Method, device and system for measuring torsion or bending at a joint between two limbs

The invention claimed is: 1. A joint motion sensing device, for use on a joint connecting a first body part of a body and a second body part of the body to detect torsion or bending of the first and second body parts relative to each other at the joint, the device comprising an electrically conductive loop having a first, second and third loop part, the first loop part configured to run from the first body part to the second body part along a surface of the body at a first side of the joint, the second loop part configured to run over the second body part and the third loop part configured to run from the second body part back to the first body part along the surface of the body at a second side of the joint opposite the first side, the electrically conductive loop continuing from the first loop part into the second loop part and from there into the third loop part, forming at least a part of a loop area with the first, second and third loop part at a boundary of the loop area; an output unit coupled to the electrically conductive loop, for providing an output signal based on inductance of the electrically conductive loop; a transmitter coupled to the output unit, for sending an output signal that is representative for an output of the output unit to a receiver. 2. A device according to claim 1 , wherein the electrically conductive loop has a fourth loop part, configured to run over the first body part between the first and third loop part and from the first side of the joint to the second side of the joint, the electrically conductive loop continuing from the first and third loop part into the fourth loop part, the second and fourth loop parts configured to run over surface parts of the first and second body parts that face a same direction, so that the electrically conductive loop is configured to cover the surface of the body at the joint from the first side of the joint to the second side of the joint. 3. A device according to claim 2 , wherein the output unit is coupled to the electrically conductive loop, the output signal being a measure of a self inductance of the electrically conductive loop formed by the first, second, third and fourth loop parts, or of a plurality of serially connected electrically conductive loops with loop parts that run in parallel with the first, second, third and fourth loop parts. 4. A device according to claim 1 , wherein the electrically conductive loop has a fourth loop part, configured to run over the first body part between the first and third loop part, the electrically conductive loop continuing from the first and third loop part into the fourth loop part, the second and fourth loop parts configured to run over surface parts of the first and second body parts that face in mutually opposite directions, so that the electrically conductive loop is configured to have a combination of the body parts intersect the loop area once without returning through the loop area, whereby the combination of the body parts runs through the loop area, regardless of a degree of torsion or bending of the first and second body parts relative to each other at the joint. 5. A device of claim 4 , comprising a brace mountable over the joint, encircling both the first and second body parts, wherein the electrically conductive loop lies on a surface of said brace or within said surface, encircling an inner space defined by the brace for receiving the combination of the first and second body part. 6. A device of claim 4 , comprising a substrate that is configured to allow attachment to the first and second body parts, encircling both the first and second body parts, wherein the electrically conductive loop lies on a surface of said substrate or within said surface, encircling an inner space defined by the substrate for receiving the combination of the first and second body part. 7. A device according to claim 1 , comprising two accelerometers, configured for positioning on the first body part and on the second body part, respectively. 8. A device according to claim 1 , comprising a brace mountable over the joint attached to the first and second body parts, wherein the loop area lies on a surface of said brace or within said surface. 9. A system for detecting torsion or bending of a first body part and a second body part relative to each other, the system comprising the device of claim 1 and further comprising, a receiver for receiving the sent output signal, a memory for storing data, a processor for calculating the degree of torsion or bending of said body parts relative to each other. 10. A device according to claim 1 , comprising a substrate that is configured to allow attachment to the first and second body parts, wherein the loop area of the conductive loop lies on a surface of said substrate or within said surface. 11. A device according to claim 10 , wherein the substrate comprises a fabric, wherein the conductive loop is attached to or integrated in the fabric. 12. A method of measuring a degree of torsion or bending of a first body part and a second body part of a body relative to each other at a joint between the body parts, the method comprising attaching an electrically conductive loop to the body parts, the electrically conductive loop having a first, second and third loop part, the first loop part running from the first body part to the second body part along a surface of the body at a first side of the joint, the second loop part running over the second body part and the third loop part running from the second body part back to the first body part along the surface of the body at a second side of the joint opposite the first side, the electrically conductive loop continuing from the first loop part into the second loop part and from there into the third loop part, forming at least a part of a loop area with the first, second and third loop part at a boundary of the loop area; measuring an output signal that is a measure for an inductance of the electrically conductive loop during torsion or bending, relating said output signal of the sensor to a degree of torsion or bending by using calibration data. 13. A method according to claim 12 , wherein the electrically conductive loop has a fourth loop part, running over the first body part between the first and third loop part from a first side of the joint to a second side of the joint opposite the first side, the electrically conductive loop continuing from the first and third loop part into the fourth loop part, the second and fourth loop parts running over surface parts of the first and second body parts that face a same direction, so that the loop area covers the surface of the body at the joint from the first side of the joint to the second side of the joint. 14. A method according to claim 13 , wherein said measuring comprises generating an output signal that is a measure for a self inductance of the electrically conductive loop formed by the first, second, third and fourth loop parts. 15. A method according to claim 12 , wherein the electrically conductive loop has a fourth loop part, running over the first body part between the first and third loop part, the electrically conductive loop continuing from the first and third loop part into the fourth loop part, the second and fourth loop parts running over surface parts of the first and second body parts that face in mutually opposite directions, so that a combination of the body parts intersects the loop area once without returning through the loop area, whereby the combination of the body parts runs through the loop area, regardless of the degree of torsion or bending of the first and second body pa