TY - Generic T1 - "And Science will Know To-morrow": An Exploration of Rudyard Kipling's "Wireless" T2 - HamSCI Workshop 2024 Y1 - 2024 A1 - Leah Davydov AB -

Written in 1902, Rudyard Kipling's short story "Wireless" juxtaposes early exercises in short-wave radio transmission with Victorian spiritualism. It tells a dual account of a misdirected "transmissions" as one man's interception of wireless telegraph signals plays out alongside seeming instant of spiritual possession. While the supernatural element of the story remains ambiguous--and receives a curt dismissal from the narrative's suspected medium himself--the "Marconi experiment" playing out in the background has long proven an intriguing element of the narrative. For those familiar with much earlier proposed theories of animal magnetism upon which seances often rested, wireless technology could readily be read as keeping in step with popular theories of the era eventually discarded as pseudoscience. In this talk, I will look to the how Kipling presents a story in which radio is superimposed upon the pre-existing "scientific" paradigms of mesmeric models of psychical phenomena--exploring how Marconi's cutting edge experiments might be read by an audience primed to believe in very different sorts of waves and forces.

JF - HamSCI Workshop 2024 PB - HamSCI CY - Cleveland, OH ER - TY - Generic T1 - Construction of a Table-Top Antenna Range for Learning Electromagnetics Concepts T2 - HamSCI Workshop 2024 Y1 - 2024 A1 - Augustine Brapoh A1 - Matthew Dittmar A1 - Aidan Szabo A1 - Robert Troy A1 - Nathaniel Frissell A1 - Stephen A. Cerwin AB -

Antenna construction and measurement provide an effective method of teaching electromagnetic and antenna concepts, including polarization, gain, directivity, and reflection. During the Spring 2024 semester, the University of Scranton EE 448 Electromagnetics II class is undertaking a project to build a table-top antenna range at 2450 MHz (λ = 12 cm). The table top range will give hands-on visual and intuitive reinforcement of abstract concepts covered mathematically in the course textbook. This frequency was chosen due to the convenient size of antennas and the fact that the antennas will be usable in the 2.4 GHz Industrial, Scientific, and Medical (ISM) and amateur bands. ISM band applications include WiFi, Bluetooth, RFID, NFC, and more. In this presentation and poster, we demonstrate three types of antennas the class has built so far: dipoles, dipoles with corner reflectors, and loops over ground planes. We also demonstrate the use of a NanoVNA to measure antenna properties, as well as show ideas for future projects.

JF - HamSCI Workshop 2024 PB - HamSCI CY - Cleveland, OH ER - TY - Generic T1 - PyLAP/PHaRLAP HF Ray Tracing and SAMI3: Integration and Refactoring T2 - HamSCI Workshop 2024 Y1 - 2024 A1 - Devin Diehl A1 - Rachel Boedicker A1 - Joseph Huba A1 - Nathaniel A. Frissell AB -

PyLAP is a high frequency (HF) ray tracing toolkit that is used to model radio wave propagation through the ionosphere. Currently PyLAP uses the empirical International Reference Ionosphere (IRI) model. In an effort to use PyLAP to observe more discrete structures in ionosphere that are otherwise unobservable with IRI, PyLAP is being Integrated with the Physics-based SAMI3 Model of the ionosphere. Along with this there will be an effort to refactor some of the current PyLAP codebase so that it is more readable and usable for anyone using the current system including both professional and citizen scientists.

JF - HamSCI Workshop 2024 PB - HamSCI CY - Cleveland, OH ER - TY - Generic T1 - Ray-trace modelling of diurnal variation in two-hop sidescatter propagation T2 - HamSCI Workshop 2024 Y1 - 2024 A1 - Gwyn Griffiths A1 - Devin Diehl A1 - R. Lynn Rhymes A1 - Frederick Wahl AB -

Two-hop sidescatter, an off-great circle propagation mode enabling above-the-basic-MUF communications, is identified by low SNR and high spectral spread (width between -3 dB points). Observable at 7 MHz and above, as a daytime mode it enables propagation from 10s km to 100s km. Additionally, it may appear before, and or after, great-circle one-hop propagation as it operates with a lower F2 layer critical frequency. We have devised a computationally efficient modelling approach for two-hop sidescatter using 3D ray tracing. First, ray landing spots from a transmitter are found over 360° azimuth and a sensible range of elevations. Second, the process is repeated for a transmitter at the receiver. The key assumption is that reciprocity holds sufficiently to avoid the computationally demanding need to place a transmitter at every transmitter ray landing spot. A scattering metric, the product of the number of landing spots from transmitter and pseudo-transmitter in a 1°x1° area, is a useful approximation to the location and strength of the sidescatter. The off-great circle scattering location from the model has been verified by a rotating-antenna experiment at 14 MHz on paths from Northern California to Utah and Oregon using FST4W digital mode. The diurnal variations of sidescatter location and strength are particularly interesting for a meridional transmitter and receiver geometry: morning (local time) scatter from the east, from land on the California to Oregon path, with afternoon through nighttime scatter from the west, from the ocean. We discuss a qualitative comparison of hourly model simulations with signal level and circuit reliability data from FST4W spots. The nighttime minimum in both parameters is pronounced in the observations and model. An afternoon dip in circuit reliability, without reduction in signal level, is tentatively explained by the model showing strongest scatter alternating between east and west before settling to the west. We postulate that severe multipath scatter from both east and west, land and ocean, sufficiently increased frequency spread to reduce probability of decode for the ~6 Hz bandwidth FST4W mode. This study illustrates the usefulness of combining 3D ray tracing with purposeful observations to explain an underappreciated propagation mode.

JF - HamSCI Workshop 2024 PB - HamSCI CY - Cleveland, OH ER - TY - Generic T1 - Why is sporadic-E propagation so weird? T2 - HamSCI Workshop 2024 Y1 - 2024 A1 - Chris Deacon AB -

Mid-latitude sporadic-E ("Es") clouds are transient, thin layers of dense but patchy ionization which appear in the E region of the ionosphere. The process of formation of Es is different from that of the background ionosphere and can, by comparison, produce much higher ionization densities. Sporadic-E propagation is well known to radio amateurs because it allows communication at higher frequencies and/or over shorter skip distances than is possible via the background ionosphere, but Es is also currently the subject of much academic research. This is partly because of the disruptive impact of Es on satellite communications and satellite radars, but there is also growing scientific interest in the Mesosphere / Lower Thermosphere region of the upper atmosphere, which is where Es mainly occurs. The thin, intense, and variable nature of Es means that reflected signals can have quite extreme temporal, spatial, and polarization characteristics. My PhD research showed that the reflection process at 50 MHz is primarily magnetoionic in nature, but many detailed features remain to be explained. To explore the observed polarization behaviour in more detail and to link that behaviour to the physical properties of the Es layers, a PHaRLAP-based raytrace simulation has been developed which predicts polarization parameters a signal passes through an Es cloud. As a case study, the observed significant and systematic differences in the polarization of the signals received in the UK over very similar paths from beacons in Hungary and Slovenia have been investigated in detail. Each of the two beacons shows strongly defined elliptical polarization, but the sense of rotation and predominant tilt angle are consistently opposite from each other, over multiple Es reflection events and on multiple days. This presentation will summarize the earlier work and then describe the building and testing of the PHaRLAP simulation model and the case study results obtained so far. Finally, outstanding questions about the weird nature of Es propagation will be discussed and opportunities for further work described.

