(7%) Problem 4: You stand at the top of a deep well. To determine the depth, D, of the well youdrop a rock from the top of the well and listen for the splash as the rock hits the water's surface. Thesound of the splash arrives t = 4.3 s after you drop the rock. The speed of sound in the well is vs =337 m/s.Joseph, Daniel - daniel.joseph@doane.edu@theexpertta.com - tracking id: 9N69-67-2C-41-BA81-36806. In accordance with Expert TA's Terms of Service.copying this information to any solutions sharing website is strictly forbidden. Doing so may result in termination ofyour Expert TA Account.E 50% Part (a) Enter the quadratic equation for the distance, D, in terms of the time, the acceleration due to gravity, and the speed of sound. Arrange theexpression so that the coefficient of the D2 term is 1.0 =D²-2 t D vs + (vst)²-2D vs2/g ✔ Correct!DA 50% Part (b) Solve the quadratic equation for the depth of the well, D, and calculate it's value, in meters.D=1sin()cotan()atan()cosh()cos()asin()acotan()tanh()tan()acos()sinh()cotanh()JT85E2()1+LPP7410D9 HOME63ENDOtheexpertta.comGrade SummaryDeductionsPotential0%100%SubmissionsAttempts remaining: 1(83% per attempt)detailed view

Name: (7%) Problem 4: You stand at the top of a deep well. To determine the
Uploaded: 2024-03-05T11:56:34.000Z
Channel: Bartleby
Description: (7%) Problem 4: You stand at the top of a deep well. To determine the depth, D, of the well youdrop a rock from the top of the well and listen for the splash as the rock hits the water's surface. Thesound of the splash arrives t = 4.3 s after you dr

Given that Speed of sound in well is vs=337m/s The sound of splash arrives at a time (t) =4.3s…

Science

Physics

(7%) Problem 4: You stand at the top of a deep well. To determine the depth, D, of the well you drop a rock from the top of the well and listen for the splash as the rock hits the water's surface. The sound of the splash arrives t = 4.3 s after you drop the rock. The speed of sound in the well is vs = 337 m/s. Joseph, Daniel - daniel joseph@doane.edu @theexpertta.com - tracking id: 9N69-67-2C-41-BA81-36806. In accordance with Expert TA's Terms of Service. copying this information to any solutions sharing website is strictly forbidden. Doing so may result in termination of your Expert TA Account. 50% Part (a) Enter the quadratic equation for the distance, D, in terms of the time, the acceleration due to gravity, and the speed of sound. Arrange the expression so that the coefficient of the D² term is 1. 0=D²-21D vs +(vst)²-2D v2g ✔ Correct! 50% Part (b) Solve the quadratic equation for the depth of the well, D, and calculate it's value, in meters. D= cos() asin() sin() cotan() atan() acotan() cosh() tanh() tan() acos() sinh() cotanh() Л ( ) E AL 71 + lo 7 8 9 4 5 6 2 3 - D 0 HOME END Ⓒtheexpertta.com Grade Summary Deductions Potential 0% 100% Submissions Attempts remaining: 1 (83% per attempt) detailed view

(7%) Problem 4: You stand at the top of a deep well. To determine the depth, D, of the well you drop a rock from the top of the well and listen for the splash as the rock hits the water's surface. The sound of the splash arrives t = 4.3 s after you drop the rock. The speed of sound in the well is vs = 337 m/s. Joseph, Daniel - daniel joseph@doane.edu @theexpertta.com - tracking id: 9N69-67-2C-41-BA81-36806. In accordance with Expert TA's Terms of Service. copying this information to any solutions sharing website is strictly forbidden. Doing so may result in termination of your Expert TA Account. 50% Part (a) Enter the quadratic equation for the distance, D, in terms of the time, the acceleration due to gravity, and the speed of sound. Arrange the expression so that the coefficient of the D² term is 1. 0=D²-21D vs +(vst)²-2D v2g ✔ Correct! 50% Part (b) Solve the quadratic equation for the depth of the well, D, and calculate it's value, in meters. D= cos() asin() sin() cotan() atan() acotan() cosh() tanh() tan() acos() sinh() cotanh() Л ( ) E AL 71 + lo 7 8 9 4 5 6 2 3 - D 0 HOME END Ⓒtheexpertta.com Grade Summary Deductions Potential 0% 100% Submissions Attempts remaining: 1 (83% per attempt) detailed view

Physics for Scientists and Engineers with Modern Physics

10th Edition

ISBN:9781337553292

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter4: Motion In Two Dimensions

Section: Chapter Questions

Problem 44AP: A projectile is launched from the point (x = 0, y = 0), with velocity (12.0i19.0j)m/s2, at t = 0....

