M. Konitzer

Bio: M. Konitzer is an academic researcher from Heinrich Hertz Institute. The author has contributed to research in topics: Deconvolution & Histogram. The author has an hindex of 3, co-authored 4 publications receiving 183 citations.

Robustness of DPSK direct detection transmission format in standard fibre WDM systems

Abstract: The practicability of using phase modulation in a 16 channel 10 Gbit/s system over 1600 km of standard SMF with simple dispersion compensation and the robustness in presence of ASK modulated channels has been shown for the first time.

Histogram method for identification and evaluation of crosstalk

Abstract: Signal performance monitoring by a new histogram method is proposed for the identification of crosstalk. It is based on a deconvolution method. An investigation into the measured histograms for signals with inband crosstalk is presented and the BER successfully evaluated.

Penalties through XPM crosstalk in a switched long haul standard fiber WDM system based on normalized transmission sections

Abstract: For the first time penalties due to XPM crosstalk have been measured by switching neighbouring channels in a long distance 16/spl times/10 Gb/s ASK NRZ system based on standard single mode fibre (SMF) links with dispersion optimized transmission sections.

Histogram method for identification and evaluation of crosstalk

Abstract: Signal performance monitoring by a novel histogram method is proposed for identification crosstalk, it is based on a deconvolution method. Measured histograms for signals with inband crosstalk are investigated and the BER is successfully estimated.

Optical phase-shift-keyed transmission

Abstract: Differential-phase-shift keying (DPSK) has recently been used to reach record distances in long-haul lightwave communication systems. This paper will review theoretical, as well as implementation, aspects of DPSK, and discuss experimental results.

Optical differential quadrature phase-shift key (oDQPSK) for high capacity optical transmission

Abstract: Signaling using oDQPSK offers great potential for application in 10 and 40 Gb/s DWDM transmission systems, offering increased spectral efficiency, relaxed dispersion management and improved PMD tolerance. Practical realization of encoder and decoder functionality through integration should lead to wide system application.

Spectral efficiency limits and modulation/detection techniques for DWDM systems

Abstract: Information-theoretic limits to spectral efficiency in dense wavelength-division-multiplexed (DWDM) transmission systems are reviewed, considering various modulation techniques (unconstrained, constant-intensity, binary), detection techniques (coherent, direct), and propagation regimes (linear, nonlinear). Spontaneous emission from inline optical amplifiers is assumed to be the dominant noise source in all cases. Coherent detection allows use of two degrees of freedom per polarization, and its spectral efficiency limits are several b/s/Hz in typical terrestrial systems, even considering nonlinear effects. Using either constant-intensity modulation or direct detection, only one degree of freedom per polarization can be used, significantly reducing spectral efficiency. Using binary modulation, regardless of detection technique, spectral efficiency cannot exceed 1 b/s/Hz per polarization. When the number of signal and/or noise photons is small, the particle nature of photons must be considered. The quantum-limited spectral efficiency for coherent detection is slightly smaller than the classical capacity, but that for direct detection is 0.3 b/s/Hz higher than its classical counterpart. Various binary and nonbinary modulation techniques, in conjunction with appropriate detection techniques, are compared in terms of their spectral efficiencies and signal-to-noise ratio requirements, assuming amplified spontaneous emission is the dominant noise source. These include a) pulse-amplitude modulation with direct detection, b) differential phase-shift keying with interferometric detection, c) phase-shift keying with coherent detection, and d) quadrature-amplitude modulation with coherent detection.

Method and system for antenna interference cancellation

Abstract: A wireless communication system can comprise two or more antennas that interfere with one another via free space coupling, surface wave crosstalk, dielectric leakage, or other interference effect. The interference effect can produce an interference signal on one of the antennas. A cancellation device can suppress antenna interference by generating an estimate of the interference signal and subtracting the estimate from the interference signal. The cancellation device can generate the estimate based on sampling signals on an antenna that generates the interference or on an antenna that receives the interference. The cancellation device can comprise a model of the crosstalk effect. Transmitting test signals on the communication system can define or refine the model.

Differential phase-shift keying for high spectral efficiency optical transmissions

Abstract: Differential phase-shift keying (DPSK) has attracted significant attentions in research and development during the last several years. An overview of DPSK for high spectral efficiency optical transmission is presented in this paper. The advantages of DPSK in terms of receiver sensitivity and tolerance to fiber nonlinearity will be discussed in detail. A simplified method for estimating the performance of phase-shift keying in numerical simulations is explained. Results of experimental and numerical investigations of several phase shift keying formats, including polarization division multiplexing and multilevel encoding, will be reviewed. Finally, methods for further enhancing performance of phase-shift keying in long-haul transmissions, specifically the compensation of nonlinear phase jitter, are presented.