PHYSICS 221 Spring 2004 EXAM 1: Feb 12 2004 8:00pm—9:30pm Name (printed): ____________________________________________ ID Number: ______________________________________________ Section Number: __________________________________________ INSTRUCTIONS: Each question is of equal weight, answer all questions. All questions are multiple choice. Before turning over this page, put away all materials except for pens, pencils, erasers, rulers, your calculator and “aid sheet”. An “aid sheet” is one two sided 8½×11 page of notes prepared by the student. "In general, any calculator, including calculators that perform graphing numerical analysis functions, is permitted. Electronic devices that can store large amounts of text, data or equations are NOT permitted." If you are unsure whether or not your calculator is allowed for the exam ask your TA. Examples of allowed calculators: Texas Instruments TI-30XII/83/83+/89, 92+ Casio FX115/250HCS/260/7400G/FX7400GPlus/FX9750 Sharp EL9900C. Examples of electronic devices that are not permitted: Any laptop, palmtop, pocket computer, PDA or e-book reader. In marking the multiple choice bubble sheet use a number 2 pencil. Do NOT use ink. If you did not bring a pencil, ask for one. Fill in your last name, middle initial, and first name. Your ID is the middle 9 digits on your ISU card. Special codes K to L are your recitation section , for the Honors section please encode your section number as follows: H1⇒02; H2⇒13 and H3⇒31. If you need to change any entry, you must completely erase your previous entry. Also, circle your answers on this exam. Before handing in your exam, be sure that your answers on your bubble sheet are what you intend them to be. It is strongly suggested that you circle your choices on the question sheet. You may also copy down your answers on the record sheet (page 12) and take this page with you for comparison with the answer key to be posted later. When you are finished with the exam, place all exam materials, including the bubble sheet, and the exam itself, in your folder and return the folder to your recitation instructor. No cell phone calls allowed. Either turn off your cell phone or leave it at home. Anyone answering a cell phone must hand in their work; their exam is over. Total number of questions is 26. Best of luck, David Atwood and Anatoli Frishman Physics 221 2004 S Exam 1 Page 1 of 14 G G [1] The components of vector A and B are given as follows: Ax = +3.1 B x = −5.6 Ay = −7.0 B y = −3.1 G G The magnitude of the vector difference B − A , is closest to: (A) 1.3 (B) 9.5 (C) 4.6 (D) 91.0 (E) 100.0 G G [2] Consider the vectors A and B shown in the diagram below lie in the xy plane. Both G G vectors have the same magnitude A=B=3. The vector product A ⋅ B is: y 3 G A x 30º 30º (A) 7.8 (B) 4.5 (C) 3.0 (D) 9.0 (E) 15.6 3 G B G G [3] Consider the vector C = 2.00iˆ − 5.00 ˆj − 1.00kˆ , the unit vector in the direction of C is: (A) 0.54iˆ − 0.80 ˆj − 0.27kˆ (B) 0.37iˆ − 0.91 ˆj − 0.18kˆ (C) 0.50iˆ − 1.30 ˆj − 0.25kˆ (D) 0.43iˆ − 1.10 ˆj − 0.21kˆ (E) 0.21iˆ − 0.97 ˆj − 0.11kˆ Physics 221 2004 S Exam 1 Page 2 of 14 G G G G G G [4] If the vectors P , Q and R satisfy the relations P + Q = R and P 2 + Q 2 = R 2 , what G G is the angle between P and Q ? (A) 0º (B) 15º (C) 30º (D) 90º (E) 120º [5] A child stand on a bridge throws a rock straight down with a downwards velocity of 5m/s. The rock leaves the child’s hand at t=0. In a coordinate system where up is positive which of the graphs shown here best represents the velocity of the stone as a function of time? (B) (A) (D) (C) (E) [6] John runs 1 km north at 6 m/s and then runs an additional 1 km in the same direction at 4 m/s. What is the magnitude of John’s average velocity for his 2km run? (A) 3.0 m/s (B) 4.0 m/s (C) 4.8 m/s (D) 5.0 m/s (E) 5.4 m/s Physics 221 2004 S Exam 1 Page 3 of 14 [7] The position of a particle along the x-axis as a function of time is given by the expression: x(t)=at3+bt+c where a=4m/s3, b=2m/s and c=5m. What is the acceleration of the particle at the time t = 4 s ? (A) 0 m/s2 (B) 24 m/s2 (C) 48 m/s2 (D) 96 m/s2 (E) 192 m/s2 [8] In the graph of position versus time, at which points is the acceleration is zero: (A) P, Q, R and S (B) P, Q, S (C) R only (D) P and S (E) Q only [9] Ball #1 is thrown vertically upwards with a speed of v0 from the top of a building and hits the ground with speed v1. Ball #2 is thrown vertically downwards from the same place with the same speed v0 and hits the ground with speed v2. Which one of the following three statements is true. Neglect the effects of air friction. (A) v1>v2 (B) v1=v2 (C) v1<v2 (D) Depends on which ball is more massive (E) None of the above Physics 221 2004 S Exam 1 Page 4 of 14 [10] A person kicks a soccer ball off level ground at an angle of 45° above the horizontal. In order that the ball reaches a maximum height of 30m above the ground during its flight, what is the initial speed of the soccer ball? (A) 25 m/s (B) 29 m/s (C) 34 m/s (D) 37 m/s (E) 41 m/s [11] A straight 100m wide river flows at a speed of 2.0m/s with respect to the bank. A canoe is paddled at a speed of 4.0m/s with respect to the water. The trajectory of the canoe is directly across the river, perpendicular to the flow of water, as viewed from the bank. How long does it take for the canoe to cross the river? (A) 22 s (B) 25 s (C) 29 s (D) 32 s (E) 50 s [12] A cannon ball is fired at an angle of 30º to the horizontal on level ground with an initial velocity of 490m/s. Assuming air resistance is negligible, how long will the cannon ball remain aloft? (A) 25s (B) 50s (C) 100s (D) 200s (E) The answer depends on the mass of the cannon ball [13] A box that weighs 500N sits on the floor of an elevator. The elevator is moving upwards at a constant velocity of 5m/s. What is the magnitude of the net force acting on the box? (A) 1000 N (B) 750 N (C) 500 N (D) 250 N (E) 0 N Physics 221 2004 S Exam 1 Page 5 of 14 [14] A cannon ball is fired at a speed of 80.0m/s straight up from a cannon located at the base of a cliff that is 100m high. It proceeds upwards above the cliff and eventually falls back down. When it passes the edge of the cliff in the downward direction, what is the speed of the cannon ball? Neglect air resistance. v=? v=80.0m/s 100m Cannon (A) 44.4 m/s (B) 50.0 m/s (C) 66.6 m/s (D) 73.6 m/s (E) Cannot be determined with the given information. [15] An elevator with a mass of 2000kg is given an upwards acceleration of 0.98m/s² by a cable. What is the tension in the cable? (A) 10 kN (B) 12 kN (C) 16 kN (D) 18 kN (E) 22 kN [16] A block of mass m slides down a frictionless ramp that is at an angle θ with respect to the horizontal, where θ is between 10° and 80°. The magnitude of the acceleration of the block is . (A) 2g cosθ (B) 2g sinθ (C) g (D) g cos θ (E) g sin θ Physics 221 2004 S Exam 1 Page 6 of 14 [17] When Bill drives from home to work he drives through a circular curve in the road at 60km/hr during which a net force of magnitude F is acting on him. On the trip back from work to home he rounds the same curve at twice the speed. What is the magnitude of the net force acting on Bill while rounding the curve on his return trip. (A) 0 (B) F (C) 2F (D) 4F (E) 8F [18] A 130kg block rests on a horizontal frictionless ice surface. Jane pulls the block north with a force of 120N while Sue pulls the block east with a force of 50N. What is the magnitude of the acceleration of the block? (A) 0.00 m/s² (B) 0.385 m/s² (C) 0.923 m/s² (D) 1.00 m/s² (E) 1.31 m/s² [19] At time t=0s a 1kg block is at point P on a frictionless ramp inclined at 30º to the horizontal. At this time the block is sliding up the ramp with a velocity of 4.9m/s. The block subsequently slides further up the ramp but due to the action of gravity it eventually reverses its course and slides back down to point P. At what point in time does this return of the block to point P take place? (A) t=0.5 s (B) t=1.0 s (C) t=2.0 s (D) t=4.0 s (E) t=5.0 s Physics 221 2004 S Exam 1 P 30º Page 7 of 14 [20] Four blocks of mass m1=1kg, m2=2kg, m3=3kg, m4=4kg are on a frictionless horizontal surface as shown on the figure below. The blocks are connected by ideal massless strings. A force FL=30N is applied to the left block and is directed to the left. Another force FR=50N is applied to the right block, and is directed to the right. What is the magnitude of the tension T in the string between m2 and m3. T=? FL=30N m1=1kg m2=2kg m3=3kg m4=4kg FR=50N (A) T=6N (B) T=20N (C) T=30N (D) T=36N (E) T=50N [21] A 1.00kg wooden block is initially held at rest on a horizontal surface where the coefficient of static friction with the block is µs=0.46 and the coefficient of kinetic friction is 0.35. The block is connected to an ideal string that runs over an