See similar textbooks

Similar questions

A ball is thrown straight up. It passes a 2.00-m-high window 7.50 m off the ground on its path up and takes 0.312 s to go past the window. What was the ball's initial velocity? Hint: First consider only the distance along the window, and solve for the ball's velocity at the bottom of the window. Next, consider only the distance from the ground to the bottom of the window, and solve for the initial velocity using the velocity at the bottom of the window as the final velocity.
A student writes, "A bird that is diving for prey has a speed of -10 m / s." What is wrong with the student's statement? What has the student actually described? Explain.
PROBLEM 2 A soccer player kicks a rock horizontally off a 40.0-m-high cliff into a pool of water. If the player hears the sound of the splash 3.00 s later, what was the initial speed given to the rock? Assume the speed of sound in air is 343 m/s.
ANSWER 3- (ii) Find the smallest non-zero time when (a) the velocity is zero (b) the object is at theorigin.
3.) A PARTICLE IS MOVING ALONG A HORIZONTAL LINE ACCORDING TO THE GIVEN EQUATION WHEREAT (t) SECONDS, (s )METERS IS THE DIRECTED DISTANCE OF THE PARTICLE FROM THE ORIGIN, (v) meters per second IS THE INSTANTANEOUS ACCELERATION OF THE PARTICLE, FIND (v) AND (a) IN TERMS OF (t).2 MAKE A TABLE THAT GIVES A Description THE POSITION AND MOTION OF THE PARTICLE, INCLUDE IN THE TABLE THE INTERVALS OF TIME WHEN THE PARTICLE IS MOVING TO THE LEFT, WHEN IT IS MOVING TO THE RIGHT, WHEN THE VELOCITY IS INCREASING, WHEN THE VELOCITY IS DECREASING, WHEN THE SPEED IS INCREASING, WHEN THE SPEED IS DECREASING, AND THE POSITION OF THE PARTICLE WITH RESPECT TO THE ORIGIN DURING THESE INTERVALS OF TIME. SHOW THE BEHAVIOR OF THE MOTION. The Equation is S = t^3 - 9t^2 + 15t ; t>=0.
The British Queen Elizabeth-class battleship HMS Warspite achieved the longest naval gunnery hit from a moving ship to a moving target in history, hitting the Italian battleship Guilio Cesare in the Battle of Taranto. According to known data, the range was 24000 meters, and that the British 15-inch Mk I naval gun has a maximum muzzle velocity of 800 meters per second. Due to movement, a headwind was against the British battleship, forcing its shells to decelerate by approximately 0.5 meters per second squared. Find the firing angle of the Warspite upon hitting Guilio Cesare. Find the impact velocity of the 15-inch naval cannon's shell.
You are talking with a cell phone while trailing a police car by 20m; both ypur car andthe police car traveling at 100km/h. Your conversation diverts your attention fromthe police car for 2,0 s. At the beginning g of that 2,0s the police officer beginsbraking suddenly at 6m/s2. A- What is the separation between the two cars whenyour attention finally returns? Suppose that you take another 0,3 s to realize yourdanger and begin braking. B- If you too brake at 6m/s2, what is your speed when youhit the police car.
1. The position of the particle is given by s = (9t^3 – 6t^2 – 32t + 16) meters, where t is inseconds. Determine: a. Plot the graph of the particle equation (e.g. plot t = 0, 1, 2, … , 5)and connect the dots) b. The starting position of the particle (include the sign) c. The time when the velocity of the particle is zero
To solve for velocity and acceleration of B. Please use only the Dependent Motion Analysis (DMA). To compute for the velocity of ? with respect to ?, and the acceleration of ? with respect to ?, use only the Relative Motion Analysis (RMA).
A student stands at the edge of a cliff and throws a stone horizontally over the edge with the speed of vo =18.5 m/s. the cliff is h=49.0 m above a flat, horizontal beach. this is a subpart solution. (c) write the equation for x- and y- components of the velocity of the stone with time. vx= and vy= (d) write the equation for the position with the time, using the coodinates.
I am having trouble with a 3d motion problem. The problem is as follosw, "At t = 0, a particle moving in the xy plane with constant acceleration has a velocity of i = (3.00 i - 2.00 j) m/s and is at the origin. At t = 2.00 s, the particle's velocity is = (7.00 i + 8.20 j) m/s. (Use the following as necessary: t. Round your coefficients to two decimal places.)" The problem asks me to find acceleration of the particle at any time t and to find its coordinates at any time t. Thanks for the help
An inquisitive physics student and mountain climber climbs a 51.0-m-high cliff that overhangs a calm pool of water. He throws two stones vertically downward, 1.00 s apart, and observes that they cause a single splash. The first stone has an initial speed of 2.06 m/s. (a) How long after release of the first stone do the two stones hit the water?