Difference between revisions of "D8. Conservation of dynamic magnitudes"

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Els <span style="text-decoration: underline;">[[D4. Teoremes vectorials|'''vector theorems''']]</span> relate the variation of two dynamic magnitudes (<math>\overline{\Ms\Ds}</math>) that depend on the mass geometry and the motion of the system (the linear momentum and the angular momentum) with the resultant of the external actions on the system <math>(\sum \overline{\As\mathrm{C}_\mathrm{ext}})</math> ( <math>\sum \overline{\As\mathrm{C}_\mathrm{ext}}</math> includes the external interactions and, if working in a <span style="text-decoration: underline;">[[D1. Lleis fundacionals de la mecànica newtoniana#D1.1 Referències galileanes|'''non-Galilean reference frame''']]</span>,the associated inertial actions). In a generic way, these theorems can be written in the following form:<br>
The <span style="text-decoration: underline;">[[D4. Teoremes vectorials|'''vector theorems''']]</span> relate the variation of two dynamic magnitudes (<math>\overline{\Ds\Ms}</math>) that depend on the mass geometry and the motion of the system (the linear momentum and the angular momentum) with the resultant of the external actions on the system <math>(\sum \overline{\As\mathrm{C}_\mathrm{ext}})</math> ( <math>\sum \overline{\As\mathrm{C}_\mathrm{ext}}</math> includes the external interactions and, if working in a <span style="text-decoration: underline;">[[D1. Lleis fundacionals de la mecànica newtoniana#D1.1 Referències galileanes|'''non-Galilean reference frame''']]</span>,the associated inertial actions). In a generic way, these theorems can be written in the following form:<br>


<center><math>\sum \overline{\As\mathrm{C}_\mathrm{ext}}=\dert{\overline{\Ms\Ds}}{R}.</math></center><br>
<center><math>\sum \overline{\As\mathrm{C}_\mathrm{ext}}=\dert{\overline{\Ds\Ms}}{R}.</math></center><br>


Quan en alguna <u>direcció fixa a la referència R</u>(dfR) alguna component de les accions externes és zero, la component corresponent de la magnitud dinàmica es manté constant: es diu que aquesta component <u>es conserva</u>:<math>\left. \sum \overline{\As\mathrm{C}_\mathrm{ext}}\right]_\mathrm{dfR}=0 \Rightarrow \left. \overline{\Ms\Ds}\right]_\mathrm{dfR}=\text{constant}</math>.<br>
When in a <u>direction fixed to the reference frame R</u>(dfR) direction fixed to the reference frame R <u>is conserved</u>:<math>\left. \sum \overline{\As\mathrm{C}_\mathrm{ext}}\right]_\mathrm{dfR}=0 \Rightarrow \left. \overline{\Ds\Ms}\right]_\mathrm{dfR}=\text{constant}</math>.<br>


Una conservació és una propietat interessant: permet ignorar l’evolució del sistema durant un temps finit i mantenir un coneixement parcial (si no es conserven totes les components de <math>\overline{\Ms\Ds}</math>) o total (si la conservació es produeix en les tres direccions de l’espai de R) de l’estat del sistema.<br>
A conservation is an interesting property: it allows one to ignore the evolution of the system for a finite time and maintain a partial knowledge (if not all the components of <math>\overline{\Ds\Ms}</math>) are conserved) or a total knowledge (if the conservation occurs in the three directions of the space of R) of the system’s state.<br>


Hi ha dues precaucions a tenir en compte quan es tracta d’invocar conservacions:<br>
Two important things have to be kept in mind when it comes to invoking conservations:<br>


* Cal estar segur que la component de les accions externes que és nul·la correspon a una direcció fixa  a la referència (un valor nul en una direcció no fixa a R només és indicatiu de valor constant de <math>\overline{\Ms\Ds}</math> en aquella direcció, no de direcció constant!).<br>
* We have to be sure that the component of the external actions that is zero corresponds to a direction fixed in the reference frame (a zero value in a direction variable with respect to R means that the <math>\overline{\Ds\Ms}</math> component in that direction has a constant value, but not a constant direction!).<br>


* Cal recordar que la conservació es refereix a una magnitud dinàmica i no cinemàtica (en principi). Quan la <math>\overline{\Ms\Ds}</math> és la quantitat de moviment <math>(\overline{\Ms\Ds}=\Ms\vel{G}{R})</math>, en ser proporcional a la velocitat del centre de masses, la component corresponent de <math>\vel{G}{R}</math> es conserva. Quan la <math>\overline{\Ms\Ds}</math> és el moment cinètic d’un únic sòlid referit a un punt d’aquest sòlid <math>(\overline{\Ms\Ds}=\overline{\mathrm{H}}_\mathrm{RTQ}(\Qs),\Qs \in \mathrm{S})</math> , com que en general no és proporcional a la velocitat angular <math>\velang{S}{R}</math> , no es pot assegurar que la conservació del primer impliqui la constància de la segona.<br>
* We have to remember that conservation refers to a dynamic magnitude and not a kinematic one (in principle). When the <math>\overline{\Ds\Ms}</math> is the linear momentum <math>(\overline{\Ds\Ms}=\Ms\vel{G}{R})</math>, as it is proportional to the velocity of the center of mass, the corresponding component of <math>\vel{G}{R}</math> is conserved. When it is the angular momentum of a single rigid body about a point that belongs to that rigid body <math>\overline{\Ds\Ms}</math> since in general it is not proportional to the angular velocity <math>(\overline{\Ds\Ms}=\overline{\mathrm{H}}_\mathrm{RTQ}(\Qs),\Qs \in \mathrm{S})</math> the conservation of <math>\overline{\Ds\Ms}</math> does not imply that of <math>\velang{S}{R}</math>.<br>


Les conservacions solen ser el resultat de simplificacions en la formulació dels problemes, com per exemple negligir les friccions. En la vida real, en general no es conserva res.  
Conservations are often the consequence of simplifications in the formulation of problems, such as neglecting friction. In real life, in general nothing is conserved.
<div>  
<div>  
=====💭 Demostració ➕=====
=====💭 Proof ➕=====
<small>
<small>
Projectem el teorema vectorial en una base que tingui una direcció fixa a la referència (per exemple, la direcció 3):<br>
Let’s project the vector thorem in a vector basis with a dierction fixed to the reference frame (for example, direction3): <br>


<math>\sum \overline{\As\mathrm{C}_\mathrm{ext}}=\dert{\overline{\Ms\Ds}}{R} \quad \Rightarrow \quad \vector{\sum\As\mathrm{C}_1}{\sum\As\mathrm{C}_2}{\sum\As\mathrm{C}_3}=\left\{\dert{\overline{\Ms\Ds}}{R}\right\}=\vector{\dot{\Ms\Ds_1}}{\dot{\Ms\Ds_2}}{\dot{\Ms\Ds_3}}+\left\{\velang{B}{R}\right\}\times \vector{\Ms\Ds_1}{\Ms\Ds_2}{\Ms\Ds_3}</math><br>
<math>\sum \overline{\As\mathrm{C}_\mathrm{ext}}=\dert{\overline{\Ds\Ms}}{R} \quad \Rightarrow \quad \vector{\sum\As\mathrm{C}_1}{\sum\As\mathrm{C}_2}{\sum\As\mathrm{C}_3}=\left\{\dert{\overline{\Ds\Ms}}{R}\right\}=\vector{\dot{\Ds\Ms_1}}{\dot{\Ds\Ms_2}}{\dot{\Ds\Ms_3}}+\left\{\velang{B}{R}\right\}\times \vector{\Ds\Ms_1}{\Ds\Ms_2}{\Ds\Ms_3}</math><br>


Ja que la direcció 3 és fixa a R, la velocitat angular de la base <math>\velang{B}{R}</math> no pot tenir cap component que no sigui en direcció 3. Per tant:<br>
Since direction 3 is fixed to R, the angular velocity of the vector basis relative to R <math>\velang{B}{R}</math> must have a component in that direction. Therefore: <br>


<math>\vector{\sum\As\mathrm{C}_1}{\sum\As\mathrm{C}_2}{\sum\As\mathrm{C}_3}=\left\{\dert{\overline{\Ms\Ds}}{R}\right\}=\vector{\dot{\Ms\Ds_1}}{\dot{\Ms\Ds_2}}{\dot{\Ms\Ds_3}}=\vector{0}{0}{\Omega_3}\times \vector{\Ms\Ds_1}{\Ms\Ds_2}{\Ms\Ds_3}= \vector{\dot{\Ms\Ds_1}-\Omega_3\cdot\Ms\Ds_2}{\dot{\Ms\Ds_2}-\Omega_3\cdot\Ms\Ds_1}{\dot{\Ms\Ds_3}}</math><br>
<math>\vector{\sum\As\mathrm{C}_1}{\sum\As\mathrm{C}_2}{\sum\As\mathrm{C}_3}=\left\{\dert{\overline{\Ds\Ms}}{R}\right\}=\vector{\dot{\Ds\Ms_1}}{\dot{\Ds\Ms_2}}{\dot{\Ds\Ms_3}}=\vector{0}{0}{\Omega_3}\times \vector{\Ds\Ms_1}{\Ds\Ms_2}{\Ds\Ms_3}= \vector{\dot{\Ds\Ms_1}-\Omega_3\cdot\Ds\Ms_2}{\dot{\Ds\Ms_2}-\Omega_3\cdot\Ds\Ms_1}{\dot{\Ds\Ms_3}}</math><br>




Si <math>\sum \As\mathrm{C}_3=0 \quad \Rightarrow \quad \dot{\Ms\Ds_3}=0 \quad \Rightarrow \quad \Ms\Ds_3=\text{CONSTANT!}.</math><br>
Si <math>\sum \As\mathrm{C}_3=0 \quad \Rightarrow \quad \dot{\Ds\Ms_3}=0 \quad \Rightarrow \quad \Ds\Ms_3=\text{CONSTANT!}.</math><br>




En canvi, si <math>\sum \As\mathrm{C}_1</math> o <math>\sum \As\mathrm{C}_2</math> són nul·les, les components corresponents de <math>\overline{\Ms\Ds}</math> ( <math>\Ms\Ds_1</math> o <math>\Ms\Ds_2</math>)no són en principi constants:<br>
However, if <math>\sum \As\mathrm{C}_1</math> or <math>\sum \As\mathrm{C}_2</math> are zero, the corresponding components in <math>\overline{\Ds\Ms}</math> ( <math>\Ds\Ms_1</math> or <math>\Ds\Ms_2</math>) are not constant in principle:<br>




<math>\sum \As\mathrm{C}_1=0 \quad \Rightarrow \quad \dot{\Ms\Ds_1}-\Omega_3\cdot\Ms\Ds_2 =0 \quad \Rightarrow \quad \dot{\Ms\Ds_1}=\Omega_3\cdot\Ms\Ds_2 \quad \Rightarrow \quad \Ms\Ds_1 \neq \text{constant},</math><br>
<math>\sum \As\mathrm{C}_1=0 \quad \Rightarrow \quad \dot{\Ds\Ms_1}-\Omega_3\cdot\Ds\Ms_2 =0 \quad \Rightarrow \quad \dot{\Ds\Ms_1}=\Omega_3\cdot\Ds\Ms_2 \quad \Rightarrow \quad \Ds\Ms_1 \neq \text{constant},</math><br>


<math>\sum \As\mathrm{C}_2=0 \quad \Rightarrow \quad \dot{\Ms\Ds_2}+\Omega_3\cdot\Ms\Ds_1 =0 \quad \Rightarrow \quad \dot{\Ms\Ds_2}=-\Omega_3\cdot\Ms\Ds_1 \quad \Rightarrow \quad \Ms\Ds_2 \neq \text{constant}  .</math><br>
<math>\sum \As\mathrm{C}_2=0 \quad \Rightarrow \quad \dot{\Ds\Ms_2}+\Omega_3\cdot\Ds\Ms_1 =0 \quad \Rightarrow \quad \dot{\Ds\Ms_2}=-\Omega_3\cdot\Ds\Ms_1 \quad \Rightarrow \quad \Ds\Ms_2 \neq \text{constant}  .</math><br>


</small>
</small>
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==D8.1 Exemples==
==D8.1 Examples==
====✏️ Exemple D8.1: salt d’una persona al damunt d’una plataforma ====
====✏️ EXAMPLE D8.1: person jumping on a platform====
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:<small>
:<small>
{|
{|
|
|
:[[Fitxer:ExD8-1-1-cat.png|thumb|left|180px|link=]]
:[[File:ExD8-1-1-eng.png|thumb|left|180px|link=]]
|Una persona de massa M, que es mou amb velocitat <math>\mathrm{v}_0</math> sobre un terra llis <math>(\mu=0)</math>, salta sobre una plataforma de massa m que inicialment es troba quieta respecte del terra, i s’hi queda en repòs respecte d’ella.<u> Es tracta d’investigar com evoluciona el moviment d’aquestes dues peces.</u><br>
|A person of mass M, moving at speed <math>\mathrm{v}_0</math> on a smooth ground <math>(\mu=0)</math>, jumps onto a platform of mass m which is initially at rest with respect to the floor, and comes to rest relative to it. We want to investigate the <u> evolution of the motion of these two elements (person and platform).</u><br>


|}
|}
:<u>Hi ha conservació de la quantitat de moviment?</u>.<br>
:<u>Is the linear momentum conserved?</u>.<br>


:El salt de la persona té lloc al damunt d’un terra llis que no introdueix cap força horitzontal sobre ella ni sobre la plataforma. Per tant, durant el salt i per al SISTEMA (persona + plataforma) i la referència terra:<br>
:The person's jump takes place on a smooth ground that does not introduce any horizontal force on the person or on the platform. Therefore, during the jump and for the SYSTEM (person + platform) and the ground reference frame:<br>


:<math>\left.\sum \overline{\Fs}_\mathrm{ext}\right]_\mathrm{horitzontal}=0 \quad \Rightarrow \quad</math> quantitat de moviment horitzontal respecte del terra CONSTANT! <br>
:<math>\left.\sum \overline{\Fs}_\mathrm{ext}\right]_\mathrm{horizontal}=0 \quad \Rightarrow \quad</math> CONSTANT horizontal linear momentum relative to the ground! <br>


:Abans del salt <math>(\ts_\mathrm{inicial})</math>, la quantitat de moviment (respecte del terra) està associada només a la persona: <math>(\rightarrow \ms\vs_0)</math>. Just després del salt <math>(\ts_\mathrm{final})</math>, ja que la persona està en repòs respecte de la plataforma, totes dues peces es mouen amb la mateixa velocitat respecte del terra: <math>\left[\rightarrow (\Ms+\ms)\vs \right].</math>.
:Before jumping <math>(\ts_\mathrm{inicial})</math>, the linear momentum (relative to the ground) is only associated with the person: <math>(\rightarrow \ms\vs_0)</math>. Just after jumping <math>(\ts_\mathrm{final})</math>, as the person is at rest relative to the platform, both elements move with the same velocity relative to the ground <math>\left[\rightarrow (\Ms+\ms)\vs \right].</math>.
[[Fitxer:ExD8-1-2-cat-esp.png|thumb|center|350px|link=]]


:La conservació de la quantitat de moviment horitzontal entre aquests dos instants permet calcular la velocitat final del conjunt: <math>(\rightarrow \ms\vs_0) = \left[\rightarrow (\Ms+\ms)\vs \right] \quad \Rightarrow \quad \vs=\frac{\ms}{\Ms+\ms}\vs_0.</math>.<br>
[[File:ExD8-1-2-eng.png|thumb|center|350px|link=]]


:Aquesta velocitat es manté mentre el conjunt llisca al damunt del terra llis, però tan bon punt entra a la zona rugosa <math>(\mu \neq 0)</math>, deixarà de fer-ho: la força de fricció del terra sobre la plataforma, horitzontal i oposada a <math>\overline{\vs}_\Ts</math>(plataforma), la farà disminuir. Ja no es conserva la quantitat de moviment: <br>
:The conservation of the horizontal linear momentum between these two time instants allows us to calculate the final velocity of the system: <math>(\rightarrow \ms\vs_0) = \left[\rightarrow (\Ms+\ms)\vs \right] \quad \Rightarrow \quad \vs=\frac{\ms}{\Ms+\ms}\vs_0.</math>.<br>


:<math>\overline{\Fs}_\mathrm{terra \rightarrow sist}=(\leftarrow \Fs_\mathrm{fricció})=(\Ms+\ms)\acc{G}{T}.</math>
:This speed is constant while the system slides on the smooth ground, but as soon as it enters the rough area <math>(\mu \neq 0)</math>, that will change: the friction force of the ground on the platform, horizontal and opposite to <math>\overline{\vs}_\Ts</math> (platform) will make it decrease. The linear momentum is no longer conserved: <br>


:La quantitat de moviment horitzontal de la persona i la de la plataforma (per separat) no es conserven durant el salt per causa de les forces d’enllaç horitzontals que apareixen entre elles quan comença el contacte persona-plataforma.
:<math>\overline{\Fs}_\mathrm{ground \rightarrow syst}=(\leftarrow \Fs_\mathrm{friction})=(\Ms+\ms)\acc{G}{E}.</math>
 
:The horizontal linear momentum of the person and the platform (separately) are not conserved during the jump because of the horizontal constraint forces that appear between them when the person-platform contact begins.


