Chapter 12 Kinematics ME 242 Chapter 12 Question 1 We obtain the acceleration fastest (A)By taking the derivative of x(t) (B)By Integrating x(t) twice (C)By integrating the accel as function of displacement (D)By computing the time to liftoff, then choosing the accel such that the velocity is 160 mph ME 242 Chapter 12 160 mi/h = 235 ft/s Question 2 The acceleration is approximately (A)92 ft/s2 (B)66 ft/s2 (C)85.3 ft/s2 (D)182 ft/s2 (E)18.75 ft/s2 Ya pili ME 242 Chapter 12 Solution: 160 mi/h = 235 ft/s We use v*dv = a*dx 1/ v2 = a*d, Integrate: 2 Question 2 The acceleration is approximately where d is the length of the runway, and the 2 (A)92 ft/s start velocity = 0 (B)66 ft/s2 (C)85.3 ft/s2 (D)182 ft/s2 (E) 18.75 ft/s2 0.5 * v22 300 ft * a 0.5 * 2352 a 92 ft / s 2 300 Ya kwanza Question 3 Road map: We obtain the velocity fastest (A)By Taking the derivative of a(t) (B)By Integrating a(t) (C)By integrating the accel as function of displacement (D)By computing the time to bottom, then computing the velocity. ME242 Tutoring • Graduate Assistant Ms. Yang Liu will be available to assist with homework preparation and answer questions. • Coordination through the Academic Success Center in TBE-A 207 Tuesday and Friday mornings. • Contact hours: MW after class ME242 Reading Assignments • Look up the next Homework assignment on Mastering • Example: your second assignment covers sections 12.5 and 12.6 • Study the text and practice the examples in the book • An I-Clicker reading test on each chapter section will be given at the start of each lecture • More time for discussion and examples Supplemental Instruction ME 242 • Questions – Yang Liu – PhD student in ME – yangliu205@gmail.com – Lab: SEB 4261 Chapter 12-5 Curvilinear Motion X-Y Coordinates v g B (d,h) 0 y A (x0,y0) x horiz. distance = d h Here is the solution in Mathcad Example: Hit target at Position (360’, -80’) Example: Hit target at Position (360, -80) Two solutions exist (Tall Trajectory and flat Trajectory). The Given - Find routine finds only one solution, depending on the guess values chosen. Therefore we must solve twice, using multiple guess values. We can also solve explicitly, by inserting one equation into the second: 92.87 50 h1( t) h2( t) 0 50 100 100 0 0 100 200 d1 ( t) d2 ( t) 300 360 NORMAL AND TANGENTIAL COMPONENTS (Section 12.7) When a particle moves along a curved path, it is sometimes convenient to describe its motion using coordinates other than Cartesian. When the path of motion is known, normal (n) and tangential (t) coordinates are often used. In the n-t coordinate system, the origin is located on the particle (the origin moves with the particle). The t-axis is tangent to the path (curve) at the instant considered, positive in the direction of the particle’s motion. The n-axis is perpendicular to the t-axis with the positive direction toward the center of curvature of the curve. NORMAL AND TANGENTIAL COMPONENTS (continued) The positive n and t directions are defined by the unit vectors un and ut, respectively. The center of curvature, O’, always lies on the concave side of the curve. The radius of curvature, r, is defined as the perpendicular distance from the curve to the center of curvature at that point. The position of the particle at any instant is defined by the distance, s, along the curve from a fixed reference point. ACCELERATION IN THE n-t COORDINATE SYSTEM Acceleration is the time rate of change of velocity: . . a = dv/dt = d(vut)/dt = vut + vut . Here v represents the change in . the magnitude of velocity and ut represents the rate of change in the direction of ut. After mathematical manipulation, the acceleration vector can be expressed as: . a = v ut + (v2/r) un = at ut + an un. ACCELERATION IN THE n-t COORDINATE SYSTEM (continued) So, there are two components to the acceleration vector: a = at ut + an un • The tangential component is tangent to the curve and in the direction of increasing or decreasing velocity. . at = v or at ds = v dv • The normal or centripetal component is always directed toward the center of curvature of the curve. an = v2/r • The magnitude of the acceleration vector is a = [(at)2 + (an)2]0.5 NORMAL AND TANGENTIAL COMPONENTS (Section 12.7) When a particle moves along a curved path, it is sometimes convenient to describe its motion using coordinates other than Cartesian. When the path of motion is known, normal (n) and tangential (t) coordinates are often used. In the n-t coordinate system, the origin is located on the particle (the origin moves with the particle). The t-axis is tangent to the path (curve) at the instant considered, positive in the direction of the particle’s motion. The n-axis is perpendicular to the t-axis with the positive direction toward the center of curvature of the curve. Normal and Tangential Coordinates Velocity Page 53 v s * ut Normal and Tangential Coordinates ‘e’ denotes unit vector (‘u’ in Hibbeler) ‘e’ denotes unit vector (‘u’ in Hibbeler) Learning Techniques •Complete Every Homework •Team with fellow students •Study the Examples •Ask: Ms. Yang, peers, me •Mathcad provides structure and numerically correct results Course Concepts •Math •Think Conceptually •Map your approach BEFORE starting work 12.8 Polar coordinates Polar coordinates ‘e’ denotes unit vector (‘u’ in Hibbeler) Polar coordinates ‘e’ denotes unit vector (‘u’ in Hibbeler) . . . . . . . . . 12.10 Relative (Constrained) Motion A J L vA = const vA is given as shown. Find vB i B Approach: Use rel. Velocity: vB = vA +vB/A (transl. + rot.) Vectors and Geometry r(t) j y (t) i x 12.10 Relative (Constrained) Motion V_truck = 60 V_car = 65 Make a sketch: A V_rel v_Truck B The rel. velocity is: V_Car/Truck = v_Car -vTruck Example Vector equation: Sailboat tacking at 50 deg. against Northern Wind (blue vector) VWind VBoat VWind/ Boat We solve Graphically (Vector Addition) Example Vector equation: Sailboat tacking at 50 deg. against Northern Wind VWind VBoat VWind/ Boat An observer on land (fixed Cartesian Reference) sees Vwind and vBoat . Land 12.10 Relative (Constrained) Motion VB VA VB / A Plane Vector Addition is two-dimensional. vA vB vB/A Example cont’d: Sailboat tacking against Northern Wind VWind VBoat VWind/ Boat 2. Vector equation (1 scalar eqn. each in i- and jdirection). Solve using the given data (Vector Lengths and orientations) and Trigonometry 500 150 i Chapter 12.10 Relative Motion Vector Addition rA rB rA / B VA VB VA / B Differentiating gives: VB VA VB / A Exam 1 • We will focus on Conceptual Solutions. Numbers are secondary. • Train the General Method • Topics: All covered sections of Chapter 12 • Practice: Train yourself to solve all Problems in Chapter 12 Exam 1 Preparation: Start now! Cramming won’t work. Questions: Discuss with your peers. Ask me. The exam will MEASURE your knowledge and give you objective feedback. Exam 1 Preparation: Practice: Step 1: Describe Problem Mathematically Step2: Calculus and Algebraic Equation Solving And here a few visual observations about contemporary forms of socializing, sent to me by a colleague at the Air Force Academy. Enjoy! Having coffee with friends. A day at the beach. Cheering on your team. Out on an intimate date. Having a conversation with your BFF A visit to the museum Enjoying the sights