Power monitoring device for powerful fiber laser systems

A pig-tailed optical component used in a powerful fiber laser system is configured with a power monitor unit. The monitor unit has a plate-shaped beam splitter operative to reflect portions of at least one of respective forward and backreflected light signals, and multiple photo-detectors.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to a powerful fiber laser system and, in particular, to an optical coupler configured to monitor the power of forward and backreflected light signals propagating along a light path in forward and backward directions, respectively.

2. Prior Art Discussion

A powerful fiber laser system typically includes one or more laser cascades and is capable of outputting tens and hundreds of watts. A light signal propagating along a powerful fiber laser system may vary within a broad range. The instability of the propagating signal detrimentally affects the task to be performed by a powerful laser system and the functionality of the system's components. To monitor the variation of power of light signals, optical laser systems are provided with taps. The purpose of such taps is to bleed off a small portion of optical signal so as to analyze the signal for desirable characteristics by a photo-detector.

Quite often, to prevent detrimental effect of light backreflection that may be caused by inner obstacles, such as splices coupling adjacent fibers, optical isolators are coupled between the cascades. The backreflection can be also caused by an outer obstacle, such as the surface to be processed during, for example, cutting and welding processes. Typically, a hybrid structure configured with an isolator and tap is installed in a powerful laser system

The taps alone or in combination with isolators come in a variety of configurations.FIGS. 1 and 2, for example, illustrate a multi-cascaded fiber laser system10including an input cascade Li11and at least one output cascade Lo12. A power monitor14preferably, but not necessarily, is coupled to the output of output cascade12and includes serially coupled an isolator core and a fiber tap. The fiber tap is configured with a fiber tap source and a photo detector16, as illustrated inFIG. 2. Typically, detector16is located adjacent to a fiber bent or a taper where leaking light of the propagating signal may be sensed by detector16. Based on multiple measurements, the stability of such a tap, i.e., the ratio between the measured power and the actual power of the propagating signal, is high and may reach about 10%. As a result, the measurement data of the actual power may be imprecise and lead to unsatisfactory performance of the laser system.

A need, therefore, exits for a power monitor operative to provide improved measurements of the power of light signals generated by a powerful laser system.

A further need exists for a photo detector configured to withstand relatively high powers of the tapped signal.

SUMMARY OF THE INVENTION

These needs are satisfied by a power monitor unit configured in accordance with the present disclosure. The disclosed powerful fiber laser system includes, among others, an isolator core provided with a tap component.

In accordance with one aspect of the disclosure, the monitor includes a semi-transparent plate entrained by light which propagates from an input fiber to an output fiber through an isolator core. The plate has two opposite faces, at least one of which is covered by a reflective coating. The coated face of the plate allows to reroute or tap a small portion of a forward propagating light and a backreflected propagating light, which is reflected from internal or external obstacles, to one or more photo detectors. Alternatively, the opposite faces can be covered by respective reflective coatings. As a consequence, one of the coated faces taps a forward propagating light, whereas the opposite face taps a portion of the backreflected light; the tapped lights are sensed by respective photo detectors. The configuration of the disclosed power monitor allows for the increased stability of the measurements.

The light tapped off by the plate is still quite powerful to saturate, destroy or, at least, cause a photometer to malfunction. Accordingly, in accordance with a further aspect of the disclosure, the face of the photometer has a diffuser substantially weakening the received light. As a result, the reliability of the disclosed system is improved.

SPECIFIC DESCRIPTION

Reference will now be made in detail to the disclosed system. Wherever possible, same or similar reference numerals are used in the drawings and the description to refer to the same or like parts or steps. The drawings are in simplified form and are far from precise scale.

FIG. 3illustrates a signal power monitor system including a pigtailed linearly-polarized isolator20typically intended for use in a powerful laser system LS, which is shown in a highly diagrammatic manner and may include one or multiple cascades. The signal power monitor system is preferably coupled to the output cascade, but may be located between the cascades. The isolator20includes an upstream fiber22carrying a light signal Ii along a light path to a downstream fiber24. Optically coupled between upstream and downstream fibers22and24, respectively, is an isolator core26, which is provided with a tap coupler monitor32and flanked by input and output collimators28and42, respectively.

