Filters
Question type
Study Flashcards

Use Euler's method with h = 0.1 to approximate y(1.0) and y(2.0) for the differential equation Use Euler's method with h = 0.1 to approximate y(1.0) and y(2.0) for the differential equation , . A) 1.4996, 0.5508 B) 2.7573, 3.0562 C) 2.7364, 3.0928 D) 2.8488, 3.1430 , Use Euler's method with h = 0.1 to approximate y(1.0) and y(2.0) for the differential equation , . A) 1.4996, 0.5508 B) 2.7573, 3.0562 C) 2.7364, 3.0928 D) 2.8488, 3.1430 .


A) 1.4996, 0.5508
B) 2.7573, 3.0562
C) 2.7364, 3.0928
D) 2.8488, 3.1430

Correct Answer

verifed

verified

An object's cooling constant, k, is often taken to be proportional to the its surface area. An iron ball cools from 350oC to 100oC in 30 seconds in a fast flowing stream of 30oC water. Use Newton's Law of Cooling to estimate how cool a similar volume of hot iron would become in 30 seconds if it were in the shape of a rod with surface area 3 times larger than the ball's.


A) 30.7oC
B) 75.9oC
C) 30.0oC
D) 33.3oC

Correct Answer

verifed

verified

Find and interpret all equilibrium points for the competing species model. Find and interpret all equilibrium points for the competing species model.

Correct Answer

verifed

verified

(0, 0): none of either species...

View Answer

Use the direction field below to sketch a solution curve and estimate the initial value y(0) for the differential equation Use the direction field below to sketch a solution curve and estimate the initial value y(0) for the differential equation , such that the solution curve passes through the point (2, 2). , such that the solution curve passes through the point (2, 2). Use the direction field below to sketch a solution curve and estimate the initial value y(0) for the differential equation , such that the solution curve passes through the point (2, 2).

Correct Answer

verifed

verified

Is the following differential equation separable or not? Is the following differential equation separable or not? A) separable B) not separable


A) separable
B) not separable

Correct Answer

verifed

verified

In 1995 an investor put $2500 in an account which paid 8%. In 2005 she withdrew $1500 from the account. What will the account be worth in 2020 ?


A) $16,972.64
B) $13,492.46
C) $7389.06
D) $4063.85

Correct Answer

verifed

verified

Construct a direction field for the differential equation. Construct a direction field for the differential equation.

Correct Answer

verifed

verified

Find the solution to the following separable differential equation. Find the solution to the following separable differential equation. A) B) C) D)


A) Find the solution to the following separable differential equation. A) B) C) D)
B) Find the solution to the following separable differential equation. A) B) C) D)
C) Find the solution to the following separable differential equation. A) B) C) D)
D) Find the solution to the following separable differential equation. A) B) C) D)

Correct Answer

verifed

verified

Solve the following initial value problem explicitly. Solve the following initial value problem explicitly. A) B) C) D)


A) Solve the following initial value problem explicitly. A) B) C) D)
B) Solve the following initial value problem explicitly. A) B) C) D)
C) Solve the following initial value problem explicitly. A) B) C) D)
D) Solve the following initial value problem explicitly. A) B) C) D)

Correct Answer

verifed

verified

Find all equilibrium points for the following coupled predator-prey-model equations. Find all equilibrium points for the following coupled predator-prey-model equations. A) (0, 0) , (1.500, 0) , (0.500, 0.500) B) (0, 0) , (0.500, 0) , (1.500, 0.500) C) (0, 0) , (0.500, 1.500) , (0, 0.500) D) (0, 0) , (1.500, 0) , (0.500, 0.250) Find all equilibrium points for the following coupled predator-prey-model equations. A) (0, 0) , (1.500, 0) , (0.500, 0.500) B) (0, 0) , (0.500, 0) , (1.500, 0.500) C) (0, 0) , (0.500, 1.500) , (0, 0.500) D) (0, 0) , (1.500, 0) , (0.500, 0.250)


