Robert L. FORWARD : Statite Satellite -- Articles &
patents

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**Robert L. FORWARD**  
**Statite Satellite**

  


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[**https://www.youtube.com/watch?v=jxN--4BKH7g**](https://www.youtube.com/watch?v=jxN--4BKH7g)**Statites & Quasites  //  Cool Worlds**We now have around 5000 satellites in orbit of the Earth and
all of them are compelled to follow orbital paths dictated by
Johannes Kepler's Laws of Planetary Motion, first written down
in the early 17th century. Could there be a way to hack the
orbital physics and break away from Kepler's Laws? Today we'll
explore a novel space technology called statites, and a twist on
it we're calling quasites, that could very well do exactly this.  
  


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[**https://arc.aiaa.org/doi/10.2514/3.25487**](https://arc.aiaa.org/doi/10.2514/3.25487)**Solar sail halo orbits. Part I - Heliocentric case.****Colin R. Mclnnes and John F. L. Simmons**  

![](AIAA23.55639.fp.png)

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[**https://arc.aiaa.org/doi/10.2514/3.55639**](https://arc.aiaa.org/doi/10.2514/3.55639)**Solar Sail Halo Orbits Part II - Geocentric Case****Colin R. McInnes and John F. L. Simmons**  

![](AIAASolarSail3.25487.fp.png)

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[**https://strathprints.strath.ac.uk/18865/**](https://strathprints.strath.ac.uk/18865/)**Light levitated geostationary cylindrical orbits are
feasible****Abstract** -- This paper discusses a new family of
non-Keplerian orbits for solar sail spacecraft displaced above
or below the Earth's equatorial plane. The work aims to prove
the assertion in the literature that displaced geostationary
orbits exist, possibly to increase the number of available slots
for geostationary communications satellites. The existence of
displaced non-Keplerian periodic orbits is A-rst shown
analytically by linearization of the solar sail dynamics around
a geostationary point. The full displaced periodic solution of
the non-linear equations of motion is then obtained using a
Hermite-Simpson collocation method with inequality path
constraints. The initial guess to the collocation method is
given by the linearized solution and the inequality path
constraints are enforced as a box around the linearized
solution. The linear and nonlinear displaced periodic orbits are
also obtained for the worst-case Sun-sail orientation at the
solstices. Near-term and high-performance sails can be displaced
between 10 km and 25 km above the Earth's equatorial plane
during the summer solstice, while a perforated sail can be
displaced above the usual station-keeping box (75 AGBP 75 km) of
nominal geostationary satellites. Light-levitated orbit
applications to Space Solar Power are also considered.  
  


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 **<https://www.ijsciences.com/pub/pdf/V72018031562.pdf><https://www.semanticscholar.org/paper/General-relativistic-gravity-machine-utilizing-Musha-J.Pinheiro/b1d74f520f2674460730c3d3b5ad296aff21a3de>General Relativistic Gravity Machine using
Electromagneto-Torsion Field  
Takaaki Musha, Mario J.Pinheiro  
[ [PDF](MushaV72018031562.pdf) ]  
  
Abstract  --** Some field propulsion systems are based
on the solution of General Relativity Theory and are related to
the connection between gravity and electromagnetic field. For
example, Robert Forward proposed a gravity machine working
according to the Einsteinas General Relativity Theory, which
requires ultra dense matter with the density of a dwarf star to
produce useful thrust, but the proposed theoretical scheme
cannot be realized by conventional technologies. The authors
propose several concepts of a gravity machine utilizing an
intense electromagnetic field that produces sufficient thrust to
propel the spaceship, in accordance with Einsteinas General
Relativity Theory.  
  


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**Amer. J. Physics, Vol. 31, No. 3, 166-170, March, 1963****Guidelines to Antigravity****ROBERT L. FORWARD****[ [PDF](GuidelinesAntigravityRobertForward.pdf) ]****Abstract** -- This paper emphasizes certain little
known aspects of Einstein's general theory of relativity.
Although these features are of minor theoretical importance,
their understanding and use can lead to the generation and
control of gravitational forces. Three distinctly different
non-Newtonian gravitational forces are described. The research
areas which might lead to methods for the control of gravitation
are pointed out and guidelines for initial investigation into
these areas are given.  
  


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[**https://gwern.net/doc/technology/1989-forward.pdf**](https://gwern.net/doc/technology/1989-forward.pdf)[**https://arc.aiaa.org/doi/pdf/10.2514/3.26287**](https://arc.aiaa.org/doi/pdf/10.2514/3.26287)**Statite -- A Non-orbiting Spacecraft****Robert L. Forward  //** **Forward Unlimited****[ [PDF](ForwardStatite.pdf) ]**  
  


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**[US5183225](US5183225A.pdf) --
STATITE: SPACECRAFT THAT UTILIZES SIGHT PRESSURE****Abstract** -- An artificial space object capable of
operating usefully adjacent to, but not in orbit about, a
celestial body such as the Earth, comprising: payload means for
providing useful services from a position in space adjacent to
the Earth, light pressure propulsion means for intercepting
light pressure and directing the resulting force to oppose the
gravitational force between the Earth and the space object; and
attachment means for attaching the propulsion system to the
payload, whereby the force generated by the propulsion system
may be transmitted to payload. The invention is designated a
"Statite", i.e. a useful space payload maintained by light
pressure in a position adjacent to the surface of a celestial
body, but not in orbit around it...  
  


