SciELO - Scientific Electronic Library Online

 
vol.62 número1Two-dimensional harmonic and Green’s functions on a spherical surfaceDifracción de luz por esferas dieléctricas: micro- y nano-partículas índice de autoresíndice de materiabúsqueda de artículos
Home Pagelista alfabética de revistas  

Servicios Personalizados

Revista

Articulo

Indicadores

Links relacionados

  • No hay artículos similaresSimilares en SciELO

Compartir


Revista mexicana de física E

versión impresa ISSN 1870-3542

Rev. mex. fís. E vol.62 no.1 México ene./jun. 2016

 

Education

Experimental aspects of the gyroscope’s movement

P. Morales a  

D.E. Jaramillo a  

J. Osorio a  

aInstituto de Física, Universidad de Antioquia, Calle 67 No. 53-108, A.A. 12 26, Medellín, Colombia.


ABSTRACT

In presence of a uniform gravitational field, Euler equations for a gyroscope can be written as a non-linear equation for the components of Riemann’s stereographic projection of the symmetry axis over a horizontal plane. Under the approximation of nutations with low amplitude, the solution of this equation corresponds to the sum of two rotating vectors with angular frequencies related to both angular velocities of nutation and precession. Such velocities are functions of rotation rapidity and inertia momentum of the gyroscope. From pictures of the movement projection of a commercial gyroscope, and using a laser that turn on during half revolution cycle of a disk, we can determine all kinematic quantities of the gyroscope, velocities of: rotation, precession and nutation, along with the angle of average inclination from axis. After complete a total of 120 experiments, we corroborate that the expressions given for velocities of precession and nutation, in function of rotation, match with experimental data. This is an easy experiment to implement, and can be used in advanced courses of mechanic.

Keywords: Spinning top’s movement; Euler equations

PACS: 42.25.Gy; 42.25.Lc.

1. Introduction

The movement of a spinning top has always raised the curiosity of experts and non-experts; basically, it is due to the stability that the spinning top acquires while rotate. Although the explanation of its behavior is not immediate in mechanical terms, from Euler and Lagrange is understood the dynamics of this movement, and its theoretical aspects are found in books of advanced mechanics 1-3.

Despite of the extensive literature one can find regarding to theories about the spinning top and the gyroscope 4-7, there are very few reports about the measurements of precession and nutation rates. In pioneering works, by using stroboscopes, people could measure: angular velocity, inclination angle and the path of the spinning top tip over coal or graphite paper; but they did not provide velocities of nutation and precession 8.

Currently, by using high speed video cams, those measurements can be directly done. This kind of methodology is used on projects or experiments for university labs, however, in this case collecting numerical data is a difficult task because it requires a shot reproduction, frame by frame, in order to determine the body’s trajectory as a function of time 9.

In this work, we present a simple way to find, for a certain time interval, the measurements for velocities of: precession, nutation, and rotation, in a gyroscope; all this by using a single picture and a laser light adhered to the gyroscope, which is projected over a horizontal plane. To compare experimental values with theoretical, we use an approximate solution for Euler equations for the problem of symmetrical spinning top with fixed point by using Riemann stereographic projection on the horizontal plane.

2. Gyroscope Movement

Generally, a gyroscope is a rigid body with axial symmetry that can rotate around a fixed point on its symmetry axis. In particular, it consists of a rod with a fixed point on its middle and which has the freedom of self-orienting in any direction inside a specific angular range. At the same time, the rod has a rotating disk located on one of its ends whose axis coincides with the rod. At the other end, the rod also has a counterweight which allows adjusting the center of mass for the system.

The most notorious thing of this instrument is the fact that when the disk rotates speedily, the center of mass does not fall to the lowest position, instead, it keeps moving slowly in a horizontal circle with fast nodding motion in the axis of rotation.

The movement in a gyroscope is composed by three independent movements: 1) Rotation, which is the disk movement on its own axis; 2) Precession, which is the average horizontal movement done by the disk axis around a vertical, and 3) Nutation which corresponds to small and fast oscillations of the axis. Usually, Nutation has small amplitude and tends to quickly disappear under friction; this is why frequently it goes unnoticed.

