Mass
MRE recognizes that each mass object exist in a 3 position change cycle circulating lobe connections involving both past and future separate mass object events at the same moment. As such a single mass object A1’s change line as a z-axis of propagation has a predicted location and momentum separate from other mass objects’ respective change line with their version of past and future. Change Line Mechanics
Two atomic clocks were placed at a fixed vertical separation with respect to each other on earth’s surface. The cesium atom’s action parts position changes are derived mainly from the circulations with the earth’s mass objects. There is a one-foot vertical separation between the two clocks. The cesium atom changes to new positions where dominantly influenced by circulations with earth’s mass. The atomic clock at floor level had greater disruptive circulations from earth as lobe D3 interacting with lobe L1 of the atomic clock’s traveling cesium atoms during position changes. D3 disrupted L1 from the cesium atom that altered the return circulation lobe angle from the atomic clock’s radiation device circulating lobe L2 that was outside the cesium atom’s ground state photon absorption frequency energy range. MRE identifies the event as a dilation but does not have any mechanics that affected time and as such is not an example of time dilation. The further away from earth a stationary atomic clock has greater registry of higher energy ground state cesium atoms due to less disruptive D3 circulations from earth. Mass objects further away can still cause disruptive circulation events. But, dominantly there are less occurrences in the outer space vicinity of earth since there are fewer mass objects with D3 circulating lobes capable of rotating L1 and causing deviation between L1 to L2 for excessive energy transfers. As such the atomic clock’s cesium atom’s L1 circulation lobes would be redistributed to a variety of other separate mass objects. In this situation, the moon would have more position change circulations with the cesium clock further from earth. MRE Technology
Our organization provides mass internal mechanics technology to be utilized in a wide variety of applications. MRE describes the internal mechanics of existence where actions derive substance. MRE Technology is a growing organization with opportunities in a wide variety of scientific fields in need of advancements as well as inventions to be made in areas including communications, medicine, and energy conversions.Contact us
dgolden@mretechnology.com
Mass Size
Do mass objects have a fixed size in terms of perceiving spatial arrangements? Under the MRE circulation concept, the answer is no. The further away mass objects are from each other, the less circulations in common networks creating a constricted or squeezed effect where the mass object appears smaller due to the lower quantity of circulating connections between the separate mass objects. The further away mass objects are from each other there is a greater probability their circulation strength will be weaker because of less common network lobe connections. To be clear, the mass object has an overall assumed value of potential connections as described in the MRE Periodic Table. But for one mass object A1 interacting with a second A2, the size does involve the number of circulating interactions at a given instance. This can be understood with distant galaxies where earth detection equipment requires a long exposure and now with calibrations over a long period plus from various separate detectors to the extent that at a given instance only a small amount of light reaches an earth detector. But when combining multiple instances the size and resolution is increased. This is due to the number of circulating interactions at a given instance is smaller than viewed over an extended period of time.Mass Relationships
There are two types of mass relationships. One is with respect to mass objects that are not internally bound but circulate through common environment networks and the other is a single bound subatomic mass object A1’s parts changing to common new positions. A1’s positions are provided by other mass objects in common environment networks. Location relationships are derived from the amount of overall delay length between separate mass objects. A1’s parts cannot be measured independently since they are bound to common new positions. Each of A1’s circulating parts changes to new common positions with its other circulating parts in a sequential order. But, the position change of the sequence is not realized until A1’s parts are relocated to a new position. The mass object has an instant connection while interacting with other separate mass objects as delay lengths. Under this circumstance, a variety of apparent past and future circulation connectivity take place from a reference mass object’s perspective. Mdodulating Relative Entanglements (MRE)
The modulating relative entanglement (MRE) provides an approach that allows all objects to be described from band-pass and band-stop action filter configurations utilizing geometric action structures to explain mass object position changes within displaced circulation environment networks. The fundamental structure of the universe consists of mass objects changing to new positions with respect to other mass objects creating event dynamic relationships identified as energy. Events perceived as the past and future circulate with each other as potential position change differences developing seismic action structures perpetually changing states through storing and releasing kinetic actions from environment networks initiating new positions. This allows an infinite amount of events to be perceived from the perspective of a reference mass objects. 
