Touch screen stylus with force and/or angle sensing functionality

What is claimed is: 1. A handheld stylus, comprising: a handheld body; an outer ring coupled to or integral with the body; a tip arranged radially inside of the outer ring and spaced apart from the outer ring to be movable with respect to the outer ring, the tip being movably coupled to the body such that the tip is movable relative to the outer ring and in an axial direction in response to forces applied to the tip; and a plurality of capacitive sensors defined between the outer ring and the tip, the plurality of capacitive sensors arranged in two rows spaced apart from each other in the axial direction, each of the plurality of capacitive sensors configured to detect a respective capacitance during an interaction between the handheld stylus and a display device; and a processor configured to: calculate, based on the respective capacitances detected by the plurality of capacitive sensors arranged spaced apart from each other in the axial direction, relative movements between the tip and the outer ring along the axial direction resulting from forces applied to the tip; calculate, based on the respective capacitances detected by the plurality of capacitive sensors, stylus state data including at least one of (a) an angle of the stylus relative to the display device or (b) a magnitude of force on the stylus tip; and communicate the calculated stylus state data to the display device to control a visual parameter of markings generated on the display device based on the calculated stylus state data. 2. The handheld stylus of claim 1 , comprising: at least one first conductive element secured to or integral with the outer ring and located at least partially around a circumference of the ring; a plurality of second conductive elements secured to or integral with the movable tip and located at least partially around a circumference of the tip and being arranged in two rows spaced apart in the axial direction; wherein the tip is arranged such that the at least one first conductive element and the plurality of second conductive elements are spaced apart from each other; wherein the plurality of capacitive sensors are formed by the at least one first conductive elements and the plurality of second conductive elements, respectively; and wherein the plurality of capacitive sensors is configured to detect a plurality of respective capacitance values representing changes in respective distances between the at least one first conductive element and the plurality of second conductive elements, respectively caused by movement of the tip relative to the body. 3. The handheld stylus of claim 1 , comprising: at least one first conductive element secured to or integral with the tip and located at least partially around a circumference of the tip; a plurality of second conductive elements secured to or integral with around the outer ring and located in two rows at least partially around a circumference of the outer ring; wherein the tip is arranged such that the at least one first conductive element and the plurality of second conductive elements are spaced apart from each other; wherein the plurality of capacitive sensors are formed by the at least one first conductive element and the plurality of second conductive elements, respectively; wherein the at least first conductive element extends from a center between the two rows in the axial direction towards the first row less than the plurality of second conductive elements of the first row and in direction towards the second row less than the plurality of second conductive elements of the second row, and wherein the plurality of capacitive sensors is configured to detect a plurality of respective capacitance values representing changes in respective distances between the at least one first conductive element and the plurality of second conductive elements, respectively caused by movement of the tip relative to the body. 4. The handheld stylus of claim 3 , wherein the first conductive element is a single first conductive element extending at least partially around the circumference of the tip or the inner surface of the outer ring. 5. The handheld stylus of claim 3 , wherein a single first conductive element is coupled through a switch with ground. 6. The handheld stylus of claim 1 , wherein the plurality of capacitive sensors is configured to detect the axial movements of the tip. 7. The handheld stylus of claim 1 , wherein the tip is movably coupled to the body through a flexible rod which allows movement of the tip along the axial direction, and wherein changes in the plurality of respective capacitances detected by the plurality of sensors of the first and second row are used to form a capacitive force sensor to detect the axial movements of the tip. 8. The handheld stylus of claim 1 , wherein the control electronics are configured to generate signals for controlling a width of a line generated on the display device based on the signals received from the plurality of capacitive sensors. 9. The handheld stylus of claim 1 , wherein the control electronics are configured to generate signals for controlling a color or shade of a line generated on the display device based on the signals received from the plurality of capacitive sensors. 10. The handheld stylus of claim 1 , comprising: electronics configured to generate data signals based on signals received from the plurality of capacitive sensors during an interaction between the stylus and a display device; and a communication system integrated into the stylus and configured to communicate the data signals to the display device in real time. 11. The handheld stylus of claim 10 , wherein the integrated communication system of the stylus is configured to communicate the data signals to the display device by controlling a capacitive coupling between the stylus tip and the display device. 12. A handheld stylus, comprising: a handheld body; an outer ring coupled to integral with the body; a tip arranged within, and spaced apart from, the outer ring, the tip being movably coupled to the body such that the tip is movable relative to the outer ring in response to forces applied to the tip; and a plurality of capacitive sensors defined between the outer ring and the tip, the plurality of sensors arranged spaced apart from each other in an axial direction, each of the plurality of capacitive sensors configured to detect a respective capacitance during an interaction between the handheld stylus and a display device; and a processor configured to: calculate, based on the respective capacitances detected by the plurality of capacitive sensors arranged spaced apart from each other in the axial direction, relative movements between the tip and the outer ring along the axial direction resulting from forces applied to the tip; calculate, based on the respective capacitances detected by the plurality of capacitive sensors, stylus state data including at least one of (a) an angle of the stylus relative to the display device or (b) a magnitude of force on the stylus tip; and communicate the calculated stylus state data to the display device for controlling a visual parameter of markings generated on the display device based on the calculated stylus state data. 13. The handheld stylus of claim 12 , comprising an elongated member having a first end secured to the body and a second end coupled to the tip, the elongated member configured to flex in response to the forces applied to the tip. 14. The handheld stylus of claim 12 , wherein the tip comprises a deformable form element. 15. The handheld stylus of claim 12 , wherein the