The general solutions form a set of possible configurations as functions of time: :\\subseteq\mathcal\,, The configuration space can be defined more generally, and indeed more deeply, in terms of
topological In mathematics, topology (from the Greek words , and ) is concerned with the properties of a geometric object that are preserved under continuous deformations, such as stretching, twisting, crumpling, and bending; that is, without closing ...
manifold In mathematics, a manifold is a topological space that locally resembles Euclidean space near each point. More precisely, an n-dimensional manifold, or ''n-manifold'' for short, is a topological space with the property that each point has a n ...
s and the
tangent bundle In differential geometry, the tangent bundle of a differentiable manifold M is a manifold TM which assembles all the tangent vectors in M . As a set, it is given by the disjoint unionThe disjoint union ensures that for any two points and of ...
.


Hamiltonian mechanics

Hamiltonian and Hamilton's equations The
Legendre transformation In mathematics, the Legendre transformation (or Legendre transform), named after Adrien-Marie Legendre, is an involutive transformation on real-valued convex functions of one real variable. In physical problems, it is used to convert functions ...
of the Lagrangian replaces the generalized coordinates and velocities (q, q̇) with (q, p); the generalized coordinates and the '' generalized momenta'' conjugate to the generalized coordinates: :\mathbf = \frac = \left(\frac,\frac,\cdots \frac\right) = (p_1, p_2\cdots p_N)\,, and introduces the Hamiltonian (which is in terms of generalized coordinates and momenta): :H(\mathbf,\mathbf,t) = \mathbf\cdot\mathbf - L(\mathbf,\mathbf,t) where • denotes the
dot product In mathematics, the dot product or scalar productThe term ''scalar product'' means literally "product with a scalar as a result". It is also used sometimes for other symmetric bilinear forms, for example in a pseudo-Euclidean space. is an alge ...
, also leading to
Hamilton's equations Hamiltonian mechanics emerged in 1833 as a reformulation of Lagrangian mechanics. Introduced by Sir William Rowan Hamilton, Hamiltonian mechanics replaces (generalized) velocities \dot q^i used in Lagrangian mechanics with (generalized) ''momenta ...
: :\mathbf = - \frac\,,\quad \mathbf = + \frac \,, which are now a set of 2''N'' first-order ordinary differential equations, one for each ''qi''(''t'') and ''pi''(''t''). Another result from the Legendre transformation relates the time derivatives of the Lagrangian and Hamiltonian: :\frac=-\frac\,, which is often considered one of Hamilton's equations of motion additionally to the others. The generalized momenta can be written in terms of the generalized forces in the same way as Newton's second law: :\mathbf = \boldsymbol\,. Generalized
momentum space In physics and geometry, there are two closely related vector spaces, usually three-dimensional but in general of any finite dimension. Position space (also real space or coordinate space) is the set of all ''position vectors'' r in space, and h ...
Analogous to the configuration space, the set of all momenta is the ''momentum space'' (technically in this context; ''generalized momentum space''): :\mathcal = \\,. "Momentum space" also refers to "k-space"; the set of all
wave vector In physics, a wave vector (or wavevector) is a vector used in describing a wave, with a typical unit being cycle per metre. It has a magnitude and direction. Its magnitude is the wavenumber of the wave (inversely proportional to the wavelength), ...
s (given by
De Broglie relation Matter waves are a central part of the theory of quantum mechanics, being an example of wave–particle duality. All matter exhibits wave-like behavior. For example, a beam of electrons can be diffracted just like a beam of light or a water wave ...
s) as used in quantum mechanics and theory of
wave In physics, mathematics, and related fields, a wave is a propagating dynamic disturbance (change from equilibrium) of one or more quantities. Waves can be periodic, in which case those quantities oscillate repeatedly about an equilibrium (re ...
s: this is not referred to in this context. Phase space The set of all positions and momenta form the ''phase space''; :\mathcal = \mathcal\times\mathcal = \ \,, that is, the Cartesian product × of the configuration space and generalized momentum space. A particular solution to Hamilton's equations is called a '' phase path'', a particular curve (q(''t''),p(''t'')) subject to the required initial conditions. The set of all phase paths, the general solution to the differential equations, is the ''
phase portrait A phase portrait is a geometric representation of the trajectories of a dynamical system in the phase plane. Each set of initial conditions is represented by a different curve, or point. Phase portraits are an invaluable tool in studying dyn ...
'': :\ \subseteq \mathcal\,, ;The Poisson bracket All dynamical variables can be derived from position r, momentum p, and time ''t'', and written as a function of these: ''A'' = ''A''(q, p, ''t''). If ''A''(q, p, ''t'') and ''B''(q, p, ''t'') are two scalar valued dynamical variables, the ''Poisson bracket'' is defined by the generalized coordinates and momenta: : \begin \ \equiv \_ & = \frac\cdot\frac - \frac\cdot\frac\\ & \equiv \sum_k \frac\frac - \frac\frac\,, \end Calculating the
total derivative In mathematics, the total derivative of a function at a point is the best linear approximation near this point of the function with respect to its arguments. Unlike partial derivatives, the total derivative approximates the function with res ...
of one of these, say ''A'', and substituting Hamilton's equations into the result leads to the time evolution of ''A'': : \frac = \ + \frac\,. This equation in ''A'' is closely related to the equation of motion in the
Heisenberg picture In physics, the Heisenberg picture (also called the Heisenberg representation) is a formulation (largely due to Werner Heisenberg in 1925) of quantum mechanics in which the operators (observables and others) incorporate a dependency on time, but ...
of
quantum mechanics Quantum mechanics is a fundamental theory in physics that provides a description of the physical properties of nature at the scale of atoms and subatomic particles. It is the foundation of all quantum physics including quantum chemistr ...
, in which classical dynamical variables become quantum operators (indicated by hats (^)), and the Poisson bracket is replaced by the commutator of operators via Dirac's canonical quantization: :\ \rightarrow \frac hat,\hat,.


