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Riga 1: {\| class="wikitable" \|- ! Descrizione \|\| Figura \|\| Momento di inerzia \|\| Commento Riga 7: \|align="center"\| \| <math> I = m r^2</math> \|— AUn ~~point~~massa ~~mass~~puntiforme ~~does~~non ~~not~~ha ~~have~~momento adi ~~moment~~inerzia ofintorno ~~inertia~~al ~~round~~proprio ~~its~~asse, ~~own~~ma ~~axis,~~usando ~~but~~il by[[Teorema ~~using~~di ~~the~~Huygens-Steiner\|teorema ~~Parallel~~degli ~~axis~~assi paralleli]] si ottiene un momento di inerzia ~~theorem~~intorno a un asse di rotazione distante.<!-- ###### a moment of inertia around a distant axis of rotation is achieved. ##### --> \|- \| ~~Two~~Due ~~point~~masse ~~masses~~puntiformi, ''M'' ~~and~~e ''m'', ~~with~~con [[~~reduced~~massa ~~mass~~ridotta]] ''<math> \mu </math>'' ~~and~~e ~~separated~~separate byda auna ~~distance~~distanza, ''x''. \|align="center"\| \| <math> I = \frac{ M m }{ M \! + \! m } x^2 = \mu x^2 </math> \|— \|- \| ~~[[Rod~~Asta ~~(geometry)\|Rod]] of~~di ~~length~~lunghezza ''L'' ~~and~~e ~~mass~~massa ''m'' <br>(~~Axis~~asse ofdi ~~rotation~~rotazione atalla ~~the~~fine ~~end of the rod~~dell'asta) \| align="center"\|[[Image:moment of inertia rod end.png]] \| <math>I_{\mathrm{~~end~~estrem.}} = \frac{m L^2}{3} \,\!</math>  <ref name="serway"/> \| ~~This~~Questa ~~expression~~espressione ~~assumes~~assume ~~that~~che ~~the~~l'asta ~~rod~~sia isun anfilo ~~infinitely~~infinitamente ~~thin~~sottile ~~(but~~ma ~~rigid) wire~~rigido. ~~This~~Questo isè ~~also~~anche aun ~~special~~caso ~~case~~particolare ofdella ~~the~~piastra ~~thin~~rettangolare ~~rectangular~~con ~~plate~~asse ~~with~~di ~~axis~~rotazione ofalla ~~rotation~~fine atdella ~~the~~piastra, ~~end of the plate,~~e ~~with~~con ''h'' = ''L'' ~~and~~e ''w'' = ''0''. \|- \| ~~[[Rod~~Asta ~~(geometry)\|Rod]]~~di ~~of length~~lunghezza ''L'' ~~and~~e ~~mass~~massa ''m'' \| align="center"\|[[Image:moment of inertia rod center.png]] \| <math>I_{\mathrm{~~center~~centrale}} = \frac{m L^2}{12} \,\!</math>  <ref name="serway"/> \| ~~This~~Questa ~~expression~~espressione ~~assumes~~assume ~~that~~che ~~the~~l'asta ~~rod~~sia isun anfilo ~~infinitely~~infinitamente ~~thin~~sottile ~~(but~~ma ~~rigid) wire~~rigido.Questo è ~~This is a special case of~~anche ~~the~~un ~~thin~~caso ~~rectangular~~particolare ~~plate~~della ~~with~~piastra ~~axis~~rettangolare ofcon ~~rotation~~asse atdi ~~the~~rotazione ~~center~~al ofcentro ~~the~~della ~~plate~~piastra, ~~with~~con ''w'' = ''L'' ~~and~~e ''h'' = ''0''. \|- \| ~~Thin~~Cerchio ~~circular~~sottile ~~[[hoop]]~~di ~~of radius~~raggio ''r'' ~~and~~e ~~mass~~massa ''m'' \| align="center"\|[[Image:moment of inertia hoop.svg\|170px]] \| <math>I_z = m r^2\!</math><br><math>I_x = I_y = \frac{m r^2}{2}\,\!</math> \| ~~This~~Questo isè aun ~~special~~caso ~~case~~particolare ofsia adel [[~~torus~~Toro (geometria)\|toro]] ~~for~~per ''b'' = 0. (~~See~~vedi più in ~~below.