Tuesday, April 30, 2013

Mystery Object

Mystery object seen through the PDT Telescope
MYSTERY OBJECT CONTEST
NEW: Can you identify this eerie object?

Hint... it was seen through the recently completed Power Dynamic Telescope and it's a large celestial object in space. It was captured with the Molecular Unit and Multi Adjunctive Mode. We'll reveal the result in a future post.

What is this black and blue object lurking inside the glowing depths of this interesting green turbulent crypt of deep space matter? Does it have something to do with a gravitational black hole or is it a new object emerging from space and time? Identifying and interpreting cosmos images has become an important part of the Big Brain's Space Program. Be the first to identify this object and we'll send out a prize award. All followers and colleagues not part of the imaging team will qualify for this contest. Refer to the above CONTACT menu and use the email address provided.

http://humanoidolabs.blogspot.tw/2013/04/mystery-object.html

In the event the prize is not formally claimed within ten days, the next time-based person who had correctly identified the mystery object will be selected.

Monday, April 29, 2013

Space Launch Slated for Thursday

SPACECRAFT LAUNCH SLATED FOR THURSDAY
Our new schedule just in, cites the human spacecraft launch will take place on Thursday, May 1st, 2013. Government registrations are completed and approved. Exploration of Near Space and the deployment of the Tiny Space Telescope, with a study of our new GPS instruments are currently scheduled for this flight.

http://humanoidolabs.blogspot.tw/2013/04/telescope-for-near-space.html

It was decided to go ahead with back to back space launches and recoveries to double the amount of collectible space data. This is also double the amount of work to conduct the space program. We hope to collect usable data and images with the first Tiny Space Telescope. This could include daytime solar and night time star imagery for the testing of future celestial navigation.

http://humanoidolabs.blogspot.tw/2013/04/near-space-test.html

The Big Brain machine appears intent on running with both manned and unmanned versions of its space program. Currently the space program is using a new PDT, a Power Dynamic Telescope, in tandem to explore black holes and the edge of the Universe.

Black Holes Raise More Questions

Black Hole with unknown BL Trans
BLACK HOLES RAISE MORE QUESTIONS THAN ANSWERS
The Big Brain Machine Initiative to explore space and study black holes to fulfill requirements of the Prime Directive has recently taken a turn with the introduction and completion of the largest and most powerful telescope in the series of Adjunctive Telescopes. These new telescopes have tools never before available in unique combinations that permit seeing things in unusual places where typically telescopes do not look.

In the number of days the PDT has remained in its infancy of operation, and based on enigmatic black hole data returned so far, we can say that approximately 33 questions are raised and only 2 answers have resulted. This is truly mind boggling and was never expected. The massively large telescope was expected to see new things, and it has, and we expected to be able to offer identifications of what we were seeing, and we have not. We did not anticipate the new and enigmatic causation occurring inside the black hole domain. This is a place where the laws of physics, space and time are unknown, so what we are seeing may be inexplicable.

"A black hole is a region of spacetime from which gravity prevents anything, including light, from escaping. The theory of general relativity predicts that a sufficiently compact mass will deform spacetime to form a black hole. Around a black hole there is a mathematically defined surface called an event horizon that marks the point of no return. The hole is called "black" because it absorbs all the light that hits the horizon, reflecting nothing, just like a perfect black body in thermodynamics. Quantum field theory in curved spacetime predicts that event horizons emit radiation like a black body with a finite temperature. This temperature is inversely proportional to the mass of the black hole, making it difficult to observe this radiation for black holes of stellar mass or greater."

"The defining feature of a black hole is the appearance of an event horizon—a boundary in spacetime through which matter and light can only pass inward towards the mass of the black hole. Nothing, not even light, can escape from inside the event horizon. The event horizon is referred to as such because if an event occurs within the boundary, information from that event cannot reach an outside observer, making it impossible to determine if such an event occurred."

