Match the following
`{:(,"Table - 1",,"Table - 2",),((A),sigma^(2)//epsi_(0),(P),C^(2)//J - m,),((B),epsi_(0),(Q),"Farad",),((C),("ampere - second")/("Volt"),(R),J//m^(3),),((D),(V)/(E),(S),"metre",):}`

Match the following |{:(,"Table-1",,"Table-2"),((A),"stress"xx"Strain",(P),J),((B),(YA)/l,(Q),N//m),((C),Yl^(3),(R),J//m^(3)),((D),(Fl)/(AY),(S),m):}|

Match the following {:(,,"Table-1",,"Table-2"),(,(A),L,(P),[M^(0)L^(0)T^(-2)]),(,(B),"Magnetic Flux",(Q),[ML^(2)T^(-2)A^(-1)]),(,(C),LC,(R),[ML^(2)T^(-2)A^(-2)]),(,(D),CR^(2),(S),"None"):}

Match the following. |{:(,"Table-1",,"Table-2"),((A),"Coefficient of viscosity",(P),[M^(2)L^(-1)T^(-2)]),((B),"Surface tension",(Q),[ML^(0)T^(-2)]),((C),"Modulus of elasticity",(R),[ML^(-1) T^(-2)]),((D),"Energy per unit volume",(S),"None"),(,"of a fiuid",,):}|

Match the following column. {:(,"A",,"B"),((A),"Work",(p),kg m//s^(2)),((B),"Force",(q),m^(2)),((C),"Speed",(r),m//s),((D),"Area",(s),kg m^(2)//s^(2)):}

Match the following : {:(,"Column-I",,"Column-II"),((A),3s^(1),(p),n=3),((B), 3p^(1),(q), l=0),((C ), 4s^(1),(r ) , l=1),((D),4d^(1),(s),m=0),(,,(t),m=+-1):}

Comparing L-C oscillation with the oscillation if spring-block-system, match the following table. Comparing L-C oscillations with the oscillations of spring-block sytem, match the following table {:(,,underset(("LC oscillations"))"Table-1",,underset(("Spring-block oscillations"))"Table-2"),(,(A),L,(P),k),(,(B),C,(Q),m),(,(C),i,(R),v),(,(D),(di)/(dt),(S),x),(,,,(T),"None"):}

Match the quantities with their respective dimensions. {:(,"A",,"B"),((A),"Displacement",(p),MLT^(-2)),((B),"Velocity",(q),M^(0)LT^(-2)),((C),"Acceleration",(r),M^(0)LT^(-1)),((D),"Force",(s),M^(0)LT^(0)):}

Match the quantities with their SI unit. {:(,"(A)",,"(B)"),((A),"Mass",(p),"Ampere"),((B),"Temperature",(q),"Metre"),((C),"Length",(r),"Kelvin"),((D),"Current",(s),"Kilogram"):}

Some physical quanties are given in Column I and some possible SI units in which these quantities may be expressed are given in Column II. Match the physical quantities in Column I with the units in Column II. {:(,"Column I",,,"Column II"),((A),GM_(e)M_(s),,(p),("volt")("coulomb")("metre")),(,G-"universal gravitational constant",,,),(,M_(e)-"mass of the earth," M_(s)- "mass of the sun",,,),((B),(3RT)/(M),,(q),("kilogram")("metre")^(3)("second")^(-2)),(,R-"universal gas constant,",,,),(,T- "absolute temperature, M- molar mass",,,),((C),F^(2)/(q^(2)B^(2)),,(r),("metre")^(2)("second")^(-2)),(,F-"force,"q-"charge," B- "magnetic field",,,),((D),(GM_(e))/R_(e),,(s),("farad")("volt")^(2)(kg)^(-1)),(,G- "universal gravitational constant,",,,),(,M_(e)- "mass of the earth," R_(e)- "radius of the earth.",,,):}

Match the following: {:(," ""Column-I",," ""Column-II"),((a),F = A sin(B t) + (1)/(C ln (Dx)) "For above equation to be dimensionally correct",(p),[A] = [M^(1)L^(1)T^(-1)]","[B] = [M^(0)L^(0)T^(-1)]","[C] = [M^(0)L^(0)T^(-1)]),((b) ,"Pressure" = P + (1)/(2)rhov^(2) + gX ,(q),[A] = [M^(0)L^(1)T^(-1)]"," [B] = [M^(0)L^(0)T^(-1)]","[C] = [M^(0)L^(0)T^(-1)]","),((c),X = At+(v)/(B ln(Cr)),(r),[A] = [M^(1)L^(1)T^(-2)]","[B] = [M^(0)L^(0)T^(-1)]","[C] = [M^(-1)L^(0)T^(1)]),(,,(s),"Dimensionally incorrect""):} (Where F = force, P = pressure, rho = density, t = time, v = velocity, a = acceleration, X = displacement)