Kinematic Equations Used in situations with uniform acceleration.

Slides:

Advertisements

Similar presentations

Motion in One Dimension

Advertisements

The Equations of Motion

Derivation of Kinematic Equations

I have to solve for WHAT? Kinematics Equations.

Motion with Uniform Acceleration

01-1 Physics I Class 01 1D Motion Definitions.

02-1 Physics I Class 02 One-Dimensional Motion Definitions.

Constant velocity Average velocity equals the slope of a position vs time graph when an object travels at constant velocity.

WE CAN ONLY USE THESE IN ONE DIRECTION AT A TIME (only X or only Y not both at same time)

Motion with Constant Acceleration

Derivation of Kinematic Equations

Chapter 2 Motion in One Dimension. Quantities in Motion Any motion involves three concepts Displacement Velocity Acceleration These concepts can be used.

Times Up0:010:020:03 0:040:050:060:070:080:09 0:101:002:003:004:005:00 Warm Up Describe what the V-T graph would look like for an object with negative.

You need: Binder For Notes.  Describe motion in terms of frame of reference, displacement, time interval and velocity.  Calculate displacement, average.

Scalar (Dot) Product. Scalar Product by Components.

2.2 Acceleration Physics A.

Graphical Analysis of SHM

Unit One The Newtonian Revolution Principia: Three Laws of motion Law of universal gravitation.

Final Velocity after Any Displacement The Last Equation… For now.

Derivation of Kinematic Equations

Equations of Uniform Accelerated Motion

Kinematics Equations. The main equations will be asterisked NOTE: You will NOT be expected to do this on a test, but it is important to know these equations.

Kinematics Kinematics is the branch of physics that describes the motion of points, bodies (objects) and systems of bodies (groups of objects) without.

Kinematic Equations with Constant Acceleration If an object moves with constant acceleration, we can use four kinematics equations Some Assumptions and.

المحاضرة الخامسة. 4.1 The Position, Velocity, and Acceleration Vectors The position of a particle by its position vector r, drawn from the origin of some.

A constantly changing velocity. Accelerated Motion.

2.1 Position, Velocity, and Speed 2.1 Displacement  x  x f - x i 2.2 Average velocity 2.3 Average speed  

position time position time tangent!  Derivatives are the slope of a function at a point  Slope of x vs. t  velocity - describes how position changes.

Solving Uniform Acceleration Problems. Equations for Uniformly Accelerated Motion variable not involved - d variable not involved - a variable not involved.

Aim: How do we use the kinematics formulas? Do Now: What is the difference between average velocity and instantaneous velocity? Quiz Tomorrow.

By: Christie, Danielle, and Nicole. Solves for Final Velocity Variables needed Initial Velocity Acceleration Change in time Displacement is not needed.

Warm up Problem A bus travels 280 km south along a straight path with an average velocity of 24.4 m/s to the south. The bus stops for 24 min, then it travels.

Relationship Between Velocity and Acceleration Velocity and acceleration are in the same direction Acceleration is uniform (blue arrows maintain the same.

*Only hold in cases of Uniform Acceleration

Kinematic Equations Chapter 2 Section 2. Accelerated Motion  Motion with constant acceleration is what we will mostly look at in this class  Example:

Falling Objects Falling objects experience uniform acceleration “Free fall” = the motion of falling objects in the absence of air resistance Free-fall.

1D Kinematics Equations and Problems. Velocity The rate at an object changes position relative to something stationary. X VT ÷ x ÷

Motion in One Dimension

Derivation of Kinematic Equations

Graphical Interpretation of Motion in One Dimension

Mechanics 1 : Kinematics

Graphical analysis of motion

Derivation of Kinematic Equations

Describing Motion Draw a detailed diagram like figure 2-9 that represents the response to conceptual example 2-4. Objective(s)/SWBAT (Students will be.

Derivation of Kinematic Equations

Chapter 2 Objectives Describe motion in terms of changing velocity.

Velocity and Acceleration

Describing Motion A rocket traveling at 88 m/s is accelerated uniformly to 132 m/s over a 15 s interval. What is its displacement during this time?

Motion with constant acceleration

Multiple Stage Kinematics Problems

Kinematics in one Dimension: Uniform motion graphs

Kinematics: The Mathematics of Motion

Derivation of Kinematic Equations

Acceleration Acceleration (a): The rate of change of an object’s velocity. Vector English Translation: Something is speeding up or slowing down.

Contents: 2-1E, 2-5E, 2-9P, 2-13P, 2-33P, 2-36P*

Chapter 2: Kinematics in One Dimension

Chapter 2 Uniformly Accelerated Motion

Derivation of Kinematic Equations

The Kinematics Equations

Kinematics-Part II Kinematics-Part I Velocity: Position: Acceleration:

Final Velocity and Acceleration Equations

Physics 12 - Key Points of the Lesson

Motion in One Dimension

Derivation of Kinematic Equations

Derivation of Kinematic Equations

Physics 20 Kinematics Review.

Section 1 Displacement and Velocity

Extracting them from Graphs

Presentation transcript:

Kinematic Equations Used in situations with uniform acceleration

Notes on the equations Gives displacement as a function of velocity and time Use when you don’t know and aren’t asked for the acceleration

Notes on the equations Shows velocity as a function of acceleration and time Use when you don’t know and aren’t asked to find the displacement

Graphical Interpretation of the Equation

Notes on the equations Gives displacement as a function of time, velocity and acceleration Use when you don’t know and aren’t asked to find the final velocity

Notes on the equations Gives velocity as a function of acceleration and displacement Use when you don’t know and aren’t asked for the time