JF - HamSCI Workshop 2024 PB - HamSCI CY - Cleveland, OH ER - TY - Generic T1 - AC Motor Drive With Power Factor Correction Using Arduino T2 - HamSCI Workshop 2023 Y1 - 2023 A1 - Christian D. Chakiris A1 - Robert C. Brudnicki A1 - Robert D. Troy A1 - John A. Nelson A1 - Matthew K. Dittmar A1 - Augustine D. Brapoh Jr. A1 - Milton Andrade A1 - Sade Lugo A1 - Aidan T. Szabo A1 - Kenneth Dudeck AB -

By using various electrical and computer engineering concepts, this project incorporates different sectors explored through current curriculum. By implementing these concepts, a fully functioning AC motor controller will be designed. The project is split into 5 groups: AC to DC power conversion, DC to AC power control, power factor correction, capacitor bank control, and Arduino interfacing, all working on separate critical components for the motor controller. As this is currently a work in progress, actual conclusions cannot be made, but speculation based on calculations is available.

JF - HamSCI Workshop 2023 PB - HamSCI CY - Scranton, PA ER - TY - Generic T1 - Evaluation of Global Ionospheric TEC Using Simultaneous Observations from Amateur Radio Networks, International Space Station, and NeQuickG Model for Space Weather Prediction T2 - HamSCI Workshop 2023 Y1 - 2023 A1 - Gamal Zayed A1 - Marcin Lesniowski A1 - Pasumarthi Babu Sree Harsha A1 - Matthew Downs A1 - Daniel Metcalfe A1 - Sila Kardelen Karabulut AB -

Ionospheric electron density plays a significant role in long-distance communications and sky-wave propagation. Prediction of the accurate state of the ionosphere is necessary to understand the accurate signal perturbations thereby estimating the critical parameters for better signal transmission. The space weather impacts on such trans-ionospheric technological systems are evident. In this work, a web application is developed to represent the global day-to-day electron density variations from the NeQuickG model. Also, the ground-based HAM radio broadcast network hop data with different wavelengths (eg. 10 m and 20 m) and simultaneous top-side electron density with space-based International Space Station (ISS) probe data from floating point measurement units are examined. The electron density variations for the year 2017 are clearly represented. Optimization techniques are necessary to frame a denser spatial grid-based ionospheric electron density map from all the observations. It is essential to estimate the optimal weight function that can distribute the observation influence over empty grid bins with minimum error variance through a probabilistic approach. User-understandable metrics development exclusively for Amateur radio operators and civil aviation sectors is focused. In the near future, the developed web-based application could serve as a better visualization platform for space weather forecasting.

This project, Fellowship of the Ionosphere, is a Global Finalist in the 2022 NASA Space Apps Challenge. NASA Space Apps 2022 had 31,400+ registered participants from 162 counties and territories, with over 3000 submissions from 5327 teams. Global Finalists are ranked as one of the top 35 projects from all submissions.

JF - HamSCI Workshop 2023 PB - HamSCI CY - Scranton, PA ER - TY - Generic T1 - Field-Aligned Potential Drops in an Ionospheric Streamer T2 - HamSCI Workshop 2023 Y1 - 2023 A1 - Jason Derr A1 - Sina Sadegzadeh A1 - Richard Wolf A1 - Frank Toffoletto A1 - Jian Yang A1 - Weiqin Sun AB -

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’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.

JF - HamSCI Workshop 2023 PB - HamSCI CY - Scranton, PA ER - TY - JOUR T1 - Heliophysics and amateur radio: citizen science collaborations for atmospheric, ionospheric, and space physics research and operations JF - Frontiers in Astronomy and Space Sciences Y1 - 2023 A1 - Frissell, Nathaniel A. A1 - Ackermann, John R. A1 - Alexander, Jesse N. A1 - Benedict, Robert L. A1 - Blackwell, William C. A1 - Boedicker, Rachel K. A1 - Cerwin, Stephen A. A1 - Collins, Kristina V. A1 - Cowling, Scott H. A1 - Deacon, Chris A1 - Diehl, Devin M. A1 - Di Mare, Francesca A1 - Duffy, Timothy J. A1 - Edson, Laura Brandt A1 - Engelke, William D. A1 - Farmer, James O. A1 - Frissell, Rachel M. A1 - Gerzoff, Robert B. A1 - Gibbons, John A1 - Griffiths, Gwyn A1 - Holm, Sverre A1 - Howell, Frank M. A1 - Kaeppler, Stephen R. A1 - Kavanagh, George A1 - Kazdan, David A1 - Kim, Hyomin A1 - Larsen, David R. A1 - Ledvina, Vincent E. A1 - Liles, William A1 - Lo, Sam A1 - Lombardi, Michael A. A1 - MacDonald, Elizabeth A. A1 - Madey, Julius A1 - McDermott, Thomas C. A1 - McGaw, David G. A1 - McGwier, Robert W. A1 - Mikitin, Gary A. A1 - Miller, Ethan S. A1 - Mitchell, Cathryn A1 - Montare, Aidan A1 - Nguyen, Cuong D. A1 - Nordberg, Peter N. A1 - Perry, Gareth W. A1 - Piccini, Gerard N. A1 - Pozerski, Stanley W. A1 - Reif, Robert H. A1 - Rizzo, Jonathan D. A1 - Robinett, Robert S. A1 - Romanek, Veronica I. A1 - Sami, Simal A1 - Sanchez, Diego F. A1 - Sarwar, Muhammad Shaaf A1 - Schwartz, Jay A. A1 - Serra, H. Lawrence A1 - Silver, H. Ward A1 - Skov, Tamitha Mulligan A1 - Swartz, David A. A1 - Themens, David R. A1 - Tholley, Francis H. A1 - West, Mary Lou A1 - Wilcox, Ronald C. A1 - Witten, David A1 - Witvliet, Ben A. A1 - Yadav, Nisha AB -

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) 2024–2033 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.

VL - 10 UR - https://www.frontiersin.org/articles/10.3389/fspas.2023.1184171/fullhttps://www.frontiersin.org/articles/10.3389/fspas.2023.1184171/full JO - Front. Astron. Space Sci. ER - TY - Generic T1 - Institute of Electrical and Electronics Engineers at the University of Scranton T2 - HamSCI Workshop 2023 Y1 - 2023 A1 - Cuong Nguyen A1 - Veronica Romanek A1 - Francis Lynch Jr. A1 - Joseph Tholley A1 - Robert Troy A1 - Matthew Dittmar A1 - John Nelson A1 - Sade Lugo AB -

The Institute of Electrical and Electronics Engineers (IEEE) is an international professional association for all things electronic engineering and electrical engineering. The mission of the IEEE is “advancing technology for the benefit of humanity”. At the University of Scranton, we help physics and engineering majors see the possibilities of where they could end up after college in their respective fields. Weekly seminars are tailored to present the business processes involved and innovative ideas developed by various researchers, companies, and industries. The club also serves as the social network through which our students and alumni can share their experiences and form a friendship that transcends many stages of life.

