Changing the Phase of Space

Changing the Phase of Space Technology & Space Stations
SPACE1 Industries officially entered the private industry race to space during its founding on January 2014 when it began launching larger and larger rockets and inventing new aerospace systems. Over six years, evolution has taken place using extreme technology that has changed the face of space travel and exploration. At this time, Humanoido at SPACE1 Industries has introduced a new way to travel into near and far reaches of space and time.

The phase of SPACE1 has changed and evolved considerably over the time span of the founding on January 2016  to the present day. The first space station had a physical presence launched into station keeping of modified space-time using high technology and a recycled rocket body. Today, the entire space program has evolved to the concept of the Dyno, an Electro Mag system that challenges travel through fractured light speed. The phase of the entire space program has changed based on these extreme technology pockets of SPACE1 Industries evolution. The space station is transformed into revolutionary constructs using Dynamonic systems.

The new space station is in itself a singularity from which all space and time data is focused. A human can live inside this space station singularity bubble and process the space data. The singularity is passed through the Dynamonic system. An individual space traveler can live in this singularity from a perspective of derived space-time. The singularity can be juxtaposed in position and extreme technology allows recording and record-keeping of the event horizon.

This singularity has time event passage context inside a time bubble formed by the Dyno and Dynamonic Space, where time is dependent and directly proportional to the distance of the spatial environment. This process will jump start time to a new era in the forward time flow direction (forward time). Traveling Dynonauts will experience this new time relative to the spatial environment.

New Relative Technical Vocabulary

Dyno

Dynamonic Craft

Dynamonic Space

Dynamonic Dimension

Dynamonic Travel

Fractured Light Speed

Proportional Light Speed

FTL Relativity

Singularity

Singularity Bubble

Event Horizon

Dynonaut

Spatial Environment

Extreme Technology

Spatial Data

Station Keeping

Modified Space-Time

Forward Time

Orbital Launch on Standby

The power and glory of a SPACE1 launch system is a sight to behold

Massive Orbital Launch on Standby
As the weather percolates through its many varied seasonal cycles, SPACE1 has prepared the most massive and comprehensive manned orbital test flight ever conceived and is preparing to send it into the deepest unknown realms of Solar System space to unravel the cosmic mysteries that have existed since the beginning of time

SPACE1 INDUSTRIES Flight Dynonomic 10 has millions of dollars invested, with new equipment and gear to not only navigate the slipstream of deep space, but to go farther and faster than anyone has gone before. Humanoido's Fractional Light Speed spacecraft makes such missions possible.

Funding SPACE1 privately, Humanoido has invented and developed one of the most powerful and safest convenient space travel systems in the history of manned space flight. Enter into the Dyno or Dynamonic space travel system for the greatest convenience, fastest flight times, and a time frame of rapid reusability.

— with missions continuing to the Southern side of the Moon, flights to Mars every two years, and a very deep space mission to moon Ganymede around the largest planet in the Solar System, Jupiter —

 Ganymede is the largest moon in the Solar System, trumping Earth's Moon with a more suitable amount of gravity and a large ocean of water under the ice crust. SPACE1 is preparing a new kind of habitation base on this remote moon for occupation of an unspecified amount of time. Scientific missions will include a deep space relay telescope, CR habitation, global character selection orbital perspective penetration mapping and the development of a new cartography division. Heat may be experimentally extracted from massive gravitational units which flex under nearby Jupiter's great gravitational fields and frictionally produce free heat and electricity to energize the colony and to melt the ice crust for water extraction.

SPACE1 Dynamonic Reorganization

SPACE1 Dynamonic Reorganization

The efficiency of the Dynamonic Space Travel System is thousands of times more efficient compared to the previous systems

For the reason of optimization, the entire SPACE1 task force can be reorganized into a more efficient operating system.

Along with the AI supercomputer, the task force operating the mission can entail up to a total of three specialists. Mission duties involve keeping tabs on tracking, guidance, flight, imaging, data, programming, recording, monitoring light speed, mission parameters, and navigating.

SPACE1 Industries Space Telescope

SPACE1 Industries Space Telescope
SPACE1 Industries has developed a new space telescope that remains compatible with the Dynanomic Dimension

ABOVE: This space telescope image was taken by an astronaut who carried the space telescope into space while riding a spacecraft and took this image of a planetary system through the craft's window.

