The average velocity would be the total displacement over the total time interval. To calculate this, divide the total displacement by the total time to get the average velocity.
You use the equation: acceleration=change in velocity/time interval a = 60 / 10 a = 6
The average overhand throw velocity for Division 1 softball players is around 60-70 miles per hour. This velocity can vary depending on the position of the player and their level of experience and training.
If a 5 mile stretch of a bus journey lasts 15 minutes, then the average speed over this stretch was 20mph. But undoubtedly the bus achieved greater speeds than this, and it also spent time sitting still in queues. So the simple answer to the question is 'yes'. Less trivially and more interestingly: unless velocity is actually constant, then an object's average velocity over a finite time interval - and hence any empirical measurement of its speed - must (nearly always) differ from the instantaneous velocity. As the time period grow closer to zero, the measured velocity will converge on the instantaneous figure, but will never reach it.
The velocity sensor should be placed at approximately 40-60% of the total water depth, so in this case, it should be placed at around 5-7.5 meters from the surface to estimate the stream's average velocity accurately. Placing it in this range helps account for variations in velocity across the vertical profile of the stream.
The average velocity for the first 3 seconds of a skydiver's free fall would depend on the initial speed, air resistance, and gravitational acceleration, but generally, it could be around 55-60 m/s.
a=change over velocity/time 60-initial velocity 45-final velocity 45-60= 15m/s 15/5= 3- acceleration
You use the equation: acceleration=change in velocity/time interval a = 60 / 10 a = 6
The angular velocity of a pulley turning 1800 rpm is 60 pi radians per second.
60 km/h
It's 60 divided by 5, Which is 12m/s east. Velocity is a vector for speed, since velocity has a direction and speed does not. Velocity has the SI units of meters per second. So you take the meters and divide by how many seconds to get your velocity.
If the values range from 0 to 60 and there are 6 classes, then the interval is 60/6 = 10.
Average acceleration over an interval of time = (final speed - initial speed) / (time for the change)= [ (0 - 30) / 1 ] (meters / second-minute) = [ (0 - 30) / (60) ] (meters / second-second) =-0.5 meter / sec2
1000 metres = 1 kilometre : 60 seconds = 1 minute : 60 minutes = 1 hour Velocity (or speed) = Distance ÷ Time Velocity = 14 ÷ 1 = 14 metres per second = 14 x 60 x 60 = 50400 metres per hour = 50400 ÷ 1000 = 50.4 kph.
The interval is [25, 160].
After any whole number of revolutions, the total displacement is zeroand so the average velocity is zero.At any instant, the magnitude (speed component) of instantaneous velocity is(pi) x (distance from center of rotation) x (RPM / 30) units per second.
To find the mass of the dog, we can use the formula for momentum, which is momentum = mass × velocity. Given the momentum of 60 kg·m/s and a velocity of 3 m/s, we can rearrange the formula to find mass: mass = momentum / velocity. Thus, the mass of the dog is 60 kg·m/s ÷ 3 m/s = 20 kg.
The class interval is 5.