JF - HamSCI Workshop 2023 PB - HamSCI CY - Scranton, PA ER - TY - Generic T1 - Medium Scale Traveling Ionospheric Disturbances and their Connection to the Lower and Middle Atmosphere T2 - HamSCI Workshop 2023 Y1 - 2023 A1 - Nathaniel A. Frissell A1 - Francis Tholley A1 - V. Lynn Harvey A1 - Sophie R. Phillips A1 - Katrina Bossert A1 - Sevag Derghazarian A1 - Larisa Goncharenko A1 - Richard Collins A1 - Mary Lou West A1 - Diego F. Sanchez A1 - Gareth W. Perry A1 - Robert B. Gerzoff A1 - Philip J. Erickson A1 - William D. Engelke A1 - Nicholas Callahan A1 - Lucas Underbakke A1 - Travis Atkison A1 - J. Michael Ruohoniemi A1 - Joseph B. H. Baker JF - HamSCI Workshop 2023 PB - HamSCI CY - Scranton, PA ER - TY - Generic T1 - A New Station for the W3USR University of Scranton Amateur Radio Club T2 - HamSCI Workshop 2023 Y1 - 2023 A1 - Tom Pisano A1 - Nathaniel Frissell A1 - Jeff DePolo A1 - The W3USR University of Scranton Amateur Radio Club JF - HamSCI Workshop 2023 PB - HamSCI CY - Scranton, PA ER - TY - Generic T1 - Power Factor Detection and Correction of a Variable Speed AC motor T2 - HamSCI Workshop 2023 Y1 - 2023 A1 - Christian Chakirus A1 - Robert Brudnicki A1 - Robert Troy A1 - Kenneth Dudeck JF - HamSCI Workshop 2023 PB - HamSCI CY - Scranton, PA ER - TY - Generic T1 - PyLap: An Open Source Python Interface to the PHaRLAP Ionospheric Raytracing Toolkit T2 - HamSCI Workshop 2023 Y1 - 2023 A1 - Devin Diehl A1 - Gerard Piccini A1 - Alexander Calderon A1 - Joshua Vega A1 - William Liles A1 - Nathaniel A. Frissell AB -

PyLap is a Python interface to the ionospheric ray tracing toolkit PHaRLAP. The software allows users to generate accurate models of the ionosphere and ray tracing to make plots of radio propagation through the ionosphere. Not only does this software look, feel, and operate very similarly to how the MATLAB interface is currently used, it is also completely free alternative to the current MATLAB interface.

JF - HamSCI Workshop 2023 PB - HamSCI CY - Scranton, PA ER - TY - JOUR T1 - Amateur Radio: An Integral Tool for Atmospheric, Ionospheric, and Space Physics Research and Operations JF - White Paper Submitted to the National Academy of Sciences Decadal Survey for Solar and Space Physics (Heliophysics) 2024-2033 Y1 - 2022 A1 - Nathaniel A. Frissell A1 - Laura Brandt A1 - Stephen A. Cerwin A1 - Kristina V. Collins A1 - David Kazdan A1 - John Gibbons A1 - William D. Engelke A1 - Rachel M. Frissell A1 - Robert B. Gerzoff A1 - Stephen R. Kaeppler A1 - Vincent Ledvina A1 - William Liles A1 - Michael Lombardi A1 - Elizabeth MacDonald A1 - Francesca Di Mare A1 - Ethan S. Miller A1 - Gareth W. Perry A1 - Jonathan D. Rizzo A1 - Diego F. Sanchez A1 - H. Lawrence Serra A1 - H. Ward Silver A1 - David R. Themens A1 - Mary Lou West ER - TY - Generic T1 - Consolidated Amateur Radio Reports as Indicators of Intense Sporadic-E Layers T2 - HamSCI Workshop 2022 Y1 - 2022 A1 - Chris Deacon A1 - Cathryn Mitchell A1 - Robert Watson AB -

A case study is presented to demonstrate the usefulness and validity of consolidated amateur (‘ham’) radio signal reports as indicators of the presence of ionospheric sporadic-E (Es). It is shown that amateur data can provide an important supplement to other techniques, allowing the detection of Es where no suitable ionosonde or satellite radio occultation measurements are available. The effectiveness of the approach is demonstrated by reference to ionosonde data, and the advantages and limitations of the technique are discussed.

JF - HamSCI Workshop 2022 PB - HamSCI CY - Huntsville, AL ER - TY - JOUR T1 - Fostering Collaborations with the Amateur Radio Community JF - White Paper Submitted to the National Academy of Sciences Decadal Survey for Solar and Space Physics (Heliophysics) 2024-2033 Y1 - 2022 A1 - Nathaniel A. Frissell A1 - Laura Brandt A1 - Stephen A. Cerwin A1 - Kristina V. Collins A1 - Timothy J. Duffy A1 - David Kazdan A1 - John Gibbons A1 - William D. Engelke A1 - Rachel M. Frissell A1 - Robert B. Gerzoff A1 - Stephen R. Kaeppler A1 - Vincent Ledvina A1 - William Liles A1 - Elizabeth MacDonald A1 - Gareth W. Perry A1 - Jonathan D. Rizzo A1 - Diego F. Sanchez A1 - H. Lawrence Serra A1 - H. Ward Silver A1 - Tamitha Mulligan Skov A1 - Mary Lou West ER - TY - Generic T1 - Ionosphere Plasma Density Estimation by Ray Tracing Optimization T2 - HamSCI Workshop 2022 Y1 - 2022 A1 - David de la Torre A1 - Enrique Rojas AB -

In recent years, several studies have tried to estimate volumetric electron density by methods of refraction tomography on an HF network. These methods involve a dynamic optimization problem where the ray tracing equations have to be solved in every optimization step. Furthermore, to improve the estimates, data from incoherent scatter radars and GPS can also be assimilated. However, the computational complexity involved in these estimates is considerable. Even though some efforts have been implemented to reduce this complexity, it is clear that new methods have to be explored. Furthermore, to our knowledge, the possibility of using the frequency sweep capability of ionosondes has not been considered. This work simplifies the dispersion relation to an unmagnetized collisionless plasma to focus our efforts on the inverse process. Instead of using sensitivity analysis, we propose a direct collocation approach, where the points on the transmitter and receiver can be fixed, therefore, eliminating the chances of the extreme misfire.

