the equations for the motion of the particle are written as

Similar documents
Dynamics 4600:203 Homework 03 Due: February 08, 2008 Name:

(a) 1m s -2 (b) 2 m s -2 (c) zero (d) -1 m s -2

XI PHYSICS M. AFFAN KHAN LECTURER PHYSICS, AKHSS, K.

Ground Rules. PC1221 Fundamentals of Physics I. Position and Displacement. Average Velocity. Lectures 7 and 8 Motion in Two Dimensions

REVIEW: Going from ONE to TWO Dimensions with Kinematics. Review of one dimension, constant acceleration kinematics. v x (t) = v x0 + a x t

Do not turn over until you are told to do so by the Invigilator.

KINEMATICS PREVIOUS EAMCET BITS ENGINEERING PAPER

Problem Set 2 Solutions

v( t) g 2 v 0 sin θ ( ) ( ) g t ( ) = 0

Prince Sultan University Physics Department First Semester 2012 /2013. PHY 105 First Major Exam Allowed Time: 60 min

Dynamics 4600:203 Homework 09 Due: April 04, 2008 Name:

2.2 Differentiation and Integration of Vector-Valued Functions

Homework # 2. SOLUTION - We start writing Newton s second law for x and y components: F x = 0, (1) F y = mg (2) x (t) = 0 v x (t) = v 0x (3)

UNIVERSITY OF SASKATCHEWAN Department of Physics and Engineering Physics

jfpr% ekuo /kez iz.ksrk ln~xq# Jh j.knksm+nklth egkjkt

Physics 11 Fall 2012 Practice Problems 2 - Solutions

7.2 Maximization of the Range of a Rocket

Get Solution of These Packages & Learn by Video Tutorials on PROJECTILE MOTION

(C) 7 s. (C) 13 s. (C) 10 m

Physics 18 Spring 2011 Homework 2 - Solutions Wednesday January 26, 2011

Components of a Vector

Energizing Math with Engineering Applications

AAPT UNITED STATES PHYSICS TEAM AIP 2009

Problem Set: Fall #1 - Solutions

1 CHAPTER 7 PROJECTILES. 7.1 No Air Resistance

UNIVERSITY OF SASKATCHEWAN Department of Physics and Engineering Physics

PSI AP Physics 1 Kinematics. Free Response Problems

Motion in Two Dimensions Sections Covered in the Text: Chapters 6 & 7, except 7.5 & 7.6

Unit 1 Test Review Physics Basics, Movement, and Vectors Chapters 2-3

Physics 111. Lecture 7 (Walker: 4.2-5) 2D Motion Examples Projectile Motion

Firing an Ideal Projectile

Vector Valued Functions

PSI AP Physics C Kinematics 2D. Multiple Choice Questions

OSCILLATIONS

Parameterization and Vector Fields

Linear Motion. Miroslav Mihaylov. February 13, 2014

University of Alabama Department of Physics and Astronomy. PH 125 / LeClair Fall Exam III Solution

Ground Rules. PC1221 Fundamentals of Physics I. Position and Displacement. Average Velocity. Lectures 7 and 8 Motion in Two Dimensions

Cunningham, Drew Homework 32 Due: Apr , 4:00 am Inst: Florin 1

Phys101 First Major-111 Zero Version Monday, October 17, 2011 Page: 1

Exam 2A Solution. 1. A baseball is thrown vertically upward and feels no air resistance. As it is rising

Projectile Motion. Equipment: Ballistic Gun Apparatus Projectiles Table Clamps 2-meter Stick Carbon Paper, Scratch Paper, Masking Tape Plumb Bob

James T. Shipman Jerry D. Wilson Charles A. Higgins, Jr. Omar Torres. Chapter 2 Motion Cengage Learning

MOTION OF A PROJECTILE

INTRODUCTION & RECTILINEAR KINEMATICS: CONTINUOUS MOTION

MOTION IN A STRAIGHT LINE. time interval t and as t approaches zero, the ratio. has a finite limiting value.(where x is the distance

Parametric Equations

Assignment 6. Name MULTIPLE CHOICE. Choose the one alternative that best completes the statement or answers the question.