"When an object falls into a black hole, any information about the shape of the object or distribution of charge on it is evenly distributed along the horizon of the black hole, and is lost to outside observers. The behavior of the horizon in this situation is a dissipative system that is closely analogous to that of a conductive stretchy membrane with friction and electrical resistance—the membrane paradigm. This is different from other field theories like electromagnetism, which do not have any friction or resistivity at the microscopic level, because they are time-reversible. Because a black hole eventually achieves a stable state with only three parameters, there is no way to avoid losing information about the initial conditions: the gravitational and electric fields of a black hole give very little information about what went in. The information that is lost includes every quantity that cannot be measured far away from the black hole horizon, including approximately conserved quantum numbers such as the total baryon number and lepton number. This behavior is so puzzling that it has been called the black hole information loss paradox." Wikipedia

Black Hole Floaters & Red Matter

Inside the heart and center of a Black Hole, Red Matter and a White Floater undergo enigmatic molecular transformation. Power Dynamic Telescope image.
BLACK HOLE FLOATERS
and Red Matter Mystery
Another mystery and new discovery emerged today when images returned from the Power Dynamic PDT Telescope, showing white floaters and red matter, were subjected to study at the Power Dynamic Telescope Control and Processing Center.

What is this red matter domain and what are these floaters inside the black hole? Why does one transform the other? —

The image shows a red domain and white floaters. The view is aimed at the heart and center of the black hole and at several mystery objects, named floaters, also deep inside.

The real enigma is the transformation of the center floater object as it appears to have transparency, change color and transform when it floats over the apparent underlying domain object.

The floater objects appear to have a white base color but when one passes over the red domain object, it obviously changes color to yellow. Another white floater is evident, with two more intensive whitish globules inside.

A yellow border on the floater object appears to be generated by the red domain object and just on the other side, the color abruptly turns bright white. A marked and profound delineation appears between the two objects and a border is established. This mystery deepens when examining additional imagery.

Black Hole Object Edge Work

BLACK HOLE OBJECT
EDGE WORK
Intensive EW processing still cannot bring out any detail of what's inside this erie object suspended inside the black hole and under the influence of its powerful and space altering gravity.

BL Sobel on Black Hole Object

BL SOBEL ON BLACK HOLE
The unknown object inside the black hole vicinity undergoes BL Sobel processing indicating and showing the space gradient between black hole effectual space and the object.

The object, even with processing, is relatively featureless contributing to its overall mystery. What is known, the object resides directly under the influence of the black hole and experiences relativistic effects including temporal time transformation from huge gravity.

Travel Inside a Black Hole

TRAVEL INSIDE A BLACK HOLE
This is the first time we've had a telescope powerful enough to travel inside a black hole.* Penetrating a black hole, in between two jets, to explore the space inside is now possible with the new Power Dynamic Telescope with its molecular and adjunctive capabilities engaged.

*"Inside a black hole" needs a definition. It's possible to see up to the event horizon optically but perhaps not deeper. Beyond the EH boundary, it's a mush of compressed space and time particles where the gravitational forces are so great that no light can escape.

So actually to see inside the black hole on the other side of the event horizon must deploy some other means than the direct observation of optical light.

Powerful black holes are strong emitters of x-rays and a radio spectrum telescope analyzer is highly useful.

Optical light observations within the black hole up to the event horizon are very useful. It's also very useful to study compression of space and time near the black hole.

We also define the black hole as the position determined by its jets. Observing between the jet-limits also qualifies as the black hole's domain.

http://humanoidolabs.blogspot.tw/2013/04/black-hole-heart.html

Strange Object Inside Black Hole

ERIE OBJECT DISCOVERED
INSIDE BLACK HOLE
This is the first closer look at an erie object found inside a black hole with the new telescope. What purpose does it serve? What are the functioning dynamics of this object.

Found recently with the PDT Power Dynamic Telescope, we don't know what it is, but it's one of several objects found inside a black hole. It lies somewhere between the center of the core and the position slightly outward towards one relativistic jet. This class of enigmatic objects found inside black holes within the confines of contort space will become a subject of study. Thermal Imaging and X-raying have revealed no additional information at this time.

Black Hole Contort Space


Strange Erie Relativistic Space Warped by Temporal Time
FIRST VIEWS OF CONTORT SPACE! 

— INSIDE A BLACK HOLE — 

While other astronomers are focused on the jets from these black holes, the Big Brain Initiative is looking at the very luminous heart’s center, where relativistic event space is warped and the curvature of time is changed by huge gravity. This data can provide information for solving the riddle of going beyond the singularity when space and time was born in the Universe.

In this very deep image, the very distant galaxy 3C348 Hercules A, located 2.1 billion light years from the Earth, is penetrated to reveal the black hole at its core. Next, we used the Power Dynamic Telescope to penetrate further, deep within the black hole and its vicinity.


This image represents a very massive undertaking. The giant Power Dynamic Telescope uses nearly 30 Adjunctives for penetrating deep inside the elliptical galaxy’s core and mining this powerful black hole treasure. This far in, contort space looks strange and erie, warped by temporal time.


