JPWO2019150097A5 - - Google Patents

Description

According to the first aspect of the present invention, it is an injection synchronous laser system.
A master laser that produces a continuous wave output field with frequency (f ₀ ),
One or one used to generate a first seed light field with a first frequency (f ₁ ) and a second seed light field with a second frequency (f ₂ ) from a continuous wave output field. With multiple optical modulators
Equipped with
The first seed light field provides an input that injects and synchronizes one or more optical amplifiers at the first frequency (f ₁ ), with the one or more optical amplifiers at the first frequency (f ₁ ). Generate one or more continuous wave output fields for injection synchronous laser systems,
The second seed light field provides an input that injects and synchronizes one or more optical amplifiers at the second frequency (f ₂ ), with the one or more optical amplifiers at the second frequency (f ₂ ). Generate one or more continuous wave output fields for injection synchronous laser systems,
Injection synchronous laser system, further
A first phase-locked loop that provides a first feedback signal to one or more optical modulators and a continuous wave output field generated at the first frequency (f ₁ ) in the first optical amplifier. With the first phase-locked control loop, which synchronizes the phase with the continuous wave output field,
A second phase sync control loop that provides a second feedback signal to one or more optical modulators and a continuous wave output field generated at a second frequency (f ₂ ) in the second optical amplifier. Is provided with a system comprising a first phase synchronization control loop for phase synchronization with the continuous wave output field .

According to the second aspect of the present invention, it is a method of injecting and synchronizing two or more optical amplifiers.
-A step to generate a continuous wave output field with frequency (f ₀ ), and
-A step of optically modulating a continuous wave output field using one or more optical modulators , thereby a first seed light field having a first frequency (f ₁ ) and a first. An optically modulated step that creates a second seed light field with a frequency of 2 (f ₂ ),
-A step of utilizing a first seed light field, thereby injecting and synchronizing one or more optical amplifiers at a first frequency (f ₁ ) with a step of utilizing a first seed light field. ,
-The step of using one or more optical amplifiers to generate one or more continuous wave output fields at the first frequency (f ₁ ).
-A step of utilizing a second seed light field, thereby injecting and synchronizing one or more optical amplifiers at a second frequency (f ₂ ). ,
-The step of using one or more optical amplifiers to generate one or more continuous wave output fields at the second frequency (f ₂ ).
-A step that utilizes a first phase-locked loop, which provides a first feedback signal to one or more optical modulators and is generated at a first frequency (f ₁ ) in a first optical amplifier. A step of using a first phase synchronization control loop for phase-synchronizing the continuous wave output field with the continuous wave output field, and
-A step utilizing a second phase-locked loop, which provides a second feedback signal to one or more optical modulators and is generated at a second frequency (f ₂ ) in a second optical amplifier. A step of using a second phase synchronization control loop for phase-synchronizing the continuous wave output field with the continuous wave output field, and
Methods are provided that include.

According to the third aspect of the present invention, the injection synchronous laser system is a master laser that generates a continuous wave output field having a frequency (f ₀ ), and a first frequency (f) from the continuous wave output field. It comprises a first optical modulator utilized to generate a first seed light field having ₁ ), the first seed light field being a first optical amplifier at a first frequency (f ₁ ). Provides input to inject and synchronize,
The injection synchronous laser system further comprises a first phase synchronization control loop that provides the first optical modulator with a feedback signal that allows the output field of the first optical amplifier to be phase synchronized to the continuous wave output field . The system is provided.

Preferably, the injection synchronous laser system further comprises a second optical modulator utilized to generate a second seed light field with a second frequency (f ₂ ) from the continuous wave output field. The second seed light field may provide an input that injects and synchronizes the second optical amplifier to the second frequency (f ₂ ). In this embodiment, the injection synchronous laser system provides a second phase synchronization control that provides the second optical modulator with a feedback signal that allows the output field of the second optical amplifier to be phase synchronized to the continuous wave output field . Further loops may be provided.

According to the fourth aspect of the present invention, it is a method of injecting and synchronizing an optical amplifier.
-A step to generate a continuous wave output field with frequency (f ₀ ), and
-An optically modulated step that optically modulates the continuous wave output field, thereby producing a first seed light field having a first frequency (f ₁ ).
-A step of utilizing the first seed light field, thereby injecting and synchronizing the first optical amplifier to the first frequency (f ₁ ).
-A step of generating a feedback signal, which is a step of generating a feedback signal of the first optical modulator, thereby phase-synchronizing the output field of the first optical amplifier with a continuous wave output field .
Methods are provided that include.

