User talk:F=q(E+v^B)/Mathematical summary of physics

Well, in the Lagrangian formalism, you look for constraints (what limits the motion of the particle? which regions can the particle only move in?). Here, the particle is a pendulum "bob" constrained by the rod only to oscillate only in one vertical plane, back and forth along one arc. So the bob only has one degree of freedom (important tech term, abbreviate to "d.f", which is not a differential!).

Just to be sure: d.f's are basically the number of ways the particle can move subject to the constraints. Each degree of freedom can be described by a number: a generalized coordinate, usually denoted by q. Instead of using all coordinates in the space (for this example just 2), we only need one coordinate to define and describe the position of the bob. More: its completely arbitrary: - we can use the arc length the bob traverses (relative to some initial position), the distance moved along some axis (x or y, no need for both), or the angle θ, which is the most convenient to use for the problem.

So lets use "q = θ" as our generalized coordinate. To solve for the equation of motion we need the kinetic energy T and potential energy V of the particle is, then can calc. the Lagrangian L, then use Lagrange's equations and tidy up, solve etc.

The problem was set up in Cartesian coords, so the x and y coords, and time derivatives, are:

${\displaystyle x=\ell \sin \theta \quad y=\ell (1-\cos \theta )\Rightarrow {\dot {x}}=\ell \cos \theta {\dot {\theta }}\quad {\dot {y}}=\ell \sin \theta {\dot {\theta }}}$ 

Notice how x and y are amalgamated into θ.

The potential energy is easy (using the approximation mgh rather than GmM/r where M = mass of Earth and r = distance from Earth's c.o.m to pendulum bob c.o.m):

${\displaystyle V=mgy=mg\ell (1-\cos \theta )}$ 

the kinetic energy is:

${\displaystyle T={\frac {1}{2}}mv^{2}}$ 

where the speed (squared) of the bob is: (you may be able to tell already, just radius l times time derivative of angle θ):

${\displaystyle v^{2}={\dot {x}}^{2}+{\dot {y}}^{2}=\ell ^{2}{\dot {\theta }}^{2}\Rightarrow T={\frac {1}{2}}m\ell ^{2}{\dot {\theta }}^{2}}$ 

so the Lagrangian is:

${\displaystyle L=T-V={\frac {1}{2}}m\ell ^{2}{\dot {\theta }}^{2}-mg\ell (1-\cos \theta )}$ 

Lagrange's equations for this problem are (see the main page):

${\displaystyle {\dfrac {d}{dt}}\left({\dfrac {\partial L}{\partial {\dot {q}}}}\right)={\dfrac {\partial L}{\partial q}}\quad \Rightarrow \quad {\dfrac {d}{dt}}\left({\dfrac {\partial L}{\partial {\dot {\theta }}}}\right)={\dfrac {\partial L}{\partial \theta }}}$ 

This is important: The gen. coords and their time derivatives are necessarily treated as independent variables. Do NOT use the chain rule on the ${\displaystyle {\dot {q}}}$ 's !!!

Calculating the derivatives:

${\displaystyle {\dfrac {d}{dt}}\left({\dfrac {\partial L}{\partial {\dot {\theta }}}}\right)=m\ell ^{2}{\ddot {\theta }},\quad {\dfrac {\partial L}{\partial \theta }}=-mg\ell \sin \theta }$ 

so the equation of motion is:

${\displaystyle \ell {\ddot {\theta }}=-g\sin \theta }$ 

which is the familiar non-linear pendulum differential equation. You can take this from here yourself (apparently elliptic integrals are needed for exact solutions, I don't understand them in detail...). Of course for small amplitudes its easy to approximate, since

${\displaystyle \sin \theta \approx \theta \quad \Rightarrow \quad {\ddot {\theta }}\approx -{\frac {g}{\ell }}\theta \quad \Rightarrow \quad \theta \approx A\sin \left({\sqrt {\frac {g}{\ell }}}t\right)+B\cos \left({\sqrt {\frac {g}{\ell }}}t\right)}$ 

Since at t = 0, θ = 0, so B = 0, this reduces to

${\displaystyle \theta \approx A\sin \left({\sqrt {\frac {g}{\ell }}}t\right)}$ 

Suppose we have a similar system, a simple pendulum with bob mass m₁, rod length l₁, angle θ₁, with another pendulum suspended from the 1st bob (like a chain), of mass m₂, rod length l₂, angle θ₂. The system is placed at (0, l₁ + l₂).

