ICE: A Scalable, Low-Cost FPGA-Based Telescope Signal Processing and Networking System

Bandura, Kevin; Bender, A. N.; Cliche, J. F.; Haan, T. de; Dobbs, M.; Gilbert, A.; Griffin, S.; Hsyu, G.; Ittah, David; Parra, John de la; Montgomery, J.; Pinsonneault-Marotte, Tristan; Siegel, Seth R.; Smecher, G.; Tang, Q. Y.; Vanderlinde, K.; Whitehorn, N.

doi:10.1142/s2251171716410051

Cited by 53 publications

(35 citation statements)

References 29 publications

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“…The signal is then sent through a customized poly-phase filter bank (PFB) and FFT algorithm, performed at 18+18-bit precision to channelize the signal into 1024 frequency channels between 400-800 MHz. 42 The X-engine of the correlator will correlate all sky inputs for each of the 1024 frequency channels, and is implemented in an array of HPC GPU nodes. To network the data between the FPGA F-engine and the GPU X-engine, the data is sent via a custom backplane and point-to-point digital connections into the GPU nodes, during which it undergoes a corner-turn operation.…”

Section: Digital Back Endmentioning

confidence: 99%

HIRAX: a probe of dark energy and radio transients

et al. 2016

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The Hydrogen Intensity and Real-time Analysis eXperiment (HIRAX) is a new 400-800 MHz radio interferometer under development for deployment in South Africa. HIRAX will comprise 1024 six meter parabolic dishes on a compact grid and will map most of the southern sky over the course of four years. HIRAX has two primary science goals: to constrain Dark Energy and measure structure at high redshift, and to study radio transients and pulsars. HIRAX will observe unresolved sources of neutral hydrogen via their redshifted 21-cm emission line ('hydrogen intensity mapping'). The resulting maps of large-scale structure at redshifts 0.8-2.5 will be used to measure Baryon Acoustic Oscillations (BAO). BAO are a preferential length scale in the matter distribution that can be used to characterize the expansion history of the Universe and thus understand the properties of Dark Energy. HIRAX will improve upon current BAO measurements from galaxy surveys by observing a larger cosmological volume (larger in both survey area and redshift range) and by measuring BAO at higher redshift when the expansion of the universe transitioned to Dark Energy domination. HIRAX will complement CHIME, a hydrogen intensity mapping experiment in the Northern Hemisphere, by completing the sky coverage in the same redshift range. HIRAX's location in the Southern Hemisphere also allows a variety of cross-correlation measurements with large-scale structure surveys at many wavelengths. Daily maps of a few thousand square degrees of the Southern Hemisphere, encompassing much of the Milky Way galaxy, will also open new opportunities for discovering and monitoring radio transients. The HIRAX correlator will have the ability to rapidly and efficiently detect transient events. This new data will shed light on the poorly understood nature of fast radio bursts (FRBs), enable pulsar monitoring to enhance long-wavelength gravitational wave searches, and provide a rich data set for new radio transient phenomena searches. This paper discusses the HIRAX instrument, science goals, and current status.

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Section: Digital Back Endmentioning

confidence: 99%

HIRAX: a probe of dark energy and radio transients

et al. 2016

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“…The CHIME correlator is based on an FX design, where the F-engine digitizes (samples at 800 MSPS and quantizes to 8 bits) and channelizes (i.e., divide the 400 MHz input bandwidth into thousands of frequency channels) the analog signals from the 2048 receivers of the interferometer (see Bandura et al, 2016a, for details of the CHIME F-engine). The complex-valued data from each frequency channel is then quantized to 4 bits (4 bits real + 4 bits imaginary) before being reorganized by a corner-turn system (see Bandura et al, 2016b, for details of the corner-turn network) and fed into the X-engine that computes the full N 2 correlation matrix (see Denman et al, 2015;Recnik et al, 2015, for details of the CHIME X-engine).…”

Section: Introductionmentioning

confidence: 99%

Quantization Bias for Digital Correlators

Mena-Parra

Bandura

Dobbs

et al. 2018

J. Astron. Instrum.

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Received (to be inserted by publisher); Revised (to be inserted by publisher); Accepted (to be inserted by publisher);In radio interferometry, the quantization process introduces a bias in the magnitude and phase of the measured correlations which translates into errors in the measurement of source brightness and position in the sky, affecting both the system calibration and image reconstruction. In this paper we investigate the biasing effect of quantization in the measured correlation between complex-valued inputs with a circularly symmetric Gaussian probability density function (PDF), which is the typical case for radio astronomy applications. We start by calculating the correlation between the input and quantization error and its effect on the quantized variance, first in the case of a real-valued quantizer with a zero mean Gaussian input and then in the case of a complex-valued quantizer with a circularly symmetric Gaussian input. We demonstrate that this input-error correlation is always negative for a quantizer with an odd number of levels, while for an even number of levels this correlation is positive in the low signal level regime. In both cases there is an optimal interval for the input signal level for which this inputerror correlation is very weak and the model of additive uncorrelated quantization noise provides a very accurate approximation. We determine the conditions under which the magnitude and phase of the measured correlation have negligible bias with respect to the unquantized values: we demonstrate that the magnitude bias is negligible only if both unquantized inputs are optimally quantized (i.e., when the uncorrelated quantization error model is valid), while the phase bias is negligible when 1) at least one of the inputs is optimally quantized, or when 2) the correlation coefficient between the unquantized inputs is small. Finally, we determine the implications of these results for radio interferometry.

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“…Input voltage data are collected from 256 dual-polarization receivers on each of the 4 cylinders, i.e., a total of 2048 distinct inputs. Custom FPGA boards (F-engine) [3,4] digitize and channelize these data to 1024 frequency channels via a 4-tap polyphase filter bank (PFB), then scale this voltage data to 4+4-bit complex numbers, at a 2.56 µs cadence (see Table 1). Spatial correlation (X-engine) is performed in a GPU cluster that consists of 256 processing nodes each with 4 AMD Fiji GPUs, similar to that presented in [10,6,7].…”

Section: Chime Correlatormentioning

confidence: 99%

CHIME FRB: An application of FFT beamforming for a radio telescope

Vanderlinde

Paradise

et al. 2017

2017 XXXIInd General Assembly and Scientific Symposium of the International Union of Radio Science (URSI GASS)

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We have developed FFT beamforming techniques for the CHIME radio telescope, to search for and localize the astrophysical signals from Fast Radio Bursts (FRBs) over a large instantaneous field-of-view (FOV) while maintaining the full angular resolution of CHIME. We implement a hybrid beamforming pipeline in a GPU correlator, synthesizing 256 FFT-formed beams in the North-South direction by four formed beams along East-West via exact phasing, tiling a sky area of ∼ 250 square degrees. A zero-padding approximation is employed to improve chromatic beam alignment across the wide bandwidth of 400 to 800 MHz. We up-channelize the data in order to achieve fine spectral resolution of ∆ν =24 kHz and time cadence of 0.983 ms, desirable for detecting transient and dispersed signals such as those from FRBs.

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ICE: A Scalable, Low-Cost FPGA-Based Telescope Signal Processing and Networking System

Cited by 53 publications

References 29 publications

HIRAX: a probe of dark energy and radio transients

HIRAX: a probe of dark energy and radio transients

Quantization Bias for Digital Correlators

CHIME FRB: An application of FFT beamforming for a radio telescope

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