Variable-geometry timepiece display mechanism with resilient hand

The invention claimed is: 1. A variable-geometry timepiece display mechanism comprising: at least one resilient hand which comprises a first drive pipe integral with a first end of a flexible strip, and a second drive pipe integral with another end of said flexible strip, and which comprises a display index or tip which, in an unstressed free state of said resilient hand wherein both said first pipe and said second pipe are not subjected to any stress and are remote from one another, is remote from said first pipe and from said second pipe, the operating position of said resilient hand being a stressed position where said first pipe and said second pipe are coaxial to one another about an output axis; first means for driving said first pipe about said output axis; and second means for driving said second pipe about said output axis, said first drive means and second drive means being arranged so as to deform said flexible strip, by varying the angular position of said second pipe relative to the angular position of said first pipe about said output axis, and so as to vary the radial position of said display index or tip relative to said output axis, wherein said first drive means and/or said second drive means comprise an accelerator or decelerator device, which is arranged such that it accelerates, or stabilizes the speed of, or slows down at least said first pipe and/or said second pipe over at least part of the angular travel thereof, which accelerator or decelerator device comprises a first shaped gear train and/or respectively a second shaped gear train, said first shaped gear train and said second shaped gear train being arranged such that they symmetrically control said first pipe and said second pipe, such that said flexible strip is symmetrical relative to a radial originating from said output axis and passing by way of said tip or index, over at least part of the angular travel of said resilient hand, and wherein said accelerator or decelerator device comprises: a first differential gear on the drive gear train of said first pipe, said first differential gear including a first protrusion, and a first cam having an internal opening in contact with the first protrusion to form an input of the first differential gear; and/or a second differential gear on the drive gear train of said second pipe, and said second differential gear including a second protrusion, and a second cam having an internal opening in contact with the second protrusion to form an input of said second differential gear. 2. The mechanism according to claim 1 , wherein said resilient hand comprises a plurality of flexible segments that are joined end-to-end at at least one tip, a first flexible segment thereof extends between said first pipe and a first tip forming said index, and said second pipe, wherein said display mechanism comprises an input wheel set, which is arranged so as to be driven such that it pivots about an input axis by a movement, and defining an input angle with a reference, and comprising said first means for driving said first pipe, and second means for stressing at least said first flexible segment, which are arranged so as to vary the position of at least said first tip relative to said output axis, said first tip being at a variable distance from said first pipe, as a function of the forces applied to said flexible strip by said second stressing means, wherein said second stressing means comprise said second means for driving said second pipe in an assembled and stressed state of said resilient hand in which both said first pipe is driven by said first drive means, and said second pipe is driven by said second drive means, wherein said first shaped gear train and said second shaped gear train are arranged such that they symmetrically control said first pipe and said second pipe, such that said first flexible segment and said second flexible segment are symmetrical relative to a radial originating from said output axis and passing by way of said tip at which said first flexible segment and said second flexible segment are joined, over at least part of the angular travel of said resilient hand. 3. The mechanism according to claim 2 , wherein said first drive means and said second stressing means are arranged so as to drive said resilient hand over the entirety of the angular travel thereof about said output axis, and provide it, in projection on a display plane or on a dial, and at different angular positions of said resilient hand, with at least one first shape in which said flexible segments comprised in said flexible strip do not cross paths outside of said first pipe, and at least one second shape in which said flexible segments comprised in said flexible strip cross paths outside of said first pipe. 4. The mechanism according to claim 3 , wherein said first shape is an almond shape, and said second shape is a heart shape. 5. The mechanism according to claim 2 , wherein in the free state, said resilient hand extends over as many parallel levels as there are said flexible segments, and is arranged such that it is mounted in a non-twisted manner in a stressed operating position wherein said first pipe and said second pipe are superimposed on one another. 6. The mechanism according to claim 2 , wherein in the free state, said resilient hand extends over a first planar level comprising said first pipe and over a second planar level comprising said second pipe, and comprises a connecting area between said first planar level and said second planar level at one said tip between a first flexible segment bearing said first pipe and a second flexible segment joined to said first flexible segment and bearing said second pipe, and wherein said resilient hand is arranged such that it is mounted in a non-twisted manner in a stressed operating position wherein said first pipe and said second pipe are superimposed on one another. 7. The mechanism according to claim 1 , wherein said hand is arranged such that it travels a total non-retrograde path and that, over said total path, the average speed of said first pipe is equal to the average speed of said second pipe. 8. The mechanism according to claim 1 , wherein said first drive means and/or said second drive means comprise at least one first gear train stage and one second gear train stage, arranged such that each controls a part of the shape transformation of said resilient hand over part of the angular travel thereof, with distribution per stage. 9. The mechanism according to claim 8 , further comprising: at least one said stage, said first cam between an input wheel set arranged so as to be driven by a movement and said first pipe, said first cam being arranged such that it controls said first differential gear, a first input thereof is formed by said input wheel set, a second input thereof is a wheel set or a rack controlled by said first cam, and the output thereof gears with the gear train for transmitting the movement to said first pipe. 10. The mechanism according to claim 9 , wherein said first cam is a single cam between said input wheel set and said first pipe, at the level of at least one said stage, the single cam being arranged such that it controls said first differential gear, said first input thereof is formed by said input wheel set, said second input thereof is a first rack controlled by said first cam, and the output thereof gears with the gear train for transmitting the movement to said first pipe, and between said input wheel set and said second pipe, said single cam being arranged such that it controls said second differential gear, a first input thereof is formed by said input wheel set, a second input thereof is a second rack controlled by said first cam, and the o