Showing posts with label Project 501. Show all posts
Showing posts with label Project 501. Show all posts
Sunday, May 19, 2019
Sunday, May 5, 2019
Friday, November 9, 2018
Saturday, June 6, 2015
Project 501 Urgent Status Update
Due to current HVBN instability and proximity of omega
convergence point, an update is required.
Beta protocol: maintain LEVSF pivot, JEJ/LJVTX/P501, SWA CZC MND PIE PRM SRD BOS URF.
Request urgent modulation of S2EXT protocol.
Beta protocol: maintain LEVSF pivot, JEJ/LJVTX/P501, SWA CZC MND PIE PRM SRD BOS URF.
Request urgent modulation of S2EXT protocol.
Sunday, May 4, 2014
Project 501 Update
Alpha
timeline with HVBN until intersection has an increasing probability of p=0.9. Alternative
beta timeline with sporadic YXRs, converging into possible LEVSF pivoting to next
HVBN before intersection, has a decreasing probability of p=0.1 due to
increased grid ratio.
Beta
strategies have been modulated.
Intersection
probability peak comes close to omega convergence point with an antarionid RM
intersection which includes P501 and all hyperphasic intersections in the
optimal sequence order. Alpha and beta timelines converge into one as we limit
towards the omega convergence point.
Saturday, October 5, 2013
Project 501 Update
Alpha timeline with HVBN until intersection has a probability of p=0.8. The alternative beta timeline with multiple MVBNs, converging into possible next HVBN before intersection has a probability of p=0.2.
Beta strategies have been modulated and need to remain strictly classified.
There are two major intersection probability peaks remaining.
The previous intersection probability peak within RR2-3 intermediate period has collapsed due to incomplete intel about L1 and L0 anomaly.
The first major intersection probability peak comes shortly after the beginning of the RR3-4 intermediate period, p=0.3. Alpha timeline is partially classified P501 with gradual to fast M increase and with probability of some form of EL contact. This leads to complex interference with existing HVBN on the surface, multiple MVBNs being one triangulation alternative and time compression into the convergence point being another one. Shortly before the omega convergence point this timeline anyway converges into an antarionid RM intersection. Beta timeline comes with declassified P501 with multiple MVBNs and then with RM intersections as soon as possible.
The second major intersection probability peak comes close to omega convergence point with an antarionid RM intersection, p=0.7. Alpha and beta timelines converge into one as we limit towards the omega convergence point.
Beta strategies have been modulated and need to remain strictly classified.
There are two major intersection probability peaks remaining.
The previous intersection probability peak within RR2-3 intermediate period has collapsed due to incomplete intel about L1 and L0 anomaly.
The first major intersection probability peak comes shortly after the beginning of the RR3-4 intermediate period, p=0.3. Alpha timeline is partially classified P501 with gradual to fast M increase and with probability of some form of EL contact. This leads to complex interference with existing HVBN on the surface, multiple MVBNs being one triangulation alternative and time compression into the convergence point being another one. Shortly before the omega convergence point this timeline anyway converges into an antarionid RM intersection. Beta timeline comes with declassified P501 with multiple MVBNs and then with RM intersections as soon as possible.
The second major intersection probability peak comes close to omega convergence point with an antarionid RM intersection, p=0.7. Alpha and beta timelines converge into one as we limit towards the omega convergence point.
Wednesday, June 26, 2013
Project 501 Report
Alpha timeline with HVBN until intersection has an increasing probability of p=0.6. The alternative beta
timeline with sporadic YXRs, converging into possible next HVBN before
intersection has a decreasing probability of p=0.4 due to increased grid ratio.
Beta strategies have not yet been
modulated and will come in a separate report.
There are three major
intersection probability peaks.
The first one comes within the
first half of the RR2-3 intermediate period, p=0.3. Alpha timeline is
classified P501 with gradual M increase but without any hyperphasic
intersections. Hyperphasic intersections come in cascading convergence only as
we limit towards the omega convergence point. Beta timeline comes with declassified
P501 with RM intersections as soon as possible.
There is a minor peak towards the
end of RR2-3 period which coincides with L2 penetration point.
The second major intersection
probability peak comes shortly after the beginning of the RR3-4 intermediate
period, p=0.3. Alpha timeline is partially classified P501 with gradual to fast
M increase and with probability of some form of EL contact. This leads to
complex interference with existing HVBN on the surface. Some time before the
omega convergence point this timeline bifurcates into fast hyperphasic
intersections. Beta timeline again comes with declassified P501 with RM
intersections as soon as possible.
The third major intersection
probability peak comes close to omega convergence point with an antarionid RM
intersection which includes P501 and all hyperphasic intersections in the
optimal sequence order, p=0.4. Alpha and beta timelines converge into one as we
limit towards the omega convergence point.
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