There was a question in the 2003 HSC on this, ad it spun me out a bit.
(b) A particle of mass m is thrown from the top, O, of a very tall building with an
initial velocity u at an angle α to the horizontal. The particle experiences the
effect of gravity, and a resistance proportional to its velocity in both the
horizontal and vertical directions. The equations of motion in the horizontal and
vertical directions are given respectively by
x: = −kx. and y: = −ky. − g x. is x dot and x: is x double dot
where k is a constant and the acceleration due to gravity is g. (You are NOT
required to show these.)
(i) Derive the result
x. = ue^(-kt)cosα
from the relevant equation of motion.
(ii) Verify that
y. = (1/k)[(kusinα + g)e^-kt - g]
satisfies the appropriate equation
of motion and initial condition.
(iii) Find the value of t when the particle reaches its maximum height.
(iv) What is the limiting value of the horizontal displacement of the particle?
Are we expected to be able to integrate these sorts of equations? I ask because I remember seeing in a thread a while ago that they took non-uniform circular motion out of the syllabus a couple of years ago, and just wondering whether it is the same with this. If it is examinable, could someone please tell me where I could locate some similar questions to practise on? I have a feeling it could come up (there hasnt been a projectile Q since 2003)
BTW I have the solutions book, ao i know how to do the question.
(b) A particle of mass m is thrown from the top, O, of a very tall building with an
initial velocity u at an angle α to the horizontal. The particle experiences the
effect of gravity, and a resistance proportional to its velocity in both the
horizontal and vertical directions. The equations of motion in the horizontal and
vertical directions are given respectively by
x: = −kx. and y: = −ky. − g x. is x dot and x: is x double dot
where k is a constant and the acceleration due to gravity is g. (You are NOT
required to show these.)
(i) Derive the result
x. = ue^(-kt)cosα
from the relevant equation of motion.
(ii) Verify that
y. = (1/k)[(kusinα + g)e^-kt - g]
satisfies the appropriate equation
of motion and initial condition.
(iii) Find the value of t when the particle reaches its maximum height.
(iv) What is the limiting value of the horizontal displacement of the particle?
Are we expected to be able to integrate these sorts of equations? I ask because I remember seeing in a thread a while ago that they took non-uniform circular motion out of the syllabus a couple of years ago, and just wondering whether it is the same with this. If it is examinable, could someone please tell me where I could locate some similar questions to practise on? I have a feeling it could come up (there hasnt been a projectile Q since 2003)
BTW I have the solutions book, ao i know how to do the question.