A) (0, 0) , (1.500, 0) , (0.500, 0.500)
B) (0, 0) , (0.500, 0) , (1.500, 0.500)
C) (0, 0) , (0.500, 1.500) , (0, 0.500)
D) (0, 0) , (1.500, 0) , (0.500, 0.250)

Correct Answer

verifed

verified

The Polymerase Chain Reaction (PCR) is used to replicate segments of DNA. It is used to make DNA samples big enough for testing, starting from very small samples collected, for instance, from a crime scene. PCR can double the number of a particular DNA segment every two minutes. Write an equation for the number of segments as a function of the number of minutes, t, if there is initially just one segment.


A) The Polymerase Chain Reaction (PCR) is used to replicate segments of DNA. It is used to make DNA samples big enough for testing, starting from very small samples collected, for instance, from a crime scene. PCR can double the number of a particular DNA segment every two minutes. Write an equation for the number of segments as a function of the number of minutes, t, if there is initially just one segment. A) B) C) D)
B) The Polymerase Chain Reaction (PCR) is used to replicate segments of DNA. It is used to make DNA samples big enough for testing, starting from very small samples collected, for instance, from a crime scene. PCR can double the number of a particular DNA segment every two minutes. Write an equation for the number of segments as a function of the number of minutes, t, if there is initially just one segment. A) B) C) D)
C) The Polymerase Chain Reaction (PCR) is used to replicate segments of DNA. It is used to make DNA samples big enough for testing, starting from very small samples collected, for instance, from a crime scene. PCR can double the number of a particular DNA segment every two minutes. Write an equation for the number of segments as a function of the number of minutes, t, if there is initially just one segment. A) B) C) D)
D) The Polymerase Chain Reaction (PCR) is used to replicate segments of DNA. It is used to make DNA samples big enough for testing, starting from very small samples collected, for instance, from a crime scene. PCR can double the number of a particular DNA segment every two minutes. Write an equation for the number of segments as a function of the number of minutes, t, if there is initially just one segment. A) B) C) D)

Correct Answer

verifed

verified

Solve the following initial value problem explicitly. Solve the following initial value problem explicitly. A) B) C) D)


A) Solve the following initial value problem explicitly. A) B) C) D)
B) Solve the following initial value problem explicitly. A) B) C) D)
C) Solve the following initial value problem explicitly. A) B) C) D)
D) Solve the following initial value problem explicitly. A) B) C) D)

Correct Answer

verifed

verified

Solve the following initial value problem explicitly. Solve the following initial value problem explicitly. y(1) = -5 A) B) C) D) y(1) = -5


A) Solve the following initial value problem explicitly. y(1) = -5 A) B) C) D)
B) Solve the following initial value problem explicitly. y(1) = -5 A) B) C) D)
C) Solve the following initial value problem explicitly. y(1) = -5 A) B) C) D)
D) Solve the following initial value problem explicitly. y(1) = -5 A) B) C) D)

Correct Answer

verifed

verified

An object falling freely through the atmosphere will accelerate due to the force of gravity at 9.86 m/s2 [Acceleration is the derivative of velocity with respect to time.] The atmosphere, however, will commonly exert a retarding force proportional to the object's velocity squared. The proportionality constant will depend largely on the object's shape. Write and solve the differential equation, then identify a free-falling object's terminal velocity (the limiting velocity) in terms of its drag proportionality constant, k. [To solve explicitly, you may use the initial condition v(0) = 0.]

Correct Answer

verifed

verified

blured image blured image Taking the limit a...

