The present disclosure relates to optical fibers and in particular to methods of forming lenses for optical fibers.
Optical fibers are used for a wide range of optics- and optics-electronics-based applications and systems. In essentially all such applications and systems, light needs to be coupled into and out of the optical fiber in some manner.
One way light is coupled into and out of optical fibers is through the use of optical fiber lenses. An optical fiber lens is a lens that resides at an end of an optical fiber. The optical fiber lens serves to couple light into and/or out of the optical fiber according to the particular needs of the system or application. Optical fiber lenses are used, for example, in optical fiber connectors and optical-coherence-tomography applications.
Several types of optical fiber lenses that are available have light-turning capability. However, such lenses include separate molded parts such as mirrors and lenses that need to be added to the optical fiber. The need for manufacturing separate parts and aligning them during manufacturing adds cost to the fiber-lens system.
An aspect of the disclosure is a method of forming a faceted TIR optical fiber lens on an end of an optical fiber having a first axis. The method includes heating the fiber end to form a bulbous tip; allowing the bulbous tip to cool, the bulbous tip having a refractive index, a center and a curved outer surface; and laser cleaving the cooled bulbous tip to form a facet that intersects the first axis at a facet angle θ that defines the facet as a TIR surface.
Another aspect of the disclosure is the method described above, wherein the facet angle is in a range defined by 25°≦θ≦46°.
Another aspect of the disclosure is a method of forming a faceted TIR optical fiber lens on an end of an optical fiber having a first axis. The method includes heating the fiber end with a defocused infrared laser beam to form a bulbous tip having a refractive index, a center and a curved outer surface having a radius of curvature R, wherein 70 μm≦R≦500 μm; allowing the bulbous tip to cool; and laser cleaving the bulbous tip to define a totally internally reflecting facet for light traveling along the first axis, wherein the curved outer surface and the refractive index define a focal length f of the TIR lens, wherein 100 μm≦f≦500 μm.
Another aspect of the disclosure is a method of transmitting and detecting light from a light source. The method includes operably arranging the light source relative to a faceted total-internal-reflection (TIR) optical fiber lens that is integrally formed at an end of the optical fiber. The faceted TIR optical fiber lens is defined by a bulbous tip having a curved outer surface and a facet that defines a TIR surface. The facet defines a second axis that intersects the first axis. The method also includes coupling light into the faceted TIR optical fiber lens along one of the first and second axes, and detecting the light along the other of the first and second axes.
Additional features and advantages are set forth in the Detailed Description below, and in part will be readily apparent to those skilled in the art from the description or recognized by practicing the embodiments as described in the written description and claims hereof, as well as the appended drawings. It is to be understood that both the foregoing general description and the following Detailed Description are merely exemplary and are intended to provide an overview or framework to understand the nature and character of the claims.
The accompanying drawings are included to provide a further understanding and are incorporated in and constitute a part of this specification. The drawings illustrate one or more embodiment(s) and together with the Detailed Description serve to explain principles and operation of the various embodiments. As such, the disclosure will become more fully understood from the following Detailed Description, taken in conjunction with the accompanying Figures, in which:
Reference is now made in detail to various embodiments of the disclosure, examples of which are illustrated in the accompanying drawings. Whenever possible, the same or like reference numbers and symbols are used throughout the drawings to refer to the same or like parts. The drawings are not necessarily to scale, and one skilled in the art will recognize where the drawings have been simplified to illustrate the key aspects of the disclosure.
The claims as set forth below are incorporated into and constitute a part of this Detailed Description.
The entire disclosure of any publication or patent document mentioned herein is incorporated by reference.
The notation “μm” is used herein as an abbreviation for “micron” or “microns.”
The exposure time necessary to form bulbous tip 44 depends on the F/# of focusing lens 36, the distance d1 from fiber end 14 to focus F1 and the amount of power in laser beam 30 at the fiber end. The parameters needed to form bulbous tip 44 so that it has a substantially spherical shape can be determined empirically. In an example, fiber end 14 is processed within an atmosphere of inert gas (e.g., N2) to prevent oxidization. In an example, laser 32 outputs laser beam 30 having a total power in the range from 5 W to 50 W, focusing lens 36 has an F/# of about 10, the distance d1 is about 300 μm, and the exposure time is about 1 second.
The bulbous tip 44 can be formed using heating means other than laser 32, such as by a flame or an arc of a splice unit, for example. However, using additional or more complex physical processes to form bulbous tip 44 tends to increase the cost of the process, and these physical processes may also prove more difficult to implement.
In forming bulbous tip 44, the “new” fiber end 14 does not necessarily correspond to the location of transition location 15. This is because the heating process used to form bulbous tip 44 generally blends the glass that makes up the portion of fiber 10 adjacent the bulbous tip. Accordingly,
Once bulbous tip 44 has been formed, it is cleaved. In an example, a laser is used to perform the cleaving operation.
