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According to one embodiment of the invention, a sports racket includes a racket frame comprising a head portion, handle portion and a throat portion joining the head portion to the handle portion. The racket frame also comprises a self-powered piezoelectric damping system for damping vibrations of t

According to one embodiment of the invention, a sports racket includes a racket frame comprising a head portion, handle portion and a throat portion joining the head portion to the handle portion. The racket frame also comprises a self-powered piezoelectric damping system for damping vibrations of the racket during play. The self-powered piezoelectric damping system comprises at least one transducer laminated to the racket and at least one circuit located within the racket handle portion and electrically connected to the at least one transducer.

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I claim: 1. A racket comprising: a racket frame comprising a racket handle portion orientated along a longitudinal axis of the racket, a racket head portion allowing for the attachment thereto of generally longitudinally directed strings and generally laterally directed strings to form a string bed

I claim: 1. A racket comprising: a racket frame comprising a racket handle portion orientated along a longitudinal axis of the racket, a racket head portion allowing for the attachment thereto of generally longitudinally directed strings and generally laterally directed strings to form a string bed of the racket, and a racket throat area joining the handle portion with the head portion; and a self-powered piezoelectric damping system comprising two transducer elements laminated to the racket frame and a first circuit located within the racket handle portion and electrically connected to the transducer elements by way of a Y-shaped flex circuit, the first circuit including at least one storage element configured to store electrical power extracted from the two transducer elements; wherein stored electrical power is transmitted back through the Y-shaped flex circuit to the transducers for conversion to mechanical power, the mechanical power being adapted to actively stiffen the racket; wherein the transducer elements each have a size of about 8 cm2 to about 16 cm2; and wherein electrical power derived from mechanical deformation of the racket is supplied back to the transducer elements, the transducer elements being mounted in a region of the racket where maximum deformation occurs. 2. The racket of claim 1, wherein at least one of the two transducer elements is located at the racket throat area. 3. The racket of claim 1, wherein at least one of the transducer element is electrically connected to the first circuit. 4. The racket of claim 1, wherein at least one of the transducer element is located at the racket throat area and electrically connected to the first circuit. 5. The racket of claim 1, wherein the racket further includes a protective coating covering at least one of the transducer elements. 6. The racket of claim 1, wherein the circuit is affixed to an end cap of the racket and the end cap is affixed to the racket handle portion. 7. The racket according to claim 1, wherein the transducer elements include piezoelectric fibers. 8. A racket comprising: a racket frame comprising a racket handle portion orientated along a longitudinal axis of the racket, a racket head portion allowing for the attachment thereto of generally longitudinally directed strings and generally laterally directed strings to form a string bed of the racket, and a racket throat area joining the handle portion with the head portion; a self-powered piezoelectric damping system comprising two transducer elements laminated to the racket frame and at least one first circuit located within the racket handle portion and electrically connected to the transducer elements by way of a Y-shaped flex circuit; and at least one storage element configured to store electrical power extracted from the two transducer elements, wherein the racket handle portion includes a slot in the racket handle portion and the first circuit is affixed within the slot; wherein stored electrical power is transmitted back through the Y-shaped flex circuit to the transducers for conversion to mechanical power, the mechanical power being adapted to actively stiffen the racket; wherein the transducer elements each have a size of about 8 cm2 to about 16 cm2; and wherein electrical power derived from mechanical deformation of the racket is supplied back to the transducer elements, the transducer elements being mounted in a region of the racket where maximum deformation occurs. 9. The racket of claim 8, wherein the slot extends completely through the racket handle portion. 10. The racket of claim 8, wherein the slot is at least partially filled with a foam to fix the circuit within the slot. 11. The racket of claim 8, wherein the circuit includes a circuit board and the circuit board is affixed to the racket handle portion. 12. The racket according to claim 8, wherein the transducer elements include piezoelectric fibers. 13. The racket of claim 8, wherein the racket further includes a protective coating covering at least one of the transducer elements. 14. A racket comprising: a racket frame comprising a racket handle portion orientated along a longitudinal axis of the racket, a racket head portion allowing for the attachment thereto of generally longitudinally directed strings and generally laterally directed strings to form a string bed of the racket, and a racket throat area joining the handle portion with the head portion; a self-powered piezoelectric damping system comprising two transducer elements and at least one first circuit located within the racket handle portion and electrically connected to the transducer elements by way of a Y-shaped flex circuit; and a storage element configured to store electrical power extracted from the two transducer elements; wherein electrical power derived from mechanical deformation of the racket is supplied back to the transducer elements, the transducer elements being mounted in a region of the racket where maximum deformation occurs; wherein the first circuit is located within a slot in the racket handle portion and electrically connected to the Y-shaped flex circuit to enable transmission of electrical power from within the slot, back through the Y-shaped flex circuit, and to the transducers for conversion to mechanical power, the mechanical cower being adapted to actively stiffen the racket. 15. The racket of claim 14, wherein at least one of the two transducer elements is located at the racket throat area. 16. The racket of claim 14, wherein at least one of the transducer element is electrically connected to the first circuit. 17. The racket of claim 14, wherein at least one of the transducer element is located at the racket throat area and electrically connected to the first circuit. 18. The racket of claim 14, wherein the racket further includes a protective coating covering at least one of the transducer elements. 19. The racket of claim 14, wherein the circuit is affixed to an end cap of the racket and the end cap is affixed to the racket handle portion. 20. The racket according to claim 14, wherein the transducer elements include piezoelectric fibers.