Title: Unifying uncertainties for rotor-like quantum systems

Abstract: Quantum rotor represents the second simplest model after the harmonic oscillator with profound interdisciplinary but yet unexplored implications. It overreaches its mechanical meaning with significant consequences and promising applications in, e.g., singular optics, super-conductive circuits with Josephson junction or optimal pulse shaping in time frequency domains at ultimate quantum limit. Quantification of complementarity between angular momentum and angular variable is essential for exploitation of this canonical pair in quantum metrology. Whereas the natural measures for position and momentum are variances, the uncertainty associated with angular variable can be linked to moments of inertia of the unit ring about axes passing through its center of mass. This interpretation provides variants for saturable uncertainty relations which can be further used in quantum metrology of the quantum rotor and explains ambiguities in choice of possible uncertainty measures associated with sine and cosine functions of angular variable. Special attention will be payed to uncertainty products which are exactly or approximately minimised by von Mises states, which play the role of squeezed states for quantum rotor and allow optimal detection of quantum states at the ultimate limits.