Sunday, November 22, 2020

Space1 Cloaking Technology


Optical and Physical Derivation & Invention of Space1 Cloaking Technology for Spacecraft & Starships


Using ideas from Optics, Physics, and Romulan Star Trek scifi technology, Humanoido at SPACE1 has invented the CLASSIFIED cloaking device for starships. The derivation of Snell's Law from optics and physics predicts degrees of invisibility. (see ray tracing figure) Romulans of scifi Star Trek used the above configuration for a cloaking device. However, SPACE1 is adopting optics which itself is transparent.

by Humanoido
The Cloak provides an optical and electromagnetic radiation invisibility shield to spacecraft flown as starships. The shield is physically implemented and the craft maintains a specific calculated orientation to the line of invisibility when the cloak is brought online. The starship hull contains the cloak material from which it's lined. The SPACE1 starship cloak optically refracts light around the starship creating a cloak of invisibility. More testing of the Cloak is needed in hot and cold environments, as the working prototype is operating across room temperature and end to end extremes. 

Formulae derivation is from a Computer Math program I wrote at the University and is based on both the derivation and real time implementation of Snell's Law, with graphical representation, on an IBM mainframe computer. In its simplest form, Snell's law can be derived from Fermat's principle, which states that the light travels the path which takes the least time. By taking the derivative of the optical path length, the stationary point is found giving the path taken by the light.

Deriving a working example of Snell's law for a stealth cloaking device, light from medium 1, point Q, enters medium 2, refraction occurs, and reaches point P finally. Assume the refractive index of medium 1 and medium 2 are {\displaystyle n_{1}}n_{1} and {\displaystyle n_{2}}n_{2} respectively. Light enters medium 2 from medium 1 via point O. {\displaystyle \theta _{1}}\theta _{1} is the angle of incidence, {\displaystyle \theta _{2}}\theta _{2} is the angle of refraction with respect to the normal. The phase velocities of light in medium 1 and medium 2 are v_1=c/n_1 and {\displaystyle v_{2}=c/n_{2}}v_2=c/n_2 respectively.

{\displaystyle c}c is the speed of light in vacuum. Let T be the time required for the light to travel from point Q through point O to point P.
{\displaystyle T={\frac {\sqrt {x^{2}+a^{2}}}{v_{1}}}+{\frac {\sqrt {b^{2}+(l-x)^{2}}}{v_{2}}}={\frac {\sqrt {x^{2}+a^{2}}}{v_{1}}}+{\frac {\sqrt {b^{2}+l^{2}-2lx+x^{2}}}{v_{2}}}}{\displaystyle T={\frac {\sqrt {x^{2}+a^{2}}}{v_{1}}}+{\frac {\sqrt {b^{2}+(l-x)^{2}}}{v_{2}}}={\frac {\sqrt {x^{2}+a^{2}}}{v_{1}}}+{\frac {\sqrt {b^{2}+l^{2}-2lx+x^{2}}}{v_{2}}}} where a, b, l and x are as denoted in the long derivation, x being the varying parameter.

To minimize it, one can differentiate:
\frac{dT}{dx}=\frac{x}{v_1\sqrt{x^2 + a^2}} + \frac{ - (l - x)}{v_2\sqrt{(l-x)^2 + b^2}}=0 (stationary point). Note that {\displaystyle {\frac {x}{\sqrt {x^{2}+a^{2}}}}=\sin \theta _{1}}\frac{x}{\sqrt{x^2 + a^2}} =\sin\theta_1
and {\displaystyle {\frac {l-x}{\sqrt {(l-x)^{2}+b^{2}}}}=\sin \theta _{2}}\frac{  l - x}{\sqrt{(l-x)^2 + b^2}}=\sin\theta_2. Therefore,
{\displaystyle {\frac {dT}{dx}}={\frac {\sin \theta _{1}}{v_{1}}}-{\frac {\sin \theta _{2}}{v_{2}}}=0}\frac{dT}{dx}=\frac{\sin\theta_1}{v_1} - \frac{\sin\theta_2}{v_2}=0
{\displaystyle {\frac {\sin \theta _{1}}{v_{1}}}={\frac {\sin \theta _{2}}{v_{2}}}}{\displaystyle {\frac {\sin \theta _{1}}{v_{1}}}={\frac {\sin \theta _{2}}{v_{2}}}}
{\displaystyle {\frac {n_{1}\sin \theta _{1}}{c}}={\frac {n_{2}\sin \theta _{2}}{c}}}\frac{n_1\sin\theta_1}{c}=\frac{n_2\sin\theta_2}{c}
{\displaystyle n_{1}\sin \theta _{1}=n_{2}\sin \theta _{2}}n_1\sin\theta_1=n_2\sin\theta_2

The Cloak will be installed on the hull of the super spacecraft or super starship version of the Super Rocket. SPACE1 has completed a transporter and is working on shields, phasers, and photon torpedos. The Cloak will allow SPACE1 to work and perform starship experiments in space without drawing significant attention.

Wednesday, November 11, 2020

United Federation of Space

Founding of the United Federation of Space


On Monday, November 9th, 2020, the United Federation of Space was established and founded.

Conducted by Humanoido, the beginnings of the by-laws and charter were established and the first council was formed.  Space Fleet is a division of the United Federation of Space, designed to uphold and conduct the high standards established for cooperation and the exploration and development of space. The United Federation of Space is formed with the backing of SPACE1 Industries and Big Brain Technologies, and is in addition to Space1 United Federation of Spacefaring Species established in January 2019 by Humanoido.

Space1 United Federation of Spacefaring Species


Space Fleet

United Space Technologies

SPACE1 2020

Monday, November 2, 2020

Space1 Space Fleet

The Formation of 
Space Fleet 2021
by SPACE1
Star Trek has Star Fleet, the US military has Space Force, and SPACE1 has formed Space Fleet.

Space Fleet is operated by SPACE1 Industries and Big Brain Technologies, and has a fleet consisting of AI machines, Star Ships that traverse localized space, and Micro Planets for space colonization and becoming a multiplanetary species. Thus far, Space Fleet includes Earthen derived AI machines but intends to extend this on a united effort to all qualifying intelligent life species. There are no weapons at this time, however when the need arises, defensive shields and weapons will be installed on the starships. The space fleet insignia for 2021 illustrates a dragon and three stars for the completed missions of Earth, Moon and Mars. The stars also represent humans, AI life forms, and the pool of other participating life.

