RU2346310C1 - Optical signal switching unit - Google Patents

Abstract

FIELD: physics; optics.

SUBSTANCE: invention relates to optical data encoding, decoding and transmitting devices, in particular, to optical signal switching devices used in computer networks. Switching device comprises six logical units. Logical unit comprises inputs/outputs from the first to the sixth one. The first input/output of the1^st - the 6^th logical units is input/output of the 1^st - the 6^th channels of the switching device, respectively. The 2^nd - the 6^th inputs/outputs of the first logical unit are connected, respectively, to the 2^nd input/output of the second logical unit, to the 3^rd input/output of the sixth logical unit, to the 4^th input/output of the third logical unit, to the 5^th input/output of the fifth logical unit and to the 6^th input/output of the fourth logical unit. The 3^rd - the 6^th inputs/outputs of the second logical unit are connected, respectively, to the 3^rd input/output of the third logical unit, to the 4^th input/output of the fourth logical unit, to the 5^th input/output of the sixth logical unit and to the 6^th input/output of the fifth logical unit. The 2^nd, the 5^th and the 6^th inputs/outputs of the third logical unit are connected, respectively, to the 2^nd input/output of the fourth logical unit, to the 4^th input/output of the fifth logical unit and to the 6^th input/output of the sixth logical unit.

EFFECT: simplified optical signal switching device and enhanced functional capabilities thereof.

2 cl, 12 dwg

Description

The present invention relates to devices for encoding, decoding and transmitting data represented by optical signals, in particular, to optical signal switches used in computer networks.

Known wave filter switch optical signals [1], containing the first and second optical fibers, forming in a limited area fused and stretched twisted pair. The first input-output of the first optical fiber is the first multiplexed input-output of the switch. The second input-output of the first optical fiber is the first demultiplexed input-output of the switch. The first input-output of the second optical fiber is the second multiplexed input-output of the switch. The second input-output of the second optical fiber is the second demultiplexed input-output of the switch. The wave filter filter of optical signals [1] allows you to multiplex and demultiplex bi-directional optical signals with different wavelengths.

The disadvantage of the device [1] are limited functionality. In particular, it is impossible to switch optical signals between the first and second multiplexed or demultiplexed inputs / outputs. This does not allow using it as a central switching link when building a computer network with a star topology.

A known optical signal switch [2], containing six logical blocks, the logical block contains the first to sixth inputs / outputs, the first input-output of the first to sixth logical blocks is respectively the input-output of the first to sixth channels of the switch. The logic unit is configured to transmit optical signals in certain directions. In particular, it can be configured to transmit signals in a computer network with a ring logical structure and star topology. Other settings are also possible.

The disadvantages of the switch [2] are complexity and limited functionality.

The first drawback is the use of a matrix of mirrors with controlled transparency. Amplifiers are needed to compensate for signal attenuation in a chain of mirrors. Mirror transparency can be controlled manually when configuring the system or remotely. The latter option implies the availability of software-accessible controls (for example, based on a microprocessor with appropriate software); in any case, the switch must have the means to supply voltage to it, which leads to its additional complication and degrades performance.

The second disadvantage is that only one channel is used to transmit data in each direction.

The purpose of the invention is to simplify the switch and expand its functionality.

