Tibial trial for joint arthroplasty

The invention claimed is: 1. A tibial trial, comprising: a base component; an articulating component; a rotary joint located between the base component and the articulating component to permit the articulating component to freely rotate relative to the base component; and at least one rotation sensor to measure rotational positions of the articulating component relative to the base component. 2. The tibial trial of claim 1 wherein said rotary joint connects said articulating component and said base component at their geometric centers. 3. The tibial trial of claim 1 wherein said rotary joint is rigidly fixed to the base component and to said articulating component to induce rotation on said rotary joint. 4. The tibial trial of claim 1 further comprising a plurality of articulating components that vary from one another in at least one parameter of size, shape, slope so as to assess a final tibial component size, flexion-extension gap, or ligament balancing. 5. The tibial trail of claim 1 further comprising a lock to lock said articulating component in an internal-external rotational position. 6. The tibial trial of claim 1 wherein said at least one rotational sensor comprises at least one of: a potentiometer, Hall Effect sensor, encoder, rotary variable differential transformer, or a resolver. 7. The tibial trial of claim 1 further comprising at least one processor to process a set of rotational position data supplied from said at least one rotational sensor. 8. The tibial trail of claim 1 further comprising at least one memory storage unit to store the rotational position data supplied from said at least one rotational sensor. 9. The tibial trail of claim 1 wherein said at least one rotation sensor provides rotational position data to a display located on said articulating component or on said base component. 10. The tibial trail of claim 1 wherein said articulating component further comprises an aperture and said base component further comprises a groove, said groove having a semi-circular or circular shape to correspond with a rotation of said aperture as said articulating component rotates relative to said base component. 11. The tibial trial of claim 1 wherein said base component further comprises at least one anchoring mechanism to attach said base component to a tibial plateau of a patient's tibia bone. 12. The tibial trial of claim 11 wherein said at least one anchoring mechanism has two protrusions from a lower surface of said base component, the two protrusions configured to fit into two complimentary holes formed on the tibial plateau of a tibia bone. 13. The tibial trial of claim 1 wherein said at least one rotational sensor provides rotational position data via a wired or a wireless connection to an external device. 14. The tibial trial of claim 13 wherein said external device comprises at least one of: a computer, a monitor, a computer assisted surgical device, an optical tracking system, a smart phone, a heads up display (HUD) unit, wearable display glasses and headgear, or any combination thereof. 15. The tibial trial of claim 13 wherein said wireless connection comprises at least one of Bluetooth, Internet connection, radiofrequency, electromagnetic, visible light, or infrared light. 16. The tibial trial of claim 13 further comprising one or more light emitting diodes (LEDs) to wirelessly transfer data to an external device. 17. The tibial trial of claim 1 further comprising a second rotary joint for adjusting an amount of tibial posterior slope between said base component and said articulating component. 18. The tibial trial of claim 17 wherein said second rotary joint further comprises at least one of: worm gears, hinges, screws, actuators, springs, bearings, ratchets, or step motors. 19. A method of using the tibial trial of claim 1 , said method comprising: measuring, with the rotation sensor, rotational positions of said articulating component relative to said base component as a knee joint is articulated in flexion-extension; and determining an optimum internal-external rotation of the articulating component relative to said base component based on the rotational measurements. 20. The method of claim 19 wherein a computer assisted device determines the optimum internal-external rotation and mills a keel hole or marks a position for a keel hole.