Time (s)012 Mass of car & bucket (kg) Mass of falling bucket (kg) Force of falling bucket (F = m x a (earth) ) (N) Acceleration of the system ( F = m.

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Presentation transcript:

Time (s)012 Mass of car & bucket (kg) Mass of falling bucket (kg) Force of falling bucket (F = m x a (earth) ) (N) Acceleration of the system ( F = m x a ) (m/s/s) Speed at the end of this second ( a = (Vf-Vo)/t ) (m/s) Distance traveled during this second ( s = ½ a t^2 ) (m) Total distance traveled (m)

Time (s)012 Mass of car & bucket (kg) Mass of falling bucket (kg) Force of falling bucket (F = m x a (earth) ) (N) Acceleration of the system ( F = m x a ) (m/s/s) Speed at the end of this second ( a = (Vf-Vo)/t ) (m/s) Distance traveled during this second ( s = ½ a t^2 ) (m) Total distance traveled (m)

Time (s)012 Mass of car & bucket (kg) Mass of falling bucket (kg) Force of falling bucket (F = m x a (earth) ) (N) Acceleration of the system ( F = m x a ) (m/s/s) Speed at the end of this second ( a = (Vf-Vo)/t ) (m/s) Distance traveled during this second ( s = ½ a t^2 ) (m) Total distance traveled (m)

Time (s)012 Mass of car & bucket (kg) Mass of falling bucket (kg) Force of falling bucket (F = m x a (earth) ) (N) Acceleration of the system ( F = m x a ) (m/s/s) Speed at the end of this second ( a = (Vf-Vo)/t ) (m/s) Distance traveled during this second ( s = ½ a t^2 ) (m) Total distance traveled (m)

Time (s)012 Mass of car & bucket (kg) Mass of falling bucket (kg) Force of falling bucket (F = m x a (earth) ) (N) Acceleration of the system ( F = m x a ) (m/s/s) Speed at the end of this second ( a = (Vf-Vo)/t ) (m/s) Distance traveled during this second ( s = ½ a t^2 ) (m) Total distance traveled (m)

Time (s)012 Mass of car & bucket (kg) Mass of falling bucket (kg) Force of falling bucket (F = m x a (earth) ) (N) Acceleration of the system ( F = m x a ) (m/s/s) Speed at the end of this second ( a = (Vf-Vo)/t ) (m/s) Distance traveled during this second ( s = ½ a t^2 ) (m) Total distance traveled (m)