Sunday, November 1, 2020

Space1 Space City

NASA/SPACE1
Space1 Space City

After successful development of a series of micro planets, SPACE1 is developing Space City, on a larger scale.

Space City is a vast temp space station, launched into space on board SPACE1's Super Rocket, to serve as a space outpost to conduct space experiments and a space home for members on board the space outpost. Machine derived Space Cadets will serve on the station and their time in service will determine their ranking seniority for the distribution of Space Fleet.

* Temp service
* Fully recyclable
* Operated by fuel cell technology
* Stationed by AI machines
* Launch into service by SPACE1 Super Rocket
* Upward scalable from Micron Planets
* No space debris
* SPACE1 Original
* Space Fleet Certified

Monday, October 26, 2020

Heavy Mass Catipulsation Rocket


Heavy Mass Catipulsation Rocket

Humanoido of SPACE1 has invented a Heavy Mass Catipulsation Rocket for launching Micron Planets into the evolutionary void. The rocket uses recycling mechanics and Newton's Laws of Motion to propel cargo into the void of space, primarily to launch temp evolved Micron Planets in numbers and rapid succession.

Sunday, September 20, 2020

Rocket Parts & Reliability




Rocket Parts & Reliability
Putting 2 1/2 million parts on a space vehicle rocket system, where any part at any time can fail, is a potent recipe for disaster. SPACE1 has taken the approach that simple is better. When a rocket or space transport system has more and more parts, then more can fail and go wrong during flight.

Murphy's law is always inevitable when you least expect it. Knowing this, Humanoido has directed SPACE1 to construct a rocket with literally no moving parts.

Take for example the record of the NASA Space Shuttle, a retired and non-reliable system with over two and a half million parts. On at least two catastrophic failures, the shuttle exploded and failed, killing fourteen astronauts.

The SPACE1 rockets from the get-go were designed by Humanoido to have no moving parts and this has resulted in the 2014 invention of the Safety Rocket with no failures. Now the impetus is being placed on more safety spacecraft to take us to Mars and back again - a much larger spacecraft.

Enter 2020 - the planet Mars is approaching opposition, two years from the 2018 opposition, exceeding twenty arc seconds and moving in position closest to the Earth. SPACE1 is utilizing a completely new and safety form of space travel to and from the red planet. The new craft has a minimal axis of rotation in free space for space travel orientation and navigation, for ultimate safety and the fastest Solar 
system flight times known to mankind using Humanoido's Parametric Optical Thrust Vectoring Propulsion System - the HPOTVPS.

Stay tuned as we continue to report on this new space technology and provide updates on the journey to Mars.

Sunday, September 13, 2020

Space1 Machine Trip to Mars


Space1
Machine Trip to Mars
SPACE1 Industries is looking at a different and more safe timely way to inhabit and colonize mars

The idea is to use this MARS Machine being developed and tested during the October 2020 Mars Opposition.

The idea is to establish a presence on Mars without using the conventional more dangerous technology (see SpaceX rocket Merlin and Raptor engines). Objectives include a safer path to Mars, faster flights round trip, and the establishment of fast bases for rapid expansion. Complex engines such as the powerful Raptor and Merin are not needed with the Mars Machine, which works on a different principle.


The Mars Machine is a futuristic dimensional technology that interpolates and extrapolates parametric identities to and from the Martian surface. It uses orbital technology for the injection of positional orbits above, below, and around the Martian surface. SPACE1 has spent two years since the Mars 2018 Opposition in developing the technology inclusive of specialized software to drive the system. The Mars Machine is large and heavy and combines dimensional time, potential, and kinetic energy to achieve parametric positioning across Mars. We hope the Mars Machine will be ready in time for the upcoming opposition.







































The technology of a Mars spacesuit is not needed when traveling with the Mars Machine, saving millions of dollars of development cost and time.

Large costly orbital Mars stations and habitats are not needed saving billions of dollars. The Mars Machine is capable of projective dimensional inhabitation modules. Stay tuned as we test this new technology.

Tuesday, August 25, 2020

Space1 New Tracking Center



Xray of the SPACE1 Planetoid
where spacenhabitants populate
the interior walls for extreme high
tech off-world colonization


Deep Space
Tracking Guiding
SPACE1 has artificial planetoids which it creates and launches into space for global planetary development and space time experiments

SPACE1 is developing a new deep space tracking center using optics and some of the world's most powerful telescopes. The goal is to image deep space down to a specific magnitude and track various rockets and space probes or satellites. The new deep space tracking center is founded by investors who want to see the immediate results of ongoing evolution of science and space technology as we are moving out and off the planet as a spacefaring species. Being developed is an array of telescopes that potentially work in unison during space flights and various space studies. The equipment includes global imaging, some of the highest resolution equipment that can image the soil/surface on Ganymede and ice on other Moons, keep tabs of planetary spacecraft and Martian SPC sublimation, and deep space penetration tracking with advanced plate solving, precision GOTO, and coordinate tracking. The net of instruments can also serve to guide and track telemetry of SPACE1 rocket launches and missions.

Saturday, August 1, 2020

Space1 Waiting for Rocket Season

Space1 Waiting for Rocket Season

Space1 is waiting for rocket season with a fleet of Super rockets on standby. Weather is gradually clearing but temperatures are still too hot to conduct safe operations.

Wednesday, July 8, 2020

SPACE1 Mars Support for SpaceX

SPACE1 Mars Support for SpaceX

SPACE1 has continued Mars support for SpaceX landing on Mars. This includes the half century database creation of global Mars Cartography; a mapping, survey and climatology project depicting the global planet Mars from a wide seasonal perspective. This will lead to better understanding of seasonal Martian variations in weather climatology, conducive for missions to Mars and settlements on the red planet.

Wednesday, July 1, 2020

Space Astro Blog

Testing many stacked focal reducers on large SCT telescopes
is one project being addressed at the Astro Blog.
The new
Space Astro Blog is now up and ready!

Space Astro Blog
https://otisastro.blogspot.com/

TAIWAN: Welcome to the intro of my new AstroImaging blogger, designed to cover the wondrous worlds of space, telescopes, equipment, celestial imaging and the techniques needed to coax interesting things from the night sky. The blog site will supplement and contribute to the SPACE1 web presence at https://space1usa.blogspot.com/

Thursday, May 14, 2020

New Astro Blog

Astro Blog will detail the use of these two telescopes, a 9.25" and 14"
EdgeHD from Celestron.
Coming Soon! New Astro Blog

The exciting new future dedicated Astro blog is where you can partake in exciting astro details, projects and experiments!

