In considering the size and speed of a merchant ship for a given service, the following assumptions are made:
A car rests on four equal weightless wheels of diameter 3 feet, which can rotate about central bearings of diameter 2 inches. If the angle of friction between each wheel and its bearing be 18\(^\circ\), show that the car will not rest on a rough inclined plane, if the inclination of the plane to the horizontal be greater than 1\(^\circ\), approximately, assuming that a wheel and its bearing are in contact along a single generator.
Show that, if \(x\) and \(y\) are positive, \(m\) and \(n\) positive integers, and if the greatest term of the Binomial expansion of \((x+y)^m\) is the \(p\)th, and the greatest term of that of \((x+y)^n\) is the \(q\)th, then the greatest term of the expansion of \((x+y)^{m+n}\) is the \((p+q)\)th or the \((p+q-1)\)th.
Obtain the real solutions of the equations \[ x^3 + \frac{7}{3}xy^2 = y^3 + \frac{7}{3}yx^2 = 1 \] to three significant figures.
Starting from the definitions of sine and cosine by means of the infinite series, \[ \sin x = x - \frac{x^3}{3!} + \dots, \qquad \cos x = 1 - \frac{x^2}{2!} + \dots, \] give an outline, without detailed proof, of the steps by which the chief results of the trigonometry of a real angle can be established.
Simultaneous values of the speed and the acceleration are observed, during the run of a train, to be as follows:
A uniform heavy beam \(AB\) of weight \(3W\), loaded with equal weights \(W\) at \(A\) and a point of trisection \(D\), rests in a horizontal position on two supports at \(B\) and a point of trisection \(C\), where \(AC=CD=DB\). Sketch diagrams showing the distributions of shearing stress and bending moment along the beam.
Prove that, if \(S_r\) denotes \(1^r + 2^r + 3^r + \dots + n^r\), then \[ S_5 + S_7 = 2S_1^2. \quad [sic] \]
\(ABC\) is a triangle and \(AD\) the perpendicular on \(BC\). Obtain a formula for \(\cos A\) in terms of the lengths \(AD, BD, AC\).
Prove that, if the coefficients in the equation \[ ax^2+2hxy+by^2+2gx+2fy+c=0 \] are real, and \(a, h, b\) are not all zero, the real part of the locus represented by the equation is either (1) an ellipse, (2) a hyperbola, (3) a parabola, (4) two intersecting straight lines, (5) two parallel straight lines, (6) one straight line (counted doubly), (7) a point, or (8) non-existent; and state the conditions in each case. Determine the different types of locus represented by \[ 2x^2 + 2\lambda xy + \lambda y^2 + \lambda(\lambda^2-1) = 0, \] as \(\lambda\) changes from a large negative to a large positive value.