Method and device for creating a control channel in an optical transmission signal and method and device for extracting the information included therein

The invention claimed is: 1. A method for creating a control channel in an optical transmission signal, (a) wherein the optical transmission signal comprises an optical carrier frequency component, a higher frequency modulation component carrying user information to be transported from a first end to a second end of an optical transmission link and a lower frequency modulation component carrying control information, the higher frequency modulation component realizing a user channel and the lower frequency modulation component realizing the control channel, (b) wherein the lower frequency modulation component is created by amplitude modulation, and (c) wherein the lower frequency modulation component is created by using a binary digital modulation scheme and a binary digital modulation signal in such a way that the lower frequency modulation component comprises a binary digital pilot tone signal component corresponding to a pilot tone signal having a predetermined pilot tone frequency. 2. The method according to claim 1 , comprising creating the binary digital pilot tone signal component by an amplitude pulse density modulation. 3. The method according to claim 1 , comprising creating the pilot tone signal component is created for a predetermined time interval. 4. The method according to claim 1 , wherein the lower frequency modulation component further comprises a binary digital control signal component using a binary digital modulation scheme. 5. The method according to claim 4 , wherein the binary digital pilot tone signal component and the binary digital control signal component are time-division multiplexed. 6. The method according to claim 1 , wherein the higher frequency modulation component carrying user information is a high bit-rate digital signal, wherein the bit rate of the high bit rate digital signals exceeds the bit rate of a binary digital control signal component by such an amount that the cross talk is essentially zero or at least lower than a predetermined threshold. 7. The method according to claim 1 , comprising creating the pilot tone signal component at a constant bit rate, which is chosen in such a way that at least a predetermined number of bits exists per period of the pilot tone. 8. A method for extracting information transported in a control channel of an optical transmission signal according to claim 1 , comprising receiving and converting the optical transmission signal into an electrical transmission signal and applying a Fast Fourier Transform analysis to extract the frequency and/or the absolute or relative amplitude of the pilot tone. 9. A device for creating a control channel in an optical transmission signal, comprising an optical transmitter device and a controller device configured to control the optical transmitter device, wherein the controller device is configured to create a modulation signal supplied to the optical transmitter device, and wherein the optical transmitter device is configured to create an optical transmission signal comprising an optical carrier frequency component, a higher frequency modulation component carrying user information to be transported from a first end of an optical transmission link to a second end of an optical transmission link and a lower frequency modulation component carrying control information, the higher frequency modulation component realizing a user channel and the lower frequency modulation component realizing a control channel, and wherein that the controller device is configured to create the modulation signal in the form of a binary digital modulation signal using a binary digital modulation scheme and wherein that the optical transmitter device is configured to create the lower frequency modulation component according to the binary digital modulation signal by amplitude-modulating an optical carrier signal or a modulated optical carrier signal, and, wherein the controller device and the optical transmitter device are configured in such a way, that the lower frequency modulation component is created in such a way that the lower frequency modulation component comprises a binary digital pilot tone signal component corresponding to a pilot tone signal having a predetermined pilot tone frequency. 10. The device according to claim 9 , wherein the controller comprises or is configured to receive or determine at least one data pattern for creating the binary digital modulation signal in such a way that the binary digital pilot tone signal component corresponds to a predetermined pilot tone frequency. 11. The device according to claim 9 , wherein the binary digital modulation signal component is a pulse density modulation signal. 12. The device according to claim 9 , wherein the optical transmitter device is configured to add the binary digital modulation signal to a data signal comprising the user information to be transported in the higher frequency modulation component and using the resulting sum signal as a modulation signal supplied to an optical transmitter comprised by the optical transmitter device. 13. The device according to claim 9 , wherein the optical transmitter device comprises an optical amplifier and that the binary digital modulation signal is supplied to a gain port of the optical amplifier for creating the binary digital pilot tone signal component or a binary digital control signal component. 14. The device according to claim 9 , wherein the control device is configured to create the modulation signal in such a way that the control channel is established. 15. A device for extracting the information transported in a control channel of an optical transmission signal, wherein the optical transmission signal comprises an optical carrier frequency component, a higher frequency modulation component carrying user information to be transported from a first end to a second end of an optical transmission link and a lower frequency modulation component carrying control information, the higher frequency modulation component realizing a user channel and the lower frequency modulation component realizing the control channel, wherein the lower frequency modulation component is created by amplitude modulation, wherein the lower frequency modulation component is created using a binary digital modulation scheme and a binary digital modulation signal in such a way that the lower frequency modulation component comprises a binary digital pilot tone signal component corresponding to a pilot tone signal having a predetermined pilot tone frequency, and, wherein the optical transmission signal is received and converted into an electrical receive signal by an optical receiver of an optical receiver device and that a Fast Fourier Transform analysis is applied onto the electrical receive signal by a receiver control unit of the optical receiver device in order to determine the frequency and/or the absolute or relative amplitude of the pilot tone. 16. The method according to claim 4 , wherein the lower frequency modulation component further comprises a binary digital control signal component using a binary digital modulation scheme identical to a binary modulation scheme for creating the binary digital pilot tone signal component. 17. The method according to claim 7 , wherein the predetermined number of bits is 10. 18. The method according to claim 7 , wherein the predetermined number of bits is 25. 19. The method according to claim 6 , wherein the cross talk is at least lower than the predetermined threshold by a factor of at least 100. 20. The method