CURVILINEAR MOTION: NORMAL AND TANGENTIAL COMPONENTS

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CURVILINEAR MOTION: NORMAL AND TANGENTIAL COMPONENTS Today s Objectives: Students will be able to: 1. Determine the normal and tangential components of velocity and acceleration of a particle traveling along a curved path. In-Class Activities: Check Homework Reading Quiz Applications Normal and Tangential Components of Velocity and Acceleration Special Cases of Motion Concept Quiz Group Problem Solving Attention Quiz

READING QUIZ 1. If a particle moves along a curve with a constant speed, then its tangential component of acceleration is A) positive. B) negative. C) zero. D) constant. 2. The normal component of acceleration represents A) the time rate of change in the magnitude of the velocity. B) the time rate of change in the direction of the velocity. C) magnitude of the velocity. D) direction of the total acceleration.

APPLICATIONS Cars traveling along a clover-leaf interchange experience an acceleration due to a change in speed as well as due to a change in direction of the velocity. If the car s speed is increasing at a known rate as it travels along a curve, how can we determine the magnitude and direction of its total acceleration? Why would you care about the total acceleration of the car?

APPLICATIONS (continued) A motorcycle travels up a hill for which the path can be approximated by a function y = f(x). If the motorcycle starts from rest and increases its speed at a constant rate, how can we determine its velocity and acceleration at the top of the hill? How would you analyze the motorcycle's flight at the top of the hill?

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 u n and u t, 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.

VELOCITY IN THE n-t COORDINATE SYSTEM The velocity vector is always tangent to the path of motion (t-direction). The magnitude is determined by taking the time derivative of the path function, s(t).. v = vu t where v = s = ds/dt Here v defines the magnitude of the velocity (speed) and u t defines the direction of the velocity vector.

ACCELERATION IN THE n-t COORDINATE SYSTEM Acceleration is the time rate of change. of velocity:. a = dv/dt = d(vu t )/dt = vu t + vu t. Here v represents the change in. the magnitude of velocity and u t represents the rate of change in the direction of u t. After mathematical manipulation, the acceleration vector can be expressed as:. a = vu t + (v 2 /r)u n = a t u t + a n u n.

ACCELERATION IN THE n-t COORDINATE SYSTEM (continued) There are two components to the acceleration vector: a = a t u t + a n u n The tangential component is tangent to the curve and in the direction of increasing or decreasing velocity.. a t = v or a t ds = v dv The normal or centripetal component is always directed toward the center of curvature of the curve. a n = v 2 /r The magnitude of the acceleration vector is a = [(a t ) 2 + (a n ) 2 ] 0.5

SPECIAL CASES OF MOTION There are some special cases of motion to consider. 1) The particle moves along a straight line.. r => a n = v 2 /r = 0 => a = a t = v The tangential component represents the time rate of change in the magnitude of the velocity. 2) The particle moves along a curve at constant speed.. a t = v = 0 => a = a n = v 2 /r The normal component represents the time rate of change in the direction of the velocity.

SPECIAL CASES OF MOTION (continued) 3) The tangential component of acceleration is constant, a t = (a t ) c. In this case, s = s o + v o t + (1/2)(a t ) c t 2 v = v o + (a t ) c t v 2 = (v o ) 2 + 2(a t ) c (s s o ) As before, s o and v o are the initial position and velocity of the particle at t = 0. How are these equations related to projectile motion equations? Why? 4) The particle moves along a path expressed as y = f(x). The radius of curvature, r, at any point on the path can be calculated from [ 1 + (dy/dx) 2 ] 3/2 r = d 2 y/dx 2

THREE-DIMENSIONAL MOTION If a particle moves along a space curve, the n and t axes are defined as before. At any point, the t-axis is tangent to the path and the n-axis points toward the center of curvature. The plane containing the n and t axes is called the osculating plane. A third axis can be defined, called the binomial axis, b. The binomial unit vector, u b, is directed perpendicular to the osculating plane, and its sense is defined by the cross product u b = u t x u n. There is no motion, thus no velocity or acceleration, in the binomial direction.

EXAMPLE PROBLEM Given: Starting from rest, a motorboat travels around a circular path of r = 50 m at a speed that increases with time, v = (0.2 t 2 ) m/s. Find: The magnitudes of the boat s velocity and acceleration at the instant t = 3 s. Plan: The boat starts from rest (v = 0 when t = 0). 1) Calculate the velocity at t = 3s using v(t). 2) Calculate the tangential and normal components of acceleration and then the magnitude of the acceleration vector.

