Category Archives: m. Monitoring methods

Determine how the sensors will be monitored.


Wilkinson Microwave Anisotropy Probe

Isaiah 40:25  “To whom will you compare Me, or who is My equal?” asks the Holy One. 26  Lift up your eyes on high: Who created all these? He leads forth the starry host by number; He calls each one by name. Because of His great power and mighty strength, not one of them is missing.

#FallingBodies #GravityTest #DEW
Cosmic Background Image Model

#BigBang #CMB #HorizonProblem #Mandalas

Image of the #EntireSky #AboveEarth

Isotropy in the Cosmic Background

Apart from the small fluctuations discussed above (one part in 100,000), the observed cosmic microwave background radiation exhibits a high degree of Isotropy, a zeroth order fact that presents both satisfaction and difficulty for a comprehensive theory.

Anisotropy, in physics, the quality of exhibiting properties with different values when measured along axes in different directions.

Should we correct the name to WMIP?

#BigBang #CMB #HorizonProblem #Mandalas

Hammer-Aitoff projection

#NASA  Explains

Charles L. Bennett, Principal Investigator

WMAP – Fundamental Measurements of Cosmology

WMAP – Universe 101

WMWP – Results

Inflation (cosmology)

Big Bang – “Theory”


Possible space curvatures of the universe: Closed, Flat, Open

1.  Horizon Problem:

2.  Flatness Problem:

3.  Magnetic-Monopole Problem:

4.  Etc. Problems:

of the is as .

How’s  at the   after ?

#BigBang #CMB #HorizonProblem #Mandalas

#BigBang #CMB #HorizonProblem #Mandalas

#BigBang #CMB #HorizonProblem #Mandalas

WMAP – Cosmological Parameters

#BigBang #CMB #HorizonProblem #Mandalas

#BigBang #CMB #HorizonProblem #Mandalas

#BigBang #CMB #HorizonProblem #Mandalas

Cosmic Microwave Background Explained | Space Time | PBS Digital Studios

How Do You Measure the Size of the Universe? | Space Time | PBS Digital Studios

How Big is the Observable Universe: “Well, it’s a Sphere with the radius of about 46 Billion LightYears . . . ”

#BigBang #CMB #HorizonProblem #Mandalas

“How do they know . . .  In a #NutShell – You start with the age of the universe, current estimate is about 13.8 years, and then . . . ”


Psalm 123:1  A Song of Ascents. I lift up my eyes to You, the One enthroned in heaven. 2  As the eyes of servants look to the hand of their master, as the eyes of a maidservant look to the hand of her mistress, so our eyes are on the LORD our God until He shows us mercy.

Free-Fall Camera

Eye on It!

Will Not Quit!

Philippians 3:14  I press on toward the goal to win the prize of God’s heavenly calling in Christ Jesus.

#DEW, #DiamondAgeofArchitecture, #EdgeofSpace, #FallingBodies, #GravityRevolution, #GravityTest, #STEAM



National Aeronautics and Space Administration Synchronized Position Hold, Engage, Reorient, Experimental Satellites (N.A.S.A.S.P.H.E.R.E.S. )

Edge of Space Falling Bodies Gravity Test


One small step …

#DEW, #DiamondAgeofArchitecture, #EdgeofSpace, #Fallingbodies, #GravityRevolution, #GravityTest, #STEAM



Ezekiel 1:18  As for their rims they were lofty and awesome, and the rims of all four of them were full of eyes round about.



As Felix appears to reach his Terminal Velocity of approximately 729 mph at (T: +50 secs) and begins “Violently Spinning”, the camera switches to show mission control for 9 seconds until (T: +59 secs), while the Spinning continues for another 20 seconds once the camera switches back to Felix.  Amazing Stamina!

Additional Video and Data

Felix’s World Records:

Exit Altitude: 128,100 feet

Free Fall Drop Distance: 119,846 feet

Free Fall Time: 4 minutes, 20 seconds

Maximum Velocity: 833.4 miles per hour (Mach 1.2)!



“Objects with High Magnetic Permeability will Accelerate Slower.”


Falling Bodies due to Earth’s Gravitational Motion will Accelerate until they reach their Terminal Velocity and then begin to Spin, creating a Charge as they pass through Earth’s Magnetic FieldObjects with higher Magnetic Permeability will become Magnetized, spin faster, and fall slower than objects with lower Magnetic Permeability.


1. AISI 1006 Carbon Steel (UNS G10060): (high permeability)           10 cm diameter (hollowed to be 1.0 kg, equal to other spheres)

2. Alloy Steel 52100 (UNS G52986): (not as high permeability)         10 cm diameter (hollowed to be 1.0 kg, equal to other spheres)

3. Aluminum Bronze (UNS C95400): (low permeability)                         10 cm diameter (hollowed to be 1.0 kg, equal to other spheres)

4. Titanium – Ti (UNS R50250): (zero permeability)                                        10 cm diameter (hollowed to be 1.0 kg, equal to other spheres)


High Altitude Balloon – To Be Determined …


  1.  Deploy a High Altitude Balloon to the Edge of Space and Elevate 4 Metallic Spheres each having the same Outside Diameter (10 cm), Surface Texture (Smooth Reflective) and Mass (1 kg) with the only differences between them being a variation in their Checker Pattern Color and their Magnetic Permeability (Ranging from High to Zero).
  2. Simultaneously release the 4 Metallic Spheres using a Barometric Pressure Sensor and then High Speed Video Record the Visual Effects of Gravitational Motion and other Natural Forces (Air Resistance, Electromagnetism) acting upon their Free-Fall Motion.
  3. Utilize High Zoom Lens Cameras to Video Capture (Including Infrared) their Rates of Acceleration, Times they reach Terminal Velocity, Times they begin to Spin, Axis of their Spin Rotations, Rates of Spin, and their Times to Impact the Ground.
  4. Measure their Separations after Impact and any Residual Levels of Acquired Magnetism.



Work in Progress …