The goal is achieved in that in the optical signal switch containing six logical blocks, the logical block contains the first to sixth inputs / outputs, the first input-output of the first to sixth logical blocks is respectively the input-output of the first to sixth channels of the switch, the second to the sixth inputs are the outputs of the first logical block are connected respectively with the second input-output of the second logical block, with the third input-output of the sixth logical block, with the fourth input-output of the third logical block, with the fifth input-output the house of the fifth logical block and with the sixth input-output of the fourth logical block, the third to the sixth inputs and outputs of the second logical block are connected respectively to the third input-output of the third logical block, with the fourth input-output of the fourth logical block, with the fifth input-output of the sixth logical block and with the sixth input-output of the fifth logical block, the second, fifth and sixth inputs and outputs of the third logical block are connected respectively to the second input-output of the fourth logical block, with the fourth input-in the output of the fifth logical block and with the sixth input-output of the sixth logical block, the third and fifth inputs and outputs of the fourth logical block are connected respectively with the third input-output of the fifth logical block and with the fourth input-output of the sixth logical block, the second input-output of the fifth logical block connected to the second input-output of the sixth logic block, the first, second, fifth and sixth logical blocks contain the first to fourth wave filters, the multiplexed input-output of the first wave filter is by the first input-output of the corresponding logic unit, the first and second demultiplexed inputs and outputs of the first wave filter are connected respectively to the multiplexed inputs and outputs of the second and third wave filters, the first demultiplexed input and output of the second wave filter is connected to the multiplexed input and output of the fourth wave filter, the first and the second demultiplexed inputs and outputs of which are respectively the sixth and fifth inputs and outputs of the corresponding logical lock, the second demultiplexed input-output of the second wave filter is the fourth input-output of the corresponding logic block, the first and second demultiplexed inputs and outputs of the third wave filter are the third and second inputs and outputs of the corresponding logic block, the third and fourth logical blocks contain the fifth - eighth wave filters, the multiplexed input-output of the fifth wave filter is the first input-output of the corresponding logic block, the first and second the fifth demultiplexed inputs and outputs of the fifth wave filter are connected respectively to the multiplexed inputs and outputs of the sixth and seventh wave filters, the second demultiplexed input and output of the sixth wave filter is connected to the multiplexed input and output of the eighth wave filter, the first and second demultiplexed inputs and outputs of which are respectively the fifth and the fourth inputs and outputs of the corresponding logic unit, the first demultiplexed input-output of the sixth wave filter and is the sixth input-output of the corresponding logic block, the first and second demultiplexed inputs and outputs of the seventh wave filter are the third and second inputs and outputs of the corresponding logic block, the first wave filters of the first, second, fifth and sixth logic blocks, as well as the fifth wave filters the third and fourth logical blocks are wave filters of the first type, the second wave filters of the first, second, fifth and sixth logical blocks, as well as the sixth wave the filters of the third and fourth logical blocks are wave filters of the second type, the third wave filters of the first, second, fifth and sixth logical blocks, as well as the seventh wave filters of the third and fourth logical blocks are wave filters of the third type, the fourth wave filters of the first, second, fifth and of the sixth logical blocks are wave filters of the fourth type, the fourth wave filters of the third and fourth logical blocks are wave filters of the fifth type.

In the proposed switch of optical signals, wave filters of the first to fifth types operate with optical signals with wavelengths numbered in the form of a series of λ1, λ2, λ3, ..., the wavelength increases uniformly with increasing number, the multiplexed input-output of the wave filter of the first type is transparent to optical signals with wavelengths with the numbers λ1, λ2, λ3, ..., the first demultiplexed input-output of the wave filter of the first type is transparent for optical signals with wavelengths with the numbers λ1, λ3, λ5, ... and is opaque to optical wavelength signals with numbers λ2, λ4, λ6, ..., the second demultiplexed input-output of the wave filter of the first type is transparent for optical signals with wavelengths with numbers λ2, λ4, λ6, ... and opaque for optical signals with wavelengths with numbers λ1, λ3, λ5, ..., the multiplexed input-output of the wave filter of the second type is transparent for optical signals with wavelengths with numbers λ1, λ3, λ5, ..., the first demultiplexed input-output of the wave filter of the second type is transparent for optical signals with wavelengths with numbers λ 1, λ5, λ9, ... and opaque for optical signals with wavelengths with the numbers λ3, λ7, λ11, ..., the second demultiplexed input-output of the wave filter of the second type is transparent for optical signals with wavelengths with the numbers λ3, λ7, λ11, ... and opaque for optical signals with wavelengths with the numbers λ1, λ5, λ9, ..., the multiplexed input-output of the wave filter of the third type is transparent for optical signals with wavelengths with the numbers λ2, λ4, λ6, ..., the first demultiplexed input-output of the wave filter the third type is transparent to optical ignals with wavelengths λ2, λ6, λ10, ... and opaque for optical signals with wavelengths λ4, λ8, λ12, ..., the second demultiplexed input-output wave filter of the third type is transparent for optical signals with wavelengths with numbers λ4 , λ8, λ12, ... and opaque for optical signals with wavelengths λ2, λ6, λ10, ..., the multiplexed input-output of the fourth wave filter is transparent for optical signals with wavelengths λ1, λ5, λ9, ..., the first demultiplexed input-output wave filter h of the fourth type is transparent for optical signals with wavelengths λ1, λ9, ... and opaque for optical signals with wavelengths λ5, λ13, ..., the second demultiplexed input-output wave filter of the fourth type is transparent for optical signals with wavelengths with numbers λ5, λ13, ... and opaque for optical signals with wavelengths λ1, λ9, ..., the fifth-type multiplexed input-output of a wave filter of the fifth type is transparent for optical signals with wavelengths λ3, λ7, λ11, ..., the first demultiplexed input the fifth type wave filter d-output is transparent for optical signals with wavelengths λ3, λ11, ... and opaque for optical signals with wavelengths λ7, λ15, ..., the second demultiplexed fifth-type wave filter input-output is transparent for optical signals with wavelengths with numbers λ7, λ15, ... and opaque for optical signals with wavelengths with numbers λ3, λ11, ...

