416 lines
No EOL
20 KiB
Text
416 lines
No EOL
20 KiB
Text
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§32
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The inertia tensor
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101
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two of the principal moments of inertia are equal and the third is zero:
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I3 = 0.
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(32.11)
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Such a system is called a rotator. The characteristic property which distin-
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guishes a rotator from other bodies is that it has only two, not three, rotational
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degrees of freedom, corresponding to rotations about the X1 and X2 axes: it
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is clearly meaningless to speak of the rotation of a straight line about itself.
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Finally, we may note one further result concerning the calculation of the
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inertia tensor. Although this tensor has been defined with respect to a system
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of co-ordinates whose origin is at the centre of mass (as is necessary if the
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fundamental formula (32.3) is to be valid), it may sometimes be more con-
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veniently found by first calculating a similar tensor I' =
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defined with respect to some other origin O'. If the distance OO' is repre-
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sented by a vector a, then r = r'+a, Xi = x'i+ai; since, by the definition
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of O, Emr = 0, we have
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I'ikIk(a2ik-aiak).
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(32.12)
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Using this formula, we can easily calculate Iik if I'ik is known.
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PROBLEMS
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PROBLEM 1. Determine the principal moments of inertia for the following types of mole-
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cule, regarded as systems of particles at fixed distances apart: (a) a molecule of collinear
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atoms, (b) a triatomic molecule which is an isosceles triangle (Fig. 36), (c) a tetratomic
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molecule which is an equilateral-based tetrahedron (Fig. 37).
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m2
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X2
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m2
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h
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x
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m
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a
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a
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m
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a
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m
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m
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a
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FIG. 36
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FIG. 37
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SOLUTION. (a)
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Is = 0,
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where Ma is the mass of the ath atom, lao the distance between the ath and bth atoms, and
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the summation includes one term for every pair of atoms in the molecule.
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For a diatomic molecule there is only one term in the sum, and the result is obvious it is
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the product of the reduced mass of the two atoms and the square of the distance between
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them: I1 = I2 = m1m2l2((m1+m2).
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(b) The centre of mass is on the axis of symmetry of the triangle, at a distance X2 = mzh/u
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from its base (h being the height of the triangle). The moments of inertia are I1 = 2m1m2h2/u,
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I2 = 1m1a2, I3 = I+I2.
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(c) The centre of mass is on the axis of symmetry of the tetrahedron, at a distance
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X3 = mgh/u from its base (h being the height of the tetrahedron). The moments of inertia
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102
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Motion of a Rigid Body
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§32
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are I1 = = I3 = mia². If M1 = M2, h = (2/3)a, the molecule is a
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regular tetrahedron and I1=I2 = I3 = mia2.
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PROBLEM 2. Determine the principal moments of inertia for the following homogeneous
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bodies: (a) a thin rod of length l, (b) a sphere of radius R, (c) a circular cylinder of radius R
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and height h, (d) a rectangular parallelepiped of sides a, b, and c, (e) a circular cone of height
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h and base radius R, (f) an ellipsoid of semiaxes a, b, c.
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SOLUTION. (a) I1 = I2 = Trul2, I3 = 0 (we neglect the thickness of the rod).
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(b) I1 = I2 = I3 = zuR2 (found by calculating the sum I+I+I3 = 2p dV).
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(c) I1 = I2 = tu(R2+th2), I3 = tuR2 (where the x3-axis is along the axis of the cylinder).
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(d) I1 = (2+c2), I2 = (a2+cc), I3 = 121(a2++b) (where the axes X1, x2, X3 are
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along the sides a, b, c respectively).
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(e) We first calculate the tensor I'ik with respect to axes whose origin is at the vertex of
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the cone (Fig. 38). The calculation is simple if cylindrical co-ordinates are used, and the result
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is I'1 = I'2 = I'3 = 2 The centre of mass is easily shown to be on the
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axis of the cone and at a distance a = 3h from the vertex. Formula (32.12) therefore gives
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I1 = I2 = I'1-2 = I3 = I'3 = TouR2.
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X3,X3'
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X2
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xi
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x2
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FIG. 38
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(f) The centre of mass is at the centre of the ellipsoid, and the principal axes of inertia are
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along the axes of the ellipsoid. The integration over the volume of the ellipsoid can be reduced
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to one over a sphere by the transformation x = as,y = bn, 2 = c5, which converts the equa-
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tion of the surface of the ellipsoid 1 into that of the unit sphere
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st+24's = 1.
