08:39Intro to vectors & scalars | One-dimensional motion | Physics | Khan AcademyKhan Academy1064views1rank
05:32Distance and displacement in one dimension | One-dimensional motion | AP Physics 1 | Khan AcademyKhan Academy638views
04:14Distance and displacement introduction | One-dimensional motion | AP Physics 1 | Khan AcademyKhan Academy617views
Multiple ChoiceStarting from a pillar, you run a distance 140m east (the + x-direction), then turn around. (a) How far west would you have to walk so that your total distance traveled is 300m?(b) What is the magnitude and direction of your total displacement?2338views84rank6comments
Multiple ChoiceSeen from above, Linda runs 5.0m/s 30° north of east. What is the x component of her velocity?412views
Textbook QuestionDraw a pictorial representation for the following problem. Do not solve the problem. What acceleration does a rocket need to reach a speed of 200 m/s at a height of 1.0 km?435views
Textbook QuestionProblems 49, 50, 51, and 52 show a partial motion diagram. For each: c. Draw a pictorial representation for your problem.323views
Textbook QuestionProblems 44, 45, 46, 47, and 48 show a motion diagram. For each of these problems, write a one or two sentence 'story' about a real object that has this motion diagram. Your stories should talk about people or objects by name and say what they are doing. 424views
Textbook QuestionFor Problems 34, 35, 36, 37, 38, 39, 40, 41, 42, and 43, draw a complete pictorial representation. Do not solve these problems or do any mathematics. A car starts from rest at a stop sign. It accelerates at 4.0 m/s² for 6.0 s, coasts for 2.0 s, and then slows at a rate of 2.5 m/s² for the next stop sign. How far apart are the stop signs?411views
Textbook QuestionYour roommate drops a tennis ball from a third-story balcony. It hits the sidewalk and bounces as high as the second story. Draw a complete motion diagram of the tennis ball from the time it is released until it reaches the maximum height on its bounce. Be sure to determine and show the acceleration at the lowest point.398views
Textbook QuestionA bowling ball rolls up an incline and then onto a smooth, level surface. Draw a complete motion diagram of the bowling ball. Don't try to find the acceleration vector at the point where the motion changes direction; that's an issue for Chapter 4.406views
Textbook QuestionA speed skater accelerates from rest and then keeps skating at a constant speed. Draw a complete motion diagram of the skater.449views
Textbook QuestionYou drop a soccer ball from your third-story balcony. Use the particle model to draw a motion diagram showing the ball's position and average velocity vectors from the time you release the ball until the instant it touches the ground.657views
Textbook QuestionA jet plane lands on the deck of an aircraft carrier and quickly comes to a halt. Draw a basic motion diagram, using the s from the video, from the time the jet touches down until it stops.462views
Textbook QuestionYou are watching a jet ski race. A racer speeds up from rest to 70 mph in 10 s, then continues at a constant speed. Draw a basic motion diagram of the jet ski, using s from the video, from its start until 10 s after reaching top speed.388views
Textbook QuestionFor Problems 34, 35, 36, 37, 38, 39, 40, 41, 42, and 43, draw a complete pictorial representation. Do not solve these problems or do any mathematics. A jet plane is cruising at 300 m/s when suddenly the pilot turns the engines up to full throttle. After traveling 4.0 km, the jet is moving with a speed of 400 m/s. What is the jet's acceleration as it speeds up?359views
Textbook QuestionFIGURE EX1.10 shows two dots of a motion diagram and vector . Copy this figure, then add dot 4 and the next velocity vector if the acceleration vector at dot 3 (b) points left. 476views
Textbook QuestionFIGURE EX1.9 shows five points of a motion diagram. Use Tactics Box 1.2 to find the average acceleration vectors at points 1, 2, and 3. Draw the completed motion diagram showing velocity vectors and acceleration vectors.938views
Textbook QuestionFIGURE EX1.8 shows the first three points of a motion diagram. Is the object's average speed between points 1 and 2 greater than, less than, or equal to its average speed between points 0 and 1? Explain how you can tell. 342views