Motion in Two or Three Dimensions

Physics 20 Homework 1 SIMS 2016

MASSACHUSETTS INSTITUTE OF TECHNOLOGY Department of Physics. Physics 8.01 Fall Problem Set 2: Applications of Newton s Second Law Solutions

Normal Force. W = mg cos(θ) Normal force F N = mg cos(θ) F N

Mechanics Cycle 3 Chapter 12++ Chapter 12++ Revisit Circular Motion

Chapter 3. Kinematics in Two Dimensions

MOTION IN TWO OR THREE DIMENSIONS

2.5 Velocity and Acceleration

Do not fill out the information below until instructed to do so! Name: Signature: Student ID: Section Number:

As observed from the frame of reference of the sidewalk:

Chapter K. Oscillatory Motion. Blinn College - Physics Terry Honan. Interactive Figure

Problem: Projectile (CM-1998) Justify your answer: Problem: Projectile (CM-1998) 5 10 m/s 3. Show your work: 3 m/s 2

Projectile Motion. Chin- Sung Lin STEM GARAGE SCIENCE PHYSICS

Physics 218 Exam I. Fall 2017 (all sections) September 27 th, 2017

PH Fall - Section 05 - Version C DRAFT

Kinematics Multiple- Choice Questions (answers on page 16)

PROJECTILE MOTION. ( ) g y 0. Equations ( ) General time of flight (TOF) General range. Angle for maximum range ("optimum angle")

Physics 0174(CHS) Exam #1 Academic Year NAME

ONLINE: MATHEMATICS EXTENSION 2 Topic 6 MECHANICS 6.3 HARMONIC MOTION

Name: Total Points: Physics 201. Midterm 1

ANALYZE In all three cases (a) (c), the reading on the scale is. w = mg = (11.0 kg) (9.8 m/s 2 ) = 108 N.

Random sample problems

Phys207: Lecture 04. Today s Agenda 3-D Kinematics Independence of x and y components Baseball projectile Shoot the monkey Uniform circular motion

Chapter 4 - Motion in 2D and 3D

Experiment 1: Simple Pendulum

ISSUED BY K V - DOWNLOADED FROM KINEMATICS

APPLICATIONS OF DERIVATIVES UNIT PROBLEM SETS

PH Fall - Section 04 - Version A DRAFT

PHYSICS I. Lecture 1. Charudatt Kadolkar. Jul-Nov IIT Guwahati

Physics 2514 Lecture 22

Planar Motion with Constant Acceleration

Motion in Two Dimensions. 1.The Position, Velocity, and Acceleration Vectors 2.Two-Dimensional Motion with Constant Acceleration 3.

Engineering Mechanics Prof. U. S. Dixit Department of Mechanical Engineering Indian Institute of Technology, Guwahati Kinematics

Multiple-Choice Questions

PHYSICS 221, FALL 2009 EXAM #1 SOLUTIONS WEDNESDAY, SEPTEMBER 30, 2009

Dot Product August 2013

Chapter 3 Acceleration

Physics 231. Topic 3: Vectors and two dimensional motion. Alex Brown September MSU Physics 231 Fall

Physics 1A. Lecture 3B. "More than anything else... any guy here would love to have a monkey. A pet monkey." -- Dane Cook

Formative Assessment: Uniform Acceleration

g L Simple Pendulum, cont Simple Pendulum Period of Simple Pendulum Equations of Motion for SHM: 4/8/16 k m

Mathematics Extension 1 Time allowed: 2 hours (plus 5 minutes reading time)

Newton's laws of motion

Dynamics - Midterm Exam Type 1

Ballistics Car P3-3527

Physics 1: Mechanics

11 Free vibrations: one degree of freedom

KINEMATICS OF A PARTICLE. Prepared by Engr. John Paul Timola

Q3.1. A. 100 m B. 200 m C. 600 m D m E. zero. 500 m. 400 m. 300 m Pearson Education, Inc.

