AMP3701
ASSIGNMENT 2 2025
UNIQUE NO.
DUE DATE: 8 AUGUST 2025
, lOMoARcPSD|18222662
APM3701/102
3.2 Assignment 02 for 2025
ASSIGNMENT 02
CHAPTER 5 – CHAPTER 7 OF STUDY GUIDE
Assignment Unique number : 700123
CLOSING DATE: 8 August 2025
TAKE NOTE OF THE FOLLOWING:
• All numbers and sections in bracket refer to the Study Guide (SG) and to the Prescribe Book
(PB), unless specified otherwise.
• Please avoid repeating proofs of formulae and theorems already done in the Study Guide
and Prescribed Book, use or apply them directly instead.
• No mark will be awarded if you copy solution from past assignments and exam solutions or
repeat proof of formulae already done in the Study Guide and Prescribed Book
QUESTION 1
Consider the heat flow in an horizontal rod of length L units and heat conductivity 1. We assume
that initially the rod was submerged in a meduim where the temperature at each point x of the rod
is described by the function f (x) . We also suppose that the left and the right ends of the rod are in
contact with media which temperatures change with time and are described by the functions g1 (t)
and g2 (t) respectively.
(a) Write down the initial-boundary problem satisfied by the temperature distribution u (x, t) in the
rod at any point x and time t (Explain all the meaning of the variables and parameters
used) . (5 Marks)
(b) Suppose that f, g 1, g2 are bounded, there exist constants m and M such that for all x in the
domain of g1 and g2, and all t ≥ 0, we have
m ≤ f (x) ≤ M; m ≤ g 1 (x) ≤ M; m ≤ g 2 (x) ≤ M;
and the temperature u (x, t) solution of the IBVP described above satisfies the inequalities
m ≤ u (x, t) ≤ M; for all x and t ≥ 0.
Show that the solution u (x, t) of the heat problem described above is unique. (Explain
clearly all the steps (10 Marks)
(c) Suppose that u1 (x, t) and u 2 (x, t) are solutions of the heat problem above (with different
initial and boundary conditions) are such that u1 (0, t) ≤ u 2 (0, t) , u1 (L, t) ≤ u 2 (L, t) , and
u1 (x, 0) ≤ u 2 (x, 0) . Show that u1 (x, t) ≤ u 2 (x, t) for all 0 ≤ x ≤ L and all t ≥ 0. (10 Marks)
[25 Marks]
7
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QUESTION 2
Find the displacement u (x, t) of a semi–infinite vibrating string, if the finite end is fixed, the initial
velocity is zero and the initial displacement is xe x at every point x of the string. (Explain all the
details) [25 Marks]
QUESTION 3
When there is heat transfer from the lateral side of an infinite cylinder of radius a into a surround-
ing medium, the temperature inside the rod depends upon the time t and the distance r from its
longitudinal axis (i.e. the axis through the centre and parallel to the lateral side).
(a) Write down the partial differential equation that models this problem. (4 Marks)
(b) Suppose that the surrounding medium is ice (at temperature zero) and the initial temperature
is constant at every point. Derive the initial and boundary conditions.
[Hint : For the boundary condition use Newton’s law of cooling.] (7 Marks)
(c) Solve the initial boundary value problem obtained in (a) and (b). (14 Marks)
[25 Marks]
QUESTION 4
Find the displacement u (r, t) of a circular membrane of radius c clamped along its circumference
if its initial displacement is zero and the circular membrane is given an constant initial velocity v in
the upward direction. [25 Marks]
TOTAL: [100 Marks]
8
,
ASSIGNMENT 2 2025
UNIQUE NO.
DUE DATE: 8 AUGUST 2025
, lOMoARcPSD|18222662
APM3701/102
3.2 Assignment 02 for 2025
ASSIGNMENT 02
CHAPTER 5 – CHAPTER 7 OF STUDY GUIDE
Assignment Unique number : 700123
CLOSING DATE: 8 August 2025
TAKE NOTE OF THE FOLLOWING:
• All numbers and sections in bracket refer to the Study Guide (SG) and to the Prescribe Book
(PB), unless specified otherwise.
• Please avoid repeating proofs of formulae and theorems already done in the Study Guide
and Prescribed Book, use or apply them directly instead.
• No mark will be awarded if you copy solution from past assignments and exam solutions or
repeat proof of formulae already done in the Study Guide and Prescribed Book
QUESTION 1
Consider the heat flow in an horizontal rod of length L units and heat conductivity 1. We assume
that initially the rod was submerged in a meduim where the temperature at each point x of the rod
is described by the function f (x) . We also suppose that the left and the right ends of the rod are in
contact with media which temperatures change with time and are described by the functions g1 (t)
and g2 (t) respectively.
(a) Write down the initial-boundary problem satisfied by the temperature distribution u (x, t) in the
rod at any point x and time t (Explain all the meaning of the variables and parameters
used) . (5 Marks)
(b) Suppose that f, g 1, g2 are bounded, there exist constants m and M such that for all x in the
domain of g1 and g2, and all t ≥ 0, we have
m ≤ f (x) ≤ M; m ≤ g 1 (x) ≤ M; m ≤ g 2 (x) ≤ M;
and the temperature u (x, t) solution of the IBVP described above satisfies the inequalities
m ≤ u (x, t) ≤ M; for all x and t ≥ 0.
Show that the solution u (x, t) of the heat problem described above is unique. (Explain
clearly all the steps (10 Marks)
(c) Suppose that u1 (x, t) and u 2 (x, t) are solutions of the heat problem above (with different
initial and boundary conditions) are such that u1 (0, t) ≤ u 2 (0, t) , u1 (L, t) ≤ u 2 (L, t) , and
u1 (x, 0) ≤ u 2 (x, 0) . Show that u1 (x, t) ≤ u 2 (x, t) for all 0 ≤ x ≤ L and all t ≥ 0. (10 Marks)
[25 Marks]
7
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QUESTION 2
Find the displacement u (x, t) of a semi–infinite vibrating string, if the finite end is fixed, the initial
velocity is zero and the initial displacement is xe x at every point x of the string. (Explain all the
details) [25 Marks]
QUESTION 3
When there is heat transfer from the lateral side of an infinite cylinder of radius a into a surround-
ing medium, the temperature inside the rod depends upon the time t and the distance r from its
longitudinal axis (i.e. the axis through the centre and parallel to the lateral side).
(a) Write down the partial differential equation that models this problem. (4 Marks)
(b) Suppose that the surrounding medium is ice (at temperature zero) and the initial temperature
is constant at every point. Derive the initial and boundary conditions.
[Hint : For the boundary condition use Newton’s law of cooling.] (7 Marks)
(c) Solve the initial boundary value problem obtained in (a) and (b). (14 Marks)
[25 Marks]
QUESTION 4
Find the displacement u (r, t) of a circular membrane of radius c clamped along its circumference
if its initial displacement is zero and the circular membrane is given an constant initial velocity v in
the upward direction. [25 Marks]
TOTAL: [100 Marks]
8
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