Difference between revisions of "Forest UCM NLM GalileanTans"

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[[File:TF_UCM_GalileanTans_RefFrame.png | 200 px]]
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[[File:TF_UCM_GalileanTans_RefFrame.xfig.txt]]
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Assume that <math>S^{\prime}</math> is a coordinate system moving at a CONSTANT speed <math>v</math> with respect to a fixed coordinate system <math>S</math>.
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Let <math>\vec{r}</math> and <math>\vec{r}^{\prime}</math> describe the position an object in motion using two different coordinate systems <math>S</math> and <math>S^{\prime}</math> respectively.
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<math>\vec{R}</math> represents a vector that locates the origin of the moving reference frame (<math>S^{\prime}</math>) with respect to the origin of reference from <math>S</math>.
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Using the definition of vector addition
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:<math>\vec{r} = \vec{R} + \vec{r}^{\prime}</math>
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Similarly
  
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:<math>\vec{v} = \frac{d \vec{r}}{dt} =  \frac{d \vec{R}}{dt}  +  \frac{d \vec{r}^{\prime}}{dt} </math>
  
[[File:TF_UCM_GalileanTans_RefFrame.png | 200 px]]
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and
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:<math>\vec{a} = \frac{d^2 \vec{r}}{dt^2} =  \frac{d^2 \vec{R}}{dt^2}  +  \frac{d^2 \vec{r}^{\prime}}{dt^2} </math>
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Newton's law of motion may be written as
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:<math>\vec{F} = m\vec{a} = m \left ( \frac{d^2 \vec{R}}{dt^2}  +  \frac{d^2 \vec{r}^{\prime}}{dt^2}  \right )</math>
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If
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:<math>\frac{d^2 \vec{R}}{dt^2}=0</math>  <math>S^{\prime}</math> is moving at a constant velocity <math>\vec{V}</math>
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Then
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:<math>\vec{F} = m\vec{a} = m \left (  \frac{d^2 \vec{r}^{\prime}}{dt^2}  \right )</math>
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Newton's law hold in coordinate system which move at a constant velocity (an inertial reference frame).  Accelerating reference frames are know as non-inertial reference frames and will be discussed later. (a coordinate system fixed to the Earth is a non-inertial reference frame since the Earth is rotating about its axis and moving in orbit about the Sun)
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=Galiean Transformation to CM frame=
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Consider the elastic scattering of two hard spheres from a fixed reference frame (Lab Frame) and an inertial frame moving at a speed <math>\vec{v}_{cm}</math> such that the momentum of the two spheres are equal in magnitude but opposite in direction.
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;A feature of elastic collisions described in the center of momentum (mass) frame is that the magnitude of each particles momentum remains the same before and after a collision, only their directions change.
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[[Image:SPIM_ElasCollis_Lab_CM_Frame.jpg | 500 px]]
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; Variable definitions
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:<math>m_1</math>= mass of incoming ball
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:<math>m_2</math>= mass of target ball
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:<math>u_1</math>= iniital velocity of  incoming ball in Lab Frame
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:<math>v_1</math>= final velocity of  <math>m_1</math> in Lab Frame
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:<math>\psi</math>= scattering angle of <math>m_1</math> in Lab frame after collision
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:<math>u_1^{\prime}</math>= iniital velocity of  <math>m_1</math> in C.M.  Frame
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:<math>v_1^{\prime}</math>= final velocity of  <math>m_1</math> in C.M. Frame
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:<math>u_2^{\prime}</math>= iniital velocity of  <math>m_2</math> in C.M.  Frame
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:<math>v_2^{\prime}</math>= final velocity of  <math>m_2</math> in C.M. Frame
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:<math>\theta</math>= scattering angle of <math>m_1</math> in C.M. frame after collision
  
The C.M. frame is often chosen to theoretically calculate cross-sections even though experiments are conducted in the Lab frame.  In such cases you will need to transform cross-sections between two frames.
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In terms of our reference frames
  