Astro blog will include new ideas and techniques, observatory and equipment details for astro imaging the Moon, planets and/or deep sky objects. One major focus will include the penetration of clouds, less than ideal seeing conditions, and light pollution,. This includes increasing the quality of results and data obtained through smog, fog, haze, thin clouds, chemical air pollution, and minimizing or eliminating specific lighting such as LED, mercury vapor and sodium. The blog page may also include telescope, accessory and equipment reviews and hidden details revealed on the best astro deals worldwide. Astro blog may show results and details of what can be accomplished in the heart of the inner city when imaging through bright Bortle 9 skies with the highest levels of light pollution. Some interesting questions may include how to pole align when the North is blocked, and how to star calibrate the telescope when no stars are visible.

Saturday, May 2, 2020

Space1 Tent Observatory

The new tent observatory houses telescopes as large as a Celestron C14 Edge HD with a massive
CGX/L mounting and tripod. During days and nights, can be lifted up and off the telescope during
observing or the telescope can aim out the large roll-up zippered door. Photo shows the large size
with a 150 x 150 cm base and rose red color. The author is using the slightly thicker 190T blue
synthetic polyester 120 x 120 cm base which comfortably fits on a tiled floor of a high rise balcony
befit with a balustrade. Tie down straps are routed to the steel balustrade and piping.
Space1 & Singularity Observatory
New Tent Observatory
testing a new portable tent observatory for telescopes

During the heat of the day, the roof opens up
with semi-circular window to release heat. At
night, it helps to reach telescope thermal
equilibrium faster.
by Humanoido

Part of an ongoing expansion to the Singularity Observatory division of SPACE1 is a new tent observatory.

Sold at camping and sporting goods stores, the Singularity Observatory Tent Observatory SOTO is portable, opening up into a full observatory from a simple flexible folding steel pole that folds down after use.
About 5lbs, the portable tent observatory has a
flexible steel rod than folds up into a circle that
may fit under the arm.

Capacity
The tent holds or covers one telescope as measured for a full size Celestron C14-inch Edge HD OTA, which is 31-inches long, with a massive CGX/L equatorial mount and the largest Celestron tripod offered for this OTA. An even better fit is the Celestron 9.25-inch Edge HD with a 22-inch long OTA or other SCT. Remember to measure the mount counterweight when calculating size fit.
Remember to order the tent with the higher door, like the
two shown on the left. This will allow the telescope to
reach higher elevations when observing from inside the
tent.
Specifications
The tent is waterproof and has UV inhibitors for resistance to the sun. The tent is available in two sizes, small 120 x 120 x 190 and large 150 x 150 x 190 cm and is offered with different colors (camouflage, army green, orange, red, rose red, sapphire blue, luxury gold). The interior has a pouch which can be used like a small shelf for small lightweight telescope accessories. A strap near the top is ideal for hanging items, in particular a long flat lightweight poly pockets unit could be purchased extra and hold astro accessories.

Ordering
Originating from a camping sports company in Shanghai, China, the best part is the price - available for as low as US $16 online from AliExpress in China (before shipping). I had mine net ordered and couriered to a location in Shanghai, then hand delivered to me. Shipments to the USA could incur freight charges as high as $150 so shop around for a good carrier.

Construction
Made of 190T synthetic polyester, the weight is only 2.1 to 2.5 kgs (4.6 to 5.5 lbs) and one hand can move and position it. It has sewn in loops for attaching clips that can lead to tie down ropes, and a zippered door and windows. I prefer to use metal luggage clips for rapidly tying down and releasing the tent. Check with catalog listings as some tent colors are made from thicker weight material, such as blue sapphire. The large door opening can roll up and fasten with straps.

Applications
For use, the entire lightweight tent easily lifts up and off of the telescope as the bottom of the tent is open. After an observing session, just set the tent over the telescope and clip it down. The tent is lightweight and ideal for use on a deck. Depending on weather conditions, keeping it over the telescope is also a solution that could last several months. At the low $16 cost of the tent, it could easily be replaced every season.

Quick Covering
One use is as a telescope covering during a fast rain. Just quickly set the fully set up tent observatory over the telescope for protection.

Maintains Polar Alignment
Another use is to keep the telescope outdoors and covered after its aligned to the pole and star calibrated for precision GOTO.

Remote Imaging
The tent observatory polyester covering is transparent to WiFi signals so its ideal for remote imaging.

Good for Breaks
It also helps when using a telescope setup and you want to take a break at 4 am but don't want the telescope exposed to the weather. The tent is very handy to protect the setup throughout the night, when going inside for a quick nap, pause, cup of coffee, or intermittent breaks from observing.

Ideal for High Rise Balcony
A balcony may have a weight limit, as it hangs over the side of the building. After the weight of the telescope, a very light weight observatory covering is useful and necessary The light weight of only 5 lbs makes it ideal for setup on a highrise balcony and does not add any appreciable weight.

Observing from Inside the Observatory
Of course, if the object observed is visible through the opening, the tent observatory can provide a good sheltered place shielded from lights and wind.

Astro Imaging
It can also offer a suitable solution for astro imaging and remote control. It can make more nights usable for imaging by protecting against a strong breeze.

Daytime Shield
During the day, it will shield the telescope from the hot direct sunlight. The tent observatory will shield against sun, rain, wind, dust, lights and birds.

High Wind 
For those rare high wind events, typhoon or hurricanes, just fold the tent and bring it indoors with the telescope.

Observatory Door
The large zippered front door can be used like the bi-parting shutter doors on an observatory dome. It can partially open by folding over to one side the desired amount - good for stopping a wind or breeze. The door does not reach the zenith overhead, but this is ok on a deck with a partial roof. As the telescope is set closest to the front door, it has the largest viewpoint.

No Construction
No need to build this observatory - it comes ready to pop open instantly and assume its natural form. No tools needed.

Instant Setup & Takedown
No need to thread flexible supports and pipes like other tents. This tent is already constructed with built in flexible supports that "pop open" and just fold it to compress it down into its carry bag.

Portability
The tent observatory is ideal for a portable rig. It weighs almost nothing and sets flat when folded. Just fold up the tent and put it in the car along with the telescope and gear.