Chapter 3 Kinematics in Two Dimensions; Vectors

Experiment 3 The Simple Pendulum

When we throw a ball :

Transcription:

Dynamics 4600:203 Homework 02 Due: ebruary 01, 2008 Name: Please denote your answers clearly, ie, box in, star, etc, and write neatly There are no points for small, messy, unreadable work please use lots of paper Problem 1: Hibbeler, 12 49 The v t raph for the motion of a car as it moves alon a straiht road is shown Draw the a t raph and determine the maximum acceleration durin the 30s time interval The car starts from rest at x = 0 v ft/s 40 v = t + 30 v = 04 t 2 10 30 t s The acceleration is the derivative of velocity, so that a = v Therefore the acceleration takes two forms, the first durin the interval 0 t 10s, for which 8 a ft/s 2 ẍt = vt = 08ft/s 3 t Durin the second interval the acceleration reduces to ẍt = vt = 100ft/s 2 The a t raph is shown to the riht inally, the maximum acceleration occurs at t = 10 s, for which ẍt = 800ft/s 2 10 30 t s Problem 2: Hibbeler, 12 81 Show that if a projectile is fired at an anle from the horizontal with an initial velocity v 0, the maximum rane the projectile can travel is iven by R max = v 2 0/, where is the acceleration of ravity What is the anle for this condition? The position of the ball is described by r P O = xt î+yt ĵ When subject to ravity, and initial velocity, v 0 xt, yt v P = ẋ0î + ẏ0ĵ = v 0 cos î + sin ĵ, the equations for the motion of the particle are written as 1

xt = v 0 cos t, yt = t2 2 + v 0 sin t Therefore, when y is written as a function of x, this reduces to yx = 2v0 2 cos2 x2 + sin cos x = v 2 0 x 1 + cos2 x v2 0 sin2 The rane occurs when y = 0, or solvin for x R = v2 0 sin2 The maximum rane thus occurs for 2 = 90, or = 45, R max = v2 0 Problem 3: Hibbeler, 12 90 The fireman standin on the ladder directs the flow of water from his hose to the fire at B Determine the velocity of the water at A if it observed that the hose is held at = 20 A v 0 30 ft 60 ft B help!! The vertical displacement of the water y as a function of the horizontal displacement x is iven as yx = 2v0 2 cos2 x2 + sin cos x The initial anle is iven as = 20, while the final displacement is x f,y f = 60ft, 30ft Therefore, solvin for v 0 yields v 0 = 2 cos sin x f cos y f x f With the iven values, this reduces to v 0 = 8968ft/s 2

Problem 4: Hibbeler, 12 94 The stones are thrown off the conveyor with a horizontal velocity of 10ft/s as shown Determine the speed at which the stones hit the round at B see textbook for fiure The position of a stone can be described with the vector r P0 = xî + y ĵ, so that usin xt = v 0 cos t, y can be written as a function of x as yx = 2v0 2 cos2 x2 + sin cos x or this system v 0 = 10ft/s, and = 0, which reduces the above to yx = 2v0 2 x 2 The round at the bottom of the conveyor can be described with the equation y r = 100ft x r 10 Therefore, the stones hit the round when their trajectory intersects the equation for the surface That is 2v0 2 x 2 f = y f = 100ft x f 10, 0161ft 1 x 2 f 010x f 100ft = 0 This equation is quadratic in x f, and may be solved to yield x f = 2523ft To find the speed at which the stones hit the round, we return to the equations for the velocity, which can be written as ẋt = v 0, ẏt = t = v 0 x inally, the speed of the stones at impact can be written as v P = 2 ẋ 2 + ẏ 2 = v0 2 + xf v 0 Usin the above value x f = 2523ft, we find that the stones hit the round with speed v P = 8187ft/s Problem 5: Hibbeler, 12 145 A truck is travelin alon the horizontal circular curve of radius r = 60m with a speed of 20m/s which is increasin at 3m/s 2 Determine the truck s radial and transverse components of acceleration see textbook for fiure 3