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For example, the moment of inertia about the x-axis is
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dz
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= tabcI'(b2 tc2),
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where I' is the moment of inertia of a sphere of unit radius. Since the volume of the ellipsoid
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is 4nabc/3, we find the moments of inertia I = tu(b2+c2), I2 = tu(a2+c2), I3 = tu(a2+b2).
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PROBLEM 3. Determine the frequency of small oscillations of a compound pendulum (a
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rigid body swinging about a fixed horizontal axis in a gravitational field).
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SOLUTION. Let l be the distance between the centre of mass of the pendulum and the axis
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about which it rotates, and a, B, y the angles between the principal axes of inertia and the
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axis of rotation. We take as the variable co-ordinate the angle between the vertical
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and a line through the centre of mass perpendicular to the axis of rotation. The velocity of
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the centre of mass is V = 10, and the components of the angular velocity along the principal
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§32
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The inertia tensor
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103
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axes of inertia are o cos a, b cos B, b cos y. Assuming the angle to be small, we find the
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potential energy U = ugl(1-cos 9 22 12. The Lagrangian is therefore
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=
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The frequency of the oscillations is consequently
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w2 = cos2y).
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PROBLEM 4. Find the kinetic energy of the system shown in Fig. 39: OA and AB are thin
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uniform rods of length l hinged together at A. The rod OA rotates (in the plane of the diagram)
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about O, while the end B of the rod AB slides along Ox.
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A
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l
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l
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x
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B
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FIG. 39
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SOLUTION. The velocity of the centre of mass of the rod OA (which is at the middle of
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the rod) is 110, where is the angle AOB. The kinetic energy of the rod OA is therefore
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T1 = where u is the mass of each rod.
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The Cartesian co-ordinates of the centre of mass of the rod AB are X = sl cos o, Y
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= 1/ sin b. Since the angular velocity of rotation of this rod is also b, its kinetic energy is
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T2 = = tul2(1- +8 sin2o)62 +1162. The total kinetic energy of this
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system is therefore = I = Tzul2 (see Problem 2(a)).
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PROBLEM 5. Find the kinetic energy of a cylinder of radius R rolling on a plane, if the mass
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of the cylinder is so distributed that one of the principal axes of inertia is parallel to the axis
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of the cylinder and at a distance a from it, and the moment of inertia about that principal
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axis is I.
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SOLUTION. Let be the angle between the vertical and a line from the centre of mass
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perpendicular to the axis of the cylinder (Fig. 40). The motion of the cylinder at any instant
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R
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FIG. 40
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may be regarded as a pure rotation about an instantaneous axis which coincides with the
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line where the cylinder touches the plane. The angular velocity of this rotation is o, since
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the angular velocity of rotation about all parallel axes is the same. The centre of mass is at a
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distance V(a2+R2-2aR cos ) from the instantaneous axis, and its velocity is therefore
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V = bv /(a2+R2-2aR cos ). The total kinetic energy is
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T = cos
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104
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Motion of a Rigid Body
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§32
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PROBLEM 6. Find the kinetic energy of a homogeneous cylinder of radius a rolling inside
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a cylindrical surface of radius R (Fig. 41).
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R
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FIG. 41
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SOLUTION. We use the angle between the vertical and the line joining the centres of the
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cylinders. The centre of mass of the rolling cylinder is on the axis, and its velocity is V =
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o(R-a). We can calculate the angular velocity as that of a pure rotation about an instantaneous
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axis which coincides with the line of contact of the cylinders it is Q = V/a = p(R-a)/a.
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If I3 is the moment of inertia about the axis of the cylinder, then
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T =
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I3 being given by Problem 2(c).
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PROBLEM 7. Find the kinetic energy of a homogeneous cone rolling on a plane.