The black hole object  has such high gravity that not even light can escape. The image shows matter glow from the mad rush of incoming matter into the black hole itself as it’s crunched into fundamental molecular mush. This black hole was likely formed when a massive star died and its core collapsed into a superdense mass.

Making a Tiny Space Telescope

BUILD A TINY SPACE TELESCOPE
We built our Tiny Space Telescope using parts from a Canon digital camera with CCD sensor elements and anti-motion correction mechanics. Convex lenses from small telescope oculars and reading glasses were recycled into the telescope. Next, the telescope was configured, for use as a telescope, by setting the lenses for the maximum focal length. A small tripod mount is attached for movement as alt-azimuth and adding mass hand grips and stability. Preconfiguring can also set the ISO to 28,000 for deep sky penetration.

Near Space Test

NEAR SPACE TESTING
A number of tests are planned for the upcoming human launch into Near Space. One, we hope to use a man-operated tiny telescope to explore daytime and/or night time objects from space. Two, what is the functioning of GPS satellites as established through a smart phone during launch, at variable positioning, at high altitudes, and from the apex of Near Space?

QUESTIONS
Answering these two questions, according to the Big Machine Brain program and the Space Exploration Initiative will be important to putting our exploration astronauts into space, and in fulfilling the Prime Directive for manned exploration.

BIG BRAIN SPACE PROGRAM - TYPES OF SPACE

https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEjrvkfTlzMPCHVmnp0pwOJM9vM2yT6JexXz5ztofe6yBk8saMZc0I4RDdVGAxC7Uo3igxYTR_4oqs0FlUWgCEhHHmCffSXMqa45GecBOn82wItN5T1G1ZFCkHYyuJiFjGotHtouD635cVz7/s1600/space.jpg

PHOTO
The photo shows space through the very large PGT-ET telescope which has multiple adjuncts in space and ground operations using a supercomputer. We don't expect results like this with the Tiny Space Telescope we're taking with us during the upcoming Near Space flight this week. The goal is imaging on the Sun, Moon, or a bright star for future celestial navigation.

VIEW PORT
The telescope test could be a success or a failure, as last time we had some challenges faced with the view port window. These windows tend to electrostatically collect dust and debris, easily scratch from the ravages of space travel (our spacecraft is reusable), and develop patches of moisture and condensation from the double layering with trapped moisture and the extreme temperatures of space. The view port also develops internal and external reflections with its multiple layering and absorbs and reflects light. It may also introduce distortion as the view port material is not optically flat.

http://humanoidolabs.blogspot.tw/2013/04/pgt-et-telescope-stars.html

TELESCOPE
The tiny telescope is currently more about testing ideas for navigation in space, for spacecraft and space object positioning. For example, the Big Brain may want to launch/release a tiny satellite into space and having a better understanding of how to orientate that spacecraft will become important.

http://humanoidolabs.blogspot.tw/2013/04/telescope-for-near-space.html

TSAT & SPACE TELESCOPE
One long range goal is the release of a TSAT (a temporary space satellite) and/or a tiny space telescope that will spend some time in space before its position decays.

http://humanoidolabs.blogspot.tw/2012/12/temporary-satellite-tsat.html 

Sunday, April 28, 2013

Tiny Telescope for Near Space

Telescope photo showing the Moon
TINY TELESCOPE FOR NEAR SPACE FLIGHT
The next Near Space flight will carry a small telescope up into the fringes of space, and will be capable of imaging planned celestial objects during the day and night. The first time telescope will be equipped with a battery operated CCD camera imager capable of single integration color or black and white at ISO 28,000 or more.

NODAL POINTS
Short term integration
The initial tests will be unguided, i.e. accepting the motions of the spacecraft. We will study the best spacecraft orientations for particular telescopic data collecting and imaging with the greatest points of stability and least angular rotation and linear motion.

This will occur at nodal points established during the flight.

IMAGE STABILIZER
The telescope will include an Image Stabilizer to reduce imaging motion and produce more clear and less trailed images.

Solar imaging
PIXELS
With over 10 million pixels, the telescope can produce fine resolution shots.

CCD
This is an electronic telescope with a built in CCD Charge Coupled Device.
 
TIMED INTEGRATIONS
The telescope is equipped to do integrations of up to 15 seconds to capture faint objects and possible star fields during flight. Solar integrations can be as short as 1/1,600th of a second.