:'''ANIMACIONS'''
:'''ANIMACIONS'''
</small>
</small>


====✏️ Exemple D8.2: aturada d’un bloc sobre un carretó ====
====✏️ EXAMPLE D8.2: stopping a block on a wagon ====
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:<small>
:<small>
{|
{|
|
|
:[[Fitxer:ExD8-2-1-cat.png|thumb|left|180px|link=]]
:[[File:ExD8-2-1-eng.png|thumb|left|180px|link=]]
|Una persona es troba al damunt d’un carretó, ambdós en repòs inicialment respecte del terra. La massa del conjunt (persona + carretó) és M, i les rodes del carretó són de massa negligible. El bloc, de massa m, té inicialment una velocitat <math>\vs_0</math> respecte del terra dirigida cap a la persona, que l’atura respecte de la plataforma. Es negligeix la fricció associada a les articulacions entre rodes i carretó<u> Es tracta d’investigar com evoluciona el moviment del sistema.</u><br>
|A person stands on a wagon, both initially at rest relative to the ground. The mass of the system (person + wagon) is M, and the wheels of the wagon are massless. The block, with mass m, has an initial velocity <math>\vs_0</math> relative to the ground directed towards the person, which stops it relative to the platform. The friction associated with the joints between wheels and wagon is neglected. We want to investigate the <u> evolution of the  movement of the system.</u><br>


|}
|}
:<u>Hi ha conservació de la quantitat de moviment?</u>.<br>
:<u>Is the linear momentum conserved?</u>.<br>


:Les rodes son <span style="text-decoration: underline;"> [[D3. Interaccions entre sòlids rígids#D3.5 Interaccions d’enllaç indirectes: Sòlids Auxiliars d’Enllaç|'''Sòlids Auxiliars d’Enllaç (SAEs)''']]</span> i no poden transmetre forces horitzontals (veure <span style="text-decoration: underline;">[[D3. Interaccions entre sòlids rígids#✏️ Exemple D3.10: caracterització d’un enllaç indirecte|'''exemple D3.10''']]</span>). Per tant, per al SISTEMA (persona + carretó amb rodes + bloc) i la referència terra:<br>
:The wheels are <span style="text-decoration: underline;"> [[D3. Interaccions entre sòlids rígids#D3.5 Interaccions d’enllaç indirectes: Sòlids Auxiliars d’Enllaç|'''Auxiliary Constraint Elements (ACE)''']]</span> and cannot transmit horizontal forces (see <span style="text-decoration: underline;">[[D3. Interaccions entre sòlids rígids#✏️ Exemple D3.10: caracterització d’un enllaç indirecte|'''example D3.10''']]</span>). Hence, for the SYSTEM (person + wagon with wheels + block) and the ground reference frame:<br>


:<math>\left.\sum \overline{\Fs}_\mathrm{ext}\right]_\mathrm{horitzontal}=0 \quad \Rightarrow \quad</math> quantitat de moviment (QM) horitzontal respecte del terra CONSTANT! <br>
:<math>\left.\sum \overline{\Fs}_\mathrm{ext}\right]_\mathrm{horizontal}=0 \quad \Rightarrow \quad</math> CONSTANT horizontal linear momentum (LM) relative to the ground! <br>


:Abans de l’aturada, la QM respecte del terra està associada només al bloc: <math>(\leftarrow \ms\vs_0)</math>. Just després de l’aturada <math>(\ts_\mathrm{final})</math>, ja que persona i bloc queden en repòs respecte del carretó, tot el sistema es mou amb la mateixa velocitat respecte del terra: <math>\left[\leftarrow (\Ms+\ms)\vs \right].</math>. La conservació de QM horitzontal entre aquests dos instants permet calcular la velocitat final del conjunt: <math>(\leftarrow \ms\vs_0) = \left[\leftarrow (\Ms+\ms)\vs \right] \quad \Rightarrow \quad \vs=\frac{\ms}{\Ms+\ms}\vs_0.</math>.
:Before stopping the block, the LM relative to the ground is associated only with the block: <math>(\leftarrow \ms\vs_0)</math>. But just after <math>(\ts_\mathrm{final})</math>, since the person and the block are at rest relative to the wagon, the entire system moves with the same velocity relative to the ground:<math>\left[\leftarrow (\Ms+\ms)\vs \right].</math>. The conservation of horizontal LM between these two time instants allows the calculation of the final velocity of the system: <math>(\leftarrow \ms\vs_0) = \left[\leftarrow (\Ms+\ms)\vs \right] \quad \Rightarrow \quad \vs=\frac{\ms}{\Ms+\ms}\vs_0.</math>.


[[Fitxer:ExD8-2-2-cat-esp.png|thumb|center|400px|link=]]
[[File:ExD8-2-2-eng.png|thumb|center|400px|link=]]


:Si es considera el bloc tot sol, per exemple, la seva QM respecte del terra no es manté constant per causa de la força de fricció del carretó sobre el bloc, que tendeix a aturar-lo. Per a un instant intermedi entre l’inicial i el final <math>(\ts_\mathrm{inicial}<\ts<\ts_\mathrm{final})</math> en el qual la velocitat del bloc respecte del terra s’ha reduït fins a <math>\vs'(<\vs_0)</math>, la velocitat del conjunt (persona + carretó) es pot calcular invocant la conservació de la QM horitzontal per al sistema (persona + carretó amb rodes + bloc):
:The LM of just the block relative to the ground does not remain constant because of the friction force of the wagon on the block, which tends to stop it. For a time instant between the initial and final ones <math>(\ts_\mathrm{initial}<\ts<\ts_\mathrm{final})</math> when the speed of the block relative to the ground has been reduced to <math>\vs'(<\vs_0)</math>, the velocity of the system (person + wagon) can be calculated through the conservation of horizontal LM for the system (person + wagon with wheels + block):


:<math>(\leftarrow \ms\vs_0) = (\leftarrow \ms\vs') + \left[\leftarrow (\Ms+\ms)\vs'' \right] \quad \Rightarrow \quad \vs''=\frac{\ms}{\Ms+\ms}(\vs_0-\vs').</math>
:<math>(\leftarrow \ms\vs_0) = (\leftarrow \ms\vs') + \left[\leftarrow (\Ms+\ms)\vs'' \right] \quad \Rightarrow \quad \vs''=\frac{\ms}{\Ms+\ms}(\vs_0-\vs').</math>


[[Fitxer:ExD8-2-3-cat-esp.png|thumb|center|300px|link=]]
[[File:ExD8-2-3-eng.png|thumb|center|300px|link=]]


:'''ANIMACIONS'''
:'''ANIMACIONS'''
</small>
</small>


====✏️ Exemple D8.3: patinador sobre gel ====
====✏️ EXAMPLE D8.3: skater on ice ====
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:<small>
:<small>
{|
{|
|
|
:[[Fitxer:ExD8-3-1-neut.png|thumb|left|100px|link=]]
:[[File:ExD8-3-1-neut.png|thumb|left|100px|link=]]
|Una persona fa patinatge sobre una pista de gel. En un cert moment, gira sobre sí mateixa amb velocitat angular <math>\Omega_0</math> amb els braços estesos, de manera que l’eix vertical que passa per <math>\Gs</math> és principal d’inèrcia i el moment d’inèrcia corresponent és <math>\Is_0</math>. <u> Es tracta d’investigar com evoluciona la rotació quan canvia la configuració dels seus braços</u> suposant que la fricció entre gel i patins és negligible <math>\mu=0</math>. <br>
|A person is skating on an ice rink. At a certain moment, his arms are symmetrically wide open and he he spins with angular velocity <math>\Omega_0</math> In that configuration, the vertical axis through <math>\Gs</math> is a principal axis of inertia and the corresponding moment of inertia is <math>\Is_0</math>. We want to investigate the <u> evolution of the rotation when the configuration of his arms changes</u> assuming that the friction between the ice and the skates is negligible <math>\mu=0</math>. <br>


|}
|}
:[[Fitxer:ExD8-3-2-neut.png|thumb|right|140px|link=]]
:[[File:ExD8-3-2-neut.png|thumb|right|140px|link=]]
:<u>Hi ha conservació del moment cinètic?</u>.<br>
:<u>Is the angular momentum conserved?</u>.<br>


:En tenir <math>\mu=0</math> entre gel i patins, les úniques  forces externes sobre el sistema (persona + patins) són verticals (pes i forces normals del gel sobre els patins). Aquestes forces verticals no poden generar moment vertical respecte de <math>\Gs</math>. Per tant, per al sistema (persona + patins): <br>
:Since <math>\mu=0</math> between ice and kates, the only external forces on the system (person + skates) are vertical (the weight and the normal forces of the ice on the skates). Those vertical forces cannot generate vertical momento about <math>\Gs</math>. Hence, for the system (person + skates): <br>


:<math>\left.\sum\overline{\Ms_\mathrm{ext}}(\Gs)\right]_\mathrm{vertical}=0=\left.\dot{\overline{\Hs}}_\mathrm{RTG}(\Gs)\right]_\mathrm{vertical} \quad \Rightarrow \quad \left.\overline{\Hs}_\mathrm{RTG}(\Gs)\right]_\mathrm{vertical} \text{CONSTANT!}</math><br>
:<math>\left.\sum\overline{\Ms_\mathrm{ext}}(\Gs)\right]_\mathrm{vertical}=0=\left.\dot{\overline{\Hs}}_\mathrm{RTG}(\Gs)\right]_\mathrm{vertical} \quad \Rightarrow \quad \left.\overline{\Hs}_\mathrm{RTG}(\Gs)\right]_\mathrm{vertical} \text{CONSTANT!}</math><br>
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:El moment cinètic vertical en la configuració inicial és <math>\overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{inicial})=(\Uparrow \Is_0 \Omega_0)</math>. Quan apropa o allunya els braços del cos, el moment d’inèrcia del sistema respecte de l’eix vertical que passa per <math>\Gs</math> canvia. Per a un valor qualsevol <math>\Is</math> d’aquest moment d’inèrcia, la conservació implica: <math>(\Uparrow \Is_0 \Omega_0)=(\Uparrow \Is \Omega)</math>. Si apropa els braços al cos, <math>\Is<\Is_0</math> , i per tant <math>\Omega>\Omega_0</math> (la velocitat angular augmenta). Per al cas concret <math>\Is=\Is_0/2</math>, la velocitat angular passa a ser el doble: <math>\Omega=2\Omega_0</math>.
:The vertical angular momentum in the initial configuration is <math>\overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{initial})=(\Uparrow \Is_0 \Omega_0)</math>. When approachng or separating the arms from the trunk, the inertia moment of the person about the vertical axis through <math>\Gs</math> changes. For any value  <math>\Is</math> of this inertia moment, conservation implies: <math>(\Uparrow \Is_0 \Omega_0)=(\Uparrow \Is \Omega)</math>. When approaching the arms to the trunk, <math>\Is<\Is_0</math>, therefore <math>\Omega>\Omega_0</math> (the angular velocity increases). For the paricular case <math>\Is=\Is_0/2</math>, the angular velocity becomes twice the initial value: <math>\Omega=2\Omega_0</math>.
:'''ANIMACIONS'''
:'''ANIMACIONS'''
</small>
</small>


====✏️ Exemple D8.4: col·lisió de dues barres ====
====✏️ EXAMPLE D8.4: collision between two bars====
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:<small>
:<small>
{|
{|
|
|
:[[Fitxer:ExD8-4-1-cat.png|thumb|left|180px|link=]]
:[[File:ExD8-4-1-eng.png|thumb|left|180px|link=]]
|Dues barres, que tenen la seva massa concentrada en un extrem, es mouen sobre un terra horitzontal perfectament llis (entre terra i barres el coeficient de fricció és nul, <math>\mu=0</math> ) una vers l’altra fins que col·lideixen i queden enganxades. <u> Es tracta de descriure el moviment final del sistema.</u><br>
|Two bars, with their mass concentrated at one end, move on a perfectly smooth horizontal ground (the friction coefficient between the ground and the bars is zero, <math>\mu=0</math>) towards each other until they collide and become stuck. We want to <u> describe the final motion of the system.</u><br>


|}
|}
:<u>Hi ha conservació de la quantitat de moviment?</u>.<br>
:<u>Is the linear momentum conserved?</u>.<br>


:Si es considera el sistema format per les dues barres, les forces externes que reben són estrictament verticals (perpendiculars al pla del moviment): el pes i les forces normals associades al contacte amb el terra. Per tant, per a aquest sistema:<br>
:If we consider the system formed by the two bars, the external forces on them are strictly vertical (perpendicular to the plane of motion): the weight and the normal forces associated with the ground contact. Therefore, for this system:<br>


:<math>\left.\sum \overline{\Fs}_\mathrm{ext}\right]_\mathrm{horitzontal}=0 \quad \Rightarrow \quad</math> quantitat de moviment (QM) horitzontal respecte del terra CONSTANT! <br>
:<math>\left.\sum \overline{\Fs}_\mathrm{ext}\right]_\mathrm{horizontal}=0 \quad \Rightarrow \quad</math> CONSTANT horizontal linear momentum (LM) relative to the ground! <br>


:Abans de la col·lisió <math>(\ts_\mathrm{abans})</math>:<br>
:Before collision <math>(\ts_\mathrm{before})</math>:<br>


:<math>\left.\overline{\mathrm{QM}}\right]_\mathrm{horitzontal}=\Ms \vel{G}{T}=2\ms\overline{\vs}_\Ts(\mathrm{barra P})+\ms\overline{\vs}_\Ts(\mathrm{barra Q})=(\rightarrow \ms\vs_0)+(\leftarrow \ms2\vs_0)=0</math><br>
:<math>\left.\overline{\mathrm{QM}}\right]_\mathrm{horizontal}=\Ms \vel{G}{T}=2\ms\overline{\vs}_\Ts(\mathrm{barra P})+\ms\overline{\vs}_\Ts(\mathrm{barra Q})=(\rightarrow \ms\vs_0)+(\leftarrow \ms2\vs_0)=0</math><br>


:Després de la col·lisió <math>\ts_\mathrm{després}</math>, <math>\left.\overline{\mathrm{QM}}\right]_\mathrm{horitzontal}</math>  del sistema ha de seguir sent zero, i per tant la velocitat del <span style="text-decoration: underline;"> [[D5. Geometria de masses#D5.1 Centre d'inèrcia|'''centre d’inèrcia ''']]</span> del sistema també: <math>\overline{\vs}_\Ts(\Gs,\ts_\mathrm{després})</math>. Això vol dir que, després de la col·lisió, el sòlid únic format per les dues barres tindrà el CIR respecte del terra col·locat permanentment a <math>\Gs</math>:
:After collision <math>\ts_\mathrm{after}</math>, <math>\left.\overline{\mathrm{QM}}\right]_\mathrm{horizontal}</math>  of the system has to be zero, therefore the velocity of the system’s <span style="text-decoration: underline;"> [[D5. Geometria de masses#D5.1 Centre d'inèrcia|'''center of inertia ''']]</span> is also zero: <math>\overline{\vs}_\Ts(\Gs,\ts_\mathrm{after})</math>. Hence, after collision, the rigid body formed by the two bars will have the '''ICR''' relative to the ground permanently located at <math>\Gs</math>:
[[Fitxer:ExD8-4-2-cat.png|thumb|right|350px|link=]]
[[File:ExD8-4-2-eng.png|thumb|right|350px|link=]]


:Posició del centre d’inèrcia <math>\Gs</math>: sobre la línia que uneix <math>\Ps</math> i <math>\Qs</math>, a una distància 4L per sota de <math>\Qs</math>.<br>
:Position of the inertia center <math>\Gs</math>: on the line <math>\Ps</math> and <math>\Qs</math>, at a distance 4L below <math>\Qs</math>.<br>


:<math>\left.\QGvec\right]_{\uparrow \downarrow}=\frac{\left.\ms \QQvec \right]_{\uparrow \downarrow} +\left. 2\ms \QPvec\right]_{\uparrow \downarrow}}{\ms+2\ms}</math><br>
:<math>\left.\QGvec\right]_{\uparrow \downarrow}=\frac{\left.\ms \QQvec \right]_{\uparrow \downarrow} +\left. 2\ms \QPvec\right]_{\uparrow \downarrow}}{\ms+2\ms}</math><br>
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:<math>\left.\QGvec\right]_{\uparrow \downarrow}=\frac{2}{3}(\downarrow 6\Ls)=(\downarrow 4\Ls)</math><br>
:<math>\left.\QGvec\right]_{\uparrow \downarrow}=\frac{2}{3}(\downarrow 6\Ls)=(\downarrow 4\Ls)</math><br>


:Per a cada barra per separat no hi ha conservació de la quantitat de moviment: la col·lisió genera forces molt intenses entre elles en direcció perpendicular a les barres que provoquen acceleració en els centres d’inèrcia respectius.<br>
:There is no conservation of the linear momentum for each bar separately: the collision generates very intense forces between them and perpendicular to the bars, that provoke nonzero acceleration of their inertia centres.<br>


:<u>Hi ha conservació del moment cinètic?</u><br>
:<u>Is the angular momentum conserved?</u><br>


:Per altra banda, les forces verticals (perpendiculars al pla del moviment) no poden generar moments verticals respecte de cap punt. Si es considera el TMC a <math>\Gs</math> per al sistema format per les dues barres: <br>
:On the other hand, vertical forces (perpendicular to the plane of motion) cannot generate vertical moments about any point. If we apply the AMT at <math>\Gs</math> to the system formed by the two bars:<br>


:<math>\left.\sum\overline{\Ms_\mathrm{ext}}(\Gs)\right]_\mathrm{vertical}=0=\left.\dot{\overline{\Hs}}_\mathrm{RTG}(\Gs)\right]_\mathrm{vertical} \quad \Rightarrow \quad \left.\overline{\Hs}_\mathrm{RTG}(\Gs)\right]_\mathrm{vertical} \text{CONSTANT!}</math><br>
:<math>\left.\sum\overline{\Ms_\mathrm{ext}}(\Gs)\right]_\mathrm{vertical}=0=\left.\dot{\overline{\Hs}}_\mathrm{RTG}(\Gs)\right]_\mathrm{vertical} \quad \Rightarrow \quad \left.\overline{\Hs}_\mathrm{RTG}(\Gs)\right]_\mathrm{vertical} \text{CONSTANT!}</math><br>


:<math>\left.\overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{abans})\right]_\mathrm{vertical}=\left.\overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{després})\right]_\mathrm{vertical} </math><br>
:<math>\left.\overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{before})\right]_\mathrm{vertical}=\left.\overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{after})\right]_\mathrm{vertical} </math><br>


:En l’instant <math>\ts_\mathrm{abans}</math>, les dues barres es traslladen, i per tant <math>\Gs</math> no pertany cinemàticament a cap d’elles. El càlcul del moment cinètic s’ha de fer per <span style="text-decoration: underline;"> [[D4. Teoremes vectorials#D4.8 Descomposició baricèntrica del moment cinètic|'''descomposició baricèntrica ''']]</span>. Tenint en compte que el centre d’inèrcia de la barra P és a <math>\Ps</math>, i el de la barra Q és a <math>\Qs</math>:<br>
:At time <math>\ts_\mathrm{before}</math>, the two bars have a translational motion, and therefore <math>\Gs</math> does not belong kinematically to either of them. Its angular momentum has to be calculated through <span style="text-decoration: underline;"> [[D4. Teoremes vectorials#D4.8 Descomposició baricèntrica del moment cinètic|'''barycentric decomposition  ''']]</span>. Taking into account that the center of inertia of bar P is <math>\Ps</math>, and that of bar Q is <math>\Qs</math>:<br>


