JP6943370B2 - High-speed multi-core batch optical switch system - Google Patents

Description

The present invention relates to an optical communication technique, and more specifically, the present invention relates to a system capable of collectively switching light from a multi-core fiber.

A multi-core batch optical switch having 1 input and 2 output ports corresponding to a 7-core optical fiber composed of a core separation element, a condensing optical system, and a micromirror optical switch element has been proposed. This switch device uses a core separation element connected to a multi-core optical fiber to emit the optical signal of each core of the multi-core optical fiber into the space in the same direction as an optical beam, and the optical beam of all cores is emitted by the condensing optical system. Are bundled and focused on a micromirror optical switch element, and the path is switched by controlling the mirror accuracy and changing the traveling direction of the optical beams of all cores at once.

L. E. Nelson, et. Al., Spatial Superchannel Routing in a Two Span ROADM System for Space Division Multiplexing, JLT, Vol. 32, No. 4, pp.783-789, 2014

A micromirror optical switch element is used in the above switch device. The micromirror optical switch element needs to be driven mechanically. Therefore, the above-mentioned switch device has a problem that high-speed route switching cannot be realized.

Therefore, a switch system that does not need to be driven mechanically and can realize high-speed route switching that can be controlled at high speed is desired.

The present invention basically includes a spatial light modulation element that does not need to be mechanically driven, and a telecentric optical system capable of making the main ray of an optical beam parallel to the optical axis. A spatial light modulation element changes physical characteristics such as refractive index and transmittance at high speed by applying an external force such as voltage or pressure to the element, and diffracts a plurality of light beams by forming a diffraction grating in the entire element. High-speed control is performed collectively for the traveling direction of all beam bundles passing through. By using a telecentric optical system that can align the incident angles to the elements by making the optical axes parallel, the optical axes of the optical beams of all cores of the multi-core optical fiber are aligned in parallel, and the incident angles to the spatial optical modulation element. Since the difference between the above is controlled and the diffracted light intensity and the diffraction angle of the light beams of all cores become constant, a spatial optical modulation element capable of high-speed operation can be used as an element of a multi-core batch optical switch.

The present invention relates to an optical switch system. This optical switch system
Multi-core fiber 3 and
Spatial light modulation element 5 for collectively switching beam bundles emitted from a plurality of cores of the multi-core fiber 3 to any of the plurality of multi-core fibers, and
It has a control unit 7 for controlling the spatial light modulation element 5.

The spatial light modulation element 5 is preferably an acoustic optical element that deflects at high speed by sound waves.

This optical switch system preferably further includes a first optical system 9 for transmitting beam bundles emitted from a plurality of cores of the multi-core fiber 3 to the spatial light modulation element 5.
The first optical system 9 is, for example,
A collimating lens 11 for converting an optical beam emitted from a plurality of cores of the multi-core fiber 3 into a collimating beam.
It has a condensing lens 13 for reducing the beam diameter so that a plurality of collimated beams emitted from the collimating lens 11 can be incident on the spatial light modulation element 5.

This optical switch system preferably further includes a first optical system 9 for transmitting beam bundles emitted from a plurality of cores of the multi-core fiber 3 to the spatial light modulation element 5.
The first optical system 9 is, for example,
A collimating lens 11 for converting an optical beam emitted from a plurality of cores of the multi-core fiber 3 into a collimating beam.
It has a condenser lens 13 having a focal length shorter than that of the collimating lens 11 so as to narrow the beam interval so that a plurality of collimating beams emitted from the collimating lens can be incident on the spatial light modulation element 5.

Next, the present invention provides an optical switch method.
The light beams emitted from the plurality of cores of the multi-core fiber 3 are adjusted by using the collimating lens 11 and the condenser lens 13 so as to be incident on the spatial light modulation element 5 at a desired angle. By collectively controlling the entire spatial light modulation element 5, the direction in which a plurality of light beams incident on the spatial light modulation element 5 are emitted from the spatial light modulation element 5 is controlled. Then, each of the plurality of light beams traveling in the controlled direction travels to each core of the selected multi-core fiber.

The present invention can provide a switch system that does not need to be driven mechanically and can realize high-speed path switching.

FIG. 1 is a conceptual diagram for explaining the optical switch system of the present invention.

Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. The present invention is not limited to the forms described below, but also includes those which are appropriately modified by those skilled in the art from the following forms to the extent obvious to those skilled in the art.