Properties of the Lagrangian and Hamiltonian functions

Following are overlapping properties between the Lagrangian and Hamiltonian functions. * All the individual generalized coordinates ''qi''(''t''), velocities ''q̇i''(''t'') and momenta ''pi''(''t'') for every degree of freedom are mutually independent. Explicit time-dependence of a function means the function actually includes time ''t'' as a variable in addition to the q(''t''), p(''t''), not simply as a parameter through q(''t'') and p(''t''), which would mean explicit time-independence. * The Lagrangian is invariant under addition of the '' total''
time derivative A time derivative is a derivative of a function with respect to time, usually interpreted as the rate of change of the value of the function. The variable denoting time is usually written as t. Notation A variety of notations are used to denote th ...
of any function of q and ''t'', that is: L' = L +\fracF(\mathbf,t) \,, so each Lagrangian ''L'' and ''L describe ''exactly the same motion''. In other words, the Lagrangian of a system is not unique. * Analogously, the Hamiltonian is invariant under addition of the ''
partial Partial may refer to: Mathematics * Partial derivative, derivative with respect to one of several variables of a function, with the other variables held constant ** ∂, a symbol that can denote a partial derivative, sometimes pronounced "partial ...
'' time derivative of any function of q, p and ''t'', that is: K = H + \fracG(\mathbf,\mathbf,t) \,, (''K'' is a frequently used letter in this case). This property is used in
canonical transformations In Hamiltonian mechanics, a canonical transformation is a change of canonical coordinates that preserves the form of Hamilton's equations. This is sometimes known as form invariance. It need not preserve the form of the Hamiltonian itself. Canoni ...
(see below). *If the Lagrangian is independent of some generalized coordinates, then the generalized momenta conjugate to those coordinates are constants of the motion, i.e. are conserved, this immediately follows from Lagrange's equations: \frac=0\,\rightarrow \,\frac = \frac \frac=0 Such coordinates are "
cyclic Cycle, cycles, or cyclic may refer to: Anthropology and social sciences * Cyclic history, a theory of history * Cyclical theory, a theory of American political history associated with Arthur Schlesinger, Sr. * Social cycle, various cycles in s ...
" or "ignorable". It can be shown that the Hamiltonian is also cyclic in exactly the same generalized coordinates. *If the Lagrangian is time-independent the Hamiltonian is also time-independent (i.e. both are constant in time). *If the kinetic energy is a homogeneous function of degree 2 of the generalized velocities, ''and'' the Lagrangian is explicitly time-independent, then: T((\lambda \dot_i)^2, (\lambda \dot_j \lambda \dot_k), \mathbf) = \lambda^2 T((\dot_i)^2, \dot_j\dot_k, \mathbf)\,,\quad L(\mathbf,\mathbf)\,, where ''λ'' is a constant, then the Hamiltonian will be the ''total conserved energy'', equal to the total kinetic and potential energies of the system: H = T + V = E\,. This is the basis for the
Schrödinger equation The Schrödinger equation is a linear partial differential equation that governs the wave function of a quantum-mechanical system. It is a key result in quantum mechanics, and its discovery was a significant landmark in the development of th ...
, inserting quantum operators directly obtains it.