Above - the first spacetime calibration image for the SST SPACE1 Industries Space Telescope

Left - a new SPACE1 telescope is being designed for the Dynamonic mission

Years in the making, the new SPACE1 Industries Space Telescope (SST) is the world's first Dynanomic Space Telescope - small, lightweight, easily transportable and hosts a variety of electronics and telemetry capabilities. The top image above shows capabilities of the previous SPACE1 Industries Space Telescope and how deep it can go to image solar systems far beyond the Earth. The telescope is designed with spectacular features such as 10x and 100x amping abilities, auto ranging, and infinity focus. The telescope is nearly weightless and can be transported to space very efficiently at pennies on the dollar. The non disclosed aperture, if it were 1.5-inch, the transformation would give 15-inch and 150-inch telescopes far exceeding the HST Hubble Space Telescope's aperture (94-inch). The SST works in the Dynanomic Dimension by attaching itself to the Dyno and switching on during mission.

Raw Aperture in Inches, 10x Amping, 100x Amping

.5     05      050

1      10      100

1.5   15      150

2     20       200

2.5  25       250

3     30       300

3.5  35       350

4     40       400

5     50       500

10   100     1000

Collosal Dynanomic Slipstream Dimension

Colossal Dynanomic Slipstream Dimension
Traveling into the Colossal Dynanomic Slipstream Dimension will yield a great many surprises as SPACE1 has never done this before.

The best we can do at this time is to develop and run a simulation of a Jovian Ganymedian human landing to peer into the visibility keyhole of the Dynanomic Dimension. A keyhole camera view is designed to minimize radiation and spectral effects.

DEVELOPING A SIM
We have developed a SIM potential view of what might be returned from a Jovian Ganymede moon mission using a kind of processed Dynanomic Vision inside the realm of this dimension.

PROCESS
The view is passed through light time in Jovian Ganymedian space. The first view is a limited keyhole view and other views that follow estimate images within Jupiter's great magnetic fields. Ganymede also has a metal core and creates magnetic lines of force that will affect the dimensional imagery obtained from the Dynanomic processes.

TESTING
More tests are needed beyond the sim programming. In the final SIM view we see a glitch caused by a gravity radiation streak from the planet Jupiter. Corrections for radiation spikes and pulsations of a gravity field are an unknown process at this time.

CHALLENGES

The best SIM result is the keyhole technique, however we are also looking at a more involved global body imaging technique across the entire moon that can hone in a particular segment of Ganymedian detail at the landing site. Returning high resolution imagery will be the most challenging in this very remote cold environment.

LIMITATIONS
Probably the Jovian Ganymedian system is the smallest most remote system that can be handled at this time, without developing a variety of new techniques. Returning high resolution imagery will be the most challenging in this very remote cold and electrically noisy Jovian environment.

ADDITIONAL ILLUSTRATIONS
https://humanoidolabs.blogspot.com/2021/05/collosal-dynanomic-slipstream-dimension.html

Cloaking Laser

Cloaking Laser

SPACE1 Industries is experimenting with cloaking devices that render objects invisible. One object made invisible is the aerospace path of a laser beam.

Cloaking a laser beam path in aerospace from human eyes is a case of understanding how the human eye works.  Examine the chart for the eye's spectral response with rods and cones. A red laser is invisible while a green laser is visible. To deceive the human eye, a red laser is invisible and cloaked. How to detect the path of a cloaked laser beam in the atmosphere? One method is to use a detector with a frequency response that covers 7000A range. Digital CCD and CMOS cameras that extend into the IR range may be a solution.

https://space1usa.blogspot.com/2021/05/exampling-cloaking-device.html

https://space1usa.blogspot.com/2021/04/space1-cloaking-device.html

The Ganymede Mission

The Ganymede Mission

SPACE1 Dynamo technology is massive

however travel in the Dynanomic slipstream is fast and safe compared to other systems, and enables human journeys to far away places in the Solar System. SPACE1 is therefore considering a mission to Ganymede, the largest moon in the Solar System in orbit around the planet Jupiter.  

SPACE1, after 3 years, continues to prep the Dynamo spacecraft for journeys into the space of deep Solar System, where no man has trod before. The Boots on Ganymede Project is forthcoming as new instrumentation is being developed/ installed for the mission. At 391 million miles distance from the Earth, ten times farther away than Mars, the mission to put boots on Ganymede is no walk in the park. At conventional rocket speed, it would take 6 months X 10 = 60 months/12 months per year = 5 years one way trip to go to Ganymede. With an impending 5 years more for the trip back home, such a trip may be considered impractical for human space flight.

