Your search keyword '"Daniel J. Esman"' showing total 17 results

1. Comb-assisted real-time Discrete Fourier Transform processor.

Author

H. Hu, Daniel J. Esman, Vahid Ataie, Eduardo Temprana, Bill P.-P. Kuo, Nikola Alic, and Stojan Radic

Published

2017

2. Transmission reach doubling enabled by transmitter-side digital back propagation and frequency referenced carriers.

Author

Eduardo Temprana, Evgeny Myslivets, L. Liu, Ana Pejkic, Vahid Ataie, Bill P.-P. Kuo, Daniel J. Esman, Andreas O. J. Wiberg, Nikola Alic, and Stojan Radic

Published

2015

3. A fully frequency referenced parametric polychromatically sampled analog-to-digital conversion.

Author

Daniel J. Esman, Andreas O. J. Wiberg, Eduardo Temprana, Evgeny Myslivets, Bill P.-P. Kuo, Nikola Alic, and Stojan Radic

Published

2014

4. Photonic parametric sampled analog-to-digital conversion at 100 GHz and 6 ENOBs.

Author

Daniel J. Esman, Andreas O. J. Wiberg, Mu-Han Yang, Lan Liu, Bill P.-P. Kuo, Nikola Alic, and Stojan Radic

Published

2014

5. Comb-Assisted Cyclostationary Analysis of Wideband RF Signals

Author

Bill P.-P. Kuo, Vahid Ataie, Nikola Alic, Eduardo Temprana, Stojan Radic, and Daniel J. Esman

Subjects

Signal processing, Spectrum analyzer, Engineering, Cyclostationary process, business.industry, 02 engineering and technology, Signal, Atomic and Molecular Physics, and Optics, Background noise, 020210 optoelectronics & photonics, Interference (communication), 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Radio frequency, Wideband, business

Abstract

Signals arising in nearly all disciplines, including telecommunications, mechanics, biology, astronomy, and nature are generally modulated, carrying corresponding signatures in both the temporal and spectral domains. This fact was long recognized by cyclostationary and cumulant analysis, providing qualitatively better means to separate stochastic from deterministically modulated radiation. In contrast to simple spectral analysis, the cyclostationary technique provides a high level of spectral discrimination, allowing for considerable signal selectivity even in the presence of high levels of background noise and interference. When performed with sufficient resolution, cyclostationary analysis also provides the ability for signal analysis and classification. Unfortunately, these advantages come at a cost of large computational complexity posing fundamental detection challenges. In the case of modern ultrawideband signals, the requirements for persistent cyclostationary analysis are considerably beyond the processing complexity of conventional electronics. Recognizing this limit, we report a new photonically assisted cyclostationary analyzer that eliminates the need for high-bandwidth digitization and real-time Fourier processors. The new receiver relies on mutually coherent frequency combs used to generate a Fourier representation of the received signal in a computation-free manner. With the advent of practical, cavity-free optical frequency combs, the complexity for cyclostationary analysis can be greatly reduced, paving a path toward persistent wideband cyclostationary analysis in an ultrawideband operating regime.

Published

2017

6. Frequency-Hopping Pulse Position Modulation Ultrawideband Receiver

Author

Bill P.-P. Kuo, Vahid Ataie, Stojan Radic, Daniel J. Esman, and Nikola Alic

Subjects

Engineering, Radio receiver design, business.industry, Electrical engineering, 02 engineering and technology, Atomic and Molecular Physics, and Optics, 020210 optoelectronics & photonics, Transmission (telecommunications), Modulation, Pulse-position modulation, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Frequency-hopping spread spectrum, Transceiver, business, Frequency modulation, Low probability of intercept radar

Abstract

Pulse position modulation (PPM) has been used in the radio-frequency (RF) domain to achieve both low-dissipation requirements and provide precision ranging. In ultrawideband (UWB) architectures, it underpins an asynchronous receiver, multiple access environments, and interference-resistant transmission. When combined with frequency hopping (FH), it allows for an additional level of immunity to jamming and low probability of intercept. Realization of a FH-PPM transceiver poses a practical challenge, particularly in the UWB RF range. With UWB pulses reaching the multi-gigahertz range, FH adds to the effective bandwidth at which the receiver must be operated, exceeding the performance of a modern quantizer and digital demodulation backplane. This study describes a new photonics-assisted FH-PPM receiver architecture that rests on mutually coherent frequency combs. The performance of the new receiver was characterized by receiving and decoding an 80–Mb/s rate FH-PPM UWB signal.