:<math>\overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{abans})=\left.\overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{abans})\right]_\mathrm{barraP}+\left.\overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{abans})\right]_\mathrm{barraQ}= </math><br>
:<math>\overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{before})=\left.\overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{before})\right]_\mathrm{barP}+\left.\overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{before})\right]_\mathrm{barQ}= </math><br>


:<math>\hspace{2.9cm}=\left.\overline{\Hs}_\mathrm{RTP}(\Ps,\ts_\mathrm{abans}) \right]_\mathrm{barraP}+\GPvec\times 2\ms\vel{P}{RTG}+\left.\overline{\Hs}_\mathrm{RTQ}(\Qs,\ts_\mathrm{abans})\right]_\mathrm{barraQ}+\GQvec \times 2\ms\vel{Q}{RTG}=</math><br>
:<math>\hspace{2.9cm}=\left.\overline{\Hs}_\mathrm{RTP}(\Ps,\ts_\mathrm{before}) \right]_\mathrm{barP}+\GPvec\times 2\ms\vel{P}{RTG}+\left.\overline{\Hs}_\mathrm{RTQ}(\Qs,\ts_\mathrm{before})\right]_\mathrm{barQ}+\GQvec \times 2\ms\vel{Q}{RTG}=</math><br>


:<math>\hspace{2.9cm}=\Is_\mathrm{P}\velang{barraP}{RTG} + \GPvec \times 2\ms\vel{P}{RTG}+\Is_\mathrm{Q}\velang{barraQ}{RTG}+\GQvec\times 2\ms\vel{Q}{RTG}</math><br>
:<math>\hspace{2.9cm}=\Is_\mathrm{P}\velang{barP}{RTG} + \GPvec \times 2\ms\vel{P}{RTG}+\Is_\mathrm{Q}\velang{barQ}{RTG}+\GQvec\times 2\ms\vel{Q}{RTG}</math><br>


:<math>\velang{barraP}{RTG}=\velang{barraQ}{RTG}=\vec{0} \quad \Rightarrow \quad \overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{abans})=(\downarrow 2\Ls)\times 2\ms(\rightarrow \vs_0)+(\uparrow 4\Ls)\times \ms (\leftarrow 2\vs_0)=(\otimes 10\ms\vs_0\Ls)</math><br>
:<math>\velang{barP}{RTG}=\velang{barQ}{RTG}=\vec{0} \quad \Rightarrow \quad \overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{before})=(\downarrow 2\Ls)\times 2\ms(\rightarrow \vs_0)+(\uparrow 4\Ls)\times \ms (\leftarrow 2\vs_0)=(\otimes 10\ms\vs_0\Ls)</math><br>


:Després de la col·lisió, <math>\Gs</math> pertany al sòlid únic que s’ha format. Per tant:<br>
:After collision, <math>\Gs</math> is a point fixed to the rigid body formed by the two bars stuck together. Therefore:<br>


:<math>\overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{després})= \Is_\mathrm{G}\velang{}{RTG}=\left[2\ms(2\Ls)^2+\ms(4\Ls)^2\right](\otimes \Omega_\mathrm{T})=(\otimes 24\ms\Ls^2\Omega_\mathrm{T})</math><br>
:<math>\overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{after})= \Is_\mathrm{G}\velang{}{RTG}=\left[2\ms(2\Ls)^2+\ms(4\Ls)^2\right](\otimes \Omega_\mathrm{T})=(\otimes 24\ms\Ls^2\Omega_\mathrm{T})</math><br>


:Finalment: <math>(\otimes 10\ms\Ls\vs_0)=(\otimes\ms\Ls^2\Omega_\mathrm{T})\quad \Rightarrow \quad \Omega_\mathrm{T}=\frac{5}{12}\frac{\vs_0}{\Ls} </math> .<br>
:Finally: <math>(\otimes 10\ms\Ls\vs_0)=(\otimes\ms\Ls^2\Omega_\mathrm{T})\quad \Rightarrow \quad \Omega_\mathrm{T}=\frac{5}{12}\frac{\vs_0}{\Ls} </math> .<br>




:<u>Comentari important</u>
:<u>Important comment</u>


:Tot i que, per al sistema format per les dues barres, el moment extern vertical és nul per a qualsevol punt, no es conserva el moment cinètic ni a <math>\Ps</math> ni a <math>\Qs</math> perquè tots dos punts estan accelerats (canvien bruscament de velocitat quan hi ha la col·lisió):
:Although, for the system formed by the two bars, the vertical external moment is zero for any point, the angular momentum is not conserved either at  <math>\Ps</math> or at <math>\Qs</math> because the two points are accelerated (their velocities change abruptly when the collision occurs):


:<math>\acc{P}{Gal}=\frac{\Delta \vel{P}{Gal}}{\ts_\mathrm{després}-\ts_\mathrm{abans}}=\frac{\left[\rightarrow (\vs_0-2\Ls\Omega_\mathrm{T})\right]}{\ts_\mathrm{després}-\ts_\mathrm{abans}}</math>  ,  <math>\acc{Q}{Gal}=\frac{\Delta \vel{Q}{Gal}}{\ts_\mathrm{després}-\ts_\mathrm{abans}}=\frac{\left[\rightarrow (2\vs_0-4\Ls\Omega_\mathrm{T})\right]}{\ts_\mathrm{després}-\ts_\mathrm{abans}}</math> .
:<math>\acc{P}{Gal}=\frac{\Delta \vel{P}{Gal}}{\ts_\mathrm{after}-\ts_\mathrm{before}}=\frac{\left[\rightarrow (\vs_0-2\Ls\Omega_\mathrm{T})\right]}{\ts_\mathrm{after}-\ts_\mathrm{before}}</math>  ,  <math>\acc{Q}{Gal}=\frac{\Delta \vel{Q}{Gal}}{\ts_\mathrm{after}-\ts_\mathrm{before}}=\frac{\left[\rightarrow (2\vs_0-4\Ls\Omega_\mathrm{T})\right]}{\ts_\mathrm{after}-\ts_\mathrm{before}}</math> .


:Per tant:
:Therefore:


:<math>\left.\sum\overline{\Ms_\mathrm{ext}}(\Ps)\right]_\mathrm{vertical}+ \left.\PGvec \times \ms \acc{P}{Gal}\right]_\mathrm{vertical}=\left.\dot{\overline{\Hs}}_\mathrm{RTP}(\Ps)\right]_\mathrm{vertical}</math><br>
:<math>\left.\sum\overline{\Ms_\mathrm{ext}}(\Ps)\right]_\mathrm{vertical}+ \left.\PGvec \times \ms \acc{P}{Gal}\right]_\mathrm{vertical}=\left.\dot{\overline{\Hs}}_\mathrm{RTP}(\Ps)\right]_\mathrm{vertical}</math><br>


:<math>(\uparrow 2\Ls)\times \ms \frac{\left[\rightarrow (\vs_0-2\Ls\Omega_\mathrm{T})\right]}{\ts_\mathrm{després}-\ts_\mathrm{abans}} =\left[\otimes \frac{2\ms\Ls(\vs_0-2\Ls\Omega_\mathrm{T})}{\ts_\mathrm{després}-\ts_\mathrm{abans}} \right]=\left.\dot{\overline{\Hs}}_\mathrm{RTP}(\Ps)\right]_\mathrm{vertical} \quad \Rightarrow \quad \left.\overline{\Hs}_\mathrm{RTP}(\Ps)\right]_\mathrm{vertical}\neq \text{constant} </math><br>
:<math>(\uparrow 2\Ls)\times \ms \frac{\left[\rightarrow (\vs_0-2\Ls\Omega_\mathrm{T})\right]}{\ts_\mathrm{after}-\ts_\mathrm{before}} =\left[\otimes \frac{2\ms\Ls(\vs_0-2\Ls\Omega_\mathrm{T})}{\ts_\mathrm{after}-\ts_\mathrm{before}} \right]=\left.\dot{\overline{\Hs}}_\mathrm{RTP}(\Ps)\right]_\mathrm{vertical} \quad \Rightarrow \quad \left.\overline{\Hs}_\mathrm{RTP}(\Ps)\right]_\mathrm{vertical}\neq \text{constant} </math><br>




:<math>\left.\sum\overline{\Ms_\mathrm{ext}}(\Qs)\right]_\mathrm{vertical}+ \left.\QGvec \times \ms \acc{Q}{Gal}\right]_\mathrm{vertical}=\left.\dot{\overline{\Hs}}_\mathrm{RTQ}(\Qs)\right]_\mathrm{vertical}</math><br>
:<math>\left.\sum\overline{\Ms_\mathrm{ext}}(\Qs)\right]_\mathrm{vertical}+ \left.\QGvec \times \ms \acc{Q}{Gal}\right]_\mathrm{vertical}=\left.\dot{\overline{\Hs}}_\mathrm{RTQ}(\Qs)\right]_\mathrm{vertical}</math><br>


:<math>(\downarrow 4\Ls)\times \ms \frac{\left[\leftarrow (2\vs_0-4\Ls\Omega_\mathrm{T})\right]}{\ts_\mathrm{després}-\ts_\mathrm{abans}} =\left[\otimes \frac{8\ms\Ls(\vs_0-2\Ls\Omega_\mathrm{T})}{\ts_\mathrm{després}-\ts_\mathrm{abans}} \right]=\left.\dot{\overline{\Hs}}_\mathrm{RTQ}(\Qs)\right]_\mathrm{vertical} \quad \Rightarrow \quad \left.\overline{\Hs}_\mathrm{RTQ}(\Qs)\right]_\mathrm{vertical}\neq \text{constant} </math>
:<math>(\downarrow 4\Ls)\times \ms \frac{\left[\leftarrow (2\vs_0-4\Ls\Omega_\mathrm{T})\right]}{\ts_\mathrm{after}-\ts_\mathrm{before}} =\left[\otimes \frac{8\ms\Ls(\vs_0-2\Ls\Omega_\mathrm{T})}{\ts_\mathrm{after}-\ts_\mathrm{before}} \right]=\left.\dot{\overline{\Hs}}_\mathrm{RTQ}(\Qs)\right]_\mathrm{vertical} \quad \Rightarrow \quad \left.\overline{\Hs}_\mathrm{RTQ}(\Qs)\right]_\mathrm{vertical}\neq \text{constant} </math>




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</small>
</small>


====✏️ Exemple D8.5: col·lisió d’una anella i un braç ====
====✏️ EXAMPLE D8.5: collision of a ring and an articulated arm====
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:<small>
:<small>
{|
{|
|
|
:[[Fitxer:ExD8-5-1-cat.png|thumb|left|180px|link=]]
:[[File:ExD8-5-1-eng.png|thumb|left|180px|link=]]
|L’anella, de radi L i massa m, es mou sobre un terra horitzontal llis amb velocitat angular respecte del terra <math>\Omega_0=\ns\vs_0/\Ls</math> (on n és un número enter), i el seu centre <math>\Ps</math> s’apropa amb velocitat <math>\vs_0</math> cap a l’extrem <math>\Qs</math> del braç, de longitud 2L i massa M, que està articulat al punt <math>\Os</math> fix a terra i es troba inicialment en repòs. Després de la col·lisió, anella i braç queden enganxats. Es negligeix la fricció associada a l’articulació a <math>\Os</math>.<u> Es tracta d’investigar el moviment del sistema després de la col·lisió.</u><br>
|The ring, with radius L and mass m, moves on a smooth horizontal ground with angular velocity <math>\Omega_0=\ns\vs_0/\Ls</math> relative to the ground (where n is an integer), and its centre <math>\Ps</math> approaches the end <math>\Qs</math> of the arm with velocity <math>\vs_0</math>. The arm has a length 2L and a mass M, is articulated at point <math>\Os</math> fixed to the ground and is initially at rest. Because of the collision, the ring and arm stick together. The friction associated with the joint at <math>\Os</math> is neglected. We want to <u>investigate the motion of the system after the collision.</u><br>
 
|}
|}
:<u>Hi ha conservació de la quantitat de moviment?</u>.<br>
:<u>Is the linear momentum conserved?</u>.<br>


:Per a cada element per separat (anella i braç) no hi ha conservació de la quantitat de moviment: la col·lisió genera forces molt intenses entre elles en direcció horitzontal que provoquen acceleració en els centres d’inèrcia respectius. A més, el braç rep una força intensa a l’articulació a <math>\Os</math>.<br>
:The linear momentum of each element separately (ring and arm) is not conserved: the collision generates very intense horizontal forces between them that cause acceleration in their centers of inertia. In addition, the arm undergoes an intense force at the <math>\Os</math>-joint.<br>


:Per al sistema (anella + braç) tampoc no n’hi ha: l’articulació a <math>\Os</math> introdueix forces en el pla del moviment que provoquen acceleració en el centre d’inèrcia conjunt <math>\Gs</math>.
:There is no conservation of the linear momentum for the system (ring + arm) either: the <math>\Os</math>-joint introduces forces into the plane of motion responsible for the acceleration of the system’s center of inertia <math>\Gs</math>.


:<u>Conservació del moment cinètic?</u>
:<u>Is the angular momentum conserved?</u>


:[[Fitxer:ExD8-5-2-cat.png|thumb|right|200px|link=]]
:[[File:ExD8-5-2-eng.png|thumb|right|200px|link=]]
:Per al sistema (anella + braç), les forces associades a l’articulació provoquen moment extern vertical (ortogonal al pla del moviment) a qualsevol punt tret del punt <math>\Os</math>:
:For the system (ring + arm), the forces associated with the joint yield a nonzero vertical external moment (orthogonal to the plane of motion) at any point except at <math>\Os</math>:


:<math>\left.\sum\overline{\Ms_\mathrm{ext}}(\Os)\right]_\mathrm{vertical}=0=\left.\dot{\overline{\Hs}}_\mathrm{RTG}(\Os)\right]_\mathrm{vertical} \quad \Rightarrow \quad \left.\overline{\Hs}_\mathrm{RTG}(\Os)\right]_\mathrm{vertical} \text{CONSTANT!}</math><br>
:<math>\left.\sum\overline{\Ms_\mathrm{ext}}(\Os)\right]_\mathrm{vertical}=0=\left.\dot{\overline{\Hs}}_\mathrm{RTG}(\Os)\right]_\mathrm{vertical} \quad \Rightarrow \quad \left.\overline{\Hs}_\mathrm{RTG}(\Os)\right]_\mathrm{vertical} \text{CONSTANT!}</math><br>


:En ser <math>\Os</math> permanentment fix a terra, ha de ser el '''CIR''' permanent respecte del terra del sòlid únic format després de la col·lisió. Abans de la col·lisió, el '''CIR''' de l’anella es troba a <math>\Ls/2</math> per sota del centre <math>\Ps</math>:
:Since <math>\Os</math> is permanently fixed to the ground, it must be the permanent '''ICR''' relative to the ground of the rigid formed by the ring and the arm stuck together after the collision. Before the collision, the ring '''ICR''' is located at <math>\Ls/2</math> below the center <math>\Ps</math>:


:<math>\vel{S}{T}=\vel{P}{T}+\velang{}{0}\times \PSvec = (\rightarrow \vs_0) + \left(\otimes \frac{\ns\vs_0}{\Ls}\right)\times (\downarrow \Ls)=\left[\leftarrow (\ns-1)\vs_0\right].</math>
:<math>\vel{S}{T}=\vel{P}{T}+\velang{}{0}\times \PSvec = (\rightarrow \vs_0) + \left(\otimes \frac{\ns\vs_0}{\Ls}\right)\times (\downarrow \Ls)=\left[\leftarrow (\ns-1)\vs_0\right].</math>


:La distància e entre <math>\Ps</math> i el '''CIR''' de l’anella respecte del terra abans de la col·lisió es pot trobar a partir de:
:The distance e between <math>\Ps</math> and the ring '''ICR''' relative to the ground before collision can be found from:  


:<math>\left.\begin{array}{l}
:<math>\left.\begin{array}{l}
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\end{array}\right\} \Rightarrow \es=\frac{\Ls}{\ns} .</math>
\end{array}\right\} \Rightarrow \es=\frac{\Ls}{\ns} .</math>


:Un valor negatiu de n voldria dir que el '''CIR''' es troba a una distància e pel damunt de <math>\Ps</math>.
:A negative value for n means that the '''ICR''' is located at a distance e above <math>\Ps</math>.


