1,212 research outputs found
High accuracy computation with linear analog optical systems: a critical study
High accuracy optical processors based on the algorithm of digital multiplication by analog convolution (DMAC) are studied for ultimate performance limitations. Variations of optical processors that perform high accuracy vector-vector inner products are studied in abstract and with specific examples. It is concluded that the use of linear analog optical processors in performing digital computations with DMAC leads to impractical requirements for the accuracy of analog optical systems and the complexity of postprocessing electronics
Acousto-optic signal processors for transmission and reception of phased-array antenna signals
Novel acousto-optic processors for control and signal processing in phased-array antennas are presented. These processors can operate in both the antenna transmit and receive modes. An experimental acousto-optic processor is demonstrated in the laboratory. This optical technique replaces all the phase-shifting devices required in electronically controlled phased-array antennas
Programmable image associative memory using an optical disk and a photorefractive crystal
The optical disk is a computer-addressable binary storage medium with very high capacity. More than 10^10 bits of information can be recorded on a 12-cm-diameter optical disk. The natural two-dimensional format of the data recorded on an optical disk makes this medium particularly attractive for the storage of images and holograms, while parallel access provides a convenient mechanism through which such data may be retrieved. In this paper we discuss a closed-loop optical associative memory based on the optical disk. This system incorporates image correlation, using photorefractive media to compute the best association in a shift-invariant fashion. When presented with a partial or noisy version of one of the images stored on the optical disk, the optical system evolves to a stable state in which those stored images that best match the input are temporally locked in the loop
Optical implementations of radial basis classifiers
We describe two optical systems based on the radial basis function approach to pattern classification. An optical-disk-based system for handwritten character recognition is demonstrated. The optical system computes the Euclidean distance between an unknown input and 650 stored patterns at a demonstrated rate of 26,000 pattern comparisons/s. The ultimate performance of this system is limited by optical-disk resolution to 10^11 binary operations/s. An adaptive system is also presented that facilitates on-line learning and provides additional robustness
Optical memory: introduction by the feature editors
The contributions to this feature issue represent a wide range of topics in optical memory
Optical computing: introduction by the guest editors to the feature in the 1 May 1988 issue
The feature in the 1 May 1988 issue of Applied Optics includes a collection of papers originally presented at the 1987 Lake Tahoe Topical Meeting on Optical Computing. These papers emphasize digital optical computing systems, optical interconnects, and devices for optical computing, but analog optical processing is considered as well
From Neutron Star Observables to the Equation of State. I. An Optimal Parametrization
The increasing number and precision of measurements of neutron star masses,
radii, and, in the near future, moments of inertia offer the possibility of
precisely determining the neutron star equation of state. One way to facilitate
the mapping of observables to the equation of state is through a
parametrization of the latter. We present here a generic method for optimizing
the parametrization of any physically allowed EoS. We use mock equations of
state that incorporate physically diverse and extreme behavior to test how well
our parametrization reproduces the global properties of the stars, by
minimizing the errors in the observables mass, radius, and the moment of
inertia. We find that using piecewise polytropes and sampling the EoS with five
fiducial densities between ~1-8 times the nuclear saturation density results in
optimal errors for the smallest number of parameters. Specifically, it
recreates the radii of the assumed EoS to within less than 0.5 km for the
extreme mock equations of state and to within less than 0.12 km for 95% of a
sample of 42 proposed, physically-motivated equations of state. Such a
parametrization is also able to reproduce the maximum mass to within 0.04 M_sun
and the moment of inertia of a 1.338 M_sun neutron star to within less than 10%
for 95% of the proposed sample of equations of state.Comment: Minor changes made to match published ApJ versio
Image correlators using optical memory disks
Image correlators are described and experimentally demonstrated that are implemented using optical memory disks to store a large library of reference images
Optical-radar imaging of scale models for studies in asteroid astronomy
During the past five years, delay-Doppler radar has become the primary technique for studying the structure of Earth-crossing asteroids. None of these objects has yet been visited by spacecraft, so ground-truth test cases are lacking. A laboratory system is described that provides optical-radar images at 0.1-mm resolution. These data are analogous to the highest-resolution asteroid radar images currently available and provided realistic test cases for developing signal-processing techniques. The system can be thought of as a 1/188,000 scale model of the Arecibo radar, or a 1/52,800 scale model of the Goldstone radar
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