アルファ時間軸とHVBNの交差までの可能性はp=0.8。代替えのベータ時間軸と複数のMVBNが交差する前に次のHVBNに収束する可能性はp=0.2。
ベータ戦略は調整され、要機密厳守。
2つの大きな交差確率のピークが残存。
前回のRR2-3中間期にあった交差の可能性ピークは、L1とL0の異常について情報不十分のため、失敗。
最初の大きな交差確率のピークはRR3-4中間期の始まってすぐ後、p=0.3で発生。アルファ時間軸は部分的機密P501であり、いくつかのELコンタクトの形をとる可能性のあるMの緩やかから早くなる上昇を伴う。こちらは既存の地表のHVBNへの複雑な介入となり、複数のMVBNは一つの三角分割に取って代わり、収束点への時間圧縮が別のものになる。オメガ収束点への直前で、アンタリオンRM交差点にどうにか収束。ベータ時間軸は機密解除されたP501と複数のMVBNを伴って訪れる。そしてRM交差点は可能な限り迅速に。
二つ目の大きな交差可能性ピークはアンタリオンRM交差点と共にp=0.7でオメガ収束点へ接近。アルファとベータ時間軸は、オメガ収束点へ限定して向かうことから、一つに収束します。
翻訳: NOGI
(原文)
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.