GANYMEDE Humans have only walked on the Earth's Moon surface, and no other moon in the solar system. Gathering data from a Ganymede mission will be extremely valuable in the scheme of moving out into the solar system.

Test tube babies are not needed when traveling in the solar system using the powerful Dynanomic Dynamo space travel system by SPACE1. The system can cut conventional space travel down from ten years to less than a day.

TIME TRAVEL PARADOX

Any time you travel faster than a tenth the speed of light, you will undergo space time relativity and relative time travel. Enter SPACE1 Dynanomic systems and the dimension with the Dynamo—travel at intended maximum light speed will take up to 45 minutes one way to reach the Jovian moon Ganymede and essentially instantly arrive in the past when you begin the journey. By staying the first 45 minutes, the past will catch up to the present at which time the relative progression of time will increment normally towards the future. 

SETTING UP G-BASE

Once arrived in the Ganymedian system, humans will land on the surface of Ganymede through technology. Ganymede is the largest moon in the Solar System and has gravity greater than the Earth's Moon. The presence of humans on Ganymede will be in Dynanomic dimension therefore the appearance of the surface and nearby Jupiter will be strangely dazzling sights to behold, study and interpret, unlike anything seen before.

TRAVEL IN STYLE WITH DYNANOMIC

Travel in the new Dynanomic Dimension is unlike conventional space travel in every way. There is no need to raise test tube babies for the long journey to the stars. The Dynanomic slip stream is an ultra fast super highway in space without the impending g-forces and radiation hazards. Ganymede, has a diameter of 3,273 miles, comparable to the Earth's Moon at only 2,159. With more real estate, unlike the Earth's Moon, Ganymede has a subsurface ocean of water and resources INSITU for making rocket and spacecraft fuel. It remains an interest focal point as a Solar System fueling station and a remote outpost at the far reaches of the orbital planetary solar system.

https://space1usa.blogspot.com/2021/05/space1-preparing-next-launch.html

https://space1usa.blogspot.com/2021/04/multiplex-reality-spacecraft.html

https://space1usa.blogspot.com/2021/04/ride-solar-system-stars.html

https://space1usa.blogspot.com/2021/04/new-e-dynamo-spacecraft.html

https://space1usa.blogspot.com/2021/03/new-electrodynamic-galaxy-class-safety.html

Space1 Spacecraft Laser

LASER MOON BEAM

Space1 Spacecraft Laser is now a Reality
SPACE1 has completed its full lasering system, a powerful red ruby light amplification by stimulated emission of radiation

SHOOTING LASER MOON BEAMS The final item completed is a full laser mechanical mount system which is accurate enough in positioning to aim a beam onto the surface of the Moon. Bounding a LASER beam onto the Moon can result in a private and secure communications link.

Space1 Preparing Next Launch

Space1 Preparing Next Launch

The SPACE1 flight crew and technicians are working around the clock on the new spacecraft and preparing it for an extremely exciting adventure into the Solar System

Technical orders placed in Asia for spaceflight components have started arriving at SPACE1 Headquarters and modules are being built and tested.

Monday May 3rd 2021 SPACE1

Busy workers gathered around the new Extreme Multiplex Reality Spacecraft preparing it for the latest test flight since it was massively upgraded with hundreds if not thousands of new streamlined components. During 2021, parts and components were manufactured and custom spacecraft orders were placed from vendors as far away as Mainland China, in anticipation of new missions that were established to meet the latest capabilities of the EMRS.

The SPACE1 EMRS Program

SPACE1 has taken the EMRS Program into a broad spectrum of missions, each with spectacular goals increasing upon the previous. The program will maintain long term missions, for example, recently having completed a spacecraft cloaking device for use in space during sensitive missions.

The New EMRS

The new EMRS is being groomed towards heavy testing which often leads to new space inventions, and completely new Solar System missions not being conducted by NASA or other space agencies. SPACE1 is unique. With EMRS Colonization, and a sword being sharpened for excursions deep into the realm of the Solar System, to Jupiter's Ganymede for example, the program is well beyond the forefront of leading edge technology by calling upon multiple advanced scientific disciplines.