Figure 1 presents a simplified sketch of the design of the known [1] wave filter; on figa - transparency diagram of the wave filter F1 of the first type; on figb - transparency diagrams of wave filters F2 and F3 of the second and third types; on figv - transparency diagrams of the wave filters F4 and F5 of the fourth and fifth types; on figa-z and figa - examples of paths of transmission of optical signals through a wave filter of the first type; on figb - an example of the inclusion of a filter of the first type in a data transmission system. Figure 5 presents the most common options for the topology of computer networks; Fig.6 is a functional diagram of the proposed six-channel optical signal switch; 7-12 - functional diagrams of the first to sixth logical blocks - components of the proposed six-channel optical signal switch.

The wave filter 1 (Fig. 1) is designed to separate (sort) a group of signals by wavelengths. It is built on the basis of a specially twisted and fused with the simultaneous stretching of the melt optical fibers 2 and 3 [1]. Hereinafter, depending on the setting of the physical parameters of the filter during its manufacture, it is designated F1, F2, F3, F4 or F5 (filter of the first to fifth types). In any case, the filter is symmetrical in the sense that the pairs of its terminals X-W, W-X, Y-Z and Z-Y are functionally equivalent.

Depending on the parameters of twisting, melting and stretching of the optical fibers during the manufacture of the filter, it acquires selective transparency with respect to the transmission of light signals of certain wavelengths. In other words, the filter can in some way sort the input stream of “multi-colored” infrared light signals arriving from the outside in arbitrary combinations to pin X (to any of the four pins). The signals are assumed to have wavelengths λ1, λ2, ..., λ16 uniformly distributed on the horizontal numerical axes of the transparency diagrams shown in FIG. 2. Adjacent wavelengths are separated by gaps of 100 nm or more.

Graphs 4 and 5 (figure 2,) display the transparency diagrams of the channels X-Y and X-Z of the filter F1. Since the filter is symmetrical, these same graphs display the transparency diagrams of the W-Z and W-Y channels, as well as the two remaining channels obtained by mutually reverse substitution of the X, W symbols with the Y, Z symbols. Levels 0 and 100% correspond to the opaque and fully transparent channel states. The graphs for their simplification are represented by two antiphase sinusoids, although in reality their shape is more complex and depends on the filter manufacturing technology. From graph 4 it follows that the X-Y channel (as well as the W-Z channel) of the F1 filter is transparent for light with wavelengths λ1, λ3, λ5, ..., λ15 and opaque for light with wavelengths λ2, λ4, λ6, ..., λ16. If the channel is transparent, then light of the corresponding wavelengths can be transmitted through it in either or simultaneously in both directions. An opaque channel does not transmit light of the corresponding wavelengths in any direction.

Figure 5 shows that the X-Z channel (as well as the W-Y channel) of the F1 filter is transparent to light with wavelengths λ2, λ4, λ6, ..., λ16 and opaque to light with wavelengths λ1, λ3, λ5, ..., λ15.

Graphs 6 and 7 (figure 2, b) display the transparency diagrams of the channels X-Y and X-Z (W-Z and W-Y) of the filter F2. They are represented by sinusoids with doubled periods compared to graphs 4 and 5. From graph 6 it follows that the X-Y channel of the F2 filter is transparent to light with wavelengths λ1, λ5, λ9, λ13 and opaque to light with wavelengths λ3, λ7, λ11, λ15. Graph 7 is out of phase with graph 6 and displays the transparency diagram of the channel X-Z of filter F2. The transparency of the X-Y and X-Z channels (W-Z and W-Y) of the F2 filter with respect to light signals with wavelengths λ2, λ4, λ6, ..., λ16 is undefined, but such signals do not arrive at this filter during its operation.

