Two particles of masses \(m, m'\) are attached to the middle point \(A\) and to the end point \(A'\) of a light inextensible string \(OAA'\) of length \(2l\). The end \(O\) is fixed and the system executes a small oscillation under gravity in a vertical plane through \(O\). If \(x, x'\) are the horizontal distances of the particles from the vertical line through \(O\) at time \(t\), and \(n^2=g/l\), prove that \begin{align*} m\frac{d^2x}{dt^2} + (m+2m')n^2x - m'n^2x' &= 0, \\ \frac{d^2x'}{dt^2} + n^2x' - n^2x &= 0, \end{align*} and hence show that if \(m=3m'\), a motion is possible in which \(x+x'=0\).
Prove that if \(n\) is a positive integer:
Prove that the function \[ y = \frac{a_1x^2+b_1x+c_1}{a_2x^2+b_2x+c_2} \] will take all real values as \(x\) takes every real value provided \[ (b_2^2-4a_2c_2)y^2+2y(2a_2c_1+2c_2a_1-b_1b_2)+b_1^2-4a_1c_1 \] is never negative. Hence, or otherwise, show that the function \(y\) will take all real values if the pairs of roots of the two equations \(a_1x^2+b_1x+c_1=0\), \(a_2x^2+b_2x+c_2=0\) are both real and interlacing, i.e. one and only one root of either equation lies between the two roots of the other.
(a) Express the function \(\frac{x^2-2}{(x^2+x+2)^2(x^2+x+1)}\) as partial fractions in the form \[ \frac{Ax+B}{(x^2+x+2)^2} + \frac{Cx+D}{x^2+x+2} + \frac{Ex+F}{x^2+x+1}, \] determining the values of \(A, B, C, D, E\) and \(F\). (b) Show, if \(n\) is a positive integer, that in the expansion of \(\frac{x-1}{(x-2)^n(x-3)}\) in partial fractions, the numerator of the fraction \(\frac{1}{(x-2)^r}\) is \(-2\) if \(n>r>1\). What is it when \(r=n\)?
If \(f(x)\) denote the polynomial expression \(x^n+p_1x^{n-1}+\dots+p_n\), where \(n\) is a positive integer and the coefficients \(p_r\) are real, show that the equation \(f(x)=0\) can have at most one real root between two consecutive real roots of the derived equation \(f'(x)=0\). Show also that if \(\alpha\) is a root of both equations it will be a multiple root of \(f(x)=0\). Hence, or otherwise, show that the equation \(2x^9-9x^2-1=0\) has only one real root and that this root is greater than unity.
(i) If \(ax^2+2hxy+by^2+2gx+2fy+c=0\), show that \[ \frac{d^2y}{dx^2} = \Delta/(hx+by+f)^3, \] where \(\Delta = \begin{vmatrix} a & h & g \\ h & b & f \\ g & f & c \end{vmatrix}\). (ii) Verify by direct differentiation that if \(a\) is a constant the function \[ y(x) = \int_a^x (x-t)e^{x-t}f(t)dt \] is a solution of the equation \[ \frac{d^2y}{dx^2} - 2\frac{dy}{dx} + y = f(x). \] (iii) Prove that \[ \frac{d^3x}{dy^3}\left(\frac{dy}{dx}\right)^5 = 3\left(\frac{d^2y}{dx^2}\right)^2 - \frac{d^3y}{dx^3}\frac{dy}{dx}. \]
(i) Prove that \[ \int_0^\infty \frac{dx}{1+x^3} = \int_0^\infty \frac{x dx}{1+x^3} = \frac{2\pi}{3\sqrt{3}}. \] (ii) By means of the substitution \((1+e\cos\phi)(1-e\cos\psi)=1-e^2\), or otherwise, show that, if \(e<1\), \[ (1-e^2)^{-n-\frac{1}{2}}\int_0^\pi (1+e\cos\phi)^{-n}d\phi = \int_0^\pi (1-e\cos\psi)^{n-1}d\psi. \] Hence evaluate \[ \int_0^\pi \frac{\sin^2\theta d\theta}{1+e\cos\theta}. \]
A solid hemisphere of radius \(a\) is such that the density at distance \(r\) from its centre is proportional to \((a-r)^n\). Show that its centre of mass is at distance \(3a/2(n+4)\) from the plane face.
Trace the curve \((x^2+y^2)^2 = 8axy^2\), and find the areas of its loops. Show that the smallest circle that will completely circumscribe the curve has radius \(3\sqrt{3}/2 a\), and find the coordinates of its centre.
Define the radius of curvature at a general point of a plane curve, and from the definition derive the equation of the circle of curvature at the point \(t\) of the curve having parametric equations \(x=x(t), y=y(t)\). Show that the equation of the curve whose circles of curvature have equation \[ (x-t)^2+y^2-2y\cosh t+1=0, \] where \(t\) is a variable parameter, may be put in the form \[ y = \operatorname{sech}(x+\sqrt{1-y^2}). \]