FALSE!
That is the case when you are talking about instantaneous speed and velocity - or when the velocity is constant. In the case of an average speed and velocity, this relation does not hold.
For two bodies with equal radius, the more massive has the greater escape velocity. For two bodies with equal mass, the one with smaller radius has the greater escape velocity. Both conditions listed in the question indicate greaterescape velocity.
A velocity potential is a scalar function whose gradient is equal to the velocity of the fluid at that point. If a fluid is incompressible and has zero viscosity (an ideal fluid) its velocity as a function of position can always be described by a velocity potential. For a real fluid this is not generally possible.
isopach lines are contour lines that connect areas of equal ground thickness.
Isoplats.
Mainly, when the velocity doesn't change. Also, in the case of varying velocity, the instantaneous velocity might, for a brief instant, be equal to the average velocity.
when a car travels equal distance in equal intervals of time its velocity is uniform and equal
In that case, the velocity is said to be constant.
For the instantaneous value of average velocity, average speed and average velocity are equal.
Always.
In uniform motion.
the tangential velocity is equal to the angular velocity multiplied by the radius the tangential velocity is equal to the angular velocity multiplied by the radius
Because charge particles produces magnetic field which causes electromagnetic force that's why moving charges move with the velocity equal to the velocity of light.
No, It is the average velocity.
When two lines cross each other they form vertical equal opposite angles
when the body in motion covers equal displacement in equal intervals of time.