PL216641B1 - Method and system for simultaneous transmission of three optical signals through the monomode optical fibre, using the polarizing multiplication, with different states of the light polarization - Google Patents

Description

Description of the invention

The subject of the invention is a method of simultaneous transmission by single-mode optical fiber of three optical signals using polarization multiplication, with different polarization states of light transmitted on the same wavelength, and a system for simultaneous transmission of three optical signals by single-mode optical fiber using polarization multiplication, with different polarization states of light transmitted on this same wavelength.

There are known methods of transmitting two optical signals with a single-mode optical fiber with the use of polarization multiplexing. These transmission methods consist in introducing two optical signals of mutually orthogonal polarization into a single-mode optical fiber using a light polarization state splitter. The separation of the polarization states of light, i.e. optical signals, is carried out using the second light polarization state divider preceded by the light polarization state controller. The light polarization controller gives the optical signal coming to the light polarization state splitter 45 ° linear polarization, which results in the best separation of optical signals in terms of quality of the received signal.

In the European patent application EP 1772983 A1, a device for multimode optical signal transmission is described, comprising a receiving station and a transmitting station, in which transmitting station there is a code signal generator, three optical signal sources and a modulator.

The documentation of the Polish patent application P.297241 A1 presents a method and a device for performing the polarization multiplication of three optical signals transmitted on the same wavelength.

The subject of Polish patent specification PL 177262 B1 is a method of fiber optic telecommunications and a fiber optic telecommunications system, in which optical signals with a specific polarization state of light are produced, delivered to an optical fiber, and then these signals are separated due to the state of light polarization in the receiving station.

The essence of the method of simultaneous transmission by single-mode optical fiber of three optical signals with the use of polarization multiplication, with different polarization states of light transmitted on one wavelength, according to the invention, is characterized in that a first modulated electrical signal is generated in the first transmitter and transmitted to the first laser, wherein the first laser generates a first optical signal and then modulates it with a first modulated electrical signal, then this first modulated optical signal is passed to a first polarization state controller, in which the polarization state of the first modulated optical signal is determined to an azimuth linear polarization 0 °. This first modulated optical signal with linear polarization with an azimuth of 0 ° is transmitted to the first entry port of the three-input coupler. In the second transmitter, a second modulated electrical signal is generated and transmitted to a second laser, in which the second laser generates a second optical signal and then modulated with a second modulated electrical signal, after which this second modulated optical signal is transmitted to a second state controller polarization, in which the polarization state of the second modulated optical signal is set to a linear polarization with azimuth -60 °. This second modulated optical signal with linear polarization with an azimuth of -60 ° is transmitted to the second entry port of the three-input coupler. In a third transmitter, a third modulated electrical signal is generated and transmitted to a third laser, in which a third optical signal is generated by the third laser and then modulated with a third modulated electrical signal, after which this third modulated optical signal is transmitted to a third state controller polarization, in which the polarization state of the third modulated optical signal is set for a linear polarization with an azimuth of 60 °. This third modulated optical signal with linear polarization with an azimuth of 60 ° is transmitted to the third entry port of the three-input coupler.

The summed modulated optical signal appearing at the output port of the three-input coupling element is transmitted through the single-mode optical fiber and the polarization state controller of the transmitted optical signals connected in series with it to the input port of the single-input coupling element.

Summarized optical signals appearing at each exit port of a single-input coupler are simultaneously transmitted to the inputs of n polarization state analyzers. In the i-th polarization state analyzer, one of the three analyzer axis angles is 0 °, -60 °, 60 °.

PL 216 641 B1

Then the optical signal appearing at the output of the i-th polarization state analyzer is transmitted, through the i-th link, to the i-th optoelectronic element, in which the i-th optoelectronic element is converted into an electrical signal, and then this electric signal is demodulated, where i = 1, 2, ... n, where n is a finite natural number.

The essence of the system for simultaneous transmission by single-mode optical fiber of three optical signals using polarization multiplexing, with different polarization states of light transmitted on the same wavelength, according to the invention, consists in the fact that the first transmitter is connected, through the first laser, to the input of the first polarization state controller whose output is connected to the first entrance port of the three-input coupler, a second transmitter is connected, via a second laser, to an input of a second polarization state controller, the output of which is connected to the second entrance port of the three-input coupler, the third transmitter is connected by a third laser, with an input of a third polarity state controller, the output of which is connected to the third input port of the three-input coupler.

The output ports of the three-input coupler are connected, via a single-mode optical fiber, to the input of the polarization state controller of the transmitted optical signals, the output of which is connected to the input ports of the one-input coupler, the i-th output port of the single-input coupler being connected through the i-th analyzer state of polarization and the i-th link, with the i-th optoelectronic element, where i = 1, 2, ... n, where n is a finite natural number.