JF - HamSCI Workshop 2022 PB - HamSCI CY - Huntsville, AL ER - TY - CONF T1 - The Radio JOVE Project 2.0 T2 - HamSCI Workshop 2022 Y1 - 2022 A1 - C. Higgins A1 - S. Fung A1 - L. Garcia A1 - J. Thieman A1 - J. Sky A1 - D. Typinski A1 - R. Flagg A1 - J. Brown A1 - F. Reyes A1 - J. Gass A1 - L. Dodd A1 - T. Ashcraft A1 - W. Greenman A1 - S. Blair AB -

Radio JOVE is a well-known public outreach, education, and citizen science project using radio astronomy and a hands-on radio telescope for science inquiry and education. Radio JOVE 2.0 is a new direction using radio spectrographs to provide a path for radio enthusiasts to grow into citizen scientists capable of operating their own radio observatory and providing science-quality data to an archive. Citizen scientists will have opportunities for presenting and publishing scientific papers. Radio JOVE 2.0 uses more capable software defined radios (SDRs) and spectrograph recording software as a low-cost ($300) radio spectrograph that can address more science questions related to heliophysics, planetary and space weather science, and radio wave propagation. Our goals are: (1) Increase participant access and expand an existing radio spectrograph network, (2) Test and develop radio spectrograph hardware and software, (3) Upgrade the science capability of the data archive, and (4) Develop training modules to help a hobbyist become a citizen scientist. We will overview Radio JOVE 2.0 and give a short demonstration of the new radio spectrograph using the SDRplay RSP1A receiver with a dipole antenna and the associated Radio-Sky Spectrograph (RSS) software.

JF - HamSCI Workshop 2022 PB - HamSCI CY - Huntsville, AL ER - TY - Generic T1 - Implementation of a point-to-point ray tracer T2 - HamSCI Workshop 2021 Y1 - 2021 A1 - Scott Driggers A1 - Steven R. Kaeppler AB -

Most ray tracers treat the problem as a Hamiltonian optics problem given an index of refraction, i.e., the ionosphere in this case.  However, Coleman 2011 developed a method for ray tracing that used a direct variation method.  The advantage of this method is that the endpoints of the ray remained fixed, while in more standard ray tracer, rays are launched until a link is made between the transmitter and receiver.  Development of this method may provide a potentially efficient method for determining the link between a transmitter receiver pair, given a model ionosphere.  We present efforts toward implementing the methodology described by Coleman 2011.

JF - HamSCI Workshop 2021 PB - HamSCI CY - Scranton, PA (Virtual) UR - https://hamsci2021-uscranton.ipostersessions.com/?s=3A-71-3B-21-F1-51-7F-5B-44-BE-57-61-1A-79-02-6B ER - TY - Generic T1 - InFlaMo – an European SID Monitoring Network Celebrates its First Solar Cycle T2 - HamSCI Workshop 2021 Y1 - 2021 A1 - Michael Danielides A1 - V. Skripatchev A1 - J. Chum AB -

The influence of solar X-ray radiation on terrestrial radio communication was found in the early 20ies century. But it was not understood immediately. Radio communication was a challenging topic back then, and became quickly a topic taught in science classes at school. Half a century later – with the start of the space age - it became evident, that the study of Earth's upper atmosphere was solving this question. Solar and other cosmic radiation is responsible for the condition of the ionosphere and the cause of black-outs in long range radio communication. Today, most of the ionospheric very long frequency (VLF) radio propagation phenomena are known and presumably almost completely understood, though it stays a challenging topic listening to the ionospheric disturbances caused by our Sun. The recent development of low-cost software defined radio wave receivers (SDRs) are an ongoing process and opens many new opportunities for applications in people's daily lives and in education. Furthermore, monitoring of Earth's lower ionosphere by utilizing VLF monitors, which are based on SDR technology, it offers new indirect insights into what happens on the Sun. Therefore, one aim of this presentation is to reach out to an educator community as well as citizen scientists to make the InFlaMo (Indirect solar Flare Monitoring) project (http://www.inflamo.org) better known. For almost the entire solar cycle 24 VLF data (20 to 30 kHz) was collected and preprocessed. The scientific analysis of the VLF data is an ongoing activity. For scientific and educational use InFlaMo project data is shared with researchers, educators and citizen scientists. The other aim is to enlarge the network of ground based multichannel SDR-receivers from Europe to overseas. The European network stations have been or are presently in Germany, Finland, Russian Federation and Czech Republic. With this rather inexpensive method monitoring the state of the ionosphere and recording the appearance of solar X-ray flares can be made available for class-room usage.

JF - HamSCI Workshop 2021 PB - HamSCI CY - Scranton, PA (Virtual) UR - https://hamsci2021-uscranton.ipostersessions.com/?s=B3-60-56-B3-59-06-92-97-C6-9C-F3-8A-9B-41-D1-59 ER - TY - CONF T1 - INVITED AMATEUR RADIO TUTORIAL: Amateur Radio Observations and The Science of Midlatitude Sporadic E T2 - HamSCI Workshop 2021 Y1 - 2021 A1 - Joseph Dzekevich AB -
Abstract: Amateurs may ask, “Why do we see Sporadic E like propagation in November and December, when many of the variables like UV radiation and solar exposure are at a minimum, unlike the very active sporadic-E summer months?” How are sporadic-E transatlantic VHF communications possible between North America and Europe? In his tutorial, Joe K1YOW will explain what Sporadic E is, how amateur operators use Sporadic E to enable long-distance VHF communications, current theories of Sporadic E formation, and how we might be able to better understand Es formation by examining amateur radio propagation logs. Joe’s studies of Sporadic E using amateur radio have been published both in QST (2017) and CQ Magazine (2020).
 
Bio: Joe Dzekevich, K1YOW, was first licensed in 1962 and currently holds an Amateur Extra Class license. He graduated from Northeastern University in 1977 with a B.S. in Industrial Technology and holds a M.B.A. from Clark University (1985). Joe is currently a retired Reliability Engineering Fellow who has worked for Bell Telephone Labs, Digital Equipment Corporation, Chipcom/3Com and Raytheon. Joe is also a senior member of the IEEE Reliability Society, where he held various offices in the local IEEE Boston Reliability Chapter and developed and taught many of the chapter’s courses. He is a member of NVARC (Nashoba Valley Amateur Radio Club), the ARRL, and HamSCI. He has always been interested in radio propagation, starting back in 1965 where he subscribed to the CRPL (Central Radio Prediction Lab) Ionospheric Predictions, where one used monthly CRPL prediction maps to chart predicted E-Layer and F-Layer radio paths.
JF - HamSCI Workshop 2021 PB - HamSCI CY - Scranton, PA (Virtual) ER - TY - Generic T1 - RJOVER: An alternative approach using SDR technology to reduce costs for the NASA Radio JOVE citizen science effort T2 - HamSCI Workshop 2021 Y1 - 2021 A1 - Tyler Kovach A1 - Skylar Dannhoff A1 - Jared May AB -

The NASA-run citizen science project, Radio JOVE, utilizes widespread distribution of single and dual-dipole antenna receiving stations to study the magnetic interactions between Jupiter and its moon, Io. The citizen science effort has been well established and maintained since 1998, and the Radio JOVE project team has streamlined kit distribution and assembly documentation for amateur data collectors and hobbyists. The antennas, receiver, software, and related components are available for purchase in kits that range in price from depending on the level of “pre-assembly”. For instance, we estimate that the prices of un-assembled and fully assembled kit receivers are approximately $95 and $225, respectively. Establishing a Radio JOVE receiving station is no small task, and these prices are reasonable and appropriate. To further data collection accessibility and broaden the participating audience, however, we seek to further reduce these costs-- specifically that of the receiver. Our primary goal is to code, integrate, and test a software-defined radio (SDR) receiver for Radio JOVE data collection to verify whether the technology could be a less expensive alternative to the original distributed kit receiver. By coordinating with the Case Western Reserve University (CWRU) Research Farm, as well as with guidance from faculty in the CWRU Electrical, Computer, and Science Engineering (ECSE) department and the Radio JOVE Project Team, we hope to establish a Radio JOVE receiving station at CWRU whereupon we can test our alternative SDR receiver for Jovian signal collection. If our alternative receiver works on a level comparable to the existing kit receiver, we can offer a cheaper, more modern and digital age approach that could appeal to a wider audience including those working with a tighter budget and those who are interested in software-defined radio, all of whom simply want to help the scientific effort. 

