In 1994, the National Science Foundation (NSF) awarded California State University, Los Angeles funds for the creation of a Fiber Optics (FO) laboratory. The funds were made available through the Advanced Academic Research Infrastructure Program of NSF under grant #ECS-9413705. This three year project which was extended to four years in the 1996-97 academic year, culminated by the end of August 1998 in the creation of a first rate research facility for conducting R&D in the general areas of sensory applications of fiber optics and optical information processing. Many undergraduate and graduate students have already benefited greatly from their experience in this laboratory throughout its development phase, many of whom are already employed and working in the industry.
During the 1997 - 1998 academic year, additional research funds were provided by NSF under grant #ECS-9729224 in order to test a novel idea for analog transmission of images though multi-mode optical fiber cables. This idea (US patent number 5,469,519) constitutes a new analog technique for transmitting an image through a multi-mode optical fiber. The technique is intrinsically interesting and is of considerable practical importance, as well as being a suitable topic for student/faculty/industry collaboration. The key innovation is that the Fourier transform of the image, rather than the image itself, will be input to the fiber. In that case, modal dispersion does not hinder reconstruction of the image at the output end of the fiber. Construction and inversion of the Fourier transform are performed optically; no digital encoding or decoding is required.
While theoretical analysis had indicated that such a transmission scheme was indeed possible, to the best of our knowledge, there have been no experimental demonstration of the feasibility of the technique.
Currently, when an optical image is to be transmitted via a waveguide of circular cross-section, the image is first spatially discretized into picture elements (pixels). Transmission is then performed in either of two ways: pixels may be converted to digital format and transmitted in the time domain, by modulation of a carrier; alternatively, each pixel may be assigned to a single small waveguide. Because the former method requires analog-to-digital and digital-to-analog conversion, the usable data-rate is constrained by non-optical signal processing, and is much lower than optical systems in general are capable of. The latter method requires use of a large bundle of small waveguides often leading to cost, reliability and cross-talk problems.
Direct analog transmission by a single multi-mode fiber is also plausible, and allows better utilization of the optical data-rate capability. Unfortunately in a homogeneous fiber waveguide, the different propagation velocities of different modes result in scrambling of the image send down the fiber. Hence, prior attempts to transmit an image down a single fiber in an analog fashion have required the use of inhomogeneous gradient index fibers, which behave like a series of coaxial lenses, focusing and defocusing the image as it travels through the fiber. These devices are difficult and expensive to manufacture. Read more