The main advantageous effects of using the method and system for the simultaneous transmission by single-mode optical fiber of three optical signals using polarization multiplexing, with different polarization states of light transmitted on the same wavelength, according to the invention, with reference to the prior art, consist in increasing the throughput of optical fiber transmission systems using the technique of polarization multiplication. Moreover, it enables to tune each of the receivers to the desired optical signal with one of the three polarization states of light used, by changing the orientation of the light polarization state analyzer axis and selecting the analyzer axis angle 0 °, -60 ° or 60 °.

An embodiment of a system for simultaneous transmission over a single-mode optical fiber of three optical signals using polarization multiplexing, with different polarization states of light transmitted on the same wavelength, according to the invention, is reproduced in the drawing in the form of a block diagram.

In an embodiment of the method of simultaneous transmission over a single-mode optical fiber of three optical signals using polarization multiplication, with different polarization states of light transmitted on the same wavelength, according to the invention, modulated electrical signals are generated in the first, second and third transmitters Ni, N2 and N3, containing an independent information.

In the first Ni transmitter, a first modulated electrical signal is generated and transmitted to the first Li laser. In the first laser Li, a first optical signal is generated and then modulated with the first modulated electrical signal, then this first modulated optical signal is transmitted to the first polarization state controller KPi in which the polarization state of the first modulated optical signal is established into linear polarization with azimuth 0 °. This first modulated optical signal with a linear polarization of 0 ° azimuth is transmitted to the first entry port of the three-input coupler Rt.

In the second transmitter N _2, a second modulated electrical signal is generated and transmitted to the second laser L2. In the second laser L2, a second optical signal is generated and then modulated with a second modulated electrical signal, after which this second modulated optical signal is transmitted to the second polarization state controller KP2, in which the polarization state of the second modulated optical signal is determined for linear polarization with azimuth -60 °.

This second modulated linear polarization optical signal with an azimuth of -60 ° is transmitted to the second entry port of the three-input coupler Rt.

In the third transmitter N3, a third modulated electrical signal is generated and transmitted to the third laser L3. In the third laser L3, a third optical signal is generated and then modulated with a third modulated electrical signal, then this third modulated optical signal is transmitted to the third polarization state controller KP3, in which the polarization state of the third modulated optical signal is determined for linear polarization with azimuth 60 °.

PL 216 641 B1

This third modulated optical signal with linear polarization with an azimuth of 60 ° is transmitted to the third entry port of the three-input coupler Rt.

The summed modulated optical signal with three polarization states of light appearing at the output ports of the three-input coupler Rt is transmitted through the single-mode optical fiber S and the polarization state controller KP4 connected in series to the input port of the single-input coupling element Rj.

In a single-input coupling element Rj, the sum optical signal with three different polarization states of the light is uniformly divided in terms of optical power into n optical signals that appear simultaneously at its n exit ports.

Optical signals appearing at the n output ports of a single-input coupler Rj are simultaneously transmitted to n polarization state analyzers ΑΡι, ... ΑΡ ₂ .

In the i-th polarization state analyzer AP, only one of the three analyzer axis angles is set to 0 °, -60 ° or 60 °. Then the optical signal with the fixed azimuth is transmitted through the i-th link to the i-th optoelectronic element Oj- This optical signal in the i-th optoelectronic element Oj. is converted into an electrical signal which is then demodulated, with i = 1, 2, ... n, where n is a finite natural number. From the i-th optoelectronic element O, independent information is obtained, which was previously generated in one of the three transmitters.

In an embodiment of a system for simultaneous transmission by single-mode optical fiber of three optical signals using polarization multiplexing with different polarization states of light at the same wavelength, according to the invention, a first Ni transmitter is connected, through a first Li laser, to the input of the first polarization state controller KP ₂ the output of which is connected to the first entrance port of the three-entry coupler Rt. The second transmitter N ₂ is connected, via a second laser L ', to the input of the second polarization state controller KP ₂ , the output of which is connected to the second entrance port of the three input coupler Rt. The third transmitter N3 is connected, via a third laser L3, to the input of the third bias state controller KP3, the output of which is connected to the third input port of the three-input coupler Rt.

The output ports of the three-input coupler Rt are connected, via a single-mode optical fiber S, to the input of the polarization state controller of the transmitted optical signals KP4, the output of which is connected to the input port of the single-input coupler Rj.

The first exit ports of the single-input coupler Rj are connected via a first polarization state analyzer APi and a link to the first optoelectronic component Oi, and the nth output ports of the single-input coupler Rj are connected via the nth polarization state analyzer AP _n and nth. link K _n with the nth optoelectronic element O _n .