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SOLUTION. We denote by 0 the angle between the line OA in which the cone touches the
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plane and some fixed direction in the plane (Fig. 42). The centre of mass is on the axis of the
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cone, and its velocity V = a0 cos a, where 2a is the vertical angle of the cone and a the
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Z
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Y
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A
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FIG. 42
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distance of the centre of mass from the vertex. The angular velocity can be calculated as
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that of a pure rotation about the instantaneous axis OA: S2 = V/a sin a = é cot a. One of
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the principal axes of inertia (x3) is along the axis of the cone, and we take another (x2) perpen-
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dicular to the axis of the cone and to the line OA. Then the components of the vector S
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(which is parallel to OA) along the principal axes of inertia are O sin a, 0, O cos a. The kinetic
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energy is thus
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=
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= 3uh202(1+5 cos2x)/40,
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where h is the height of the cone, and I1, I3 and a have been given in Problem 2(e).
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PROBLEM 8. Find the kinetic energy of a homogeneous cone whose base rolls on a plane
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and whose vertex is fixed at a height above the plane equal to the radius of the base, so that
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the axis of the cone is parallel to the plane.
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SOLUTION. We use the angle 0 between a fixed direction in the plane and the projection
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of the axis of the cone on the plane (Fig. 43). Then the velocity of the centre of mass is V = aß,
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§33
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Angular momentum of a rigid body
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105
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the notation being as in Problem 7. The instantaneous axis of rotation is the generator OA
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which passes through the point where the cone touches the plane. The centre of mass is at a
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distance a sin a from this axis, and so l = V/a sin a = O/sin a. The components of the
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vector Ca along the principal axes of inertia are, if the x2-axis is taken perpendicular to the
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axis of the cone and to the line OA, O sin a = 6, 0, N cos a = è cot a. The kinetic energy
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is therefore
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T cot2a
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= 314h282(sec2x+5)/40.
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Z
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0
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Y
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A
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FIG. 43
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PROBLEM 9. Find the kinetic energy of a homogeneous ellipsoid which rotates about one
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of its axes (AB in Fig. 44) while that axis itself rotates about a line CD perpendicular to it
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and passing through the centre of the ellipsoid.
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SOLUTION. Let the angle of rotation about CD be 0, and that about AB (i.e. the angle
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between CD and the x1-axis of inertia, which is perpendicular to AB) be . Then the com-
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ponents of S along the axes of inertia are é cos , 0 sin , b, if the x3-axis is AB. Since the
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centre of mass, at the centre of the ellipsoid, is at rest, the kinetic energy is
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=
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D
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B
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D
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A
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Do
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A
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1a
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C
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of
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8
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FIG. 44
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FIG. 45
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PROBLEM 10. The same as Problem 9, but for the case where the axis AB is not perpendicu-
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lar to CD and is an axis of symmetry of the ellipsoid (Fig. 45).
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SOLUTION. The components of Ca along the axis AB and the other two principal axes of
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inertia, which are perpendicular to AB but otherwise arbitrary, are è cos a cos , è cos a X
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sin , o to sin a. The kinetic energy is T = 11102 a)2.
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$33. Angular momentum of a rigid body
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The value of the angular momentum of a system depends, as we know, on
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the point with respect to which it is defined. In the mechanics of a rigid body,
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106
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Motion of a Rigid Body
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§33
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the most appropriate point to choose for this purpose is the origin of the
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moving system of co-ordinates, i.e. the centre of mass of the body, and in
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what follows we shall denote by M the angular momentum SO defined.
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According to formula (9.6), when the origin is taken at the centre of mass
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of the body, the angular momentum M is equal to the "intrinsic" angular
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momentum resulting from the motion relative to the centre of mass. In the
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definition M = Emrxv we therefore replace V by Sxr:
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M = =
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or, in tensor notation,
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Mi = OK
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Finally, using the definition (32.2) of the inertia tensor, we have
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(33.1)
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If the axes X1, X2, X3 are the same as the principal axes of inertia, formula
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(33.1) gives
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M2 = I2DQ,
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M3 = I303. =
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(33.2)
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In particular, for a spherical top, where all three principal moments of inertia
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are equal, we have simply
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M = IS,
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(33.3)
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i.e. the angular momentum vector is proportional to, and in the same direc-
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tion as, the angular velocity vector. For an arbitrary body, however, the
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vector M is not in general in the same direction as S; this happens only
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when the body is rotating about one of its principal axes of inertia.
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Let us consider a rigid body moving freely, i.e. not subject to any external
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forces. We suppose that any uniform translational motion, which is of no
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interest, is removed, leaving a free rotation of the body.
