The Walter Bislin model was originally developed in 2017. This is the first working Flat Earth model and Walter's research introduced us to the concept of the personal celestial sphere. We have decided to archive the Walter Bislin model removing unnecessary ads and allowing for a full screen responsive experience This models Flat Earth eclipses, sunsets, sunrises, and allows us to reconcile much phenomenon that would otherwise be misunderstood...
Abstract:This study presents observations of the full moon by 71 participants on June 22, 2024, at 9:00 am UTC 0. Using data from these observations and analysis through the Astronomy Engine, we investigated the visibility of the moon based on geocentric and globe models. Our findings indicate that 10 of the 71 participants should not have been able to see the moon if the Earth were a globe, leading us to conclude that the Earth is not a globe....
In the Journal of Geocentric Cosmology's video, we present a model that explores lunar eclipses on our Flat Earth. According to this model, the Moon is depicted as a transparent body through which the Sun can pass. The video and model demonstrate how during a lunar eclipse, instead of the Earth casting its shadow on the Moon, the Sun intersects directly with a transparent Moon.
Let me elucidate how these images of the sun provide undeniable proof that the sun is not a sphere, but rather a flat disc. This interpretation challenges mainstream scientific understanding, but when we examine the details closely, a new and fascinating picture emerges. Firstly, the images showcase the sun at different times, displaying the rotation of sunspots across its surface. Observers may hastily conclude that this indicates a spherical...
The concept of geocentric parallax, as detailed by A. A. Krishnaswami Aiyangar, offers intriguing insights into the behavior of celestial bodies when observed from different positions on the Earth's surface. This paper provides a method to calculate the parallax in Right Ascension and Declination using spherical trigonometry. However, from a Flat Earth perspective, we can use these findings to support a geocentric, flat model of the Earth. Key...
Abstract This paper explores the integration of Simulation Theory with celestial mechanics to explain the phenomenon where each observer perceives their own unique celestial sphere. We propose that while there is only one physical Sun and Moon, each observer experiences a personalized projection of these celestial bodies, akin to a simulation rendering individual perspectives. This approach offers a novel interpretation of astronomical...
In the study of celestial movements and star patterns, both the spherical and flat Earth models utilize a concept known as the celestial sphere. This imaginary sphere, which encircles the Earth, serves as a canvas where all celestial bodies are projected. The spherical model interprets this sphere as surrounding a globe, while the flat Earth theory proposes a dome-like firmament above a flat plane. This article delves into how the celestial...
Traditional understanding places celestial bodies at immense distances from Earth, necessitating powerful telescopes with extensive focal lengths to observe distant galaxies and stars. However, the stars reside within the range of 2000 km to 6000 km. This proximity challenges the conventional use of astronomical telescopes and opens up an unconventional role for high-zoom cameras like the Nikon P1000. The Shortcomings of Conventional Telescopic...
IntroductionTraditional understanding of gravity is deeply rooted in mass-centric Newtonian physics, where the gravitational force between two masses is proportional to the product of their masses and inversely proportional to the square of the distance between them. This concept inherently ties gravity to mass and the shape of the Earth. However, recent explorations into electrostatic models of gravity present a compelling shift in perspective...