Given the path of the truck, it is natural to describe its position in terms of polar coordinates, so that r P O = r, v P = ṙ + r ê, a P = r r 2 + r + 2ṙ ê ê P ĵ î With constant radius of the curve, ṙ = 0 and r = 0, so that the kinematics reduce to r P O r P O = r, v P = r ê, a P = r 2 + r ê O The speed of the truck, 20m/s, is iven in terms of the coordinates as v P = r = 20m/s, while its rate of chane is d v P = r dt = 3m/s 2 Notice that the rate of chane of the speed is different from the manitude of the acceleration rom these, we can determine and as = 1 3 rad/s, = 1 20 rad/s2 inally, with these values the acceleration of the truck can be written as a P = r 2 + r ê = 20 3 m/s2 + 3m/s 2 ê 4

Problem 6: Hibbeler, 12 152 At the instant shown, the water sprinkler is rotatin with an anular speed = 2rad/s and an anular acceleration = 3rad/s 2 If the nozzle lies in the vertical plane and water is flowin throuh it at a constant rate of 3m/s see textbook for fiure a determine the manitudes of the velocity and acceleration of a water particle as it exits the open end, r = 02m; b this part is not in the textbook but builds upon this problem once it exits the nozzle, find how far this water particle travels before hittin the round Assume that the nozzle is at round level a The kinematics of a particle of water P can be described in terms of polar coordinates as r P O = r, v P = ṙ + r ê, a P = r r 2 + r + 2ṙ ê ê ĵ î rom the problem statement, the coordinates and their derivatives of P at the nozzle exit are iven as r = 02m, ṙ = 3m/s, r = 0, = 2rad/s, = 3rad/s 2 Notice that the coordinate is not iven, and does not influence the kinematics when written in terms of the radial and tanential directions certainly does affect the orientation of and ê relative to the round The velocity and acceleration can be written as v P = 3m/s + 04m/s ê, a P = 08m/s 2 + 126m/s 2 ê inally, the manitudes of these quantities are v P = 303m/s, a P = 126m/s 2 Notice that the velocity of the water is not simply in the direction Instead, the water velocity is directed at an anle of 759 off the direction ê v P 5

b The rane of the water can be determined from the equation R = v2 0 sin2ψ, where the water has an exit speed of v 0 and a velocity direction of ψ Usin the above values, we find that v 0 = 303m/s and ψ = + 013rad, so that R = 093m sin 2 + 013rad In contrast, if the nozzle is held stationary at an anle, the rane of the sprinkler is R = 092m sin2 Problem 7: Hibbeler, 12 154 A cameraman standin at A is followin the movement of a race car, B, which is travelin alon a straiht track at a constant speed of 80ft/s Determine the anular rate at which he must turn in order to keep the camera directed on the car at the instant = 60 see textbook for fiure With the perpendicular distance between the track and O iven as d, the distance r between O and C is r CO = r = d sin Here the velocity of the car is naturally written in terms of Cartesian coordinates However, the response of the cameraman is determined in terms of polar coordinates In terms of the former, the velocity of the care is written as v 0 î C v C = v 0 î, while in terms of the polar coordinates r and with v C = ṙ + r ê, O r CO ê ĵ î = cos î + sin ĵ î = cos sin ê, ê = sin î + cos ĵ ĵ = sin + cos ê, Settin these two descriptions of v C equal to one another, we find that v 0 î = ṙ + r ê This vector equation has two unknowns, ṙ and We could write the directions and ê in terms on î and ĵ, which would lead to two scalar equations, coupled in the two 6

unknowns However, instead we write î in terms of and ê Doin so yields v 0 cos sin ê = ṙ + r ê Thus, solvin the equation in the ê for provides = v 0 sin r = v 0 sin 2 d Therefore, at = 60, we find that = 06rad/s 7

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback