C. Schmidt scite author profile

The phase dynamics that occur in bulk InGaAsP-InP semiconductor optical amplifiers (SOAs) in response to picosecond pulse excitations at 10 and 40 GHz are studied experimentally and numerically for various amplifier lengths. The time dependencies of the phase changes and of the absolute gain of the amplifier are measured simultaneously. The total phase shifts induced by 1.5-ps pulses at 10 GHz are higher than /spl pi/ in SOAs with active region lengths between 0.5 and 2 mm and exceed 2/spl pi/ in a 1.5-mm-long amplifier. Phase shifts above /spl pi/ are measured at 40 GHz in 1.5- and 2-mm-long SOAs. The dependence of the total phase shift on the amplifier bias current and length and on pump pulse energy is investigated. Numerical simulations based on a comprehensive time-domain SOA model allow us to confirm the experimental results for a wide range of amplifier parameters. In particular, SOAs with lengths up to 5 mm have been modeled, and the calculations suggest that the maximum phase shifts occur in amplifiers of approximately 2-mm length. The phase dynamics measurements are illustrated at the example of an optical time division multiplexing add-drop multiplexer, based on a SLALOM switch, gated by 10- or 40-GHz control pulses. We find that simultaneous good dropping and clearing is possible if the length and the operating conditions of the SOA in the switch are chosen such as to induce a full /spl pi/ phase shift

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Application of lock-in thermography for failure analysis in integrated circuits using quantitative phase shift analysis

Schmidt

Altmann

Breitenstein

2012

Materials Science and Engineering: B

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Comparison of interferometric all-optical switches for demultiplexing applications in high-speed OTDM systems

Schubert

Berger

Diez

et al. 2002

J. Lightwave Technol.

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We have investigated three interferometric all-optical switches based on cross-phase modulation (XPM) in semiconductor optical amplifiers (SOAs), the semiconductor laser amplifier in a loop mirror (SLALOM) switch, the Mach-Zehnder interferometer (MZI) switch, and the ultrafast nonlinear interferometer (UNI) switch. Switching windows with different widths are measured under similar conditions for all three switching configurations. We introduce the integrated contrast ratio (ICR) as a measure to evaluate the performance of a switch from switching windows. Using the ICR, the switches are compared and their application is discussed as demultiplexer in optical time division multiplexing (OTDM) systems for data rates of 40, 80, and 160 Gb/s

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Mode-Multiplexed 6⨉20-GBd QPSK Transmission over 1200-km DGD-Compensated Few-Mode Fiber

Randel¹,

Ryf²,

Gnauck³

et al. 2012

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C. Schmidt

Phase dynamics of semiconductor optical amplifiers at 10-40 GHz

Application of lock-in thermography for failure analysis in integrated circuits using quantitative phase shift analysis

Comparison of interferometric all-optical switches for demultiplexing applications in high-speed OTDM systems

Mode-Multiplexed 6⨉20-GBd QPSK Transmission over 1200-km DGD-Compensated Few-Mode Fiber

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