Latency Analysis for Sequential Detection in Low-Complexity Binary Radio Systems

Stein, Manuel; Faub, Michael

doi:10.1109/tcomm.2019.2946309

Cited by 3 publications

(3 citation statements)

References 52 publications

(86 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The binary telescope with M = 92 antennas outperforms all three 64-bit stations with M = 46 array elements in terms of imaging uncertainty, although the measurement data is by a factor 32 smaller. These results confirm that reducing the A/D resolution to 1-bit and doubling the number of receivers is an effective method to obtain highperformance low-complexity sensing architectures [17].…”

Section: B Lofar Dataset 2 -Aartfaac Stationssupporting

confidence: 68%

“…Key to such a progressive scientific platform is the transfer of theoretic advances in hardware-aware probabilistic signal modeling and likelihood-oriented statistical data processing [16], [17] to the practical design of all-digital radio telescope systems. As a firm orientation point for this challenging endeavor, the envisaged physical system is defined by sketching the architecture and components of a radio telescope which we refer to as The Massive Binary Radio Lenses.…”

Section: B Technology Vision -Massive Binary Radio Telescopesmentioning

confidence: 99%

See 1 more Smart Citation

Glancing Through Massive Binary Radio Lenses: Hardware-Aware Interferometry With 1-Bit Sensors

Stein

2019

Preprint

Self Cite

View full text Add to dashboard Cite

Energy consumption and hardware cost of signal digitization together with the management of the resulting data volume form serious issues for high-rate measurement systems with multiple sensors. Switching to binary sensing front-ends results in a resource-efficient layout but is commonly associated with significant distortion due to the nonlinear signal acquisition. In particular, for applications that require to solve high-resolution processing tasks under extreme conditions, it is a widely held belief that low-complexity 1-bit analog-to-digital conversion leads to unacceptable performance degradation. In the Big Science context of low-frequency radio astronomy, we propose a telescope architecture based on simplistic binary sampling, precise probabilistic modeling, and likelihood-oriented data processing. The main principles, building blocks, and advantages of such a radio telescope system, which we refer to as The Massive Binary Radio Lenses, are sketched. The open engineering science questions which have to be answered before building a prototype are outlined. We set sail for the academic technology study by deriving a statistical algorithm for interferometric imaging from binary array measurements. The method aims at extracting the full discriminative information about the spatial power distribution embedded in a binary sensor data stream without bias. Radio measurements obtained with LOFAR are used to test the developed imaging technique and discuss visual and quantitative results. These assessments shed light on the fact that binary radio telescopes are suited for surveying the universe.

show abstract

Section: B Lofar Dataset 2 -Aartfaac Stationssupporting

confidence: 68%

Section: B Technology Vision -Massive Binary Radio Telescopesmentioning

confidence: 99%

Glancing Through Massive Binary Radio Lenses: Hardware-Aware Interferometry With 1-Bit Sensors

Stein

2019

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…The simplicity of basic digital processing steps, small sensor data volume, and energy-efficient analog front-end design make it possible to deploy higher temporal, spectral, and spatial sampling rates. Such, with the same A/D resources, digital measurements can be acquired, which contain more information about the analog signal model [11]. To extract all this information from the data, efficient binary signal processing methods are required.…”

Section: Introductionmentioning

confidence: 99%

Spectral Power Parameter Estimation of Random Sources with Binary Sampled Signals

Stein

2019

Preprint

Self Cite

View full text Add to dashboard Cite

This paper investigates the problem of estimating the spectral power parameters of random analog sources using numerical measurements acquired with minimum digitization complexity. Therefore, spectral analysis has to be performed with binary samples of the analog sensor output. Under the assumption that the structure of the spectral power density of the analog sources is given, we investigate the achievable accuracy for power level estimation with likelihood-oriented processing. The discussion addresses the intractability of the likelihood with multivariate hard-limited samples by exploiting advances on probabilistic modeling and statistical processing of hard-limited multivariate Gaussian data. In addition to estimation-theoretic performance analysis, the results are verified by running an iterative likelihood-oriented algorithm with synthetic binary data for two exemplary sensing setups.

show abstract

On Optimal Quantization in Sequential Detection

Fauß

Stein

Poor

2022

IEEE Trans. Signal Process.

View full text Add to dashboard Cite

Latency Analysis for Sequential Detection in Low-Complexity Binary Radio Systems

Cited by 3 publications

References 52 publications

Glancing Through Massive Binary Radio Lenses: Hardware-Aware Interferometry With 1-Bit Sensors

Glancing Through Massive Binary Radio Lenses: Hardware-Aware Interferometry With 1-Bit Sensors

Spectral Power Parameter Estimation of Random Sources with Binary Sampled Signals

On Optimal Quantization in Sequential Detection

Contact Info

Product

Resources

About