Textbook Question
Growth rate functions
a. Show that the logistic growth rate function f(P)=rP(1−P/K) has a maximum value of rK/4 at the point P=K/2.
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Ch. 9 - Differential Equations
Briggs3rd EditionCalculus: Early TranscendentalsISBN: 9780136847243
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Table of contents
- Ch. 1 - Functions210
- Ch. 2 - Limits371
- Ch. 3 - Derivatives633
- Ch. 4 - Applications of the Derivative412
- Ch. 5 - Integration328
- Ch. 6 - Applications of Integration331
- Ch. 7 - Logarithmic, Exponential Functions, and Hyperbolic Functions177
- Ch. 8 - Integration Techniques394
- Ch. 9 - Differential Equations179
- Ch. 10 - Sequences and Infinite Series339
- Ch. 11 - Power Series218
- Ch.12 - Parametric and Polar Curves215
Briggs3rd EditionCalculus: Early TranscendentalsISBN: 9780136847243Not the one you use?Change textbook
Chapter 9, Problem 9.1.44a
43–44. Motion in a gravitational field: An object is fired vertically upward with initial velocity v(0)=v₀ from initial position s(0)=s₀.
a. For the following values of v₀ and s₀, find the position and velocity functions for all times at which the object is above the ground (s = 0).
v₀ = 49 m/s, s₀ = 60 m
Verified step by step guidance1
Identify the physical model: The motion of the object under gravity can be described by the second-order differential equation for position \(s(t)\(: \[\frac{d^2 s}{dt^2} = -g,\] where \)g = 9.8 \ \text{m/s}^2\) is the acceleration due to gravity acting downward.
Integrate the acceleration to find the velocity function \(v(t)\): Since \(v(t) = \frac{ds}{dt}\), integrate the acceleration once to get \[v(t) = -g t + C_1,\] where \(C_1\) is a constant determined by the initial velocity condition.
Apply the initial velocity condition \(v(0) = v_0 = 49 \ \text{m/s}\) to find \(C_1\): Substitute \(t=0\) into the velocity function to get \[v(0) = C_1 = 49,\] so \[v(t) = -9.8 t + 49.\]
Integrate the velocity function to find the position function \(s(t)\(: \[s(t) = \int v(t) dt = \int (-9.8 t + 49) dt = -4.9 t^2 + 49 t + C_2,\] where \)C_2\) is a constant determined by the initial position.
Apply the initial position condition \(s(0) = s_0 = 60 \ \text{m}\) to find \(C_2\): Substitute \(t=0\( into the position function to get \[s(0) = C_2 = 60,\] so \[s(t) = -4.9 t^2 + 49 t + 60.\] The object is above the ground for all \)t\) such that \(s(t) > 0\).
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Kinematic Equations for Motion Under Constant Acceleration
These equations describe the position and velocity of an object moving with constant acceleration, such as gravity. Position is given by s(t) = s₀ + v₀t + (1/2)at², and velocity by v(t) = v₀ + at, where a is acceleration due to gravity (usually -9.8 m/s²). They allow calculation of motion parameters at any time t.
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Initial Conditions in Differential Equations
Initial conditions specify the starting position and velocity of the object, here s(0) = s₀ and v(0) = v₀. These values are essential to uniquely determine the position and velocity functions over time when solving the motion equations.
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Determining the Time Interval When the Object is Above Ground
To find when the object is above ground, solve s(t) > 0 using the position function. This involves finding the roots of the quadratic equation s(t) = 0, which mark the times the object is at ground level. The object is above ground between these roots.
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Related Practice
Textbook Question
{Use of Tech} Torricelli’s law An open cylindrical tank initially filled with water drains through a hole in the bottom of the tank according to Torricelli’s law (see figure). If h(t) is the depth of water in the tank for t≥0 s, then Torricelli’s law implies h′(t)=−k√h, where k is a constant that includes g=9.8m/s², the radius of the tank, and the radius of the drain. Assume the initial depth of the water is h(0)=Hm.
a. Find the solution of the initial value problem.
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Textbook Question
17–20. Increasing and decreasing solutions Consider the following differential equations. A detailed direction field is not needed.
a. Find the solutions that are constant, for all t ≥ 0 (the equilibrium solutions).
y'(t) = (y−2)(y+1)
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Textbook Question
29–32. {Use of Tech} Errors in Euler’s method Consider the following initial value problems.
a. Find the approximations to y(0.2) and y(0.4) using Euler’s method with time steps of Δt = 0.2, 0.1, 0.05, and 0.025.
y′(t) = y/2, y(0) = 2; y(t) = 2eᵗᐟ²
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Textbook Question
42–43. Implicit solutions for separable equations For the following separable equations, carry out the indicated analysis.
a. Find the general solution of the equation.
e⁻ʸᐟ²y'(x) = 4x sin x² − x; y(0) = 0, y(0) = ln(1/4), y(√(π/2)) = 0
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Textbook Question
33–36. {Use of Tech} Computing Euler approximations Use a calculator or computer program to carry out the following steps.
a. Approximate the value of y(T) using Euler’s method with the given time step on the interval [0,T].
y′(t) = -2y, y(0) = 1; Δt = 0.2, T = 2; y(t) = e⁻²ᵗ
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