FIG. 1 is a conceptual diagram for explaining the optical switch system of the present invention. As shown in FIG. 1, this optical switch system includes a multi-core fiber 3 (first multi-core fiber), a spatial light modulation element 5, and a control unit 7. The spatial light modulation element 5 is an element for collectively switching beam bundles emitted from a plurality of cores of the multi-core fiber 3 to any of the plurality of multi-core fibers 23 and 25. The control unit 7 includes a control unit 7 for controlling the spatial light modulation element 5.

The multi-core fiber 3 is also called a multi-core optical fiber, and is an optical fiber having a plurality of cores in one fiber. Examples of core numbers are 7, 12, 19, 32, and 39. The spatial light modulation element 5 means an element whose refractive index and physical properties change when an external force such as voltage or pressure is applied. When the control unit 7 controls the spatial light modulation element 5 (for example, by performing phase modulation or changing the refractive index), the traveling direction of the beam bundle output from the spatial light modulation element 5 changes collectively. do. Therefore, the beam bundles emitted from the plurality of cores of the multi-core fiber 3 can be collectively switched to any one of the plurality of multi-core fibers.

The spatial light modulation element 5 is preferably an acoustic optical element. By using an acoustic optical element, a plurality of light beams can be collectively controlled by one control signal. When an electrical control signal is applied from the control unit 7 to the acoustic optical element, the lattice width of the diffraction grating formed on the entire element changes, and the deflection angle changes. As a specific example, an electrical control signal of 0 V to 3.3 V can be switched and applied in a cycle of 10 microseconds. In this way, the traveling direction of the beam bundle changes all at once. The control unit 7 may store the given electric signal and the change in the traveling direction of the beam bundle in advance, and change the signal applied to the spatial light modulation element 5 based on the input information. In this way, by changing the control signal from the control unit 7, the beam bundle can be guided to the target multi-core fibers 23 and 25. Examples of acoustic optics are an acousto-optic variable filter (AOTF), an acousto-optic modulator (AOM), an acousto-optic deflector (AOD), an acousto-optic beam splitter (AOBS), and an acousto-optic beam manager (AOBM).
The basic structure of the acoustic optics includes a crystal and a transducer mounted on the crystal. Transducers are typically configured to receive electronic signals in the radio frequency range of 30Mhz to 800Mhz. Transducers convert electronic signals into acoustic signals by physically contracting and expanding according to the electronic signal. Quartz forms an optical equivalent of an optical diffraction grating that physically oscillates according to an acoustic signal and thus selectively deflects light of a particular wavelength. Especially in AOTF, the properties of quartz result in each acoustic wavelength deflecting only a particular light wavelength, or particularly a narrow light wavelength bandwidth of, for example, about 3 nm. On the other hand, only wavelengths that exactly correlate with each acoustic frequency are 100 percent deflected, while adjacent wavelengths within the narrow 3 nm band are deflected by a lower percentage, for example 50 percent. By utilizing such a property and giving a predetermined control signal to the acoustic optical element, the traveling direction of the emitted beam bundle can be changed. However, the crystal in this case refers to a typical material that can be used for an acoustic optical element, and is not limited to this.

This optical switch system preferably further includes a first optical system 9 for transmitting beam bundles emitted from a plurality of cores of the multi-core fiber 3 to the spatial light modulation element 5.
The first optical system 9 constitutes, for example, a front telecentric optical system. This is usually for narrowing the beam width of the beam bundle emitted from the plurality of cores of the multi-core fiber 3 and transmitting it to the spatial light modulation element 5.

One example of the first optical system 9 includes a first collimating lens 11 and a first condensing lens 15. The collimating lens 11 is an optical element for using a light beam emitted (exited and diverged) from a plurality of cores of the multi-core fiber 3 as a collimating beam.
The condenser lens 15 is an optical element that reduces the beam diameter of a bundle of the plurality of collimating beams so that the plurality of collimating beams emitted from the collimating lens 11 can be incident on the spatial light modulation element 5.

Another example of the first optical system 9 includes a first collimating lens 11 and a first condensing lens 15. The collimating lens 11 has a focal length shorter than that of the condensing lens 15 so that the total diameter of all the beam luminous fluxes including the beams emitted from all the cores is minimized.