2.1. Movement equations of a gyroscope

On the basis of an inertial system, the rate of change of components from angular L corresponds to the net torque τ exerted by external forces. However, based on a rotating system {e^1,e^2,e^3}, which is spinning with angular velocity ω; the change on vector ω×e^i is added to the rate of change of a vector’s components. Therefore, Newton’s equations take the form of Euler’s equations 10:

τ=L̇+ω×L. (1)

By aligning the base vectors from the rotating system with the main axes of a gyroscope, the Momentum of Inertia Tensor becomes diagonal, I = diag(I1; I2; I3),, and components from the angular moment will depend only on the respective components of angular velocity, Li = Iiωi . Now, by aligning e^3 with the rotation axis, I1 = I2 is obtained, and the equation (1) can be written by components as follow 11:

τ1=I1ω̇1+ω2ω3(I3-I1),τ2=I1ω̇2-ω1ω3(I3-I1),τ3=I3ω̇3. (2)

Gyroscope’s orientation is fully described by three Eulerian angles corresponding to the angles that relate the main axis of a gyroscope with the coordinate axis on a steady state system {e^x,e^y,e^z}; where by convention, z axis represents vertical direction. Each of these angles can be associated to each different movement on a gyroscope. The zenith angle θ corresponds to the angular separation between the symmetry axis e^3 and the vertical; and it determines the nutation movement. The azimuthal angle ϕ, formed between the x axis and the nodes line (intersection between horizontal plane and that other, perpendicular to the symmetry axis), it determines the precession. Finally, ψ angle which accounts for the body spinning around of symmetry axis, and determines the rotational movement. Figure 1 is a graphic representation of Euler’s angles and the angular velocity associated to them.

Figure 1 Euler’s angles and their associate angular velocities. 

The total angular velocity is a vector addition of angular velocities associated to each one of Euler’s angles. Figure 1 shows that the angular velocity components based on a rotating system are:

ω1=ϕ̇sinθsinψ+θ̇cosψ,ω2=ϕ̇sinθcosψ-θ̇sinψ,ω3=ϕ̇cosθ+ψ̇. (3)

On the other hand, the torque exerted by gravitational force with respect to the fixed point, is given by a vector product between the center of mass position he^3, and the gyroscope weight -mge^z. This torque is a vector addressed to the nodes line and with components:

τ1=μsinθcosψ,τ2=-μsinθsinψ,τ3=0, (4)

where μ ≡ mgh is the maximum torque. In the case where this torque was the only contribution to torsion momentum of system (neglecting friction), then the products of e^3τ and e^zτ are nulls, so the components from the angular momentum L3 and Lz are constant of movement. These constants provide relations between variables, which in union with the energy conservation law, allows to determine values of the angular variables θ, ϕ and ψ as function of time. This procedure is equivalent to Lagrange’s method, it provides a solution in terms of elliptic functions 12. Even, though in this way an exact solution for the values of frequencies can be obtained, the relation between the oscillation amplitudes of θ and ϕ, which define a typical gyroscope movement, are not direct.

Although approximately, the direct solution of Euler’s equations gives an intuitive method to correctly describe the movement of a gyroscope. To find out such a solution, is advisable to work in the complex plane, so that we add the first equation from (2), to the second one which was previously multiplied by the imaginary number i; all this to obtain the following complex equation:

τ=-iωω3(I3-I1)+I1ω̇, (5)

with ττ1 + 2 and ωω1 + 2. From (3) and (4) is obtained for these complex quantities that τ = μ sin θe- and ω = Ωe- , where Ω ≡ (̇θ + i̇ϕ sin θ).By using these values on (5), and factorizing the exponential e- , the following expression appears:

μsinθ=iΩ(ϕ̇cosθI1-L3)+I1Ω̇. (6)

This is a differential equation on the real variables θ and ϕ, and can be expressed in terms of complex variable as

a=-itanθ2eiϕ. (7)

This variable corresponds to Riemann’s stereographic projection of a point on the sphere in the plane 13; here, the real part is directed to e^x, and the imaginary to e^y (see Fig. 2).

Figure 2 Variable a in the projective plane. 

