Suppose a spring with spring constant 16 N/m is horizontal and has one end attached to a wall and the other end attached to a 4 kg mass. Suppose that the friction of the mass with the floor (i.e., the damping constant) is 16 N - s/m. Set up a differential equation that describes this system. Let x to denote the displacement, in meters, of the mass from its equilibrium position, and give your answer in terms of x, x', x". Assume that positive displacement means the mass is farther from the wall than when the system is at equilibrium. help (equations) Find the general solution to your differential equation from the previous part. Use C1 and C2 to denote arbitrary constants. Use t for independent variable to represent the time elapsed in seconds. Enter C₁ as "c1" and C2 as "c2". Your answer should be an equation of the form x =?. help (equations) Is this system under damped, over damped, or critically damped? ? Enter a value for the damping constant that would make the system critically damped. N s/m help (numbers) Book: Section 2.4 of Notes on Diffy Qs
Suppose a spring with spring constant 16 N/m is horizontal and has one end attached to a wall and the other end attached to a 4 kg mass. Suppose that the friction of the mass with the floor (i.e., the damping constant) is 16 N - s/m. Set up a differential equation that describes this system. Let x to denote the displacement, in meters, of the mass from its equilibrium position, and give your answer in terms of x, x', x". Assume that positive displacement means the mass is farther from the wall than when the system is at equilibrium. help (equations) Find the general solution to your differential equation from the previous part. Use C1 and C2 to denote arbitrary constants. Use t for independent variable to represent the time elapsed in seconds. Enter C₁ as "c1" and C2 as "c2". Your answer should be an equation of the form x =?. help (equations) Is this system under damped, over damped, or critically damped? ? Enter a value for the damping constant that would make the system critically damped. N s/m help (numbers) Book: Section 2.4 of Notes on Diffy Qs
Linear Algebra: A Modern Introduction
4th Edition
ISBN:9781285463247
Author:David Poole
Publisher:David Poole
Chapter6: Vector Spaces
Section6.7: Applications
Problem 18EQ
Related questions
Question
Transcribed Image Text:Suppose a spring with spring constant 16 N/m is horizontal and has one end attached to a
wall and the other end attached to a 4 kg mass. Suppose that the friction of the mass with
the floor (i.e., the damping constant) is 16 N - s/m.
Set up a differential equation that describes this system. Let x to denote the displacement,
in meters, of the mass from its equilibrium position, and give your answer in terms of
x, x', x". Assume that positive displacement means the mass is farther from the wall than
when the system is at equilibrium.
help (equations)
Find the general solution to your differential equation from the previous part. Use C1 and C2
to denote arbitrary constants. Use t for independent variable to represent the time elapsed
in seconds. Enter C₁ as "c1" and C2 as "c2". Your answer should be an equation of the form
x =?.
help (equations)
Is this system under damped, over damped, or critically damped? ?
Enter a value for the damping constant that would make the system critically damped.
N s/m help (numbers)
Book: Section 2.4 of Notes on Diffy Qs
Expert Solution
This question has been solved!
Explore an expertly crafted, step-by-step solution for a thorough understanding of key concepts.
Step by step
Solved in 2 steps with 3 images
Recommended textbooks for you
Linear Algebra: A Modern Introduction
Algebra
ISBN:
9781285463247
Author:
David Poole
Publisher:
Cengage Learning
College Algebra (MindTap Course List)
Algebra
ISBN:
9781305652231
Author:
R. David Gustafson, Jeff Hughes
Publisher:
Cengage Learning
Linear Algebra: A Modern Introduction
Algebra
ISBN:
9781285463247
Author:
David Poole
Publisher:
Cengage Learning
College Algebra (MindTap Course List)
Algebra
ISBN:
9781305652231
Author:
R. David Gustafson, Jeff Hughes
Publisher:
Cengage Learning
Trigonometry (MindTap Course List)
Trigonometry
ISBN:
9781337278461
Author:
Ron Larson
Publisher:
Cengage Learning