@proceedings {850, title = {Trial of applying PHaRLAP raytracing to reproduce Ham spot data}, year = {2024}, month = {03/2024}, publisher = {HamSCI}, address = {Cleveland, OH}, abstract = {

HamSCI is one of the NASA{\textquoteright}s official citizen science projects. HamSCI\ spots database, which is from Reverse Beacon Network (RBN) and Weak Signal Propagation Reporter Network (WSPRNet), is of interest. Information of date, time, frequency, latitude, and longitude of transmitter and receiver are used. PHaRLAP is a raytracing tool that can trace the HF radio wave in 2D and 3D. We use the IRI model to generate the required ionospheric information. We employ the PHaRLAP\ to reproduce the ham spots database by launching the HF radio wave from the transmitter, of which its location is obtained from the HamSCI\ spots database. Then, we trace the O-mode propagation of the wave. The wave arrival latitude and longitude are then mapped into a grid based on the Amateur Radio Maidenhead Grid. Finally, we compare the raytracing-based arrival grid with the HamSCI\ arrival grid. The results, under the assumption of 1-hop propagation, show that the PHaRLAP\ raytracing can reproduce the HamSCI\ spots database well.

}, author = {Kornyanat Hozumi and Nathaniel A. Frissell and Min-Yang Chou and Gwyn Griffiths and William D. Engelke and Jia Yue and Shing Fung and Masha Kuznetsova} } @proceedings {731, title = {Coherent CW: A Claude Shannon Tempest on a Tabletop}, year = {2023}, month = {03/2023}, publisher = {HamSCI}, address = {Scranton, PA}, abstract = {

Experience CW as a GPS synchronized digital mode, legal on 80-40-15 for Technicians and excellent for everyone.

}, author = {Andre Yost and David Kazdan} } @proceedings {724, title = {Field-Aligned Potential Drops in an Ionospheric Streamer}, year = {2023}, month = {03/2023}, publisher = {HamSCI}, address = {Scranton, PA}, abstract = {

Field-aligned potential drops occur primarily in regions of strong upward field-aligned currents, where they can decouple the ionospheric and magnetospheric dynamics. They have been a challenge to incorporate into global magnetosphere modeling efforts. Low-entropy bubbles can form ionospheric streamers in the context of field-aligned potential drops. We have made a simple zeroth-order analytic model with order-of-magnitude reasonable field values. The model{\textquoteright}s parameter space comprises resistivity, bubble asymmetry, conductivity enhancement, and an additional parameter which can be used to adjust the entropy profiles across the bubble. We are currently exploring this parameter space and examining the resulting differences between the resulting ionospheric and magnetospheric electric fields (including electric field-reversals).\  An examination of whether bursty bulk flows or flow bursts are more likely to be responsible for streamers is ongoing.\  Both previous runs of the Rice Convection Model and data are being used to fit parameters and examine reasonable parameter regimes.

}, author = {Jason Derr and Sina Sadegzadeh and Richard Wolf and Frank Toffoletto and Jian Yang and Weiqin Sun} } @article {801, title = {Heliophysics and amateur radio: citizen science collaborations for atmospheric, ionospheric, and space physics research and operations}, journal = {Frontiers in Astronomy and Space Sciences}, volume = {10}, year = {2023}, month = {Apr-11-2024}, abstract = {

The amateur radio community is a global, highly engaged, and technical community with an intense interest in space weather, its underlying physics, and how it impacts radio communications. The large-scale observational capabilities of distributed instrumentation fielded by amateur radio operators and radio science enthusiasts offers a tremendous opportunity to advance the fields of heliophysics, radio science, and space weather. Well-established amateur radio networks like the RBN, WSPRNet, and PSKReporter already provide rich, ever-growing, long-term data of bottomside ionospheric observations. Up-and-coming purpose-built citizen science networks, and their associated novel instruments, offer opportunities for citizen scientists, professional researchers, and industry to field networks for specific science questions and operational needs. Here, we discuss the scientific and technical capabilities of the global amateur radio community, review methods of collaboration between the amateur radio and professional scientific community, and review recent peer-reviewed studies that have made use of amateur radio data and methods. Finally, we present recommendations submitted to the U.S. National Academy of Science Decadal Survey for Solar and Space Physics (Heliophysics) 2024{\textendash}2033 for using amateur radio to further advance heliophysics and for fostering deeper collaborations between the professional science and amateur radio communities. Technical recommendations include increasing support for distributed instrumentation fielded by amateur radio operators and citizen scientists, developing novel transmissions of RF signals that can be used in citizen science experiments, developing new amateur radio modes that simultaneously allow for communications and ionospheric sounding, and formally incorporating the amateur radio community and its observational assets into the Space Weather R2O2R framework. Collaborative recommendations include allocating resources for amateur radio citizen science research projects and activities, developing amateur radio research and educational activities in collaboration with leading organizations within the amateur radio community, facilitating communication and collegiality between professional researchers and amateurs, ensuring that proposed projects are of a mutual benefit to both the professional research and amateur radio communities, and working towards diverse, equitable, and inclusive communities.

