Utilisateur:Pierre Chanial/Grandeurs physiques

The primary dimensions of physical quantities are arbitrary and depend on the choice of units. I is usually based on the base units of the International System of Units.

Other dimensions, such as force rather than mass, or charge [Q] rather than current [I], could be used. Even the number of dimensions is not fixed. In the three-base unit cgs system, for example, the units of charge are erg^½ cm^½ and the dimensional analysis of this quantity in terms of base units is [M]^½ [L] [T]^-1, whereas in the analysis below charge has units of [I][T]. Grandeur dérivée Also note that the symbols are not International Standards and may be used differently than shown here.

Grandeur de base	Notation	Unité (SI)	Symbole	Description
Masse	${\displaystyle m}$	kilogramme	kg	Quantité de matière d'un objet. extensive
Position	${\displaystyle {\vec {r}}}$	mètre	m	Coordonnées spatiales.
Date	${\displaystyle t}$	seconde	s	Coordonnée temporelle.
Intensité électrique	${\displaystyle I}$	ampère	A	Rate of flow of electrical charge.
Température	${\displaystyle T}$	kelvin	K	Average kinetic energy of particles in an object. intensive
Quantité de matière	${\displaystyle n}$	mole	mol	Number of particles compared to the number of atoms in 0.012 kg of 12C. extensive
Intensité lumineuse	${\displaystyle L}$	candela	cd	Amount of energy emitted by a light source in a particular direction.
Angles	Notation	Unité SI	Symbole	Description
Position angulaire	${\displaystyle \theta ,\,\phi ,\,\varphi }$	radian	rad	Coordonnée angulaire
Angle solide	${\displaystyle \Omega }$	stéradian	sr
Grandeur dérivée	Notation	Unité SI	Symbole	Description
Superficie	${\displaystyle S,{\mathcal {A}}}$		m2	The two dimensional extent of an object.
Volume	${\displaystyle V}$		m3	The three dimensional extent of an object. extensive
Fréquence	${\displaystyle f,\,\nu }$	hertz	Hz=s-1	The number of times something happens in a period of time.
Moment d'inertie	${\displaystyle J}$		kg m2
Densité linéique	${\displaystyle \lambda }$		kg m-1	Quantité de masse par unité de longueur
Densité superficielle	${\displaystyle \sigma }$		kg m-2	Quantité de masse par unité de surface
Densité volumique	${\displaystyle \rho ,\,\mu }$		kg m-3	Quantité de masse par unité de volume intensive
Vitesse	${\displaystyle {\vec {v}}}$		m s-1	Taux de variation de la position
Vitesse angulaire	${\displaystyle {\vec {\omega }},\,\omega }$		s-1	Taux de variation de la position angulaire
Accélération	${\displaystyle {\vec {a}}}$		m s-2	Taux de variation de la vitesse
Accélération angulaire	${\displaystyle \alpha }$		s-2	Taux de variation de la vitesse angulaire
Force	${\displaystyle {\vec {F}}}$	newton	N=kg.m.s-2	Cause externe d'accélération
Moment d'une force	T		N m = kg m2 s-2	Product of a force and the perpendicular disatance of the force from the point about which it is exerted. vector
Quantité de mouvement	${\displaystyle {\vec {q}},\,{\vec {p}}}$		kg m s-1	Produit de la masse d'un objet par sa vitesse extensive
Moment cinétique	${\displaystyle {\vec {\mathcal {L}}}}$		kg m2 s-1
Pression	${\displaystyle P,\,p}$	pascal	Pa = kg m-1 s-2	Force exercée par unité de surface. intensive
Énergie	${\displaystyle E,\,W}$	joule	J = kg.m2.s-2	The capacity of a body or system to do work. extensive, scalar, conserved quantity
Densité d'énergie	${\displaystyle w,\,u}$		J.m-3=	Quantité d'énergie par unité de volume
Puissance	${\displaystyle {\mathcal {P}},\,P}$	watt	W = kg m2 s-3	Taux de variation de l'énergie
Vecteur radiant ou de Poynting	${\displaystyle {\vec {\Pi }}}$		W.m-2 =	Flux d'énergie
Electromagnétisme
Charge	${\displaystyle Q,\,q}$	coulomb	C = A s	Quantité de charge électrique extensive, conserved quantity
Densité linéique de charge	${\displaystyle \lambda }$		C m-1	Quantité de charge par unité de longueur
Densité superficielle de charge	${\displaystyle \sigma }$		C m-2	Quantité de charge par unité de surface
Densité volumique de charge	${\displaystyle \rho }$		C m-3	Quantité de charge par unité de volume intensive
Densité de courant	${\displaystyle {\vec {\jmath }}}$		A m-2
Densité superficielle de courant	${\displaystyle {\vec {\imath }}}$		A m-1
Champ électrique	${\displaystyle {\vec {E}}}$		V.m-1 =
Champ magnétique	${\displaystyle {\vec {B}}}$	tesla	T =
Flux magnétique	${\displaystyle \Phi }$	weber	wb = kg s-2 A-1	Measure of quantity of magnetism, taking account of the strength and the extent of a magnetic field.
Potentiel scalaire	${\displaystyle U,\,V}$	volt	V = J.C-1 = kg.m2.s–3.A–1	Potential difference across a conductor when a current of one ampere dissipates one watt of power. scalar
Potentiel-vecteur	${\displaystyle {\vec {A}}}$		T.m =
Capacité	${\displaystyle C}$	farad	F =
Résistance,Impédance,Réactance	${\displaystyle R,\,Z,\,X}$	ohm	${\displaystyle \Omega }$ = kg·m2·s–3·A–2	the degree to which an object opposes the passage of an electric current. scalar
Conductance,Admittance,Susceptance	${\displaystyle G,\,Y,\,B}$	siemens	S =
Résistivité	${\displaystyle \rho }$		${\displaystyle \Omega }$.m
Conductivité	${\displaystyle \sigma }$		S.m-1 =
Polarisation	${\displaystyle {\vec {P}}}$		C.m-2 =
Aimantation	${\displaystyle {\vec {M}}}$		A.m-1
Excitation électrique	${\displaystyle {\vec {D}}}$		C.m-2 =
Excitation magnétique	${\displaystyle {\vec {H}}}$		A.m-1