For a person skilled in the art of simultaneous transmission by single-mode optical fiber of three optical signals using polarization multiplexing, with different polarization states of light transmitted on the same wavelength, it is obvious that the technical means mentioned in the description of the invention, two patent claims and reproduced in the drawing, are only illustrative thereof. in the form of specific embodiments, and may be subjected to corresponding, slight obvious modifications or replaced by their equivalents resulting from natural technical progress, which, however, will not go beyond the inventive idea of a method and system for simultaneous transmission by single-mode optical fiber of three optical signals using polarization multiplexing, with different polarization states of light transmitted on the same wavelength, according to the invention, achieving the same technical effects.

PL 216 641 B1

List of reference symbols

AP1 - the first polarization state analyzer,

AP2 - second polarization state analyzer,

AP3 - third polarization state analyzer,

K1 - first link,

K2 - second link,

K3 - third link,

KP1 - the first polarization state controller,

KP2 - second polarity status checker,

KP3 - third polarity status checker,

N1 - first transmitter,

N2 - second transmitter,

N3 - third transmitter,

O1 - first receiver,

O2 - second receiver,

O3 - third receiver,

RJ - single-input broadband symmetrical coupling element,

RT - three-input broadband symmetrical coupling element,

S - single-mode optical fiber,

Z1 - the first optical signal source,

Z2 - second source of optical signal,

Z3 - the third source of the optical signal.

Claims (2)

Patent claims 1. A method of simultaneous transmission by single-mode optical fiber of three optical signals using polarization multiplication, with different polarization states of light transmitted on the same wavelength, consisting in transmitting modulated optical signals from three transmitters to receivers, characterized in that in the first transmitter (Ni) it generates the first modulated electrical signal is transmitted to the first laser (Li), in which the first laser (Li) generates a first optical signal and then modulates it with the first modulated electrical signal, after which this first modulated optical signal is transmitted to of the first polarization state controller (KPA, in which the polarization state of the first modulated optical signal is determined to linear polarization with 0 ° azimuth, this first m modulated optical signal with linear polarization with 0 ° azimuth is sent to the first entry port of the three-input coupler (Rt) inthe second transmitter (N2) generates a second modulated electrical signal and transmits it to the second laser (L2), in which the second laser (L2) generates a second optical signal and then modulates it with a second modulated electrical signal, after which the latter is modulated the optical signal is transmitted to the second polarization state controller (KP2), in which the polarization state of the second modulated optical signal is set for linear polarization with -60 ° azimuth, the second modulated optical signal with linear polarization with azimuth -60 ° is sent to the second gate input of the three-input coupling element (Rt), a third modulated electrical signal is generated in the third transmitter (N3) and transmitted to the third laser (L3), in which the third laser (L3) is generated a third optical signal and then modulated with a third with a modulated electrical signal, then this third modulated optical signal is passed to a third state controller after polarization (KP3), in which the polarization state of the third modulated optical signal is determined for linear polarization with 60 ° azimuth, this third modulated optical signal with linear polarization with 60 ° azimuth is sent to the third entry port of the three-input coupler (Rt), total signal optical, appearing on the output port of the three-input coupling element (Rt), is transmitted through the single-mode optical fiber (S) and the polarization state controller of the transmitted optical signals (KP4) connected in series to the input port of the single-input coupling element (Rt), and the total optical signals appearing at each exit gate of a single-entry coupling element (Rt) shall be transmitted simultaneously PL 216 641 B1 to the inputs of n polarization state analyzers (APi AP ₂ , ... AP _n ), where in the i-th polarization state analyzer (AP) one of the three analyzer axis angles is set 0 °, -60 °, 60 °, and then the optical signal appearing at the output of the i-th polarization state analyzer (AP) is transmitted, via the i-th link (Ki), to the i-th optoelectronic element (Oi), in which i-th optoelectronic element ( Oi) the optical signal is converted into an electric signal, and then this electric signal is demodulated with i = 1,2 ... n, where n is a finite natural number. 2. A system for simultaneous transmission by single-mode optical fiber of three optical signals with the use of polarization multiplication, with different polarization states of light transmitted on the same wavelength, consisting of transmitters and receivers connected with each other by an optical transmission link, characterized in that the first transmitter (Ni) is connected, by a first laser (Li), to the input of a first polarization state controller (KPi), the output of which is connected to the first input port of the three-input coupler (Rt), the second transmitter (N2) is connected, by a second laser (L2), with the input of the second polarization state controller (KP2), the output of which is connected to the second input port of the three-input coupler (Rt), the third transmitter (N3) is connected, via a third laser (L3), to the input of the third polarization state controller (KP3), the output of which is connected to the third entry port of the three-entry element coupling (Rt), and the output port of the three-input coupling element (Rt) is connected, via a single-mode optical fiber (S), to the input of the polarization state controller of the transmitted optical signals (KP4), the output of which is connected to the input port of the single-input coupling element (Rj), wherein the i-th output port of the single-input coupler (Rj) is connected, via the i-th polarization state analyzer (AP,) and the i-th link (K), with the i-th optoelectronic element (O) where i = 1 , 2 ... n, where n is a finite natural number.