Method for fixing a fiber having a fiber Bragg grating sensor segment onto a component and bearing device with such a fiber

What is claimed is: 1. A method for fixing a fiber having a plurality of fiber Bragg grating sensor segments onto a bearing configured to undergo changes in strain and/or temperature, comprising the steps of: i) providing the bearing which has a circumferential outer surface, the circumferential outer surface defining a groove therearound, ii) stretching each of a plurality of sections of the fiber such that each of the plurality of sections forms a separate one of the plurality of fiber Bragg grating sensor segments by a defined and calibrated preload into a preloaded condition, iii) fixing each of the plurality of sections of the fiber while in the preloaded condition on a separate one of a plurality of carrier elements such that each of the plurality of fiber Bragg grating sensor segments is on a separate carrier element, each of the plurality of carrier elements comprising a one-piece element of uniform plate shape as taken along the circumferential outer surface of the bearing, iv) fixing each of the plurality of carrier elements onto the bearing in a spaced apart fashion therealong such that each of the plurality of carrier elements is separate from the other of the plurality of carrier elements, each of the plurality of carrier elements having a concave inner surface located radially inwardly from the circumferential outer surface of the bearing such that each of the plurality of carrier elements is at least partially located within the groove. 2. The method according to claim 1 , wherein in step iii) the fixing of each of the plurality of sections of the fiber on one of the plurality of carrier elements is carried out by gluing and/or mechanical interlocking and/or fitting and/or wherein in step iv) the fixing of each of the plurality of carrier elements onto the bearing is carried out by gluing or welding. 3. The method according to claim 1 , wherein in step iii) the fixing of each of the plurality of sections of the fiber while in the preloaded condition on a separate one of the plurality of carrier elements further comprises each of the plurality of carrier elements being made from a metal material. 4. The method according to claim 1 , wherein in step iii) the fixing of each each of the plurality of sections of the fiber while in the preloaded condition on a separate one of the plurality of carrier elements further comprises each of the plurality of carrier elements having, when viewed in cross section, a rectilinear shape. 5. The method according to claim 1 , wherein in step iv) the fixing of each of the plurality of carrier elements onto the bearing further comprises fixing a concave surface of each of the plurality of carrier elements to a convex outer surface of the bearing. 6. The method according to claim 1 , wherein in step ii) the stretching of each of the plurality of sections of the fiber further comprises a length of each of the plurality of fiber Bragg grating sensor segments being less than ten millimeters (10 mm). 7. The method according to claim 1 , wherein in step ii) the stretching of each of the plurality of sections of the fiber further comprises a length of each of the plurality of fiber Bragg grating sensor segments being two millimeters (2 mm). 8. A bearing arrangement comprising: a bearing ring comprising a circumferential outer surface, the circumferential outer surface defining a groove therearound, and a sensor arrangement, wherein the sensor arrangement includes a fiber having a plurality of fiber sections each including one of a plurality of fiber Bragg grating sensor segments, a plurality of carrier elements, each of the plurality of carrier elements comprising a one-piece element of uniform plate shape as taken along the circumferential outer surface of the bearing ring, and wherein each of the plurality of fiber sections is fixed in a defined and preloaded condition on a separate one of the plurality of carrier elements, wherein the sensor arrangement is fixed to the bearing ring by fixing each of the plurality of carrier elements onto the bearing ring, wherein each of the plurality of carrier elements has a concave inner surface located radially inwardly from the circumferential outer surface of the bearing ring such that each of the plurality of carrier elements is at least partially located within the groove, and wherein each of the plurality of carrier elements is discretely spaced such that each of the plurality of fiber Bragg grating sensor segments is on a separate one of the plurality of carrier elements and such that each of the plurality of carrier elements is separate from the other of the plurality of carrier elements. 9. The bearing arrangement according to claim 8 , wherein each of the plurality of carrier elements is made from a metal material. 10. The bearing arrangement according to claim 8 , wherein each of the plurality of carrier elements has, when viewed in cross section, a rectilinear shape. 11. The bearing arrangement according to claim 8 , wherein each of the plurality of carrier elements provides a concave surface corresponding to a convex outer surface of the bearing ring, wherein each of the plurality of carrier elements is fixed with its concave surface onto the convex outer surface of the bearing ring. 12. The bearing arrangement according to claim 8 , wherein a length of each of the plurality of fiber Bragg grating sensor segments is less than ten millimeters (10 mm). 13. The bearing arrangement according to claim 12 , wherein the length of each of the plurality of fiber Bragg grating sensor segments is two millimeters (2 mm).