TY - Generic T1 - University of Michigan Space Weather Sensor Package T2 - HamSCI Workshop 2024 Y1 - 2024 A1 - Theodore Masterson A1 - Mark B. Moldwin A1 - Lauro Ojeda A1 - Julio Vata A1 - Isaac Fertig A1 - Alex Hofmann A1 - Brian Tsang AB -

Ground magnetometer and dual frequency GPS systems are used to measure space weather effects observed in geomagnetic disturbances and variations in Total Electron Content (TEC). However, such systems are usually cost-prohibitive, susceptible to noise from human infrastructure, and difficult to deploy and maintain. Our team has been working on a low-cost space weather sensor package that can be easily deployed and requires low maintenance while having good magnetic and TEC data accuracy. The system has multiple options with respect to power (e.g., AC powered or solar panel and battery system), communication (Cat5 internet, Wi-Fi, Cellular or satellite modem), and sensors (use of network protocol time, single frequency GPS time stamping, or dual frequency GPS for both time and TEC). This presentation describes the low-cost magnetometer sensor package, the simple user interfaces, and design of the electrical and structural components for ease of manufacturing. We have developed a prototype for a system that is much cheaper and easier to mass-produce and install than current commercial systems, and real-world testing has shown that these systems function reliably.

JF - HamSCI Workshop 2024 PB - HamSCI CY - Cleveland, OH ER - TY - Generic T1 - Three Time-of-Flight Measurement Projects on a Common Hardware Platform T2 - HamSCI Workshop 2022 Y1 - 2022 A1 - David Kazdan A1 - John Gibbons A1 - Kristina Collins A1 - Maxwell Bauer A1 - Evan Bender A1 - Ryan Marks A1 - Michael O'Brien A1 - Olivia O'Brien A1 - Gabriel Foss A1 - Mari Pugliese A1 - Alejandra Ramos A1 - Carolina Whitaker AB -

Three undergraduate electrical engineering project groups at Case Western Reserve University are investigating distributed ionospheric sounding through time-of-flight measurements.  All use GPS pulse-per-second signals for precise timing of received signals.  Two use as their "radar signals of opportunity" LF, MF, and HF beacons from the US Department of Commerce National Institute of Science and Technology installations north of Fort Collins, Colorado and near Kekaha, Hawaii (radio stations WWVB, WWV, and WWVH).  The third project modernizes the on-off telegraphy variant known as "coherent CW" (CCW). CCW uses amateur radio QSO or beacon transmissions as the measured signals.  It facilitates Technician-licensee participation in active HF research and in keyboard-to-keyboard digital contacts, within FCC regulations.  Using computed matched-filter techniques along the lines of FT8, CCW has a nearly optimal information-theoretic data recovery.  With transmission or lookup of station locations, it can provide automated time of flight measurements while making a contact.  The three projects use a common hardware platform for receiver or transceiver interfacing, involving synchronized analog data collection and front-end data processing with the Teensy variant of the Arduino platform.  Teensy was chosen primarily for its sampling and computing speed. WWVB’s signal can be sampled directly with the Teensy front-end and some data processing can done between sample acquisitions through timer interrupt programming.  WWV/H second ticks delay measurements use inexpensive shortwave radio audio outputs, sampled and processed by the Teensy.  The CCW sampling and matched filtering, plus synchronized Morse keying, are similarly done by the Teensy. Data presentation, user interface, and data uploading to repositories are done by minimal general purpose computers such as Raspberry Pi boards.  We will present the common hardware and interrupt strategies along with a brief overview of the three projects.  Comments and suggestions will be solicited, and of course participation in the projects is invited.  The three projects are supported by a generous grant to the Case Amateur Radio Club W8EDU from ARDC.  CARC is providing oversight of the projects and the projects use the club station as a laboratory facility.

JF - HamSCI Workshop 2022 PB - HamSCI CY - Huntsville, AL ER - TY - Generic T1 - e-POP RRI observations of the April 24, 2020 ARRL Frequency Measuring Test T2 - HamSCI Workshop 2021 Y1 - 2021 A1 - Brian O'Donnell A1 - Gareth Perry AB -

One of the science objectives of the Radio Receiver Instrument (RRI) on the CAScade, Smallsat, and Ionospheric Polar Explorer/enhanced Polar Outflow Probe (CASSIOPE/e-POP) satellite is to study ionospheric influences on high frequency (HF) radio wave from low Earth orbit. RRI is made-up of 4, 3-m monopoles which can be electronically arranged into a crossed-dipole configuration.  On April 24, 2020, RRI tuned to measure the ARRL frequency measuring test (FMT) on 40 m, and successfully recorded part of the “call up” and all of the “key down” segments of the test.  The FMT provides a unique chance to study the effects of the ionospheric plasma on stable and reliable radio signals at frequencies that are close to the ionosphere’s critical frequency, a frequency regime in which the influence of the ionospheric plasma on radio wave propagation conditions is most pronounced.  In this presentation, we give preliminary results of our analysis of RRI’s FMT measurements which include an examination of the FMT’s Doppler characteristics, and the identification tell-tale signatures of ionospheric effects on the transmitted signal such as Faraday rotation and propagation mode delay.

JF - HamSCI Workshop 2021 PB - HamSCI CY - Scranton, PA (Virtual) UR - https://hamsci2021-uscranton.ipostersessions.com/?s=34-2B-1B-32-C8-FC-4A-0B-5B-51-B9-1D-10-4E-F2-7F ER -