Principle of least action

Action Action may refer to: * Action (narrative), a literary mode * Action fiction, a type of genre fiction * Action game, a genre of video game Film * Action film, a genre of film * ''Action'' (1921 film), a film by John Ford * ''Action'' (1980 fil ...
is another quantity in analytical mechanics defined as a functional of the Lagrangian: :\mathcal = \int_^ L(\mathbf,\mathbf,t) dt \,. A general way to find the equations of motion from the action is the ''
principle of least action The stationary-action principle – also known as the principle of least action – is a variational principle that, when applied to the '' action'' of a mechanical system, yields the equations of motion for that system. The principle states tha ...
'': :\delta\mathcal = \delta\int_^ L(\mathbf,\mathbf,t) dt = 0\,, where the departure ''t''1 and arrival ''t''2 times are fixed. The term "path" or "trajectory" refers to the
time evolution Time evolution is the change of state brought about by the passage of time, applicable to systems with internal state (also called ''stateful systems''). In this formulation, ''time'' is not required to be a continuous parameter, but may be disc ...
of the system as a path through configuration space \mathcal, in other words q(''t'') tracing out a path in \mathcal. The path for which action is least is the path taken by the system. From this principle, ''all''
equations of motion In physics, equations of motion are equations that describe the behavior of a physical system in terms of its motion as a function of time.''Encyclopaedia of Physics'' (second Edition), R.G. Lerner, G.L. Trigg, VHC Publishers, 1991, ISBN (Ver ...
in classical mechanics can be derived. This approach can be extended to fields rather than a system of particles (see below), and underlies the
path integral formulation The path integral formulation is a description in quantum mechanics that generalizes the action principle of classical mechanics. It replaces the classical notion of a single, unique classical trajectory for a system with a sum, or functional i ...
of
quantum mechanics Quantum mechanics is a fundamental theory in physics that provides a description of the physical properties of nature at the scale of atoms and subatomic particles. It is the foundation of all quantum physics including quantum chemistr ...
,''Quantum Mechanics'', E. Abers, Pearson Ed., Addison Wesley, Prentice Hall Inc, 2004, Quantum Field Theory, D. McMahon, Mc Graw Hill (US), 2008, and is used for calculating geodesic motion in
general relativity General relativity, also known as the general theory of relativity and Einstein's theory of gravity, is the geometric theory of gravitation published by Albert Einstein in 1915 and is the current description of gravitation in modern physics ...
.


