Compound Fork — $1T+ IPO × Energy / grid
Each cell = a joint scenario "Both branches fire". Cell intensity = total |Δ| across the 200 highest-conviction tradeable predictions vs their unconditional posterior. Joint probabilities approximated via log-odds combination (assumes conditional independence given the prediction — coarse but bounded). Click a cell to drill into the dominant single-fork view.
Pick two fork families
| $1T+ IPO ↓ × Energy / grid → | GRID_50GW_2027 prior 40% | GRID_50GW_2029 prior 50% | GRID_50GW_DELAYED prior 10% |
|---|---|---|---|
IPO_TRILLION_2026 prior 25% | 122 claims · Σ|Δ| 15.09 | 125 claims · Σ|Δ| 15.25 | 124 claims · Σ|Δ| 15.23 |
IPO_TRILLION_2027 prior 40% | 123 claims · Σ|Δ| 15.23 | 124 claims · Σ|Δ| 15.29 | 124 claims · Σ|Δ| 15.32 |
IPO_TRILLION_2028 prior 25% | 123 claims · Σ|Δ| 15.29 | 124 claims · Σ|Δ| 15.35 | 124 claims · Σ|Δ| 15.38 |
IPO_TRILLION_NONE_5Y prior 10% | 123 claims · Σ|Δ| 15.39 | 124 claims · Σ|Δ| 15.46 | 124 claims · Σ|Δ| 15.49 |
Method note
Joint conditional probability is approximated via log-odds combination: logit(P(pred|A,B)) ≈ logit(P(pred|A)) + logit(P(pred|B)) − logit(P(pred)). This is the closed-form Bayesian update assuming A and B are conditionally independent given the prediction. It's correct when the two scenarios act on the prediction through different causal paths; it's pessimistic when they overlap. The exact joint requires running the Gibbs sampler with both scenarios clamped, which would be N×M=16 sampling runs (~12 minutes per refresh) instead of N+M=8 — a 2× cost for higher fidelity.