Identity channel

Template:Expert-subject The tennis racket theorem is a result in classical mechanics describing movement of a rigid body with three distinct angular momenta. It also dubbed Dzhanibekov effect named after Russian astronaut Vladimir Dzhanibekov who discovered the theorem's consequences while in space in 1985.^[1]

Qualitative Proof

The tennis racket theorem can be qualitatively analysed with the help of Euler's equations.

Under torque free conditions, they take the following form:

${\displaystyle \begin{array}{rl}{I}_1{\dot{\omega }}_1& =(I_2-I_3){\omega }_2{\omega }_3\text{(1)}\\ I_2{\dot{\omega }}_2& =(I_3-I_1){\omega }_3{\omega }_1\text{(2)}\\ I_3{\dot{\omega }}_3& =(I_1-I_2){\omega }_1{\omega }_2\text{(3)}\end{array}}$

Let ${\displaystyle I_1>I_2>I_3}$

Consider the situation when the object is rotating about axis with moment of inertia ${\displaystyle I_1}$. To determine the nature of equilibrium, assume small initial angular velocities along the other two axes. As a result, according to equation (1), ${\displaystyle {\dot{\omega }}_1}$ is very small. Therefore the time dependence of ${\displaystyle {\omega }_1}$ may be neglected.

Now, differentiating equation (2) and substituting ${\displaystyle {\dot{\omega }}_3}$ from equation (3),

${\displaystyle \begin{array}{rl}{I}_2{I}_3{\ddot{\omega }}_2& =(I_3-I_1)(I_1-I_2){\omega }_1{\omega }_2\\ \text{i.e.}{\ddot{\omega }}_2& =\text{(negative quantity)}\times {\omega }_2\end{array}}$

Note that ${\displaystyle {\omega }_2}$ is being opposed and so rotation around this axis is stable for the object.

Similar reasoning also gives that rotation around axis with moment of inertia ${\displaystyle I_3}$ is also stable.

Now apply the same thing to axis with moment of inertia ${\displaystyle I_2}$. This time ${\displaystyle {\dot{\omega }}_2}$ is very small. Therefore the time dependence of ${\displaystyle {\omega }_2}$ may be neglected.

Now, differentiating equation (1) and substituting ${\displaystyle {\dot{\omega }}_3}$ from equation (3),

${\displaystyle \begin{array}{rl}{I}_1{I}_3{\ddot{\omega }}_1& =(I_2-I_3)(I_1-I_2){\omega }_1{\omega }_2\\ \text{i.e.}{\ddot{\omega }}_1& =\text{(positive quantity)}\times {\omega }_1\end{array}}$

Note that ${\displaystyle {\omega }_1}$ is not opposed and so rotation around this axis is unstable. Therefore even a small disturbance along other axes causes the object to 'flip'.

See also

• Euler angles
• Moment of inertia
• Poinsot's ellipsoid
• Polhode

References

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• Mark S. Ashbaugh, Carmen C. Chicone and Richard H. Cushman, The Twisting Tennis Racket, Journal of Dynamics and Differential Equations, Volume 3, Number 1, 67-85 (1991).
• Dzhanibekov effect video demonstrated on the International Space Station

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