}, doi = {10.3389/fspas.2023.1184171}, url = {https://www.frontiersin.org/articles/10.3389/fspas.2023.1184171/fullhttps://www.frontiersin.org/articles/10.3389/fspas.2023.1184171/full}, author = {Frissell, Nathaniel A. and Ackermann, John R. and Alexander, Jesse N. and Benedict, Robert L. and Blackwell, William C. and Boedicker, Rachel K. and Cerwin, Stephen A. and Collins, Kristina V. and Cowling, Scott H. and Deacon, Chris and Diehl, Devin M. and Di Mare, Francesca and Duffy, Timothy J. and Edson, Laura Brandt and Engelke, William D. and Farmer, James O. and Frissell, Rachel M. and Gerzoff, Robert B. and Gibbons, John and Griffiths, Gwyn and Holm, Sverre and Howell, Frank M. and Kaeppler, Stephen R. and Kavanagh, George and Kazdan, David and Kim, Hyomin and Larsen, David R. and Ledvina, Vincent E. and Liles, William and Lo, Sam and Lombardi, Michael A. and MacDonald, Elizabeth A. and Madey, Julius and McDermott, Thomas C. and McGaw, David G. and McGwier, Robert W. and Mikitin, Gary A. and Miller, Ethan S. and Mitchell, Cathryn and Montare, Aidan and Nguyen, Cuong D. and Nordberg, Peter N. and Perry, Gareth W. and Piccini, Gerard N. and Pozerski, Stanley W. and Reif, Robert H. and Rizzo, Jonathan D. and Robinett, Robert S. and Romanek, Veronica I. and Sami, Simal and Sanchez, Diego F. and Sarwar, Muhammad Shaaf and Schwartz, Jay A. and Serra, H. Lawrence and Silver, H. Ward and Skov, Tamitha Mulligan and Swartz, David A. and Themens, David R. and Tholley, Francis H. and West, Mary Lou and Wilcox, Ronald C. and Witten, David and Witvliet, Ben A. and Yadav, Nisha} } @proceedings {702, title = {The North Dakota Dual Aurora Camera Version 2.0 (NoDDAC2.0), a Platform for Citizen Science and a Use Case for Implementing Best Practices in Open Data and Collaboration}, year = {2023}, month = {03/2023}, publisher = {HamSCI}, address = {Scranton, PA}, abstract = {