Gardens of Europa
Mass
MRE recognizes that each mass object exist in a 3 position change cycle circulating lobe connections involving both past and future separate mass object events at the same moment. As such a single mass object A1’s change line as a z-axis of propagation has a predicted location and momentum separate from other mass objects’ respective change line with their version of past and future. Change Line Mechanics
Two atomic clocks were placed at a fixed vertical separation with respect to each other on earth’s surface. The cesium atom’s action parts position changes are derived mainly from the circulations with the earth’s mass objects. There is a one-foot vertical separation between the two clocks. The cesium atom changes to new positions where dominantly influenced by circulations with earth’s mass. The atomic clock at floor level had greater disruptive circulations from earth as lobe D3 interacting with lobe L1 of the atomic clock’s traveling cesium atoms during position changes. D3 disrupted L1 from the cesium atom that altered the return circulation lobe angle from the atomic clock’s radiation device circulating lobe L2 that was outside the cesium atom’s ground state photon absorption frequency energy range. MRE identifies the event as a dilation but does not have any mechanics that affected time and as such is not an example of time dilation. The further away from earth a stationary atomic clock has greater registry of higher energy ground state cesium atoms due to less disruptive D3 circulations from earth. Mass objects further away can still cause disruptive circulation events. But, dominantly there are less occurrences in the outer space vicinity of earth since there are fewer mass objects with D3 circulating lobes capable of rotating L1 and causing deviation between L1 to L2 for excessive energy transfers. As such the atomic clock’s cesium atom’s L1 circulation lobes would be redistributed to a variety of other separate mass objects. In this situation, the moon would have more position change circulations with the cesium clock further from earth. Mass Size
Do mass objects have a fixed size in terms of perceiving spatial arrangements? Under the MRE circulation concept, the answer is no. The further away mass objects are from each other, the less circulations in common networks creating a constricted or squeezed effect where the mass object appears smaller due to the lower quantity of circulating connections between the separate mass objects. The further away mass objects are from each other there is a greater probability their circulation strength will be weaker because of less common network lobe connections. To be clear, the mass object has an overall assumed value of potential connections as described in the MRE Periodic Table. But for one mass object A1 interacting with a second A2, the size does involve the number of circulating interactions at a given instance. This can be understood with distant galaxies where earth detection equipment requires a long exposure and now with calibrations over a long period plus from various separate detectors to the extent that at a given instance only a small amount of light reaches an earth detector. But when combining multiple instances the size and resolution is increased. This is due to the number of circulating interactions at a given instance is smaller than viewed over an extended period of time.Mass Relationships
There are two types of mass relationships. One is with respect to mass objects that are not internally bound but circulate through common environment networks and the other is a single bound subatomic mass object A1’s parts changing to common new positions. A1’s positions are provided by other mass objects in common environment networks. Location relationships are derived from the amount of overall delay length between separate mass objects. A1’s parts cannot be measured independently since they are bound to common new positions. Each of A1’s circulating parts changes to new common positions with its other circulating parts in a sequential order. But, the position change of the sequence is not realized until A1’s parts are relocated to a new position. The mass object has an instant connection while interacting with other separate mass objects as delay lengths. Under this circumstance, a variety of apparent past and future circulation connectivity take place from a reference mass object’s perspective. Modulating Relative Entanglement
Text Book and Videos Supporting MRE Technology for Inventors, Education, Medical, and Space Exploration.Contact us
dgolden@mretechnology.com
Mdodulating
Relative
Entanglements
(MRE)
The modulating relative entanglement (MRE) provides an approach that allows all objects to be described from band-pass and band-stop action filter configurations utilizing geometric action structures to explain mass object position changes within displaced circulation environment networks. The fundamental structure of the universe consists of mass objects changing to new positions with respect to other mass objects creating event dynamic relationships identified as energy. Events perceived as the past and future circulate with each other as potential position change differences developing seismic action structures perpetually changing states through storing and releasing kinetic actions from environment networks initiating new positions. This allows an infinite amount of events to be perceived from the perspective of a reference mass objects. 
Gardens of Europa
MRE YouTube Channel
