A low-resolution, GSa/s streaming digitizer for a correlation-based trigger system

TL;DR

This paper introduces RITC, a low-resolution, high-speed streaming digitizer designed for real-time correlation triggering in ultra-high energy neutrino detection, enabling efficient broadband radio signal digitization under power constraints.

Contribution

The paper presents the design and implementation of RITC, a 3-bit, 3-channel streaming ADC with >1 GHz bandwidth and 2.6 Gsps sampling rate, tailored for ultra-high energy neutrino experiments.

Findings

RITC achieves >1 GHz analog bandwidth.

It supports 2.6 gigasamples-per-second sampling.

The system enables real-time correlation triggering.

Abstract

Searches for radio signatures of ultra-high energy neutrinos and cosmic rays could benefit from improved efficiency by using real-time beamforming or correlation triggering. For missions with power limitations, such as the ANITA-3 Antarctic balloon experiment, full speed high resolution digitization of incoming signals is not practical. To this end, the University of Hawaii has developed the Realtime Independent Three-bit Converter (RITC), a 3-channel, 3-bit, streaming analog-to-digital converter implemented in the IBM-8RF 0.13 um process. RITC is primarily designed to digitize broadband radio signals produced by the Askaryan effect, and thus targets an analog bandwidth of >1 GHz, with a sample-and-hold architecture capable of storing up to 2.6 gigasamples-per-second. An array of flash analog-to-digital converters perform 3-bit conversion of sets of stored samples while acquisition continues elsewhere in the sampling array. A serial interface is provided to access an array of on chip digital-to-analog converters that control the digitization thresholds for each channel as well as the overall sampling rate. Demultiplexed conversion outputs are read out simultaneously for each channel via a set of 36 LVDS links, each running at 650 Mb/s. We briefly describe the design architecture of RITC. Evaluation of the RITC is currently under way, and we will report testing updates as they become available, including prospects for the use of this architecture as the analog half of a novel triggering system for the ANITA-3 ultra-high energy neutrino experiment.