Graphs 8 and 9 (figure 2, b) display the transparency diagrams of the channels X-Y and X-Z (W-Z and W-Y) of the filter F3. They are represented by sinusoids of the same frequency as sinusoids 6 and 7, but are shifted relative to them in phase to the right by a quarter of the period. From graph 8 it follows that the X-Y channel of the F3 filter is transparent to light with wavelengths λ2, λ6, λ10, λ14 and opaque to light with wavelengths λ4, λ8, λ12, λ16. Graph 9 is out of phase with graph 8 and displays the transparency diagram of channel X-Z of filter F3. The X-Z channel of the F3 filter is transparent to light with wavelengths λ4, λ8, λ12, λ16 and opaque to light with wavelengths λ2, λ6, λ10, λ14. The transparency of the channels X-Y and X-Z (W-Z and W-Y) of the filter F3 with respect to light signals with wavelengths λ1, λ3, λ5, ..., λ15 is uncertain, but such signals do not arrive at this filter during its operation.

Graphs 10 and 11 (figv) show the diagrams of the transparency of the channels X-Y and X-Z (W-Z and W-Y) of the filter F4. They are represented by sinusoids with doubled periods in comparison with graphs 6-9. From graph 10 it follows that the X-Y channel of the F4 filter is transparent to light with wavelengths λ1, λ9 and opaque to light with wavelengths λ5, λ13. Graph 11 is out of phase with graph 10 and displays the transparency diagram of channel X-Z of filter F4. This channel is transparent to light with wavelengths λ5, λ13 and opaque to light with wavelengths λ1, λ9. The transparency of the X-Y and X-Z channels (WZ and WY) of the F4 filter with respect to light signals with wavelengths λ2-λ4, λ6-λ8, λ10-λ12, λ14-λ16 is undefined, but such signals do not arrive at this filter in the process of his work.

Graphs 12 and 13 (figure 2, c) display the transparency diagrams of the channels X-Y and X-Z (W-Z and W-Y) of the filter F5. From graph 12 it follows that the channel X-Y of the filter F5 is transparent to light with wavelengths λ1, λ11 and opaque to light with wavelengths λ7, λ15. Graph 13 is out of phase with graph 12 and displays the transparency diagram of channel X-Z of filter F5. This channel is transparent to light with wavelengths λ7, λ15 and opaque to light with wavelengths λ3, λ11. The transparency of the X-Y and X-Z channels (WZ and WY) of the F5 filter with respect to light signals with wavelengths λ1, λ2, λ4-λ6, λ8-λ10, λ12-λ14, λ16 is undefined, but such signals do not arrive at this filter in the process of its operation.

Examples 14-19 of the paths of the passage of optical signals through the wave filter F1 (figa-e) show the propagation of a group of light signals through the filter from left to right, from right to left and simultaneously in both directions. In these examples, one of the filter pins is not used.

In accordance with example 18 (Fig. 3, d), the input-output X of the filter F1 is hereinafter referred to as multiplexed input-output, input-output Y - the first demultiplexed input-output, input-output Z - the second demultiplexed input-output of the filter. Similarly, the input-output X of the filters F2-F5 is hereinafter referred to as multiplexed input-output, input-output Y - the first demultiplexed input-output, input-output Z - the second demultiplexed input-output.

In examples 20-22 shown in figs. 3g, h and figa, all the conclusions of the filter F1 are used.

Examples 20 and 21 show the possibility of using the filter F1 to interface unidirectional transmission lines of optical signals with bidirectional.

In example 20, the optical signal supplied to input X on the left side contains 16 components with wavelengths λ1-λ16. The signal taken from the output of the filter W also contains 16 components with the same wavelengths λ * 1-λ * 16. The signs "*" indicate that the signals arrived at the inputs of the filter F1 on the right side. At the input-output Y, signals with wavelengths λ1, λ3, λ5, ..., λ15 propagate to the right, and signals with wavelengths λ * 2, λ * 4, λ * 6, ..., λ * 16 - to the left. At the input / output Z, signals with wavelengths λ2, λ4, λ6, ..., λ16 propagate to the right, and signals with wavelengths λ * 1, λ * 3, λ * 5, ..., λ * 15 - to the left.

Example 21 differs from example 20 in the directions of signal transmission through the terminals X and W of the filter F1.