Textbook QuestionFor Problems 34, 35, 36, 37, 38, 39, 40, 41, 42, and 43, draw a complete pictorial representation. Do not solve these problems or do any mathematics. A car traveling at 30 m/s runs out of gas while traveling up a 10° slope. How far up the hill will the car coast before starting to roll back down?213views
Textbook QuestionFor Problems 34, 35, 36, 37, 38, 39, 40, 41, 42, and 43, draw a complete pictorial representation. Do not solve these problems or do any mathematics. David is driving a steady 30 m/s when he passes Tina, who is sitting in her car at rest. Tina begins to accelerate at a steady 2.0 m/s² at the instant when David passes. How far does Tina drive before passing David?247views
Textbook QuestionProblems 49, 50, 51, and 52 show a partial motion diagram. For each: a. Complete the motion diagram by adding acceleration vectors.264views
Textbook QuestionProblems 49, 50, 51, and 52 show a partial motion diagram. For each: a. Complete the motion diagram by adding acceleration vectors.271views
Textbook QuestionProblems 49, 50, 51, and 52 show a partial motion diagram. For each: c. Draw a pictorial representation for your problem.274views
Textbook QuestionA steel ball rolls across a 30-cm-wide felt pad, starting from one edge. The ball's speed has dropped to half after traveling 20 cm. Will the ball stop on the felt pad or roll off?656views
Textbook QuestionThe vertical position of a particle is given by the function y = (t^2 - 4t + 2) m, where t is in s. (b) What is the particle's position at that time?527views
Textbook QuestionA good model for the acceleration of a car trying to reach top speed in the least amount of time is a𝓍 = a₀ ─ kv𝓍, where a₀ is the initial acceleration and k is a constant. a. Find an expression for k in terms of a₀ and the car's top speed vₘₐₓ.416views
Textbook QuestionA particle moving along the x-axis has its position described by the function x = (2t^3 + 2t + 1) m, where t is in s. At t = 2s what are the particle's (a) position510views
Textbook QuestionA particle's velocity is described by the function vₓ =kt² m/s, where k is a constant and t is in s. The particle's position at t₀ = 0 s is x₀ = ─9.0 m. At t₁ = 3.0 s, the particle is at x₁ = 9.0 m. Determine the value of the constant k. Be sure to include the proper units.880views
Textbook QuestionThe position of a particle is given by the function x = (2t^3 = 6t^2 + 12) m, where t is in s. (a) At what time does the particle reach its minimum velocity? What is (vx)min?532views1rank
Textbook QuestionA particle's velocity is given by the function 𝓋ₓ = (2.0 m/s) sin (πt), where t is in s. a. What is the first time after t = 0 s when the particle reaches a turning point?435views
Textbook QuestionA particle moving along the x-axis has its veocity described by the function vx = 2t^2 m/s, where t is in s. itsinitial position is x0 = 1 m at t0 = 0 s. At t = 1 s what are the particle's (a) position407views
Textbook QuestionThe position of a particle is given by the function x = (2t^3 = 6t^2 + 12) m, where t is in s. (b) At what time is the acceleration zero?402views
Textbook QuestionWhen a 1984 Alfa Romeo Spider sports car accelerates at the maximum possible rate, its motion during the first 20 s is extremely well modeled by the simple equation where P = 3.6 ✕ 10⁴ watts is the car's power output, m = 1200 kg is its mass, and v𝓍 is in m/s. That is, the square of the car's velocity increases linearly with time. a. Find an algebraic expression in terms of P, m, and t for the car's acceleration at time t.464views
Textbook QuestionCALC. A car's velocity as a function of time is given by v_x(t) = α + βt^2, where α = 3.00 m/s and β = 0.100 m/s^3. (c) Draw v_x-t and a_x-t graphs for the car's motion between t = 0 and t = 5.00 s.465views
Textbook QuestionA turtle crawls along a straight line, which we will call the x-axis with the positive direction to the right. The equation for the turtle's position as a function of time is x(t) = 50.0 cm + (2.00 cm/s)t − (0.0625 cm/s2)t2. (e) Sketch graphs of x versus t, υx versus t, and ax versus t, for the time interval t = 0 to t = 40 s.442views
Textbook QuestionA rubber ball bounces. We'd like to understand how the ball bounces. a. A rubber ball has been dropped and is bouncing off the floor. Draw a motion diagram of the ball during the brief time interval that it is in contact with the floor. Show 4 or 5 frames as the ball compresses, then another 4 or 5 frames as it expands. What is the direction of a during each of these parts of the motion?472views