Applied Physics Research Canada, Published a paper on ....Dynamic Universe Model Predicts the Live Trajectory of New Horizons Satellite Going To Pluto...

Applied Physics Research; Vol. 7, No. 4; 2015
ISSN 1916-9639 E-ISSN 1916-9647
Published by Canadian Center of Science and Education 63
Dynamic Universe Model Predicts the Live Trajectory of New Horizons Satellite Going To Pluto
S. N. P. Gupta1
1 Retd AGM ( C&IT) Bhilai steel Plant, Bhilai, 490001, CG, India
Correspondence: S. N. P. Gupta, Retd AGM (C&IT) Bhilai steel Plant, Retd AGM (C&IT) Bhilai steel Plant,
Bhilai, 490001, CG, India. Tel: 91-964-409-6888 / 788-222-4670. E-mail: snp.gupta@gmail.com
Received: March 16, 2014 Accepted: May 27, 2015 Online Published: July 31, 2015
doi:10.5539/apr.v7n4p63 URL: http://dx.doi.org/10.5539/apr.v7n4p63

Abstract
In this paper, Dynamic Universe Model is used for prediction of trajectory of New Horizons (NH) satellite from 3rd Jan 2009 to 1st Jan 2017, taking trajectory ephemerides data of Jan 1&2, 2009 from NASA’s official web of NH, as basis. The NH web gives data up to 1st Sept 2015 as on 20 Jul 2014. The present calculated data from Dynamic Universe Model is given up to 1st Jan 2017, which is 16 months more than the available data. And further trajectory data also can be calculated. It may please be noted the error percentage in predictions went to a maximum in error percentages (0.24 %, -0.0009 %, -0.05 %) compared with NH web for the same date in XYZ coordinates, where as error percentages started from -0.002%, 0.00016 %, -0.0003 % for XYZ coordinates respectively.

Keywords: dynamic universe model, New Horizons (NH) satellite, Pluto Mission, Satellite Trajectory calculations, Pioneer Anomaly
1. Introduction
1.1 Using Dynamic Universe Model for New Horizons Trajectory:
Dynamic universe model can explain Pioneer anomaly, i.e., the higher gravitational attraction forces experienced towards SUN after Jupiter, in a similar way it can also explain NH trajectory anomalies and predict for few more years than the present predictions. New Horizons (NH) is NASA’s artificial satellite now going towards to the dwarf planet Pluto. It is the first spacecraft to go near and study Pluto and its moons, Charon, Nix, and Hydra. NH is expected to go near to Pluto in 2015. Later NH will be used for studying Kuiper Belt. The behavior of NH is similar to Pioneer Space craft as
NH traveling in a similar manner.

Journal of Astrophysics & Aerospace Technology USA accepted a paper .... Explaining formation of Astronomical Jets using Dynamic Universe Model....on Aug 06,

Journal of Astrophysics & Aerospace Technology published a paper....'.Explaining formation of Astronomical Jets using Dynamic Universe Model, 2015  Aug 06...

Explaining formation of Astronomical Jets using Dynamic Universe Model
Satyavarapu Naga Parameswara Gupta* 

Accepted on Aug 06, 2015

Astrophysics & Aerospace Technology ISSN: 2329-6542
Gupta, J Astrophys Aerospace Technol 2015, 3:1

Abstract 

Astronomical jets are observed from the centres of many Galaxies including our own Milkyway. The formation of such jet is explained using SITA simulations of Dynamic Universe Model. For this purpose the path traced by a test neutron is calculated and depicted using a set up of one densemass of the mass equivalent to mass of Galaxy center, 90 stars with similar masses of stars near Galaxy center, mass equivalents of 23 Globular Cluster groups, 16 Milkyway parts, Andromeda and Triangulum Galaxies at appropriate distances. Five different kinds of theoretical simulations gave positive results
The path travelled by this test neutron was found to be an astronomical jet emerging from Galaxy center.

Journal of Astrophysics & Aerospace Technology USA published a paper on ....'.No Dark Matter’ Prediction from Dynamic Universe Model Came True!....on July 05, 2015'

No Dark Matter’ Prediction from Dynamic Universe Model Came True!
Satyavarapu Naga Parameswara Gupta*

Published on July 05, 2015
Volume 3 • Issue 1 • 1000117

Astrophysics & Aerospace Technology ISSN: 2329-6542
Gupta, J Astrophys Aerospace Technol 2015, 3:1
http://dx.doi.org/10.4172/2329-6542.1000117