JF - HamSCI Workshop 2021 PB - HamSCI CY - Scranton, PA (Virtual) UR - https://hamsci2021-uscranton.ipostersessions.com/?s=8D-A5-71-AF-BD-32-32-6C-C3-71-E2-59-AB-87-B0-0D ER - TY - Generic T1 - Simulation and Comparison of Weak-Signal VHF Propagation T2 - HamSCI Workshop 2021 Y1 - 2021 A1 - Nolan Pearce A1 - Kate Duncan AB -

Space weather's intense variance has a seemingly random effect on radio propagation in the Very High Frequency (VHF) range. Key models are built to analyze and estimate performance of wireless systems in these weak-signal propagation mediums. Chiefly, meteor burst communication, auroral propagation, and earth-moon-earth communication models are built and simulated on MATLAB. The results are confirmed through experimental testing and data comparison. Overall, modeling of these space weather events proves immense usefulness in predicting effectiveness of radio equipment through these weak-signal modes.

JF - HamSCI Workshop 2021 PB - HamSCI CY - Scranton, PA (Virtual) UR - https://hamsci2021-uscranton.ipostersessions.com/?s=0B-3C-92-BC-7A-A2-35-0C-0B-52-1C-29-5A-03-4F-46 ER - TY - Generic T1 - "Sprinkles" or "Mirrors"? Exploring the true nature of VHF propagation via sporadic-E T2 - HamSCI Workshop 2021 Y1 - 2021 A1 - Chris Deacon A1 - Ben Witvliet A1 - Cathryn Mitchell A1 - Simon Steendam AB -

Mid-latitude sporadic-E clouds (commonly abbreviated as ‘Es’) are a transient feature consisting of thin layers of dense, but patchy, ionization which occur in the E region of the ionosphere. The process of formation is different from that of the rest of the ionosphere and it can produce much higher electron densities, sometimes permitting oblique reflection of radio waves up to 150 MHz.
The mechanism for the oblique reflection of VHF waves from Es layers has not been well described, with candidates including specular reflection, scattering, and magneto-ionic double refraction. The polarization and fading characteristics of waves reflected from Es layers are proposed as a marker for the presence or absence of magneto-ionic effects. 
An experimental system has been developed for rapid and accurate polarization and fading measurements at 50 MHz. The overall sensitivity of the system has been optimized by reducing environmental electromagnetic noise, giving the ability to observe weak, short-lived Es propagation events. The effect of the ground reflection on observed polarization has been analyzed and the induced amplitude and phase biases compensated for.
A measurement campaign in the summer of 2018 gathered a large quantity of data, using amateur 50 MHz beacons, at distances between 1,000 km and 1,650 km, as signal sources. The results provide compelling evidence that Es-layer propagation at 50 MHz exhibits the characteristics of magneto-ionic double refraction, but the thin, intense and variable nature of the reflecting region means that the reflected signals can have quite extreme characteristics. Some of the results are surprising, and are yet to be explained convincingly.
In this presentation, an overview of the experimental technique will be given, and the results described. Some of this information has already been published, but much of it is new.

JF - HamSCI Workshop 2021 PB - HamSCI CY - Scranton, PA (Virtual) ER - TY - Generic T1 - Toward interpretation of HF propagation data obtained by the HamSCI Community - Ray Tracers and Ionospheric Models T2 - HamSCI Workshop 2021 Y1 - 2021 A1 - Stephen R. Kaeppler A1 - Scott Driggers A1 - Andrew Wetzel A1 - Alexander Murtha A1 - Tedi Godfrey AB -

Perhaps one of the most pressing questions the Ham Sci community needs to address is how data obtained by the tangerineSDR or other platforms will be interpreted to obtain scientifically useful information.  One approach is to produce an appropriate forward model describing the ionosphere and use ray tracers to convert that model into observables that are measured using SDRs.  The purpose of this talk is to discuss these issues in general terms, but also to discuss simulation strategies that could be useful for the data collected by a network of radio amateurs.  I will also present on the development of an open source python-based 3-D Jones Stephenson Ray tracer and other developments out of my laboratory that are relevant to ray tracing, including implementation using cuda and the development of point-to-point ray tracing.

JF - HamSCI Workshop 2021 PB - HamSCI CY - Scranton, PA (Virtual) ER - TY - CONF T1 - Let’s Push the Exploration of the Ionosphere to The Next Level (Invited) T2 - HamSCI Workshop 2020 Y1 - 2020 A1 - T. Duffy JF - HamSCI Workshop 2020 PB - HamSCI CY - Scranton, PA ER - TY - CONF T1 - Observations and Modeling Studies of the Effects of the 2017 Solar Eclipse on SuperDARN HF Propagation T2 - HamSCI Workshop 2020 Y1 - 2020 A1 - M. Moses A1 - L. Kordella A1 - G. D. Earle A1 - D. Drob A1 - J. Huba A1 - J. M. Ruohoniemi AB -

The total solar eclipses offer a unique opportunity to study the dependence of the ionospheric density and morphology on incident solar radiation. Unique responses may be witnessed during eclipses, including changes in radio frequency (RF) propagation at high frequency (HF). Such changes in RF propagation were observed by the Super Dual Auroral Radar Network (SuperDARN) radars in Christmas Valley, Oregon and in Fort Hayes, Kansas during the 2017 solar eclipse. At each site, the westward looking radar observed an increase in slant range of the backscattered signal during the eclipse onset followed by a decrease after totality. In order to investigate the underlying processes governing the ionospheric response to the eclipse, we employed the HF propagation toolbox (PHaRLAP), created by Dr. Manuel Cervera, to simulate SuperDARN data for different models of the eclipsed ionosphere. By invoking different hypotheses and comparing simulated results to SuperDARN measurements we could study the underlying processes governing the ionosphere and improve our model of the F‐Region responses to an eclipse. This method was used in three studies to: identify the cause of the increase in the distance radio waves traveled during the eclipse; evaluate different models of change in eclipse magnitude over time; and investigate the effect of the neutral wind velocity on the simulated eclipse data. This presentation will discuss observations made by SuperDARN during the 2017 eclipse, major results from our raytrace studies, and unanswered questions that may be useful to consider when planning HamSCI’s campaign and/or similar ionospheric studies for the next eclipse over the United States in 2024.