In Example 22 (FIG. 4a), all lines connected to the filter F1 are bi-directional. On each line 16 pairs of oppositely directed optical signals are transmitted, each pair has the same wavelength. Essentially, this circuit is a non-connected switch capable of transmitting data in the directions: X → Y, X → Z, W → Y, W → Z, Y → X, Y → W, Z → X, Z → W. To select the direction of transmission (routing the information packet), the data source uses wavelengths with even or odd numbers. For example, an external source of the signal supplied to the input-output Z of the filter F1, wishing to transmit a message to the communication line connected to the inputs-outputs X or W, can use light pulses for this purpose with the corresponding wavelengths λ * 6 or λ ″ 15.

Direct data transfer in adjacent directions X → W, W → X, Y → Z, Z → Y is impossible. If there is an intermediary device 23 (Fig. 4b), such transfers are feasible. For example, an external source of the signal supplied to the input-output Z of the filter F, wishing to transmit a message to the communication line 24 connected to the inputs / outputs Y, can use light pulses with a wavelength of λ * 8 for this. These pulses pass to the input-output X and are received by the device Q (23). By preliminary "agreement" with this device, it immediately gives the received pulses back to the input-output X, but uses light with a wavelength of λ13 for this. Filter F1 transfers these pulses to input-output Y, as required.

The above examples (they can be extended to filters of other types, taking into account their transparency diagrams) show the previously mentioned limited capabilities of the filter [1] when it is used as a functionally complete switch of optical signals in a computer network.

Figure 5 presents the most common options for the topology of computer networks. The topology of the type of "common bus" (figa) is used mainly in local networks of early generations. Coaxial cables are commonly used as signal transmission medium. The use of fiber-optic communication lines within the framework of this topology is difficult, since it is necessary to install optical splitters to connect each node 25 to a common trunk 26. This is not technologically advanced, in addition, each splitter divides the energy of the signal fed into it into two parts, so that the levels of the received signals depend from the relative position of the transmitter and receiver.

The topology of the "star" type with a common hub 27 (Fig.5, b) suggests the presence of radial connections between the hub and nodes 28 of the network. The concentrator summarizes all the optical signals entering it, distributes the total signal evenly between all channels, if possible, and simultaneously transmits it in the opposite directions. Some hubs work on the principle of distributing the input signal between all channels except for their own, which facilitates the detection of collisions while simultaneously addressing two or more nodes 28 to a common signal transmission medium.

The main disadvantage of this structure is that the input signal power is divided by the number of channels reaching one hundred or more. To restore the levels of the output signals, active concentrators are used, which are able to enhance the power of the light fluxes emitted by them in all directions. This complicates the structure of the hub and requires a power source.

In a network with a ring topology (Fig. 5c), nodes 29 are connected in a series closed circuit. The disadvantages inherent in the previously discussed networks (figure 5, a, b), in this case are absent. Each node suspends the distribution of information packets addressed to it and transmits “foreign” packets to the next node.

In the event of a failure of a node, the main direction of packet transmission, having reached the node closest to it, can be reversed, so that all nodes that are still operational are accessible. In order to preserve the possibility of bi-directional data transmission in a ring in case of failure of one of the nodes, this node is automatically or manually excluded from operation, and optical communication lines broken by such a failure are connected directly. In this case, the connecting element introduces losses in the transmission of the signal, in addition, the length of the newly created communication line becomes equal to the sum of the lengths of communication lines that previously connected the failed node to the neighboring ones.

This disadvantage is absent in the network with combined topology (Fig.5g). Outwardly, it resembles the previously considered network with a star topology (Fig. 5b), but instead of a hub 27, it uses a switch 30 connected to nodes 31. Unlike a hub, the switch 30 is able to combine optical fibers connecting it in a certain way with nodes 31. For example, inside the switch, you can create connections in which the network has a ring logical structure similar to that shown in figv. Arrows 32 in FIG. 5g correspond to packet transmission routes between nodes 31. As follows from the above diagram, packet transmission between nodes 31 occurs essentially along arrows 33, as in a network with a ring topology.

Isolation and bypassing of one or more faulty nodes 31 is carried out by appropriate adjustment of the internal circuits of the switch 30 and does not affect the network nodes and communication lines.

The switch 34 [2] (Fig. 5d) contains the logical blocks 35, the logical block contains the external 36 and internal 37 inputs / outputs, the external input-output 36 of the logical block 35 is the input-output of the corresponding channel of the switch and connected to the corresponding node 38 of the network. The internal inputs and outputs 37 of the logical blocks 35 are connected to the optical switching matrix 39.