According to the fifth aspect of the present invention, in the injection synchronous laser system, a frequency (f _N ) is obtained from a master laser that generates a continuous wave output field having a frequency (f ₀ ) and a continuous wave output field. It comprises one or more optical modulators utilized to generate one or more seed light fields having one or more seed light fields frequency (f) one or more optical amplifiers. Provides an input to synchronize injection to _N ),
An injection synchronous laser system is one that provides one or more feedback signals to one or more optical modulators that allow the output field of one or more optical amplifiers to be phase-locked to a continuous wave output field . Alternatively, a system is provided that further comprises a plurality of phase-locked control loops.

According to a sixth aspect of the present invention, a method of injecting and synchronizing one or more optical amplifiers with a step of generating a continuous wave output field having a-frequency (f ₀ ).
-An optically modulated step that optically modulates the continuous wave output field, thereby producing one or more seed light fields having a first frequency (f _N ).
-A step that utilizes one or more seed light fields, thereby injecting and synchronizing one or more optical amplifiers to one or more frequencies (f _N ).
-A step of generating a feedback signal of one or more optical modulators, thereby phase-synchronizing the output field of one or more optical amplifiers with a continuous wave output field . ,
Methods are provided that include.

Claims (15)

In the injection synchronous laser system (1, 25)
A master laser (2) that produces a continuous wave output field (4) with a frequency (f ₀ ), and
From the continuous wave output field (4) , a first seed light field (6) having a first frequency (f ₁ ) and a second seed light field (7) having a second frequency (f ₂ ) are obtained. With one or more optical modulators (5, 5a, 5d) used to generate,
Equipped with
The first seed light field (6) provides inputs for injecting and synchronizing one or more optical amplifiers (8ac ) at the first frequency (f ₁ ), said one or more optics. The amplifier (8a-c) generates one or more continuous wave output fields (12a-c) for the injection synchronous laser system (1, 25) at the first frequency (f ₁ ), said. The second seed light field (7) provides an input that injects and synchronizes one or more optical amplifiers (8df ) at said second frequency (f ₂ ) , said one or more optical amplifiers. ( 8df) creates one or more continuous wave output fields (12df) for the injection synchronous laser system (1, 25) at the second frequency (f ₂ ).
Injection synchronous laser systems (1, 25), further
In the first phase-locked loop (27a), the first feedback signal (29a) is provided to one or more of the optical modulators (5, 5a), and the first optical amplifier (8a) is described. A first phase synchronization control loop (27a) that phase-synchronizes the continuous wave output field (12a) generated at the first frequency (f ₁ ) with the continuous wave output field (4).
A second phase-locked loop (27b), wherein the second feedback signal (29b) is provided to one or more of the optical modulators (5, 5d) and said in the second optical amplifier (8d). It is characterized by comprising a first phase synchronization control loop (27a) for phase-synchronizing the continuous wave output field (12d) generated at the second frequency (f ₂ ) with the continuous wave output field (4). System. In the injection synchronous laser system (25) according to claim 1, the injection synchronous laser system (25 ) has N seed light fields having a frequency (f _N ) from the continuous wave output field (4) . A system comprising N optical modulators used to generate. In the injection synchronous laser system (1, 25) according to claim 1 or 2, the first frequency (f ₁ ) is set to the frequency (f ₀ ) of the continuous wave output field (4) . Equal to the sum of the modulation frequencies (Δf ₁ ) introduced by one or more optical modulators (5, 5a) and / or the second frequency (f ₂ ) is the continuous wave output field ( 5, 5a). 4) The system is characterized in that it is equal to the frequency (f ₀ ) minus the modulation frequency (Δf ₂ ) introduced by the one or more optical modulators (5, 5d) . In the injection synchronous laser system (1, 25) according to claim 3, the modulation frequency (Δf) introduced by the one or more optical modulators (5, 5a, 5d) is 0.1 GHz to 40 GHz. A system characterized by being. In the injection-synchronized laser system (1, 25) according to any one of claims 1 to 4, the first seed light field (6) is injection-synchronized by the first seed light field (6). Mode-matched with the one or more optical amplifiers (8a, 8b, 8c) and / or the second seed light field (7) is injected by the second seed light field (7). A system characterized by mode matching with the one or more optical amplifiers (8d, 8e, 8f) being synchronized. In the injection synchronous laser system (1, 25) according to any one of claims 1 to 5, the injection synchronous laser system (1, 25) has one or more frequency synchronization control loops (13, 19) are further provided to frequency synchronize one or more of the optical amplifiers (8ac) to the first seed field (6) and / or frequency synchronization control loops (13). 