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Transcript
Review for Exam I Friday, February 27th Chapters 1 - 10 Physics 1100 – Spring 2009 1 Physics 1100 – Spring 2009 2 Newton’s 1st law If the total “resultant” force acting on an object is zero, then the object will either remain at rest or it would move along a line with a constant velocity. Physics 1100 – Spring 2009 3 Newtons’ Second Law • F=ma • The acceleration of an object is directly proportional to the net force acting on the object… • …and inversely proportional to the mass of the object. Physics 1100 – Spring 2009 4 Newton’s Third Law • Action-Reaction • Whenever one body exerts a force on a second body… • …the second body exerts an equal and opposite force on the first body. Physics 1100 – Spring 2009 5 Newton’s Laws in Review • 1st – Law of Inertia • 2nd – F=ma • 3rd – Action/Reaction Physics 1100 – Spring 2009 6 Linear Motion • • • • • Speed d = v t v=d/t Velocity (magnitude & direction) Acceleration a = f / m Free Fall Velocity v = g t Free Fall Distance d = ½ g t2 Physics 1100 – Spring 2009 7 Chapter 4 - Newton’s Second Law • • • • • F=ma Friction Mass Weight Terminal Velocity Physics 1100 – Spring 2009 8 Vector or Scalar? • • • • • • Speed……….. Velocity……... Acceleration.. Time…………. Distance…….. Force………… scalar vector vector scalar scalar vector Physics 1100 – Spring 2009 9 Mass • the quantity of matter in an object • the measurement of the inertia • measured in kilograms (kg) Physics 1100 – Spring 2009 10 Weight • the force upon an object due to gravity • Weight = Mass Acceleration of gravity W = mg • measured in Newtons (N) in the metric system or pounds (lb) in the British system Physics 1100 – Spring 2009 11 When Acceleration Is Zero... • …we say the object is in Mechanical Equilibrium. • …the net force is zero. Physics 1100 – Spring 2009 12 Friction • Friction - a force that resists motion – Static frictional force: when nothing is sliding – Sliding frictional force: when surfaces are sliding – Static frictional forces always greater than sliding ones • Inertia - the resistance of an object to change in its state of motion Physics 1100 – Spring 2009 13 Free Fall Physics 1100 – Spring 2009 14 Momentum • Momentum - Inertia in motion – momentum = m v – Impulse = F t = ∆ m v • Inertia - the resistance of an object to change in its state of motion Physics 1100 – Spring 2009 15 Energy definitions • Potential Energy (due to Earth’s gravity) P.E. = m g h • Kinetic Energy K.E. = ½ m v2 • Work (units: 1 N * 1 m = 1 joule = .239 calories) W = F d = ∆ Kinetic Energy • Power (units: 1 joule / second = 1 watt) 1 Kilowatt = 1000 watts and 1 Megawatt = 1M watts 1 HorsePower = 746 Watts P=W/t Physics 1100 – Spring 2009 16 Momentum and Impulse Physics 1100 – Spring 2009 17 Momentum & Impulse Physics 1100 – Spring 2009 18 Vector Addition Physics 1100 – Spring 2009 19 Torque • Torque is the product of the force and lever-arm distance, which tends to produce rotation. • Torque = force lever arm – Examples: • wrenches • see-saws Physics 1100 – Spring 2009 20 Rotational Inertia • An object rotating about an axis tends to remain rotating unless interfered with by some external influence. • This influence is called torque. • Rotation adds stability to linear motion. – Examples: • spinning football • bicycle tires • Frisbee Physics 1100 – Spring 2009 21 • The greater the distance between the bulk of an object's mass and its axis of rotation, the greater the rotational inertia. • Examples: – Tightrope walker – Ring and Disk on an Incline – Metronome Physics 1100 – Spring 2009 22 Centripetal Force • …is applied by some object. • Centripetal means "center seeking". Centrifugal Force • …results from a natural tendency. • Centrifugal means "center fleeing". Physics 1100 – Spring 2009 23 Circular Motion • Linear speed - the distance moved per unit time. Also called simply speed. • Rotational speed - the number of rotations or revolutions per unit time. • Rotational speed is often measured in revolutions per minute (RPM). Physics 1100 – Spring 2009 24 Angular Momentum • Another conserved quantity is angular momentum, relating to rotational inertia: • Spinning wheel wants to keep on spinning, stationary wheel wants to keep still (unless acted upon by an external rotational force, or torque) • Newton’s laws for linear (straight-line) motion have direct analogs in rotational motion Physics 1100 – Spring 2009 25 Gravity • Newton’s Universal Law of Gravitation: F = GM1M2/r2 Physics 1100 – Spring 2009 26 Gravity • Weight • the force due to gravity on an object • Weight = Mass Acceleration of Gravity • W=mg • Weightlessness - a conditions wherein gravitational pull appears to be lacking – Examples: • Astronauts • Falling in an Elevator • Skydiving • Underwater Physics 1100 – Spring 2009 27 Projectile Motion • Break the motion into 2 aspects, “components” – Horizontal – Vertical • There is no force acting in the horizontal direction – Horizontal velocity does not change – Horizontal distance = time in air x horizontal velocity • There is a force acting in the vertical direction – force of gravity! – Vertical velocity changes the same as if the projectile had been thrown straight up (or dropped) – Time in air determined by vertical travel Physics 1100 – Spring 2009 28 Projectiles Physics 1100 – Spring 2009 29 Physics 1100 – Spring 2009 30 Projectile Example • The boy on the tower throws a ball 20 meters downrange as shown. What is his pitching speed? Use the equation for speed as a "guide to thinking.“ v = d/t d is 20m; but we don't know t… the time the ball takes to go 20m. But while the ball moves horizontally 20m, it falls a vertical distance of 4.9m, which takes 1 second… so t = 1s. Physics 1100 – Spring 2009 31 Equation Sheet Units • Mass = kg (kilograms) • Distance = m (meters) • Force = kg m/s2 = 1 Newton • 1 Joule (J) = 1 N m • 1 Watt = 1J/s Momentum • Momentum (p) = mv • Change in p (Dp) = Impulse = F Dt • System with no external force pinitial = pfinal Newton’s Law’s • If FNet =0, then a =0 • If FNet >0, then FNet = ma • FAB = - FBA Energy and Energy Conservation • E = PE + KE • PE = mgh • KE = ½ mv2 • Work = Fparallel Dx = DE • Power (P) = Energy/time = DE/Dt Linear Displacement • Speed v = d / t • Distance (constant speed) d = v t • Acceleration a = f / m • Velocity (constant a) v = a t • Distance (constant a) d = ½ a t2 • Free-fall acceleration = g = 10 m/s2 Rotational Kinematics • Angular velocity = linear velocity/radius w =v/r • v(linear) = w r • Torque (t) = Force x Lever Arm • Rotational Inertia (I) • Angular momentum L = I w • System with no external torque Linitial = Lfinal Weight • W = mg Gravity • F = GM1M2/r2 Physics 1100 – Spring 2009 32