The total cross-section should be frame independent
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; vector definitions
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:<math>\vec{r}_1</math> = a position vector pointing to the location of <math>m_1</math> in the fixed reference frame <math>S</math>
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:<math>\vec{r}_2</math> = a position vector pointing to the location of <math>m_2</math> in the fixed reference frame <math>S</math>
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:<math>\vec{r}_1^{\prime}</math> = a position vector pointing to the location of <math>m_1</math> in the fixed reference frame <math>S^{\prime}</math>
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:<math>\vec{r}_2^{\prime}</math> = a position vector pointing to the location of <math>m_2</math> in the fixed reference frame <math>S^{\prime}</math>
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:<math>\vec{R}</math> = a position vector pointing from the fixed reference frame origin to the moving frame origin
  
:<math>\sigma_{C.M.} = \sigma_{Lab}</math>
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==Find the velocity of the center of momentum (mass) frame==
  
or
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By definition the velocity of the center of momentum is
  
: <math>\sigma(\theta) d \Omega = \sigma(\psi) d \Omega^{\prime}</math>
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:<math>\vec{u}_1 = \vec{v}_{cm} + \vec{u}_1^{\prime}</math>
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:<math>\vec{u}_2 = \vec{v}_{cm} + \vec{u}_2^{\prime}</math>
  
where
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In the center of momentum (mass) frame the total momentum is zero
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::<math>\vec{p}_1^{\prime} + \vec{p}_2^{\prime} = 0</math>
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:: <math>m_1 \vec{u}_1^{\prime} + m_2 \vec{u}_2^{\prime} = 0</math>
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:: <math>m_1 \left ( \vec{u}_1 - \vec{v}_{cm} \right ) + m_2 \left ( \vec{u}_2 - \vec{v}_{cm} \right )= 0</math>
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:: <math>m_1 \vec{u}_1  + m_2 \vec{u}_2 = \left ( m_1 + m_2 \right ) \vec{v}_{cm} </math>
  
<math>\theta</math> is in the CM frame and <math>\psi</math> is in the Lab frame.
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: <math>\vec{v}_{cm}  = \frac{m_1 \vec{u}_1  + m_2 \vec{u}_2}{\left ( m_1 + m_2 \right ) }</math>
  
  
;A non-relativistic transformation:
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The above equation is just the calculation of the velocity of the center of mass of the two particle system.
  
: <math>\sigma(\theta) d \Omega = \sigma(\psi) d \Omega^{\prime}</math>
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;The velocity of the center of momentum frame may be calculated (non-relativistically) as the velocity of the center of mass.
: <math>\sigma(\theta) 2 \pi \sin(\theta) d \theta = \sigma(\psi) 2 \pi \sin (\psi) d \psi</math>
 
: <math>\Rightarrow \sigma(\psi) = \frac{\sin(\theta)}{\sin(\psi)} \frac{d \theta}{d \psi} \sigma(\theta)</math>
 
  
The transformation is governed by the dependence of <math>\theta</math> on <math> \psi</math> <math> \left( \frac{d \theta}{d \psi} \right )</math>
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==Scattering angles==
  
Lets return back to our picture of the scattering Process
 
  
[[Image:SPIM ElasCollis Lab CM Frame.jpg | 500 px]]
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Transforming the scattering angle between reference frames is calculated using the Galilean transformation described by the vector addition of vectors <math>v_1</math> and <math>v_1^\{prime}</math>
  
if we superimpose the vectors <math>\vec{v}_1</math> and <math>\vec{v}_1^{\prime}</math> we have
 
  
[[Image:SPIM ElasCollis Lab CM Frame_Velocities.jpg]]
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[[File:SPIM_ElasCollis_Lab_CM_Frame_Velocities.jpg]]
  
Trig identities (non-relativistic Gallilean transformation) tell us
 
  
 
<math>v_1 \sin(\psi) = v_1^{\prime} \sin(\theta)</math>
 
<math>v_1 \sin(\psi) = v_1^{\prime} \sin(\theta)</math>
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<math>\tan(\psi) = \frac{\sin(\psi)}{\cos(\psi)} = \frac{v_1^{\prime} \sin(\theta)/v_1}{\frac{v_{CM}}{v_1} + \frac{v_1^{\prime} \cos(\theta)}{v_1} }
 