:[[Fitxer:ExD8-5-3-cat-esp.png|thumb|center|500px|link=]]
:[[File:ExD8-5-3-eng.png|thumb|center|500px|link=]]


:Abans de la col·lisió <math>\ts_\mathrm{abans}</math>, <math>\Os</math> no pertany en general cinemàticament a l’anella (no és el seu '''CIR'''). El càlcul del seu moment cinètic s’ha de fer per <span style="text-decoration: underline;"> [[D4. Teoremes vectorials#D4.8 Descomposició baricèntrica del moment cinètic|'''descomposició baricèntrica ''']]</span>. El moment cinètic inicial del braç és nul perquè no es mou:  
:Before the collision <math>\ts_\mathrm{before}</math>, <math>\Os</math> is not a point fixed to the ring in general (it is not its '''ICR'''). Its angular momentum has to be calculated thorugh <span style="text-decoration: underline;"> [[D4. Teoremes vectorials#D4.8 Descomposició baricèntrica del moment cinètic|'''barycentric decomposition ''']]</span>. The initial angular momentum of the arm is zero because it does not move:


:<math>\overline{\Hs}_\mathrm{RTO=T}(\Os,\ts_\mathrm{abans})=\left.\overline{\Hs}_\mathrm{T}(\Os,\ts_\mathrm{abans})\right]_\mathrm{anella}= \left.\overline{\Hs}_\mathrm{RTP}(\Ps,\ts_\mathrm{abans})\right]_\mathrm{anella} + \OPvec \times 2\ms\vel{P}{T}= </math><br>
:<math>\overline{\Hs}_\mathrm{RTO=T}(\Os,\ts_\mathrm{before})=\left.\overline{\Hs}_\mathrm{T}(\Os,\ts_\mathrm{before})\right]_\mathrm{anella}= \left.\overline{\Hs}_\mathrm{RTP}(\Ps,\ts_\mathrm{before})\right]_\mathrm{anella} + \OPvec \times 2\ms\vel{P}{T}= </math><br>


:<math>\hspace{3.4cm}=\Is_\mathrm{P} \left(\otimes \frac{\ns\vs_0}{\Ls} \right) + \left(\downarrow 2\Ls \right)\times \ms\left(\rightarrow \vs_0 \right) = \left(\otimes \ms\Ls^2 \frac{\ns\vs_0}{\Ls}\right) + \left(\odot 2\ms\Ls\vs_0 \right) = \left[ \otimes (\ns-2)\ms\Ls\vs_0 \right]</math><br>
:<math>\hspace{3.4cm}=\Is_\mathrm{P} \left(\otimes \frac{\ns\vs_0}{\Ls} \right) + \left(\downarrow 2\Ls \right)\times \ms\left(\rightarrow \vs_0 \right) = \left(\otimes \ms\Ls^2 \frac{\ns\vs_0}{\Ls}\right) + \left(\odot 2\ms\Ls\vs_0 \right) = \left[ \otimes (\ns-2)\ms\Ls\vs_0 \right]</math><br>


:Després de la col·lisió:<br>
:After the collision:<br>


:<math>\overline{\Hs}_\mathrm{RTO}(\Os,\ts_\mathrm{després})= \Is_\mathrm{O}\overline{\Omega}_\Ts=\left( \Is_\mathrm{O}^\mathrm{anella}+ \Is_\mathrm{O}^\mathrm{braç} \right) \overline{\Omega}_\Ts= \left( \Is_\mathrm{G}^\mathrm{anella}+ \Is_\mathrm{O}^{\mathrm{anella}\otimes}+\Is_\mathrm{O}^\mathrm{braç} \right) \overline{\Omega}_\Ts = \left[ \ms\Ls^2 + \ms(2\Ls)^2+ \frac{4}{3} \ms\Ls^2\right]\overline{\Omega}_\Ts</math>
:<math>\overline{\Hs}_\mathrm{RTO}(\Os,\ts_\mathrm{after})= \Is_\mathrm{O}\overline{\Omega}_\Ts=\left( \Is_\mathrm{O}^\mathrm{anella}+ \Is_\mathrm{O}^\mathrm{braç} \right) \overline{\Omega}_\Ts= \left( \Is_\mathrm{G}^\mathrm{anella}+ \Is_\mathrm{O}^{\mathrm{anella}\otimes}+\Is_\mathrm{O}^\mathrm{braç} \right) \overline{\Omega}_\Ts = \left[ \ms\Ls^2 + \ms(2\Ls)^2+ \frac{4}{3} \ms\Ls^2\right]\overline{\Omega}_\Ts</math>


:<math>\left.\begin{array}{l}
:<math>\left.\begin{array}{l}
\bar{\mathrm{H}}_{\text {RTO }}\left(\Os, \mathrm{t}_{\text {després }}\right)=\left(\otimes \frac{19}{3} \ms\Ls^2 \Omega_{\mathrm{T}}\right) \\
\bar{\mathrm{H}}_{\text {RTO }}\left(\Os, \mathrm{t}_{\text {after }}\right)=\left(\otimes \frac{19}{3} \ms\Ls^2 \Omega_{\mathrm{T}}\right) \\
\bar{\mathrm{H}}_{\text {RTO }}\left(\Os, \mathrm{t}_{\text {abans }}\right)=\left[\otimes(\mathrm{n}-2) \mathrm{mLv}_0\right]
\bar{\mathrm{H}}_{\text {RTO }}\left(\Os, \mathrm{t}_{\text {before }}\right)=\left[\otimes(\mathrm{n}-2) \mathrm{mLv}_0\right]
\end{array}\right\} \Rightarrow \bar{\Omega}_{\mathrm{T}}=\left[\otimes(\mathrm{n}-2) \frac{19}{3} \frac{\mathrm{v}_0}{\mathrm{~L}}\right]</math>
\end{array}\right\} \Rightarrow \bar{\Omega}_{\mathrm{T}}=\left[\otimes(\mathrm{n}-2) \frac{19}{3} \frac{\mathrm{v}_0}{\mathrm{~L}}\right]</math>


:Per a n>2 , el sistema gira en sentit horari. Per a valors de n<2, el sistema gira en sentit antihorari. Per a n=2 , el sistema queda en repòs.
:For <math>n>2</math>, the system rotation is clockwise. For  <math>n<2</math>, it is counterclockwise. For <math>n=2</math>, the system is at rest.
:'''ANIMACIONS'''
:'''ANIMACIONS'''
</small>
</small>


====✏️ Exemple D8.6: sòlid lliure a l’espai ====
====✏️ EXAMPLE D8.6: free rigid body in space====
------
------
:<small>
:<small>
{|
{|
|
|
:[[Fitxer:ExD8-6-1-neut.png|thumb|left|180px|link=]]
:[[File:ExD8-6-1-neut.png|thumb|left|180px|link=]]
|El sòlid està format per dues plaques homogènies, de la mateixa massa i alçària però amplàries diferents, enganxades pel punt <math>\Os</math>.<u> Es tracta d’investigar si alguna magnitud dinàmica es conserva quan es llança enlaire.</u>Es negligeixen les interaccions aerodinàmiques.<br>
|The rigid body consists of two homogeneous plates, with the same mass and height but different widths, glued at point <math>\Os</math>. We want to investigate whether any dynamic magnitude is conserved when it is launched in the air. Aerodynamic interactions are neglected.<br>


|}
|}
:<u>Hi ha conservació de la quantitat de moviment?</u>.<br>
:<u>Is the linear momentum conserved?</u><br>


:El sòlid està sotmès a l’atracció gravitatòria terrestre com a única força externa. Per tant, la component vertical de la quantitat de moviment respecte del terra no es conserva, però les horitzontals sí..<br>
:The Earth's gravitational attraction as the only external force on the rigid body. Therefore, the vertical component of the linear momentum relative to the ground is not conserved, but the horizontal components are.<br>


:Ja que la quantitat de moviment respecte del terra i la velocitat del centre d’inèrcia <math>\vel{G=O}{T}</math> són estrictament proporcionals, les components horitzontals de <math>\vel{G}{T}</math> es mantenen constants..
:Since the linear momentum relative to the ground and the velocity of the center of inertia <math>\vel{G=O}{E}</math> are strictly proportional, the horizontal components of <math>\vel{G}{E}</math> are also constant.


:<u>Hi ha conservació del moment cinètic?</u>
:<u>Is the angular momentum conserved?</u>


:El <span style="text-decoration: underline;"> [[D3. Interaccions entre sòlids rígids#D3.2 Atracció gravitatòria|'''torsor gravitatori''']]</span> al centre de gravetat <math>\Gs</math> (que coincideix amb el centre d’inèrcia <math>\Os</math>) es redueix a una força resultant i cap moment. Per tant:
:The <span style="text-decoration: underline;"> [[D3. Interaccions entre sòlids rígids#D3.2 Atracció gravitatòria|'''gravitational torsor''']]</span> at the gravity centre <math>\Gs</math> (which is the same point as the inertia centre <math>\Os</math>) reduces to a resultant force and no moment. Therefore:


:<math>\sum\overline{\mathrm{M}}_\mathrm{ext}(\Gs)=\overline{0}=\dot{\overline{\mathrm{H}}}_\mathrm{RTG} (\Gs) \quad \Rightarrow \quad \overline{\mathrm{H}}_\mathrm{RTG} (\Gs) \mathrm{CONSTANT!}</math>
:<math>\sum\overline{\mathrm{M}}_\mathrm{ext}(\Gs)=\overline{0}=\dot{\overline{\mathrm{H}}}_\mathrm{RTG} (\Gs) \quad \Rightarrow \quad \overline{\mathrm{H}}_\mathrm{RTG} (\Gs) \mathrm{CONSTANT!}</math>


:Per al cas del sòlid que s’estudia: <math>\overline{\mathrm{H}}_\mathrm{RTG} (\Gs) = \Is\Is (\Gs) \velang{}{RTG} = \Is\Is (\Gs) \velang{}{T}.</math>
:For the rigid body under study: <math>\overline{\mathrm{H}}_\mathrm{RTG} (\Gs) = \Is\Is (\Gs) \velang{}{RTG} = \Is\Is (\Gs) \velang{}{T}.</math>
 
:El moment cinètic i la velocitat angular no són proporcionals en general (només ho són quan la direcció de la velocitat angular és una  <span style="text-decoration: underline;"> [[D5. Geometria de masses#D5.3 Eixos principals d'inèrcia|'''direcció principal d’inèrcia''']]</span> per al centre d’inèrcia <math>\Gs</math> ), i la conservació del primer no implica la constància de la segona.
 
:<u> Avaluació qualitativa del tensor d’inèrcia</u>


:En tractar-se les dues plaques de sòlids plans simètrics:
:The angular momentum and the angular velocity are not proportional in general (they are only proportional when the direction of angular velocity is a <span style="text-decoration: underline;"> [[D5. Geometria de masses#D5.3 Eixos principals d'inèrcia|'''a principal direction of inertia''']]</span> for the centre of inertia <math>\Gs</math> (section D5.3)), and the conservation of the former does not imply that of the latter.


:<u>Qualitative assessment of the inertia tensor</u>


:<math>\left[\Is\Is(\Gs)\right]=\left[\Is\Is(\Gs)\right]_\text{placa inf} + \left[\Is\Is(\Gs)\right]_\text{placa sup.} = \diag{\Is_{11}}{\Is_{11} + \Is_{33}}{\Is_{33}}+ \diag{2\Is}{\Is}{\Is} , \text{ amb} \Is_{11}<\Is_{33}.</math>
:Since the two plates are symmetrical
:<math>\left[\Is\Is(\Gs)\right]=\left[\Is\Is(\Gs)\right]_\text{lower plate} + \left[\Is\Is(\Gs)\right]_\text{upper plate} = \diag{\Is_{11}}{\Is_{11} + \Is_{33}}{\Is_{33}}+ \diag{2\Is}{\Is}{\Is} , \text{ amb} \Is_{11}<\Is_{33}.</math>


:<u>Avaluació quantitativa del tensor d’inèrcia</u>
:<u>Quantitative assessment of the inertia tensor</u>




:<math>\left[\Is\Is(\Gs)\right]=\frac{1}{3} \ms\Ls^2 \diag{1}{1+4}{4}+\frac{1}{3} \ms\Ls^2 \diag{2}{1}{1}=\frac{1}{3} \ms\Ls^2 \diag{3}{6}{5} \equiv \diag{\Is_\mathrm{petit}}{\Is_\mathrm{gran}}{\Is_\mathrm{mitjà}}</math>
:<math>\left[\Is\Is(\Gs)\right]=\frac{1}{3} \ms\Ls^2 \diag{1}{1+4}{4}+\frac{1}{3} \ms\Ls^2 \diag{2}{1}{1}=\frac{1}{3} \ms\Ls^2 \diag{3}{6}{5} \equiv \diag{\Is_\mathrm{low}}{\Is_\mathrm{high}}{\Is_\mathrm{medium}}</math>


:Les direccions 1, 2 i 3 són les direccions principals d’inèrcia per a <math>\Gs</math>.
:The directions 1, 2 and 3 are the inertia principal directions for point <math>\Gs</math>.


:<u>Cálcul del moment cinètic</u>
:<u>Angular momentum calculation</u>


:<math>\left\{\overline{\mathrm{H}}_\mathrm{RTG} (\Gs)\right\}=\diag{\Is_\mathrm{petit}}{\Is_\mathrm{gran}}{\Is_\mathrm{mitjà}} \vector{\Omega_1}{\Omega_2}{\Omega_3}=\vector{\Is_\mathrm{petit}\Omega_1}{\Is_\mathrm{gran}\Omega_2}{\Is_\mathrm{mitjà}\Omega_3}</math>,no és proporcional a <math>\velang{}{T}</math> en principi.  
:<math>\left\{\overline{\mathrm{H}}_\mathrm{RTG} (\Gs)\right\}=\diag{\Is_\mathrm{low}}{\Is_\mathrm{high}}{\Is_\mathrm{medium}} \vector{\Omega_1}{\Omega_2}{\Omega_3}=\vector{\Is_\mathrm{low}\Omega_1}{\Is_\mathrm{high}\Omega_2}{\Is_\mathrm{medium}\Omega_3}</math>, is not proportional to  <math>\velang{}{T}</math> in principle.


:Si la velocitat angular inicial és exclusivament en una de les tres direccions (és a dir, si la seva direcció es principal d’inèrcia per a <math>\Gs</math>), llavors sí que hi ha proporcionalitat entre <math>\overline{\mathrm{H}}_\mathrm{RTG} (\Gs)</math> i <math>\velang{}{T}</math>, i la conservació del primer implica la de la segona.
:If the initial angular velocity is exclusively in one of the three directions (that is, if its direction is a principal direction of inertia for <math>\Gs</math>), then there is proportionality between <math>\overline{\mathrm{H}}_\mathrm{RTG} (\Gs)</math> and <math>\velang{}{T}</math>,and the conservation of the former implies that of the latter.




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</small>
</small>


====✏️ Exemple D8.7: giroscopi ====
====✏️ EXAMPLE D8.7: gyroscope====
------
------
:<small>
:<small>
{|
{|
|
|
:[[Fitxer:ExD8-7-1-cat.png|thumb|left|180px|link=]]
:[[File:ExD8-7-1-eng.png|thumb|left|180px|link=]]
|El sistema consta d’un disc homogeni, de massa m i radi r, que està articulat a un suport de massa negligible, i d’una forquilla que pot girar lliurement al voltant de l’eix vertical. Entre suport i forquilla hi ha un motor. El moment d’inèrcia del suport respecte de l’eix vertical que passa pel centre del disc és <math>\Is=(\lambda/2)\ms\rs^2</math>. Inicialment <math>(\ts_\mathrm{incial}</math> el disc està paral·lel a terra, i gira amb velocitat angular vertical <math>\velang{disc}{T}=\psio</math> . Es negligeixen les friccions associades a totes les articulacions. <u> Es tracta d’investigar com es mou el suport quan el motor canvia l’orientació del disc respecte del terra .</u>
|The system consists of a homogeneous disk with mass m and radius r, articulated to a massless support, and a fork that can rotate freely about the vertical axis. There is a motor between the support and the fork. The inertia moment of the support with respect to the vertical axis through the center of the disk is <math>\Is=(\lambda/2)\ms\rs^2</math>. Initially <math>(\ts_\mathrm{incial}</math> the disk is parallel to the ground, and rotates with vertical angular velocity <math>\velang{disc}{T}=\psio</math>. The friction associated with all the joints is neglected. We want to <u> investigate how the support moves when the motor changes the disk orientation relative to the ground.</u>


|}
|}
:<u>Hi ha conservació del moment cinètic?</u>.<br>
:<u>Is the angular momentum conserved?</u><br>


:Per al SISTEMA disc, el moment total respecte del seu centre d’inèrcia <math>\Gs</math> és nul en la direcció del seu eix. El motor pot canviar l’orientació d’aquest eix respecte del terra (i respecte de qualsevol referència que es traslladi respecte del terra), i per tant <u>no es tracta d’una direcció fixa al terra</u> (per tant, tampoc a la RTG): no es conserva el moment cinètic en aquesta direcció.<br>
:For the disk SYSTEM, the resultant moment about its centre of inertia <math>\Gs</math> is zero in the direction of its axis. The motor can change the orientation of this axis relative to the ground (and relative to any reference frame with a translational motion relative to the ground), and therefore <u>it is not a direction fixed to the ground</u> (so not to the RTG either): the angular momentum is not conserved in this direction.<br>


:Per al SISTEMA (disc + suport + forquilla), el moment total respecte del centre del disc <math>\Os</math> és nul en la direcció vertical, que sí que és fixa a terra. Per tant:
:For the SYSTEM (disk + support + fork), the resulting moment relative to the center of the disk <math>\Os</math> is zero in the vertical direction, which is fixed to the ground. Therefore:


:<math> \left.\sum \overline{\Ms}_\mathrm{ext}(\Os)\right]_\mathrm{vert} =0 \quad \Rightarrow \quad \left.\overline{\Hs}_\mathrm{RTO=T}(\Os) \right]_\mathrm{vert}  \text{  CONSTANT!} </math>
:<math> \left.\sum \overline{\Ms}_\mathrm{ext}(\Os)\right]_\mathrm{vert} =0 \quad \Rightarrow \quad \left.\overline{\Hs}_\mathrm{RTO=T}(\Os) \right]_\mathrm{vert}  \text{  CONSTANT!} </math>


:Mentre el motor canvia l’orientació del pla del disc <math>(\dot{\theta} \neq 0)</math> , apareix la rotació del suport al voltant de l’eix vertical <math>\dot{\psi}</math> . El moment cinètic a <math>\Os</math> en cada instant és:
:As the motor changes the orientation of the disk plane <math>(\dot{\theta} \neq 0)</math>, the support rotates around the vertical axis <math>\dot{\psi}</math>. The angular momentum at <math>\Os</math> is:
:[[Fitxer:ExD8-7-2-neut.png|thumb|right|180px|link=]]
:[[File:ExD8-7-2-neut.png|thumb|right|180px|link=]]


:<math>\overline{\Hs}_\mathrm{RTO=T}(\Os,\ts)=\Is\Is^\mathrm{forq}(\Os)\velang{forq}{T}(\ts)+\Is\Is^\mathrm{disc}(\Os)\velang{disc}{T}(\ts)=\Is\Is^\mathrm{forq}(\Os)\dot{\psi}+\Is\Is^\mathrm{forq}(\Os)\left( \overline{\dot{\psi}}+ \overline{\dot{\theta}}+ \overline{\dot{\varphi}}\right)</math>
:<math>\overline{\Hs}_\mathrm{RTO=E}(\Os,\ts)=\Is\Is^\mathrm{sup}(\Os)\velang{sup}{E}(\ts)+\Is\Is^\mathrm{disk}(\Os)\velang{disk}{E}(\ts)=\Is\Is^\mathrm{sup}(\Os)\dot{\psi}+\Is\Is^\mathrm{disk}(\Os)\left( \overline{\dot{\psi}}+ \overline{\dot{\theta}}+ \overline{\dot{\varphi}}\right)</math>




:<math>\braq{\overline{\Hs}_\Ts^\mathrm{forq}(\Os,\ts)}{B}=\diag{\Is_{11}}{\Is_{22}}{(\lambda/2)\ms\rs^2}\vector{0}{0}{\dot{\psi}}=\vector{0}{0}{(\lambda/2)\ms\rs^2 \dot{\psi}},</math>
:<math>\braq{\overline{\Hs}_\Es^\mathrm{sup}(\Os,\ts)}{B}=\diag{\Is_{11}}{\Is_{22}}{(\lambda/2)\ms\rs^2}\vector{0}{0}{\dot{\psi}}=\vector{0}{0}{(\lambda/2)\ms\rs^2 \dot{\psi}},</math>