By differentiating the expression (7) respect of time, we obtain

Ω=ȧasinθ, (8)

and

Ω̇=äa-ȧ2a2sinθ+ȧa(Ω-iϕ̇sinθ)cosθ. (9)

Replacing (8) and (9) on Eq. (6) the following equation shows up:

μa=I1ȧ2a(cosθ-1)-iL3ȧ+I1ä, (10)

here, according with (7), cosθ = (1-|a|2)/(1+|a|2). Equation (100), together with ̇L3 = τ3 are equivalent to Euler’s equations (2). This equation is a generalization to θ large for the gyroscope’s equation used in external ballistic 14.

2.2. Approximate Solution to the gyroscope’s equation

Equation (10) is not linear, of second order on the complex variable a, and is not analytic. The exact solution for this equation is not easy to find. However, an approximate solution for small nutation can be easily obtained. In this case the value of θ can be replaced, on first approximation, by the mean value θ0. After changing variables

s=-iȧa, (11)

Eq. (10) can be rewritten as:

iI1ṡ=I1s2cosθ0-L3s+μ. (12)

The roots of the right hand polinomy on (12) are given by

s±=L3±L32-4μI1cosθ02I1cosθ0α±β, (13)

which corresponds to the fast precession frequencies s+ and slow s-15. The differential Eq. (12) can be solved by separating variables followed by an integration using partial fractions, thus obtaining

s=α-iβcotx, (14)

where x = βt cosθ0 + c, being c a complex constant of integration. The imaginary part of c is the relevant quantity because the real part may be eliminated through a temporal translation. Having on mind the definition of s given in (11), the value for a is obtained after integrate and exponentiate (14)

a=A'eiαt(sinx)secθ0, (15)

where A' is a constant resulting from the integration. The function sin x is proportional to e-iβtcosθ0(1-e2ix), so a can be expressed as

a=Aei(α-β)t1-Bei2βtcosθ0secθ0, (16)

with A and B arbitrary constants. On the limit when B → 0 a slow precession solution for a is given, the case when B → ∞ (with AB finite) leads to a fast precession solution. Generally, precession turns out to be of lower frequency than nutation, therefore the solution for nutation of small amplitude corresponds to (16) with |B| ≪ 1. By making a binomial approximation of the term inside parenthesis in (16), we have

a=eiωptap+aneiωnt, (17)

where ωn and ωp are frequencies of nutation and precession respectively, given by

ωn= 2βcosθ0=L32-4μI1cosθ0I1, (18)

ωp= α-β=L3-L32-4μI1cosθ02I1cosθ0. (19)

Expression (17) implies that a is the sum of two rotating vectors of constant amplitude, |ap | and |an |, which spin with frequencies ωp and ωp + ωn respectively. Because of the fact that the amplitude of precession movement is greater than that of nutation, and its frequency is lower, the trajectory that vector a presents in a plane has a shape of rosette. On expression (18) ωn is defined positive, and from (19) can be seen that ωp has the same sign as μ. The rosette shape formed on the projection plane comes given by the relative sign between frequencies of precession and nutation, which means depends on the sign of μ. When the frequencies have the same sign (μ > 0) the projection created on the plane has the apices pointing inward, while if signs are opposite (μ < 0), the apices on the projection are going outward (See Fig. 3).

Figure 3 Graphic representation of the gyroscope solution, (a) for μ > 0 and (b) for μ < 0. ϕn y ϕp are the arguments of an and ap , respectively. 

The precession frequency does not diverge for θ 0 approaching = π/2, despite first appearances. In this limit is obtained ωp = μ/L 3, like the simple theoretical expression for precession frequency found in most elementary physics textbooks, and ωn = L 3/I 1. They also correspond to the expressions of frequency values on the limit of fast rotation L32μI1. If θ 0 is less than π/2 and μ > 0 then the precession frequency will be greater than μ/L3, while nutation smaller than L 3/I1. These relations are inverted for angles higher than π/2 or μ < 0. All of this can be sumarized in an expression coming from (19) at first order in rμI1/L32 given by

ωpμL3(1+rcosθ0). (20)