FOCAL LENGTH
Atmospheric effects
The small telescope is variable at f/2 to F/4.9 with a focal length from 28mm to 105mm. Part of the telescope is electronic, thus capable of FL modification.

MONITOR
A 3-inch color monitor is attached to the telescope for focus, framing and viewing in various modes.

Storage Media
STORAGE
Deep Sky M57 on storage

iPhone 5 support with Siri AI
Free iPhone app supplements telescope data











Image storing is available in the following formats: RAW 3648 x 2736, JPEG 3648 x 2736, JPEG 2816 x 2112, JPEG 1600 x 1200, JPEG 640 x 480, JPEG 3648 x 2048, JPEG 2816 x 1584, JPEG 1920 x 1080, JPEG 640 x 360, JPEG 3648 x 2432, JPEG 2816 x 1880, JPEG 1600 x 1064, JPEG 640 x 424, JPEG 2736 x 2736, JPEG 2112 x 2112, JPEG 1200 x 1200, JPEG 480 x 480, JPEG 2192 x 2736, JPEG 1696 x 2112, JPEG 960 x 1200, JPEG 384 x 480.

M1 integration
HIGH TECH TELESCOPE
The high technology telescope supports HD recording and uses a folded lens design. This is specifically designed for Near Space flight and has low profile compacted folded dimensions of approximately 4-inches x 2 x  1. The folding design extends another one inch to the 1-inch dimension. It can do continuous auto timed repeated imaging at about 2 FPS running on Lithium Ion batteries. Images are saved to a multi media card which can be retrieved after the flight.

SUPPORT
Small telescopes can be supported with iPhone 5 functions, including the built in talk-to artificial intelligence SIRI when the sound environment is relatively quiet.

Next Human Launch into Near Space

Tiny Near Space telescope is inside the bag
BIG BRAIN'S EXPLORATION OF THE CONTINUING FRONTIER
NEXT HUMAN NEAR SPACE LAUNCH
Last time, the Big Brain Machine Initiative successfully launched and recovered an astronaut into Near Space on Sunday, February 3rd, 2013. That flight produced a successful study of fourteen Strata Layers beyond the Earth, journeyed to the fringes of space, set new records, and completed a space port view progression. Now we are once again about to depart into the frontier of Near Space and explore its domain.


http://humanoidolabs.blogspot.tw/2013/02/near-space-flight.html

The Big Brain is a Propeller powered semi-cognizant machine with a space program and a Prime Directive.


Prime Directive
http://humanoidolabs.blogspot.tw/2012/03/prime-directive.html


This time, launch conditions predicted by local weather sources are favorable 50/50 sun/rain. Either way, the launch will take place as the spacecraft will rise above the weather front to the crystal clear frontier.

This time, we're taking up a tiny space telescope, which is small enough to fit in the illustrated bag.

Most records in this Near Space space program, over the past years of exploration, have reached limits, in terms of the analysis of collected data, for maximum spacecraft height reached, coldest temperature on record, consecutive strata layering, launch and reentering vectoring, relative speeds of travel, and numerous parameters for a sub orbital flight. It's unknown if any TSATS will be released.

TSAT Temporary Satellite Invention
http://humanoidolabs.blogspot.tw/2012/12/temporary-satellite-tsat.html

December 8th, 2012 Space Launch
http://humanoidolabs.blogspot.tw/2012/12/december-space-launch-2.html
This space journey will ramp up with the introduction of two flights separated by a minimum of one day between each launch and reentry. This will be day, night, or both day /night launch/recoveries.

Space Launch One
http://humanoidolabs.blogspot.tw/2012/12/first-december-space-launch-one.html

This time, we will look for evidence Near Space phenomenon out of the ordinary, test elements of the space craft, and test an in flight astronomy program for celestial observations either daytime or night time or both.

October 12th, 2012 Human Journey into Near Space
http://humanoidolabs.blogspot.tw/2012/10/journey-into-next-space.html

Types of Space
http://humanoidolabs.blogspot.tw/2012/10/types-of-space.html

Friday, April 26, 2013

Power Dynamic Telescope PDT - through the Ring Nebula M57

The center of the Ring seen through the Power Dynamic Telescope PDT
POWER DYNAMIC TELESCOPE PDT
FANTASTIC JOURNEY THROUGH M57 RING NEBULA
M57 like you've never seen it before!

