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Simple Harmonic Motion is independent of amplitude. Our answers to Question #1 would not change. 3. What are the equations for the potential and kinetic ...
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Questions: 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
x = 4cos(1.33t+π/5)
where distance is measured in metres and time in seconds. (a) What is the amplitude, frequency, angular frequency, and period of this motion? (b) What is the equation of the velocity of this particle? (c) What is the equation of the acceleration of this particle? (d) What is the spring constant? (e) At what next time t > 0, will the object be:
i. at equilibrium and moving to the right, ii. at equilibrium and moving to the left, iii. at maximum amplitude, and iv. at minimum amplitude.
(a) First write the general expression on top of the given expression
x = Acos(ωt + ϕ 0 ) x = 4cos(1.33t + π/5)
Immediately, we get A = 4 m, ω = 1.33 rad/s, and ϕ 0 = π/5. Since ω = 2π / T = 2πf, we get T = 2π /1.33 rad/s = 4.724 s, and f = ω / 2π = 0.2117 s−1.
(b) The velocity is given by the first derivative of position with respect to time
v = −ωAsin(ωt + ϕ 0 ).
With the given values, we get
v = −5.32sin(1.33t + π/5).
(c) The acceleration is given by the second of position with respect to time, or the first derivative of the velocity with respect to time,
a = −ω^2 A cos(ωt + π/5).
With the given values, we get
a = −7.08cos(1.33t + π/5).
(d) We have the relation that ω^2 = K/m, so
K = ω^2 m = (1.33 rad/s)^2 (1.75 kg) = 3.0956 N/m.
(e) (i) & (ii) We know that at equilibrium x = 0. We also know that there are two places where this happens, one where is the velocity is positive and the object is moving to the right, and one where the velocity is negative and the object is moving to the left. So first let's set x = 0,
0 = 4cos(ωt + π/5).
We can divide through by 4, and we get
0 = cos(ωt + π/5).
Taking the inverse of both sides, the solution is
ωt + π/5 = cos−1(0) ,
and thus,
t = [cos−1(0) − π/5] / ω.
Now cos−1(0) has many solutions, all the angles in radians for which the cosine is zero. This occurs for angles θ = π/2, θ = −π/2, θ = 3π/2, θ = −3π/2, and so on. This is usually expressed
θ = nπ/2, where n = ±1, ±3, ±5, …
So our solutions for t are in the form
t = [nπ/2 − π/5] / ω, where n = ±1, ±3, ±5, …
The first nonzero time when x = 0 occurs for n = +1,
t 1 = [π/2 − π/5] / = 0.7086 s.
The second nonzero time occurs when n = +2,
t 2 = [3π/2 − π/5] / = 3.0707 s.
To tell which has the object moving to the right and which to the left we examine the velocity
v 1 = −5.32sin(1.33t 1 + π/5) = −5.32sin(π/2) = −5.32 m/s,
v 2 = −5.32sin(1.33t 2 + π/5) = −5.32sin(3π/2) = +5.32 m/s.
We see that the object is moving to the left, has negative velocity, at t = t 1 = 0.7086 s, and is moving to the right at t = t 2 =
3.0707 s.
(iii) At maximum amplitude, x = +4, so we have
4 = 4cos(ωt + π/5).
Dividing through by 4, we get
1 = cos(ωt + π/5)
Taking the inverse of both sides, the solution is
ωt + π/5 = cos−1(1) ,
and thus,
indicates that at t = 0, x(0) > 0, v(0) < 0, and a(0) < 0.
Now as we rotate counterclockwise with increasing time, there are four points of interest labelled 1, 2, 3, and 4 in the diagrams. These are the points where the object is farthest to the right, moving to the left through equilibrium, farthest to the left, and moving to the right through equilibrium respectively.
The object on the spring, or equivalently the particle undergoing UCM, passes through points 2, 3, 4, and 1 in that order. These are shown as times t 1 , t 2 , t 3 , and t 4 in diagrams (b), (c), (d), and (e) in the figure above.
The figure (b) reference circle is for v = −ωA. We have rotated from the t = 0 position of π/5 to π/2 an angle of 90° − 36° = 54°. Since a 360° rotation takes one period T, then the time required to get to here was given by the ratio t 1 /T = 54°/360°.
Solving we find t 1 = 54 / 360 × 4.724 s = 0.709 s.
The figure (c) reference circle is for x = −A. We have rotated from the t = 0 position of π/5 to π an angle of 180° − 36° = 144°. Since a 360° rotation takes one period T, then the time required to get to here was given by the ratio t 2 /T = 144°/360°.
Solving we find t 2 = 144 / 360 × 4.724 s = 1.890 s.
The figure (d) reference circle is for v = +ωA. We have rotated from the t = 0 position of π/5 to 3π/2 an angle of 270° − 36° = 234°. Since a 360° rotation takes one period T, then the time required to get to here was given by the ratio t 3 /T =
234°/360°. Solving we find t 3 = 234 / 360 × 4.724 s = 3.071 s.
