RU2001105929A - METHOD AND DEVICE FOR REDUCING INTERFERENCE IN THE CDMA OPTICAL SYSTEM - Google Patents

Claims (17)

1. An optical communication system comprising a plurality of light sources 142, a plurality of data sources 146 providing multiple data streams, a plurality of pulse modifiers, a plurality of modulators 144, each data source being connected through a respective pulse modifier to a corresponding modulator, and the pulse modifiers reduce the pulse width in the respective data streams so that the light sources are modulated by the data streams modified by the pulse width, and a set of encoders, each of which receives the output optical signal of the corresponding light source, each encoder comprising a first spectral filtering module carrying a first code, the code being a sequence of N digits, each of which takes one of at least two values, an optical a camera that spectrally encodes the input light beam with a code by dividing the light beam into N spectral components, each of which corresponds to a code digit, attenuating each spectral component according to the value of the corresponding code digit and recombination of spectral components to form the output coded light beam, while the first optical camera is designed for spectral coding of the first light beam.  2. The optical communication system according to claim 1, characterized in that the first code is selected from a set of unipolar codes, in which each code is orthogonal to the difference between any other set code and the complement of this other code.  3. The optical communication system according to claim 1, characterized in that it further comprises a plurality of decoders for receiving signals from the optical fiber and recovering the transmitted data from the optical fiber, each of the decoders comprising a phase insensitive optical power splitter designed for splitting parts of the light signal propagating through the optical fiber to components of approximately equal power.  4. The optical communication system according to claim 3, characterized in that each decoder further comprises a second and third spectral filtering modules for receiving the first and second components of the received light, the second spectral filtering module carrying a first code and the third spectral filtering module addition of the first code, the second and third spectral filtering modules output the first and second filtered components of the received light, and an optical detector designed to receive the first and second filter Baths components of received light and for generating an output electrical signal.  5. The optical communication system according to claim 4, characterized in that the output electrical signal is the result of measuring the difference between the first and second filtered components of the received light.  6. The optical communication system according to claim 4, characterized in that the output electrical signal is supplied to a limiting circuit that removes noise electrical signals that are opposite in sign from the restored data.  7. The optical communication system according to claim 4, characterized in that the output electrical signal is supplied to a limiting circuit containing an electronic detector with a quadratic characteristic.  8. The optical communication system according to claim 1, characterized in that each pulse modifier contains a circuit providing a delayed path parallel to the data path without delay, and the signals that have passed the delayed path and the path without delay are combined to form shortened pulses.  9. The optical communication system according to claim 8, characterized in that the signals that have passed the path with a delay and the path without a delay are combined by means of an EXCLUSIVE OR logic element.  10. An optical communication system comprising a plurality of light sources, a plurality of optical delay elements introducing delays into the output signals of a plurality of light sources, wherein the first light source receives a delay of a first magnitude greater than a delay of a second light source and less than a delay of a third light source, a plurality of sources data providing multiple data streams, a set of modulators, with each data source connected to a corresponding modulator, and a set of code s, each of which receives a delayed output optical signal of the corresponding light source, each encoder comprising a first spectral filtering module carrying a first code, the code being a sequence of N digits, each of which takes one of at least two values, an optical a camera that spectrally encodes the input light beam with a code by dividing the light beam into N spectral components, each of which corresponds to a code digit, attenuating each the ctral component according to the value of the corresponding code digit and the recombination of the spectral components to form the output coded light beam, while the first optical camera is designed for spectral coding of the first light beam.  11. The optical communication system according to p. 10, characterized in that it further comprises a set of decoders designed to receive signals from the optical fiber and restore the transmitted data from the optical fiber, each of the decoders contains an optical power splitter, insensitive to phase, designed for splitting parts of the light signal propagating through the optical fiber to components of approximately equal power.  12. The optical communication system of claim 11, wherein the phase-insensitive optical power separator comprises a first polarization sensitive element for receiving a light signal and separating the light signal into first and second light components, the output of the first of a polarization sensitive element, the first light component has a first polarization, and the second light component has a second polarization, the first beam path along which the first light component propagates, and the second beam path, along which the second light component propagates, a polarization modifier located on the second path of the beam, and the polarization modifier changes the polarization of the second light component so that it practically coincides with the first polarization, a beam splitter that takes the first and second light components and splits the first and second components light on the third and fourth components of light.  13. The optical communication system according to p. 10, characterized in that it further comprises a set of pulse modifiers, a set of modulators, each data source being connected through a respective pulse modifier to the corresponding modulator, pulse modifiers reduce the pulse width in the corresponding data streams so that the sources The lights were modulated by data streams modified by the pulse width.  14. The optical communication system of claim 13, wherein each decoder further comprises a second and third spectral filtering modules for receiving the first and second components of the received light, the second spectral filtering module carrying a first code and the third spectral filtering module addition of the first code, the second and third spectral filtering modules output the first and second filtered components of the received light, and an optical detector designed to receive the first and second filter ovannyh components of received light and generating an output electrical signal.  15. The optical communication system according to claim 14, characterized in that the output electrical signal is the result of measuring the difference between the first and second filtered components of the received light.  16. The optical communication system according to p. 15, characterized in that the output electrical signal is supplied to a limiting circuit that removes noise electrical signals that are opposite in sign from the restored data.  17. The optical communication system according to p. 15, characterized in that the output electrical signal is supplied to a limiting circuit containing an electronic detector with a quadratic characteristic.