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As in any closed system, the angular momentum of the freely rotating body
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is constant. For a spherical top the condition M = constant gives C = con-
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stant; that is, the most general free rotation of a spherical top is a uniform
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rotation about an axis fixed in space.
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The case of a rotator is equally simple. Here also M = IS, and the vector
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S is perpendicular to the axis of the rotator. Hence a free rotation of a rotator
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is a uniform rotation in one plane about an axis perpendicular to that plane.
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The law of conservation of angular momentum also suffices to determine
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the more complex free rotation of a symmetrical top. Using the fact that the
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principal axes of inertia X1, X2 (perpendicular to the axis of symmetry (x3)
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of the top) may be chosen arbitrarily, we take the x2-axis perpendicular to
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the plane containing the constant vector M and the instantaneous position
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of the x3-axis. Then M2 = 0, and formulae (33.2) show that Q2 = 0. This
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means that the directions of M, St and the axis of the top are at every instant
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in one plane (Fig. 46). Hence, in turn, it follows that the velocity V = Sxr
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of every point on the axis of the top is at every instant perpendicular to that
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§34
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The equations of motion of a rigid body
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107
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plane. That is, the axis of the top rotates uniformly (see below) about the
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direction of M, describing a circular cone. This is called regular precession
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of the top. At the same time the top rotates uniformly about its own axis.
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M
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n
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x3
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22pr
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x1
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FIG. 46
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The angular velocities of these two rotations can easily be expressed in
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terms of the given angular momentum M and the angle 0 between the axis
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of the top and the direction of M. The angular velocity of the top about its
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own axis is just the component S3 of the vector S along the axis:
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Q3 = M3/I3 = (M/I3) cos 0.
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(33.4)
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To determine the rate of precession Spr, the vector S must be resolved into
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components along X3 and along M. The first of these gives no displacement
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of the axis of the top, and the second component is therefore the required
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angular velocity of precession. Fig. 46 shows that Spr sin 0 = Q1, and, since
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S21 = M1/I1 = (M/I1) sin 0, we have
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Spr r=M/I1.
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(33.5)
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$34. The equations of motion of a rigid body
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Since a rigid body has, in general, six degrees of freedom, the general
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equations of motion must be six in number. They can be put in a form which
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gives the time derivatives of two vectors, the momentum and the angular
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momentum of the body.
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The first equation is obtained by simply summing the equations p = f
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for each particle in the body, p being the momentum of the particle and f the
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108
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Motion of a Rigid Body
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§34
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force acting on it. In terms of the total momentum of the body P =
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and total force acting on it F = Ef, we have
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dP/dt = F.
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(34.1)
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Although F has been defined as the sum of all the forces f acting on the
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various particles, including the forces due to other particles, F actually
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includes only external forces: the forces of interaction between the particles
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composing the body must cancel out, since if there are no external forces
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the momentum of the body, like that of any closed system, must be conserved,
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i.e. we must have F = 0.
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If U is the potential energy of a rigid body in an external field, the force
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F is obtained by differentiating U with respect to the co-ordinates of the
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centre of mass of the body:
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F = JUIR.
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(34.2)
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For, when the body undergoes a translation through a distance SR, the radius
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vector r of every point in the body changes by SR, and so the change in the
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potential energy is
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SU = (U/dr) Sr = RR Couldr = SR SR.
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It may be noted that equation (34.1) can also be obtained as Lagrange's
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equation for the co-ordinates of the centre of mass, (d/dt)àL/JV = aL/JR,
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with the Lagrangian (32.4), for which
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OL/OV=,MV=P, 0L/JR = JU/OR = F.
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Let us now derive the second equation of motion, which gives the time
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derivative of the angular momentum M. To simplify the derivation, it is
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convenient to choose the "fixed" (inertial) frame of reference in such a way
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that the centre of mass is at rest in that frame at the instant considered.
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We have M = (d/dt) Erxp = Eixp+. Our choice of the frame of
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reference (with V = 0) means that the value of i at the instant considered is
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the same as V = i. Since the vectors V and p = mv are parallel, ixp = 0.
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Replacing p by the force f, we have finally
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dM/dt = K,
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(34.3)
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where
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K = .
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(34.4)
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Since M has been defined as the angular momentum about the centre of
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mass (see the beginning of $33), it is unchanged when we go from one inertial
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frame to another. This is seen from formula (9.5) with R = 0. We can there-
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fore deduce that the equation of motion (34.3), though derived for a particular
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frame of reference, is valid in any other inertial frame, by Galileo's relativity
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principle.