19), further comprising frequency-synchronizing one or more of the optical amplifiers (8d-8f) with the second seed field (7). In the injection synchronous laser system (1, 25) according to any one of claims 1 to 6, the first phase synchronization control loop (27a) is the first optical amplifier (8a) and the continuous. A first detector configured to generate a first electric beat signal (33a) from a first optical beat signal (32a) generated from a coupled output field (12a) of a wave output field (4). A system comprising 34a). In the injection synchronous laser system (1, 25) according to any one of claims 1 to 7, the second phase synchronization control loop (27b) is the second optical amplifier (8d) and the continuous. A second detector configured to generate a second electric beat signal (33b) from a second optical beat signal (32b) generated from the coupled output field (12d) of the wave output field (4). A system comprising (34b). In the injection synchronous laser system (1, 25) according to any one of claims 1 to 8, the injection synchronous laser system (1, 25) is the master laser (2) and the one or more. Further comprising one or more optical isolators (100) disposed between the optical amplifier (8) and / or the output field, the one or more optical amplifiers (8), and / or the said. A system further comprising one or more frequency doubling stages configured to doubling the frequency of one or more of the components of the continuous wave output field (4). In a method of injecting and synchronizing two or more optical amplifiers (8a-f)
Frequency (f) ₀ ) To generate a continuous wave output field (4), and
A step of optically modulating the continuous wave output field (4) using one or more optical modulators (5, 5a, 5d), thereby the first frequency (f). ₁ The first seed light field (6) and the second frequency (f) having). ₂ ) To generate a second seed light field (7), with an optically modulated step.
This is a step of utilizing the first seed light field (6), whereby the first frequency (f). ₁ ), The step of utilizing the first seed light field, in which one or more optical amplifiers (8a-c) are injected and synchronized, and
The first frequency (f) using one or more of the optical amplifiers (8ac). ₁ ) To generate one or more continuous wave output fields (12ac), and
This is a step of utilizing the second seed light field (7), whereby the second frequency (f). ₂ ), The step of utilizing the second seed light field, in which one or more optical amplifiers (8df) are injected and synchronized, and
The second frequency (f) is utilized by utilizing one or more of the optical amplifiers (8df). ₂ ) To generate one or more continuous wave output fields (12df), and
In the step of utilizing the first phase-locked loop (27a), the first feedback signal (29a) is provided to one or more of the optical modulators (5, 5a) to provide the first optical amplifier (1). In 8a), the first frequency (f) ₁ ), The step of utilizing the first phase synchronization control loop (27a), which synchronizes the phase of the continuous wave output field (12a) with the continuous wave output field (4).
In the step of utilizing the second phase-locked loop (27b), the second feedback signal (29b) is provided to one or more of the optical modulators (5, 5d) to provide a second optical amplifier (2). At 8d), the second frequency (f) ₂ ), The step of utilizing the second phase synchronization control loop (27b), which synchronizes the phase of the continuous wave output field (12d) with the continuous wave output field (4), is included. Method. The method of injecting and synchronizing two or more optical amplifiers (8a-f) according to claim 10.
A step of mode matching the first seed light field (6) with the one or more optical amplifiers (8ac) injection synchronized by the first seed light field (6), and / or.
Further comprising: mode matching the second seed light field (7) with the one or more optical amplifiers (8d-e) injection synchronized by the second seed light field (7). How to feature. The method of injecting and synchronizing two or more optical amplifiers (8af) according to claim 10 or 11.
A step of frequency-synchronizing one or more of the optical amplifiers (8a-c) to the first seed light field (6), and / or.
A method further comprising: frequency-synchronizing one or more of the optical amplifiers (8df) with the second seed light field (7). In the method of injecting and synchronizing two or more optical amplifiers (8a-f) according to any one of claims 10 to 12, the step of generating the first feedback signal (29a) is the optical amplifier (8a-f). A method comprising one step of generating a first optical beat signal (32a) from one of 8a) and the combined output field (12a) of the continuous wave output field (4). In the method of injecting and synchronizing two or more optical amplifiers (8a-f) according to claim 10, the step of generating the second feedback signal (29b) is one of the optical amplifiers (8d) and the above. A method comprising the step of generating a second optical beat signal (32b) from the coupled output field (12d) of the continuous wave output field (4). The method of injecting and synchronizing two or more optical amplifiers (8a-f) according to any one of claims 10 to 14 is
A step of optically separating the continuous wave output field (4) from the one or more optical amplifiers (8a-f), and / or.
Further comprising: doubling the frequency of one or more of the components of the output field (12a-f), the one or more optical amplifiers (8a-f), and the continuous wave output field (4). A method characterized by that.