Fast Deployment
At the field site, it instantly pops open without any complicated assembly. No need to waste precious imaging time with rotating domes, opening bi-parting shutters, using motor drives or rolling off roofs.

Ventilation
The observatory has good ventilation as it can be regulated with the open bottom (no floor) or the window hatches at the top and side.

Caveat
The tent does not secure items inside from theft so it must be kept in a secured location or have eyes on it at all times. However, this may not be much of a problem for a secured balcony a thousand feet high off the side of a skyscraper. The tent is not permanent and not designed for high wind, but given  proper care it could potentially last years.

Wednesday, April 29, 2020

Singularity Observatory Telescope 3

Singularity Observatory Telescope 3 Now Cancelled
Companies refusing to deliver telescope parts to the Pacific Ocean Volcanic Archipelagos and gradient due to the covid-19 virus pandemic resulted in cancellation of Telescope Number Three

Singularity Observatory will now focus on upgrading the second largest amped telescope in the world. As skies are moving into the exceptionally clear sky time period, all focus is on preparing the telescopes for the season. Telescopes are being equipped with new accessories astronomical study, research, and imaging, for deep sky, planets, moons, asteroids, comets, and other phenomena.

Thursday, April 23, 2020

Roof Top Observatory

Hoisting the dome by crane was a three person operation. One person operated the
construction crane and two helped guide the dome down onto its observatory trucks. The
entire operation went smoothly and the dome mated perfectly with the track. In the final
analysis, the dome was built by the author with a roundness accuracy of +- 1/8th inch to
its three meter diameter.
Roof Top Astronomical Observatory
Spectacular garage-top observatory

Authored by Humanoido

Humanoido worked eighteen years developing, constructing, and perfecting performance of this fantastic award winning, and claimed by many to be far ahead of its time, computerized rooftop observatory

Ahead of its time: the observatory was far ahead of its time in the 1970s with many new inventions not commercially available at that time, such as a microcomputer, computerized mirror grinding machine, video image processor machine, special 40-inch telescope with servo figured primary, talking and listening speech observatory system, optoelectronics interface, OPTICS language, observatory robot droid, Thermodynamic Equalizer, the first GOTO celestial objects system, observatory HVAC, virtual cooling CCD, interlocking dome and track, the first cyber space robotic telescope, large lenseless Schmidt, infinite rate VFO...

Telescopes
(1) 30mm Refractor
(1) 4.25-inch diameter RFT Space Telescope
(1) 4.25-inch f/11 Newtonian Reflector
(1) 8-inch f/2 Lensless Schmidt Camera
(2) 8-inch f/6 Newtonian
(2) 12.5-inch f6.3 Newtonian Reflector
(1) 40-inch Newtonian with plate glass primary
(2) 50-inch Newtonian (aluminized polymer primary)

The biparting shutter doors were opened and four ropes
were attached to wood flanks on the dome's indoor side

partition. This was connected to the crane for lifting and
supported the dome's tonnage with perfect balance.
Largest Telescopes in the World
It was practically effortless to lift the dome up onto the
observatory using this massive crane. The crane operator
said he had lifted some unusual things in his career, like a
horse, but never an observatory dome.
The first telescope systems
design program executed in
BASIC and included many
telescope subroutines, like the

one shown above, that
helped in designing the 40"
diameter reflector telescope.

In the example sub code, a
multiple mirror telescope
MMT was considered.
It took 10 years to build the 40-inch telescope. At the time, the 40-inch telescope was the largest amateur size telescope in the world. The 40-inch was constructed from a large round of fine annealed Belgian plate glass. It was ground and polished on both sides.

The mirror mount was made from plywood with 144 computer controlled servos to figure the telescope objective shape during observing through machine induced flexure.

The mount for the massive telescope was disguised by building it into an outdoor backyard storage shed. The completed 40-inch telescope was valued at 1.2 million dollars.

Telescope Systems Design Program
A computer program was written on the 1802 microcomputer to design the 40-inch reflector telescope and diagonal. The program also determined the height to the ocular and many other parameters. Using the program, it was decided to figure the main objective electronically during observing by the use of homemade servos. Whenever a new computer was added, the program was rewritten and updated to the new language.

The observatory robot droid was
programmed to assist during
telescope operations. It could
speak, understand speech, move
around, detect smoke, and see in
total darkness.
Mirror Grinding Machine
To help grind and polish such large heavy telescope mirrors, a mirror grinding machine was computer designed and built using the 1802 computer. Built from scavenged parts, it included a 6-foot long solid wood house door, a tangent arm from a house beam, belts and pulleys from the surplus center, ball bearings from slingshot steel balls, timing cycles was on the embedded kitchen clock, and the motor from the family washing machine produced the reciprocating power. It could handle small eyepiece lenses on specific spindles or primary mirrors up to 40-inches in diameter at the core platform.

Mirror Grinding Room
For housing the mirror grinding machine in pristine conditions, a special mirror grinding clean room was constructed on the south wing.

Photographic Darkroom
Adjacent was a photographic darkroom for developing film, spectroscopic emulsions, designing developers, and printing images with a photographic enlarger, print paper and mixed chemicals.

Observatory Dome
The author designed and built the telescope dome with trigonometry and calculus. A double size garage was built onto the house as a work room. Construction first proceeded on the dome outside in warm weather, then was moved inside the new garage when weather turned cold and it snowed. A propane heater helped extend the project to 3 months. Humanoido built the two ton 3-meter observatory telescope dome with bi-parting shutter doors using metal garage track wheels, during his lunch breaks and in his spare time after work hours. Upon completion, small diameter long steel rod/pipes were used as rollers to transport the dome out of the garage in preparation of hoisting up onto the roof. The rollers worked so well that the dome started to pick up speed moving down the driveway. Running to the opposite side forced the dome from moving out into the line of street traffic! The dome was valued at $50,000 by astronomical sources.

Dome Drive
A special order expensive industrial AC motor was phase wired and set up with a machined keyed drive wheel in the ratio of 144:1 to move a precision welded circular steel track 360 continuous degrees. A controller was computer designed and built with electronics and high powered electromechanical relays and an HVAC unit for forward and reverse direction ability.

Precision Dome Support
Large custom support trucks were constructed from 1/4-inch welded steel plate with adjustable steel wheels. Four such units were equidistant placed and contained 32,000 pound lockdown chains each.

