The velocity of a ball thrown at 16 ft/sec is 16 ft/sec. This means that the ball is moving at a constant speed of 16 feet per second in a particular direction.
The velocity of the ball is 16 feet/sec when it is thrown upward.
The velocity of a ball thrown upward at 16 ft/sec would be 16 ft/sec when it leaves the hand, but it will decrease due to gravity as it moves upward.
If a ball is thrown vertically upward with a velocity of 160 ft/s, then its height after t seconds is s = 160t - 16t^2. If a ball is thrown vertically upward with a velocity of 160 ft/s, then its height after t seconds is s = 160t − 16t^2.
The initial velocity of the ball thrown upward at 16 ft per second is 16 ft/s.
The initial velocity of the ball is 16 feet per second when thrown upward. The velocity decreases as the ball travels upward due to gravity until it reaches its peak and starts to fall back down.
The velocity of the ball is 16 feet/sec when it is thrown upward.
The velocity of a ball thrown upward at 16 ft/sec would be 16 ft/sec when it leaves the hand, but it will decrease due to gravity as it moves upward.
If a ball is thrown vertically upward with a velocity of 160 ft/s, then its height after t seconds is s = 160t - 16t^2. If a ball is thrown vertically upward with a velocity of 160 ft/s, then its height after t seconds is s = 160t − 16t^2.
The initial velocity of the ball thrown upward at 16 ft per second is 16 ft/s.
The initial velocity of the ball is 16 feet per second when thrown upward. The velocity decreases as the ball travels upward due to gravity until it reaches its peak and starts to fall back down.
16 feet/second is the speed. To know the velocity, you would also need to specify the direction in which the object moves.
Substitute the 2 in for t.38(2)-16(2)^276-64=12
The velocity of the ball will decrease as it moves upward due to gravity acting against it. At the highest point of its trajectory, the velocity will briefly be zero before it begins to fall back down.
only about 25 times in 16 games in 2008.
If it was thrown horizontally, it had an initial velocity of 10 meters/sec parallel to the ground. (It traveled 40 meters in 4 secs with no acceleration. x=vt) It also took 4 secs to travel vertically. It started with a vertical velocity of 0 m/s. Using x=v0 + (1/2) a t2 a = -g ( Acceleration due to gravity 9.8m/s2) x=0-(1/2)g*16 = -8 * 9.8 = -78.4 m It fell 78.4 meters before coming to a stop.
An impulse is simply a change of momentum, and momentum is defined as mass x velocity; so you just divide the momentum by the mass to get the velocity. Note about the units: newton x second is the same as kilogram x meter/second2.
First Answer:Yes it does.Second Answer:Not so much. The most important thing is velocity, tracking, rotation, accuracy, and hitting the sweet spot or "pocket" of the pins. You will get more pin action from 16 pound ball than a 6 pound ball thrown with the same velocity though, so in broader general terms yes, but not from just a difference in a few pounds alone.