The figure (e) reference circle is for x = +A. We have rotated from the t = 0 position of π/5 to 2π an angle of 360° − 36° = 324°. Since a 360° rotation takes one period T, then the time required to get to here was given by the ratio t 2 /T = 324°/360°.
Solving we find t 4 = 324 / 360 × 4.724 s = 4.252 s.
Our answers for (e) are thus
(i) t = 3.071 s, (ii) t = 0.709 s,
(iii) t = 4.252 s, and (iv) t = 1.890 s.
Simple Harmonic Motion is independent of amplitude. Our answers to Question #1 would not change.
The potential energy is spring potential energy and is given by U = ½Kx^2 , so
U = ½(3.0956)[4cos(1.33t + π/5)] 2 = 24.76cos^2 (1.33t + π/5).
The kinetic energy is given by K = ½mv^2 , so
K = ½(1.75)[−5.32sin(1.33t + π/5)] 2 = 24.76sin^2 (1.33t + π/5).
The total energy is the sum of potential and kinetic energies,
E = U + K = 24.76 J.
Examining the graph we see that the largest displacement is 10 cm, so A = 0.10 m. We also see that the motion repeats every 0.2 seconds, so T = 0.2 s. Angular frequency is related to the period by ω = 2π/T, so ω = 10π.
The equation for the velocity of an object undergoing SHM has the form v(t) = vmaxsin(ωt+ϕ 0 ), where vmax = ωA and ω = 2π/T. Examining the graph, we see that the period is T = 0.1 s, so ω = 20π s 1. Also the maximum velocity is 5 m/s. From this we determine that A = vmax/ω = (5 m/s)/( 20π s 1 ) = 1/(4π) m = 0.0796 m. Furthermore, the maximum acceleration is amax = ω^2 A = ωvmax = 100π m/s^2.
To draw the reference circle note that the t = 0 velocity is positive (moving to the right) which only occurs when the object is in quadrants III and IV. Next note that the given v t graph has the velocity going to a maximum, which occurs when the object passes through equilibrium. Thus the object is in the third quadrant.
We use the velocity equation, v(t) = vmaxsin(ωt+ϕ 0 ), at t = 0 to find the phase constant ϕ 0. We already found ω = 20π s 1. Again we look at the value of the graph at t = 0 which is v(0) = 2.40 m/s. So we have 2.40 = 5sin(ϕ 0 ), or sin(ϕ 0 ) = 0.48.
There are two angles on the unit circle that satisfy this, ϕ 0 = 28.69° and ϕ 0 = 151.31°. The second angle is in the third quadrant as is necessary. As a positive angle this is ϕ 0 = 208.7° = 3.643 rad. Our equation is x(t) = (0.0796 m)cos(20πt + 3.643).
The spring constant is given by ω^2 = K/m, so K = (20π s 1 )^2 (2.00 kg) = 7896 N/m.
The total energy is Etotal = ½KA^2 = 25 J.
To find when the object is at point A, maximum velocity to the right, note that the object must be at point 4 of the reference circle. So the object needs to rotate to 270° from 208.7°. Since rotating 360° takes one period which here is 0.1 s, tA = 61.3/ 360 × 0.1 s = 0.0170 s.
The equation for the acceleration of an object undergoing SHM is has the form a(t) = amaxcos(ωt+ϕ 0 ), where amax = ω^2 A and ω = 2π/T. Examining the graph, we see that the period is T = 0.030 s, so ω = 200π/3 s 1. Also the maximum acceleration is 0.040 m/s^2. From this we deduce that A = amax/ω^2 = (0.040 m/s^2 )/(200p/3 s 1 )^2 = 9.119 × 10 6 m. Furthermore, the maximum velocity is vmax = ωA = amax/ω = 1.9099 × 10 4 m/s.
To draw the reference circle note that the t = 0 acceleration is positive (moving to the right) which only occurs when the object is in quadrants II and III. Next note that the given a t graph has the acceleration going to zero, which occurs when the object passes through equilibrium. Thus the object is in the third quadrant.
We can take the general equation, x = Acos(ωt + ϕ 0 ) and substitute in the t = 0 values to find ϕ 0.
0.40A = Acos(0 + ϕ 0 ) ,
which reduces to
0.40 = cos(ϕ 0 ) ,
or
ϕ 0 = cos 1 ( 0.40).
Remember that your calculator will only give you one answer but there is also a second answer 360° minus the calulator answer.
Solving yields 113.6° (1.983 rad) or 246.4° (4.300 rad). The second answer is in the third quadrant and is thus the correct phase constant.
To sketch the x t graph first note that the t = 0 position is 0.40A and that the velocity is positive v = ωAand that the object on the reference circle will rotate next to point 4, which has x = 0. So graph must rise through x = 0.
To sketch the v t graph first note that the t = 0 velocity is positive and has value v = −ωAsin(ϕ 0 ) = 0.9164ωA .When the
object rotates to position 4, equilibrium velocity will be a maximum. So the velocity has risen.
Sketch the x t and v t graphs. When exactly will the block reach equilibrium?
The phase constant ϕ 0 is measured from the positive x axis. Thus ϕ 0 = 240° = 4π/3.