Logic blocks 35 can be configured to transmit signals between nodes 38 in a ring circuit, as shown in FIG. Settings are possible that provide logical isolation and bypass of faulty nodes 38 or communication lines with these nodes.

The proposed switch, shown in Fig.6, contains the first to sixth logical blocks 40-45, each logical block contains the first sixth 46-51 inputs / outputs, the first input-output 46 of the first to sixth logical blocks 40-45 is respectively an input- the output of the first to sixth channels of the switch.

The second - the sixth 47-51 inputs and outputs of the first logical block 40 are connected respectively with the second input-output 47 of the second logical block 41, with the third input-output 48 of the sixth logical block 45, with the fourth input-output 49 of the third logical block 42, with the fifth the input-output 50 of the fifth logical block 44 and with the sixth input-output 51 of the fourth logical block 43, the third - the sixth 48-51 inputs and outputs of the second logical block 41 are connected respectively with the third input-output 48 of the third logical block 42, with the fourth input 49th exit of that logical block 43, with the fifth input-output 50 of the sixth logical block 45 and with the sixth input-output 51 of the fifth logical block 44, the second 47, fifth 50 and sixth 51 inputs and outputs of the third logical block 42 are connected respectively to the second input-output 47 the fourth logical block 43, with the fourth input-output 49 of the fifth logical block 44 and with the sixth input-output 51 of the sixth logical block 45, the third 48 and fifth 50 inputs and outputs of the fourth logical block 43 are connected respectively to the third input-output 48 of the fifth logical block 44 and with the fourth input-output 49 of the sixth logical unit 45, the second input-output 47 of the fifth logical unit 44 is connected to the second input-output 47 of the sixth logical unit 45.

The first 40 (FIG. 6, FIG. 7), second 41 (FIG. 6, FIG. 8), fifth 44 (FIG. 6, FIG. 11) and sixth 45 (FIG. 6, FIG. 12) logic blocks contain the first is the fourth 52-55 wave filters, the multiplexed input-output 56 of the first wave filter 52 is the first input-output 46 of the corresponding logic unit, the first 57 and second 58 demultiplexed inputs and outputs of the first wave filter 52 are connected respectively to the multiplexed inputs and outputs 59 and 60 second 53 and third 54 wave filters, the first 61 demultiplexed input-output of the second wave the filter 53 is connected to the multiplexed input-output 62 of the fourth wave filter 55, the first 63 and second 64 demultiplexed inputs and outputs of which are respectively the sixth 51 and fifth 50 inputs and outputs of the corresponding logic unit, the second demultiplexed input-output 65 of the second wave filter 53 is the fourth the input-output 49 of the corresponding logical unit, the first 66 and second 67 demultiplexed inputs-outputs of the third wave filter 54 are respectively the third 48 and second 47 inputs-you odes corresponding logical block.

The third 42 (Fig. 6, Fig. 9) and the fourth 43 (Fig. 6, Fig. 10) logic blocks contain the fifth - eighth 68-71 wave filters, the multiplexed input-output 72 of the fifth wave filter 68 is the first input-output 46 of the corresponding logical unit, the first 73 and second 74 demultiplexed inputs and outputs of the fifth wave filter 68 are connected respectively to the multiplexed inputs and outputs 75 and 76 of the sixth 69 and seventh 70 wave filters, the second 77 demultiplexed input and output of the sixth wave filter 69 is connected to multiplexed input-output 78 of the eighth wave filter 71, the first 79 and second 80 demultiplexed inputs and outputs of which are respectively the fifth 50 and fourth 49 inputs and outputs of the corresponding logic unit, the first 81 demultiplexed input and output of the sixth 69 wave filter is the sixth input-output 51 of the corresponding logic block, the first 82 and second 83 demultiplexed inputs and outputs of the seventh wave filter 70 are respectively the third 48 and second 47 inputs and outputs of the corresponding logical block,

The first wave filters 52 of the first 40, second 41, fifth 44 and sixth 45 logic blocks, as well as the fifth 68 wave filters of the third 42 and fourth 43 logic blocks are wave filters F1 of the first type (Fig. 1, Fig. 2a), the second wave filters 53 of the first 40, second 41, fifth 44 and sixth 45 logic blocks, as well as sixth wave filters 69 of the third 42 and fourth 43 logical blocks are wave filters F2 of the second type (Fig. 1, Fig. 2b), third wave filters 54 of the first 40 , second 41, fifth 44 and sixth 45 logical blocks, as well as seventh the wave filters 70 of the third 42 and fourth 43 logic blocks are wave filters F3 of the third type (Fig. 1, Fig. 2b), the fourth wave filters 55 of the first 40, second 41, fifth 44 and sixth 45 logic blocks are wave filters F4 of the fourth type ( 1, FIG. 2c), the fourth wave filters 71 of the third 42 and the fourth 43 logic blocks are fifth type wave filters F5 (FIG. 1, FIG. 2c).