The North Dakota Dual Aurora Camera (NoDDAC) is an interdisciplinary project created in collaboration with the University of North Dakota (UND), Live Aurora Network, and Aurorasaurus. Aurora cameras provide ground-truth visual data to aurora chasers and scientists but are sparse at midlatitudes (35-55{\textdegree}N). Deploying light-sensitive video and all-sky still cameras at these midlatitudes provides a valuable resource to aurora-chasing communities, as well as amateur radio operators in the auroral zone. In addition, NoDDAC data demonstrate scientific merit, as it can be correlated with radio and ionospheric propagation changes to investigate the connection between optical aurora and radio science. This project is unique; the practices of utilizing dual cameras with consumer-off-the-shelf equipment, emphasizing open data as a responsive community resource and promoting citizen science make NoDDAC an accessible resource benefiting multiple audiences. Since early 2021, NoDDAC has detected hundreds of auroras as well as notable events like STEVEs (Strong Thermal Emission Velocity Enhancement). NoDDAC is stationed at Martens Observatory (48.1{\textdegree}N, 97.6{\textdegree}W), which is operated by the UND Department of Physics and Astrophysics. Live Aurora Network provides weatherproof camera housings and their proprietary IPTimelapse software which allows for remote control of the cameras. This year we present NoDDAC2.0, the next evolution of NoDDAC funded by NASA{\textquoteright}s EPSCoR program. NoDDAC2.0 will upgrade the all-sky camera and feature a robust open-data platform to share aurora data with the public and scientists. We outline a strategy to increase the science utility of NoDDAC data, incorporating a citizen science project launching on the Zooniverse platform. We also present plans to integrate NoDDAC data into the AuroraX conjunction finder system so that satellite data can be easily correlated to aurora images. Most importantly, we are collaborating with the Nueta Hidatsa Sahnish College on the Fort Berthold Indian Reservation to install an independent aurora camera system in North Dakota. Not only does this represent a unique collaborative opportunity, but at a separation distance of 300 miles from Martens Observatory, this second camera will allow us to explore research questions relating to the precise location, height, and spatial extent of certain auroral phenomena.

}, author = {Timothy Young and Vincent Ledvina and Elizabeth MacDonald and Laura Brandt and Wayne Barkhouse and Alex Schultz and Cody Payne and Anne Mitchell and Kristian Haugen and Will Shearer and Kerry Hartman and Sasha Sillitti and Michael McCormack and Steve Collins} } @proceedings {751, title = {Toward Developing an Algorithm for Separation of Transmitters of High Frequency Chirp Signals of Opportunity for the Purpose of Ionospheric Sounding}, year = {2023}, month = {03/2023}, publisher = {HamSCI}, address = {Scranton, PA}, author = {Simal Sami and Nisha Yadav and Nathaniel A. Frissell and Robert Spalletta and Declan Mulhall and Dev Raj Joshi and Juha Vierinen} } @proceedings {747, title = {Web-Based Application for the Visualization and Analysis of Ionogram Data Observed by GNU Chirpsounder2}, year = {2023}, month = {03/2022}, publisher = {HamSCI}, address = {Scranton, PA}, abstract = {

The focus of my system is to develop a web-based application for the visualization and analysis of data observed by GNU Chirpsounder2. We receive many ionograms each day from different transmitters around the world. Currently, data is in an unsorted format, so my initial task is to classify ionograms by chirp-rate and distance of the transmitter from the receiver. Once these two parameters are identified, it is necessary to have a method for sorting, analyzing, and visualizing the collected ionograms to conduct scientific studies or make the observations useful for radio communications operations.

}, author = {Nisha Yadav and Simal Sami and Dev Raj Joshi and Nathaniel A. Frissell and Robert A. Spalletta and Paul M. Jackowitz and Juha Vierinen} } @proceedings {631, title = {Ham Radio and the Discovery of the Ionosphere (Keynote)}, year = {2022}, month = {03/2022}, publisher = {HamSCI}, address = {Huntsville, AL}, abstract = {

Ham radio{\textquoteright}s involvement in the discovery of the ionosphere during the early 20th century constitutes a core part of the radio amateur community{\textquoteright}s collective memory. I will review this episode in a broader historical context. Why radio waves could propagate over long distances along the earth{\textquoteright}s curvature had been debated since the invention of wireless telegraphy in the late 1890s. By the 1910s, physicists{\textquoteright} consensus was that radio waves bounced back from an electrically conductive surface in the upper sky known as the "Kennelly-Heaviside layer." Meanwhile, electrical engineers{\textquoteright} empirical studies led to the so-called "Austin-Cohen formula" that predicted a decrease of propagating range with wavelength, implying that transoceanic or transcontinental wireless communication could only be achieved at wavelengths longer than 200 m. Despite these scientific convictions, the American Radio Relay League (ARRL) and its sister organizations in the UK and France in the 1920s embarked large-scale collective experiments for transatlantic wireless signal transmission at wavelengths shorter than 200 m. Their success challenged the Austin-Cohen formula. In addition, ARRL members collaborated with US naval researchers to experiment with medium-range radio-wave propagation. Their studies resulted in the identification of the skip zone{\textemdash}that radio signals disappeared at certain distances from a transmitter but emerged again at a further range. These findings from radio amateurs{\textquoteright} activities paved a crucial ground for the British and American scientists Edward Appleton, Miles Barnett, Gregory Breit, and Merle Tuve to perform radio experiments that provided direct evidence for the ionosphere{\textemdash}a more complex geophysical entity than the Kennelly-Heaviside layer. In this talk, I will examine the radio amateurs{\textquoteright} collective experiments in the discovery of the ionosphere. I will also discuss the implications of this form of collaboration to ham radio{\textquoteright}s later collective technical activities and engagements with "citizen science."