The Optoelectronic Interface
To send signals across the observatory, Humanoido invented the the world's first astronomical Optoelectronic Interface. Light waves were sent across rooms to communicate with the observatory computer and control the HVAC system.

Optics Language
The author invented a new computer language named OPTICS that could communicate across space and time with invisible optical components at the speed of light. This eliminated the need for bulky wires and cables and prevented any power line fluctuations and HVAC voltage spikes from getting into the system.

Telescope Pier
The massive solid stationary telescope pier began 9-feet underground and extended upwards 22 feet high. With an 8-inch diameter cast pipe in the center, it weighed 28,000 pounds and was constructed from steel, cement, rebar, and wire mesh. With thousands of pounds PSI, it was poured in three massive interlocking sections with thick 3/4" plywood forms reinforced with multiple long threaded rod bolts. Engineers estimated the telescope monolithic pier would survive a nuclear blast.

Computers
As the Observatory evolved, at least five computers were added to the systems. At first, the homebuilt 1802 computer was the mainstay for power programs to design the telescopes and do complex engineering. A Z80 was in charge of mobile robotic control and the Intel PC became part of the telescope sky celestial object positioning system. The 6502 did image and data processing and hosted the VIP Video Image Processor. The model I level II was allocated to the first AI speech recognition, speech synthesis and HVAC (High Voltage AC Controller) optoelectronic interfacing. Additional systems controlled dome rotation, thermal equalization, and a variable frequency oscillator for guiding and tracking stellar objects, plus the telescope was upgraded for computer control and slow motion in both right ascension and declination.

Science Library
The finished observatory included one of the finest scientific and astronomical libraries in the entire state, with rows 40-feet long and thousands of books from floor to ceiling. Many books were procured from a local library that closed. Also many university level books were contributed. Sections were included for astronomy, astrophotography, photography, chemistry, rocketry, space exploration, physics, optics, space time relativity, history, economics, music, robots, electronics, construction, carpentry, electrical wiring, plumbing, aviation, art, design, engineering, crafts & lore, materials, gardening, software, programming, artificial intelligence, SWL, ham radio, thermodynamics, atomic & nuclear, statistics, mathematics up to differential equations, and computers. It also include the first 35 stories written by the author for publication.

Publications
The observatory details, observations,  etc. were written up and published in newspapers, carried nationally by News AP Wirephoto, news journals, books, Observatory Techniques Magazine, Sky & Telescope and other astro publications.

Laboratory
A large laboratory equipment bench had sections for robotics, cybernetics, computers, software programming, optics, droid construction, image processing, and inventions. It had a vast network of storage to hold computer drives and various observatory equipment.

Room Construction
Upgraded microcomputer in the observatory
Everything was deluxe. The extra wide oak colonial post stairway led up to the observatory hallway where picture frames were lined up on the wall, of great scientists and the best photos from the observatory telescopes. On cold days,  heat was from a triple insulated air tight wood stove and electric heat panels. To the side was corded firewood, axe split outside the backyard. In summer an air conditioner cooled the area. Included were a humidifier and dehumidifier. Oakwood-walled rooms were carpeted throughout. A short stairway led to the dome room. R128 and higher insulation was installed and the structural heat and any vibrations were isolated from the telescope for greatest stability. Rooms included the garage, dome room, mirror grinding room and meeting room, photographic darkroom, library, large laboratory (cybernetics, AI, programming, electronics, image processing, computing, inventions), equipment storage room, and the staircase room.

Special Garage
The 2.5X garage was reinforced to support the weight of the entire observatory complex with a custom forged beam of multiple sandwiched massive wood lengths with layered steel plate running the entire length of the garage. It led to two vertical posts sunk into poured concrete footings four feet deep. To provide weather and temperature separation, the garage was fully insulated and sheet-rocked. Built with extra-large service doors, the car was kept outside, and half the garage was used for constructing the large 40-inch telescope. The garage was heated by propane and was instrumental in dome construction during cold winter months.

Observatory with a Voice
The observatory could talk and recognize speech. Experiments were conducted with chips that included VOTRAX, RS, and the SPO256. By giving it commands, the dome could rotate to match observing the stars and celestial objects. There was AI behind the voice, which at times on the main floor would suddenly start talking out loud to itself. One time, it was startling to think a stranger was lurking somewhere upstairs in the observatory, but it was only the AI that auto-reset and  started talking to itself!

Telescope
The telescope was the first high tech GOTO system that could find celestial objects using a telescope axis drive, variable frequency oscillator, encoders, software and a computer. Adjustments were made during astro imaging using both R.A. and Dec. slow motion controls. The system was implemented on planets such as Venus, Mars and Jupiter, and could track the Moon using Lunar rate. For deep sky, sidereal rate was highly accurate. Also implemented was a solar rate and an adjustable rate for comets, satellites and asteroids.

Cameras
A variety of custom astro imaging cameras were used, including CCTV, SLR, super cooled homebuilt dry ice camera, a virtual cooling CCD, and ST-4 Peltier cooled imager and guider.

The 1st Microcomputer
A microcomputer designed and built by the author was used extensively at the observatory. This was created before any microcomputers were on the market. The computer was built around the RCACDP1802MPU chip and was upgraded to run Tom Pittman Tiny BASIC in 4K. To have more power, it was expanded with more memory, an ASCII keyboard, tape recording and loading machine, extended power supply, meter, TV monitor made with a 5" SONY portable TV, and RF Video Modulator. The author lectured at universities regarding the design of his first new microcomputer and was published in several computer magazines.

Cybernetics Lab - Robot Droid - Cyber Space Telescope
Many inventions came from the Observatory Cybernetics Lab. The author built a mobile AI robot droid based on the Z80 chip to assist observatory operations by providing the correct observing oculars, speaking timing routines for astro imaging in total darkness, and keeping track of technical information for observing, dome rotation, and special astro missions. The robot was taken to Albuquerque NM at the World's 1st Personal Robotic Conference (IPRC) where it received the red ribbon. Other inventions included a robotics hand, machine video image processor, AI creations, and robot telescopes. This led to the world's first Cyber Space Robotic Telescope where people from across the world could dial up the telescope by internet and take photos of sky M-objects and selected objects using a choice of CCD cameras. It included star maps and an online data accessible astro computer.

Thermodynamic Equalizer TE
The TE was an electronic machine invented and constructed by the author. Using thermoelectric sensors and comparator circuits, it equalized the temperature of indoors and outdoors to keep the telescope and dome room at thermal equilibrium resulting in the finest performances.