~~basso), asche ~~well~~del astubo ofcilindrico acon ~~thick-walled~~pareti ~~cylindrical~~spesse ~~tube~~ed ~~with~~estremità ~~open ends~~aperte, ~~with~~con ''r''<sub>1</sub>=''r''<sub>2</sub> ~~and~~e ''h'' = 0. \|- \| ~~Thin, solid~~ [[~~disk (mathematics)\|disk~~Disco]] ofsolido e sottile, di ~~radius~~raggio ''r'' ~~and~~e ~~mass~~massa ''m'' \|align="center"\| [[Image:moment of inertia disc.svg\|170px]] \| <math>I_z = \frac{m r^2}{2}\,\!</math><br><math>I_x = I_y = \frac{m r^2}{4}\,\!</math> \| ~~This~~Questo isè aun ~~special~~caso ~~case~~particolare ofdel ~~the~~cilindro ~~solid cylinder~~solido, ~~with~~con ''h'' = 0. \|- \| ~~Thin~~Superficie ~~[[cylinder~~cilindrica ~~(geometry)\|cylindrical]]~~sottile ~~shell~~con ~~with~~estremità ~~open ends~~aperte, ofdi ~~radius~~raggio ''r'' ~~and~~e ~~mass~~massa ''m'' \|align="center"\| [[Image:moment of inertia thin cylinder.png]] \| <math>I = m r^2 \,\!</math>  <ref name="serway">{{~~cite~~cita ~~book~~libro \|~~title~~titolo=Physics for Scientists ~~and~~e Engineers, second ed. \|~~author~~autore=Raymond A. Serway \|~~page~~pagina=202 \|~~publisher~~editore=Saunders College Publishing \|isbn=0-03-004534-7 \|~~year~~anno=1986 }}</ref> \| Questa espressione vale per un cilindro vuoto (come per esempio un tubo), con spessore delle pareti trascurabile (appunto approssimabile a una superficie cilindrica). E' un caso particolare del tubo cilindrico con pareti spesse ed estremità aperte e ''r''<sub>1</sub>=''r''<sub>2</sub>. ~~\| This expression assumes the shell thickness is negligible. It is a special case of the thick-walled cylindrical tube for ''r''<sub>1</sub>=''r<sub>2</sub>.~~ ~~Also,~~Anche auna ~~point~~massa ~~mass~~puntiforme (''m'') atalla ~~the~~fine ~~end~~di ~~of a rod~~un'asta ofdi ~~length~~lunghezza ''r'' ~~has~~ha ~~this~~lo ~~same~~stesso ~~moment~~momento ofdi ~~inertia~~inerzia, ~~and~~e ~~the~~il ~~value~~valore ''r'' ~~is called~~è ~~the~~chiamato [[~~radius~~raggio ofdi ~~gyration~~inerzia]]. \|- \|~~Solid~~Cilindro ~~cylinder~~solido ofdi ~~radius~~raggio ''r'', ~~height~~altezza ''h'' ~~and~~e ~~mass~~massa ''m'' \|align="center"\| [[Image:moment of inertia solid cylinder.svg\|170px]] \|<math>I_z = \frac{m r^2}{2}\,\!</math>  <ref name="serway"/><br/><math>I_x = I_y = \frac{1}{12} m\left(3r^2+h^2\right)</math> \| ~~This~~Questo isè aun ~~special~~caso ~~case~~particolare ofdel ~~the~~tubo ~~thick-walled~~cilindrico con pareti spesse ed ~~cylindrical~~estremità ~~tube~~aperte, ~~with~~con ''r''<sub>1</sub>=0. (~~Note~~Nota: in questa immagine gli assi X-Y ~~axis~~sono ~~should~~scambiati berispetto ~~swapped~~agli ~~for~~assi acartesiani standard ~~right handed frame~~) \|- \| ~~Thick-walled~~Tubo ~~cylindrical~~cilindrico ~~tube~~con ~~with~~pareti ~~open~~spesse ~~ends~~ed estremità aperte, ofdi ~~inner~~raggio ~~radius~~interno ''r''<sub>1</sub>, ~~outer~~raggio ~~radius~~esterno ''r''<sub>2</sub>, ~~length~~lunghezza ''h'' ~~and~~e ~~mass~~massa ''m'' \|align="center"\| [[Image:moment of inertia thick cylinder h.png]] \| <!