Because facet 60 defines a TIR surface, it serves to form second axis 62 that intersects first axis 12 at an angle β (see
The facet angle θ is such that light 70 traveling generally along first axis 12 or folded second axis 62 within a reasonable angular range can undergo total-internal reflection (TIR) at facet 60 within bulbous tip 44. For a silica-based fiber 10, bulbous tip 44 is made substantially of silica, which has a refractive index n of about 1.45 at the infrared wavelengths transmitted by most optical fibers. The critical angle φC associated with this refractive index and measured relative to the surface normal of the surface in question is given by φC=arcsin (1/1.45)≈44°. For bulbous tip 44, this translates into a critical facet angle θC=90°−φC. In the above example, θC=90°−44°=46°. For a facet angle θ>θC, there will be no TIR within bulbous tip 44. Thus, in an example embodiment, facet angle θ is such that the TIR condition within bulbous tip 44 is satisfied, i.e., θ≦θC. In an example embodiment, the facet angle θ is the range defined by 25°≦θ≦46°.
Light traveling in fiber 10 as guided light 70 can be described as diverging starting substantially at effective fiber end 14′, which in an example defines an object plane OP. A configuration where facet 60 intersects center 48 of bulbous tip 44 ensures that diverging light 70 reflected via TIR by the facet and then focused by the remaining portion of surface 46 of the bulbous tip is centered and symmetrical relative to folded second axis 62. The light 70 thus forms the smallest possible focus spot at image plane IP. An example range for focal length f is defined by 100 μm ≦f ≦500 μm, while in another example the range is defined by 125 μm ≦f ≦200 μm.
In an example of TIR lens 45, facet 60 does not intersect center 48 of bulbous tip 44.
For example, with reference to
Thus, an aspect of the disclosure includes a method of directing light from light source 100. The method includes coupling light 70 from light source 100 into fiber 10. The method also includes light 70 diverging starting substantially at effective fiber end 14′. This diverging light 70 is then reflected by facet 60 by TIR to direct the light along second axis 62 and through a portion of curved outer surface 46 of TIR lens 45. The method further includes forming an image at image plane IP, which resides outside of the TIR lens.
Another aspect of the disclosure is a method of directing light 70 from light source 100 into fiber 10. The method includes operably arranging light source 100 relative to TIR lens 45 along second axis 62. The method also includes directing light 70 from light source 100 along second axis 62 and passing the light through a portion of lens surface 46 to focus the light and then reflect this light from facet 60 via TIR. The TIR light 70 then forms an image substantially at effective fiber end 14′ of fiber 10. This light 70 then enters optical fiber 10 and travels down the optical fiber as guided light.
Design Examples
In practice, the object OB is a circle of light of diameter DOB at effective fiber end 14′. The diameter DOB corresponds to the size of the mode of guided light 70, which in an example is the mode-field diameter of the guided light as defined by the 1/e2 intensity drop off. For SP-28 single-mode fiber 10, the diameter DOB is about 9 microns.
The image IM is also a circle of light (or “light spot” or “focus spot”) having a nominal diameter DIM. The relative sizes of the light-spot object OB and corresponding light-spot image IM are related through the magnification M of TIR lens 45 via the relationship M=DIM/DOB. The optical axis of TIR lens 45 is represented by axis 12 since the axis is unfolded. The reversal of the orientation of image IM and object OB relative to axis 12 indicates a negative magnification.
The axial distance from object plane OP to lens surface 46 (i.e., the object distance) is denoted by s, and the distance from the lens surface to the image plane IP (i.e., the image distance) is denoted by s′. The refractive index of optical fiber 10 is assumed to be a constant value n between the object plane OP and lens surface 46. The refractive index of the medium between lens surface 46 and image plane IP is denoted n′.
The two equations of interest for TIR lens 45 as depicted in
n′/s′=(n′/f)+(n/s) and
1/f=(n−1)/R,
where f is the focal length, and R is the radius of curvature of lens surface 46. It is assumed that the radius R of lens surface 46 will not be smaller than the fiber diameter DF, which in an example is 62.5 microns. In an example, radius R can be in the range from about 70 microns to about 500 microns. In an example, object distance s can be in the range defined by 100 μm≦s≦2,000 μm. Also in an example, image distance s′ can be in the range defined by 200 μm≦s′≦4000 μm
A first example of TIR lens 45 has the design parameters as set forth below in Design Table 1, with the distance parameters given in microns and the sign of the distance parameters measured relative to the apex of lens surface 46.
For a single-mode fiber that has a DOB of about 9 microns, the diameter DIM for spot image IM at image plane IP is about 16 microns. These design parameters are suitable for cardiac OCT applications, as well as for VCSEL telecommunication transmitters.
A second example embodiment of TIR lens 45 is set forth in Design Table 2 below.
The image diameter DIM is about 30 microns if a single-mode fiber 10 with a diameter DOB of about 9 microns is used. This size for image IM is well matched to the photosensitive area of a high-speed photodiode.
It will be apparent to those skilled in the art that various modifications to the preferred embodiments of the disclosure as described herein can be made without departing from the spirit or scope of the disclosure as defined in the appended claims. Thus, the disclosure covers the modifications and variations provided they come within the scope of the appended claims and the equivalents thereto.
This application claims the benefit of priority under 35 U.S.C. §119 of U.S. Provisional Application Ser. No. 61/826,152, filed on May 22, 2013, the content of which is relied upon and incorporated herein by reference in its entirety.
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