Work, Power & Energy Cheat sheet
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This document provides a cheat sheet on key concepts and formulas for work, power, and energy in AP Physics. It defines important terms like force, displacement, velocity, acceleration, and energy. Key formulas are presented for work, power, kinetic energy, and gravitational potential energy. Metric units and conventions for signs in work calculations are also outlined. Problem solving tips are given for work, power, and energy problems, emphasizing identifying given information, appropriate formulas, and energy conversions.
Work, Power & Energy Cheat sheet
- 1. RapidLearningCenter.com © Rapid Learning Inc. All Rights Reserved AP Physics - Core Concept Cheat Sheet 07: Work, Power and Energy Key Physics Terms • Force: Any influence that tends to accelerate an object; a push or a pull. Measured in Newtons. • Distance: The quantity that describes the position of an object. • Displacement: The quantity that describes the change in location of an object and includes its direction of motion. • Velocity: The distance an object travels per unit of time including its direction of motion. • Acceleration: Rate at which an object’s velocity changes with time; this change may in speed, direction, or both. • Vector: A quantity that represents magnitude (size) and direction. It is usually represented with an arrow to indicate the direction; the arrow may be drawn to scale. • Vector Component: The perpendicular parts into which a vector can be separated and that act in different directions from the vector. • Work: Product of force on an object and the distance through which the object is moved. • Power: Work done per unit of time. • Energy: The ability to do work. • Base level: An arbitrary reference point from which distances are measured. • Kinetic Energy: The energy an object has due to its motion. • Gravitational Potential Energy: The energy an object has due to its position above some base level. • Work-Energy Theorem: The work done is equal to the change in energy. • Conservation of Energy: Energy is not created or destroyed, just transformed from one type to another. Variables Used • d = distance or displacement • v = velocity • a = acceleration • t = time • F = force • Δ = change in • Θ = angle • m = mass • g= Acceleration due to gravity, = -9.8 m/s2 • h = height above base level • W = work • P = power • KE =kinetic energy • PE = potential energy Key Formulas • W= Fd = mad • W = Fd cos θ • P = W/t • a = Δv/Δt • cos θ = adjacent / hypotenuse • KE = ½ mv2 • PE = mgh Key Conventions •If the force and displacement are in the same direction, the work is positive, +. •If the force and displacement are in opposite directions, the work is negative, -. Key Metric Units •Force: Newtons, N •Displacement: meters, m •Energy: Joules, J, 1 Joule = 1 N m = 1 kg m2 /s2 •Work: Joules, J •Power : Watts, W, 1 Watt = 1 J/s Key Concepts • Work is done only when a force acts in the direction of motion of an object. • If the force is perpendicular to the direction of motion, then no work is done. • Power is the ratio of work done per unit time. • Any moving object possesses kinetic energy. • When an object is lifted above some arbitrary base level position, its gravitational potential energy is increased. • Energy may appear in different forms, but it is always conserved. The total amount of energy before and after some interaction is constant. • Work and energy are interchangeable. Typical Vector Diagrams Work and Power Problem Solving Tips These tips will make it easier to solve work and power physics problems: • Thoroughly read the entire problem. • Draw a diagram if needed. • Identify all given information. • Identify the quantity to be found. • Select appropriate formula(s) that incorporate what you know and what you want to find. • Convert units if needed. Use units throughout your calculations. • Do any mathematical calculations carefully. • When using trig functions, be sure your calculator is the correct mode (degrees or radians). • When calculating work, be sure to use only the component of force in the direction of motion. • For conservation of energy problems, try to identify the various types of energy in the situation. If possible, equate the energies to help solve for any unknowns. • Check to see if your answer seems reasonable. If not, go back and look for errors. Energy Specific Problem Solving Tips These tips will make it easier to solve energy specific: • For conservation of energy problems, try to identify the various types of energy in the situation. If possible, equate the energies to help solve for any unknowns. • Often quantities like mass cancel out. This means you don’t need to know these to calculate another variable. • When assigning the base level, the ground or floor in the problem is usually a good choice. • If energy seems to be missing or disappear, consider where the energy may have been converted. Heat, friction, and air resistance are common possibilities. How to Use This Cheat Sheet: These are the keys related this topic. Try to read through it carefully twice then write it out on a blank sheet of paper. Review it again before the exams. θ θ Component of force used in work calculation since this is the direction of motion. weight Component of force used in work calculation since this is the direction of motion. applied force