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The vector rxf is called the moment of the force f, and so K is the total
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torque, i.e. the sum of the moments of all the forces acting on the body. Like
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§34
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The equations of motion of a rigid body
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109
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the total force F, the sum (34.4) need include only the external forces: by
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the law of conservation of angular momentum, the sum of the moments of
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the internal forces in a closed system must be zero.
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The moment of a force, like the angular momentum, in general depends on
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the choice of the origin about which it is defined. In (34.3) and (34.4) the
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moments are defined with respect to the centre of mass of the body.
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When the origin is moved a distance a, the new radius vector r' of each
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point in the body is equal to r-a. Hence K = Erxf = Er'xf+ Eaxf or
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K = K'+axF.
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(34.5)
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Hence we see, in particular, that the value of the torque is independent of
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the choice of origin if the total force F = 0. In this case the body is said to
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be acted on by a couple.
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Equation (34.3) may be regarded as Lagrange's equation (d/dt) OL/OS
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= 0L/dd for the "rotational co-ordinates". Differentiating the Lagrangian
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(32.4) with respect to the components of the vector S2, we obtain
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= IikOk = Mi. The change in the potential energy resulting from an
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infinitesimal rotation SO of the body is SU = - Ef.Sr = -
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= So. Erxf = -K.SO, whence
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K =-20/00, =
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(34.6)
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so that aL/dd = 00/08 = K.
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Let us assume that the vectors F and K are perpendicular. Then a vector a
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can always be found such that K' given by formula (34.5) is zero and
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K a x F.
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(34.7)
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The choice of a is not unique, since the addition to a of any vector parallel
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to F does not affect equation (34.7). The condition K' = 0 thus gives a straight
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line, not a point, in the moving system of co-ordinates. When K is perpendi-
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cular to F, the effect of all the applied forces can therefore be reduced to that
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of a single force F acting along this line.
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Such a case is that of a uniform field of force, in which the force on a particle
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is f = eE, with E a constant vector characterising the field and e characterising
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the properties of a particle with respect to the field. Then F = Ee,
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K = erxE. Assuming that # 0, we define a radius vector ro such that
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(34.8)
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Then the total torque is simply
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=roxF
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(34.9)
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Thus, when a rigid body moves in a uniform field, the effect of the field
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reduces to the action of a single force F applied at the point whose radius
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vector is (34.8). The position of this point is entirely determined by the
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t For example, in a uniform electric field E is the field strength and e the charge; in a
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uniform gravitational field E is the acceleration g due to gravity and e is the mass m.
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110
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Motion of a Rigid Body
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§35
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properties of the body itself. In a gravitational field, for example, it is the
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centre of mass.
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$35. Eulerian angles
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As has already been mentioned, the motion of a rigid body can be described
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by means of the three co-ordinates of its centre of mass and any three angles
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which determine the orientation of the axes X1, X2, X3 in the moving system of
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co-ordinates relative to the fixed system X, Y, Z. These angles may often be
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conveniently taken as what are called Eulerian angles.
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Z
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X2
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Y
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FIG. 47
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Since we are here interested only in the angles between the co-ordinate
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axes, we may take the origins of the two systems to coincide (Fig. 47). The
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moving x1x2-plane intersects the fixed XY-plane in some line ON, called the
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line of nodes. This line is evidently perpendicular to both the Z-axis and the
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x3-axis; we take its positive direction as that of the vector product ZXX3
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(where Z and X3 are unit vectors along the Z and X3 axes).
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We take, as the quantities defining the position of the axes x1, X2, X3
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relative to the axes X, Y, Z the angle 0 between the Z and X3 axes, the angle
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between the X-axis and ON, and the angle as between the x1-axis and ON.
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The angles and 4 are measured round the Z and X3 axes respectively in the
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direction given by the corkscrew rule. The angle 0 takes values from 0 to TT,
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and and 4 from 0 to 2n.t
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t The angles 0 and - are respectively the polar angle and azimuth of the direction
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X3 with respect to the axes X, Y, Z. The angles 0 and 12-- are respectively the polar angle
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and azimuth of the direction Z with respect to the axes X1, X2, X3. |