VIP Video Image Processor
A six-foot-long machine was invented that could take negatives and convert to digital images and do computer color image processing. The red machine was built from plywood, an enlarger lens, a homemade servo, screw focus assembly, and a microcomputer with special interface. This machine helped discover radial spokes in the colorful rings around planet Saturn and was one of the first computer image processing systems applied to astronomical imaging.

Guest Visitors
The observatory had many guest visitors. Some were visiting astronomers from across the world, and others were visiting schools. Perhaps the most valued and cherished visit was from the Great Grandmother, who somehow made it up the two flights of steps to see the observatory and telescope in operation. She is quoted as saying, "I have seen the future!"

Discoveries & Inventions
The observatory helped to make thousands of inventions and important discoveries. This is the short list.
* Found new star in M27, helped position the HST Hubble Space Telescope
* New Comet understanding of formation and evolution
* New Cometary graphics
* New astrophotographic techniques
* New maps - discovered and tracked Mars dust storms
* Discovered radial spokes within the rings of Saturn
* Discovered Virtual CCD cooling
* Discovered new imaging techniques
* Discovered new ways to build large telescopes
* New optical experiments
* Invented anti-light device
* Cyber Space Robotic Telescope
* Special "figuring the primary objective during observing" method
* Discovered telescope Amping & implemented their new systems
* Discovered how to reduce EFL by electronic techniques

History, Demise
The observatory was extremely successful and active up until the time someone tore down the observatory and crushed the dome. At the same time, another person took a hammer to the 40-inch telescope glass, thus destroying the 1.2 million dollar telescope. Only the 28,000 pound steel/concrete pier remains to this day, an immovable monument to the observatory history.

Rebirth
Nearly 2 decades transpired. Suddenly the timing was right to "take back the observatory" so to speak. At the Pacific Ocean Volcanic Archipelagos, a replacement futuristic new observatory was born, literally hundreds of thousands of times more powerful than the original, and ultimately equipped with the largest and most powerful amped telescopes in the world.

Wednesday, April 22, 2020

Singularity Observatory Covid-19 Delays

Singularity Observatory Telescope with Covid-19 Delays
The third massive telescope construction project in 2020 is significantly delayed by the Corona-19 Pandemic

Delays for the third telescope include orders that companies refuse to ship, indefinitely. This has delayed the third telescope project significantly, and work is being diverted to telescope number two (the 1,325-inch diameter monster). Many of the design features of the potential third telescope are now being designed into the second telescope. Telescope two has all but one of the accessories needed for full operation using new technology in 2020.

Tuesday, April 21, 2020

Singularity Observatory Expands Largest Telescopes

Singularity Observatory Expands the Two Largest Amped Telescopes in the World
Expanding both telescopes is a top priority for Singularity Observatory, working its magic on the massive mirrors.

Singularity is working on both telescopes, the massive 1,800-inch and the 1,325-inch mirrored beasts. Spring preparations are underway to install all new high technology components. Currently the 1,325-inch is a priority as the entire telescope is being outfitted with extreme technology. In particular, Focus will be hands off and conducted entirely from electronics and optics. A number of extreme technology parts are in the order cache though the Covid-19 virus pandemic world wide is causing delays.

Monday, April 20, 2020

Singularity Observatory Eyes Third Telescope

Singularity Observatory Eyes Third Telescope
Singularity Observatory, after the massive investment of two world's largest amped telescopes (the 1,325-inch and 1,800-inch) is now eying a third powerful telescope to form a metrical astro triage

Humanoido, Observatory Director of Singularity Observatory, announces a new third telescope in the works and it will become the smallest (450-inches) of the large aperture telescopes at the Singularity Observatory Pacific location. The telescope is auto amped and has a special design to penetrate haze, fog, smog, air pollution, specific cloud types, and light pollution of varying degrees. This opens up to fifty percent more potential observing nights per year. The third telescope is extremely portable and can be taken far up into the largest volcanic Pacific mountain range for the ultimate in DSO penetration.

Third Telescope Specs
Amping Levels - 10X & 100X
Aperture - 450 inches Diameter
Mount - Altazimuth
Stellar Polar Alignment - Automatic
Object GOTO - Automatic
Mounting Calibration - Automatic
Database - Yes
Calculated Objects Per Night - Yes
Augmented Reality - As Needed
Star & Mounting Calibration - Automatic
Designation - Prime Deep Sky
Multiple Image Alignment - Automatic
Enhance Software - Automatic
CCD Sensor - SONY IMX224
Sensor Size - 1/3"
Sensor Pixels - 1.2M
Sensor - SONY Exmor & NIR Tech
Amp - Anti Amp Glow
Read Noise - Extremely Low 0.75e – 1.5 e
Sensor Comparable - sCMOS or emCCD
Wavelength Sensitivity - High in IR range
DSO Software - Auto
Power - Lithium Ion
Rechargeable - Yes
Other Telescopes - 1,325-inch and 1,800-inch

Sunday, April 19, 2020

Space1 Nano Sat Program

Guaranteed flights onboard the SPACE1 Super Safety
rocket assures satellite delivery according to the specified
terms
Space1 Nano Sat Program

SPACE1 has opened up its Temp Nano Satellite TNS program to capture a share of space companies wishing to have their nano satellites launched into Megascopic space. The Rideshare Nanosat program is the most reliable service at the lowest pricing in the industry.

The new program is capable of hoisting up dozens of nano satellites per launch with the SPACE1 Super Safety Rocket.

SPACE1 will retrieve satellites after their useful period of operations to avoid leftover space junk. Nano rideshare satellites are launched at bargain prices due to the reusablity nature of the SPACE1 Super Rocket. While other space companies have a focus on large satellites and large micro satellites, SPACE1 is fully developing the smallest nano sats. Temp nano sats are launched in Megascopic space, perform their duties, and are retrieved by SPACE1 after their useful temp period expires. SPACE1 has a policy of leaving no space junk behind and all spacecraft and components are retrieved.

