Table of contents

0. Functions7h 55m

Introduction to Functions
18m

Piecewise Functions
10m

Properties of Functions
9m

Common Functions
1h 8m

Transformations
5m

Combining Functions
27m

Exponent rules
32m

Exponential Functions
28m

Logarithmic Functions
24m

Properties of Logarithms
36m

Exponential & Logarithmic Equations
35m

Introduction to Trigonometric Functions
38m

Graphs of Trigonometric Functions
44m

Trigonometric Identities
47m

Inverse Trigonometric Functions
48m

1. Limits and Continuity2h 2m

Introduction to Limits
41m

Finding Limits Algebraically
40m

Continuity
40m

2. Intro to Derivatives1h 33m

Tangent Lines and Derivatives
30m

Derivatives as Functions
14m

Basic Graphing of the Derivative
23m

Differentiability
26m

3. Techniques of Differentiation3h 18m

Basic Rules of Differentiation
39m

Higher Order Derivatives
12m

Product and Quotient Rules
55m

Derivatives of Trig Functions
40m

The Chain Rule
49m

4. Applications of Derivatives2h 38m

Motion Analysis
36m

Implicit Differentiation
27m

Related Rates
59m

Linearization
13m

Differentials
21m

5. Graphical Applications of Derivatives6h 2m

Intro to Extrema
23m

Finding Global Extrema
50m

The First Derivative Test
1h 5m

Concavity
1h 1m

The Second Derivative Test
31m

Curve Sketching
44m

Applied Optimization
1h 25m

6. Derivatives of Inverse, Exponential, & Logarithmic Functions2h 37m

Derivatives of Exponential & Logarithmic Functions
1h 52m

Logarithmic Differentiation
20m

Derivatives of Inverse Trigonometric Functions
24m

7. Antiderivatives & Indefinite Integrals1h 26m

Antiderivatives
17m

Indefinite Integrals
25m

Integrals of Trig Functions
15m

Initial Value Problems
27m

8. Definite Integrals4h 44m

Estimating Area with Finite Sums
42m

Riemann Sums
1h 21m

Introduction to Definite Integrals
22m

Fundamental Theorem of Calculus
37m

Average Value of a Function
21m

Substitution
1h 19m

9. Graphical Applications of Integrals2h 27m

Area Between Curves
1h 18m

Introduction to Volume & Disk Method
1h 8m

10. Physics Applications of Integrals 3h 16m

Kinematics
1h 13m

Work
2h 3m

11. Integrals of Inverse, Exponential, & Logarithmic Functions2h 31m

Integrals of Exponential Functions
40m

Integrals Involving Logarithmic Functions
58m

Integrals Involving Inverse Trigonometric Functions
52m

12. Techniques of Integration7h 41m

Integration by Parts
2h 32m

Partial Fractions
4h 29m

Improper Integrals
39m

13. Intro to Differential Equations2h 55m

Basics of Differential Equations
48m

Slope Fields
19m

Euler's Method
22m

Separable Differential Equations
1h 25m

14. Sequences & Series5h 36m

Sequences
1h 22m

Review of Factorials
11m

Series
44m

Convergence Tests
3h 17m

15. Power Series2h 19m

Introduction to Power Series
1h 9m

Taylor Series & Taylor Polynomials
1h 10m

16. Parametric Equations & Polar Coordinates7h 58m

Parametric Equations
1h 6m

Calculus with Parametric Curves
1h 13m

Polar Coordinates
2h 5m

Calculus in Polar Coordinates
55m

Conic Sections
2h 36m

0. Functions

Exponential & Logarithmic Equations

Calculus

0. Functions

Exponential & Logarithmic Equations

Previous problemNext problem

2:04 minutes

Problem 7.2.46b

Textbook Question

Overtaking City A has a current population of 500,000 people and grows at a rate of 3%/yr. City B has a current population of 300,000 and grows at a rate of 5%/yr.
b. Suppose City C has a current population of y₀ < 500,000 and a growth rate of p > 3%/yr. What is the relationship between y₀ and p such that Cities A and C have the same population in 10 years?