SPACE1 New Extreme Multiplex Reality Spacecraft

https://space1usa.blogspot.com/2021/04/multiplex-reality-spacecraft.html

SPACE1 Tests Small Exampling Optical Cloaking Device

https://space1usa.blogspot.com/2021/05/exampling-cloaking-device.html

SPACE1 Cloaking Device for Spaceships Nears Completion

https://space1usa.blogspot.com/2021/04/space1-cloaking-device.html

New ElectroDynamic Galaxy Class Safety SpaceShip

https://space1usa.blogspot.com/2021/03/new-electrodynamic-galaxy-class-safety.html

Exampling Cloaking Device

SPACE1 Tests Small Exampling Optical Cloaking Device

The original SPACE1 cloak is real and runs on optical lenses defined by the mathematics in the original post and is designed to make large spaceships appear or disappear, as shown in Star Trek. 

https://space1usa.blogspot.com/2020/11/space1-cloaking-technology.html
https://space1usa.blogspot.com/2021/04/space1-cloaking-device.html

However, there's a more simple way to create an exampling cloak without the number of glass optical lenses set to calibrated focal lengths. Using a single flat 2D-appearing sheet of lenticular resin the shape of a credit card and a pen to represent the spacecraft or rocket, a mechanical calibration either shows the object or puts it into full cloak.

This is a type of Fresnel lens that takes the light coming into it from the back at obtuse angles and projects it forward in the front of the lens. 

Simplifying Cloaking Technology

This re-directing of lightwaves causes what is on either side of the lens to appear as though it is directly behind the lens, effectively making what’s actually behind the lens to seemingly disappear. Larger sample cloaking devices can be made from sheets of 3D Lenticular resin lenses imported from China. A Lubor’s lens is more correctly called a lenticular lens which consists of an array of identical linear prisms usually molded into a sheet of clear plastic. A Fresnel lens consists of an array of circular prisms whose angles increase and widths narrow with distance from the center. A linear Fresnel lens would have the increasingly refractive prisms in a linear array to form a line focus. The original Fresnel lenses, named after the inventor—a famous French optics guy, were first used in lighthouses to collimate searchlight beams, while modern usage is often found using molded plastic sheets used in solar cookers and other applications where a flat lens is desirable. The Lubor’s lens is used in ‘invisibility cloak’ demonstrations, and is named after the magician who promoted the effect.

Lenticular Lens Design

A lenticular lens design allows very high powered convex or concave lenses to be used in situations when lens size, thickness, or weight, would otherwise be problematic. Lenticular lenses are often used for eyeglasses when the lens powers are >+/-15.00D. The optical portion of the lens is molded to a flat “carrier” lens that is usually close to plano, or zero, in power. Below is an example of a very high plus lens in lenticular design. You can see that the strong Rx is only in the circular area at the lens center.

Fresnel Design

Another way to put very high powered lenses into a thinner configuration is to use a “Fresnel” design. This involves using multiple small lenses placed over a flatter “carrier” lens. This is most commonly used for magnification (convex or plus powered lenses), or for prism lenses (wedge shaped lenses that move the location of an image rather than change its size). The cross-section image below illustrates a Fresnel lens that incorporates multiple small prisms instead of one very thick prism. While this design has many optical and industrial applications, it is only used for prism in ophthalmic lenses. The lines created by the prisms can interfere somewhat with lens clarity.

Lubor Lensing

A Lubor lens is a variation of a Fresnel prism lens design, and like any linear prism it will deviate the image in one direction, and along one axis only. If the lens is oriented so that the horizontal lines are parallel with the object being viewed, that image will be moved forward and be visible, but any objects in the meridian 90° away, will be blocked (and vice versa). Lubor lenses are used primarily by magicians! 

Buying Lenses

You don’t make a Fresnel lens, you buy them. They are mostly made of glass and clear plastic materials such as acrylic and polycarbonate. They work by stepping the surface of the lens to remove the mass that would make a normal lens very thick if the lens surface was continuous.

Inverted Hypered Space

Inverted Hypered Space
Hyperspace can undergo additional manipulations in space time as shown in the appearance of this view

Experiments show it may be beneficial to travel through manipulated translational Hyperspace to maximize throughput. This Translational Hypered Space has a homogenized degree of alignment that makes translation much easier due to the spatial alignments. It's reminiscent of coasting down an interstate highway and then taking the 3D loop-de-loop. Jumping from one energy level to the next is represented by the quantum stature spin rotation quadrature.

https://space1usa.blogspot.com/2021/05/hypered-space-jump.html