}, author = {Chen-Pang Yeang} } @proceedings {614, title = {The North Dakota Dual Aurora Camera (NoDDAC), A Student-led Citizen Science Project: Data Showcase, Future Developments, and Scientific Potential}, year = {2022}, month = {03/2022}, publisher = {HamSCI}, address = {Huntsville, AL}, abstract = {

The North Dakota Dual Aurora Camera (NoDDAC) is a student-led project in collaboration with the University of North Dakota (UND), Live Aurora Network, and Aurorasaurus. Aurora cameras provide ground-truth visual data to aurora chasers and scientists, but are sparse at midlatitudes. Deploying a light-sensitive video camera and allsky still camera in these areas provides a valuable resource to aurora-chasing communities, including ham radio operators in the auroral zone, and demonstrates scientific merit. For example, the analysis of rare phenomena benefits from observations at multiple locations. In addition, NoDDAC data can be correlated with radio and ionospheric propagation changes, as well as geomagnetic activity, to investigate the connection between optical aurora and radio science. This project is unique; utilizing dual cameras with COTS equipment, emphasizing open data as a responsive community resource, and promoting citizen science make it an accessible resource benefing multiple audiences. Since early 2021, NoDDAC has detected aurora on more than 20 occasions, as well as unusual events like overhead auroras, STEVEs, and noctilucent clouds.\ 

NoDDAC is stationed at Martens Observatory (48.1{\textdegree}N), which is operated by the UND Department of Physics and Astrophysics. Live Aurora Network housings weatherproof both cameras, and their proprietary IPTimelapse software uploads images to a web server for analysis. The north-facing camera records video, allowing Zooniverse-style citizen science for small auroral features. Live Aurora Network streams both cameras on their website and app. Ultimately, when aurora is detected IPTimelapse will post a clip of the display to @NODDAC_cameras on Twitter. Automated reports will be mapped on Aurorasaurus, alongside citizen scientist observations. Image data are archived according to open source and FAIR data principles. NoDDAC will also look for crossovers with projects such as the Personal Space Weather Station to provide additional ground-based measurements of the space environment. This presentation will reflect on the data captured with NoDDAC and outline a timeline for its future, and open the floor for collaborations with other citizen science efforts.

}, author = {Vincent Ledvina and Elizabeth MacDonald and Laura Brandt and Michael McCormack and Steve Collins and Wayne Barkhouse and Timothy Young} } @conference {398, title = {Construction of an Aurora Camera in North Dakota to Aid in Citizen Science and Space Weather Applications (ePoster)}, booktitle = {HamSCI Workshop 2020}, year = {2020}, month = {03/2020}, publisher = {HamSCI}, organization = {HamSCI}, address = {Scranton, PA}, abstract = {

We will present plans for a new student-built aurora camera integrated with a public university, local astronomy groups, and Aurorasaurus citizen science. Live aurora cameras are crucial tools for avid skywatchers, aurora chasers, and scientists.\ \ Globally there are hundreds of cameras providing nowcast views of aurora strength, yet in low-latitude areas, especially in the United States, the number of high-quality, live aurora cameras is extremely limited.\ \ The need for aurora camera coverage in mid-latitudes is apparent; not only will it be another resource for amateur astronomers and aurora-watching communities, but the analysis of many transient auroral phenomena such as substorms and STEVEs benefit from multiple geographical observations.\ \ A north-facing camera will be built near Inkster, North Dakota, on the Martens Observatory location (approximately 48.1oN), broadcasting a public live stream of the night sky while simultaneously offloading images to a storage server.\ \ The Sony a7s2 mirrorless camera, a model employed by other live broadcasts such as the LiveAuroraNetwork, will be used in conjunction with a wide-aperture lens for maximum light-gathering ability.\ \  The entire apparatus will be housed in a weatherproof enclosure and internet will be supplied on-site.\ \ The camera will be integrated with the University of North Dakota{\textquoteright}s Astrophysics and Space Studies department and will be a resource for the local astronomy community, the Northern Sky Astronomical Society.\ \ Working with Aurorasaurus, the aurora camera will {\textquotedblleft}tweet{\textquotedblright} when an aurora is spotted and be shown on the Aurorasaurus auroral oval map along with other citizen scientist observations.\ \ This aurora camera will be a valuable resource for citizen science and will aid scientists in attempting to unravel the mysteries of Earth{\textquoteright}s magnetism.