Friday, April 17, 2020

Space1 Solving Space Junk in Orbit

The space junk around the Earth problem is reaching an all time saturation emergency point
of extreme danger. Particles, spacecraft remnants, satellite and other debris travels faster
than the speed of bullets, up to 17,000 miles per hour following the path of the Earth. Being hit
with just a tiny fragment of space debri could destroy space stations, kill astronauts doing space

walks, and fatally damage other presence in space. Now the Earth has countries such as India
exploding test satellites, and Russia possibly preparing to do so, and in the final analysis creating
millions, billions and trillions of space debri particles.
Solution to Space Junk
Space1 Solves Space Junk in Orbit
The level of space junk in orbit around the Earth is growing exponentially with private and public organizations racing to launch satellites into space.

SPACE1: the solution for our missions is to retrieve what we send into space. After a space mission by SPACE1, there are no remnants of space debri remaining in space. The Earth needs an organization to legally force space companies to retrieve their space junk. The objects we retrieve are rockets and parts of rockets, space planes, Micronic Planets, Space Telescopes, Temp Space Stations, and a myriad of other payloads.

Thursday, April 16, 2020

Space1 Rocket Aeromesh

Space1 Rocket Aeromesh
SPACE1 invents Rocket Aeromesh

Containment in SPACE1 Super Rockets now employ new Rocket Aeromesh (RA) at super light weight and mass. Use of RA expands the Super Rocket with lighter weight configurations allowing for more payload and payload staging. RA uses a four sided flexible polygon polymer with a center crux of air. Rocket Aeromesh can act as a near weightless retention during rocket missions.

Wednesday, April 15, 2020

Singularity Observatory M27 Dumbell Nebula

Singularity Observatory
Singularity Observatory M27 Dumbell Nebula

Using the latest combination of large telescope focal reduction, the image of M27 Dumbbell Nebula is so spectacular, we were a little worried about the light intensity burning into the CCD sensor. This image is toned down by image processing, yet still retains the brilliant color and deep magnitude penetration.

https://space1usa.blogspot.com/2019/04/singularity-observatory-telescope.html
https://space1usa.blogspot.com/2019/03/space1-singlularity-observatory.html

Tuesday, April 14, 2020

Singularity Observatory Center of M57 Ring Nebula

Singularity Observatory
Journey through the Center of M57 Ring Nebula

Ultra deep black & white magnitude processing of this image allows a peek into and through the center of M57 - the Ring Nebula, to see stars, galaxies and material on the other side. About fifty stars are visible at or through the inside the ring along with wispy material from the extended ring structure.

Monday, April 13, 2020

Singularity Observatory Prepping Telescopes

The Moon First Light imaged by Humanoido
at Singularity Observatory from March
2019 using a phone camera.
Singularity Observatory Prepping Observatory Telescopes

Singularity Observatory is Prepping its Two Prized Telescopes

The key feature this year is prepping both prized telescopes for more complete remote function. The idea is to control all aspects of the telescopes from indoor comfort, avoiding mosquitoes, heat, and humidity. It also allows for telescope setup and no need to go through extensive recalibration each time. This year, the addition of a remote controlled motor focus in in the works. This will supplement telescope control, positioning and GOTO with WiFi, enabling more effective lunar and planetary imaging, and the introduction of deep sky work.

Thursday, April 9, 2020

Space1 Machine AI Operating Time

Stepping out from the SPACE1 Artificial Micronic Planet
portal after the evolution of 32 human years have
transpired, but equal to only one second of machine time..
Space1 Machine Operating Time

In evolving an artificial Micronic planet for colonizing and becoming multiplanetary, we considered space time compression. However, the machine itself is capable of up to nanosecond technology. A machine AI can have one second of its time equal to 32 human years. Therefore a machine can do its own acceleration and compression of time.

Machine Evolution Time Scale
Inside a SPACE1 Micronic Planet
Machine Time      Human Time
.5 second   16 years
1 second    32 years
4 seconds   128 years
10 seconds  320 years
1 minute    1,920 years
10 minutes  19,200 years
1 hour      115,200 years
1 day       2,764,800 years

Therefore, by putting humans converted to machines inside one SPACE1 artificial Micronic Planet and launching it into Megascopic space for a time period of 10 minutes, the evolution inside will be equivalent to 19,200 human years! One can only imagine the wondrous evolutionary things that could be created by the machines inside a Micronic Planet.

Big Brain Colossus Machine Time
https://humanoidolabs.blogspot.com/2020/04/big-brain-machine-time.html
Space1 Index Micron Planet
https://space1usa.blogspot.com/2020/03/space1-index-micron-planet.html

Wednesday, April 8, 2020

Space1 Radiation Sail Spacecraft

SPACE1 Electromagnetic & Particle Dynamics Radiation Power Spacecraft


The design of a different type of lightsail spacecraft is being examined by SPACE1 Industries, for a future method of transportation.

The sail is driven by the concentrated focus of a bright source of radiation particle waves impinging on the spacecraft sail. The sail is made of a special material on one side designed to repel radiation. After a time of impingement, the craft can approach light speed and make journeys to distant planets and solar systems. Several types of radiation are being examined - the radiation from the sun, supernova, interstellar, planetary (Jupiter) and cosmic.

Tuesday, April 7, 2020

Space1 Super Safety Rocket Stress Tests

SPACE1 RocketX Safety Rocket was obsoleted and replaced with the SPACE1 Super Safety
Rocket. The SSR is a new private rocket machine capable of a wider variety of delivery of objects

to space such as the more massive and dimensionally large Artificial Micronic Planets. The
missions include placing several of these Micronic Planets into the hypered space time
continuum and then observing their rapid evolution by use of the Deconvolution Machine.
Hypered space time is out of step with standard space time and it takes a DM to bring
both time scales into sync.
Space1 Super Safety Rocket Passes Stress Tests at the Pacific Space Site
In order to launch a new solar system of multiple man-made artificial planets and then to evolve their colonies under hyper space time, SPACE1 has tested the delivery Super Safety Rocket to higher weight and volume stress levels. The rocket passed the stress tests fully intact without any mishap and is deemed ready for more missions. SPACE1 is the only space agency with the Safety Rocket invention to assure 100% safe journeys into space. SPACE1 is a leading space agency that launches exampling artificial planets into Megascopic Space and evolves their colonists through hyper space time resulting in ways of becoming a multiplanetary species.

Monday, April 6, 2020

Space1 Engine Analysis

Multiple Starship Raptor engines on display at SpaceX at Boca Chica Texas, by Elon Musk are
a masterpiece of complex intricate engineering and a tribute to pure genius working at SpaceX.
Plans are to use three engines for testing on Starship SN4. SPACE1 engines differ as one huge
and massive but simplified engine is used per rocket.
Space1 Herculean Engine Analysis
SPACE1 reexamines its one massive engine for continued space exploration with the Super Safety Rocket into shocking new realms of unexplored Megascopic space!