Abstract
This paper discusses about the theoretical “non-requirement” of dark matter, or in other words, there is no missing mass in galaxies. A singularity free and collision free n-body problem solution called dynamic universe model was used to find out the theoretical star circular velocity curves in a galaxy. Here five cases are presented. In the first case a HUGE mass at the center of galaxy, sun like stars and external galaxies are assumed, when plotted, the graph of last iteration shows disk formation and velocities achieved. This circular velocities verses radius graph looks exactly similar to observations by astronomers. In all the other cases, either the central mass is missing or external galaxies are missing or both are missing where resulting graphs look different. It can be inferred that the theoretical requirement of dark matter is calculation error, that no dark matter (missing mass) is required according to dynamic universe model. This prediction was first presented in Tokyo University in 2005. Later the findings from LUX in 2013 the (Large Underground Xenon) experiment confirmed this prediction. This new Tensor math in dynamic universe model was used for solving a large variety of physical problems which are otherwise not possible with present day physics. This method solved many unsolved problems earlier like existence of blue shifted galaxies galaxy disk formations, missing mass in galaxies, pioneer anomaly, non-collapsing large scale mass structures and new horizons trajectory predictions etc.
AMS subject classifications: 70F10 (n-body problems), 70F15 (celestial mechanics), 70E55 (dynamics of multi
body systems) 70-05 (experimental work) 70-08 (computational methods).
Keywords: Dark matter; Tensors; Quasars; stars; Rotation curves;
Missing mass in galaxies; Galaxy structure; Galaxy; Kinematics and
dynamics; Cosmology; Observations
Introduction
Rotation curve of galaxy: Missing mass/dark matter concept
Observationally a galaxy also looks like a star, but on the high
telescope resolution, the constituent stars are visible, the more stars,
therefore the more massive the galaxy. By the early 1960's, there were
indications coming for doubting about the missing mass. The first
indication that there is a significant fraction of missing matter in a
galaxy is from the studies our own milky way. The quantum of mass
inside sun’s orbit around the milky way center is observationally less
than the calculated one. A straight forward rotation curves from the
rotating wheel can be seen in Figure 1, which is true according to
Kepler’s third law also as planet-like or differential rotation. Notice that
the orbital speeds falls off as you go to greater radii within the galaxy.
This is called a Keplerian rotation curve as shown in second part of
Figure 1.

'No Dark Matter' prediction from Dynamic Universe Model came true!....Astrophysics & Aerospace Technology ISSN: 2329-6542 Journal of Astrophysics & Aerospace Technology Gupta, J Astrophys Aerospace Technol 2015, 3:1 http://dx.doi.org/10.4172/2329-6542.1000117 Keywords: Dark matter; Tensors; Quasars; stars; Rotation curves; Missing mass in galaxies; Galaxy structure; Galaxy; Kinematics and dynamics; Cosmology; Observations Introduction Rotation curve of galaxy: Missing mass/dark matter concept Observationally a galaxy also looks like a star, but on the high telescope resolution, the constituent stars are visible, the more stars, therefore the more massive the galaxy. By the early 1960's, there were indications coming for doubting about the missing mass. The first indication that there is a significant fraction of missing matter in a galaxy is from the studies our own milky way. The quantum of mass inside sun’s orbit around the milky way center is observationally less than the calculated one. A straight forward rotation curves from the rotating wheel can be seen in Figure 1, which is true according to Kepler’s third law also as planet-like or differential rotation. Notice that the orbital speeds falls off as you go to greater radii within the galaxy. This is called a Keplerian rotation curve as shown in second part of Figure 1.

Astrophysics & Aerospace
Technology ISSN: 2329-6542
Journal of Astrophysics & Aerospace Technology
Gupta, J Astrophys Aerospace Technol 2015, 3:1
http://dx.doi.org/10.4172/2329-6542.1000117
Keywords: Dark matter; Tensors; Quasars; stars; Rotation curves;
Missing mass in galaxies; Galaxy structure; Galaxy; Kinematics and
dynamics; Cosmology; Observations
Introduction
Rotation curve of galaxy: Missing mass/dark matter concept
Observationally a galaxy also looks like a star, but on the high
telescope resolution, the constituent stars are visible, the more stars,
therefore the more massive the galaxy. By the early 1960's, there were
indications coming for doubting about the missing mass. The first
indication that there is a significant fraction of missing matter in a
galaxy is from the studies our own milky way. The quantum of mass
inside sun’s orbit around the milky way center is observationally less
than the calculated one. A straight forward rotation curves from the
rotating wheel can be seen in Figure 1, which is true according to
Kepler’s third law also as planet-like or differential rotation. Notice that
the orbital speeds falls off as you go to greater radii within the galaxy.
This is called a Keplerian rotation curve as shown in second part of
Figure 1.