:<math>\braq{\overline{\Hs}_\Ts^\mathrm{disc}(\Os,\ts)}{B'}=\frac{1}{4}\ms\rs^2\diag{1}{1}{2}\vector{-\dot{\theta}}{-\dot{\psi} \sin\theta}{\dot{\varphi}+\dot{\psi}\cos\theta}=\frac{1}{4}\ms\rs^2\vector{-\dot{\theta}}{-\dot{\psi} \sin\theta}{2(\dot{\varphi}+\dot{\psi}\cos\theta)}</math>
:<math>\braq{\overline{\Hs}_\Es^\mathrm{disk}(\Os,\ts)}{B'}=\frac{1}{4}\ms\rs^2\diag{1}{1}{2}\vector{-\dot{\theta}}{-\dot{\psi} \sin\theta}{\dot{\varphi}+\dot{\psi}\cos\theta}=\frac{1}{4}\ms\rs^2\vector{-\dot{\theta}}{-\dot{\psi} \sin\theta}{2(\dot{\varphi}+\dot{\psi}\cos\theta)}</math>




:El moment cinètic en direcció vertical prové de la projecció de les components 2 i 3:
:The angular momentum in the vertical direction comes from the projection of components 2 and 3:


:<math>\left.\overline{\Hs}_\Ts(\Os,\ts)\right]_\mathrm{vert} =\overline{\Hs}_\Ts^\mathrm{sup}(\Os,\ts)+ \left.\overline{\Hs}_\Ts^ \mathrm{disc} (\Os,\ts) \right]_{3'}\cos\theta - \left.\overline{\Hs}_\Ts^\mathrm{disc}(\Os,\ts)\right]_{2'} \sin\theta  ,</math>
:<math>\left.\overline{\Hs}_\Es(\Os,\ts)\right]_\mathrm{vert} =\overline{\Hs}_\Es^\mathrm{sup}(\Os,\ts)+ \left.\overline{\Hs}_\Es^ \mathrm{disk} (\Os,\ts) \right]_{3'}\cos\theta - \left.\overline{\Hs}_\Es^\mathrm{disk}(\Os,\ts)\right]_{2'} \sin\theta  ,</math>


:<math>\left.\overline{\Hs}_\Ts(\Os,\ts)\right]_\mathrm{vert} = \left(\Uparrow \frac{\lambda}{2}\ms\rs^2\dot{\psi}\right)+ \left(\Uparrow \frac{1}{4}\ms\rs^2\left[2\dot{\varphi}\cos\theta+\dot{\psi}(1+\cos^2\theta)\right]\right)</math>
:<math>\left.\overline{\Hs}_\Es(\Os,\ts)\right]_\mathrm{vert} = \left(\Uparrow \frac{\lambda}{2}\ms\rs^2\dot{\psi}\right)+ \left(\Uparrow \frac{1}{4}\ms\rs^2\left[2\dot{\varphi}\cos\theta+\dot{\psi}(1+\cos^2\theta)\right]\right)</math>




:Imposant la conservació de moment cinètic vertical:
:Taking into account the conservation of the vertical angular momentum:


:<math>\left.\begin{array}{ll}
:<math>\left.\begin{array}{ll}
\left.\overline{\mathrm{H}}_{\mathrm{T}}(\mathbf{O}, \mathrm{t})\right]_{\text {vert }}=\left(\Uparrow \frac{1}{4} \mathrm{mr}^2\left[2 \dot{\varphi} \cos \theta+\dot{\psi}\left(1+2 \lambda+\cos ^2 \theta\right)\right]\right) \\
\left.\overline{\mathrm{H}}_{\mathrm{E}}(\mathbf{O}, \mathrm{t})\right]_{\text {vert }}=\left(\Uparrow \frac{1}{4} \mathrm{mr}^2\left[2 \dot{\varphi} \cos \theta+\dot{\psi}\left(1+2 \lambda+\cos ^2 \theta\right)\right]\right) \\
\left.\begin{array}{l}
\left.\begin{array}{l}
\dot{\psi}\left(\mathrm{t}_{\text {inicial }}\right)=0 \\
\dot{\psi}\left(\mathrm{t}_{\text {initial }}\right)=0 \\
\dot{\varphi}\left(\mathrm{t}_{\text {inicial }}\right)=\dot{\varphi}_0 \\
\dot{\varphi}\left(\mathrm{t}_{\text {initial }}\right)=\dot{\varphi}_0 \\
\theta\left(\mathrm{t}_{\text {inicial }}\right)=0
\theta\left(\mathrm{t}_{\text {initial }}\right)=0
\end{array}\right\} \left.\Rightarrow \overline{\mathrm{H}}_{\mathrm{T}}\left(\mathbf{O}, \mathrm{t}_{\text {inicial }}\right)\right]_{\text {vert }}=\left[\Uparrow\left(\frac{1}{2} \mathrm{mr}^2 \dot{\varphi}_0\right)\right]  \\
\end{array}\right\} \left.\Rightarrow \overline{\mathrm{H}}_{\mathrm{T}}\left(\mathbf{O}, \mathrm{t}_{\text {initial }}\right)\right]_{\text {vert }}=\left[\Uparrow\left(\frac{1}{2} \mathrm{mr}^2 \dot{\varphi}_0\right)\right]  \\
\end{array}\right\}
\end{array}\right\}
\Rightarrow 2 \dot{\varphi} \cos \theta+\dot{\psi}\left(1+2 \lambda+\cos ^2 \theta\right)=2 \dot{\varphi}_0</math>
\Rightarrow 2 \dot{\varphi} \cos \theta+\dot{\psi}\left(1+2 \lambda+\cos ^2 \theta\right)=2 \dot{\varphi}_0</math>




:Per altra banda, per al SISTEMA disc, el moment extern en la direcció de l’eix del disc (direcció 3’) és nul.
:On the other hand, for the SYSTEM disk, the external moment in the direction of the disk axis (direction 3') is zero. Hence, <math>\left.\dot{\overline{\Hs}}_\mathrm{disk,T}(\Os)\right]_{3'}=0</math>
 
:Per tant, <math>\left.\dot{\overline{\Hs}}_\mathrm{disc,T}(\Os)\right]_{3'}=0</math>


:<math>\braq{\dot{\overline{\Hs}}_\mathrm{disc,T}(\Os,\ts)}{B'}=\frac{1}{4}\ms\rs^2 \vector{-\ddot{\theta}}{-\ddot{\psi} \sin\theta -\dot{\psi}\dot{\theta}\cos\theta}{2(\ddot{\varphi}+\ddot{\psi}\cos\theta-\dot{\psi}\dot{\theta}\sin\theta)} + \vector{-\dot{\theta}}{-\dot{\psi}\sin\theta}{\dot{\psi}\cos\theta}\times\frac{1}{4}\ms\rs^2\vector{-\dot{\theta}}{-\dot{\psi}\sin\theta}{2(\dot{\varphi}+\dot{\psi}\cos\theta)}=</math>
:<math>\braq{\dot{\overline{\Hs}}_\mathrm{disk,E}(\Os,\ts)}{B'}=\frac{1}{4}\ms\rs^2 \vector{-\ddot{\theta}}{-\ddot{\psi} \sin\theta -\dot{\psi}\dot{\theta}\cos\theta}{2(\ddot{\varphi}+\ddot{\psi}\cos\theta-\dot{\psi}\dot{\theta}\sin\theta)} + \vector{-\dot{\theta}}{-\dot{\psi}\sin\theta}{\dot{\psi}\cos\theta}\times\frac{1}{4}\ms\rs^2\vector{-\dot{\theta}}{-\dot{\psi}\sin\theta}{2(\dot{\varphi}+\dot{\psi}\cos\theta)}=</math>




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:[[Fitxer:ExD8-7-3D-neut.png|thumb|right|350px|link=]]
:[[File:ExD8-7-3D-neut.png|thumb|right|350px|link=]]
:La integració d’aquesta equació condueix a: <math>\dot{\varphi}+\dot{\psi}\cos\theta=\dot{\varphi}_0</math> , on <math>\dot{\varphi}_0</math> és la constant d’integració, que es determina imposant les condicions inicials.
:The integration of that equation yields: <math>\dot{\varphi}+\dot{\psi}\cos\theta=\dot{\varphi}_0</math>, where <math>\dot{\varphi}_0</math> is the integration constant, which may be found from the initial conditions.


:Combinant aquest resultat amb l’anterior:
:Combination of this result with the previous one yields:


:<math>\left.\begin{array}{l}
:<math>\left.\begin{array}{l}
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:[[Fitxer:ExD8-7-3-2D-neut.png|thumb|center|210px|link=]]
:[[File:ExD8-7-3-2D-neut.png|thumb|center|210px|link=]]
</small>
</small>


====✏️ Exemple D8.8: barra dins de guia llisa giratòria ====
====✏️ EXAMPLE D8.8: bar in a smooth rotating circular guide====
------
------
:<small>
:<small>
{|
{|
|
|
:[[Fitxer:ExD8-8-1-cat.png|thumb|left|180px|link=]]
:[[File:ExD8-8-1-eng.png|thumb|left|180px|link=]]
|La barra '''PQ''', homogènia i de massa m, es mou mantenint els seus dos extrems dins d’una guia llisa <math>(\mu=0)</math> , de radi r i massa negligible, que pot girar lliurement al voltant de la direcció vertical. L’angle POQ és de <math>120^o</math>. Es tracta de determinar <u>l’equació del moviment per a la coordenada</u> <math>\psi</math> . Es negligeix la rotació de la barra sobre el seu eix (rotació pròpia <math>\dot{\varphi}</math> ).
|The homogeneous bar '''PQ''', with mass m, moves with its two endpoins inside a smooth guide <math>(\mu=0)</math>, with radius r and negligible mass, which can rotate freely around the vertical direction. The '''POQ''' angle is <math>120^o</math>. We want to <u>find the equation of motion for the coordinate <math>\psi</math></u>. The rotation of the bar on its axis (spin <math>\dot{\varphi}</math>) is neglected.
|}


|}
:<u>Is the linear momentum conserved?</u><br>
:<u>Hi ha conservació de la quantitat de moviment?</u>.<br>
:The external forces on the bar are not zero: in addition to the weight, there are normal forces from the guide on the bar at <math>\Ps</math> and <math>\Qs</math> (directed towards <math>\Os</math>) and a force component perpendicular to the plane of the guide. Therefore, the resultant external force on the bar has components in the three directions of space, and the linear momentum is not conserved.
:Les forces externes sobre la barra no són nul·les: a més del pes, hi ha forces de la guia sobre la barra a <math>\Ps</math> i a <math>\Qs</math> que només tenen component normal (dirigida cap a <math>\Os</math>) i component perpendicular al pla de la guia. En total, doncs, la força externa resultant sobre la barra té components en les tres direccions de l’espai, i la quantitat de moviment no es conserva.


:Si s’analitzen les forces externes sobre el SISTEMA (barra + guia), la conclusió és la mateixa: a més del pes de la barra, hi ha la força d’enllaç associada al coixinet entre terra i guia, que té tres components no nul·les en principi.
:If we analyze the external forces on the SYSTEM (bar + guide), the conclusion is the same: in addition to the weight of the bar, there is the constraint force associated with the bearing between the ground and the guide, which has three non-zero components in principle.


:<u>Hi ha conservació del moment cinètic?</u>
:<u>Is the angular momentum conserved?</u>


:Per al SISTEMA (barra + guia), el moment extern sobre qualsevol punt de l’eix de rotació de la guia (en particular, per al punt <math>\Os</math>) component vertical nul·la (doncs el moment d’enllaç del coixinet en aquesta direcció és nul, i el pes no pot donar moment en direcció vertical). Per altra banda, l’acceleració angular de la guia respecte del terra <math>\left(\overline{\ddot{\psi}}\right)</math> té aquesta direcció. Per tant:
:For the SYSTEM (bar + guide), the external moment about any point on the axis of rotation of the guide (in particular, for point <math>\Os</math>) has a zero vertical component (since the constraint moment of the bearing in that direction is zero, and the weight cannot yield a moment in the vertical direction). On the other hand, the angular acceleration of the guide relative to the ground <math>\left(\overline{\ddot{\psi}}\right)</math> is vertical. Therefore:


:<math>\boxed{\left.\text{Full de ruta: SISTEMA (barra+guia), TMC a }\Os\right]_\mathrm{vert}}</math>
:<math>\boxed{\left.\text{Roadmap: SYSTEM (bar+guide), AMT at }\Os\right]_\mathrm{vert}}</math>




Line 512: Line 508:




:L’únic element amb massa és la barra, i el punt <math>\Os</math> hi pertany cinemàticament :
:The only element with nonzero mass is the bar, and point <math>\Os</math> is fixed to it:


:[[Fitxer:ExD8-8-2-neut.png|thumb|right|270px|link=]]
:[[File:ExD8-8-2-neut.png|thumb|right|270px|link=]]


:<math>\overline{\Hs}_\mathrm{RTO}(\Os)=\Is\Is(\Os)\velang{barra}{RTO=T}=\left[\Is\Is(\Gs)+\Is\Is^\bigoplus(\Os)\right]\left(\overline{\dot{\psi}}+\overline{\dot{\theta}}\right)</math>
:<math>\overline{\Hs}_\mathrm{RTO}(\Os)=\Is\Is(\Os)\velang{bar}{RTO=E}=\left[\Is\Is(\Gs)+\Is\Is^\bigoplus(\Os)\right]\left(\overline{\dot{\psi}}+\overline{\dot{\theta}}\right)</math>




Line 532: Line 528:




:<u>Comentari rellevant</u>
:<u>Relevant comment</u>
:[[Fitxer:ExD8-8-3-neut.png|thumb|right|430px|link=]]
:[[File:ExD8-8-3-neut.png|thumb|right|430px|link=]]


:El moment cinètic vertical no es conserva ni a <math>\Qs</math> ni a <math>\Ps</math> perquè tots dos punts estan accelerats:
:The vertical angular momentum at <math>\Qs</math> and <math>\Ps</math> is not conserved since those two points are accelerated:


:<math>\sum \overline{\bar{\Ms}}_{\text {ext }}(\mathbf{Q})-\overline{\mathbf{P G}} \times \ms \overline{\mathrm{a}}_{\text {Gal }}(\mathbf{Q})=\dot{\overline{\mathrm{H}}}_{\text {RTQ }}(\mathbf{Q}), \quad \overline{\mathbf{QG}} \times \ms \overline{\mathrm{a}}_{\text {Gal }}(\mathbf{Q})=\overline{\mathbf{QG}} \times \mathrm{m}\left[\overline{\mathrm{a}}_{\text {RЕL }}(\mathbf{Q})+\overline{\mathrm{a}}_{\mathrm{ar}}(\mathbf{Q})+\overline{\mathrm{a}}_{\text {cor }}(\mathbf{Q})\right]</math>  
:<math>\sum \overline{\bar{\Ms}}_{\text {ext }}(\mathbf{Q})-\overline{\mathbf{P G}} \times \ms \overline{\mathrm{a}}_{\text {Gal }}(\mathbf{Q})=\dot{\overline{\mathrm{H}}}_{\text {RTQ }}(\mathbf{Q}), \quad \overline{\mathbf{QG}} \times \ms \overline{\mathrm{a}}_{\text {Gal }}(\mathbf{Q})=\overline{\mathbf{QG}} \times \mathrm{m}\left[\overline{\mathrm{a}}_{\text {RЕL }}(\mathbf{Q})+\overline{\mathrm{a}}_{\mathrm{tr}}(\mathbf{Q})+\overline{\mathrm{a}}_{\text {cor }}(\mathbf{Q})\right]</math>  


:<math> \left\{\overline{\mathbf{Q G}} \times \ms \bar{\mathrm{a}}_{\mathrm{Gal}}(\mathbf{Q})\right\}=\left\{\begin{array}{c}
:<math> \left\{\overline{\mathbf{Q G}} \times \ms \bar{\mathrm{a}}_{\mathrm{Gal}}(\mathbf{Q})\right\}=\left\{\begin{array}{c}
Line 548: Line 544:
\mathrm{a}_{\mathrm{REL}}^{\mathrm{s}} \cos \left(30^{\circ}-\theta\right)+\mathrm{a}_{\mathrm{REL}}^{\mathrm{n}} \sin \left(30^{\circ}-\theta\right)
\mathrm{a}_{\mathrm{REL}}^{\mathrm{s}} \cos \left(30^{\circ}-\theta\right)+\mathrm{a}_{\mathrm{REL}}^{\mathrm{n}} \sin \left(30^{\circ}-\theta\right)
\end{array}\right\}+\left\{\begin{array}{c}
\end{array}\right\}+\left\{\begin{array}{c}
\mathrm{a}_{\mathrm{ar}}^{\mathrm{s}}-\mathrm{a}_{\mathrm{Cor}} \\
\mathrm{a}_{\mathrm{tr}}^{\mathrm{s}}-\mathrm{a}_{\mathrm{Cor}} \\
-\mathrm{a}_{\mathrm{ar}}^{\mathrm{n}} \\
-\mathrm{a}_{\mathrm{tr}}^{\mathrm{n}} \\
0
0
\end{array}\right\}\right]
\end{array}\right\}\right]
</math>
</math>


:<math>\left.\left.\left.\overline{\mathbf{Q G}} \times \ms \overline{\mathrm{a}}_{\text {Gal }}(\mathbf{Q})\right]_{\text {vert }}=\overline{\mathbf{QG}} \times \ms \overline{\mathrm{a}}_{\text {Gal }}(\mathbf{Q})\right]_{3^{\prime}}=\sqrt{3} \mathrm{m}\left(\mathrm{a}_{\text {Cor }}-\mathrm{a}_{\mathrm{ar}}^{\mathrm{s}}\right) \sin \theta \neq 0 \quad \Rightarrow \quad \dot{\bar{\Hs}}_{\text {RTQ }}(\mathbf{Q})\right]_{\text {vert }} \neq 0
:<math>\left.\left.\left.\overline{\mathbf{Q G}} \times \ms \overline{\mathrm{a}}_{\text {Gal }}(\mathbf{Q})\right]_{\text {vert }}=\overline{\mathbf{QG}} \times \ms \overline{\mathrm{a}}_{\text {Gal }}(\mathbf{Q})\right]_{3^{\prime}}=\sqrt{3} \mathrm{m}\left(\mathrm{a}_{\text {Cor }}-\mathrm{a}_{\mathrm{tr}}^{\mathrm{s}}\right) \sin \theta \neq 0 \quad \Rightarrow \quad \dot{\bar{\Hs}}_{\text {RTQ }}(\mathbf{Q})\right]_{\text {vert }} \neq 0
</math>
</math>


