Laser beam brilliance enhancing beam splitting for laser welding/brazing

What is claimed is: 1 . A laser processing head for directing laser light to a workpiece, the laser processing head comprising: a collimator disposed in an optical axis of the laser light and being configured to collimate the laser light into collimated light; a beam splitter disposed at a non-normal angle with respect to the optical axis in the collimated light and having at least two portions, the at least two portions being on a surface of the beam splitter comprising an anti-reflective portion adapted to pass the collimated light through the beam splitter and a high-reflective portion, wherein the at least two portions comprise a peripheral region of the surface and an inner region of the surface, respectively, the peripheral region surrounding the inner region, and the inner region comprising the high-reflective portion, the beam splitter being configured to split the collimated light into first light from a first of the at least two portions and into second light from a second of the at least two portions; a main output disposed in optical communication with the beam splitter, the main output being configured to direct at least the first light into a main laser beam toward the workpiece; and a secondary output disposed in optical communication with the beam splitter, the secondary output being configured to direct at least the second light into a secondary laser beam adjacent the main laser beam. 2 . The laser processing head of claim 1 , wherein the collimator comprises one or more lenses. 3 . The laser processing head of claim 1 , wherein the beam splitter comprises a substrate; wherein the high-reflective portion comprises a high reflective coating lithographically structured on the substrate or on top of an anti-reflective coating. 4 . The laser processing head of claim 1 , wherein the beam splitter is disposed at a lateral position relative to the optical axis, the lateral position being adjustable relative to the optical axis, the lateral position being configured to adjust an amount of the first light, the second light, or the first and second light split by the beam splitter. 5 . The laser processing head of claim 1 , wherein the main output comprises a focusing lens disposed on the optical axis and being configured to focus any of the collimated light, communicated from the beam splitter and incident to the focusing lens, into the main laser beam toward the workpiece. 6 . The laser processing head of claim 5 , wherein the main output comprises at least one reflector disposed in the optical axis between the beam splitter and the focusing lens and being configured to reflect any of the collimated light communicated from the beam splitter and incident to the focusing lens. 7 . The laser processing head of claim 1 , wherein the secondary output comprises: at least one focusing lens disposed in optical communication with the beam splitter and being configured to focus any of the collimated light communicated from the beam splitter and incident to the focusing lens; and at least one waveguide having an input disposed in optical communication with the focusing lens and having an output disposed in optical communication toward the workpiece. 8 . The laser processing head of claim 7 , wherein the waveguide comprises an optical fiber or a bundle of microfibers. 9 . The laser processing head of claim 7 , wherein the output of the waveguide comprises a micro-lens, an optical block, a beam shaping element, or a plain tip. 10 . The laser processing head of claim 1 , the beam splitter being configured to split the collimated light into inner light from the inner region and into peripheral light from the peripheral region; wherein the main output is configured to direct at least the peripheral light as the first light into the main laser beam toward the workpiece; and wherein the secondary output is configured to direct at least the inner light as the second light into the secondary laser beam adjacent the main laser beam. 11 . The laser processing head of claim 9 , wherein the inner region of the beam splitter comprises an elliptical shape, an oval shape, a symmetric shape, an asymmetric shape, a uniform shape, or a non-uniform shape. 12 . The laser processing head of claim 1 , wherein the main output comprises a reflector disposed between the collimator and the beam splitter, the reflector being configured to at least partially reflect any of the collimated light incident thereto. 13 . The laser processing head of claim 1 , wherein the inner region is ovular. 14 . The laser processing head of claim 1 , wherein the inner region has a free-formed shape. 15 . The laser processing head of claim 1 , wherein the inner region has a non-uniform shape. 16 . The laser processing head of claim 1 , wherein the inner region is comprised of a plurality of discrete portions. 17 . The laser processing head of claim 1 , wherein the inner region is offset from the center of the surface. 18 . The laser processing head of claim 1 , further comprising an actuator adapted to laterally translate the beam splitter with respect to the optical axis. 19 . A method to direct laser light to a workpiece, the method comprising: collimating the laser light into collimated light along an optical axis; splitting the collimated light into first light and second light using a beam splitter having at least two portions on a surface of the beam splitter, including an anti-reflective portion adapted to pass the collimated light through the beam splitter and a high-reflective portion, wherein the at least two portions comprise a peripheral region of the surface and an inner region of the surface, respectively, the peripheral region surrounding the inner region, and the inner region comprising the high-reflective portion; directing at least a portion of the first light into a main laser beam toward the workpiece; and directing at least a portion of the second light into a secondary laser beam toward the workpiece. 20 . The method of claim 19 , further comprising delivering a wire to the main laser beam; and wherein directing at least the portion of the first light into the main laser beam toward the workpiece comprises melting the wire with the main laser beam. 21 . The method of claim 19 , wherein splitting the collimated light into the first light and the second light using the beam splitter comprises: reflecting the second light from the high-reflective portion in an inner area of the beam splitter, and passing the first light through the anti-reflective portion in a peripheral area of the beam splitter. 22 . The method of claim 19 , wherein directing at least the portion of the second light into the secondary laser beam toward the workpiece comprises: pre-heating the workpiece using the secondary laser beam before a joint is made; or heating the workpiece using the secondary laser beam after a joint is made. 23 . The method of claim 19 , further comprising adjusting an amount of the second light directed to the secondary beam by translating the beam splitter perpendicular to the optical axis.