Published

2017

7. Detection of Fast Transient Events in a Noisy Background

Author

Stojan Radic, Nikola Alic, Eduardo Temprana, Bill P.-P. Kuo, Vahid Ataie, and Daniel J. Esman

Subjects

Carrier-to-receiver noise density, Physics, Signal processing, Noise temperature, Noise measurement, Bandwidth (signal processing), 02 engineering and technology, Noise floor, Atomic and Molecular Physics, and Optics, 020210 optoelectronics & photonics, Colors of noise, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Signal averaging

Abstract

Transient signals accompanied by a high noise level pose both basic and practical detection challenges. Disciplines that range from communication and astronomy to molecular physics face a very similar detection problem. When phenomena of interest are repetitive, different averaging techniques can be applied in order to elevate the signal above the detection threshold. In contrast, nonrepetitive signals, commonly occurring in communication and astronomy, cannot be processed using averaging techniques. With the advent of near-noiseless replication techniques, single-instance signal separation from noise has become possible. Here, we demonstrate that a single-instance signal can be mapped to 300 optical carrier frequencies and detected with low-bandwidth receivers to generate detection gains of 24 dB with respect to a single integrating receiver with the same bandwidth. The spectral-replicating receiver was used to detect a single-instance signal with power that was four times lower than the accompanying noise level.

Published

2016

8. Subnoise Signal Detection and Communication

Author

Stojan Radic, Daniel J. Esman, Nikola Alic, Bill P.-P. Kuo, and Vahid Ataie

Subjects

Engineering, Noise (signal processing), business.industry, Detector, Electrical engineering, 02 engineering and technology, Signal, Atomic and Molecular Physics, and Optics, Radio spectrum, 020210 optoelectronics & photonics, Interference (communication), 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Waveform, Wireless, Detection theory, business

Abstract

Radio frequency spectrum is one of the scarcest commodities in existence, with progressively increasing value. As a physical foundation of an untethered society, it now carries the majority of social, defense, and commercial interactions. All of these must reside within narrow, strictly regulated spectral windows allocated for cellular, military, navigation, and broadcast services. Band localization minimizes interference but also mandates that the entire cellular traffic be confined in less than one percent of the physical radio-frequency range. To defy this restriction and emit freely in any band, the signal power must be small to avoid interference with existing traffic. By spreading the signal over a sufficiently wide spectral range, the emission in any band can be maintained below naturally occurring noise. Unfortunately, the reception of a spectrally broadened, subnoise data channel poses a fundamental challenge: a fast, bursty waveform must be detected, separated from noise and reconstructed at rates exceeding gigahertz. Here, we show that a 20-MHz-wide signal can be spread by 300-fold, detected and reconstructed by a physical Fourier transform even when it is much weaker than the received noise. Rather than quantizing the 6-GHz-wide signal and computing its correlation with the decoding waveform, the signal was physically detected and reconstructed by coherently coupled frequency combs. By eliminating high-speed electronics from the receiver, it is now possible to access the entire radio-frequency range that extends beyond 100 GHz. We anticipate that new, band-unrestricted wireless services will emerge to maximize throughput, mitigate interference, and achieve a high level of physical security.

Published

2016

9. Highly Linear Broadband Photonic-Assisted Q-Band ADC

Author

Andreas O. J. Wiberg, Stojan Radic, Nikola Alic, and Daniel J. Esman

Subjects

Effective number of bits, Engineering, Spurious-free dynamic range, business.industry, Optical transistor, Bandwidth (signal processing), Electronic engineering, Figure of merit, Optical performance monitoring, Optical modulation amplitude, business, Atomic and Molecular Physics, and Optics, Anti-aliasing filter

