Multimode launch systems for use in performing an otdr measurement on a multi-fiber array dut and method of performing same

What is claimed is: 1 . A multimode launch system to be connected to an Optical Time-Domain Reflectometer (OTDR) for use in performing at least one OTDR measurement on a multi-fiber array Device Under Test (DUT), the multimode launch system comprising: an optical switch having an input multimode optical fiber and a plurality of output multimode optical fibers, the optical switch being configured to receive test light from the OTDR into the input multimode optical fiber and to selectively transmit the received test light into one of the plurality of output multimode optical fibers during use; a launch array device having an end being connectable to the plurality of output multimode optical fibers of the optical switch and another end being connectable to the multi-fiber array DUT during use, the launch array device having a plurality of multimode launch optical fibers each having at least one first guidance parameter being smaller than a corresponding one of at least one second guidance parameter of at least one of the input multimode optical fiber and the plurality of output multimode optical fibers of the optical switch; and a multi-fiber mode conditioner along the launch array device for inducing a preferential attenuation of higher-order optical modes of test light propagated into the multi-fiber array DUT during use. 2 . The multimode launch system of claim 1 wherein the at least one first guidance parameter includes a first fiber core diameter and the corresponding one of the at least one second guidance parameter is a second fiber core diameter. 3 . The multimode launch system of claim 2 wherein the first fiber core diameter is 50 μm and the second fiber core diameter is 62.5 μm. 4 . The multimode launch system of claim 1 wherein the at least one first guidance parameter includes a first numerical aperture and the corresponding one of the at least one second guidance parameter is a second numerical aperture. 5 . The multimode launch system of claim 4 wherein the first numerical aperture is 0.2 and the second numerical aperture is 0.27. 6 . The multimode launch system of claim 1 further comprising a mode filter connectable between the input multimode optical fiber of the optical switch and the OTDR during use, the mode filter inducing a preferential attenuation of higher-order optical modes. 7 . The multimode launch system of claim 6 wherein the mode filter has a portion of optical fiber having a guidance parameter being substantially equal to the first guidance parameter. 8 . The multimode launch system of claim 6 wherein the mode filter has a portion of a multimode optical fiber wrapped around a mandrel of a given diameter. 9 . The multimode launch system of claim 6 wherein the mode filter, the optical switch and the launch array device are removably connectable to the OTDR. 10 . The multimode launch system of claim 6 wherein the mode filter, the optical switch and the launch array device are mounted inside the OTDR. 11 . The multimode launch system of claim 1 wherein the multi-fiber mode conditioner includes wrapping a portion of each of the plurality of multimode launch optical fibers around a mandrel of a given diameter. 12 . The multimode launch system of claim 1 wherein the plurality of output multimode optical fibers of the optical switch and the launch array device are connected via multi-fiber array connectors. 13 . The multimode launch system of claim 12 wherein the multi-fiber array connectors are multimode multi-fiber angle-polished array connectors. 14 . The multimode launch system of claim 1 wherein the launch array device has at least one end being terminated by a multimode multi-fiber angle-polished array connector. 15 . The multimode launch system of claim 15 wherein the optical switch has an end being terminated by an angle-polished connector and connectable towards the OTDR. 16 . The multimode launch system of claim 6 wherein the launch array device has at least one end being terminated by a multimode multi-fiber angle-polished array connector and wherein the mode filter is terminated by two angle-polished connectors, one of the angle-polished connectors of the mode filter being connectable to the OTDR and the other one of the angle-polished connectors of the mode filter being connectable to the optical switch. 17 . An OTDR enclosing the multimode launch system of claim 1 , wherein the multi-fiber array DUT is connectable to the optical switch via a multi-fiber array connector of the OTDR. 18 . A method for performing a measurement using an Optical Time-Domain Reflectometer (OTDR) on a multi-fiber array Device Under Test (DUT), the method comprising: using an optical switch, propagating test light received from the OTDR and transmitting the received test light along one of a plurality of multimode launch optical fibers of a launch array device each being connected to a respective one of a plurality of multimode optical fibers of the multi-fiber array DUT; using a multi-fiber mode conditioner of the launch array device, inducing a preferential attenuation of high-order optical fiber modes of the test light being propagated along the launch array device and on a portion of the test light being backscattered along the launch array device; and using the optical switch, scrambling the optical fiber modes of the backscattered portion of test light prior to detection by the OTDR. 19 . The method of claim 18 , using a mode filter, filtering the scrambled optical fiber modes of the backscattered portion of the test light prior to detection by the OTDR. 20 . A multimode launch system to be connected to an Optical Time-Domain Reflectometer (OTDR) for use in performing at least one OTDR measurement on a multi-fiber array Device Under Test (DUT), the multimode launch system comprising: an optical switch being connectable to the OTDR during use; a launch array device having an end being connectable to the optical switch and another end being connectable to the multi-fiber array DUT during use, the launch array device having a plurality of multimode launch optical fibers each having at least one first guidance parameter being smaller than a corresponding one of at least one second guidance parameter of at least one multimode optical fiber of the optical switch; and a multi-fiber mode conditioner along the launch array device for inducing a preferential attenuation of higher-order optical modes of test light propagated into the multi-fiber array DUT during use.