Defining Motion- Velocity and Acceleration

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Presentation transcript:

Defining Motion- Velocity and Acceleration Did you watch the video? http://aplusphysics.com/courses/regents/videos/Define_Motion_Reg/Define_Motion_Reg.html

Most of this video you already know: What does the line mean over the “v”? average What do we use for “d” when calculating speed? distance What do we use for “d” when calculating velocity? displacement What is acceleration? Describes how quickly velocity changes- speeding up or slowing down

Acceleration Formula 𝑎= ∆𝑣 𝑡 = 𝑣 𝑓 − 𝑣 𝑖 𝑡 𝑎= ∆𝑣 𝑡 = 𝑣 𝑓 − 𝑣 𝑖 𝑡 Review the Problem Solving Format: Unknown/Given Formula Solve for unknown (if needed) Substitute with units Answer with correct units

Acceleration is a vector. The direction of the acceleration vector depends on two things: whether the object is speeding up or slowing down whether the object is moving in the + or - direction The general principle for determining the acceleration is: If an object is slowing down, then its acceleration is in the opposite direction of its motion.

Velocity vector is showing you direction of movement. Acceleration vector is showing you how that movement is changing (speeding up or slowing down).

acceleration vector and velocity vector are in the Same sign direction = positive acceleration = car speeding up to the right/east - + acceleration vector and velocity vector are in opposite sign directions = negative acceleration = car is slowing down as it moves toward the right/east - + acceleration vector and velocity vector are in opposite sign directions = positive acceleration = car is slowing down as it moves toward the left/west - + acceleration vector and velocity vector are in the same sign direction =negative acceleration = car speeding up to the left/west - +

Orange Book Practice:

Protractor-Ruler A cart is concurrently being pushed with a force of 9 Newton's south by one student and 6 Newton's east by another. Use a protractor and ruler to draw a scaled diagram representing these 2 vector quantities and then determine the resultant vector (direction and magnitude) of these forces. In other words, towards which direction will the cart end up moving and with what total force? Be sure to include the scale you used. Scale: 1 cm = 1 Newton Vector Addition- tip to tail Draw in resultant Measure length of resultant to get its magnitude Magnitude of resultant = 10.8 cm = 10.8 Newtons