`{:(,"Column I",,"Column II"),((A),"Dimensional variable",(p),pi),((B),"Dimensionless variable",(q),"Force"),((C),"Dimensional constant",(r),"Angle"),((D),"Dimensionless constant",(s),"Gravitational constant"):}`

Match the column I with Column II:- {:("Column I","Column II"),((A)" Unicellular",(i)" Spirogyra"),((B)" Colonial",(ii)" Kelps"),((C)" Filamentous",(iii)" Volvox"),((D)" massive plant bodies",(iv)" Chlamydomonas"):}

A balloon rises up with constant net acceleration of 10 m//s^(2) . After 2 s a particle drops from the balloon. After further 2 s match the following : ("Take" g=10 m//s^(2)) {:(,"Column I",,,"Column II"),((A),"Height of perticle from ground",,(p),"Zero"),((B),"Speed of particle",,(q),10 SI "units"),((C),"Displacement of Particle",,(r),40 SI "units"),((D),"Acceleration of particle",,(s),20 SI "units"):}

In y = Asinomegat + Asin(omegat + (2pi)/(3)) |{:(,"Column-I",,"Column-II"),((A),"Motion",(p),"is periodic but no SHM"),((B),"Amplitude",(q),"is SHM"),((C),"Initial phase",(r),A),((D),"Maximum velocity",(s),pi//3),(,,(t),omegaA//2),(,,(u),"None"):}|

Column - II shows the optical phenomenon that can be associated with optical components given in column- I . Note the column - I may have more than one matching options in column-II. {:("Column I","Column II"),((A)"Convex mirror",(p)"Dispersion"),((B)"Converging lens",(q) "Deviation"),((C)"Thin prism" , (r) "Real image of real object") , ((D) "Glass slab", (s) "Virtual images of real object"):}

{:(,"Column I",,,"Column II"),((A),"Moment of inertia",,(p),"newton"//"metre"^(2)),((B),"Surface tension",,(q),"kg"//("metre-sec")),((C),"Angular acceleration",,(r),"kg-metre"^(2)),((D),"Coefficient of viscosity",,(s),"newton"//"metre"),((E),"Modulus of elasticity",,(t),"radian"//"sec"^(2)):}

{:(,"Column I",,"Column II"),((A),"Base unit",(p),N),((B),"Derived unit",(q),hp),((C),"Improper unit",(r),"kgwt"),((D),"Practical",(s),"rad"),((E),"Supplementary unit",(t),kg):} (Note : Here it is given that you have to match one to one only)

If net force on a system of particles is zero. Then {:(,"Column I",,"Column II",),((A),"Acceleration of centre of mass",(p),"Constant",),((B),"Velocity of centre of mass",(q),"Zero",),((C ),"Momentum of centre of mass",(r ),"May br zero",),((D),"Velocity of an individual particle of the system",(s),"May be constant",):}

Match the following: {:(,"Column-I",,"Column-II"),((A),"Isobaric process",(p),"No heat exchange"),((B),"Isothermal process ",(q),"Constant pressure"),((C),"Isoentropy process",(r),"Constant internal energy"),((D),"Isochoric process",(s),"Work done is zero"):}

A particle is rotating in a circle of radius 1m with constant speed 4 m//s . In time 1s, match the following (in SI units) {:(,"Column I",,,"Column II"),((A),"Displacement",,(p),8 sin 2),((B),"Distance",,(q),4),((C),"Average velocity",,(r),2sin 2),((D),"Average acceleration",,(s),4 sin 2):}

{:(Column-I,Column-II),((A)"Conductance",(p)Cm^(-1)),((B)"Specific condutance",(q)Ohm^(-1)cm^(2)mol^(-1)),((C)"Cell constant",(r)Ohm^(1-)),((D)"Equivalent conductance",(s)Ohm^(-1)cm^(-1)),((E)"Molar conductance",(u)Ohm^(-1)cm^(2) "equivalent"^(-1)):}