View Answer

Consider a chemical system containing species A, B, and C; and that A and B can react to make C in a bimolecular reaction with rate constant of k1, and C can decompose to make A and B in a first order reaction with rate constant of k-1. If the instantaneous amounts of A, B, and C are represented as a, b, and c, and the initial amounts are given as A0, B0, and C0, the change in C can be represented with the differential equation Consider a chemical system containing species A, B, and C; and that A and B can react to make C in a bimolecular reaction with rate constant of k<sub>1</sub>, and C can decompose to make A and B in a first order reaction with rate constant of k<sub>-1</sub>. If the instantaneous amounts of A, B, and C are represented as a, b, and c, and the initial amounts are given as A<sub>0</sub>, B<sub>0</sub>, and C<sub>0</sub>, the change in C can be represented with the differential equation . If A<sub>0</sub> = 2 , B<sub>0</sub> = 2, C<sub>0</sub> = 0, k<sub>1</sub> = 0.04, and k<sub>-1</sub> = 0.04, solve the differential equation for c and graph the solution. [Note: c can never be larger than C<sub>0</sub> plus the smaller of A<sub>0</sub> or B<sub>0</sub>. Nor can it be smaller than 0.] . If A0 = 2 , B0 = 2, C0 = 0, k1 = 0.04, and k-1 = 0.04, solve the differential equation for c and graph the solution. [Note: c can never be larger than C0 plus the smaller of A0 or B0. Nor can it be smaller than 0.]

Correct Answer

verifed

verified

blured image blured image When Ao=1.5, Bo=1.5,...

View Answer

Find the solution to the following separable differential equation. Find the solution to the following separable differential equation. A) B) C) D)


A) Find the solution to the following separable differential equation. A) B) C) D)
B) Find the solution to the following separable differential equation. A) B) C) D)
C) Find the solution to the following separable differential equation. A) B) C) D)
D) Find the solution to the following separable differential equation. A) B) C) D)

Correct Answer

verifed

verified

Use your calculator to construct the direction field for the following differential equation. [Use the standard zoom window.] Use your calculator to construct the direction field for the following differential equation. [Use the standard zoom window.]

Correct Answer

verifed

verified

Construct a direction field for the differential equation. Construct a direction field for the differential equation.

Correct Answer

verifed

verified

Find all equilibrium points for the following system of equations. Find all equilibrium points for the following system of equations. A) B) C) D)


A) Find all equilibrium points for the following system of equations. A) B) C) D)
B) Find all equilibrium points for the following system of equations. A) B) C) D)
C) Find all equilibrium points for the following system of equations. A) B) C) D)
D) Find all equilibrium points for the following system of equations. A) B) C) D)

Correct Answer

verifed

verified

In 1965, Fairchild Semiconductor's R&D Director, Gordon Moore, noted that the maximum number of transistors that could be included cost effectively in one integrated circuit had been doubling yearly since 1959. While growth has not increased quite as quickly since 1965, it has still been exponential, and the continued exponential growth has become known as "Moore's Law". Considering that Intel's 4004 processor, introduced in 1971, had 2250 transistors, and their Pentium III processor, introduced in 1999, had 24,000,000 transistors, on average how long has it taken for processors to double the number of transistors they use.


A) 2.1 years
B) 0.6 years
C) 13.7 years
D) 0.3 years

Correct Answer

verifed

verified

Showing 21 - 40 of 72

Related Exams

Exam 1

Preliminaries

101 Questions

Exam 2

Limits and Continuity

105 Questions

Exam 3

Differentiation

116 Questions

Exam 4

Applications of the Derivative

118 Questions

Exam 5

Integration

129 Questions

Exam 6

Applications of the Definite Integral

85 Questions

Exam 7

Exponentials, Logarithms and Other Transcendental Functions

66 Questions

Exam 8

Integration Techniques

123 Questions

Exam 10

Infinite Series

111 Questions

Exam 11

Parametric Equations and Polar Coordinates

129 Questions

Exam 12

Vectors and the Geometry of Space

107 Questions

Exam 13

Vector-Valued Functions

103 Questions

Exam 14

Functions of Several Variables and Partial Differentiation

112 Questions

Exam 15

Multiple Integrals

92 Questions

Exam 16

Vector Calculus

67 Questions

Exam 17

Second Order Differential Equations

38 Questions

Show Answer