-- Please read the discussion on the talk ~~page~~pagina ~~and~~e the ~~cited~~citad source before changing the sign to a minus. --><math>I_z = \frac{1}{2} m\left({r_1}^2 + {r_2}^2\right)</math>  <ref name="serway"/><ref>[{{cita web\| url=http://www.livephysics.com/problems-~~and~~e-answers/classical-mechanics/find-moment-of-inertia-of-a-uniform-hollow-cylinder.html\|titolo= Classical Mechanics - Moment of inertia of a uniform hollow cylinder].\|editore= LivePhysics.com.\|accesso=31 ~~Retrieved on~~gennaio 2008~~-01-31.~~\|lingua=en}}</ref><br><math>I_x = I_y = \frac{1}{12} m\left[3\left({r_2}^2 + {r_1}^2\right)+h^2\right]</math><br>oro ~~when~~definendo ~~defining the~~lo ~~normalized~~spessore ~~thickness~~normalizzato ''t<sub>n</sub>'' = ''t''/''r'' ~~and~~e ~~letting~~ponendo ''r'' = ''r''<sub>2</sub>, <br>~~then~~allora <math>I_z = mr^2\left(1-t_n+\frac{1}{2}{t_n}^2\right) </math> \| ~~With~~con ~~a density of~~densità ''ρ'' ~~and~~e ~~the~~la ~~same~~stessa ~~geometry~~geometria <math>I_z = \frac{1}{2} \pi\rho h\left({r_2}^4 - {r_1}^4\right)</math> <math>I_x = I_y = \frac{1}{12} \pi\rho h\left(3({r_2}^4 - {r_1}^4)+h^2({r_2}^2 - {r_1}^2)\right)</math> \|- \| [[~~Sphere~~Sfera]] (~~hollow~~cava) ofdi ~~radius~~raggio ''r'' ~~and~~e ~~mass~~massa ''m'' \|align="center"\| [[Image:moment of inertia hollow sphere.svg\|170px]] \|<math>I = \frac{2 m r^2}{3}\,\!</math>  <ref name="serway"/> \| AUna ~~hollow~~sfera ~~sphere~~cava ~~can~~può beessere ~~taken~~considerata tocome becostituita ~~made~~da updue ofpile ~~two~~di ~~stacks~~cerchi ofinfinitamente ~~infinitesimally thin~~sottili, ~~circular~~uno ~~hoops~~sopra l'altro, ~~where~~con ~~the~~i ~~radius~~raggi ~~differs~~che ~~from~~aumentano da ''0'' toa ''r'' (oro ~~a single~~un'unica ~~stack~~pila, ,con ~~where~~il ~~the~~raggio ~~radius~~dei ~~differs~~cerchi ~~from~~crescente da ''-r'' toa ''r''). \|- \| [[~~ball (mathematics)\|Ball~~Sfera]] (~~solid~~piena) ofdi ~~radius~~raggio ''r'' ~~and~~e ~~mass~~massa ''m'' \|align="center"\| [[Image:moment of inertia solid sphere.svg\|170px]] \|<math>I = \frac{2 m r^2}{5}\,\!</math>  <ref name="serway"/> \| A ~~sphere~~Una ~~can~~sfera bepuò ~~taken~~essere toconsiderata become ~~made~~costituita upda ofdue ~~two~~pile ~~stacks~~di ofdischi ~~infinitesimally~~solidi ~~thin~~infinitamente sottili, ~~solid~~uno ~~discs~~sopra l'altro, ~~where~~con ~~the~~i ~~radius~~raggi ~~differs~~che ~~from~~aumentano da ''0'' toa ''r'' (oro ~~a single~~un'unica ~~stack~~pila, ~~where~~con ~~the~~il ~~radius~~raggio ~~differs~~dei ~~from~~cerchi crescente da ''-r'' toa ''r''). Un altro modo per ottenere la sfera piena è considerarla costituita da sfere cave infinitamente sottili, con raggio crescente da ''0'' a ''r''. ~~Also, it can be taken to be made up of infinitesimally thin, hollow spheres, where the radius differs from 0 to ''r''.~~ \|- \| [[~~right angle\|Right~~Cono]] ~~circular~~circolare [[~~cone~~Angolo ~~(geometry)~~retto\|~~cone~~retto]] ~~with~~con ~~radius~~raggio ''r'', ~~height~~altezza ''h'' ~~and~~e ~~mass~~massa ''m'' \|align="center"\| [[Image:moment of inertia cone.svg\|120px]] \|<math>I_z = \frac{3}{10}mr^2 \,\!