Hamiltonian-Jacobi mechanics

;
Canonical transformations In Hamiltonian mechanics, a canonical transformation is a change of canonical coordinates that preserves the form of Hamilton's equations. This is sometimes known as form invariance. It need not preserve the form of the Hamiltonian itself. Canoni ...
The invariance of the Hamiltonian (under addition of the partial time derivative of an arbitrary function of p, q, and ''t'') allows the Hamiltonian in one set of coordinates q and momenta p to be transformed into a new set Q = Q(q, p, ''t'') and P = P(q, p, ''t''), in four possible ways: :\begin & K(\mathbf,\mathbf,t) = H(\mathbf,\mathbf,t) + \fracG_1 (\mathbf,\mathbf,t)\\ & K(\mathbf,\mathbf,t) = H(\mathbf,\mathbf,t) + \fracG_2 (\mathbf,\mathbf,t)\\ & K(\mathbf,\mathbf,t) = H(\mathbf,\mathbf,t) + \fracG_3 (\mathbf,\mathbf,t)\\ & K(\mathbf,\mathbf,t) = H(\mathbf,\mathbf,t) + \fracG_4 (\mathbf,\mathbf,t)\\ \end With the restriction on P and Q such that the transformed Hamiltonian system is: :\mathbf = - \frac\,,\quad \mathbf = + \frac \,, the above transformations are called ''canonical transformations'', each function ''Gn'' is called a
generating function In mathematics, a generating function is a way of encoding an infinite sequence of numbers () by treating them as the coefficients of a formal power series. This series is called the generating function of the sequence. Unlike an ordinary seri ...
of the "''n''th kind" or "type-''n''". The transformation of coordinates and momenta can allow simplification for solving Hamilton's equations for a given problem. The choice of Q and P is completely arbitrary, but not every choice leads to a canonical transformation. One simple criterion for a transformation q → Q and p → P to be canonical is the Poisson bracket be unity, :\ = 1 for all ''i'' = 1, 2,...''N''. If this does not hold then the transformation is not canonical. ;The
Hamilton–Jacobi equation In physics, the Hamilton–Jacobi equation, named after William Rowan Hamilton and Carl Gustav Jacob Jacobi, is an alternative formulation of classical mechanics, equivalent to other formulations such as Newton's laws of motion, Lagrangian mecha ...
By setting the canonically transformed Hamiltonian ''K'' = 0, and the type-2 generating function equal to Hamilton's principal function (also the action \mathcal) plus an arbitrary constant ''C'': :G_2(\mathbf,t) = \mathcal(\mathbf,t) + C\,, the generalized momenta become: :\mathbf = \frac and P is constant, then the Hamiltonian-Jacobi equation (HJE) can be derived from the type-2 canonical transformation: :H = - \frac where ''H'' is the Hamiltonian as before: :H = H(\mathbf,\mathbf,t) = H\left(\mathbf,\frac,t\right) Another related function is Hamilton's characteristic function :W(\mathbf)=\mathcal(\mathbf,t) + Et used to solve the HJE by additive separation of variables for a time-independent Hamiltonian ''H''. The study of the solutions of the Hamilton–Jacobi equations leads naturally to the study of symplectic manifolds and
symplectic topology Symplectic geometry is a branch of differential geometry and differential topology that studies symplectic manifolds; that is, differentiable manifolds equipped with a closed, nondegenerate 2-form. Symplectic geometry has its origins in the Ha ...
. In this formulation, the solutions of the Hamilton–Jacobi equations are the
integral curve In mathematics, an integral curve is a parametric curve that represents a specific solution to an ordinary differential equation or system of equations. Name Integral curves are known by various other names, depending on the nature and interpret ...
s of
Hamiltonian vector field In mathematics and physics, a Hamiltonian vector field on a symplectic manifold is a vector field defined for any energy function or Hamiltonian. Named after the physicist and mathematician Sir William Rowan Hamilton, a Hamiltonian vector field is ...
s.


Routhian mechanics

Routhian mechanics alt= In classical mechanics, Routh's procedure or Routhian mechanics is a hybrid formulation of Lagrangian mechanics and Hamiltonian mechanics developed by Edward John Routh. Correspondingly, the Routhian is the function which replaces both the ...
is a hybrid formulation of Lagrangian and Hamiltonian mechanics, not often used but especially useful for removing cyclic coordinates. If the Lagrangian of a system has ''s'' cyclic coordinates q = ''q''1, ''q''2, ... ''qs'' with conjugate momenta p = ''p''1, ''p''2, ... ''ps'', with the rest of the coordinates non-cyclic and denoted ζ = ''ζ''1, ''ζ''1, ..., ''ζN − s'', they can be removed by introducing the ''Routhian'': :R=\mathbf\cdot\mathbf - L(\mathbf, \mathbf, \boldsymbol, \dot)\,, which leads to a set of 2''s'' Hamiltonian equations for the cyclic coordinates q, :\dot = +\frac\,,\quad \dot = -\frac\,, and ''N'' − ''s'' Lagrangian equations in the non cyclic coordinates ζ. :\frac\frac = \frac\,. Set up in this way, although the Routhian has the form of the Hamiltonian, it can be thought of a Lagrangian with ''N'' − ''s'' degrees of freedom. The coordinates q do not have to be cyclic, the partition between which coordinates enter the Hamiltonian equations and those which enter the Lagrangian equations is arbitrary. It is simply convenient to let the Hamiltonian equations remove the cyclic coordinates, leaving the non cyclic coordinates to the Lagrangian equations of motion.


Appellian mechanics

Appell's equation of motion In classical mechanics, Appell's equation of motion (aka the Gibbs–Appell equation of motion) is an alternative general formulation of classical mechanics described by Josiah Willard Gibbs in 1879 and Paul Émile Appell in 1900. Statement T ...
involve generalized accelerations, the second time derivatives of the generalized coordinates: :\alpha_r = \ddot_r = \frac\,, as well as generalized forces mentioned above in D'Alembert's principle. The equations are :\mathcal_ = \frac\,, \quad S = \frac \sum_^ m_ \mathbf_^\,, where :\mathbf_k = \ddot_k = \frac is the acceleration of the ''k'' particle, the second time derivative of its position vector. Each acceleration a''k'' is expressed in terms of the generalized accelerations ''αr'', likewise each rk are expressed in terms the generalized coordinates ''qr''.


