178 lines
8.9 KiB
Markdown
178 lines
8.9 KiB
Markdown
---
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title: 27-parametric-resonance
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---
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PROBLEM
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Determine the forced oscillations due to an external force f = fo exp(at) COS st in the
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presence of friction.
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SOLUTION. We solve the complex equation of motion
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2+wo2x = (fo/m) exp(at+iyt)
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and then take the real part. The result is a forced oscillation of the form
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x=bexp(at)cos(yt+8),
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where
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b =
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tan s =
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§27. Parametric resonance
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There exist oscillatory systems which are not closed, but in which the
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external action amounts only to a time variation of the parameters.t
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The parameters of a one-dimensional system are the coefficients m and k
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in the Lagrangian (21.3). If these are functions of time, the equation of
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motion is
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(27.1)
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We introduce instead of t a new independent variable T such that
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dr = dt/m(t); this reduces the equation to
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d2x/d-2+mkx=0.
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There is therefore no loss of generality in considering an equation of motion
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of the form
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(27.2)
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obtained from (27.1) if m = constant.
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The form of the function w(t) is given by the conditions of the problem.
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Let us assume that this function is periodic with some frequency y and period
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T = 2n/y. This means that w(t+T) = w(t), and so the equation (27.2) is
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invariant under the transformation t t+ T. Hence, if x(t) is a solution of
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the equation, so is x(t+T). That is, if x1(t) and x2(t) are two independent
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integrals of equation (27.2), they must be transformed into linear combina-
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tions of themselves when t is replaced by t + T. It is possible to choose X1
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and X2 in such a way that, when t t+T, they are simply multiplied by
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t A simple example is that of a pendulum whose point of support executes a given periodic
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motion in a vertical direction (see Problem 3).
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+ This choice is equivalent to reducing to diagonal form the matrix of the linear trans-
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formation of x1(t) and x2(t), which involves the solution of the corresponding quadratic
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secular equation. We shall suppose here that the roots of this equation do not coincide.
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§27
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Parametric resonance
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81
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constants: x1(t+T) = 1x1(t), x2(t+T) = u2x2(t). The most general functions
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having this property are
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(t) = 111t/TII1(t), x2(t) = M2t/T112(t),
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(27.3)
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where II1(t), II2(t) are purely periodic functions of time with period T.
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The constants 1 and 2 in these functions must be related in a certain way.
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Multiplying the equations +2(t)x1 = 0, 2+w2(t)x2 = 0 by X2 and X1
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respectively and subtracting, we = = 0, or
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X1X2-XIX2 = constant.
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(27.4)
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For any functions x1(t), x2(t) of the form (27.3), the expression on the left-
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hand side of (27.4) is multiplied by H1U2 when t is replaced by t + T. Hence
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it is clear that, if equation (27.4) is to hold, we must have
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M1M2=1.
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(27.5)
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Further information about the constants M1, 2 can be obtained from the
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fact that the coefficients in equation (27.2) are real. If x(t) is any integral of
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such an equation, then the complex conjugate function x* (t) must also be
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an integral. Hence it follows that U1, 2 must be the same as M1*, M2*, i.e.
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either 1 = M2* or 1 and 2 are both real. In the former case, (27.5) gives
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M1 = 1/1*, i.e. /1112 = 1/22/2 = 1: the constants M1 and 2 are of modulus
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unity.
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In the other case, two independent integrals of equation (27.2) are
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x2(t) = -/I2(t),
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(27.6)
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with a positive or negative real value of u (Iu/ # 1). One of these functions
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(x1 or X2 according as /x/ > 1 or /u/ <1) increases exponentially with time.
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This means that the system at rest in equilibrium (x = 0) is unstable: any
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deviation from this state, however small, is sufficient to lead to a rapidly
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increasing displacement X. This is called parametric resonance.
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It should be noticed that, when the initial values of x and x are exactly
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zero, they remain zero, unlike what happens in ordinary resonance (§22),
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in which the displacement increases with time (proportionally to t) even from
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initial values of zero.
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Let us determine the conditions for parametric resonance to occur in the
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important case where the function w(t) differs only slightly from a constant
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value wo and is a simple periodic function:
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w2(1) = con2(1+h cosyt)
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(27.7)
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where
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the
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constant h 1; we shall suppose h positive, as may always be
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done by suitably choosing the origin of time. As we shall see below, para-
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metric resonance is strongest if the frequency of the function w(t) is nearly
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twice wo. Hence we put y = 2wo+e, where E < wo.