}, author = {Vincent Ledvina and Elizabeth MacDonald and Wayne Barkhouse and Timothy Young} } @article {255, title = {Citizen radio science: an analysis of Amateur Radio transmissions with e-POP RRI}, journal = {Radio Science}, year = {2018}, abstract = {

We report the results of a radio science experiment involving citizen scientists conducted on 28 June 2015, in which the Radio Receiver Instrument (RRI) on the Enhanced Polar Outflow Probe (e-POP) tuned-in to the 40 and 80 m Ham Radio bands during the 2015 American Radio Relay League (ARRL) Field Day. We have aurally decoded the Morse coded call signs of 14 Hams (amateur operators) from RRI{\textquoteright}s data to help ascertain their locations during the experiment. Through careful analysis of the Hams{\textquoteright} transmissions, and with the aid of ray tracing tools, we have identified two notable magnetoionic effects in the received signals: plasma cutoff and single-mode fading. The signature of the former effect appeared approximately 30 seconds into the experiment, with the sudden cessation of signals received by RRI despite measurements from a network of ground-based receivers showing that the Hams{\textquoteright} transmissions were unabated throughout the experiment. The latter effect, single-mode fading, was detected as a double-peak modulation on the individual {\textquotedblleft}dots{\textquotedblright} and {\textquotedblleft}dashes{\textquotedblright} of one the Ham{\textquoteright}s Morse coded transmissions. We show that the modulation in the Ham{\textquoteright}s signal agrees with expected fading rate for single-mode fading. The results of this experiment demonstrate that Ham Radio transmissions are a valuable tool for studying radio wave propagation and remotely sensing the ionosphere. The analysis and results provide a basis for future collaborations in radio science between traditional researchers in academia and industry, and citizen scientists in which novel and compelling experiments can be performed.

}, keywords = {Citizen Science, ionosphere, Radio Propagation, Radio Science, Satellite}, doi = {10.1029/2017RS006496}, url = {https://agupubs.onlinelibrary.wiley.com/doi/abs/10.1029/2017RS006496}, author = {Perry, G. W. and Frissell, N. A. and Miller, E. S. and Moses, M. and Shovkoplyas, A. and Howarth, A. D. and Yau, A. W.} } @conference {51, title = {e-POP Radio Science Using Amateur Radio Transmissions}, booktitle = {Fall AGU - Poster Presentation}, year = {2015}, month = {12/2015}, publisher = {American Geophysical Union}, organization = {American Geophysical Union}, address = {San Francisco, CA}, abstract = {

A major component of the enhanced Polar Outflow Probe (e-POP) Radio Receiver Instrument (RRI) mission is to utilize artificially generated radio emissions to study High Frequency (HF) radio wave propagation in the ionosphere. In the North American and European sectors, communications between amateur radio operators are a persistent and abundant source source of HF transmissions. We present the results of HF radio wave propagation experiments using amateur radio transmissions as an HF source for e-POP RRI. We detail how a distributed and autonomously operated amateur radio network can be leveraged to study HF radio wave propagation as well as the structuring and dynamics of the ionosphere over a large geographic region. In one case, the sudden disappearance of nearly two-dozen amateur radio HF sources located in the midwestern United States was used to detect a enhancement in foF2 in that same region. We compare our results to those from other more conventional radio instruments and models of the ionosphere to demonstrate the scientific merit of incorporating amateur radio networks for radio science at HF.

}, author = {Nathaniel A. Frissell and Gareth Perry and Ethan S. Miller and Alex Shovkoplyas and Magdalina Moses and H. James and Andrew Yau} }