4. (Inspired by recent eclipse...) If a small body were to orbit a much larger stationary body (e.g. a star), its motion would be governed by the following ODEs: x = GMs(xs-x) [(x-xs)²+(y-ys)2] 3/2 x(0) = xo x(0) = xo GMs (ys-y) ÿ = [(x-xs)²+(y-ys)2]3/2 y(0) = Yo y(0) = yo Where x(t) and y(t) give the position of the small body over time, G is the gravitational constant, Ms is the mass of the large body, and xs and y, specify its fixed position. a) Convert this problem to a system of first order ODEs. b) Assume G = = = 10, Ms 5, xsys = 0 with initial conditions xo == -1, yo = 0, xo = 5, yo = 5 and use ode45 to solve the system until t = 3. You can use the attached code and complete the missing parts. Also include the final plot of the trajectory.
4. (Inspired by recent eclipse...) If a small body were to orbit a much larger stationary body (e.g. a star), its motion would be governed by the following ODEs: x = GMs(xs-x) [(x-xs)²+(y-ys)2] 3/2 x(0) = xo x(0) = xo GMs (ys-y) ÿ = [(x-xs)²+(y-ys)2]3/2 y(0) = Yo y(0) = yo Where x(t) and y(t) give the position of the small body over time, G is the gravitational constant, Ms is the mass of the large body, and xs and y, specify its fixed position. a) Convert this problem to a system of first order ODEs. b) Assume G = = = 10, Ms 5, xsys = 0 with initial conditions xo == -1, yo = 0, xo = 5, yo = 5 and use ode45 to solve the system until t = 3. You can use the attached code and complete the missing parts. Also include the final plot of the trajectory.
Algebra & Trigonometry with Analytic Geometry
13th Edition
ISBN:9781133382119
Author:Swokowski
Publisher:Swokowski
Chapter5: Inverse, Exponential, And Logarithmic Functions
Section: Chapter Questions
Problem 18T
Question
please solve a b
![4. (Inspired by recent eclipse...) If a small body were to orbit a much larger stationary body (e.g. a star), its
motion would be governed by the following ODEs:
x =
GMs(xs-x)
[(x-xs)²+(y-ys)2] 3/2
x(0) = xo
x(0) = xo
GMs (ys-y)
ÿ
=
[(x-xs)²+(y-ys)2]3/2
y(0) = Yo
y(0) = yo
Where x(t) and y(t) give the position of the small body over time, G is the gravitational constant, Ms is the
mass of the large body, and xs and y, specify its fixed position.
a) Convert this problem to a system of first order ODEs.
b) Assume G
=
=
=
10, Ms 5, xsys = 0 with initial conditions xo
==
-1, yo = 0,
xo = 5, yo = 5 and use ode45 to solve the system until t = 3. You can use the attached code and complete
the missing parts. Also include the final plot of the trajectory.](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2F0b248bcb-d422-475d-9311-e6ae6a3d6b31%2Faf663ff8-8227-4b46-b334-5cfb61343066%2Fn6i1dt_processed.png&w=3840&q=75)
Transcribed Image Text:4. (Inspired by recent eclipse...) If a small body were to orbit a much larger stationary body (e.g. a star), its
motion would be governed by the following ODEs:
x =
GMs(xs-x)
[(x-xs)²+(y-ys)2] 3/2
x(0) = xo
x(0) = xo
GMs (ys-y)
ÿ
=
[(x-xs)²+(y-ys)2]3/2
y(0) = Yo
y(0) = yo
Where x(t) and y(t) give the position of the small body over time, G is the gravitational constant, Ms is the
mass of the large body, and xs and y, specify its fixed position.
a) Convert this problem to a system of first order ODEs.
b) Assume G
=
=
=
10, Ms 5, xsys = 0 with initial conditions xo
==
-1, yo = 0,
xo = 5, yo = 5 and use ode45 to solve the system until t = 3. You can use the attached code and complete
the missing parts. Also include the final plot of the trajectory.
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
Recommended textbooks for you
Algebra & Trigonometry with Analytic Geometry
Algebra
ISBN:
9781133382119
Author:
Swokowski
Publisher:
Cengage
Calculus For The Life Sciences
Calculus
ISBN:
9780321964038
Author:
GREENWELL, Raymond N., RITCHEY, Nathan P., Lial, Margaret L.
Publisher:
Pearson Addison Wesley,
Trigonometry (MindTap Course List)
Trigonometry
ISBN:
9781337278461
Author:
Ron Larson
Publisher:
Cengage Learning
Algebra & Trigonometry with Analytic Geometry
Algebra
ISBN:
9781133382119
Author:
Swokowski
Publisher:
Cengage
Calculus For The Life Sciences
Calculus
ISBN:
9780321964038
Author:
GREENWELL, Raymond N., RITCHEY, Nathan P., Lial, Margaret L.
Publisher:
Pearson Addison Wesley,
Trigonometry (MindTap Course List)
Trigonometry
ISBN:
9781337278461
Author:
Ron Larson
Publisher:
Cengage Learning