<math>\tan(\psi) = \frac{\sin(\psi)}{\cos(\psi)} = \frac{v_1^{\prime} \sin(\theta)/v_1}{\frac{v_{CM}}{v_1} + \frac{v_1^{\prime} \cos(\theta)}{v_1} }
 
= \frac{\sin(\theta)}{\cos(\theta) + \frac{v_{CM}}{v_1^{\prime}}}</math>
 
= \frac{\sin(\theta)}{\cos(\theta) + \frac{v_{CM}}{v_1^{\prime}}}</math>
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For an elastic collision only the directions change in the CM Frame: <math>u_1^{\prime}= v_1^{\prime}</math>  & <math>u_1^{\prime}= v_2^{\prime}</math>
 
For an elastic collision only the directions change in the CM Frame: <math>u_1^{\prime}= v_1^{\prime}</math>  & <math>u_1^{\prime}= v_2^{\prime}</math>
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: <math>\tan(\psi) = \frac{\sin(\theta)}{\cos(\theta) + \frac{m_1}{m_2}}</math>
 
: <math>\tan(\psi) = \frac{\sin(\theta)}{\cos(\theta) + \frac{m_1}{m_2}}</math>
  
after a little trig substitution
 
 
<math>\Rightarrow \frac{m_1}{m_2} = \frac{sin(\theta - \psi)}{\sin(\psi)} =</math> constant
 
 
now use the chain rule to find <math>\frac{d \theta}{d \psi}</math>
 
 
: <math>f \equiv  \frac{sin(\theta - \psi)}{\sin(\psi)} =</math> constant
 
:<math>df = 0 = \frac{ \partial f}{\partial \psi} d \psi  + \frac{ \partial f}{\partial \theta} d \theta </math>
 
: <math>\Rightarrow \frac{d \theta}{d \psi} = \frac{-\frac{ \partial f}{\partial \psi} }{\frac{ \partial f}{\partial \theta} }</math>
 
 
:<math>-\frac{ \partial f}{\partial \psi} = \frac{\cos(\theta - \psi)}{\sin(\psi)} + \frac{\sin(\theta - \psi)}{\sin(\psi)}</math>
 
:<math>\frac{ \partial f}{\partial \theta }= 1 + \frac{\sin(\theta - \psi) \cos(\psi)}{\cos(\theta - \psi) \sin(\psi)}</math>
 
 
after substitution:
 
: <math>\sigma(\psi) = \frac{\sin(\theta)}{\sin(\psi)} \frac{d \theta}{d \psi} \sigma(\theta)</math>
 
: <math>=\frac{\sin(\theta)}{\sin(\psi)} \left [ 1 + \frac{\sin(\theta - \psi) \cos(\psi)}{\cos(\theta - \psi) \sin(\psi)} \right ] \sigma(\theta)</math>
 
 
For the above equation to be more useful one would prefer to recast it in terms of only <math>\psi</math> and masses.
 
 
:<math>\sigma(\psi) = \frac{\left [ \frac{m_1}{m_2}\cos(\psi) + \sqrt{1-\left ( \frac{m_1 \sin(\psi) }{m_2} \right )^2 }\right ]}{\sqrt{1 - \left ( \frac{m_1 \sin(\psi)}{m_2}\right )^2 }}\sigma(\theta)</math>
 
  
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Now you can transform the angles between the two frames if you know the masses of the two particles.
  
 
[[Forest_UCM_NLM#Galilean_Transformations]]
 
[[Forest_UCM_NLM#Galilean_Transformations]]

Latest revision as of 13:38, 20 August 2014

TF UCM GalileanTans RefFrame.png

File:TF UCM GalileanTans RefFrame.xfig.txt

Assume that [math]S^{\prime}[/math] is a coordinate system moving at a CONSTANT speed [math]v[/math] with respect to a fixed coordinate system [math]S[/math].