Extensions to classical field theory

;
Lagrangian field theory Lagrangian may refer to: Mathematics * Lagrangian function, used to solve constrained minimization problems in optimization theory; see Lagrange multiplier ** Lagrangian relaxation, the method of approximating a difficult constrained problem with ...
Generalized coordinates apply to discrete particles. For ''N'' scalar fields ''φi''(r, ''t'') where ''i'' = 1, 2, ... ''N'', the
Lagrangian density Lagrangian may refer to: Mathematics * Lagrangian function, used to solve constrained minimization problems in optimization theory; see Lagrange multiplier ** Lagrangian relaxation, the method of approximating a difficult constrained problem with ...
is a function of these fields and their space and time derivatives, and possibly the space and time coordinates themselves: \mathcal = \mathcal(\phi_1, \phi_2, \dots, \nabla\phi_1, \nabla\phi_2, \dots, \partial_t \phi_1, \partial_t \phi_2, \ldots, \mathbf, t)\,. and the Euler–Lagrange equations have an analogue for fields: \partial_\mu \left(\frac\right) = \frac\,, where ''∂μ'' denotes the 4-gradient and the
summation convention In mathematics, especially the usage of linear algebra in Mathematical physics, Einstein notation (also known as the Einstein summation convention or Einstein summation notation) is a notational convention that implies summation over a set of i ...
has been used. For ''N'' scalar fields, these Lagrangian field equations are a set of ''N'' second order partial differential equations in the fields, which in general will be coupled and nonlinear. This scalar field formulation can be extended to vector fields,
tensor field In mathematics and physics, a tensor field assigns a tensor to each point of a mathematical space (typically a Euclidean space or manifold). Tensor fields are used in differential geometry, algebraic geometry, general relativity, in the analysis ...
s, and
spinor field In differential geometry, given a spin structure on an n-dimensional orientable Riemannian manifold (M, g),\, one defines the spinor bundle to be the complex vector bundle \pi_\colon\to M\, associated to the corresponding principal bundle \pi_\col ...
s. The Lagrangian is the
volume integral In mathematics (particularly multivariable calculus), a volume integral (∭) refers to an integral over a 3-dimensional domain; that is, it is a special case of multiple integrals. Volume integrals are especially important in physics for many ...
of the Lagrangian density:Gravitation, J.A. Wheeler, C. Misner, K.S. Thorne, W.H. Freeman & Co, 1973, L = \int_\mathcal \mathcal \, dV \,. Originally developed for classical fields, the above formulation is applicable to all physical fields in classical, quantum, and relativistic situations: such as
Newtonian gravity Newton's law of universal gravitation is usually stated as that every particle attracts every other particle in the universe with a force that is proportional to the product of their masses and inversely proportional to the square of the distan ...
,
classical electromagnetism Classical electromagnetism or classical electrodynamics is a branch of theoretical physics that studies the interactions between electric charges and currents using an extension of the classical Newtonian model; It is, therefore, a classical fie ...
,
general relativity General relativity, also known as the general theory of relativity and Einstein's theory of gravity, is the geometric theory of gravitation published by Albert Einstein in 1915 and is the current description of gravitation in modern physics ...
, and quantum field theory. It is a question of determining the correct Lagrangian density to generate the correct field equation. ;
Hamiltonian field theory In theoretical physics, Hamiltonian field theory is the field-theoretic analogue to classical Hamiltonian mechanics. It is a formalism in classical field theory alongside Lagrangian field theory. It also has applications in quantum field theory ...
The corresponding "momentum" field densities conjugate to the ''N'' scalar fields ''φi''(r, ''t'') are: \pi_i(\mathbf,t) = \frac\,\quad\dot_i\equiv \frac where in this context the overdot denotes a partial time derivative, not a total time derivative. The Hamiltonian density \mathcal is defined by analogy with mechanics: \mathcal(\phi_1, \phi_2,\ldots, \pi_1, \pi_2, \ldots,\mathbf,t) = \sum_^N \dot_i(\mathbf,t)\pi_i(\mathbf,t) - \mathcal\,. The equations of motion are: \dot_i = +\frac\,,\quad \dot_i = - \frac \,, where the
variational derivative In the calculus of variations, a field of mathematical analysis, the functional derivative (or variational derivative) relates a change in a functional (a functional in this sense is a function that acts on functions) to a change in a function on w ...
\frac = \frac - \partial_\mu \frac must be used instead of merely partial derivatives. For ''N'' fields, these Hamiltonian field equations are a set of 2''N'' first order partial differential equations, which in general will be coupled and nonlinear. Again, the volume integral of the Hamiltonian density is the Hamiltonian H = \int_\mathcal \mathcal \, dV \,.


