Optical quantizing and coding for ultrafast A/D conversion using nonlinear fiber-optic switches based on Sagnac interferometer

Ikeda, Katsuhiko; Abdul, J.M.; Namiki, Shu; Kitayama, Ken‐ichi

doi:10.1364/opex.13.004296

Cited by 48 publications

(18 citation statements)

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“…In addition, it should be noted that our method is modeled only by extracting one bit from each chaotic pulse with the AOFF functioned as an all-optical one-bit quantizer. If it was replaced with an all-optical multibit quantizer such as that in [48], the bit rates would be much faster. We also note that there have been recently a large number of optoelectronic proposals expected to generate ultrahigh speed random bits by applying different multibit extraction for one sample and postprocessing of bits [22]- [26].…”

Section: B Merits and Prospect Of All-optical Trngsmentioning

confidence: 99%

Fast and Tunable All-Optical Physical Random Number Generator Based on Direct Quantization of Chaotic Self-Pulsations in Two-Section Semiconductor Lasers

Wang

et al. 2013

IEEE J. Select. Topics Quantum Electron.

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We present numerically an all-optical approach to generate fast physical random numbers. This approach is based on chaotic self-pulsations, a kind of chaos superimposed on periodic pulse trains. Two-section semiconductor lasers (TSSLs) can exhibit this phenomenon of chaos, under an appropriate external optical injection. Simulations demonstrate that, without sampling and postprocessing procedures, this technique can produce random numbers at gigabit per second rates through directly quantizing the chaotic self-pulsations via an all-optical flip-flop. Further simulation results show that the random number generation rate can be continuously and easily tuned in a large range from 5 to 10 Gb/s by adjusting some control parameters of the TSSL subject to continuous-wave optical injection, such as injection strength, frequency detuning, gain current, and absorber bias. Moreover, our numerical studies show that these generated random numbers sequences above with the proposed method can pass successfully standard benchmark tests for randomness.

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Section: B Merits and Prospect Of All-optical Trngsmentioning

confidence: 99%

Fast and Tunable All-Optical Physical Random Number Generator Based on Direct Quantization of Chaotic Self-Pulsations in Two-Section Semiconductor Lasers

Wang

et al. 2013

IEEE J. Select. Topics Quantum Electron.

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“…In recent years, all-optical ADCs have attracted the attention of researchers due to their high sampling rate and ultra-wide bandwidth. 1 So far, many different schemes of all-optical ADC have been developed, in which the interferometric ADC has been widely used due to its simple structure and high speed, such as Taylor scheme, 2,3 nonlinear optical loop mirror (NOLM), 4,5 and phase shifted optical quantization (PSOQ). [6][7][8][9][10] The advantage of the PSOQ is its simple structure: only one phase modulator is needed.…”

Section: Introductionmentioning

confidence: 99%

Proposal for an all optical analog-to-digital converter based on modal birefringence in a polarization maintaining fiber

2013

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Abstract. A photonic analog-to-digital converter (ADC) utilizing the modal birefringence of the polarization maintaining fiber (PMF) is proposed. In the PMF, sampling pulses with different wavelengths have different phase shifted transfer functions, which could be used for quantizing and encoding in a photonic ADC. A proof-of-concept experiment is performed and a 2.5 GHz sinusoidal electrical analog signal is quantized by using 16 different wavelengths. The experimental result with an effective number of bits of 4.5 is achieved.

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“…Optical-to-electrical transducers are needed to reconvert optical samples into electrical signals so that the quantization functions can be performed with electronic circuitry. In this sampling scheme the optical-to-electrical and electrical-to-optical transducers create bottlenecks that diminish the sampled signals [2,3]. PIN photodiode (PIN-PD) based RF sampling circuits have been reported as alternatives to avoid optical-to-electrical and electrical-to-optical transducers.…”

Section: Introductionmentioning

confidence: 99%

Frequency spurious aversion by minimal reverse bias selection of a high-speed optically triggered sampling circuit based on a positive–intrinsic–negative photodiode

et al. 2012

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In this paper we present a procedure for the selection of the minimal dc reverse bias voltage of a high-speed optically triggered sampling circuit. The optically triggered sampling circuit is based on a PIN photodiode. A set of expressions that includes the optical power dependence of the current passing through the PIN photodiode is derived. Theoretical results of the procedure are experimentally verified with practical measurements obtained from a 3 giga samples per second (GS/s) and a 20 GS/s sampling circuit implemented with commercial PIN photodiodes. Reductions in the signal-to-noise and distortion ratio of 37.28 and 6.9 dBs, as well as increments in the spurious free dynamic range of 31 and 19 dBs in the sampled signals, are respectively averted by the selection of the minimal reverse bias.

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Optical quantizing and coding for ultrafast A/D conversion using nonlinear fiber-optic switches based on Sagnac interferometer

Cited by 48 publications

References 0 publications

Fast and Tunable All-Optical Physical Random Number Generator Based on Direct Quantization of Chaotic Self-Pulsations in Two-Section Semiconductor Lasers

Fast and Tunable All-Optical Physical Random Number Generator Based on Direct Quantization of Chaotic Self-Pulsations in Two-Section Semiconductor Lasers

Proposal for an all optical analog-to-digital converter based on modal birefringence in a polarization maintaining fiber

Frequency spurious aversion by minimal reverse bias selection of a high-speed optically triggered sampling circuit based on a positive–intrinsic–negative photodiode

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