ideal pulley and then is connected to a hanging 0.50kg mass, as shown in the figure below. After the 1.00kg block is released, the magnitude of the acceleration of the block is: 1.00kg 0.50kg (A) 0.0 m/s² (B) 1.0 m/s² (C) 3.3 m/s² (D) 5.6 m/s² (E) 9.8 m/s² Physics 221 2004 S Exam 1 Page 8 of 14 [22] Two boxes of mass m and 4m are pushed together along a frictionless surface by a constant force of magnitude N as shown in the figure below. Let FL be the magnitude of the net force on the large box and FS the magnitude of the net force on the small box. Which of the following relations between these magnitudes is true? FL 4m FS N m (A) FL<N, (B) FL>N, (C) FL>N, (D) FL=N, (E) FL=N, FS<N FS<N FS=N FS<N FS=N [23] A person drives a car over the top of a hill, the cross section of which can be approximated by a circle of radius 256m, as shown below. What is the greatest speed at which he can drive without the car leaving the road at the top of the hill? 256 m (A) 10 m/s (B) 20 m/s (C) 25 m/s (D) 50 m/s (E) 75 m/s Physics 221 2004 S Exam 1 Page 9 of 14 [24] A particle moves at a constant speed along the trajectory shown below. Compare the magnitude of the acceleration of the particle at points A and B, aA and aB respectively. (A) aA>aB ≠0 (B) aA>aB =0 (C) aA<aB (D) aA=aB =0 (E) aA=aB ≠0 [25] The figure shows the overhead view of two stones that travel in circles over a frictionless horizontal surface both with a period of 1s. Each stone is tied to a cord whose opposite end is anchored at the center of the circle. Which of the following statements concerning the tension in the two cords is true? (A) The tension in the long cord is greater than the tension in the short cord. (B) The tension in the long cord is less than the tension in the short cord. (C) The tension in the long cord is equal to the tension in the short cord. (D) The relation between the two tensions cannot be determined from the information given. [26] A year (y) is equal to 3.16×107s. A light-year (ly) is a unit of distance used in astronomy which is equal to 9.47×1015m. What is the correct conversion of the acceleration of gravity near the earth’s surface (g=9.8 m/s²) into units of (ly)/y²: (A) g= 3.27×10-8 (ly)/y² (B) g= 3.10 ×10+8 (ly)/y² (C) g= 1.03×10-15 (ly)/y² (D) g= 9.79×10+15 (ly)/y² (E) g= 1.03 (ly)/y² Physics 221 2004 S Exam 1 Page 10 of 14 Formula Sheet 1. Physical Constants (numerical value used to derive answers in exam): 1.1) Acceleration of gravity on Earth’s Surface: g=9.8m/s² 1.2) Radius of Earth: Rearth=6.38×106m 1.3) Mass of Proton: mp=1.67×10-27kg 3. Vectors G G G G 3.1) Dot Product: A ⋅ B = Ax B x + Ay B y + Az B z =| A || B | cosθ G G where θ is the angle between A and B . G 3.2) Components: A = Ax iˆ + Ay ˆj + Az kˆ G G G 3.3) Magnitude: | V |= V = V x2 + V y2 + V z2 = V ⋅ V 5. One Dimensional Motion 5.1) Average Velocity: v = ∆x / ∆t 5.2) Instantaneous Velocity: v = dx / dt 2. Calculus 2.1) d dx x n = nx n −1 d dx sin x = cos x x n +1 n +1 d dx cos x = − sin x n ∫ x dx = 4. Algebra 4.1) The solutions to ax 2 + bx + c = 0 are x = 1 2a (− b ± b 2 − 4ac ) 6. Forces G G 6.1) Newton’s Second: F = ma G G 6.2) Newton’s Third: FAB = − FBA 6.2) Kinetic Friction: f k = µ k N 6.4) Static Friction: f s ≤ µ s N 6.5) Centripetal Force: F = v x = v0 x + a x t mv 2 R x = x0 + v0 x t + 12 a x t 2 5.3) For Constant Acceleration only: v 2 − v 2 = 2a ( x − x ) 0x 0 x x x − x0 1 = 2 (v x + v 0 x ) t 7. Three Dimensional Motion G 7.1) Position Vector: r = xiˆ + yˆj + zkˆ G G G G 2 G 7.2) Velocity and Acceleration: v = dtd r a = dtd v = dtd 2 r G G G v = v0 + at G G G G r = r0 + v 0 t + 12 at 2 7.3) Constant Acceleration only: v 2 − v 2 = 2aG ⋅ (rG − rG ) 0 G G0 r − r0 1 G G = 2 (v + v 0 ) t ω = 2πf v = Rω 7.4) Circular Motion: f = 1 / T 7.4a) Angular Velocity: ω = dθ / dt 7.5) Centripetal Acceleration: a rad = Rω 2 = v 2 / R = ( 4π 2 R ) / T 2 G G G 7.6) Changing Reference Frames: v PA = v PB + v BA Physics 221 2004 S Exam 1 Page 11 of 14 Record Sheet You may fill in this sheet with your choices, detach it and take it with you after the exam for comparison with the posted answers 1 11 21 2 12 22 3 13 23 4 14 24 5 15 25 6 16 26 7 17 27 8 18 28 9 19 29 10 20 30 Physics 221 2004 S Exam 1 Page 12 of 14 Scratch Paper (intentionally left blank) Physics 221 2004 S Exam 1 Page 13 of 14 Scratch Paper (intentionally left blank) Physics 221 2004 S Exam 1 Page 14 of 14