Symmetry, conservation, and Noether's theorem

; Symmetry transformations in classical space and time Each transformation can be described by an operator (i.e. function acting on the position r or momentum p variables to change them). The following are the cases when the operator does not change r or p, i.e. symmetries. where ''R''(n̂, θ) is the
rotation matrix In linear algebra, a rotation matrix is a transformation matrix that is used to perform a rotation in Euclidean space. For example, using the convention below, the matrix :R = \begin \cos \theta & -\sin \theta \\ \sin \theta & \cos \theta \en ...
about an axis defined by the
unit vector In mathematics, a unit vector in a normed vector space is a vector (often a spatial vector) of length 1. A unit vector is often denoted by a lowercase letter with a circumflex, or "hat", as in \hat (pronounced "v-hat"). The term ''direction v ...
n̂ and angle θ. ;
Noether's theorem Noether's theorem or Noether's first theorem states that every differentiable symmetry of the action of a physical system with conservative forces has a corresponding conservation law. The theorem was proven by mathematician Emmy Noether ...
Noether's theorem states that a
continuous Continuity or continuous may refer to: Mathematics * Continuity (mathematics), the opposing concept to discreteness; common examples include ** Continuous probability distribution or random variable in probability and statistics ** Continuous ...
symmetry transformation of the action corresponds to a
conservation law In physics, a conservation law states that a particular measurable property of an isolated physical system does not change as the system evolves over time. Exact conservation laws include conservation of energy, conservation of linear momentum, c ...
, i.e. the action (and hence the Lagrangian) doesn't change under a transformation parameterized by a
parameter A parameter (), generally, is any characteristic that can help in defining or classifying a particular system (meaning an event, project, object, situation, etc.). That is, a parameter is an element of a system that is useful, or critical, when ...
''s'': L (s,t), \dot(s,t)= L (t), \dot(t) the Lagrangian describes the same motion independent of ''s'', which can be length, angle of rotation, or time. The corresponding momenta to ''q'' will be conserved.


See also

*
Lagrangian mechanics In physics, Lagrangian mechanics is a formulation of classical mechanics founded on the stationary-action principle (also known as the principle of least action). It was introduced by the Italian-French mathematician and astronomer Joseph- ...
*
Hamiltonian mechanics Hamiltonian mechanics emerged in 1833 as a reformulation of Lagrangian mechanics. Introduced by Sir William Rowan Hamilton, Hamiltonian mechanics replaces (generalized) velocities \dot q^i used in Lagrangian mechanics with (generalized) ''momenta ...
*
Theoretical mechanics Mechanics (from Ancient Greek: μηχανική, ''mēkhanikḗ'', "of machines") is the area of mathematics and physics concerned with the relationships between force, matter, and motion among physical objects. Forces applied to objects re ...
*
Classical mechanics Classical mechanics is a physical theory describing the motion of macroscopic objects, from projectiles to parts of machinery, and astronomical objects, such as spacecraft, planets, stars, and galaxies. For objects governed by classical ...
* Dynamics * Nazariy Mexanika *
Hamilton–Jacobi equation In physics, the Hamilton–Jacobi equation, named after William Rowan Hamilton and Carl Gustav Jacob Jacobi, is an alternative formulation of classical mechanics, equivalent to other formulations such as Newton's laws of motion, Lagrangian mecha ...
*
Hamilton's principle In physics, Hamilton's principle is William Rowan Hamilton's formulation of the principle of stationary action. It states that the dynamics of a physical system are determined by a variational problem for a functional based on a single function, ...
* Kinematics *
Kinetics (physics) In physics and engineering, kinetics is the branch of classical mechanics that is concerned with the relationship between the motion and its causes, specifically, forces and torques. Since the mid-20th century, the term " dynamics" (or "analytic ...
*
Non-autonomous mechanics Non-autonomous mechanics describe non- relativistic mechanical systems subject to time-dependent transformations. In particular, this is the case of mechanical systems whose Lagrangians and Hamiltonians depend on the time. The configuration space o ...
* Udwadia–Kalaba equation


References and notes

{{DEFAULTSORT:Analytical Mechanics Mathematical physics Theoretical physics Dynamical systems