Skip to main content
Ch 04: Kinematics in Two Dimensions
Knight Calc - Physics for Scientists and Engineers 5th Edition
Knight Calc5th EditionPhysics for Scientists and EngineersISBN: 9780137344796Not the one you use?Change textbook
All textbooksKnight Calc 5th EditionCh 04: Kinematics in Two DimensionsProblem 48b
Chapter 4, Problem 48b

A projectile is launched from ground level at angle θ and speed v₀ into a headwind that causes a constant horizontal acceleration of magnitude a opposite the direction of motion. What is the angle for maximum range if a is 10% of g?

Verified step by step guidance
1
Step 1: Begin by understanding the problem. The projectile is launched at an angle θ with an initial speed v₀, and there is a headwind causing a constant horizontal acceleration of magnitude a opposite to the motion. We are tasked with finding the angle θ for maximum range when a is 10% of g (gravitational acceleration).
Step 2: Write the equations of motion for the projectile. The horizontal motion is affected by the headwind, so the horizontal acceleration is -a. The vertical motion is affected by gravity, so the vertical acceleration is -g. The equations of motion are: Horizontal: x = v₀ cos(θ) t - (1/2) a t² Vertical: y = v₀ sin(θ) t - (1/2) g t²
Step 3: Determine the time of flight. The projectile lands when its vertical displacement y becomes zero. Using the vertical motion equation, set y = 0 and solve for t: t = (2 v₀ sin(θ)) / g. This is the total time of flight.
Step 4: Substitute the time of flight into the horizontal motion equation to find the range R. The range is the horizontal displacement when the projectile lands: R = v₀ cos(θ) t - (1/2) a t². Substitute t = (2 v₀ sin(θ)) / g into this equation.
Step 5: Maximize the range R with respect to θ. To find the angle for maximum range, take the derivative of R with respect to θ and set it equal to zero. Solve the resulting equation for θ, keeping in mind that a = 0.1 g. This will give the angle θ for maximum range under the given conditions.

Verified video answer for a similar problem:

This video solution was recommended by our tutors as helpful for the problem above.
Video duration:
15m
Was this helpful?

Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Projectile Motion

Projectile motion refers to the motion of an object that is launched into the air and is subject to gravitational force and other forces, such as air resistance. The trajectory of a projectile is typically parabolic, and its motion can be analyzed in two dimensions: horizontal and vertical. Understanding the components of initial velocity and the effects of acceleration due to gravity is crucial for solving projectile motion problems.
Recommended video:
Guided course
04:44
Introduction to Projectile Motion

Range of a Projectile

The range of a projectile is the horizontal distance it travels before landing. It depends on the initial speed, launch angle, and the effects of any external forces, such as wind or air resistance. For maximum range in ideal conditions (without air resistance), the optimal launch angle is 45 degrees. However, when external forces like a headwind are present, this angle must be adjusted to account for the additional horizontal acceleration.
Recommended video:
Guided course
04:44
Introduction to Projectile Motion

Effect of Headwind on Projectile Motion

A headwind is a wind that blows directly opposite to the direction of motion, creating a constant horizontal acceleration that affects the projectile's range. In this scenario, the headwind reduces the effective horizontal velocity of the projectile, necessitating a recalibration of the launch angle for maximum range. When the headwind's acceleration is a fraction of gravitational acceleration (like 10% of g), it alters the optimal angle for achieving the furthest distance.
Recommended video:
Guided course
04:44
Introduction to Projectile Motion
Related Practice
Textbook Question

A projectile is launched from ground level at angle θ and speed v0 into a headwind that causes a constant horizontal acceleration of magnitude a opposite the direction of motion. Find an expression in terms of a and g for the launch angle that gives maximum range.

2230
views
Textbook Question

A ball is thrown toward a cliff of height h with a speed of 30 m/s and an angle of 60° above horizontal. It lands on the edge of the cliff 4.0 s later. What was the maximum height of the ball?

2639
views
Textbook Question

A projectile's horizontal range over level ground is v02sin2θg\(\frac{v_0^2 \sin 2\theta}{g}\). At what launch angle or angles will the projectile land at half of its maximum possible range?

2391
views
Textbook Question

A gray kangaroo can bound across level ground with each jump carrying it 10 m from the takeoff point. Typically the kangaroo leaves the ground at a 20° angle. If this is so: What is its maximum height above the ground?

451
views
Textbook Question

A spaceship maneuvering near Planet Zeta is located at r=(600i400j+200k)×103km,\(\mathbf{r}\) = (600\(\mathbf{i}\) - 400\(\mathbf{j}\) + 200\(\mathbf{k}\)) \(\times\) 10^3 \, \(\text{km}\), relative to the planet, and traveling at v=9500im/s\(\mathbf{v}\) = 9500\(\mathbf{i}\) \, \(\text{m/s}\). It turns on its thruster engine and accelerates with a=(40i20k)m/s2\(\mathbf{a}\) = (40\(\mathbf{i}\) - 20\(\mathbf{k}\)) \, \(\text{m/s}\)^2 for 35 min35\(\text{ min}\). What is the spaceship's position when the engine shuts off? Give your answer as a position vector measured in km\(\operatorname{km}\).

2136
views
Textbook Question

A ball is thrown toward a cliff of height h with a speed of 30 m/s and an angle of 60° above horizontal. It lands on the edge of the cliff 4.0 s later. What is the ball's impact speed?

2052
views