Verified step by step guidance

Express the population of City A after 10 years using the exponential growth formula: \(P_A(10) = 500,000 \times (1 + 0.03)^{10}\), where 0.03 represents the 3% growth rate.

Express the population of City C after 10 years similarly: \(P_C(10) = y_0 \times (1 + p)^{10}\), where \(y_0\) is the initial population of City C and \(p\) is its growth rate (expressed as a decimal).

Set the populations equal to find when City A and City C have the same population after 10 years: \(500,000 \times (1 + 0.03)^{10} = y_0 \times (1 + p)^{10}\).

Isolate \(y_0\) to express it in terms of \(p\): \(y_0 = \frac{500,000 \times (1 + 0.03)^{10}}{(1 + p)^{10}}\).

Interpret this relationship: for City C to catch up with City A in 10 years, its initial population \(y_0\) and growth rate \(p\) must satisfy the equation above, with \(y_0 < 500,000\) and \(p > 0.03\).

Verified video answer for a similar problem:

This video solution was recommended by our tutors as helpful for the problem above

Video duration:

Play a video:

0 Comments

Key Concepts

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

Exponential Growth Model

Population growth at a constant percentage rate is modeled by exponential functions, where the population at time t is given by P(t) = P₀ * (1 + r)^t. Here, P₀ is the initial population, r is the growth rate per time period, and t is the number of time periods. This model helps predict future populations based on current data.

Equating Populations to Find Conditions

To find when two populations are equal, set their exponential growth expressions equal and solve for the unknown variable. This involves forming an equation like P₀₁*(1 + r₁)^t = P₀₂*(1 + r₂)^t and manipulating it to express one variable in terms of others, which reveals the relationship between initial populations and growth rates.

Logarithmic Functions for Solving Exponential Equations

When solving equations involving variables in exponents, logarithms are used to isolate the variable. Taking the natural log or log base 10 of both sides allows the exponent to be brought down as a multiplier, enabling algebraic manipulation to find unknown growth rates or initial populations.

Watch next

Master Solving Exponential Equations Using Like Bases with a bite sized video explanation from Patrick

Related Videos

Related Practice

Textbook Question

Solving equations Solve each equation.

ln 3x + ln (x + 2) = 0

286

views

Textbook Question

The parabola y=x²+1 consists of two one-to-one functions, g₁(x) and g₂(x). Complete each exercise and confirm that your answers are consistent with the graphs displayed in the figure. <IMAGE>

Find formulas for g₁((x) and g₁⁻¹(x). State the domain and range of each function.

998

views

Textbook Question

Determine whether the following statements are true and give an explanation or counterexample.

(4x+1)^{ln x} = x^ln(4x+1)

171

views

Textbook Question

Explain why b^x = e^xlnb.

1043

views

Textbook Question

Chemotherapy In an experimental study at Dartmouth College, mice with tumors were treated with the chemotherapeutic drug Cisplatin. Before treatment, the tumors consisted entirely of clonogenic cells that divide rapidly, causing the tumors to double in size every 2.9 days. Immediately after treatment, 99% of the cells in the tumor became quiescent cells which do not divide and lose 50% of their volume every 5.7 days. For a particular mouse, assume the tumor size is 0.5 cm³ at the time of treatment.

a. Find an exponential decay function V₁(t) that equals the total volume of the quiescent cells in the tumor t days after treatment.

views

Textbook Question

Compounded inflation The U.S. government reports the rate of inflation (as measured by the consumer index) both monthly and annually. Suppose for a particular month, the monthly rate of inflation is reported as 0.8%. Assuming this rate remains constant, what is the corresponding annual rate of inflation? Is the annual rate 12 times the monthly rate? Explain.

views

Textbook Question

d. Plot a graph of V(t) for 0 ≤ t ≤ 15. What happens to the size of the tumor, assuming there are no follow-up treatments with Cisplatin?

views

Textbook Question

Rule of 70 Bankers use the Rule of 70, which says that if an account increases at a fixed rate of p%/yr, its doubling time is approximately 70/p. Use linear approximation to explain why and when this is true.

views

Show more practices

Download the Mobile app

Accessibility

Privacy

Do not sell my personal information