To sketch the x t graph, we need to know the t = 0 position. Here x(0) = Acos(240°) = −½A. To determine the behaviour for t > 0, note that the object in the reference circle rotates counterclockwise and will reach equilibrium, x = 0.
To sketch the v t graph, we need to know the t = 0 velocity. Here v(0) = −ωAsin(240°) = +0.866ωA. To determine the behaviour for t > 0, now that the object in the reference circle rotates counterclockwise and will reach equilibrium, x = 0, where the velocity is positive maximum v = +ωA.
The object has to rotate through 30° counterclockwise to reach equilibrum. Since a rotation of 360° takes one period T, this object will reach equilibrium in time t = 30 / 360 × T = T/12. We just need to know the period T. Since ω^2 = K/M, ω = 15 rad/s. Now T = 2π/ω = 0.419 s. So the object reaches equilibrium in t = (= 0.419 s)/12 = 0.0349 s.
An examination of our relationships for SHM indicates that the velocity of a particle is at a maximum as it goes through equilibrium. So the problem has given use the maximum velocity. As well we have vmax = ωA, and ω = [K/m]½, so
The object has a negative position and is moving to the right so it must be in quadrant III on the reference circle.
insert diagram
We can take the general equation, s = Scos(ωt + ϕ 0 ) and substitute in the t = 0 values to find ϕ 0.
0.6S = Scos(0 + ϕ 0 ) ,
which reduces to
0.60 = cos(ϕ 0 ) ,
or
ϕ 0 = cos 1 ( 0.60).
Remember that your calculator will only give you one answer but there is also a second answer 360° minus the calulator answer.
Solving yields 126.9° (2.214 rad) or 233.4° (4.069 rad). The second answer is in the third quadrant and is thus the correct phase constant.
To sketch the x t graph first note that the t = 0 position is 0.60S and that the velocity is positive v = ωA and that the object on the reference circle will rotate next to point 4, which has x = 0. So graph must rise through x = 0.
To sketch the v t graph first note that the t = 0 velocity is positive and has value v = −ωSsin(ϕ 0 ) = 0.8028ωS. When the
object rotates to position 4, equilibrium velocity will be a maximum. So the velocity has risen.
Examining the motion we see that the object swings for half the motion on a string of length L, and the other half as a string of length L/n. From the period of a pendulum, we know how long each of these motion are. Therefore the total time is
T = ½T 1 + ½T 2 = π{[L/g]½^ + [L/(ng)]½}.
My thanks to C. Kufazvinei and F. Z. Mavhunga for pointing out a previous typographical error in the above equation.
(a) The fact that we are looking for ω indicates an SHM problem. It is not the simple one spring and block system we studied since there are two springs. However energy methods let us handle everything since we know Ef = Ei, hence we have
(c) We found that for the single spring and rolling disk. If we had the spring and a block the result would have
been. We would need to increase the spring constant in the spring disk system to increase ω to the same value as
the spring block system. To get rid of the fraction 2 / 3 in our spring disk system we need Knew = 3 / 2 K.
(d) We found that for the single spring and rolling disk. If we had the spring and a block the result would have
been. We would need to decrease the mass in the spring disk system to increase ω to the same value as the
spring block system. To get rid of the fraction 2 / 3 in our spring disk system we need Mnew = 2 / 3 M.
(a) The fact that we are looking for ω indicates an SHM problem. It is not a simple single spring and block system since there is also rolling. However energy methods let us handle everything since we know Ef = Ei, hence we have
2 × ½KA^2 = ½Mv^2 + ½Iωrolling^2
For a solid sphere, I = 2 / 5 Mr^2. Since it is rolling, ωrolling = v/r. The above equation reduces to
KA^2 = 7 / 10 Mv^2
Solving for v yields.
(b) Now this is the maximum velocity of the block and we know for SHM that vmax = ωA. So.
(c) We found that for the double spring and rolling disk. If we had a spring and a block system, the result would
have been. We would need to decrease the spring constant in the double spring disk system to decrease ω to the
same value as the spring block system. To get rid of the fraction 10 / 7 in our double spring disk system equation we need Knew = 7 / 10 K.
(d) We found that for the double spring and rolling disk. If we had a spring and a block system, the result would
have been. We would need to increase the mass in the double spring disk system to decrease ω to the same
value as the spring block system. To get rid of the fraction 10 / 7 in our double spring disk system equation we need Mnew = (^10) / 7 M.
First we have a totally inelastic collision, so
(M 1 + M 2 )vf = M 1 v.
This tells us that
vf = M 1 v /(M 1 + M 2 ) = (5)(15 m/s)/(5 + 3) = 9.375 m/s.
This is the maximum velocity of the double−block SHM.
(a) From our relations for SHM, we know that ω = [K/m]½, so
ω = [(3000 N/m) / (5 kg + 3 kg)] ½^ = 19.36 rad/s.
(b) From the SHM relations, we also know vmax = ωA, so the maximum compression is
A = vmax / ω = (9.375 m/s) / (19.36 rad/s) = 0.4842 m.
(c) The maximum acceleration is given by amax = ω^2 A, so
amax = (19.36 rad/s)^2 (0.4842 m) = 181.5 m/s^2.