Let [math]\vec{r}[/math] and [math]\vec{r}^{\prime}[/math] describe the position an object in motion using two different coordinate systems [math]S[/math] and [math]S^{\prime}[/math] respectively.


[math]\vec{R}[/math] represents a vector that locates the origin of the moving reference frame ([math]S^{\prime}[/math]) with respect to the origin of reference from [math]S[/math].

Using the definition of vector addition

[math]\vec{r} = \vec{R} + \vec{r}^{\prime}[/math]

Similarly

[math]\vec{v} = \frac{d \vec{r}}{dt} = \frac{d \vec{R}}{dt} + \frac{d \vec{r}^{\prime}}{dt} [/math]

and

[math]\vec{a} = \frac{d^2 \vec{r}}{dt^2} = \frac{d^2 \vec{R}}{dt^2} + \frac{d^2 \vec{r}^{\prime}}{dt^2} [/math]


Newton's law of motion may be written as

[math]\vec{F} = m\vec{a} = m \left ( \frac{d^2 \vec{R}}{dt^2} + \frac{d^2 \vec{r}^{\prime}}{dt^2} \right )[/math]


If

[math]\frac{d^2 \vec{R}}{dt^2}=0[/math] [math]S^{\prime}[/math] is moving at a constant velocity [math]\vec{V}[/math]

Then

[math]\vec{F} = m\vec{a} = m \left ( \frac{d^2 \vec{r}^{\prime}}{dt^2} \right )[/math]

Newton's law hold in coordinate system which move at a constant velocity (an inertial reference frame). Accelerating reference frames are know as non-inertial reference frames and will be discussed later. (a coordinate system fixed to the Earth is a non-inertial reference frame since the Earth is rotating about its axis and moving in orbit about the Sun)

Galiean Transformation to CM frame

Consider the elastic scattering of two hard spheres from a fixed reference frame (Lab Frame) and an inertial frame moving at a speed [math]\vec{v}_{cm}[/math] such that the momentum of the two spheres are equal in magnitude but opposite in direction.

A feature of elastic collisions described in the center of momentum (mass) frame is that the magnitude of each particles momentum remains the same before and after a collision, only their directions change.

SPIM ElasCollis Lab CM Frame.jpg


Variable definitions
[math]m_1[/math]= mass of incoming ball
[math]m_2[/math]= mass of target ball
[math]u_1[/math]= iniital velocity of incoming ball in Lab Frame
[math]v_1[/math]= final velocity of [math]m_1[/math] in Lab Frame
[math]\psi[/math]= scattering angle of [math]m_1[/math] in Lab frame after collision
[math]u_1^{\prime}[/math]= iniital velocity of [math]m_1[/math] in C.M. Frame
[math]v_1^{\prime}[/math]= final velocity of [math]m_1[/math] in C.M. Frame
[math]u_2^{\prime}[/math]= iniital velocity of [math]m_2[/math] in C.M. Frame
[math]v_2^{\prime}[/math]= final velocity of [math]m_2[/math] in C.M. Frame
[math]\theta[/math]= scattering angle of [math]m_1[/math] in C.M. frame after collision

In terms of our reference frames

vector definitions
[math]\vec{r}_1[/math] = a position vector pointing to the location of [math]m_1[/math] in the fixed reference frame [math]S[/math]
[math]\vec{r}_2[/math] = a position vector pointing to the location of [math]m_2[/math] in the fixed reference frame [math]S[/math]
[math]\vec{r}_1^{\prime}[/math] = a position vector pointing to the location of [math]m_1[/math] in the fixed reference frame [math]S^{\prime}[/math]
[math]\vec{r}_2^{\prime}[/math] = a position vector pointing to the location of [math]m_2[/math] in the fixed reference frame [math]S^{\prime}[/math]
[math]\vec{R}[/math] = a position vector pointing from the fixed reference frame origin to the moving frame origin