When the switch is connected to the computer network, its nodes are connected to the inputs and outputs 46 of the first to sixth logical blocks 40-45. For convenience of presentation in Fig.6-Fig.12 fiber-optic communication channels with network nodes are indicated by the letters A, B, ..., F.

To exchange data between network nodes, optical signals with wavelengths λ1-λ16 uniformly distributed on the horizontal numerical axes of the diagrams shown in FIG. 2 are used.

Using the proposed switch, a complete graph of bi-directional connections between network nodes connected to fiber optic channels A-F is implemented:

А↔В, А↔С, А↔D, А↔Е, А↔F, В↔С, В↔D, В↔Е, В↔F, С↔D, С↔Е, С↔F, D↔ E, D↔F, E↔F.

The table shows the wavelengths of the optical signals corresponding to data transmission routes between different pairs of fiber optic channels of the switch.

Table Data transfer route Optical wavelengths A↔B λ4, λ8, λ12, λ16 A↔C λ7, λ15 A↔d λ1, λ9 А↔Е λ5, λ13 A↔f λ2, λ6, λ10, λ14 В↔С λ2, λ6, λ10, λ14 B↔D λ7, λ15 VE λ1, λ9 B↔f λ5, λ13 C↔d λ4, λ8, λ12, λ16 С↔Е λ3, λ11 C↔f λ1, λ9 D↔e λ2, λ6, λ10, λ14 D↔f λ3, λ11 E↔f λ4, λ8, λ12, λ16

It follows from the table that, for example, for bi-directional transmission of data packets between network nodes connected to channels A and F of the switch, you can use signals with wavelengths λ2, λ6, λ10, λ14 - one of these signals or to parallelize the transmission simultaneously two, three or four signals.

The application of the proposed optical signal switch allows simplifying the construction of networks with a fully connected graph of connections between its nodes or with a logical structure of the ring type and star topology. Due to the possibility of connecting each channel with each, parallelization of data streams and logical isolation of faulty network nodes are implemented. The switch operates without a power source. The route of the data packet transmitted by the network node is specified at the physical (and not at the network) level by selecting the wavelength of the linear signal.

Information sources

1. US Patent No. 5809190 (Fig. 5).

2. US Patent No. 6,134,357 (Fig. 4) (prototype).

Claims (2)