From Eqs. (19) and (18), can be found relations between precession and nutation frequencies which are independent of the state of movement, given by:

ωpcosθ0ωp+ωn= μI1, (21)

(2cosθ0ωp+ωn)ω3= I3I1. (22)

Given that ω3=ψ̇+ωpcosθ0, from expression (22) is obtained that the number of rotations per nutation Δn=ψ̇/ωn, in function of precession and nutation frequencies, and the azimuthal angle, is given by

Δn=I1I3+2I1I3-1ωpωncosθ0. (23)

This relation predicts that the number of rotations by nutation tends to the value I1/I3 for θ = π/2 or L3 large, but in general (23) has a linear behavior with respect to the parameter (ωp /ωn )cosθ0, where the slope and the axis intersection are determined by I1/I3.

Finally, to obtain the expressions of these angles as a function of time, solution (17) and definition (7) are equating, and considering |an /ap | ≪ 1 we got:

tanθ2=|ap|+|an|cos(ωnt+δ), (24)

and except a constant

ϕ=ωpt+|an/ap|sin(ωnt+δ), (25)

where δ is the argument of an /ap . From this last expression is evident that the mean value of the angular velocity ϕ is the precession velocity ωp , while for tanθ/2 is |ap |, what we make to coincide with tanθ0/2, having an relative uncertainty of order (|ap |/|an |)2.

Results aforementioned coincide with the Lagrangian description in the approximation of harmonic potential to first order in the parameter μI1/L32 15.

3. Experimental section

3.1. Experimental Assembly

With an experimental set up we looked for a corroboration of the gyroscope solution, Eq. (17), with its corresponding parameter values, fits in an exactly way to an experimental situation. For this experience was used a Pasco ME8960 gyroscope, it consist of a disk of 1.755 ± 0.001 kg mass with a radius of 12.7 ± 0.1 cm and a thickness of 2.0 ± 0.1 cm, which can spin around an axis with little friction, at the same time this axis may be orientated in any azimuthal direction but inside a range of 30° to 140° respect to the zenith. The orientable axis has a fixed point at 12.7 ± 0.1 cm from the disk, which is pivoted at 30.7 ± 0.1 cm from the floor over a vertical bar. This bar is nailed in the center of an A-shaped base of molten iron, and it can rotates around its own axis. At the opposite end of orientable axis, opposite to the disk, there is a counterweight that works to vary the position of the center of mass.

To visualize the a vector, a simple laser pointer device is set up in such a way that it remains on the same vertical plane than orientable axis, but presenting an angle with respect to the vertical equal to half of zenithal angle of the axis. This can be achieved by setting the pointer on the base of an isosceles triangle where one of its congruent sides aligns with the vertical bar and the other with the orientable axis, as showed in Fig. 4.

Figure 4 Laser assembly on the gyroscope. 

To have information about the angular velocity of rotation from the disk, an electric switch was installed to the pointer device so, it turns on during half of revolution cycle and then turns off on the other half. The switch was fixed by sticking a copper semi-disk to one of the faces of the spinning disk. The laser’s feeder circuit becomes closed only when two small brushes, in contact with the disk, also get in touch with the cooper semi-disk, thus the circuit is open every half revolution. (see Fig. 4).

In our case the laser light is projected upward over a horizontal screen 70 cm away from floor, which is formed by a framed fabric in a way that the luminous dot can be observed over the screen. A mirror just above the screen works as a guide of images from screen to the digital camera; the camera is installed in a tripod, on side of the mirror and pointing out to it, as can be seen in Fig. 5.

Figure 5 Experimental Assembly. 

By taking a photography of luminous dot in a time interval large enough is obtained a discontinuous light beam, each segment of the bright line along with the following dark interval, correspond to a disk rotation. Initially counterweights were set on the disk axis in a way that the center of mass will stay just on the pivoted point from orientable axis. Later, an additional counterweight, with a mass of 151.48 ± 0.01 g, was set on one of the orientable axis ends. Experiments with the counterweight on the same disk side at 21.0 ± 0.1 cm from pivoted point (forward) were made, and then with the counterweight on opposite side (backward) to 34.5 ± 0.1 since pivoted point. The counterweight mass value multiplied by the pivoted point distance and by the constant of gravity, accounts for the maximum torque μ to which the gyroscope is subjected. Given the laser pointer position, with an additional counterweight ahead, the rosette shape formed by the movement of the dot of light shows its apices outward; reciprocally, by adding the counterweight back, rosette’s apices point inward, as show Fig. 3.