</math>  <ref name="beer">{{~~cite~~cita ~~book~~libro \|~~title~~titolo=Vector Mechanics for Engineers, fourth ed. \|~~author~~autore=~~Ferdinand~~Ferdine P. Beer ~~and~~e E. Russell Johnston, Jr \|~~page~~pagina=911 \|~~publisher~~editore=McGraw-Hill \|isbn=0-07-004389-2 \|~~year~~anno=1984 }}</ref><br/><math>I_x = I_y = \frac{3}{5}m\left(\frac{r^2}{4}+h^2\right) \,\!</math>  <ref name="beer"/> \|— \|- \| [[Toro (geometria)\|Toro]] con raggio del ''tubo'' (raggio del cerchio rosso) ''a'', distanza dal centro del ''tubo'' al centro del toro (raggio del cerchio rosa) ''b'' e massa ''m''. ~~\| [[Torus]] of tube radius ''a'', cross-sectional radius ''b'' and mass ''m''.~~ \|align="center"\| [[Image:torus cycles.png\|122px]] \| ~~About~~Intorno aal ~~diameter~~diametro: <math>\frac{1}{8}\left(4a^2 + 5b^2\right)m</math>  <ref name="~~weisstein_torus~~weisstein_toro">{{~~cite~~cita web \| url = http://scienceworld.wolfram.com/physics/MomentofInertiaRing.html \| ~~title~~titolo = Moment of Inertia — Ring \| ~~author~~autore = [[Eric W. Weisstein]] \| ~~publisher~~editore = [[Wolfram Research]] \| ~~accessdate~~accesso = 2010-03-25 }}</ref><br/> ~~About~~Intorno ~~the~~all'asse ~~vertical axis~~verticale: <math>\left(a^2 + \frac{3}{4}b^2\right)m</math>  <ref name="~~weisstein_torus~~weisstein_toro"/> \|— \|- \| [[~~Ellipsoid~~Ellissoide]] (~~solid~~solido) ofdi ~~semiaxes~~semiassi ''a'', ''b'', ~~and~~e ''c'', ~~with~~con ~~axis~~asse ofdi ~~rotation~~rotazione ''a'' ~~and~~e ~~mass~~massa ''m'' \| [[Image:Ellipsoid_321.png‎\|170px]] \|<math>I_a = \frac{m (b^2+c^2)}{5}\,\!</math> \|— \|- \| ~~Thin~~Piastra ~~rectangular~~rettangolare ~~plate~~sottile ofdi ~~height~~altezza ''h'', ~~and of width~~larghezza ''w'' ~~and~~e ~~mass~~massa ''m'' <br>(~~Axis~~Asse ofdi ~~rotation~~rotazione ~~at the end of~~all'estremità ~~the~~della ~~plate~~piastra) \|align="center"\| [[Image:Recplaneoff.svg]] \|<math>I_e = \frac {m h^2}{3}+\frac {m w^2}{12}\,\!</math> \|— \|- \| ~~Thin~~Piastra ~~rectangular~~rettangolare ~~plate~~sottile ofdi ~~height~~altezza ''h'', ~~and of width~~larghezza ''w'' ~~and~~e ~~mass~~massa ''m'' \|align="center"\| [[Image:Recplane.svg]] \|<math>I_c = \frac {m(h^2 + w^2)}{12}\,\!</math>  <ref name="serway"/> \|— \|- \| ~~Solid~~ [[~~cuboid~~Parallelepipedo]] ofsolido ~~height~~di altezza ''h'', ~~width~~larghezza ''w'', ~~and depth~~profondità ''d'', ~~and~~e ~~mass~~massa ''m'' \|align="center"\| [[Image:moment of inertia solid rectangular prism.png]] \|<math>I_h = \frac{1}{12} m\left(w^2+d^2\right)</math><br><math>I_w = \frac{1}{12} m\left(h^2+d^2\right)</math><br><math>I_d = \frac{1}{12} m\left(h^2+w^2\right)</math> \| ~~For~~Per aun ~~similarly~~cubo ~~oriented~~orientato ~~[[cube~~allo ~~(geometry)\|cube]]~~stesso ~~with~~modo ~~sides~~e ofcon ~~length~~lati di lunghezza <math>s</math>,: <math>I_{CM} = \frac{m s^2}{6}\,\!