1. The optical signal switch containing six logical blocks, the logical block contains the first to sixth inputs / outputs, the first input-output of the first to sixth logical blocks is respectively the input-output of the first to sixth channels of the switch, characterized in that the second to the sixth inputs the outputs of the first logical block are connected respectively with the second input-output of the second logical block, with the third input-output of the sixth logical block, with the fourth input-output of the third logical block, with the fifth input-output of the logical block and with the sixth input-output of the fourth logical block, the third and sixth inputs and outputs of the second logical block are connected respectively to the third input-output of the third logical block, with the fourth input-output of the fourth logical block, with the fifth input-output of the sixth logical block and with the sixth input-output of the fifth logical unit, the second, fifth and sixth inputs and outputs of the third logical unit are connected respectively to the second input-output of the fourth logical unit, with the fourth input-output the fifth logical block and with the sixth input-output of the sixth logical block, the third and fifth inputs and outputs of the fourth logical block are connected respectively to the third input-output of the fifth logical block and with the fourth input-output of the sixth logical block, the second input-output of the fifth logical block is connected with the second input-output of the sixth logical block, the first, second, fifth and sixth logical blocks contain the first and fourth wave filters, the multiplexed input-output of the first wave filter is the first the input-output of the corresponding logic unit, the first and second demultiplexed inputs and outputs of the first wave filter are connected respectively to the multiplexed inputs and outputs of the second and third wave filters, the first demultiplexed input and output of the second wave filter is connected to the multiplexed input and output of the fourth wave filter, the first and the second demultiplexed inputs and outputs of which are respectively the sixth and fifth inputs and outputs of the corresponding logical unit, the second demultiplexed input-output of the second wave filter is the fourth input-output of the corresponding logic block, the first and second demultiplexed inputs and outputs of the third wave filter are the third and second inputs and outputs of the corresponding logic block, the third and fourth logical blocks contain the fifth - eighth wave filters , the multiplexed input-output of the fifth wave filter is the first input-output of the corresponding logic block, the first and second demu the fifth multiplexed inputs and outputs of the fifth wave filter are connected respectively to the multiplexed inputs and outputs of the sixth and seventh wave filters, the second demultiplexed input and output of the sixth wave filter is connected to the multiplexed input and output of the eighth wave filter, the first and second demultiplexed inputs and outputs of which are fifth and the fourth inputs and outputs of the corresponding logic unit, the first demultiplexed input-output of the sixth wave filter is is the sixth input-output of the corresponding logic block, the first and second demultiplexed inputs and outputs of the seventh wave filter are the third and second inputs and outputs of the corresponding logic block, the first wave filters of the first, second, fifth and sixth logic blocks, as well as the fifth wave filters of the third and the fourth logical blocks are wave filters of the first type, the second wave filters of the first, second, fifth and sixth logical blocks, as well as the sixth wave filter the third and fourth logical blocks are wave filters of the second type, the third wave filters of the first, second, fifth and sixth logical blocks, as well as the seventh wave filters of the third and fourth logical blocks are wave filters of the third type, the fourth wave filters of the first, second, fifth and sixth logical blocks are wave filters of the fourth type, fourth wave filters of the third and fourth logical blocks are wave filters of the fifth type. 2. The optical signal switch according to claim 1, characterized in that the wave filters of the first to fifth types operate with optical signals with wavelengths numbered in the form of a series of λ1, λ2, λ3, ..., the wavelength increases uniformly as its number increases, multiplexed the input-output of the wave filter of the first type is transparent for optical signals with wavelengths λ1, λ2, λ3, ..., the first demultiplexed input-output of the wave filter of the first type is transparent for optical signals with wavelengths λ1, λ3, λ5, ... and lack of vision Designed for optical signals with wavelengths λ2, λ4, λ6, ..., the second demultiplexed input-output of a wave filter of the first type is transparent for optical signals with wavelengths λ2, λ4, λ6, ... and opaque for optical signals with wavelengths with numbers λ1, λ3, λ5, ..., the multiplexed input-output of the wave filter of the second type is transparent for optical signals with wavelengths with the numbers λ1, λ3, λ5, ..., the first demultiplexed input and output of the wave filter of the second type is transparent for optical signals with lengths ox with the numbers λ1, λ5, λ9, ... and opaque for optical signals with wavelengths with the numbers λ3, λ7, λ11, ..., the second demultiplexed input-output of the wave filter of the second type is transparent for optical signals with wavelengths with the numbers λ3, λ7, λ11 , ... and opaque for optical signals with wavelengths λ1, λ5, λ9, ..., multiplexed input-output of a wave filter of the third type is transparent for optical signals with wavelengths λ2, λ4, λ6, ..., the first demultiplexed input-output wave filter of the third type is transparent to optical signals with wavelengths λ2, λ6, λ10, ... and opaque for optical signals with wavelengths λ4, λ8, λ12, ..., the second demultiplexed input-output wave filter of the third type is transparent for optical signals with wavelengths with numbers λ4, λ8, λ12, ... and opaque for optical signals with wavelengths with numbers λ2, λ6, λ10, ..., the multiplexed input-output of a wave filter of the fourth type is transparent for optical signals with wavelengths with numbers λ1, λ5, λ9, ..., first demultiplexed wave input-output The fourth filter type is transparent for optical signals with wavelengths λ1, λ9, ... and opaque for optical signals with wavelengths λ5, λ13, ..., the second demultiplexed input-output wave filter of the fourth type is transparent for optical signals with wavelengths with numbers λ5, λ13, ... and opaque for optical signals with wavelengths with numbers λ1, λ9, ..., the multiplexed input-output of a wave type fifth filter is transparent for optical signals with wavelengths with numbers λ3, λ7, λ11, ..., the first demultiplex the fifth wave filter input / output is transparent for optical signals with wavelengths λ3, λ11, ... and opaque for optical signals with wavelengths λ7, λ15, ..., the second demultiplexed fifth waveform filter input / output is transparent for optical signals with wavelengths with numbers λ7, λ15, ... and opaque for optical signals with wavelengths with numbers λ3, λ11, ...

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