3.2. Results

With the mass values of both, counterweights and disk, and taking into account their position, the calculation of values for the main inertia momentum and maximum torque, related to each situation of additional counterweight, is direct. These values are given by Table I.

Table I Values for inertia moment and maximum torque in both positions of additional counterweight. 

I1(g·m2) I3(g·m2) μ(g·m2/s2)
Counterweight forward 100 ± 1 13.3 ± 0.1 316 ± 1
Counterweight backward 112 ± 1 13.3 ± 0.1 512 ± 1

The disk was set up to spin around the orientable axis at a specific velocity ψ and certain value of θ0. The system was left to evolve and the trajectory of luminous dot was photographed, with a digital camera which has an aperture time control, inside a dark room. The camera was located above screen and by over the gyroscope, an exposure time of 10 seconds for each photo was set, also a green laser was used which is why the result of each photography is a dotted green line with a dark background. After inverting colors using an editor of images, pictures are seen as a red trace with white background.

From photographic records is obtained: an angular interval of a nutation Δϕ, the number of rotations per nutation Δn, the total number of rotations n, and the circumference diameters D1 and D2, intern and extern, tangent to the trajectory of luminous dot. The values of these diameters must be given using units of a reference diameter Dr, which is defined as the trajectory diameter of luminous dot when gyroscope precesses uniformly with θ = π/2. These measurements, along with the exposition time t, allow us to find the frequencies of rotation, precession and nutation, as well as the average value of zenithal angle, through next relations:

ωp=nΔϕtΔn,ωn=2πntΔn,ψ˙=2πnt,tanθ02=D1D2Dr.

Using these values, and according to (21) and (22), relations given by μ/I1 and I1/I3 can be calculated. 60 pictures of each counterweight, back and front, were analyzed. Figure 6 shows one example of each case, where the way how every measurement was obtained is described. The average values of these quantities are called experimental values; the associated uncertainty is the standard deviation of data, divided by square root of the amount of data. Theoretical data correspond to those obtained from Table I. The average values for μ/I1 and I1/I3, experimental and theoretical, are shown in Table II.

Figure 6 Pictures of the projection of gyroscope movement with inverted colors. Counterweight ahead and back respectively. 

Table II Theoretical and experimental values for μ/I1 and I1/I3

Forward Backward
μI1(s-2) I1I3 μI1(s-2) I1I3
Theoretical 3.16 ± 0.03 7.51 ± 0.07 4.57 ± 0.04 8.47 ± 0.08
Experimental 3.20 ± 0.03 7.42 ± 0.02 4.58 ± 0.02 8.53 ± 0.02

According to (23) the graphs of ωn in function of (ωp cosθ + ωn )-1, present a linear form with a slope of μ/I1.

Figure 7 shows the experimental results using counterweight back and then ahead. Solid lines represent theoretical values.

Figure 7 Experimental value of μ/I1 for experiments with counterweight ahead (light circles), and with it on back (dark circles). 

A kind of dispersion in values can be noticed; it possibly is because of a high value of the relative uncertainties on Δn. If it is only considered one nutation cycle, it shall an uncertainty of order 1/Δn, which, in our case is around 12%. In order to diminish the uncertainty, N cycles of nutation are taken, reducing the error in one factor of 1/N. However, for low velocities, N cannot be too large because the Δn variation per cycle of nutation will be significantly affected by friction, therefore on the beginning exists an insuperable limit on precision of measurements, determined by the disk friction.

Figure 8 shows experimental results for the number of rotation per nutation as a function of the relation between precession and nutation frequencies, multiplied by cosine of θ0. Solid lines represent theoretical values.

Figure 8 Relation between the number of revolutions per nutation cycle for the experiments with the counterweight ahead (light circles) and back (dark circles). 