</math>. \|- \| ~~Solid~~ [[~~cuboid~~Parallelepipedo]] ofsolido ~~height~~di altezza ''D'', ~~width~~larghezza ''W'', ~~and length~~lunghezza ''L'', ~~and~~e ~~mass~~massa ''m'' ~~with~~con ~~the~~asse ~~longest~~lungo ~~diagonal~~la asdiagonale ~~the~~più ~~axis~~lunga. \|align="center"\| [[Image: Moment of Inertia Cuboid.jpg\|140px]] \|<math>I = \frac{m\left(W^2D^2+L^2D^2+L^2W^2\right)}{6\left(L^2+W^2+D^2\right)}</math> \| ~~For~~Per aun ~~cube~~cubo ~~with~~di ~~sides~~lato <math>s</math>, <math>I = \frac{m s^2}{6}\,\!</math>. \|- \| ~~Plane~~Poligono ~~[[polygon]]~~piano ~~with~~con ~~vertices~~vertici <math>\vec{P}_{1}</math>, <math>\vec{P}_{2}</math>, <math>\vec{P}_{3}</math>, ..., <math>\vec{P}_{N}</math> ~~and~~e massa <math>m</math> uniformemente distribuita, che ruota intorno a un asse perpendicolare al piano e passante per l'origine. ~~mass <math>m</math> uniformly distributed on its interior, rotating about an axis perpendicular to the plane and passing through the origin.~~ \|align="center"\| [[Image:Polygon moment of inertia.png\|130px]] \|<math>I=\frac{m}{6}\frac{\sum\limits_{n=1}^{N-1}\\|\vec{P}_{n+1}\times\vec{P}_{n}\\|((\vec{P}_{n+1}\cdot\vec{P}_{n+1})+(\vec{P}_{n+1}\cdot\vec{P}_{n})+(\vec{P}_{n}\cdot\vec{P}_{n}))}{\sum\limits_{n=1}^{N-1}\\|\vec{P}_{n+1}\times\vec{P}_{n}\\|}</math> \|~~This~~Questa ~~expression~~espressione ~~assumes~~assume ~~that~~che ~~the~~il ~~polygon~~poligono issia [[~~star-shaped~~Insieme ~~polygon~~stellato\|~~star-shaped~~stellato]]. ~~The~~I ~~vectors~~vettori <math>\vec{P}_{1}</math>, <math>\vec{P}_{2}</math>, <math>\vec{P}_{3}</math>, ..., <math>\vec{P}_{N}</math> ~~are~~sono i [[~~position vector~~Posizione\|~~position~~vettori ~~vectors~~posizione]] ~~of the~~dei ~~vertices~~vertici. \|- \| Disco infinito con massa [[Distribuzione normale\|distribuita normalmente]] su due assi intorno all'asse di rotazione ~~\| Infinite [[disk (mathematics)\|disk]] with mass [[normally distributed]] on two axes around the axis of rotation~~ (~~i.e.~~per esempio: <math> \rho(x,y) = \tfrac{m}{2\pi ab}\, e^{-((x/a)^2+(y/b)^2)/2} </math> ~~Where :~~dove <math> \rho(x,y) </math> isè la ~~the~~densità ~~mass-density~~della asmassa ain ~~function~~funzione ofdi x ~~and~~e y). \|align="center"\| [[File:Gaussian 2D.png\|130px]] \| <math>I = m (a^2+b^2) \,\!</math> Riga 131: \|} <!-- There is no such thing as an illegal set of axes. They may be invalid for some purposes but the x, y ~~and~~e z may just be labels. The right-~~hand~~he rule has no bearing here. the x-y-z axis for the solid cylinder does not follow the right-~~hand~~he rule ~~and~~e is an illegal set of axis. --> ==~~See~~Vedi ~~also~~anche== [[~~Parallel~~Momento ~~axis~~di ~~theorem~~inerzia]] [[Teorema di Huygens-Steiner\|Teorema di Huygens-Steiner, o degli assi paralleli]] [[Perpendicular axis theorem]] [[List of area moments of inertia]] *[[List of moment of inertia tensors]] ==~~References~~Note== <references/> <!-- [[Category:Mechanics\|Moment of inertia]] [[Category:Physics lists\|Moments of inertia]] [[Category:~~Introductory~~IntAstauctory physics]] [[ar:ملحق:قائمة عزم القصور الذاتي]] Riga 159 ⟶ 158: [[uk:Список моментів інерції]] [[zh:轉動慣量列表]] -->