The rear telecentric optical system 21 may be configured from the spatial light modulation element to the output fiber. That is, the beam bundle may be guided to the respective multi-core fibers 23 and 25 by using an optical system having lenses 27 and 31 and collimators 29 and 33. Each light beam output from the collimator may be designed to reach the corresponding core of the multi-core fiber.

The rear telecentric optical system 21 from the spatial light modulation element to the output fiber is not limited to the output of two paths, but may be a switch for switching ON / OFF of the one-path output that extracts only the first-order diffracted light, or the second-order diffracted light, 3 A multi-path selector switch that extracts the next diffracted light may be used.

Next, the present invention provides an optical switch method.
The light beams emitted from the plurality of cores of the first multi-core fiber 3 are adjusted by using the collimating lens 11 and the condensing lens 15 so as to be incident on the spatial light modulation element 5 at a desired angle. The control unit 7 collectively controls the entire spatial light modulation element 5 to control the direction in which a plurality of light beams incident on the spatial light modulation element 5 are emitted from the spatial light modulation element 5. Then, the light beams emitted from the plurality of cores of the first multi-core fiber 3 reach the desired multi-core fibers 23 and 25. Then, each of the plurality of light beams traveling in the controlled direction travels to the respective core of the selected multi-core fiber.

The light beams emitted from the plurality of cores of the first multi-core fiber 3 are combined with a telecentric optical system in which the main ray and the optical axis from each core are parallel by the optical system 9 provided with the collimating lens 11 and the condenser lens 15. Further, the spatial optical modulation element 5 is arranged at an angle and a position where the maximum diffraction efficiency can be obtained with respect to the spatial optical modulation element 5. When the space modulation element 5 does not diffract, the condenser lens 27, the collimating lens 29, and the multi-core fiber 23 are arranged so as to form a telecentric optical system on both sides of the space modulation element 5, and the space modulation element 5 is diffracted. In this case, the condenser lens 31, the collimating lens 33, and the multi-core fiber 25 are similarly arranged so as to form a telecentric optical system on both sides. It operates as an optical switch in response to the high-speed deflection action of the space modulation element 5 by these arrangements and the control signal emitted from the control unit 7.

The present invention can be used in the field of optical information communication.

3 Multi-core fiber 5 Spatial light modulation element 7 Control unit 9 First optical system 11 Collimating lens 13 Condensing lens

Claims (5)

Multi-core fiber (3) and
A spatial light modulation element (5) for collectively switching beam bundles emitted from a plurality of cores of the multi-core fiber (3) to any one of the plurality of multi-core fibers.
It has a control unit (7) for controlling the spatial light modulation element (5).
An optical switch system,
Further having a first optical system (9) for transmitting beam bundles emitted from a plurality of cores of the multi-core fiber (3) to the spatial light modulation element (5).
The first optical system (9) is
A collimating lens (11) for collectively forming the beam bundles emitted from the plurality of cores of the multi-core fiber (3) into a collimating beam.
It has one condenser lens (13) for allowing the collimated beam to be collectively incident on the spatial light modulation element (5).
Optical switch system . The optical switch system according to claim 1.
The spatial light modulation element (5) is an optical switch system which is an acoustic optical element. The optical switch system according to claim 1.
The condenser lens (13)
The beam diameter is reduced so that the collimated beam emitted from the collimating lens (11) can be incident on the spatial light modulation element (5).
Optical switch system. The optical switch system according to claim 1.
The condenser lens (13)
So as to narrow the beam spacing of the collimated beam emitted from the collimating lens, is shorter focal length than the collimating lens (11),
Optical switch system. This is a step of adjusting the beam bundles emitted from the plurality of cores of the multi-core fiber (3) so as to be incident on the spatial light modulation element (5) by using the collimating lens (11) and the condenser lens (13). ，
A step in which the collimating lens (11) collectively forms a collimating beam from beam bundles emitted from a plurality of cores of the multi-core fiber (3).
A step including a step of allowing the condenser lens (13) to collectively incident the collimating beam on the spatial light modulation element (5), and a step of enabling the collimating beam to be incidentally incident on the spatial light modulation element (5).
By collectively controlling the spatial light modulation element (5), the direction in which the collimated beam incident on the spatial light modulation element (5) is emitted from the spatial light modulation element (5) can be controlled . An optical switching method including a step of collectively switching beam bundles emitted from a plurality of cores of a multi-core fiber (3) to one of a plurality of multi-core fibers.

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