Solution: EXAMPLE (continued) 1) The velocity vector is v = v u t, where the magnitude is given by v = (0.2t 2 ) m/s. At t = 3s: v = 0.2t 2 = 0.2(3) 2 = 1.8 m/s. 2) The acceleration vector is a = a t u t + a n u n = vu t + (v 2 /r)u n.. Tangential component: a t = v = d(.2t 2 )/dt = 0.4t m/s 2 At t = 3s: a t = 0.4t = 0.4(3) = 1.2 m/s 2 Normal component: a n = v 2 /r = (0.2t 2 ) 2 /(r) m/s 2 At t = 3s: a n = [(0.2)(3 2 )] 2 /(50) = 0.0648 m/s 2 The magnitude of the acceleration is a = [(a t ) 2 + (a n ) 2 ] 0.5 = [(1.2) 2 + (0.0648) 2 ] 0.5 = 1.20 m/s 2

CONCEPT QUIZ 1. A particle traveling in a circular path of radius 300 m has an instantaneous velocity of 30 m/s and its velocity is increasing at a constant rate of 4 m/s 2. What is the magnitude of its total acceleration at this instant? A) 3 m/s 2 B) 4 m/s 2 C) 5 m/s 2 D) -5 m/s 2 2. If a particle moving in a circular path of radius 5 m has a velocity function v = 4t 2 m/s, what is the magnitude of its total acceleration at t = 1 s? A) 8 m/s B) 8.6 m/s C) 3.2 m/s D) 11.2 m/s

GROUP PROBLEM SOLVING Given: A jet plane travels along a vertical parabolic path defined by the equation y = 0.4x 2. At point A, the jet has a speed of 200 m/s, which is increasing at the rate of 0.8 m/s 2. Find: The magnitude of the plane s acceleration when it is at point A. Plan: 1. The change in the speed of the plane (0.8 m/s 2) is the tangential component of the total acceleration. 2. Calculate the radius of curvature of the path at A. 3. Calculate the normal component of acceleration. 4. Determine the magnitude of the acceleration vector.

Solution: GROUP PROBLEM SOLVING (continued) 1) The tangential component of acceleration. is the rate of increase of the plane s speed, so a t = v = 0.8 m/s 2. 2) Determine the radius of curvature at point A (x = 5 km): dy/dx = d(0.4x 2 )/dx = 0.8x, d 2 y/dx 2 = d (0.8x)/dx = 0.8 At x =5 km, dy/dx = 0.8(5) = 4, d 2 y/dx 2 = 0.8 [ 1 + (dy/dx) 2 ] 3/2 => r = = [1 + (4) 2 ] 3/2 /(0.8) = 87.62 km 2 d 2 y/dx 3) The normal component of acceleration is a n = v 2 /r = (200) 2 /(87.62 x 10 3 ) = 0.457 m/s 2 4) The magnitude of the acceleration vector is a = [(a t ) 2 + (a n ) 2 ] 0.5 = [(0.8) 2 + (0.457) 2 ] 0.5 = 0.921 m/s 2

ATTENTION QUIZ 1. The magnitude of the normal acceleration is A) proportional to radius of curvature. B) inversely proportional to radius of curvature. C) sometimes negative. D) zero when velocity is constant. 2. The directions of the tangential acceleration and velocity are always A) perpendicular to each other. B) collinear. C) in the same direction. D) in opposite directions.

Summary v = vu t v = s = ds/dt a = vu t + (v 2 /r)u n = a t u t + a n u n. a t = v or a t ds = v dv ρ = 1 + dy dx 2 3 2 d 2 y dx 2 tanθ = dy dx

Summary Special Case: constant acceleration 1D s = v 0t t + 1/2a t t 2 s = ½(v 0t + v t )t v t = v 0t + a t t 2at s = (v t ) 2 (v t ) 2 x = v x0 t + 1/2a x t 2 x = ½(v x0 + v x )t v x = v x0 + a x t 2ax x = (v x ) 2 (v x0 ) 2

Summary Have y(x) ρ = 1 + dy dx 2 3 2 d 2 y dx 2 tanθ = dy u t = icosθ + jsinθ dx u n = isinθ + jcosθ s(x) = 0 x 1 + dy dx 2 dx s(t) Have v x (t) Have v t (t) dx = v x dt a x = dv x dt ds = v t dt a t = dv t dt x(t) s(t) a n = v t 2 ρ

Summary Have a t (t) dv t = a t dt v t (t) s(t) Have a t (s) a t ds = v t dv t v t (s)

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