Non‐coherent pulse compression — aperiodic and periodic waveforms

Levanon, Nadav; Cohen, Itzik; Arbel, Nadav; Zadok, Avi

doi:10.1049/iet-rsn.2015.0046

Cited by 21 publications

(9 citation statements)

References 15 publications

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“…maximising the SNR improvement, so-called coding gain, whilst minimising the hardware overhead and extra measurement time); however, all currently existing code types present fundamental and/or practical limitations. For instance, although codes formed by a single sequence 40,[56][57][58][59][60][61][62]64 are ideal for minimising measurement time and data storage, they either exhibit an imperfect peak-tosidelobes ratio after the decoding 40,56,64 or are periodic/cyclic codes [57][58][59][60][61][62]64 that suffer from impairments induced by signaldependent noise 1 (resulting in a compromised coding gain that has not yet been quantified in literature). As more robust alternatives, distortion-free aperiodic codes constituted by several sequences, such as Golay [41][42][43][44][45][46][47] , Simplex codes [48][49][50][51][52]63 and their derivatives 54,55 , have been mostly used for DOFS.…”

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confidence: 99%

Genetic-optimised aperiodic code for distributed optical fibre sensors

et al. 2020

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Distributed optical fibre sensors deliver a map of a physical quantity along an optical fibre, providing a unique solution for health monitoring of targeted structures. Considerable developments over recent years have pushed conventional distributed sensors towards their ultimate performance, while any significant improvement demands a substantial hardware overhead. Here, a technique is proposed, encoding the interrogating light signal by a single-sequence aperiodic code and spatially resolving the fibre information through a fast post-processing. The code sequence is once forever computed by a specifically developed genetic algorithm, enabling a performance enhancement using an unmodified conventional configuration for the sensor. The proposed approach is experimentally demonstrated in Brillouin and Raman based sensors, both outperforming the state-of-the-art. This methodological breakthrough can be readily implemented in existing instruments by only modifying the software, offering a simple and cost-effective upgrade towards higher performance for distributed fibre sensing.

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confidence: 99%

Genetic-optimised aperiodic code for distributed optical fibre sensors

et al. 2020

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“…The PACF clearly show that the magnitude of sidelobes other than peak is '1' which is constant. Levanon [13] and Jahangir [14] demonstrated the ideal periodic correlation properties of M-sequences and Legendre sequences by taking the crosscorrelation between the unipolar version {1, 0} of transmitted signal and the bipolar reference signal {±1}. It is shown that this method is advantageous in context of Non-coherent Pulse Compression (NCPC) radar.…”

Section: Sequences With Perfect Periodic Autocorrelationmentioning

confidence: 99%

“…The perfect periodic cross-correlation property is achieved at the cost of high energy loss. The energy efficiency of unipolar M-sequence (N=7) is nearly 57% and such signals are preferred in noncoherent processing [13,14]. For coherent processing, the reference signal must be same as the transmitted signal.…”

Section: Sequences With Perfect Periodic Autocorrelationmentioning

confidence: 99%

Sequences with Perfect Periodic Auto and Cross Correlation Properties

Bhatt¹

2020

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Perfect binary or ternary sequences exhibit an impulse-like Periodic Autocorrelation Function (PACF). Signals with perfect periodic autocorrelation properties are useful in many applications in communications and radar fields. The additional complexity in the design of radar signals is to take care of the cross-correlation properties when multiple radars are sharing the same frequency band. This paper proposes the waveform design approach related to the multi-radar network, when radars are employing coherent pulse train or CW waveforms. Such practical scenario demands the design of waveforms which have perfect autocorrelation and cross-correlation properties. Construction procedure, correlation properties and detection performance of such sequences are presented in this paper.

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“…Noncoherent pulse compression (NCPC) introduced in [7]- [9] employs the on-off keying (OOK) modulation. The OOK transmitted signal suggested for NCPC are based on Manchester coding well-known binary sequences, like Barker or minimum peak sidelobe (MPSL) codes.…”

Section: Related Previous Techniquementioning

confidence: 99%

A new noncoherent radar pulse compression based on complementary sequences

Seleym

2014

2014 IEEE Radar Conference

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Noncoherent pulse compression (NCPC) is of interest to direct-detection laser ranging, and to simple radars that utilize noncoherent microwave power sources. In this technique, a unipolar sequence of pulses using on-off keying (OOK) modulation can be used in transmission. Bipolar binary complementary sequence pairs offer the possibility of perfect sidelobe cancellation, but in case of using unipolar codes, there is a severe degradation in the reflected echoes peak sidelobe level in compression filter response. Many techniques are suggested for sidelobe suppression. A recent technique used Manchester coding with a periodic autocorrelation of binary complementary pairs. This technique yields two large negative sidelobes response in addition to a broad bandwidth. In this paper, a new technique is proposed for NCPC via using a hybrid of two identical matched filters for each sequence. The output response is the sum of the complementary pair responses. This approach achieves a perfect correlation response with a peak of 2N (N is the length of each sequence) and a sidelobe level of zero without expanding the bandwidth in addition to implementation simplicity. Keywords-noncoherent pulse compression; complementary coded pulse compression; on-off keying modulationI.

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Non‐coherent pulse compression — aperiodic and periodic waveforms

Cited by 21 publications

References 15 publications

Genetic-optimised aperiodic code for distributed optical fibre sensors

Genetic-optimised aperiodic code for distributed optical fibre sensors

Sequences with Perfect Periodic Auto and Cross Correlation Properties

A new noncoherent radar pulse compression based on complementary sequences

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