:<math>\mu=\text{datos.mean()}</math>
:<math>\sigma=\text{datos.std()}</math>


</small>
</small>

Latest revision as of 18:38, 4 November 2024

[math]\displaystyle{ \newcommand{\uvec}{\overline{\textbf{u}}} \newcommand{\vvec}{\overline{\textbf{v}}} \newcommand{\evec}{\overline{\textbf{e}}} \newcommand{\Omegavec}{\overline{\mathbf{\Omega}}} \newcommand{\velang}[2]{\Omegavec^{\textrm{#1}}_{\textrm{#2}}} \newcommand{\Alfavec}{\overline{\mathbf{\alpha}}} \newcommand{\accang}[2]{\Alfavec^{\textrm{#1}}_{\textrm{#2}}} \newcommand{\ds}{\textrm{d}} \newcommand{\ps}{\textrm{p}} \newcommand{\ns}{\textrm{n}} \newcommand{\hs}{\textrm{h}} \newcommand{\cs}{\textrm{c}} \newcommand{\gs}{\textrm{g}} \newcommand{\Ns}{\textrm{N}} \newcommand{\Hs}{\textrm{H}} \newcommand{\Fs}{\textrm{F}} \newcommand{\ms}{\textrm{m}} \newcommand{\ts}{\textrm{t}} \newcommand{\us}{\textrm{u}} \newcommand{\vs}{\textrm{v}} \newcommand{\Rs}{\textrm{R}} \newcommand{\Ts}{\textrm{T}} \newcommand{\Ls}{\textrm{L}} \newcommand{\As}{\textrm{A}} \newcommand{\Ds}{\textrm{D}} \newcommand{\Bs}{\textrm{B}} \newcommand{\es}{\textrm{e}} \newcommand{\fs}{\textrm{f}} \newcommand{\is}{\textrm{i}} \newcommand{\Is}{\textrm{I}} \newcommand{\ks}{\textrm{k}} \newcommand{\js}{\textrm{j}} \newcommand{\rs}{\textrm{r}} \newcommand{\ss}{\textrm{s}} \newcommand{\Os}{\textbf{O}} \newcommand{\Gs}{\textbf{G}} \newcommand{\Cbf}{\textbf{C}} \newcommand{\Or}{\Os_\Rs} \newcommand{\Qs}{\textbf{Q}} \newcommand{\Cs}{\textbf{C}} \newcommand{\Ps}{\textbf{P}} \newcommand{\Ss}{\textbf{S}} \newcommand{\Js}{\textbf{J}} \newcommand{\P}{\textrm{P}} \newcommand{\Q}{\textrm{Q}} \newcommand{\Ms}{\textrm{M}} \newcommand{\deg}{^\textsf{o}} \newcommand{\xs}{\textsf{x}} \newcommand{\ys}{\textsf{y}} \newcommand{\zs}{\textsf{z}} \newcommand{\dert}[2]{\left.\frac{\ds{#1}}{\ds\ts}\right]_{\textrm{#2}}} \newcommand{\ddert}[2]{\left.\frac{\ds^2{#1}}{\ds\ts^2}\right]_{\textrm{#2}}} \newcommand{\vec}[1]{\overline{#1}} \newcommand{\vecbf}[1]{\overline{\textbf{#1}}} \newcommand{\vecdot}[1]{\overline{\dot{#1}}} \newcommand{\OQvec}{\vec{\Os\Qs}} \newcommand{\GQvec}{\vec{\Gs\Qs}} \newcommand{\GPvec}{\vec{\Gs\Ps}} \newcommand{\PSvec}{\vec{\Ps\Ss}} \newcommand{\QQvec}{\vec{\Qs\Qs}} \newcommand{\QGvec}{\vec{\Qs\Gs}} \newcommand{\QPvec}{\vec{\Qs\Ps}} \newcommand{\JQvec}{\vec{\Js\Qs}} \newcommand{\GJvec}{\vec{\Gs\Js}} \newcommand{\OPvec}{\vec{\Os\textbf{P}}} \newcommand{\OCvec}{\vec{\Os\Cs}} \newcommand{\OGvec}{\vec{\Os\Gs}} \newcommand{\GCvec}{\vec{\Gs\Cs}} \newcommand{\PGvec}{\vec{\Ps\Gs}} \newcommand{\abs}[1]{\left|{#1}\right|} \newcommand{\braq}[2]{\left\{{#1}\right\}_{\textrm{#2}}} \newcommand{\matriz}[9]{ \begin{bmatrix} {#1} & {#2} & {#3}\\ {#4} & {#5} & {#6}\\ {#7} & {#8} & {#9} \end{bmatrix}} \newcommand{\diag}[3]{ \begin{bmatrix} {#1} & {0} & {0}\\ {0} & {#2} & {0}\\ {0} & {0} & {#3} \end{bmatrix}} \newcommand{\vector}[3]{ \begin{Bmatrix} {#1}\\ {#2}\\ {#3} \end{Bmatrix}} \newcommand{\vecdosd}[2]{ \begin{Bmatrix} {#1}\\ {#2} \end{Bmatrix}} \newcommand{\vel}[2]{\vvec_{\textrm{#2}} (\textbf{#1})} \newcommand{\acc}[2]{\vecbf{a}_{\textrm{#2}} (\textbf{#1})} \newcommand{\accs}[2]{\vecbf{a}_{\textrm{#2}}^{\textrm{s}} (\textbf{#1})} \newcommand{\accn}[2]{\vecbf{a}_{\textrm{#2}}^{\textrm{n}} (\textbf{#1})} \newcommand{\velo}[1]{\vvec_{\textrm{#1}}} \newcommand{\accso}[1]{\vecbf{a}_{\textrm{#1}}^{\textrm{s}}} \newcommand{\accno}[1]{\vecbf{a}_{\textrm{#1}}^{\textrm{n}}} \newcommand{\re}[2]{\Re_{\textrm{#2}}(\textbf{#1})} \newcommand{\psio}{\dot{\psi}_0} \newcommand{\Pll}{\textbf{P}_\textrm{lliure}} \newcommand{\agal}[1]{\vecbf{a}_{\textrm{Gal}} (#1)} \newcommand{\angal}[1]{\vecbf{a}_{\textrm{NGal}} (#1)} \newcommand{\vgal}[1]{\vecbf{v}_{\textrm{Gal}} (#1)} \newcommand{\fvec}[2]{\overline{\mathbf{F}}_{\textrm{#1}\rightarrow\textrm{#2}}} \newcommand{\mvec}[2]{\overline{\mathbf{M}}_{\textrm{#1}\rightarrow\textrm{#2}}} }[/math]


The vector theorems relate the variation of two dynamic magnitudes ([math]\displaystyle{ \overline{\Ds\Ms} }[/math]) that depend on the mass geometry and the motion of the system (the linear momentum and the angular momentum) with the resultant of the external actions on the system [math]\displaystyle{ (\sum \overline{\As\mathrm{C}_\mathrm{ext}}) }[/math] ( [math]\displaystyle{ \sum \overline{\As\mathrm{C}_\mathrm{ext}} }[/math] includes the external interactions and, if working in a non-Galilean reference frame,the associated inertial actions). In a generic way, these theorems can be written in the following form:

[math]\displaystyle{ \sum \overline{\As\mathrm{C}_\mathrm{ext}}=\dert{\overline{\Ds\Ms}}{R}. }[/math]


When in a direction fixed to the reference frame R(dfR) direction fixed to the reference frame R is conserved:[math]\displaystyle{ \left. \sum \overline{\As\mathrm{C}_\mathrm{ext}}\right]_\mathrm{dfR}=0 \Rightarrow \left. \overline{\Ds\Ms}\right]_\mathrm{dfR}=\text{constant} }[/math].

A conservation is an interesting property: it allows one to ignore the evolution of the system for a finite time and maintain a partial knowledge (if not all the components of [math]\displaystyle{ \overline{\Ds\Ms} }[/math]) are conserved) or a total knowledge (if the conservation occurs in the three directions of the space of R) of the system’s state.

Two important things have to be kept in mind when it comes to invoking conservations:

  • We have to be sure that the component of the external actions that is zero corresponds to a direction fixed in the reference frame (a zero value in a direction variable with respect to R means that the [math]\displaystyle{ \overline{\Ds\Ms} }[/math] component in that direction has a constant value, but not a constant direction!).
  • We have to remember that conservation refers to a dynamic magnitude and not a kinematic one (in principle). When the [math]\displaystyle{ \overline{\Ds\Ms} }[/math] is the linear momentum [math]\displaystyle{ (\overline{\Ds\Ms}=\Ms\vel{G}{R}) }[/math], as it is proportional to the velocity of the center of mass, the corresponding component of [math]\displaystyle{ \vel{G}{R} }[/math] is conserved. When it is the angular momentum of a single rigid body about a point that belongs to that rigid body [math]\displaystyle{ \overline{\Ds\Ms} }[/math] since in general it is not proportional to the angular velocity [math]\displaystyle{ (\overline{\Ds\Ms}=\overline{\mathrm{H}}_\mathrm{RTQ}(\Qs),\Qs \in \mathrm{S}) }[/math] the conservation of [math]\displaystyle{ \overline{\Ds\Ms} }[/math] does not imply that of [math]\displaystyle{ \velang{S}{R} }[/math].

Conservations are often the consequence of simplifications in the formulation of problems, such as neglecting friction. In real life, in general nothing is conserved.

💭 Proof ➕

Let’s project the vector thorem in a vector basis with a dierction fixed to the reference frame (for example, direction3):

[math]\displaystyle{ \sum \overline{\As\mathrm{C}_\mathrm{ext}}=\dert{\overline{\Ds\Ms}}{R} \quad \Rightarrow \quad \vector{\sum\As\mathrm{C}_1}{\sum\As\mathrm{C}_2}{\sum\As\mathrm{C}_3}=\left\{\dert{\overline{\Ds\Ms}}{R}\right\}=\vector{\dot{\Ds\Ms_1}}{\dot{\Ds\Ms_2}}{\dot{\Ds\Ms_3}}+\left\{\velang{B}{R}\right\}\times \vector{\Ds\Ms_1}{\Ds\Ms_2}{\Ds\Ms_3} }[/math]

Since direction 3 is fixed to R, the angular velocity of the vector basis relative to R [math]\displaystyle{ \velang{B}{R} }[/math] must have a component in that direction. Therefore:

[math]\displaystyle{ \vector{\sum\As\mathrm{C}_1}{\sum\As\mathrm{C}_2}{\sum\As\mathrm{C}_3}=\left\{\dert{\overline{\Ds\Ms}}{R}\right\}=\vector{\dot{\Ds\Ms_1}}{\dot{\Ds\Ms_2}}{\dot{\Ds\Ms_3}}=\vector{0}{0}{\Omega_3}\times \vector{\Ds\Ms_1}{\Ds\Ms_2}{\Ds\Ms_3}= \vector{\dot{\Ds\Ms_1}-\Omega_3\cdot\Ds\Ms_2}{\dot{\Ds\Ms_2}-\Omega_3\cdot\Ds\Ms_1}{\dot{\Ds\Ms_3}} }[/math]


Si [math]\displaystyle{ \sum \As\mathrm{C}_3=0 \quad \Rightarrow \quad \dot{\Ds\Ms_3}=0 \quad \Rightarrow \quad \Ds\Ms_3=\text{CONSTANT!}. }[/math]


However, if [math]\displaystyle{ \sum \As\mathrm{C}_1 }[/math] or [math]\displaystyle{ \sum \As\mathrm{C}_2 }[/math] are zero, the corresponding components in [math]\displaystyle{ \overline{\Ds\Ms} }[/math] ( [math]\displaystyle{ \Ds\Ms_1 }[/math] or [math]\displaystyle{ \Ds\Ms_2 }[/math]) are not constant in principle:


[math]\displaystyle{ \sum \As\mathrm{C}_1=0 \quad \Rightarrow \quad \dot{\Ds\Ms_1}-\Omega_3\cdot\Ds\Ms_2 =0 \quad \Rightarrow \quad \dot{\Ds\Ms_1}=\Omega_3\cdot\Ds\Ms_2 \quad \Rightarrow \quad \Ds\Ms_1 \neq \text{constant}, }[/math]

[math]\displaystyle{ \sum \As\mathrm{C}_2=0 \quad \Rightarrow \quad \dot{\Ds\Ms_2}+\Omega_3\cdot\Ds\Ms_1 =0 \quad \Rightarrow \quad \dot{\Ds\Ms_2}=-\Omega_3\cdot\Ds\Ms_1 \quad \Rightarrow \quad \Ds\Ms_2 \neq \text{constant} . }[/math]

D8.1 Examples

✏️ EXAMPLE D8.1: person jumping on a platform

ExD8-1-1-eng.png
A person of mass M, moving at speed [math]\displaystyle{ \mathrm{v}_0 }[/math] on a smooth ground [math]\displaystyle{ (\mu=0) }[/math], jumps onto a platform of mass m which is initially at rest with respect to the floor, and comes to rest relative to it. We want to investigate the evolution of the motion of these two elements (person and platform).
Is the linear momentum conserved?.
The person's jump takes place on a smooth ground that does not introduce any horizontal force on the person or on the platform. Therefore, during the jump and for the SYSTEM (person + platform) and the ground reference frame:
[math]\displaystyle{ \left.\sum \overline{\Fs}_\mathrm{ext}\right]_\mathrm{horizontal}=0 \quad \Rightarrow \quad }[/math] CONSTANT horizontal linear momentum relative to the ground!
Before jumping [math]\displaystyle{ (\ts_\mathrm{inicial}) }[/math], the linear momentum (relative to the ground) is only associated with the person: [math]\displaystyle{ (\rightarrow \ms\vs_0) }[/math]. Just after jumping [math]\displaystyle{ (\ts_\mathrm{final}) }[/math], as the person is at rest relative to the platform, both elements move with the same velocity relative to the ground [math]\displaystyle{ \left[\rightarrow (\Ms+\ms)\vs \right]. }[/math].
ExD8-1-2-eng.png
The conservation of the horizontal linear momentum between these two time instants allows us to calculate the final velocity of the system: [math]\displaystyle{ (\rightarrow \ms\vs_0) = \left[\rightarrow (\Ms+\ms)\vs \right] \quad \Rightarrow \quad \vs=\frac{\ms}{\Ms+\ms}\vs_0. }[/math].
This speed is constant while the system slides on the smooth ground, but as soon as it enters the rough area [math]\displaystyle{ (\mu \neq 0) }[/math], that will change: the friction force of the ground on the platform, horizontal and opposite to [math]\displaystyle{ \overline{\vs}_\Ts }[/math] (platform) will make it decrease. The linear momentum is no longer conserved:
[math]\displaystyle{ \overline{\Fs}_\mathrm{ground \rightarrow syst}=(\leftarrow \Fs_\mathrm{friction})=(\Ms+\ms)\acc{G}{E}. }[/math]
The horizontal linear momentum of the person and the platform (separately) are not conserved during the jump because of the horizontal constraint forces that appear between them when the person-platform contact begins.
ANIMACIONS

✏️ EXAMPLE D8.2: stopping a block on a wagon

ExD8-2-1-eng.png
A person stands on a wagon, both initially at rest relative to the ground. The mass of the system (person + wagon) is M, and the wheels of the wagon are massless. The block, with mass m, has an initial velocity [math]\displaystyle{ \vs_0 }[/math] relative to the ground directed towards the person, which stops it relative to the platform. The friction associated with the joints between wheels and wagon is neglected. We want to investigate the evolution of the movement of the system.
Is the linear momentum conserved?.
The wheels are Auxiliary Constraint Elements (ACE) and cannot transmit horizontal forces (see example D3.10). Hence, for the SYSTEM (person + wagon with wheels + block) and the ground reference frame:
[math]\displaystyle{ \left.\sum \overline{\Fs}_\mathrm{ext}\right]_\mathrm{horizontal}=0 \quad \Rightarrow \quad }[/math] CONSTANT horizontal linear momentum (LM) relative to the ground!
Before stopping the block, the LM relative to the ground is associated only with the block: [math]\displaystyle{ (\leftarrow \ms\vs_0) }[/math]. But just after [math]\displaystyle{ (\ts_\mathrm{final}) }[/math], since the person and the block are at rest relative to the wagon, the entire system moves with the same velocity relative to the ground:[math]\displaystyle{ \left[\leftarrow (\Ms+\ms)\vs \right]. }[/math]. The conservation of horizontal LM between these two time instants allows the calculation of the final velocity of the system: [math]\displaystyle{ (\leftarrow \ms\vs_0) = \left[\leftarrow (\Ms+\ms)\vs \right] \quad \Rightarrow \quad \vs=\frac{\ms}{\Ms+\ms}\vs_0. }[/math].
ExD8-2-2-eng.png
The LM of just the block relative to the ground does not remain constant because of the friction force of the wagon on the block, which tends to stop it. For a time instant between the initial and final ones [math]\displaystyle{ (\ts_\mathrm{initial}\lt \ts\lt \ts_\mathrm{final}) }[/math] when the speed of the block relative to the ground has been reduced to [math]\displaystyle{ \vs'(\lt \vs_0) }[/math], the velocity of the system (person + wagon) can be calculated through the conservation of horizontal LM for the system (person + wagon with wheels + block):
[math]\displaystyle{ (\leftarrow \ms\vs_0) = (\leftarrow \ms\vs') + \left[\leftarrow (\Ms+\ms)\vs'' \right] \quad \Rightarrow \quad \vs''=\frac{\ms}{\Ms+\ms}(\vs_0-\vs'). }[/math]
ExD8-2-3-eng.png
ANIMACIONS

✏️ EXAMPLE D8.3: skater on ice

ExD8-3-1-neut.png
A person is skating on an ice rink. At a certain moment, his arms are symmetrically wide open and he he spins with angular velocity [math]\displaystyle{ \Omega_0 }[/math] In that configuration, the vertical axis through [math]\displaystyle{ \Gs }[/math] is a principal axis of inertia and the corresponding moment of inertia is [math]\displaystyle{ \Is_0 }[/math]. We want to investigate the evolution of the rotation when the configuration of his arms changes assuming that the friction between the ice and the skates is negligible [math]\displaystyle{ \mu=0 }[/math].
ExD8-3-2-neut.png
Is the angular momentum conserved?.
Since [math]\displaystyle{ \mu=0 }[/math] between ice and kates, the only external forces on the system (person + skates) are vertical (the weight and the normal forces of the ice on the skates). Those vertical forces cannot generate vertical momento about [math]\displaystyle{ \Gs }[/math]. Hence, for the system (person + skates):
[math]\displaystyle{ \left.\sum\overline{\Ms_\mathrm{ext}}(\Gs)\right]_\mathrm{vertical}=0=\left.\dot{\overline{\Hs}}_\mathrm{RTG}(\Gs)\right]_\mathrm{vertical} \quad \Rightarrow \quad \left.\overline{\Hs}_\mathrm{RTG}(\Gs)\right]_\mathrm{vertical} \text{CONSTANT!} }[/math]