In operation, input signal Ii is emitted from input fiber22and focused by input collimator28so as to propagate in a forward direction Df through isolator core26. The isolator core26has a well known structure including an upstream polarizer34, a 45° optically active rotator element36, a Faraday rotator38and an output polarizer40all optically connected to one another. The rotation of the plane of polarization provided by Faraday rotator38in one direction allows light to pass through both polarizers34and40, respectively, which polarize light in orthogonal planes, whereas, in the opposite direction, the plane of polarization is rotated so that the passage of the light through isolator core26is blocked. As known, a polarizer is a device for producing light beam polarized in a specific direction. The input polarizer34is configured as a plate with a polarizing coating and is typically aligned to a linear polarization angle of input light Ii. The polarizing coating is important within the context of high power laser systems since it is capable of withstanding high powers without being destroyed. The isolator20may have an additional input polarizer34′ in order to provide for polarizing ability. The output polarizer40is aligned to a non-parallel polarization angle so as to transmit this polarization state at the angle of 90° or 0°, as known to one of ordinary skills sin the art.

Referring toFIG. 4in addition toFIG. 3, tap coupler monitor32includes a splitter46optically coupled between output polarizer40and output collimator42and photo detectors44and52, respectively. In the forward direction, splitter46is operative to branch a small portion, tap signal Iti, of Ii signal off its light path through a short-focal lens53to photodetector44capable of sensing tap signal Iti. The splitter46is configured as a rectangular plate having opposite faces48and50which extend in a non-orthogonal plane with respect to an optical axis A-A′ of system20. Note that splitter46can be installed at any location along the optical path between input and output collimators28and42, respectively. Accordingly, the location of splitter46as shown inFIG. 3is just exemplary.

In accordance with one embodiment, both faces48and50(FIG. 4) of splitter46are covered by respective anti-reflective coating films capable of reflecting only a small portion of forward light signal Ii and backreflected light signal Iir to respective photo-detectors44and52, which are operative to simultaneously sense the forward propagating and backreflected lights. The experimental data shows that the stability of tap coupler monitor32, that is a ratio Pti/Pi between the power Pti of tap signal Iti and the power Pi of light signal Ii, can be about 10% and even smaller, particularly, if the isolator is linearly polarized. As a result, the data regarding the power of input light signal Ii and, therefore, the data regarding the functionality of system20is substantially more reliable than in the known prior art of powerful laser systems.

Alternatively, either face48or face50of slitter46can be coated with a film. The coated face is thus operative to tap both the forward propagating and backreflected signals. Note that either coated or uncoated face can tap the light. The faces48and50can extend in parallel planes, as shown inFIG. 4. However, faces48and50can be configured to extend in non-parallel planes.

FIG. 5illustrates photodetector44, which is configured, for example, as a pin photodiode. The percentage of tapped light Iti can be as small as about half a percent of light signal Ii. However, even such a negligible portion of the Ii signal in powerful laser systems may be detrimental to sensitive photo detectors. To avoid the possibility of destruction of photodiode44, its surface may have a diffuser54formed by applying and cooling a drop of epoxy resin or any other material capable of adequately scattering the incident light. Experimental data shows that diffuser54provides for about 3-15 dB attenuation of the reflected signal while backreflecting a negligible portion of the Iti signal. The configuration of photo detectors44and52is identical and, in addition to being configured as a photodiode, can include any other known photodetecting element which may be provided with diffuser54. The measurement of oppositely propagating forward and backreflected light signals may be simultaneous or sequential. While two detectors44and52are shown, only one can be used for measuring the power of light signal propagating in the desired direction, as known to one of ordinary skills in the art.

Returning toFIG. 4, splitter46is preferably a relatively thick plate. Accordingly, photo-detectors44and52, respectively, are axially offset relative to one another to accommodate for the thickness of splitter46.

The above description of the power monitor unit including splitter46and photodetectors44,52relates to an optical isolator. However, as readily understood by one of ordinary kills in the laser art, the disclosed power monitor system may be easily associated with other optical elements, as discussed immediately below.

FIG. 6Adiagrammatically illustrates an optical system including in part input and output collimators56,58, respectively flanking an optical filter64and the disclosed power monitor unit which includes a splitter60and one or two photodetectors62. The splitter60is configured in accordance with the above disclosed splitter. The optical filter64is well known to one of ordinary skills in the laser art and needs not to be disclosed in detail.FIG. 6Bdiagrammatically illustrates a further application of the disclosed power monitor unit including splitter60and photodector(s)62, which are located between input and output collimators56,58, respectively. In this configuration, the disclosed power monitor unit functions simply as a power meter.FIG. 6Cdiagrammatically illustrates an optical circulator66located between input and output collimators56,58, respectively, and optically coupled to the disclosed power monitor unit. As readily understood by one of ordinary skills in the laser art, other applications of the disclosed power monitor unit can be easily envisioned.

It will be apparent to those skilled in the art that various modifications and variations can be made in the presently disclosed laser powerful system. Thus, it is intended that the present disclosure cover the modifications and variations of this disclosure provided they come within the scope of the appended claims and their equivalents.