Abstract

A highly linear broadband photonic-assisted analog-to-digital converter (ADC) based on high-frequency optical sampling utilizing a dual output Mach–Zehnder modulator operating with signal frequencies up to 50 GHz is presented. The pulses employed in the optical sampling were generated by a cavity-less pulse source operated at 10 GHz in preference to conventional mode-locked lasers. The optical sampling front-end greatly extends the operational frequency range of the Nyquist limited electronic digitization back-end. The performance of the sampling system is characterized with 7.1 effective number of bits (ENOBs) at 40 with 5 GHz fully accessible bandwidth, and greater than 99 dB·Hz2/3 spurious free dynamic range for the 30–40 GHz frequency range. Furthermore, more than 8 ENOB was achieved by reducing the effective bandwidth to 1 GHz with a digital filter, demonstrating the additional advantage of using a higher sampling rate compared to previous demonstrations. A new figure of merit of photonic-assisted sub-sampled ADCs is also presented accompanied with a comparison to previous implementations.

Published

2015

10. Coherent Filterless Wideband Microwave/Millimeter-Wave Channelizer Based on Broadband Parametric Mixers

Author

James R. Adleman, Stojan Radic, Evgeny Myslivets, Andreas O. J. Wiberg, Nikola Alic, Lan Liu, Sanja Zlatanovic, Bill P.-P. Kuo, Vahid Ataie, E. W. Jacobs, and Daniel J. Esman

Subjects

Engineering, business.industry, Dynamic range, Frequency domain, Extremely high frequency, Bandwidth (signal processing), Broadband, Electronic engineering, Wideband, Photonics, business, Atomic and Molecular Physics, and Optics, Microwave

Abstract

An essential capability in many applications, ranging from commercial, surveillance and defense, is to analyze the spectral content of intercepted microwave and millimeter-wave signals over a very wide bandwidth in real-time and with high resolution. A range of photonic schemes have been introduced for the real-time processing of wideband signals to overcome limitations of current conventional electronic frequency measurement approaches. Here, a novel microwave/millimeter-wave channelizer is presented based on a RF photonic front-end employing parametric wavelength multicasting and comb generation. This new technology enables a contiguous bank of channelized coherent I/Q IF signals covering extremely wide RF instantaneous bandwidth. High channel counts and wide RF instantaneous bandwidth are enabled by use of parametrically generated frequency-locked optical combs spanning >4 THz. Full field analysis capabilities of the coherent detection system are demonstrated by frequency domain analysis of 18 contiguous 1.2 GHz IF channels covering 15.5 GHz to 37.1 GHz input frequency range, and time and spectral domain analysis of a 75 GHz harmonically generated input signal. Sensitivity and dynamic range of the system are analyzed and discussed.

Published

2014

11. Comb-Assisted Real-Time Discrete Fourier Transform Processor

Author

Bill P.-P. Kuo, Vahid Ataie, Eduardo Temprana, Huan Hu, Nikola Alic, Stojan Radic, and Daniel J. Esman

Subjects

Discrete-time Fourier transform, Computer science, Bluestein's FFT algorithm, Fast Fourier transform, Analog-to-digital converter, Hardware_PERFORMANCEANDRELIABILITY, 02 engineering and technology, Discrete Hartley transform, Discrete Fourier transform, law.invention, Discrete Fourier transform (general), symbols.namesake, 020210 optoelectronics & photonics, Cyclotomic fast Fourier transform, law, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Hardware_REGISTER-TRANSFER-LEVELIMPLEMENTATION, Signal processing, DFT matrix, Short-time Fourier transform, Fractional Fourier transform, Fourier transform, Discrete sine transform, Pulse compression, Discrete frequency domain, symbols, Harmonic wavelet transform

Abstract

We present a high-speed flexible photonic-assisted Discrete Fourier Transform (DFT) processor based on a dual, phase-locked optical parametric combs. A 25-point DFT at 500 Million-DFT-point per second throughput is achieved relying on slow, 20 MS/s Analog to Digital Converter (ADC).

