4.2 Acceleration vector  (Page 3/4)

If the position function of a particle is a linear function of time, what can be said about its acceleration?

If an object has a constant x -component of the velocity and suddenly experiences an acceleration in the y direction, does the x- component of its velocity change?

If an object has a constant x- component of velocity and suddenly experiences an acceleration at an angle of $70\text{°}$ in the x direction, does the x- component of velocity change?

The position of a particle is $\overrightarrow{r}(t)=(3.0t^2\widehat{i}+5.0\widehat{j}-6.0t\widehat{k})\text{m}.$ (a) Determine its velocity and acceleration as functions of time. (b) What are its velocity and acceleration at time t = 0?

A particle’s acceleration is $(4.0\widehat{i}+3.0\widehat{j})\text{m/}{\text{s}}^2.$ At t = 0, its position and velocity are zero. (a) What are the particle’s position and velocity as functions of time? (b) Find the equation of the path of the particle. Draw the x- and y- axes and sketch the trajectory of the particle.

A boat leaves the dock at t = 0 and heads out into a lake with an acceleration of $2.0\text{m/}{\text{s}}^2\widehat{i}.$ A strong wind is pushing the boat, giving it an additional velocity of $2.0\text{m/s}\widehat{i}+1.0\text{m/s}\widehat{j}.$ (a) What is the velocity of the boat at t = 10 s? (b) What is the position of the boat at t = 10s? Draw a sketch of the boat’s trajectory and position at t = 10 s, showing the x- and y -axes.

The position of a particle for t >0 is given by $\overrightarrow{r}(t)=(3.0t^2\widehat{i}-7.0t^3\widehat{j}-5.0t^{\mathrm{-2}}\widehat{k})\text{m}.$ (a) What is the velocity as a function of time? (b) What is the acceleration as a function of time? (c) What is the particle’s velocity at t = 2.0 s? (d) What is its speed at t = 1.0 s and t = 3.0 s? (e) What is the average velocity between t = 1.0 s and t = 2.0 s?

The acceleration of a particle is a constant. At t = 0 the velocity of the particle is $(10\widehat{i}+20\widehat{j})\text{m/s}.$ At t = 4 s the velocity is $10\widehat{j}\text{m/s}.$ (a) What is the particle’s acceleration? (b) How do the position and velocity vary with time? Assume the particle is initially at the origin.

A particle has a position function $\overrightarrow{r}(t)=\text{cos}(1.0t)\widehat{i}+\text{sin}(1.0t)\widehat{j}+t\widehat{k},$ where the arguments of the cosine and sine functions are in radians. (a) What is the velocity vector? (b) What is the acceleration vector?

A Lockheed Martin F-35 II Lighting jet takes off from an aircraft carrier with a runway length of 90 m and a takeoff speed 70 m/s at the end of the runway. Jets are catapulted into airspace from the deck of an aircraft carrier with two sources of propulsion: the jet propulsion and the catapult. At the point of leaving the deck of the aircraft carrier, the F-35’s acceleration decreases to a constant acceleration of $5.0\text{m/}{\text{s}}^2$ at $30\text{°}$ with respect to the horizontal. (a) What is the initial acceleration of the F-35 on the deck of the aircraft carrier to make it airborne? (b) Write the position and velocity of the F-35 in unit vector notation from the point it leaves the deck of the aircraft carrier. (c) At what altitude is the fighter 5.0 s after it leaves the deck of the aircraft carrier? (d) What is its velocity and speed at this time? (e) How far has it traveled horizontally?