Method, system, and transceiver device for bi-directionally transmitting digital optical signals over an optical transmission link

The invention claimed is: 1. A method for bi-directionally transmitting digital optical signals over an optical transmission link, the method including: (a) supplying a first optical transmit signal at a predetermined optical wavelength to a first end of the optical transmission link and transmitting the first optical transmit signal in a first transmission direction to a second end of the optical transmission link, the first optical transmit signal being created according to a non-return-to-zero first binary digital signal and comprising an optical bit-interleaved seeding signal having a symbol rate equal to a bit rate of the first binary digital signal and wherein the symbol interval of the optical bit-interleaved seeding signal is divided into two equally long sub-intervals, the bit information of the first binary digital signal being transported in a first of the two sub-intervals and the second sub-intervals being set to a seeding level with respect to optical power of the first optical transmit signal; and (b) supplying a second optical transmit signal at the predetermined optical wavelength to the second end of the optical transmission link and transmitting the second optical transmit signal in a second transmission direction to the first end of the optical transmission link, the second optical transmit signal being created by creating an optical wavelength reuse signal using the first optical transmit signal received at the second end of the optical transmission link, the optical wavelength reuse signal being modulated according to a second digital signal in such a way that the bit information of the second digital signal is included in the second sub-intervals of the symbol interval of the first optical transmit signal. 2. The method of claim 1 further including: (a) converting the first binary digital signal into a binary bit-interleaved digital signal having twice the bit rate of the first binary digital signal by dividing each bit interval into two equally long sub-intervals, setting one sub-interval to the signal value of the first binary digital signal and setting the respective other sub-interval to the logical 1 value of the first binary digital signal; (b) pre-coding the first binary digital signal and duobinary encoding the pre-coded binary bit-interleaved digital signal; and (c) modulating an optical light source having the predetermined optical wavelength using the pre-coded and encoded binary bit-interleaved digital signal as modulating signal. 3. The method of claim 2 wherein the duobinary optical bit-interleaved seeding signal is a ternary optical signal with respect to the electric field of the signal and a binary digital signal with respect to the optical power of the signal, and is created by using an optical modulator device which converts the modulating signal into the optical bit-interleaved seeding signal in such a way that the extreme values of the modulating signal correspond to +E and −E and the intermediate value of the modulating signal corresponds to 0, wherein +E, 0 and −E designates the amplitude of the electric vector of the optical bit-interleaved seeding signal. 4. The method of claim 1 further including: (a) pre-coding the first binary digital signal and duobinary encoding the pre-coded first binary digital signal; (b) low-pass filtering the pre-coded and duobinary encoded first binary digital signal in such a way that the filtered pre-coded and duobinary encoded first binary digital signal assumes in each transition between its extreme values a value which essentially equals the average value of the extreme values at points in time which essentially define a quarter of the bit interval; and (c) modulating an optical light source having the predetermined optical wavelength using the low-pass filtered pre-coded and encoded first binary digital signal as modulation signal. 5. The method of claim 4 wherein the duobinary optical bit-interleaved seeding signal is a ternary optical signal with respect to the electric field of the signal and a binary digital signal with respect to the optical power of the signal, and is created by using an optical modulator device which converts the modulating signal into the optical bit-interleaved seeding signal in such a way that the extreme values of the modulating signal correspond to +E and −E and the intermediate value of the modulating signal corresponds to 0, wherein +E, 0 and −E designates the amplitude of the electric vector of the optical bit-interleaved seeding signal. 6. The method claim 1 further including dividing the optical bit-interleaved seeding signal received at the second end of the transmission link, with respect to the optical power of the signal, into an optical receive signal and an optical branch-off signal, and receiving the first binary digital signal by detecting the optical power during the first of the two sub-intervals using an integrate-and-dump receiver. 7. The method of claim 6 further including applying a reflective modulator device to the optical branch-off signal to create the optical wavelength reuse signal. 8. The method of claim 1 wherein the second sub-intervals of the optical wavelength reuse signal are amplitude-modulated. 9. The method of claim 8 wherein the second digital signal is an NRZ or RZ signal. 10. An optical data transmission system for bi-directionally transmitting digital optical signals over an optical transmission link, the optical data transmission system including: (a) a first optical transceiver device configured to be connected to a first end of the optical transmission link and adapted to, (i) to create a first optical transmit signal at a predetermined optical wavelength and supply the first optical transmit signal to a first end of the optical transmission link for transmission in a first transmission direction to a second end of the optical transmission link, the first optical transmit signal being created according to a non-return-to-zero first binary digital signal and comprising an optical bit-interleaved seeding signal having a symbol rate equal to a bit rate of the first binary digital signal and wherein the symbol interval of the optical bit-interleaved seeding signal is divided into two equally long sub-intervals, the bit information of the first binary digital signal being transported in a first of the two sub-intervals and the second sub-intervals being set to a seeding level with respect to optical power of the first optical transmit signal, and (ii) to receive a second optical transmit signal at the predetermined optical wavelength which is supplied to the second end of the optical transmission link and transmitted in a second opposite transmission direction to the first end of the optical transmission link; and (b) a second optical transceiver device configured to be connected to the second end of the optical transmission link and adapted to, (i) receive the first optical transmit signal and to detect the information included in the first sub-intervals of the symbol interval thereof, and (ii) create a second optical transmit signal at the predetermined optical wavelength and supply the second optical transmit signal to the second end of the optical transmission link for transmission in a second transmission direction to the first end of the optical transmission link, the second optical transmit signal being created by creating an optical wavelength reuse signal using the first optical transmit signal received at the second end of the optical transmission link, the optical wavelength reuse signal being modulated according to a second digital signal in such a way that the bit information of the second digital signal is included in the second sub-intervals of the symbo