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**Electrodynamic tether and method of use  -- US6116544** **Measurement of static force field gradients --
US3273397** **PASSIVE BEAM-DEFLECTING APPARATUS -- US3612659****High power pulse time modulation communication system
with explosive power amplification means -- US3390334**   
  


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[**https://en.wikipedia.org/wiki/Statite**](https://en.wikipedia.org/wiki/Statite)**Statite**A statite (a portmanteau of the words static and satellite)
is a hypothetical type of artificial satellite that employs a
solar sail to continuously modify its orbit in ways that gravity
alone would not allow. Typically, a statite would use the solar
sail to "hover" in a location that would not otherwise be
available as a stable geosynchronous orbit. Statites have been
proposed that would remain in fixed locations high over Earth's
poles, using reflected sunlight to counteract the gravity
pulling them down. Statites might also employ their sails to
change the shape or velocity of more conventional orbits,
depending upon the purpose of the particular statite.  
  
The concept of the statite was invented independently and at
about the same time by Robert L. Forward[1] (who coined the term
"statite") and Colin McInnes, who used the term "halo orbit"[2]
(not to be confused with the type of halo orbit discovered by
Robert Farquhar). Subsequently, the terms "non-Keplerian orbit"
and "artificial Lagrange point" have been used as a
generalization of the above terms.  
  
No statites have been deployed to date, as solar sail technology
remains in its infancy. NASA's cancelled Sunjammer solar sail
mission had the stated objective of flying to an artificial
Lagrange point near the Earth/Sun L1 point, to demonstrate the
feasibility of the Geostorm[3] geomagnetic storm warning mission
concept proposed by NOAA's Patricia Mulligan.[4] A constellation
of statites have been proposed for performing a rendezvous with
an interstellar object.[5]  
  
A so-called quasite is a variation of a statite, being slightly
unbalanced to allow other forces to balance its position, though
having a slow orbit. This is employed in the proposal by David
Kipping for a so-called Torqued Accelerator using Radiation from
the Sun (TARS) slingshot accelerator,[6] essentially being a
light mill in space.[7]  
  


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[**https://ntrs.nasa.gov/api/citations/19910012827/downloads/19910012827.pdf**](https://ntrs.nasa.gov/api/citations/19910012827/downloads/19910012827.pdf)**Exotic Power and Propulsion Concepts****Robert Forward****[ [PDF](ForwardExoticPower19910012827.pdf) ]**


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 **<https://oac.cdlib.org/findaid/ark:/13030/c8f76bh3/>Robert Forward Collected Papers**


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[**https://www.newscientist.com/article/mg12917594-000-science-polar-satellite-could-revolutionisecommunications/**](https://www.newscientist.com/article/mg12917594-000-science-polar-satellite-could-revolutionisecommunications/)**Polar 'satellite' could revolutionise communications**  


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[**https://ui.adsabs.harvard.edu/abs/2025AerSy.tmp...95Q/abstract**](https://ui.adsabs.harvard.edu/abs/2025AerSy.tmp...95Q/abstract)**Continuous high-latitude solar observation using
sailcraft****Quarta, Alessandro A.** **Abstract** -- The peculiar characteristics of a
photonic solar sail-propelled spacecraft (sailcraft) enable the
design of scientific mission scenarios that are difficult to
achieve with conventional propulsion systems, whether chemical
or electric. In this context, a particularly challenging case,
feasible only through the use of a high-performance solar sail,
is the creation and maintenance of an equilibrium point in
heliocentric space. At this point, the sailcraft's velocity is
zero, and the thrust provided by the photonic solar sail
balances the Sun's gravitational attraction. When a sailcraft
reaches such a heliostationary point, thus becoming a statite (a
term coined by Robert Forward), it can maintain this condition
until the sail membrane degrades. This paper analyzes the
transfer trajectories and mission performance of a sailcraft
targeting a heliostationary point located above the Sun's poles,
at a given distance from the star's center of mass. Such a
statite would enable both continuous observation of the Sun's
poles and high-latitude regions, as well as uninterrupted
communication with ground stations without the risk of radio
occultation by the solar disk. The study considers a
three-dimensional scenario starting from an elliptical parking
orbit and accounts for incomplete reflections of the sail's thin
membrane in modeling the thrust vector. In particular, a new
mission strategy is proposed in which the sailcraft's
heliocentric trajectory to the target heliostationary point is
divided into two optimized phases.   
  


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