There are now two generalized coordinates, the angle of each pendulum. So there will be two coupled (generally) 2nd order equations to solve.

The kinetic energy of the system is (remember energy is additive):

${\displaystyle T=T_{1}+T_{2}={\dfrac {1}{2}}(m_{1}\ell _{1}^{2}{\dot {\theta }}_{1}^{2}+m_{2}\ell _{2}^{2}{\dot {\theta }}_{2}^{2})}$ 

the potential energy is:

${\displaystyle V=V_{1}+V_{2}=m_{1}g[(\ell _{1}+\ell _{2})-\ell _{1}\cos \theta _{1}]+m_{2}g[(\ell _{1}+\ell _{2})-\ell _{1}\cos \theta _{1}-\ell _{2}\cos \theta _{2}]}$ 

The Lagrangian is (notice how we can ignore the constant terms since their derivatives will be zero):

${\displaystyle L=T-V={\dfrac {1}{2}}(m_{1}\ell _{1}^{2}{\dot {\theta }}_{1}^{2}+m_{2}\ell _{2}^{2}{\dot {\theta }}_{2}^{2})-m_{1}g[{\cancelto {}{(\ell _{1}+\ell _{2})}}-\ell _{1}\cos \theta _{1}]-m_{2}g[{\cancelto {}{(\ell _{1}+\ell _{2})}}-\ell _{1}\cos \theta _{1}-\ell _{2}\cos \theta _{2}]}$ 

${\displaystyle L=T-V={\dfrac {1}{2}}(m_{1}\ell _{1}^{2}{\dot {\theta }}_{1}^{2}+m_{2}\ell _{2}^{2}{\dot {\theta }}_{2}^{2})-m_{1}g[-\ell _{1}\cos \theta _{1}]-m_{2}g[-\ell _{1}\cos \theta _{1}-\ell _{2}\cos \theta _{2}]}$ 

${\displaystyle L=T-V={\dfrac {1}{2}}(m_{1}\ell _{1}^{2}{\dot {\theta }}_{1}^{2}+m_{2}\ell _{2}^{2}{\dot {\theta }}_{2}^{2})+m_{1}g\ell _{1}\cos \theta _{1}+m_{2}g[\ell _{1}\cos \theta _{1}+\ell _{2}\cos \theta _{2}]}$ 

${\displaystyle L=T-V={\dfrac {1}{2}}(m_{1}\ell _{1}^{2}{\dot {\theta }}_{1}^{2}+m_{2}\ell _{2}^{2}{\dot {\theta }}_{2}^{2})+(m_{1}+m_{2})g\ell _{1}\cos \theta _{1}+m_{2}g\ell _{2}\cos \theta _{2}}$ 

Lagrange's equations are:

${\displaystyle {\dfrac {d}{dt}}\left({\dfrac {\partial L}{\partial {\dot {\theta }}_{1}}}\right)={\dfrac {\partial L}{\partial \theta _{1}}}\quad {\dfrac {d}{dt}}\left({\dfrac {\partial L}{\partial {\dot {\theta }}_{2}}}\right)={\dfrac {\partial L}{\partial \theta _{2}}}}$ 

calculating the derivatives:

${\displaystyle {\dfrac {d}{dt}}\left({\dfrac {\partial L}{\partial {\dot {\theta }}_{1}}}\right)=m_{1}\ell _{1}^{2}{\ddot {\theta }}_{1}\quad {\dfrac {d}{dt}}\left({\dfrac {\partial L}{\partial {\dot {\theta }}_{2}}}\right)=m_{2}\ell _{2}^{2}{\ddot {\theta }}_{2}}$ 

${\displaystyle {\dfrac {\partial L}{\partial \theta _{1}}}=-(m_{1}+m_{2})g\ell _{1}\sin \theta _{1}\quad {\dfrac {\partial L}{\partial \theta _{2}}}=-m_{2}g\ell _{2}\sin \theta _{2}}$ 

so the equations of motion happen to be decoupled:

${\displaystyle m_{1}\ell _{1}^{2}{\ddot {\theta }}_{1}=-(m_{1}+m_{2})g\ell _{1}\sin \theta _{1},\quad m_{2}\ell _{2}^{2}{\ddot {\theta }}_{2}=-m_{2}g\ell _{2}\sin \theta _{2}}$ 

Here is a nice and important example - the force on a charged particle of mass m and charge q in an electromagnetic field (A, ϕ).

