Device for monitoring a shaft coupling coupling a first shaft to a second shaft

The invention claimed is: 1. A device for monitoring a shaft coupling coupling a first shaft to a second shaft, the device comprising: an optical unit comprising a receiving element designed to receive an electromagnetic radiation; and a modifying unit designed to modify a radiant energy impinging on the receiving element as the first shaft runs asynchronously with respect to the second shaft, said modifying unit comprising a holographic optical component designed for arrangement on and/or within the first shaft, and a diaphragm designed for arrangement on and/or within the second shaft and comprising radially arranged slots and radially arranged filled regions in an at least substantially regular sequence, said diaphragm comprising an at least substantially centrally arranged opening, wherein the holographic optical component is designed for illumination or irradiation with the electromagnetic radiation and generates a pattern having radially arranged areas with a first radiant energy and radially arranged areas with a second radiant energy in an at least substantially regular sequence. 2. The device of claim 1 , wherein the receiving element is embodied to receive light. 3. The device of claim 1 , wherein the electromagnetic radiation is coherent. 4. The device of claim 1 , wherein the pattern generated by the holographic optical component is generated by diffraction and/or refraction and/or reflection and/or interference of the electromagnetic radiation. 5. The device of claim 1 , wherein the receiving element is a photodiode. 6. The device of claim 1 , wherein the optical unit comprises an emission element designed to emit the electromagnetic radiation. 7. The device of claim 6 , wherein the emission element is designed to emit bundled electromagnetic radiation and/or to emit electromagnetic radiation with a constant wavefront. 8. The device of claim 6 , wherein the emission element is a laser diode. 9. The device of claim 1 , wherein the areas with the first radiant energy are capable of being shielded and/or shaded by the filled areas of the diaphragm. 10. The device of claim 1 , wherein the holographic optical component and the diaphragm are arranged such that the second radiant energy impinges on the receiving element as the first shaft runs asynchronously with respect to the second shaft. 11. The device of claim 1 , wherein the holographic optical component and the diaphragm are arranged such that the first radiant energy impinges on the receiving element at least partially as the first shaft runs asynchronously with respect to the second shaft. 12. A shaft coupling for coupling a first shaft to a second shaft, the shaft coupling comprising a device, said device comprising an optical unit comprising a receiving element designed to receive an electromagnetic radiation, and a modifying unit designed to modify a radiant energy impinging on the receiving element as the first shaft runs asynchronously with respect to the second shaft, said modifying unit comprising a holographic optical component designed for arrangement on and/or within the first shaft, and a diaphragm designed for arrangement on and/or within the second shaft and comprising radially arranged slots and radially arranged filled regions in an at least substantially regular sequence, said diaphragm comprising an at least substantially centrally arranged opening, wherein the holographic optical component is designed for illumination or irradiation with the electromagnetic radiation and generates a pattern having radially arranged areas with a first radiant energy and radially arranged areas with a second radiant energy in an at least substantially regular sequence. 13. The shaft coupling of claim 12 , wherein the receiving element is a photodiode. 14. The shaft coupling of claim 12 , wherein the optical unit comprises an emission element designed to emit the electromagnetic radiation. 15. The shaft coupling of claim 14 , wherein the emission element is a laser diode. 16. The shaft coupling of claim 12 , wherein the areas with the first radiant energy are capable of being shielded and/or shaded by the filled areas of the diaphragm. 17. The shaft coupling of claim 12 , wherein the holographic optical component and the diaphragm are arranged such that the second radiant energy impinges on the receiving element as the first shaft runs asynchronously with respect to the second shaft. 18. The shaft coupling of claim 12 , wherein the holographic optical component and the diaphragm are arranged such that the first radiant energy impinges on the receiving element at least partially as the first shaft runs asynchronously with respect to the second shaft. 19. A dynamoelectric rotary machine, comprising: a first shaft; a second shaft; a shaft coupling designed to couple the first shaft and the second shaft; and a device for monitoring the shaft coupling, said device comprising an optical unit comprising a receiving element designed to receive an electromagnetic radiation, and a modifying unit designed to modify a radiant energy impinging on the receiving element as the first shaft runs asynchronously with respect to the second shaft, said modifying unit comprising a holographic optical component designed for arrangement on and/or within the first shaft, and a diaphragm designed for arrangement on and/or within the second shaft and comprising radially arranged slots and radially arranged filled regions in an at least substantially regular sequence, said diaphragm comprising an at least substantially centrally arranged opening, wherein the holographic optical component is designed for illumination or irradiation with the electromagnetic radiation and generates a pattern having radially arranged areas with a first radiant energy and radially arranged areas with a second radiant energy in an at least substantially regular sequence. 20. The dynamo-electric rotary machine of claim 19 , wherein at least one of the first shaft and the second shaft is a hollow shaft.