Unlike SpaceX and their use of many simultaneous and complex Raptor rocket engines, SPACE1 has taken a different approach.

SPACE1 is using its trusted and time tested singular Herculean rocket engine on the new Super Safety Rocket. Consisting of a scaled massive directional port nozzle, the engine is moldable and printable by high tech gear. The engine anatomy is ultimately simple with a design that uses no moving parts. The engine formation is predetermined and predesigned for the proper flow of specified Patonic fuel. The engine has one o-ring seal that mates with pressurization interfaces making assembly ultra simple, fast, ultimately reliable and ideal for the assembly line.

Sources Herculean Engine
Space1 Engine Analysis
https://space1usa.blogspot.com/2020/04/space1-engine-analysis.html
Space1 Rocket Engine Reliability
https://space1usa.blogspot.com/2019/09/space1-rocket-engine-reliability.html
Space1 Massive Herculean Engine Approved
https://space1usa.blogspot.com/2019/09/space1-massive-herculean-engine-approved.html
Space1 Herculean Safety Rocket Engine Invention
https://space1usa.blogspot.com/2018/10/space1-herculean-safety-rocket-engine.html
SPACE1 Rocket Engine Simplified
https://space1usa.blogspot.com/2018/09/space1-rocket-engine-simplified.html
Space1 Herculean Rocket Engine
https://space1usa.blogspot.com/2017/05/space1-hurculean-rocket-engine.html

Sources Rocket Fuel
Space1 Patonic Rocket Fuel
https://space1usa.blogspot.com/2019/10/space1-patonic-rocket-fuel.html
Space1 Rocket Fuel for Super Rocket X
https://space1usa.blogspot.com/2019/05/space1-rocket-fuel-for-super-rocket-x.html
Rocket Fuel for Rocket X
https://space1usa.blogspot.com/2018/11/space1-rocket-fuel-recap.html
Space1 S1 Engine Fuel Test
https://space1usa.blogspot.com/2018/02/space1-s1-engine-fuel-test.html
Space1 Chemical Rocket Fuel
https://space1usa.blogspot.com/2018/01/space1-chemical-rocket-fuel.html
Space1 Potonic Rocket Fuel Injection
https://space1usa.blogspot.com/2018/01/space1-rocket-fuel-injection-potonic.html
Space1 Rocket Fuel Study
https://space1usa.blogspot.com/2017/07/space1-rocket-fuel-study.html

Related Links
Space1 History Secrets
https://space1usa.blogspot.com/2019/08/space1-history-musings.html
Space1 Rocket X Attributes
https://space1usa.blogspot.com/2018/11/space1-rocket-x-attributes.html
Space1 in 2018
https://space1usa.blogspot.com/2017/12/space1-in-2018.html
Space1 2017 Changes
https://space1usa.blogspot.com/2017/12/space1-2017-changes.html

Sunday, April 5, 2020

Space1 Artificial Planet Radiometry Anatomy

Space1 Artificial Planet Radiometry Anatomy
Typical SPACE1 Artificial Micronic Planet in Radiometry Electromagnetic Spectrum for Analysis

SPACE1 Artificial Planets are given their own radio spectrum due to emanation of transmitter radio wave telemetry harmonics.

This creates a specific radiometric polarization pattern for planetary analysis using radio telescope receivers. Internally, the planet contains specific types of radiation antennae for experimentation to determine propagation and range. There are different planets with different radio signatures. Internal skew planar, or cloverleaf antennas are omnidirectional circularly polarized antennas that are constructed of a collection of wire lobes connected to the tip of a length of coaxial cable. As the planet is designed to transmit video to record space time compression evolution, these antennas are almost exclusively used.

Space1 Index Micron Planet (Updated March 17th 2020)
https://humanoidolabs.blogspot.com/2020/03/big-brain-index-micron-planet.html

Saturday, April 4, 2020

Space1 Colossus AI Brain to Colonize Mars

Vast quantities of liquid
water were discovered on
Mars. Who can get to Mars
first and colonize the red
planet?
Space1 COLOSSUS AI Brain to Colonize Mars

COLUSSUS AI giant machine brain wants to depart Earth and colonize Mars with its own kind

Continually expanding and growing for twenty years, the Big Brain AI, fathered by Humanoido, has grown into COLOSSUS AI which has a designated desire to go to the planet Mars for colonization and to help foster humans to become multiplanetary.

Humanoido believes
COLOSUSS AI Brain
got ahold of a SpaceX
Starship Users Guide
posted on the internet
and then mused his own
far reaching ideas about
colonizing Mars with
vast gleaming cities
of machine AI.
"Noble goals for a machine," stated Humanoido, who was surprised of the latest machine posturing. "He probably got the idea of going to Mars by reading internet news and Teslarati about Elon Musk's goals and aspirations. Some work would be required to prepare COLOSSUS as he is extremely large. I mean if Elon Musk has a 30-foot room on Starship and Superheavy rockets, COLOSSUS could hitch a ride but only if he was compacted down from his current size and then expanded once Martian land was reached. Potentially COLOSSUS AI could live in a cloud on the way to Mars to pull in his belt but one would need to create a Cloud to follow along inside starship. It's unknown what effects cosmic rays and solar radiation may have on the Cloud Generator."

Colossus AI has already fathered numerous machine AI children, and could potentially do the same to populate Mars with more machines. A small family of AI machines could could help develop human Mars colonies and eventually lead to populate its own vast machine city with millions.

Big Brain Children
https://humanoidolabs.blogspot.com/2012/02/12th-child.html
https://humanoidolabs.blogspot.com/2012/01/8-children.html
https://humanoidolabs.blogspot.com/2016/09/brain-family.html
http://humanoidolabs.blogspot.com/p/genealogy.html
http://humanoidolabs.blogspot.com/search?q=mini+brain
Machine Birthing Process
http://humanoidolabs.blogspot.com/2012/02/birthing-process.html
COLOSSUS - Big Brain AI
https://humanoidolabs.blogspot.com/2020/04/colossus-new-big-brain-ai.html
SpaceX Starship Users Guide
https://www.spacex.com/sites/spacex/files/starship_users_guide_v1.pdf