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82
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Small Oscillations
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§27
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The solution of equation of motion+
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+wo2[1+hcos(2wot)t]x
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(27.8)
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may be sought in the form
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(27.9)
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where a(t) and b(t) are functions of time which vary slowly in comparison
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with the trigonometrical factors. This form of solution is, of course, not
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exact. In reality, the function x(t) also involves terms with frequencies which
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differ from wother by integral multiples of 2wo+e; these terms are, how-
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ever, of a higher order of smallness with respect to h, and may be neglected
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in a first approximation (see Problem 1).
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We substitute (27.9) in (27.8) and retain only terms of the first order in
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€, assuming that à ea, b ~ eb; the correctness of this assumption under
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resonance conditions is confirmed by the result. The products of trigono-
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metrical functions may be replaced by sums:
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cos(wot1e)t.cos(2wote)t =
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etc., and in accordance with what was said above we omit terms with fre-
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quency 3(wo+1e). The result is
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= 0.
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If this equation is to be justified, the coefficients of the sine and cosine must
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both be zero. This gives two linear differential equations for the functions
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a(t) and b(t). As usual, we seek solutions proportional to exp(st). Then
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= 0, 1(e-thwo)a- - sb = 0, and the compatibility condition
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for these two algebraic equations gives
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(27.10)
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The condition for parametric resonance is that S is real, i.e. s2 > 0.1 Thus
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parametric resonance occurs in the range
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(27.11)
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on either side of the frequency 2wo.ll The width of this range is proportional
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to h, and the values of the amplification coefficient S of the oscillations in the
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range are of the order of h also.
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Parametric resonance also occurs when the frequency y with which the
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parameter varies is close to any value 2wo/n with n integral. The width of the
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t An equation of this form (with arbitrary y and h) is called in mathematical physics
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Mathieu's equation.
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+ The constant u in (27.6) is related to s by u = - exp(sn/wo); when t is replaced by
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t+2n/2wo, the sine and cosine in (27.9) change sign.
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II If we are interested only in the range of resonance, and not in the values of S in that
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range, the calculations may be simplified by noting that S = 0 at the ends of the range, i.e.
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the coefficients a and b in (27.9) are constants. This gives immediately € = thwo as in
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(27.11).
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§27
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Parametric resonance
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83
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resonance range (region of instability) decreases rapidly with increasing N,
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however, namely as hn (see Problem 2, footnote). The amplification co-
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efficient of the oscillations also decreases.
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The phenomenon of parametric resonance is maintained in the presence
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of slight friction, but the region of instability becomes somewhat narrower.
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As we have seen in §25, friction results in a damping of the amplitude of
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oscillations as exp(- - At). Hence the amplification of the oscillations in para-
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metric resonance is as exp[(s-1)t] with the positive S given by the solution
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for the frictionless case, and the limit of the region of instability is given by
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the equation - X = 0. Thus, with S given by (27.10), we have for the resonance
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range, instead of (27.11),
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(27.12)
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It should be noticed that resonance is now possible not for arbitrarily
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small amplitudes h, but only when h exceeds a "threshold" value hk. When
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(27.12) holds, hk = 4X/wo. It can be shown that, for resonance near the fre-
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quency 2wo/n, the threshold hk is proportional to X1/n, i.e. it increases with n.
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PROBLEMS
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PROBLEM 1. Obtain an expression correct as far as the term in h2 for the limits of the region
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of instability for resonance near 2 = 2wo.
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SOLUTION. We seek the solution of equation (27.8) in the form
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x = ao cos(wo+1e)t +bo (wo+le)t +a1 cos 3( (wo+le)t +b1 sin 3(wo+le)t,
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which includes terms of one higher order in h than (27.9). Since only the limits of the region
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of instability are required, we treat the coefficients ao, bo, a1, b1 as constants in accordance
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with the last footnote. Substituting in (27.8), we convert the products of trigonometrical
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functions into sums and omit the terms of frequency 5(wo+1) in this approximation. The
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result is
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[
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- cos(wo+l)
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cos 3(wo+1e)tt
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sin 3(wo+1e)t = 0.
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In the terms of frequency wothe we retain terms of the second order of smallness, but in
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those of frequency 3( (wo+1) only the first-order terms. Each of the expressions in brackets
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must separately vanish. The last two give a1 = hao/16, b1 = hbo/16, and then the first two
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give woe +thwo2+1e2-h2wo2/32 = 0.
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Solving this as far as terms of order h2, we obtain the required limits of E:
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= theo-h20003.
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PROBLEM 2. Determine the limits of the region of instability in resonance near y = wo.
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SOLUTION. Putting y = wote, we obtain the equation of motion
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0.
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Since the required limiting values of ~~h2, we seek a solution in the form
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ao cos(wote)t sin(wote)t cos 2(wo+e)t +b1 sin 2(wo+e)t- +C1,
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84
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Small Oscillations
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