JF - HamSCI Workshop 2020 PB - HamSCI CY - Scranton, PA ER - TY - CONF T1 - Propagation Teepee: A High Frequency (HF) Radio Spectral Feature Identified by Citizen Scientists T2 - HamSCI Workshop Y1 - 2020 A1 - S. F. Fung A1 - D. Typinski A1 - R. F. Flagg A1 - T. Ashcraft A1 - W. Greenman A1 - C. Higgins A1 - J. Brown A1 - L. Dodd A1 - A. S. Mount A1 - F. J. Reyes A1 - J. Sky A1 - J. Thieman A1 - L. N. Garcia AB -

We report on the observations of a high frequency (HF) spectral feature that appears often in ground‐based spectral data at 15‐30 MHz.The feature, likely of terrestrial origin, is often recorded by a group of amateur radio astronomers, the Spectrograph User Group (SUG), whose main interest is in observing radio emissions from Jupiter. The feature appears as spectral enhancements with the frequency of enhancement first increasing and then decreasing with time, resulting in a “triangular spectral feature.” Its shape is reminiscent of teepee tents (or TPs for short), the moveable dwellings of some groups of native‐Americans. TPs usually have sharp or well‐defined upper frequency limits for both the leading and trailing edges. While some TPs are observed in isolation, they are often seen in groups, distributed either in time or in frequency as a nested group at a particular time. Most TPs appear to be diffuse even at high time resolution, but a few TPs seen at high time resolution reveal that those TPs consist actually of discrete bursts, strongly suggestive that the band noise produced from lightning as possible radiation sources of the TPs. In this paper, we investigate the possible generation of TPs as a result of ionospheric reflection of band noise produced by remote lightning storms.

JF - HamSCI Workshop PB - HamSCI CY - Scranton, PA ER - TY - JOUR T1 - Rapid and Accurate Measurement of Polarization and Fading of Weak VHF Signals Obliquely Reflected from Sporadic-E Layers JF - IEEE Transactions on Antennas and Propagation Y1 - 2020 A1 - Chris Deacon A1 - Witvliet, Ben A. A1 - Cathryn Mitchell A1 - Simon Steendam KW - Brewster angle KW - ionosphere KW - radio noise KW - Radio wave propagation KW - VHF AB -

In the E-region of the ionosphere, at heights between 90 and 130 km, thin patches of enhanced ionization occur intermittently. The electron density in these sporadic-E (Es) clouds can sometimes be so high that radio waves with frequencies up to 150 MHz are obliquely reflected. While this phenomenon is well known, the reflection mechanism itself is not well understood. To investigate this question, an experimental system has been developed for accurate polarimetric and fading measurements of 50 MHz radio waves obliquely reflected by mid-latitude Es layers. The overall sensitivity of the system is optimized by reducing environmental electromagnetic noise, giving the ability to observe weak, short-lived 50 MHz Es propagation events. The effect of the ground reflection on observed polarization is analyzed and the induced amplitude and phase biases are compensated for. It is found that accurate measurements are only possible below the pseudo-Brewster angle. To demonstrate the effectiveness of the system, initial empirical results are presented which provide clear evidence of magneto-ionic double refraction.

UR - https://researchportal.bath.ac.uk/en/publications/rapid-and-accurate-measurement-of-polarization-and-fading-of-weak ER - TY - RPRT T1 - The Rebirth of HF Y1 - 2020 A1 - Paul Denisowski AB -

HF stands for ‘high frequency’ and is usually used to refer to signals with frequencies in the range of 3 MHz to 30 MHz, although in many cases the practical definition of HF has be extended down to frequencies as low as 1.5 MHz. HF is also sometimes referred to, somewhat loosely, as ‘shortwave,’ especially in the context of broadcasting. These HF frequencies correspond to wavelengths in the range of approximately 10 to 100 meters. Given that modern homes contain Wi-Fi access points operating in the gigahertz range and that some 5G deployments are taking place in so-called millimeter-wave bands, the names “high” frequency and "shortwave" may seem a bit misplaced, but it is worth nothing that the first experiments in long-distance radio communication by Marconi around the year 1900 used even lower frequency signals.

One of the best-known applications of HF is worldwide or global communications. Both government and commercial broadcasters can reach listeners worldwide using HF frequencies. This global reach is also extremely useful in many government and military applications, and HF is used extensively by amateur radio operators around the world. This paper will begin with an exploration of the unique properties of HF that enable global communications.

PB - Rohde and Schwarz CY - Munich, Germany ER - TY - MGZN T1 - Winter Sporadic-E-Like Propagation on 6 Meters Y1 - 2020 A1 - Joseph A. Dzekevich AB -

The question was asked: why do we see sporadic-E like propagation in November and December, when many of the variables like UV radiation and solar exposure are at a minimum, unlike the very active sporadic-E summer months?  Much like it was shown that North Atlantic transatlantic 6m propagation during the summer was made more possible by strategically placed weather storm systems, it looks like a similar effect with very strong jet stream boundaries also affect sporadic-E like communications during the winter months.  This citizen science study is another example how amateur radio can contribute to science, and illustrates the great potentials for studies using ham radio data.  We have many amateur radio stations on the air, using modes like FT8 which make contacts on propagation paths that we thought were previously impossible. 

JF - CQ Amateur Radio VL - 76 UR - https://www.cq-amateur-radio.com/ IS - 11 ER - TY - CONF T1 - IonTV: Using WWV Timing Reference Signals to Observe Ionospheric Variation T2 - HamSCI Workshop 2019 Y1 - 2019 A1 - Philip J. Erickson A1 - William Liles A1 - J. Dusenbury A1 - K.C. Kerby-Patel A1 - Ethan Miller A1 - Gary Bust A1 - Cathryn Mitchell AB -

For decades, an AM modulated time signal has been broadcast at multiple HF frequencies by the National Institute of Standards and Technology (NIST).  Shortwave radio stations WWV in Colorado and WWVH in Hawaii use these frequencies for the broad dissemination of accurate coordinated universal time information.  As the HF signal traverses the ionosphere, propagation effects ensue, and the high temporal precision of the original transmitted signal provides an attractive potential for wide-sense monitoring of ionospheric variations.  We present the results of an ongoing set of data collections and statistical analysis of the received variation in WWV timing signals aimed at extracting ionospheric propagation effects.  The work includes design of a software defined receiver (SDR) for processing the amplitude modulated dual sideband (AM-DSB) timing signal. By observing the time shift between consecutive seconds of the 10MHz WWV timing signal, reflected from the ionosphere, the change in the effective height of the ionosphere can be estimated.  Simultaneous measurements taken from different observation angles allow a more accurate sensing of ionospheric electron density variability as projected into refractive effects.  The project also has a goal of creating a straightforward and reliable way for hobbyists and citizen scientists to demodulate and process their own NIST timing data. We describe a sample analysis of several blocks of WWV received data, both on remote paths and locally through groundwave propagation near the Colorado transmit array, including simultaneous collects. To process the timing data, several approaches will be described, including a heterodyne SDR with a digital phase-locked-loop (PLL).  Carrier offset tracking using PLL techniques produce Doppler shifts that are associated with traveling ionospheric disturbances and inherent electron density variability.  Demodulation and amplitude/phase analysis of the 100 Hz subcarrier of WWV can also provide precise delta-time information on ionospheric propagation through examination of variability in arrival of the leading edge of 1 pulse-per-second ticks.  Results to date suggest that variation between consecutive second markers is a uniformly distributed Gaussian random variable with at least some of this variation due to ionospheric factors, although systematics must be addressed.

