RU2000117854A - OPTICAL MULTIPLEXING DEVICE FOR INPUT / OUTPUT OF CHANNELS - Google Patents

Claims (22)

1. An optical multiplexing device comprising a filter unit defining a light path from a common port to at least a first channel port, a second channel port and a transit port, in that order, wherein the common port and the transit port are substantially transparent at least to the waves of a certain spectral range, the first channel port contains a first optical filter element, essentially transparent to the waves of the spectral subband lying within the specified spectral range its port, and essentially reflecting other wavelengths within this spectral range, and the second channel port contains a second optical filter element having transmission and reflection characteristics that are essentially identical to the characteristics of the first optical filter element, characterized in that the light path from the common port to at least the first channel port, the second channel port and the transit port, in this order, includes (a) a first stretch of the path of the expanded light beam, pass inside a first optical block including a first channel port, (b) a second segment of an extended light beam path passing inside a second optical block including a second channel port, and (c) a waveguide optically connecting a first segment of an expanded light beam path with a second path segment expanded beam of light.  2. An optical multiplexing device comprising an optical unit defining a path of a light beam traveling in a zigzag pattern with multiple reflections from a common port to at least a first channel port, a second channel port and a transit port, in the indicated order, wherein the common port and the transit port are essentially transparent at least for waves of a certain spectral range, the first channel port contains a first optical filter element, essentially transparent for waves of the spectral subband, lies within the specified spectral range of the common port, and essentially reflecting other wavelengths within this spectral range, and the second channel port contains a second optical filter element having transmission and reflection properties that are essentially identical to the characteristics of the first optical filter element, characterized in that each of the first and second optical filter elements contains a multi-cavity interference filter having 3-5 resonators.  3. The optical multiplexing device according to claim 2, characterized in that in the indicated spectral subband, each of the multi-resonator interference filters has a reflection coefficient from -7.5 to -15 dB.  4. The optical multiplexing device according to claim 3, characterized in that the optical unit provides a common isolation of at least -30 dB in the specified spectral subband.  5. The optical multiplexing device according to claim 2, characterized in that the optical unit is essentially rectilinear and forms a gas-filled optical gap between the first surface of the optical unit and the opposite surface, which is located at a distance from the first surface and essentially parallel to it, while the common port is on the first surface, and at least one of the channel ports is on the opposite surface.  6. The optical multiplexing device according to claim 5, characterized in that the common port contains a first collimator aligned to pass the expanded beam through the common port to the first channel port, the first channel port contains a second collimator aligned to receive the extended beam transmitted the first filter element, and the second channel port contains a third collimator, aligned to pass the expanded beam to the second channel port.  7. The optical multiplexing device according to claim 6, characterized in that the transit port comprises a fourth collimator aligned to receive the expanded beam transmitted by the transit port.  8. The optical multiplexing device according to claim 6, characterized in that the first channel port further comprises a post filter placed between the first filter element and the second collimator, wherein the post filter has transmission characteristics substantially identical to those of the first filter element.  9. The optical multiplexing device according to claim 2, characterized in that the optical unit has a first surface and an opposite surface, which is located at a distance from the first surface and essentially parallel to it, the common port is on the first surface, the first channel port is on the opposite surface , the second channel port is on the first surface and the transit port is on the second surface, the first collimator is aligned to pass the expanded beam through the common port at least re to the first portion of the first optical filter element, the first portion of the second optical filter element, the second portion of the first optical filter element and the second portion of the second optical filter element, in this order, in front of the transit port, the second sections having transmission and reflection characteristics of light, essentially identical to the characteristics of the first sections.  10. The optical multiplexing device according to claim 9, characterized in that the first and second sections of the first optical filter element are spaced apart sections of the first single filter component mounted on the second surface of the optical unit.  11. The optical multiplexing device according to claim 9, characterized in that the first and second sections of the second optical filter element are spaced apart from each other sections of the second single filter component mounted on the first surface of the optical unit.  12. The optical multiplexing device according to claim 2, characterized in that it further comprises a housing that limits the enclosed space and has passages for optical waveguides from the enclosed space outside the enclosure, the optical unit being installed inside the enclosed space.  13. The optical multiplexing device according to p. 12, characterized in that the housing hermetically closes the enclosed space.  