Abstract: Methods for detecting and compensating for multiple optical signals produced in a multi-mode fiber system are provided. A representative method includes detecting a plurality of optical signals radiating from an end of the multi-mode fiber by a multisegment photodetector having different detector regions that detect different portions of the plurality of optical signals, and modifying detected signal by the multisegment photodetector to reduce the affects of modal dispersion among the plurality of optical signals. Other methods also are provided.

Abstract: A method and system using the principle of generalized maximum likelihood estimation to resolve sample timing uncertainties that are associated with the decoding of communication signals. By using generalized maximum likelihood estimation, sample timing uncertainty can be resolved by taking multiple samples of the received signal within a symbol period and determining which sample best corresponds to the optimal sample timing. The sample which best corresponds to the optimal sample timing can be determined from a timing index which can be calculated from ambiguity indicators that are based on the samples of the received signal.

Abstract: The present invention combines standard binary ASK modulation with differential PSK (DPSK) modulation to achieve a two times or doubled increase in data throughput and a spectral efficiency of 1 bit/s/Hz. In other words, the present invention can be characterized as overlaying DPSK onto a regular binary ASK transmission. Each bit generated by the inventive modulation technique can have one of two intensities and one of two phases such that every symbol transmitted can comprise two bits. The present invention encodes (and subsequently decodes) information into both the phase and amplitude of a carrier signal. This translates into less complex circuitry and lower costs for a receiver in the inventive system. This also means that phase integrity does not need to be maintained throughout the communications system like that of a coherent QAM communications system because the relative phase instead of the absolute phase is tracked.

Abstract: Methods for detecting and compensating for multiple optical signals produced in a multi-mode fiber system are provided. A representative method includes detecting a plurality of optical signals radiating from an end of the multi-mode fiber by a multisegment photodetector having different detector regions that detect different portions of the plurality of optical signals, and modifying detected signal by the multisegment photodetector to reduce the affects of modal dispersion among the plurality of optical signals. Other methods also are provided.

Abstract: Systems for detection and compensation of modal dispersion in an optical fiber system including a multisegment photodetector coupled to an end of an optical fiber for detecting optical signals exiting the optical fiber and for converting the optical signals to an electrical output are provided. A representative multisegment photodetector includes a plurality of photodetector regions configured such that each of the plurality of photodetectors detects a portion of the plurality of optical signals exiting the end of the optical fiber and modifies the signal to reduce the affects of modal dispersion.

Abstract: Decreasing the average transmitted power in an optical fiber communication channel using multilevel amplitude modulation in conjunction with Pulse Position Modulation (PPM). This multilevel PPM method does not entail any tradeoff between decreased power per channel and channel bandwidth, enabling a lower average transmitted power compared to On/Off Keying (OOK) with no reduction in aggregate data rate. Therefore, multilevel PPM can be used in high-speed Dense Wavelength Division Multiplexed (DWDM) systems where the maximum number of channels is traditionally limited by nonlinear effects such as self-phase modulation (SPM), cross-phase modulation (XPM), four-wave mixing (FWM), stimulated Brillouin scattering (SBS), and stimulated Raman scattering (SRS). This modulation technique can enable an increased number of channels in DWDM systems, thereby increasing aggregate data rates within those systems.

Abstract: Data throughput rates are increased in an optical fiber communication system without requiring replacement of the existing optical fiber in a link. Channel throughput is increased by upgrading the components and circuitry in the head and terminal of an optical fiber communication system link. Aggregate throughput in a fiber optic link is increased beyond the range of conventional Wavelength Division Multiplexed (WDM) upgrades, while precluding the necessity of replacing existing fiber plants. The increase in system throughput is achieved by using advanced modulation techniques to encode greater amounts of data into the transmitted spectrum of a channel, thereby increasing the spectral efficiency of each channel. This novel method of increasing transmission capacity by upgrading the head and terminal of the system to achieve greater spectral efficiency and hence throughput, alleviates the need to replace existing fiber plants.

Abstract: A nonlinear optical device structure is formed by a compound semiconductor having a graded chemical composition such that the average drift velocity of electrons is in the same direction as, but of greater magnitude than, that of holes. In this way, when a pump optical beam (control beam) is flashed (as by a picosecond pulse) upon the structure, electron-hole pairs are created with a resulting temporary spatial separation between the holes and the electron--whereby an electric dipole moment is temporarily induced in the structure. In turn, this dipole moment temporarily modifies either the birefringence or absorption property, or both, with respect to a controlled beam--whereby the polarization, phase, or intensity, of the controlled beam can be modified by the control beam. After the electrons and holes drift to positions which extinguish the dipole the structure is ready for a repeat performance.