JF - HamSCI Workshop 2019 PB - HamSCI CY - Cleveland, OH ER - TY - CONF T1 - IonTV: Using WWV Timing Reference Signals to Observe Ionospheric Variation T2 - Hamvention HamSCI Forum Y1 - 2019 A1 - Philip J. Erickson A1 - William Liles A1 - J. Dusenbury A1 - K.C. Kerby-Patel A1 - Ethan Miller A1 - Gary Bust A1 - Cathryn Mitchell AB -

For decades, an AM modulated time signal has been broadcast at multiple HF frequencies by the National Institute of Standards and Technology (NIST).  Shortwave radio stations WWV in Colorado and WWVH in Hawaii use these frequencies for the broad dissemination of accurate coordinated universal time information.  As the HF signal traverses the ionosphere, propagation effects ensue, and the high temporal precision of the original transmitted signal provides an attractive potential for wide-sense monitoring of ionospheric variations.  We present the results of an ongoing set of data collections and statistical analysis of the received variation in WWV timing signals aimed at extracting ionospheric propagation effects.  The work includes design of a software defined receiver (SDR) for processing the amplitude modulated dual sideband (AM-DSB) timing signal. By observing the time shift between consecutive seconds of the 10MHz WWV timing signal, reflected from the ionosphere, the change in the effective height of the ionosphere can be estimated.  Simultaneous measurements taken from different observation angles allow a more accurate sensing of ionospheric electron density variability as projected into refractive effects.  The project also has a goal of creating a straightforward and reliable way for hobbyists and citizen scientists to demodulate and process their own NIST timing data. We describe a sample analysis of several blocks of WWV received data, both on remote paths and locally through groundwave propagation near the Colorado transmit array, including simultaneous collects. To process the timing data, several approaches will be described, including a heterodyne SDR with a digital phase-locked-loop (PLL).  Carrier offset tracking using PLL techniques produce Doppler shifts that are associated with traveling ionospheric disturbances and inherent electron density variability.  Demodulation and amplitude/phase analysis of the 100 Hz subcarrier of WWV can also provide precise delta-time information on ionospheric propagation through examination of variability in arrival of the leading edge of 1 pulse-per-second ticks.  Results to date suggest that variation between consecutive second markers is a uniformly distributed Gaussian random variable with at least some of this variation due to ionospheric factors, although systematics must be addressed.

JF - Hamvention HamSCI Forum PB - Dayton Amateur Radio Association CY - Xenia, OH ER - TY - CONF T1 - A Low-Cost Citizen Science HF Doppler Receiver for Measuring Ionospheric Variability T2 - American Geophysical Union Fall Meeting Y1 - 2019 A1 - Kristina Collins A1 - David Kazdan A1 - John Gibbons A1 - Aidan Montare A1 - Skylar Dannhoff A1 - Philip J. Erickson A1 - Nathaniel A. Frissell AB -

Advancement in understanding short term and small spatial scale ionospheric variability requires global high time and spatial resolution measurements. Professional ionospheric sounding networks are extensive and capable, yet more measurements are still needed due to the strongly magnetized nature and large extent of the ionosphere. High Frequency (HF, 3-30 MHz) radio signals are refracted by the ionosphere, and therefore are modulated by processes such as traveling ionospheric disturbances (TIDs) and geomagnetic storms. By measuring the amplitude and Doppler shift of trans-ionospheric HF signals, it is possible to detect signatures of ionospheric absorption and changes in propagation path length. We present a design for a low-cost citizen science HF multi-band receiver that measures the amplitude and Doppler shift of reference signals of opportunity from the US National Institute of Standards and Technology station WWV and the Canadian Institute for National Measurement Standards station CHU. The receiver will make 1 s cadence measurements on nine HF beacon frequencies and subsequently upload the results to a central server for scientific analysis. The local user will be able to review data daily, both locally and in aggregate on a web server, and participate in discussion of the ionospheric measurements. This receiver forms one component of the low-cost version of the Ham Radio Science Citizen Investigation (HamSCI) Personal Space Weather Station (PSWS), and is designed with the intention of distribution to hundreds to thousands of citizen science observers. Preliminary results from the prototype receiver will be presented.

JF - American Geophysical Union Fall Meeting PB - American Geophysical Union CY - San Francisco, CA UR - https://agu.confex.com/agu/fm19/meetingapp.cgi/Paper/602677 ER - TY - CONF T1 - WWV Doppler Shift Observations T2 - HamSCI Workshop 2019 Y1 - 2019 A1 - David Kazdan A1 - Skylar Dannhoff A1 - Aidan Montare A1 - John Gibbons JF - HamSCI Workshop 2019 PB - HamSCI CY - Cleveland, OH ER - TY - JOUR T1 - Simple and Accurate Variable Frequency RF Signal Generator JF - QEX Y1 - 2018 A1 - Elwood Downey AB -

This generator produces any frequency between 500 kHz and 40 MHz with an accu- racy approaching one part in 109, for example 0.01 Hz at 10 MHz. It uses an Arduino Nano, a GPS receiver with antenna, a digital encoder, a small TFT LCD color display, and the Silicon Labs Si5351A direct digital syn- thesizer (DDS). Together these parts cost me about $150. I will also share some interesting applications for this device.

IS - 310 ER - TY - CONF T1 - Analysis of the August 2017 Eclipse’s Effect on Radio Wave Propagation Employing a Raytrace Algorithm T2 - NSF CEDAR (Coupling, Energetics, and Dynamics of Atmospheric Regions) Y1 - 2017 A1 - M. L. Moses A1 - S. Burujupali A1 - K. Brosie A1 - S. Dixit A1 - G. D. Earle A1 - L. Kordella A1 - N. A. Frissell A1 - C. Chitale AB -

The upcoming total solar eclipse over the continental United States on August 21 offers an unique opportunity to study the dependence of the ionospheric density and morphology on incident solar radiation. There are significant differences between the conditions during a solar eclipse and the conditions normally experienced at sunset and sunrise, including the west-to-east motion of the eclipse terminator, the duration of the event, the solar zenith angle, and the continued visibility of the corona. Taken together, these factors imply that unique ionospheric responses may be witnessed during eclipses, as measured by changes in radio frequency (RF) propagation. High Frequency (HF) propagation varies greatly depending on ionospheric conditions. Hence, our analysis will include data collected during the eclipse by several HF systems shown in Figure 1 including SuperDARN, temporary radio transceiver sites, and amateur radio networks such as the Reverse Beacon Network (RBN) and Weak Signal Propagation Reporter Network (WSPRNet). The data analysis will be guided by raytrace models of HF propagation through an eclipsed ionosphere employing the HF propagation toolbox, PHaRLAP (created by Dr. Manuel Cervera).