14. Fiber-optic communication system, characterized in that it contains an optical multiplexing device containing a filter unit that determines the path of light from the common port to at least the first channel port, the second channel port and the transit port, in this order, and the common port and the transit port is essentially transparent at least for waves of a certain spectral range, the first channel port contains a first optical filter element essentially transparent for waves of the spectral subband, lying within the specified spectral range of the common port, and essentially reflecting other wavelengths within this spectral range, and the second channel port contains a second optical filter element having transmission characteristics and light reflection, essentially identical to the characteristics of the first optical filter element, a trunk line waveguide for transmitting signals of multiple channels, optically coupled to a common port, a receive line waveguide optically coupled to a first channel the main port, an input line waveguide optically coupled to the second channel port, and a transit backbone waveguide optically coupled to the transit port.  15. The fiber optic communication system according to claim 14, characterized in that the waveguide of the trunk line, the waveguide of the reception line, the waveguide of the input line and the waveguide of the transit trunk line are fiber optic lines, and each port is of a common, first channel, second channel and The transit port contains a collimator aligned with the corresponding port to focus the light passing through the port.  16. Fiber-optic communication system with spectral multiplexing, containing a trunk fiber optic line for transmitting signals of multiple channels and an optical multiplexing device, which contains an optical unit that determines the path of the light beam passing in a zigzag pattern with multiple reflections from the common port to the first channel port further to the second channel port and then at least to the transit port, wherein the common port and the transit port are essentially transparent to signals of a plurality and channels transmitted over the trunk, the first channel port containing a first optical filter element, essentially transparent to at least one channel signal transmitted by the common port, and essentially reflecting the signals of many channels transmitted by the common port, and the second channel port contains a second optical filter element having light transmission characteristics substantially identical to those of the first optical filter element, characterized in that it also contains up to Additional optical multiplexing devices, each of which includes an optical unit that determines the path of a light beam traveling in a zigzag pattern with multiple reflections from the common port to the first channel port, then to the second channel port and then at least to the transit port, with the common port and the transit port is substantially transparent to the signals of a plurality of channels transmitted over a trunk line, the first channel port comprising a first optical filter element, substantially transparent at least one channel signal transmitted by the common port and substantially reflective for signals of plural channels passed by the common port, and a second channel port comprising a second optical filter element having light transmission characteristics substantially identical to the characteristics of the first optical filter element.  17. The fiber optic communication system according to claim 16, wherein the first channel port and the second channel port are substantially transparent to a single channel signal.  18. The fiber-optic communication system according to claim 16, characterized in that the optical multiplexing devices are arranged sequentially along the trunk line and multiplex the signals of different channels.  19. The fiber optic communication system according to claim 16, characterized in that it further comprises a housing defining an enclosed space in which at least two of said optical multiplexing devices are installed.  20. The method of multiplexing optical signals, according to which a multichannel optical signal is passed from a waveguide to a common port of an optical multiplexing device containing a filter unit that determines the path of light from a common port to at least the first channel port, the second channel port and the transit port, in the specified order where the common port and the transit port are essentially transparent at least for waves of a certain spectral range, the first channel port contains a first optical filtering the first element, essentially transparent to the waves of the spectral subband lying within the specified spectral range of the common port, and essentially reflecting other wavelengths within this spectral range, and the second channel port contains a second optical filter element having transmission and reflection characteristics light essentially identical to the characteristics of the first optical filter element, the signal of a channel located in the aforementioned spectral subband is removed from the multi-channel Nogo channel signal through the first port and the new channel signal is located substantially in the same spectral subband is added to the multi-channel signal through the second channel port.  21. The method of multiplexing optical signals, according to which a multichannel optical signal is passed from the waveguide to the common port of a filter unit that determines the path of light passing with multiple reflections from the common port to the first optical filter element of the first channel port and then to the second optical filter element of the second channel port, then to the second section of the first optical filter element, then to the second section of the second optical filter element and then from the block and the filter through the transit port to the waveguide, the signal of the channel located in the selected spectral subband is removed from the multi-channel signal through the first channel port and the signal of the new channel located in essentially the same spectral subband is added to the multi-channel signal through the second channel port.  22. The method of multiplexing optical signals, according to which a multichannel optical signal is passed from the waveguide through the collimator in the form of an expanded beam to the common port of the optical unit having a first surface and an opposite surface that is located at a distance from the first surface and essentially parallel to it, and the optical unit determines the path of a beam of light passing in a zigzag pattern with multiple reflections from a common port on the first surface to the first section of the first optical filter the friction element of the first channel port on the opposite surface, then to the first section of the second optical filter element of the second channel port on the first surface, then to the second section of the first optical filter element and to the second section of the second optical filter element and then from the optical block through the transit port to the waveguide , the signal of the channel located in the selected spectral subband is removed from the multi-channel signal through the first channel port and the signal of the new channel, ahodyaschegosya in substantially the same spectral sub-band is added to the multi-channel signal through the second channel port.