Published

2017

12. Photonic aided subnoise microwave signal detection

Author

Daniel J. Esman, Vahid Ataie, and Stojan Radio

Published

2016

13. Subnoise detection of a fast random event

Author

Bill P.-P. Kuo, Vahid Ataie, Nikola Alic, Daniel J. Esman, and Stojan Radic

Subjects

Multidisciplinary, Noise (signal processing), Computer science, business.industry, Detector, Contrast (statistics), Pattern recognition, Signal, Pulse (physics), Waveform, Artificial intelligence, business, Sensitivity (electronics), Event (probability theory)

Abstract

Observation of random, nonrepetitive phenomena is of critical importance in astronomy, spectroscopy, biology, and remote sensing. Heralded by weak signals, hidden in noise, they pose basic detection challenges. In contrast to repetitive waveforms, a single-instance signal cannot be separated from noise through averaging. Here, we show that a fast, randomly occurring event can be detected and extracted from a noisy background without conventional averaging. An isolated 80-picosecond pulse was received with confidence level exceeding 99%, even when accompanied by noise. Our detector relies on instantaneous spectral cloning and a single-step, coherent field processor. The ability to extract fast, subnoise events is expected to increase detection sensitivity in multiple disciplines. Additionally, the new spectral-cloning receiver can potentially intercept communication signals that are presently considered secure.

Published

2015

14. Wideband optical parametric frequency comb applications in real-time signal processing

Author

Vahid Ataie, B. P-P. Kuo, Daniel J. Esman, Nikola Alic, and Stojan Radic

Subjects

Optical amplifier, business.industry, Computer science, Physics::Optics, Optical modulation amplitude, Optical performance monitoring, Optical parametric amplifier, Computer Science::Hardware Architecture, Frequency comb, Computer Science::Multimedia, Electronic engineering, Wideband, Photonics, business, Optical communications repeater

Abstract

A set of phase-locked wideband optical parametric frequency combs are presented as a core of a photonics aided signal processor allowing for the real-time spectral analysis of a 10 Gbps data stream.

Published

2015

15. Demonstration of 74 GHz Parametric Optical Sampled Analog-to-Digital Conversion

Author

Stojan Radic, Evgeny Myslivets, Daniel J. Esman, Andreas O. J. Wiberg, Nikola Alic, Zhi Tong, and Lan Liu

Subjects

Effective number of bits, Analog signal, business.industry, Computer science, Analog to digital conversion, Broadband, Electrical engineering, Electronic engineering, Optical sampling, business, Parametric statistics

Abstract

We demonstrate a broadband analog parametric optical sampling gate-driven analog-todigital conversion applicable to high speed signals. A record-fast analog signal of 74 GHz was characterized at 5.4 ENOB for the first time.

Published

2013

16. High-speed, rate-scalable photonic-assisted digitizer equalization by frequency comb referencing

Author

Evgeny Myslivets, Stojan Radic, Eduardo Temprana, B.P.-P. Kuo, Daniel J. Esman, Nikola Alic, and Andreas O. J. Wiberg

Subjects

Signal processing, Computer science, business.industry, Bandwidth (signal processing), Equalization (audio), Sampling (statistics), Atomic and Molecular Physics, and Optics, Frequency comb, Effective number of bits, Optics, Sampling (signal processing), Pulse compression, Nyquist–Shannon sampling theorem, Oversampling, Photonics, business, Parametric statistics

Abstract

A scalable analog-to-digital converter based on polychromatic sampling and optical-domain frequency referencing is described. The new architecture relies on low-distortion replication of an optical signal to spectrally distinct copies and subsequent polychromatic parametric sampling. Frequency comb referencing of parametric replication and sampling was used to convert processor distortions into quasi-stationary impairments and enable a practical equalization implementation. The operation of the new digitizer was demonstrated at 30 GS/s, achieving 6.5 effective number of bits in the first Nyquist zone. In contrast to conventional analog-to-digital converters, the new preprocessor sampling bandwidth is not restricted to the first Nyquist zone, and can operate in the second and third Nyquist zones beyond 40 GHz.

Published

2014

17. Photonic RF-channelized receiver based on wideband parametric mixers and coherent detection

Author

Lan Liu, Andreas O. J. Wiberg, Nikola Alic, Stojan Radic, Daniel J. Esman, and Evgeny Myslivets

Subjects

Optics, Multicast, Computer science, business.industry, Electronic engineering, Channelized, Data_CODINGANDINFORMATIONTHEORY, Wideband, Photonics, business, Parametric statistics

Abstract

We present a photonic RF-channelized receiver based on parametric multicasting and LO generation. Using frequency locking and coherent detection, contiguous channelization of 12 sub-channels is achieved covering 24-30GHz. System analysis and characterizations are presented.