The vertical angular momentum in the initial configuration is [math]\displaystyle{ \overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{initial})=(\Uparrow \Is_0 \Omega_0) }[/math]. When approachng or separating the arms from the trunk, the inertia moment of the person about the vertical axis through [math]\displaystyle{ \Gs }[/math] changes. For any value [math]\displaystyle{ \Is }[/math] of this inertia moment, conservation implies: [math]\displaystyle{ (\Uparrow \Is_0 \Omega_0)=(\Uparrow \Is \Omega) }[/math]. When approaching the arms to the trunk, [math]\displaystyle{ \Is\lt \Is_0 }[/math], therefore [math]\displaystyle{ \Omega\gt \Omega_0 }[/math] (the angular velocity increases). For the paricular case [math]\displaystyle{ \Is=\Is_0/2 }[/math], the angular velocity becomes twice the initial value: [math]\displaystyle{ \Omega=2\Omega_0 }[/math].
ANIMACIONS

✏️ EXAMPLE D8.4: collision between two bars

ExD8-4-1-eng.png
Two bars, with their mass concentrated at one end, move on a perfectly smooth horizontal ground (the friction coefficient between the ground and the bars is zero, [math]\displaystyle{ \mu=0 }[/math]) towards each other until they collide and become stuck. We want to describe the final motion of the system.
Is the linear momentum conserved?.
If we consider the system formed by the two bars, the external forces on them are strictly vertical (perpendicular to the plane of motion): the weight and the normal forces associated with the ground contact. Therefore, for this system:
[math]\displaystyle{ \left.\sum \overline{\Fs}_\mathrm{ext}\right]_\mathrm{horizontal}=0 \quad \Rightarrow \quad }[/math] CONSTANT horizontal linear momentum (LM) relative to the ground!
Before collision [math]\displaystyle{ (\ts_\mathrm{before}) }[/math]:
[math]\displaystyle{ \left.\overline{\mathrm{QM}}\right]_\mathrm{horizontal}=\Ms \vel{G}{T}=2\ms\overline{\vs}_\Ts(\mathrm{barra P})+\ms\overline{\vs}_\Ts(\mathrm{barra Q})=(\rightarrow \ms\vs_0)+(\leftarrow \ms2\vs_0)=0 }[/math]
After collision [math]\displaystyle{ \ts_\mathrm{after} }[/math], [math]\displaystyle{ \left.\overline{\mathrm{QM}}\right]_\mathrm{horizontal} }[/math] of the system has to be zero, therefore the velocity of the system’s center of inertia is also zero: [math]\displaystyle{ \overline{\vs}_\Ts(\Gs,\ts_\mathrm{after}) }[/math]. Hence, after collision, the rigid body formed by the two bars will have the ICR relative to the ground permanently located at [math]\displaystyle{ \Gs }[/math]:
ExD8-4-2-eng.png
Position of the inertia center [math]\displaystyle{ \Gs }[/math]: on the line [math]\displaystyle{ \Ps }[/math] and [math]\displaystyle{ \Qs }[/math], at a distance 4L below [math]\displaystyle{ \Qs }[/math].
[math]\displaystyle{ \left.\QGvec\right]_{\uparrow \downarrow}=\frac{\left.\ms \QQvec \right]_{\uparrow \downarrow} +\left. 2\ms \QPvec\right]_{\uparrow \downarrow}}{\ms+2\ms} }[/math]
[math]\displaystyle{ \left.\QGvec\right]_{\uparrow \downarrow}=\frac{2}{3}(\downarrow 6\Ls)=(\downarrow 4\Ls) }[/math]
There is no conservation of the linear momentum for each bar separately: the collision generates very intense forces between them and perpendicular to the bars, that provoke nonzero acceleration of their inertia centres.
Is the angular momentum conserved?
On the other hand, vertical forces (perpendicular to the plane of motion) cannot generate vertical moments about any point. If we apply the AMT at [math]\displaystyle{ \Gs }[/math] to the system formed by the two bars:
[math]\displaystyle{ \left.\sum\overline{\Ms_\mathrm{ext}}(\Gs)\right]_\mathrm{vertical}=0=\left.\dot{\overline{\Hs}}_\mathrm{RTG}(\Gs)\right]_\mathrm{vertical} \quad \Rightarrow \quad \left.\overline{\Hs}_\mathrm{RTG}(\Gs)\right]_\mathrm{vertical} \text{CONSTANT!} }[/math]
[math]\displaystyle{ \left.\overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{before})\right]_\mathrm{vertical}=\left.\overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{after})\right]_\mathrm{vertical} }[/math]
At time [math]\displaystyle{ \ts_\mathrm{before} }[/math], the two bars have a translational motion, and therefore [math]\displaystyle{ \Gs }[/math] does not belong kinematically to either of them. Its angular momentum has to be calculated through barycentric decomposition . Taking into account that the center of inertia of bar P is [math]\displaystyle{ \Ps }[/math], and that of bar Q is [math]\displaystyle{ \Qs }[/math]:
[math]\displaystyle{ \overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{before})=\left.\overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{before})\right]_\mathrm{barP}+\left.\overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{before})\right]_\mathrm{barQ}= }[/math]
[math]\displaystyle{ \hspace{2.9cm}=\left.\overline{\Hs}_\mathrm{RTP}(\Ps,\ts_\mathrm{before}) \right]_\mathrm{barP}+\GPvec\times 2\ms\vel{P}{RTG}+\left.\overline{\Hs}_\mathrm{RTQ}(\Qs,\ts_\mathrm{before})\right]_\mathrm{barQ}+\GQvec \times 2\ms\vel{Q}{RTG}= }[/math]
[math]\displaystyle{ \hspace{2.9cm}=\Is_\mathrm{P}\velang{barP}{RTG} + \GPvec \times 2\ms\vel{P}{RTG}+\Is_\mathrm{Q}\velang{barQ}{RTG}+\GQvec\times 2\ms\vel{Q}{RTG} }[/math]
[math]\displaystyle{ \velang{barP}{RTG}=\velang{barQ}{RTG}=\vec{0} \quad \Rightarrow \quad \overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{before})=(\downarrow 2\Ls)\times 2\ms(\rightarrow \vs_0)+(\uparrow 4\Ls)\times \ms (\leftarrow 2\vs_0)=(\otimes 10\ms\vs_0\Ls) }[/math]
After collision, [math]\displaystyle{ \Gs }[/math] is a point fixed to the rigid body formed by the two bars stuck together. Therefore:
[math]\displaystyle{ \overline{\Hs}_\mathrm{RTG}(\Gs,\ts_\mathrm{after})= \Is_\mathrm{G}\velang{}{RTG}=\left[2\ms(2\Ls)^2+\ms(4\Ls)^2\right](\otimes \Omega_\mathrm{T})=(\otimes 24\ms\Ls^2\Omega_\mathrm{T}) }[/math]
Finally: [math]\displaystyle{ (\otimes 10\ms\Ls\vs_0)=(\otimes\ms\Ls^2\Omega_\mathrm{T})\quad \Rightarrow \quad \Omega_\mathrm{T}=\frac{5}{12}\frac{\vs_0}{\Ls} }[/math] .


Important comment
Although, for the system formed by the two bars, the vertical external moment is zero for any point, the angular momentum is not conserved either at [math]\displaystyle{ \Ps }[/math] or at [math]\displaystyle{ \Qs }[/math] because the two points are accelerated (their velocities change abruptly when the collision occurs):
[math]\displaystyle{ \acc{P}{Gal}=\frac{\Delta \vel{P}{Gal}}{\ts_\mathrm{after}-\ts_\mathrm{before}}=\frac{\left[\rightarrow (\vs_0-2\Ls\Omega_\mathrm{T})\right]}{\ts_\mathrm{after}-\ts_\mathrm{before}} }[/math] , [math]\displaystyle{ \acc{Q}{Gal}=\frac{\Delta \vel{Q}{Gal}}{\ts_\mathrm{after}-\ts_\mathrm{before}}=\frac{\left[\rightarrow (2\vs_0-4\Ls\Omega_\mathrm{T})\right]}{\ts_\mathrm{after}-\ts_\mathrm{before}} }[/math] .
Therefore:
[math]\displaystyle{ \left.\sum\overline{\Ms_\mathrm{ext}}(\Ps)\right]_\mathrm{vertical}+ \left.\PGvec \times \ms \acc{P}{Gal}\right]_\mathrm{vertical}=\left.\dot{\overline{\Hs}}_\mathrm{RTP}(\Ps)\right]_\mathrm{vertical} }[/math]
[math]\displaystyle{ (\uparrow 2\Ls)\times \ms \frac{\left[\rightarrow (\vs_0-2\Ls\Omega_\mathrm{T})\right]}{\ts_\mathrm{after}-\ts_\mathrm{before}} =\left[\otimes \frac{2\ms\Ls(\vs_0-2\Ls\Omega_\mathrm{T})}{\ts_\mathrm{after}-\ts_\mathrm{before}} \right]=\left.\dot{\overline{\Hs}}_\mathrm{RTP}(\Ps)\right]_\mathrm{vertical} \quad \Rightarrow \quad \left.\overline{\Hs}_\mathrm{RTP}(\Ps)\right]_\mathrm{vertical}\neq \text{constant} }[/math]


[math]\displaystyle{ \left.\sum\overline{\Ms_\mathrm{ext}}(\Qs)\right]_\mathrm{vertical}+ \left.\QGvec \times \ms \acc{Q}{Gal}\right]_\mathrm{vertical}=\left.\dot{\overline{\Hs}}_\mathrm{RTQ}(\Qs)\right]_\mathrm{vertical} }[/math]
[math]\displaystyle{ (\downarrow 4\Ls)\times \ms \frac{\left[\leftarrow (2\vs_0-4\Ls\Omega_\mathrm{T})\right]}{\ts_\mathrm{after}-\ts_\mathrm{before}} =\left[\otimes \frac{8\ms\Ls(\vs_0-2\Ls\Omega_\mathrm{T})}{\ts_\mathrm{after}-\ts_\mathrm{before}} \right]=\left.\dot{\overline{\Hs}}_\mathrm{RTQ}(\Qs)\right]_\mathrm{vertical} \quad \Rightarrow \quad \left.\overline{\Hs}_\mathrm{RTQ}(\Qs)\right]_\mathrm{vertical}\neq \text{constant} }[/math]


ANIMACIONS

✏️ EXAMPLE D8.5: collision of a ring and an articulated arm

ExD8-5-1-eng.png
The ring, with radius L and mass m, moves on a smooth horizontal ground with angular velocity [math]\displaystyle{ \Omega_0=\ns\vs_0/\Ls }[/math] relative to the ground (where n is an integer), and its centre [math]\displaystyle{ \Ps }[/math] approaches the end [math]\displaystyle{ \Qs }[/math] of the arm with velocity [math]\displaystyle{ \vs_0 }[/math]. The arm has a length 2L and a mass M, is articulated at point [math]\displaystyle{ \Os }[/math] fixed to the ground and is initially at rest. Because of the collision, the ring and arm stick together. The friction associated with the joint at [math]\displaystyle{ \Os }[/math] is neglected. We want to investigate the motion of the system after the collision.
Is the linear momentum conserved?.
The linear momentum of each element separately (ring and arm) is not conserved: the collision generates very intense horizontal forces between them that cause acceleration in their centers of inertia. In addition, the arm undergoes an intense force at the [math]\displaystyle{ \Os }[/math]-joint.
There is no conservation of the linear momentum for the system (ring + arm) either: the [math]\displaystyle{ \Os }[/math]-joint introduces forces into the plane of motion responsible for the acceleration of the system’s center of inertia [math]\displaystyle{ \Gs }[/math].
Is the angular momentum conserved?
ExD8-5-2-eng.png
For the system (ring + arm), the forces associated with the joint yield a nonzero vertical external moment (orthogonal to the plane of motion) at any point except at [math]\displaystyle{ \Os }[/math]:
[math]\displaystyle{ \left.\sum\overline{\Ms_\mathrm{ext}}(\Os)\right]_\mathrm{vertical}=0=\left.\dot{\overline{\Hs}}_\mathrm{RTG}(\Os)\right]_\mathrm{vertical} \quad \Rightarrow \quad \left.\overline{\Hs}_\mathrm{RTG}(\Os)\right]_\mathrm{vertical} \text{CONSTANT!} }[/math]
Since [math]\displaystyle{ \Os }[/math] is permanently fixed to the ground, it must be the permanent ICR relative to the ground of the rigid formed by the ring and the arm stuck together after the collision. Before the collision, the ring ICR is located at [math]\displaystyle{ \Ls/2 }[/math] below the center [math]\displaystyle{ \Ps }[/math]:
[math]\displaystyle{ \vel{S}{T}=\vel{P}{T}+\velang{}{0}\times \PSvec = (\rightarrow \vs_0) + \left(\otimes \frac{\ns\vs_0}{\Ls}\right)\times (\downarrow \Ls)=\left[\leftarrow (\ns-1)\vs_0\right]. }[/math]
The distance e between [math]\displaystyle{ \Ps }[/math] and the ring ICR relative to the ground before collision can be found from:
[math]\displaystyle{ \left.\begin{array}{l} \left|\vel{P}{T}\right|=\vs_0=\es \Omega_0 \\ \left|\vel{S}{T}\right|=(\ns-1) \vs_0=(\Ls-\es) \Omega_0 \end{array}\right\} \Rightarrow \es=\frac{\Ls}{\ns} . }[/math]
A negative value for n means that the ICR is located at a distance e above [math]\displaystyle{ \Ps }[/math].
ExD8-5-3-eng.png
Before the collision [math]\displaystyle{ \ts_\mathrm{before} }[/math], [math]\displaystyle{ \Os }[/math] is not a point fixed to the ring in general (it is not its ICR). Its angular momentum has to be calculated thorugh barycentric decomposition . The initial angular momentum of the arm is zero because it does not move:
[math]\displaystyle{ \overline{\Hs}_\mathrm{RTO=T}(\Os,\ts_\mathrm{before})=\left.\overline{\Hs}_\mathrm{T}(\Os,\ts_\mathrm{before})\right]_\mathrm{anella}= \left.\overline{\Hs}_\mathrm{RTP}(\Ps,\ts_\mathrm{before})\right]_\mathrm{anella} + \OPvec \times 2\ms\vel{P}{T}= }[/math]
[math]\displaystyle{ \hspace{3.4cm}=\Is_\mathrm{P} \left(\otimes \frac{\ns\vs_0}{\Ls} \right) + \left(\downarrow 2\Ls \right)\times \ms\left(\rightarrow \vs_0 \right) = \left(\otimes \ms\Ls^2 \frac{\ns\vs_0}{\Ls}\right) + \left(\odot 2\ms\Ls\vs_0 \right) = \left[ \otimes (\ns-2)\ms\Ls\vs_0 \right] }[/math]
After the collision:
[math]\displaystyle{ \overline{\Hs}_\mathrm{RTO}(\Os,\ts_\mathrm{after})= \Is_\mathrm{O}\overline{\Omega}_\Ts=\left( \Is_\mathrm{O}^\mathrm{anella}+ \Is_\mathrm{O}^\mathrm{braç} \right) \overline{\Omega}_\Ts= \left( \Is_\mathrm{G}^\mathrm{anella}+ \Is_\mathrm{O}^{\mathrm{anella}\otimes}+\Is_\mathrm{O}^\mathrm{braç} \right) \overline{\Omega}_\Ts = \left[ \ms\Ls^2 + \ms(2\Ls)^2+ \frac{4}{3} \ms\Ls^2\right]\overline{\Omega}_\Ts }[/math]
[math]\displaystyle{ \left.\begin{array}{l} \bar{\mathrm{H}}_{\text {RTO }}\left(\Os, \mathrm{t}_{\text {after }}\right)=\left(\otimes \frac{19}{3} \ms\Ls^2 \Omega_{\mathrm{T}}\right) \\ \bar{\mathrm{H}}_{\text {RTO }}\left(\Os, \mathrm{t}_{\text {before }}\right)=\left[\otimes(\mathrm{n}-2) \mathrm{mLv}_0\right] \end{array}\right\} \Rightarrow \bar{\Omega}_{\mathrm{T}}=\left[\otimes(\mathrm{n}-2) \frac{19}{3} \frac{\mathrm{v}_0}{\mathrm{~L}}\right] }[/math]
For [math]\displaystyle{ n\gt 2 }[/math], the system rotation is clockwise. For [math]\displaystyle{ n\lt 2 }[/math], it is counterclockwise. For [math]\displaystyle{ n=2 }[/math], the system is at rest.
ANIMACIONS

✏️ EXAMPLE D8.6: free rigid body in space

ExD8-6-1-neut.png
The rigid body consists of two homogeneous plates, with the same mass and height but different widths, glued at point [math]\displaystyle{ \Os }[/math]. We want to investigate whether any dynamic magnitude is conserved when it is launched in the air. Aerodynamic interactions are neglected.
Is the linear momentum conserved?
The Earth's gravitational attraction as the only external force on the rigid body. Therefore, the vertical component of the linear momentum relative to the ground is not conserved, but the horizontal components are.
Since the linear momentum relative to the ground and the velocity of the center of inertia [math]\displaystyle{ \vel{G=O}{E} }[/math] are strictly proportional, the horizontal components of [math]\displaystyle{ \vel{G}{E} }[/math] are also constant.
Is the angular momentum conserved?
The gravitational torsor at the gravity centre [math]\displaystyle{ \Gs }[/math] (which is the same point as the inertia centre [math]\displaystyle{ \Os }[/math]) reduces to a resultant force and no moment. Therefore:
[math]\displaystyle{ \sum\overline{\mathrm{M}}_\mathrm{ext}(\Gs)=\overline{0}=\dot{\overline{\mathrm{H}}}_\mathrm{RTG} (\Gs) \quad \Rightarrow \quad \overline{\mathrm{H}}_\mathrm{RTG} (\Gs) \mathrm{CONSTANT!} }[/math]
For the rigid body under study: [math]\displaystyle{ \overline{\mathrm{H}}_\mathrm{RTG} (\Gs) = \Is\Is (\Gs) \velang{}{RTG} = \Is\Is (\Gs) \velang{}{T}. }[/math]
The angular momentum and the angular velocity are not proportional in general (they are only proportional when the direction of angular velocity is a a principal direction of inertia for the centre of inertia [math]\displaystyle{ \Gs }[/math] (section D5.3)), and the conservation of the former does not imply that of the latter.
Qualitative assessment of the inertia tensor
Since the two plates are symmetrical
[math]\displaystyle{ \left[\Is\Is(\Gs)\right]=\left[\Is\Is(\Gs)\right]_\text{lower plate} + \left[\Is\Is(\Gs)\right]_\text{upper plate} = \diag{\Is_{11}}{\Is_{11} + \Is_{33}}{\Is_{33}}+ \diag{2\Is}{\Is}{\Is} , \text{ amb} \Is_{11}\lt \Is_{33}. }[/math]
Quantitative assessment of the inertia tensor


[math]\displaystyle{ \left[\Is\Is(\Gs)\right]=\frac{1}{3} \ms\Ls^2 \diag{1}{1+4}{4}+\frac{1}{3} \ms\Ls^2 \diag{2}{1}{1}=\frac{1}{3} \ms\Ls^2 \diag{3}{6}{5} \equiv \diag{\Is_\mathrm{low}}{\Is_\mathrm{high}}{\Is_\mathrm{medium}} }[/math]
The directions 1, 2 and 3 are the inertia principal directions for point [math]\displaystyle{ \Gs }[/math].
Angular momentum calculation
[math]\displaystyle{ \left\{\overline{\mathrm{H}}_\mathrm{RTG} (\Gs)\right\}=\diag{\Is_\mathrm{low}}{\Is_\mathrm{high}}{\Is_\mathrm{medium}} \vector{\Omega_1}{\Omega_2}{\Omega_3}=\vector{\Is_\mathrm{low}\Omega_1}{\Is_\mathrm{high}\Omega_2}{\Is_\mathrm{medium}\Omega_3} }[/math], is not proportional to [math]\displaystyle{ \velang{}{T} }[/math] in principle.
If the initial angular velocity is exclusively in one of the three directions (that is, if its direction is a principal direction of inertia for [math]\displaystyle{ \Gs }[/math]), then there is proportionality between [math]\displaystyle{ \overline{\mathrm{H}}_\mathrm{RTG} (\Gs) }[/math] and [math]\displaystyle{ \velang{}{T} }[/math],and the conservation of the former implies that of the latter.


