Method and device for reducing mode instability in an optical waveguide

The invention claimed is: 1. Optical waveguide for high-performance operation to execute a method for reducing mode instability in the optical waveguide via reducing temperature variation along the optical waveguide and/or reducing changes in the optical waveguide that are caused by spatial temperature variation as a result of mode interference, the optical waveguide comprising an active coupler element for controlling the coupling of an input signal into the optical waveguide. 2. Amplifier device for executing a method for reducing mode instability in an optical waveguide via reducing temperature variation along the optical waveguide and/or reducing changes in the optical waveguide that are caused by spatial temperature variation as a result of mode interference, with the amplifier device being comprised of a beam splitter, an optical amplifier element and at least one optical pumping unit, and with the beam splitter splitting an input signal into two light signals, wherein one light signal each is coupled-in at one end each of the amplifier element. 3. Optical waveguide for high-performance operation to execute a method for reducing mode instability in the optical waveguide via reducing temperature variation along the optical waveguide and/or reducing changes in the optical waveguide that are caused by spatial temperature variation as a result of mode interference, the optical waveguide having a refractive index configured variable over the length of the optical waveguide and/or variable over the cross-section of the optical waveguide. 4. Optical waveguide for high-performance operation to execute a method for reducing mode instability in the optical waveguide via reducing temperature variation along the optical waveguide and/or reducing changes in the optical waveguide that are caused by spatial temperature variation as a result of mode interference, the optical waveguide having a tapered outer circumference or a variable surface ratio of a signal core versus a shell. 5. Optical waveguide for high-performance operation to execute a method for reducing mode instability in the optical waveguide via reducing temperature variation along the optical waveguide and/or reducing changes in the optical waveguide that are caused by spatial temperature variation as a result of mode interference, wherein the optical waveguide viewed in its cross-section is comprised of at least two differently endowed ranges, a first range being a passive core in the surrounding of a second range of an active core of the optical waveguide, and with an output signal of the active core being completely or partly capable of being coupled into the passive core, in such a manner that the direction of propagation in the passive core is anti-parallel to the direction of propagation in the active core. 6. Optical waveguide for high-performance operation to execute a method for reducing mode instability in the optical waveguide via reducing temperature variation along the optical waveguide and/or reducing changes in the optical waveguide that are caused by spatial temperature variation as a result of mode interference, the optical waveguide comprising a temperature control element for cooling and/or heating along the optical waveguide. 7. Optical waveguide according to claim 6 , wherein the optical waveguide viewed in its cross-section is comprised of at least two differently endowed ranges. 8. Optical waveguide according to claim 7 , with an endowed range being variably configured over the length of the optical waveguide. 9. Optical waveguide according to claim 7 , reducing a disparity of a signal overlap with an endowed range via a period of a mode floatation by modifying the geometry of the differently endowed ranges and/or by modifying the geometry of the optical waveguide. 10. Optical waveguide according to claim 6 , with the temperature control element being provided with at least one heating element and/or one cooling element along the optical waveguide to generate a variable course of temperature along the optical waveguide. 11. Optical waveguide according to claim 6 , further comprising at least one actuator to generate oscillations in the optical waveguide. 12. Optical waveguide according to claim 6 , the optical waveguide being formed from a sapphire material. 13. Optical waveguide according to claim 6 , further comprising absorption elements. 14. Optical waveguide according to claim 13 , with the absorption elements having an absorption spectrum in the range of one wavelength of the light signal. 15. Optical waveguide according to claim 13 , the absorption elements having an absorption spectrum in the range of one wavelength of an optical pumping signal. 16. Optical waveguide according to claim 6 , with a basic mode and at least one higher order mode of the light signal having a defined wave propagation in the optical waveguide. 17. Optical waveguide according to claim 16 , only radial-symmetrical modes propagating in the optical waveguide and/or only radial-symmetrical modes having an overlap with the basic mode. 18. Optical waveguide for high-performance operation to execute a method for reducing mode instability in the optical waveguide via reducing temperature variation along the optical waveguide and/or reducing changes in the optical waveguide that are caused by spatial temperature variation as a result of mode interference, wherein the optical waveguide is configured to cause a basic mode and at least one higher order mode of a light signal guided by the optical waveguide to have a defined wave propagation, and wherein an effective refractive index in the optical waveguide for the basic mode is approximately identical to an effective refractive index for a higher order mode and/or with the basic mode propagating with a polarization orthogonally to the polarization of the higher order mode.