JF - NSF CEDAR (Coupling, Energetics, and Dynamics of Atmospheric Regions) CY - Keystone, CO ER - TY - CONF T1 - HamSCI: The Ham Radio Science Citizen Investigation (Banquet Presentation) T2 - NSF CEDAR (Coupling, Energetics, and Dynamics of Atmospheric Regions) Y1 - 2017 A1 - N. A. Frissell A1 - J. R. Ackermann A1 - J. Dzekevich A1 - G. D. Earle A1 - P. J. Erickson A1 - A. J. Gerrard A1 - R. B. Gerzoff A1 - S. W. Gunning A1 - M. Hirsch A1 - J. D. Katz A1 - S. R. Kaeppler A1 - R. W. McGwier A1 - E. S. Miller A1 - M. L. Moses A1 - G. Perry A1 - S. E. Reyer A1 - A. Shovkoplyas A1 - H. W. Silver A1 - J. S. Vega A1 - RBN Team JF - NSF CEDAR (Coupling, Energetics, and Dynamics of Atmospheric Regions) CY - Keystone, CO ER - TY - CONF T1 - Ionospheric Impacts of the 2017 Total Solar Eclipse T2 - Dayton Hamvention Y1 - 2017 A1 - Magalina Moses A1 - Gregory Earle A1 - Sushma Burujupalli A1 - Nathaniel A. Frissell A1 - Lee Kordella A1 - Snehal Dixit A1 - Charudatta Chitale A1 - Xiayou Han JF - Dayton Hamvention CY - Xenia, OH ER - TY - CONF T1 - Practical investigation of the polarisation of 50MHz signals T2 - HamSCI-UK Y1 - 2017 A1 - C. Deacon JF - HamSCI-UK PB - HamSCI-UK CY - Milton Keynes, UK ER - TY - CONF T1 - Upper Level Lows and Six Meter 50 Mhz Sporadic E T2 - Dayton Hamvention Y1 - 2017 A1 - Joseph A. Dzekevich A1 - Philip J. Erickson AB -

Amateur radio is used to explore possible correlations between weather storm systems and sporadic E clouds to see if they are collocated. While some of the main causes of sporadic E propagation are wind shear, meteor strikes and upper atmospheric tides (ultimately coming from solar EUV energy inputs), radio operators have noticed that sporadic E propagation is also changed significantly by hurricanes and storms.  Specific cases where K1YOW used amateur radio to investigate the effects of low pressure weather storms on the formation and/or enhancement of 6 meter sporadic E clouds are presented. DX Maps and earth wide weather model charts combined with operations on 6 meters are used to examine possible correlations between the location of the sporadic E clouds and the low pressure weather storm systems.  Initial findings show a high degree of correlation when magnetic field strength is taken into consideration.

JF - Dayton Hamvention CY - Xenia, OH ER - TY - MGZN T1 - Upper-Level Lows and 6-Meter Sporadic E Y1 - 2017 A1 - J. Dzekevich AB -

Amateur radio is used to explore possible correlations between weather storm systems and sporadic E clouds to see if they are collocated. While some of the main causes of sporadic E propagation are wind shear, meteor strikes and upper atmospheric tides (ultimately coming from solar EUV energy inputs), radio operators have noticed that sporadic E propagation is also changed significantly by hurricanes and storms.  Specific cases where K1YOW used amateur radio to investigate the effects of low pressure weather storms on the formation and/or enhancement of 6 meter sporadic E clouds are presented. DX Maps and earth wide weather model charts combined with operations on 6 meters are used to examine possible correlations between the location of the sporadic E clouds and the low pressure weather storm systems.  Initial findings show a high degree of correlation when magnetic field strength is taken into consideration.  

JF - QST VL - 101 IS - 12 ER - TY - CONF T1 - Characterizing the Ionosphere Using a Commercial Off the Shelf Software Defined Radio System T2 - Fall 2016 American Geophysical Union Y1 - 2016 A1 - Magdalina L. Moses A1 - S. Dixit A1 - Gregory D. Earle A1 - Nathaniel A. Frissell A1 - Lee Kordella A1 - Xiaoyu Han A1 - Charudatta Chitale AB -

On August 21, 2017, there will be a total solar eclipse over the continental United States (US). Solar eclipses offer a way to study the dependence of the ionospheric density and morphology on incident solar radiation. There are significant differences between the conditions during a solar eclipse and the conditions normally experienced at sunset and sunrise, including the east-west motion of the eclipse terminator, the speed of the transition, and the continued visibility of the corona throughout the eclipse interval. Taken together, these factors imply that unique ionospheric responses may be witnessed during eclipses including variations in the density and altitude of the F2 peak. In order to study these changes, we will establish four temporary field stations along the path of totality to track the maximum usable frequency (MUF) across the US over the course of the eclipse. Each field station shall consist of a commercial off the shelf (COTS) software defined radio (SDR) transceiver, a laptop computer running automatic link establishment (ALE) software, a Global Positioning System (GPS) receiver for timing, and a COTS antenna. Custom ALE software will automate the sites’ operation during the experiment to determine the MUF. As a validation test prior to the eclipse, we established three sites along the east coast to confirm that the SDRs are capable of inferring ionospheric conditions. The preliminary results characterize the effects of the sunrise/sunset terminator on our system’s measurements as well as the change in foF2 during different seasons and under different geomagnetic conditions.

JF - Fall 2016 American Geophysical Union PB - American Geophysical Union CY - San Francsico UR - http://hamsci.org/sites/default/files/publications/2016_AGU_Moses.pdf ER - TY - CONF T1 - The Ionosphere's Pocket Litter: Exploiting Crowd-Sourced Observations T2 - Fall AGU - Oral Presentation Y1 - 2015 A1 - Ethan S. Miller A1 - Nathaniel Frissell A1 - Stephen Kaeppler A1 - Robert Demajistre A1 - Andrew Knuth AB -

One of the biggest challenges faced in developing and testing our understanding of the ionosphere is acquiring data that characterizes the latitudinal and longitudinal variability of the ionosphere. While there are extensive networks of ground sites that sample the vertical distribution, we have rather poor coverage over the oceans and in parts of the southern hemisphere. Our ability to validate the ionospheric models is limited by the lack of point measurements and those measurements that essentially constitute characterization of horizontal gradients. In this talk, we discuss and demonstrate the use of various types of crowd-sourced information that enables us to extend our coverage over these regions. We will discuss new sources of these data, concepts for new experiments and the use of these data in assimilative models. We note that there are new, low cost options for obtaining data that broaden the participation beyond the aeronomy/ionospheric community.

JF - Fall AGU - Oral Presentation PB - American Geophysical Union CY - San Francisco, CA ER -