ANIMACIONS

✏️ EXAMPLE D8.7: gyroscope

ExD8-7-1-eng.png
The system consists of a homogeneous disk with mass m and radius r, articulated to a massless support, and a fork that can rotate freely about the vertical axis. There is a motor between the support and the fork. The inertia moment of the support with respect to the vertical axis through the center of the disk is [math]\displaystyle{ \Is=(\lambda/2)\ms\rs^2 }[/math]. Initially [math]\displaystyle{ (\ts_\mathrm{incial} }[/math] the disk is parallel to the ground, and rotates with vertical angular velocity [math]\displaystyle{ \velang{disc}{T}=\psio }[/math]. The friction associated with all the joints is neglected. We want to investigate how the support moves when the motor changes the disk orientation relative to the ground.
Is the angular momentum conserved?
For the disk SYSTEM, the resultant moment about its centre of inertia [math]\displaystyle{ \Gs }[/math] is zero in the direction of its axis. The motor can change the orientation of this axis relative to the ground (and relative to any reference frame with a translational motion relative to the ground), and therefore it is not a direction fixed to the ground (so not to the RTG either): the angular momentum is not conserved in this direction.
For the SYSTEM (disk + support + fork), the resulting moment relative to the center of the disk [math]\displaystyle{ \Os }[/math] is zero in the vertical direction, which is fixed to the ground. Therefore:
[math]\displaystyle{ \left.\sum \overline{\Ms}_\mathrm{ext}(\Os)\right]_\mathrm{vert} =0 \quad \Rightarrow \quad \left.\overline{\Hs}_\mathrm{RTO=T}(\Os) \right]_\mathrm{vert} \text{ CONSTANT!} }[/math]
As the motor changes the orientation of the disk plane [math]\displaystyle{ (\dot{\theta} \neq 0) }[/math], the support rotates around the vertical axis [math]\displaystyle{ \dot{\psi} }[/math]. The angular momentum at [math]\displaystyle{ \Os }[/math] is:
ExD8-7-2-neut.png
[math]\displaystyle{ \overline{\Hs}_\mathrm{RTO=E}(\Os,\ts)=\Is\Is^\mathrm{sup}(\Os)\velang{sup}{E}(\ts)+\Is\Is^\mathrm{disk}(\Os)\velang{disk}{E}(\ts)=\Is\Is^\mathrm{sup}(\Os)\dot{\psi}+\Is\Is^\mathrm{disk}(\Os)\left( \overline{\dot{\psi}}+ \overline{\dot{\theta}}+ \overline{\dot{\varphi}}\right) }[/math]


[math]\displaystyle{ \braq{\overline{\Hs}_\Es^\mathrm{sup}(\Os,\ts)}{B}=\diag{\Is_{11}}{\Is_{22}}{(\lambda/2)\ms\rs^2}\vector{0}{0}{\dot{\psi}}=\vector{0}{0}{(\lambda/2)\ms\rs^2 \dot{\psi}}, }[/math]


[math]\displaystyle{ \braq{\overline{\Hs}_\Es^\mathrm{disk}(\Os,\ts)}{B'}=\frac{1}{4}\ms\rs^2\diag{1}{1}{2}\vector{-\dot{\theta}}{-\dot{\psi} \sin\theta}{\dot{\varphi}+\dot{\psi}\cos\theta}=\frac{1}{4}\ms\rs^2\vector{-\dot{\theta}}{-\dot{\psi} \sin\theta}{2(\dot{\varphi}+\dot{\psi}\cos\theta)} }[/math]


The angular momentum in the vertical direction comes from the projection of components 2 and 3:
[math]\displaystyle{ \left.\overline{\Hs}_\Es(\Os,\ts)\right]_\mathrm{vert} =\overline{\Hs}_\Es^\mathrm{sup}(\Os,\ts)+ \left.\overline{\Hs}_\Es^ \mathrm{disk} (\Os,\ts) \right]_{3'}\cos\theta - \left.\overline{\Hs}_\Es^\mathrm{disk}(\Os,\ts)\right]_{2'} \sin\theta , }[/math]
[math]\displaystyle{ \left.\overline{\Hs}_\Es(\Os,\ts)\right]_\mathrm{vert} = \left(\Uparrow \frac{\lambda}{2}\ms\rs^2\dot{\psi}\right)+ \left(\Uparrow \frac{1}{4}\ms\rs^2\left[2\dot{\varphi}\cos\theta+\dot{\psi}(1+\cos^2\theta)\right]\right) }[/math]


Taking into account the conservation of the vertical angular momentum:
[math]\displaystyle{ \left.\begin{array}{ll} \left.\overline{\mathrm{H}}_{\mathrm{E}}(\mathbf{O}, \mathrm{t})\right]_{\text {vert }}=\left(\Uparrow \frac{1}{4} \mathrm{mr}^2\left[2 \dot{\varphi} \cos \theta+\dot{\psi}\left(1+2 \lambda+\cos ^2 \theta\right)\right]\right) \\ \left.\begin{array}{l} \dot{\psi}\left(\mathrm{t}_{\text {initial }}\right)=0 \\ \dot{\varphi}\left(\mathrm{t}_{\text {initial }}\right)=\dot{\varphi}_0 \\ \theta\left(\mathrm{t}_{\text {initial }}\right)=0 \end{array}\right\} \left.\Rightarrow \overline{\mathrm{H}}_{\mathrm{T}}\left(\mathbf{O}, \mathrm{t}_{\text {initial }}\right)\right]_{\text {vert }}=\left[\Uparrow\left(\frac{1}{2} \mathrm{mr}^2 \dot{\varphi}_0\right)\right] \\ \end{array}\right\} \Rightarrow 2 \dot{\varphi} \cos \theta+\dot{\psi}\left(1+2 \lambda+\cos ^2 \theta\right)=2 \dot{\varphi}_0 }[/math]


On the other hand, for the SYSTEM disk, the external moment in the direction of the disk axis (direction 3') is zero. Hence, [math]\displaystyle{ \left.\dot{\overline{\Hs}}_\mathrm{disk,T}(\Os)\right]_{3'}=0 }[/math]
[math]\displaystyle{ \braq{\dot{\overline{\Hs}}_\mathrm{disk,E}(\Os,\ts)}{B'}=\frac{1}{4}\ms\rs^2 \vector{-\ddot{\theta}}{-\ddot{\psi} \sin\theta -\dot{\psi}\dot{\theta}\cos\theta}{2(\ddot{\varphi}+\ddot{\psi}\cos\theta-\dot{\psi}\dot{\theta}\sin\theta)} + \vector{-\dot{\theta}}{-\dot{\psi}\sin\theta}{\dot{\psi}\cos\theta}\times\frac{1}{4}\ms\rs^2\vector{-\dot{\theta}}{-\dot{\psi}\sin\theta}{2(\dot{\varphi}+\dot{\psi}\cos\theta)}= }[/math]


[math]\displaystyle{ \hspace{2.5cm}= \frac{1}{4}\ms\rs^2\vector{-\ddot{\theta}-\dot{\psi}(2\dot{\varphi}+\dot{\psi}\cos\theta)\sin\theta}{-\ddot{\psi}\sin\theta + 2\dot{\theta}\dot{\varphi}}{2(\ddot{\varphi}+\ddot{\psi}\cos\theta-\dot{\psi}\dot{\theta}\sin\theta)} \Rightarrow \ddot{\varphi}+\ddot{\psi}\cos\theta-\dot{\psi}\dot{\theta}\sin\theta=0. }[/math]


ExD8-7-3D-neut.png
The integration of that equation yields: [math]\displaystyle{ \dot{\varphi}+\dot{\psi}\cos\theta=\dot{\varphi}_0 }[/math], where [math]\displaystyle{ \dot{\varphi}_0 }[/math] is the integration constant, which may be found from the initial conditions.
Combination of this result with the previous one yields:
[math]\displaystyle{ \left.\begin{array}{l} 2\dot{\varphi}\cos\theta+\dot{\psi}(1+2\lambda+\cos^2\theta )=2\dot{\varphi}_0\\ \dot{\varphi}+\dot{\psi}\cos\theta=\dot{\varphi}_0 \end{array}\right\} \Rightarrow \frac{\dot{\psi}}{\dot{\varphi}_0}=\frac{2(1-\cos\theta)}{2\lambda+\sin^2\theta} }[/math]


ExD8-7-3-2D-neut.png

✏️ EXAMPLE D8.8: bar in a smooth rotating circular guide

ExD8-8-1-eng.png
The homogeneous bar PQ, with mass m, moves with its two endpoins inside a smooth guide [math]\displaystyle{ (\mu=0) }[/math], with radius r and negligible mass, which can rotate freely around the vertical direction. The POQ angle is [math]\displaystyle{ 120^o }[/math]. We want to find the equation of motion for the coordinate [math]\displaystyle{ \psi }[/math]. The rotation of the bar on its axis (spin [math]\displaystyle{ \dot{\varphi} }[/math]) is neglected.
Is the linear momentum conserved?
The external forces on the bar are not zero: in addition to the weight, there are normal forces from the guide on the bar at [math]\displaystyle{ \Ps }[/math] and [math]\displaystyle{ \Qs }[/math] (directed towards [math]\displaystyle{ \Os }[/math]) and a force component perpendicular to the plane of the guide. Therefore, the resultant external force on the bar has components in the three directions of space, and the linear momentum is not conserved.
If we analyze the external forces on the SYSTEM (bar + guide), the conclusion is the same: in addition to the weight of the bar, there is the constraint force associated with the bearing between the ground and the guide, which has three non-zero components in principle.
Is the angular momentum conserved?
For the SYSTEM (bar + guide), the external moment about any point on the axis of rotation of the guide (in particular, for point [math]\displaystyle{ \Os }[/math]) has a zero vertical component (since the constraint moment of the bearing in that direction is zero, and the weight cannot yield a moment in the vertical direction). On the other hand, the angular acceleration of the guide relative to the ground [math]\displaystyle{ \left(\overline{\ddot{\psi}}\right) }[/math] is vertical. Therefore:
[math]\displaystyle{ \boxed{\left.\text{Roadmap: SYSTEM (bar+guide), AMT at }\Os\right]_\mathrm{vert}} }[/math]


[math]\displaystyle{ \left.\sum\overline{\Ms}_\mathrm{ext}(\Os) \right]_\mathrm{vert}=0 \quad \Rightarrow \quad \left.\overline{\Hs}_\mathrm{RTG}(\Os)\right]_\mathrm{vert} \text{ CONSTANT!} }[/math]


The only element with nonzero mass is the bar, and point [math]\displaystyle{ \Os }[/math] is fixed to it:
ExD8-8-2-neut.png
[math]\displaystyle{ \overline{\Hs}_\mathrm{RTO}(\Os)=\Is\Is(\Os)\velang{bar}{RTO=E}=\left[\Is\Is(\Gs)+\Is\Is^\bigoplus(\Os)\right]\left(\overline{\dot{\psi}}+\overline{\dot{\theta}}\right) }[/math]


[math]\displaystyle{ \braq{\overline{\Hs}_\mathrm{RTO}(\Os)}{}=\left(\ms(\sqrt{3\rs})^2\diag{1}{0}{1}+\ms\left(\frac{\rs}{2}\right)^2\diag{1}{1}{0}\right)\vector{\dot{\theta}}{\dot{\psi}\sin\theta}{\dot{\psi}\cos\theta} }[/math]
[math]\displaystyle{ \braq{\overline{\Hs}_\mathrm{RTO}(\Os)}{}=\frac{1}{4}\ms\rs^2\vector{14\dot{\theta}}{\dot{\psi}\sin\theta}{13\dot{\psi}\cos\theta} }[/math]


[math]\displaystyle{ \left.\overline{\Hs}_\mathrm{RTO}(\Os)\right]_\mathrm{vert} =\left.\overline{\Hs}_\mathrm{RTO}(\Os)\right]_3\cos\theta+ \left.\overline{\Hs}_\mathrm{RTO}(\Os)\right]_2\sin\theta= \frac{1}{4}\ms\rs^2\dot{\psi}(13\cos^2\theta + \sin^2\theta)= \frac{1}{4}\ms\rs^2 \dot{\psi}(1+12\cos^2\theta) }[/math]
[math]\displaystyle{ \left.\overline{\Hs}_\mathrm{RTO}(\Os)\right]_\mathrm{vert} =\text{constant } \Rightarrow \quad \frac{\ds\left.\overline{\Hs}_\mathrm{RTO}(\Os)\right]_\mathrm{vert}}{\ds\ts}=0=\frac{1}{4}\ms\rs^2 \dot{\psi}(1+12\cos^2\theta)-6\ms\rs^2 \dot{\psi}\dot{\theta}\sin\theta\cos\theta }[/math]


[math]\displaystyle{ \boxed{\ddot{\psi}(3+7\cos^2\theta)-14\dot{\psi}\dot{\theta} \sin\theta \cos\theta =0} }[/math]


Relevant comment
ExD8-8-3-neut.png
The vertical angular momentum at [math]\displaystyle{ \Qs }[/math] and [math]\displaystyle{ \Ps }[/math] is not conserved since those two points are accelerated:
[math]\displaystyle{ \sum \overline{\bar{\Ms}}_{\text {ext }}(\mathbf{Q})-\overline{\mathbf{P G}} \times \ms \overline{\mathrm{a}}_{\text {Gal }}(\mathbf{Q})=\dot{\overline{\mathrm{H}}}_{\text {RTQ }}(\mathbf{Q}), \quad \overline{\mathbf{QG}} \times \ms \overline{\mathrm{a}}_{\text {Gal }}(\mathbf{Q})=\overline{\mathbf{QG}} \times \mathrm{m}\left[\overline{\mathrm{a}}_{\text {RЕL }}(\mathbf{Q})+\overline{\mathrm{a}}_{\mathrm{tr}}(\mathbf{Q})+\overline{\mathrm{a}}_{\text {cor }}(\mathbf{Q})\right] }[/math]
[math]\displaystyle{ \left\{\overline{\mathbf{Q G}} \times \ms \bar{\mathrm{a}}_{\mathrm{Gal}}(\mathbf{Q})\right\}=\left\{\begin{array}{c} 0 \\ \sqrt{3\rs} \cos \theta \\ \sqrt{3\rs} \sin \theta \end{array}\right\} \times \ms\left[\left\{\begin{array}{c} 0 \\ \mathrm{a}_{\mathrm{REL}}^{\mathrm{s}} \sin \left(30^{\circ}-\theta\right)-\mathrm{a}_{\mathrm{REL}}^{\mathrm{n}} \cos \left(30^{\circ}-\theta\right) \\ \mathrm{a}_{\mathrm{REL}}^{\mathrm{s}} \cos \left(30^{\circ}-\theta\right)+\mathrm{a}_{\mathrm{REL}}^{\mathrm{n}} \sin \left(30^{\circ}-\theta\right) \end{array}\right\}+\left\{\begin{array}{c} \mathrm{a}_{\mathrm{tr}}^{\mathrm{s}}-\mathrm{a}_{\mathrm{Cor}} \\ -\mathrm{a}_{\mathrm{tr}}^{\mathrm{n}} \\ 0 \end{array}\right\}\right] }[/math]
[math]\displaystyle{ \left.\left.\left.\overline{\mathbf{Q G}} \times \ms \overline{\mathrm{a}}_{\text {Gal }}(\mathbf{Q})\right]_{\text {vert }}=\overline{\mathbf{QG}} \times \ms \overline{\mathrm{a}}_{\text {Gal }}(\mathbf{Q})\right]_{3^{\prime}}=\sqrt{3} \mathrm{m}\left(\mathrm{a}_{\text {Cor }}-\mathrm{a}_{\mathrm{tr}}^{\mathrm{s}}\right) \sin \theta \neq 0 \quad \Rightarrow \quad \dot{\bar{\Hs}}_{\text {RTQ }}(\mathbf{Q})\right]_{\text {vert }} \neq 0 }[/math]

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