Figure 9 shows the ratio between experimental precession speed ωp and the expected in the simplest model μ/L3, as a function of the parameter r=μI1/L32. The dotted line indicates the predicted value by the elementary model and the continuous line shows the predicted by the model for this work, according to the Eq. (20).

Figure 9 Relationship between experimental precession speed !p and its expected value μ/L3 in the simplest model, in function on the parameter r=μI1/L32, for both counterweight ahead and counterweight back 

For the data reported in Fig. 7, 8 and 9 the rotation frecuency was between 3 to 13 revolutions per second.

4. Summary

By using Riemann projections, Euler’s equations for a symmetric spinning top with a fixed point are solved, in an approximate way, when considering nutations of small amplitude. Under this approximation, the solution corresponds to the addition of two rotating vectors on the complex plane, and their velocities of rotation will define both velocities of precession and nutation for a spinning top.

The Riemann projection was visualized through an intermittent light of a laser. A photographic register of luminous dot projection allowed us to obtain in an easy and simple way, quantitative information of rotation, precession and nutation velocities, and the zenithal average angle of gyroscope; which may be expensive and complicated using different methods.

From the photographic record of laser dot trajectory on a horizontal plane, the parameters of movement for a total of 120 experiments were determined. Theoretical expressions are verified experimentally.

From the parameters obtained by photographic records, quantities μ/I1 and I3/I1 were found, and then were compared with the direct measurement of these on the mass distribution of gyroscope. Although there was some dispersion, the average on measurements is adjusted in a precise way with theoretical data.

Experimentally was shown that the number of rotations per nutation cycle is a lineal function of the relation between velocities of precession and nutation, and the average inclination angle of gyroscope axis. The slope and intercept with the axis coincide, inside the range of uncertainty, with the values predicted by the model.

The analysis made on this work does not considered the friction due to air viscosity, although the photographic registers evidence this effect; this is an indicator of the high level of sensibility in this experiment. Nevertheless, because relatively small intervals of time were taken, these effects were ignored.

REFERENCES

1. H. Goldstein, Charles Poole & John Safko, Classical Mechanics, third edition. (Addison Wesley 2002), pp. 208-221. [ Links ]

2. J.V. José and E.J. Saletan, Classical Dynamics: A Contemporary Approach. Cambridge University Press (1998), pp. 492-548. [ Links ]

3. J. Mahecha Goméz, Mecánica clásica avanzada, Ed. Universidad de Antioquia. (2006) pp. 295-310. [ Links ]

4. H. Soodak, Am. J. Phys. 70 (2002) 815. [ Links ]

5. A. Pliskin, Am. J. Phys. 22 (1954) 28-32. [ Links ]

6. R.J. Cohen, Am. J. Phys. 45 (1977) 12-17. [ Links ]

7. C.G. Gray and B. G. Nickel, Am. J. Phys. 68 (2000) 821. [ Links ]

8. L. Stefanini, Am. J. Phys. 47 (1979) 346-350. [ Links ]

9. The rise and fall of spinning tops Rod Cross, Am. J. Phys. 81 (2013) 280. [ Links ]

10. H. Goldstein , Charles Poole &John Safko , Classical Mechanics, third edition. (Addison Wesley 2002), pp. 199-200. [ Links ]

11. Daniel Kleppner & Robert J. Kolenkow, An Introduction to Mechanics. (McGraw-Hill Book Co. 1978), pp. 320-322. [ Links ]

12. E. Piña, On the motion of the symmetric Lagrange’s top, Rev. Mex. Fis. 39 (1993) 10-31. [ Links ]

13. J. W. Brown, R.V. Churchill, Complex Variable and Applications, seventh edition. Mc Graw Hill (2003). pp. 49-50. [ Links ]

14. Francisco Cucharelo Pérez, Balistica Exterior. (Ministerio de Defensa, Madrid, 1992), pp. 144-150. [ Links ]

15. K. Schonhammer, Am. J. Phys. 66 (1998) 1003. [ Links ]

Received: July 29, 2015; Accepted: November 23, 2015

Creative Commons License This is an open-access article distributed under the terms of the Creative Commons Attribution License