Small telescope M57 view
LOOKING INTO & THROUGH THE RING NEBULADiscover What’s Inside and On the Other Side!

At Left: a small telescope barely shows the 9th magnitude Ring Nebula. The center hole is featureless.


We give you permission to embark on a great Telenaut mission of exploration and discovery. Travel to the giant smoke ring - the famous Ring Nebula. Like astronauts using space ships, Telenauts use powerful telescopes to achieve their space missions.

When we arrive at this celestial wonder, we will enter into, explore inside, and then travel beyond the place that no man has ever gone before using the Big Brain's newest Adjunctive telescope.

Spectacular, mind boggling, and fantastic are the named results that come to mind when describing the newest journey into deep space made with the new Power Dynamic Telescope, bringing forth shocking new discoveries (that reside within and on the other side of the Ring).

No telescope this large ever attempted to penetrate the center hole of M57 until now. This is just the beginning of a new era in space exploration by the Big Brain Inititive. The Ring Nebula appears as a kind of cylinder, with spatial depth that can be penetrated and reveal space time on the opposite side. The things that materialized in the first exploratory image are astounding!

BREAKING NEWS! Spectacular results were imaged last night when the newest and most powerful Adjunctive telescope, the Power Dynamic Telescope PDT, was slewed towards the famous Ring Nebula, diving into the center hole to reveal the treasures hidden inside.

Supercomputer driven, the very powerful and complex Discovery Class Power Dynamic Telescope was pointed at the center of the Ring Nebula M57, and when doing Molecular calibrations - it inadvertently began looking inside the hole where we expected to only see a couple dim magnitude stars for tweaking the cams. Unexpectedly, not only could we see materialization inside, but we could see all the way through the Nebular Cast Sheen (attributed to M57) to the other side where new objects were discovered, arranged in space - resident beyond the ring!

— Telescope shows more than expected: looking into and through the ring to the other side! — 


Our Discovery List

1) The PDT allows one to look inside M57 Ring Nebula’s center hole and to look inside some distance as the ring is really a cylinder implying depth of field.


2) A Blue Cast Sheen BCS molecular window is discovered, which was created by the Ring's connecting molecular dust and gas.

3) The PDT Telescope was able to penetrate the blue cast sheen all the way to the other side of space and time.

4) There are objects both within and beyond this ring - inside and beyond the window of exploded star dust, many new faint stars and objects are seen.

5) Inside the ring we see two parallel bands of star dust and matter apparently residing inside the cylinder walls, appearing to have some connection with the matter curvature of the Ring's cylindrical shape.

6) Beyond the BCS boundary, there are many rifts, voids, stars, galaxies, nebula, and objects in space.

A star map, showing the plot of more stars and objects, can be created using the telescope’s Paradigmic Light Processor and this image.

Thursday, April 25, 2013

Power Dynamic Telescope PDT Sees Super Giant Star

POWER DYNAMIC TELESCOPE FINDS SUPER GIANT STAR DISK!

EXPLORER CLASS TELESCOPE: Spectacular new view of a giant sun located across the galaxy..

THIS IS JUST CRAZY TELESCOPIC VIEWING — SEEING This Giant Bubbling Star Image Close Up!

A giant red super sun is living across the galaxy. It's so large, we decided to try pointing the PDT telescope there to see what could materialize. Stars are generally only tiny pinpoints, unresolved pin-tip dots in the largest telescopes. However, through the giant PDT Telescope, a giant full disk bubbling sun is resolved, showing the enigmatic face of Betelgeuse, a bright super red giant star in the constellation Orion.


Gazing upon the starry heavens we've seen the orange reddish hew of the Star Betelgeuse on countless clear nights and wondered what it looks like close up. Telescopes of moderate to large size simply do not show the tiny stars as anything more than a pinpoint of featureless light. It takes very large telescopes and special techniques of interferometry to bring forth a disk and not much more is discerned. The PDT however, is so large in aperture, and with techniques of supercomputer molecular envisioning and processing with Adjuncts, that optically it can see an image with a large amount of unprecedented detail. This giant star is amazing with a massive bubbling boiling surface!

NINE NEW DISCOVERIES!
With just one observation of one star, the Explorer Class telescope has made more discoveries at a rate higher than any previous Big Brain Initiative telescope.

1) Resolving the disk is remarkable and unexpected.

2) Seeing topical features extending out from the solar perimeter is remarkable.

3) The detail in the photosphere is unprecedented.