Find the velocity of the center of momentum (mass) frame

By definition the velocity of the center of momentum is

[math]\vec{u}_1 = \vec{v}_{cm} + \vec{u}_1^{\prime}[/math]
[math]\vec{u}_2 = \vec{v}_{cm} + \vec{u}_2^{\prime}[/math]

In the center of momentum (mass) frame the total momentum is zero

[math]\vec{p}_1^{\prime} + \vec{p}_2^{\prime} = 0[/math]
[math]m_1 \vec{u}_1^{\prime} + m_2 \vec{u}_2^{\prime} = 0[/math]
[math]m_1 \left ( \vec{u}_1 - \vec{v}_{cm} \right ) + m_2 \left ( \vec{u}_2 - \vec{v}_{cm} \right )= 0[/math]
[math]m_1 \vec{u}_1 + m_2 \vec{u}_2 = \left ( m_1 + m_2 \right ) \vec{v}_{cm} [/math]
[math]\vec{v}_{cm} = \frac{m_1 \vec{u}_1 + m_2 \vec{u}_2}{\left ( m_1 + m_2 \right ) }[/math]


The above equation is just the calculation of the velocity of the center of mass of the two particle system.

The velocity of the center of momentum frame may be calculated (non-relativistically) as the velocity of the center of mass.

Scattering angles

Transforming the scattering angle between reference frames is calculated using the Galilean transformation described by the vector addition of vectors [math]v_1[/math] and [math]v_1^\{prime}[/math]


SPIM ElasCollis Lab CM Frame Velocities.jpg


[math]v_1 \sin(\psi) = v_1^{\prime} \sin(\theta)[/math]


[math]v_1 cos(\psi) = v_{cm} + v_1^{\prime} \cos(\theta)[/math]

solving for [math]\psi[/math]

[math]\tan(\psi) = \frac{\sin(\psi)}{\cos(\psi)} = \frac{v_1^{\prime} \sin(\theta)/v_1}{\frac{v_{CM}}{v_1} + \frac{v_1^{\prime} \cos(\theta)}{v_1} } = \frac{\sin(\theta)}{\cos(\theta) + \frac{v_{CM}}{v_1^{\prime}}}[/math]


For an elastic collision only the directions change in the CM Frame: [math]u_1^{\prime}= v_1^{\prime}[/math] & [math]u_1^{\prime}= v_2^{\prime}[/math]

From the definition of the C.M.
[math]\vec{v}_{CM} = \frac{m_1 \vec{u}_1 + m_2 \vec{u}_2}{m_1+m_2} = \frac{m_1}{m_1+m_2} \vec{u}_1[/math]
conservation of momentum in CM Frame [math]\Rightarrow[/math]
[math]m_1 u_1^{\prime} = - m_2 u_2{\prime}[/math]
[math] \Rightarrow v_1^{\prime} = u_1^{\prime} = \frac{-m_2}{m_1} u_2^{\prime}[/math]
Gallilean Coordinate transformation
[math]\vec{u}_1 = \vec{u}_1^{\prime} + \vec{v}_{CM} = \vec{u}_1^{\prime} + \frac{m_1}{m_1+m_2} \vec{u}_1[/math]
[math]\Rightarrow u_1{\prime} = \left [ 1 - \frac{m_1}{m_1 + m_2} \right ] u_1 = \frac{m_2}{m_1+m_2}u_1[/math]
[math]\Rightarrow v_1^{\prime} = u_1^{\prime} =\frac{m_2}{m_1+m_2} u_1[/math]
another expression for [math]\psi[/math]

using the above gallilean transformation we can do the following

[math]\frac{v_{CM}}{v_1^{\prime}}= \frac{\frac{m_1}{m_1+m_2} u_1}{\frac{m_2}{m_1+m_2} u_1} = \frac{m_1}{m_2}[/math]

or

[math]\tan(\psi) = \frac{\sin(\theta)}{\cos(\theta) + \frac{m_1}{m_2}}[/math]


Now you can transform the angles between the two frames if you know the masses of the two particles.

Forest_UCM_NLM#Galilean_Transformations