Given an A field, the particle in motion has potential momentum ${\displaystyle q\mathbf {A} (\mathbf {r} ,t)}$ , so its potential energy is ${\displaystyle q\mathbf {A} (\mathbf {r} ,t)\cdot \mathbf {\dot {r}} }$ . For a ϕ field, the potential energy is ${\displaystyle q\phi (\mathbf {r} ,t)}$ .

The potential energy is:

${\displaystyle V=q\phi -q\mathbf {A} \cdot \mathbf {\dot {r}} }$ 

The kinetic energy is:

${\displaystyle T={\frac {m}{2}}\mathbf {\dot {r}} \cdot \mathbf {\dot {r}} }$ 

hence the Lagrangian:

${\displaystyle L=T-V={\frac {m}{2}}\mathbf {\dot {r}} \cdot \mathbf {\dot {r}} +q\mathbf {A} \cdot \mathbf {\dot {r}} -q\phi }$ 

${\displaystyle L={\frac {m}{2}}({\dot {x}}^{2}+{\dot {y}}^{2}+{\dot {z}}^{2})+q({\dot {x}}A_{x}+{\dot {y}}A_{y}+{\dot {z}}A_{z})-q\phi }$ 

Lagrange's equations are

${\displaystyle {\frac {d}{dt}}{\frac {\partial L}{\partial {\dot {x}}}}={\frac {\partial L}{\partial x}}}$ 

(same for y and z). So partial derivatives are

${\displaystyle {\begin{aligned}{\frac {d}{dt}}{\frac {\partial L}{\partial {\dot {x}}}}&=m{\ddot {x}}+q{\frac {dA_{x}}{dt}}\\&=m{\ddot {x}}+{\frac {q}{dt}}\left({\frac {\partial A_{x}}{\partial t}}dt+{\frac {\partial A_{x}}{\partial x}}dx+{\frac {\partial A_{x}}{\partial y}}dy+{\frac {\partial A_{x}}{\partial z}}dz\right)\\&=m{\ddot {x}}+q\left({\frac {\partial A_{x}}{\partial t}}+{\frac {\partial A_{x}}{\partial x}}{\dot {x}}+{\frac {\partial A_{x}}{\partial y}}{\dot {y}}+{\frac {\partial A_{x}}{\partial z}}{\dot {z}}\right)\\\end{aligned}}}$ 

${\displaystyle {\frac {\partial L}{\partial x}}={\frac {\partial \phi }{\partial x}}+q\left({\frac {\partial A_{x}}{\partial x}}{\dot {x}}+{\frac {\partial A_{y}}{\partial x}}{\dot {y}}+{\frac {\partial A_{z}}{\partial x}}{\dot {z}}\right)}$ 

equating and solving:

${\displaystyle m{\ddot {x}}+q\left({\frac {\partial A_{x}}{\partial t}}+{\frac {\partial A_{x}}{\partial x}}{\dot {x}}+{\frac {\partial A_{x}}{\partial y}}{\dot {y}}+{\frac {\partial A_{x}}{\partial z}}{\dot {z}}\right)=q{\frac {\partial \phi }{\partial x}}+q\left({\frac {\partial A_{x}}{\partial x}}{\dot {x}}+{\frac {\partial A_{y}}{\partial x}}{\dot {y}}+{\frac {\partial A_{z}}{\partial x}}{\dot {z}}\right)}$ 

${\displaystyle {\begin{aligned}F_{x}&=q\left({\frac {\partial \phi }{\partial x}}+{\frac {\partial A_{x}}{\partial t}}\right)+q\left[{\dot {y}}\left({\frac {\partial A_{y}}{\partial x}}-{\frac {\partial A_{x}}{\partial y}}{\dot {y}}\right)+{\dot {z}}\left({\frac {\partial A_{z}}{\partial x}}-{\frac {\partial A_{x}}{\partial z}}\right)\right]\\&=qE_{x}+q[{\dot {y}}(\nabla \times \mathbf {A} )_{z}-{\dot {z}}(\nabla \times \mathbf {A} )_{y}]\\&=qE_{x}+q[\mathbf {\dot {r}} \times (\nabla \times \mathbf {A} )]_{x}\\&=qE_{x}+q(\mathbf {\dot {r}} \times \mathbf {B} )_{x}\end{aligned}}}$ 

Simalarly for the y and z directions. Hence the force equation is:

${\displaystyle \mathbf {F} =q(\mathbf {E} +\mathbf {\dot {r}} \times \mathbf {B} )}$