4) At the left side, the disk appears to have a giant solar storm raging. The star itself is 700 million miles in diameter according to estimates.

5) This fierce storm reaches about 233 million miles out into space, and is perhaps the largest solar storm ever observed.

6) It also effects 1/7th of the star's side facing the Earth, as the largest sunspot ever discovered, covering about 100 million miles of the star's surface diameter.

7) The star also has continuous extremely large solar storms covering the entire perimeter.

8) It appears the red giant has eight super storms going on at the same time, the highest number of super storms ever discovered at one time on any sun.

9) The main stellar disk of this sun appears to show extrapolated giant sections and regions of massive bubbling and boiling effects.

Wednesday, April 24, 2013

Star Trek New Voyages

NEW STAR TREK!
FREE VIEWING
OK, the fan movie was released a while back but we just discovered it. This new-to-us Star Trek series is posted on Youtube. Take a good break from all your hard work on science projects and watch this one hour show. You won't be disappointed seeing this great sci-fi space thriller! Check for more episodes at the main web site and Youtube.

4x03 Star Trek New Voyages: World Enough and Time
http://www.youtube.com/watch?v=l4TC5wl0IzE

Download here
http://www.startrekphase2.de/en/4x03_world_enough_and_time.html

Main web site
http://www.startreknewvoyages.com/

Guest Stars
George Takei as Hikaru Sulu
Christina Moses as Alana Sulu
Mimi Chong as Demora Sulu
Grace Lee Whitney as Janice Rand
Majel Barrett Roddenberry as The Computer Voice
Lia Johnson as Dr. Lisa Chandris


Plot  A Romulan weapons test goes awry and snares the Enterprise in an inter-dimensional trap. Lt. Commander Sulu returns to find himself 30 years out of place and the key to saving the crew of the Enterprise as the precarious grasp on their own dimension begins to slip.

Tuesday, April 23, 2013

Telescope Control System Bridge

Large bridge command center from JJ Abrams Star Trek film
TELESCOPE CONTROL SYSTEMS BRIDGE
Examples for the Power Dynamic Telescope
We're designing and building a telescope command and control center, and examining bridge console command systems from various sources for ideas. 

FIRST SOURCE
Telescope Control System Wrap Around

WHERE TO FIND BRIDGE EXAMPLES
The best examples of bridge control systems are found at the NASA command centers and various versions of Star Trek ships and vessels. These are larger control centers that take up more space, often occupying a room or a section of a wall. Operations may have designs for standing or seated occupancy.


JJ Abrams design
Floor to ceiling Vertical Bridge controls
VERTICAL PANELS
Vertical control panels are also popular. These displays are also adapted to virtual instruments with pieced together large touch screens. They often run floor to ceiling to take advantage of space.

NASA
NASA space station support operations
One example of a table and room command center is at NASA. The photo shows the NASA Flight Control System for the ISS International Space Station in 2006. It includes a series of tables, each with a computer control console for seated operations.

STAR SHIPS
Star ships, such as the Enterprise on Star Trek and many ship variations, have very well thought out and designed instrumentation control and command centers. Many of these bridges are designed for team operations and have multiple work stations. Some examples are for a science center, navigation, weapons console, stellar cartography, and sensors.

ADAPTABILITY
KELVIN Bridge (Star Trek)
These systems are very adaptable. For example, they include desk consoles for one or more work stations, vertical control panels for standing operations, and long strip control panels fit to walls in halls. Any of these may be telescope adapted, depending on the level of complexity and available space.

TOYS
Another place to look for various bridge designs is with toys. These often have compressed space
Bridge graphic
bridge designs which are especially useful when designing a command and control console with limited space in a small room.


GRAPHICS
Hallway control - Galaxy class Starship
There are many great visionaries drawing the graphics for space cartoons, space games, comic books and these hold fantastic designs. These are great sources for instrumentation control center designs and ideas.

EXTENDED RESOURCES
Also check other Star Trek movies, TV series, NASA sources for Skylab, Space Station, various Enterprise designs, science fiction, comics, toys, artwork, games, and galleries.

LINKS
Star Trek Blueprints
http://www.cygnus-x1.net/links/lcars/uss-enterprise-bridge.php

Federation Bridges
http://www.flickr.com/photos/fadmvulcan/sets/72157604354548317/detail/

Hi Res Control Panel & Bridge Images
http://www.gadgetreview.com/2013/04/hi-rez-pics-of-jj-abrams-star-trek-bridge.html