Lambda-Flight v1.1: Operational and Latent Coherence Transport Models
Reading status
Current statement
FRC 787.787 v1.1 separates three objects previously called Lambda. Lambda_obs=Lambda0 ln C_obs is an operational transform of preregistered observables; Lambda_eq is an observation-derived target; Lambda_dyn is an optional latent reaction-diffusion state that relaxes toward that target. A transport model must select Lambda_obs or separately validated Lambda_dyn before scoring. Support for Lambda_dyn requires improvement over the observation-only model and an equal-feature non-Lambda latent baseline. Even successful residual prediction would not establish a fundamental field. The nested baselines, negative controls, six test cards, and numerical regime pilot are retained. The pilot calibrates a chosen PDE and does not validate a physical Lambda-Flight mechanism.
Evidence level
Pilot-supported program
preprint
Declared μ register
μ4 · Logical / conceptual
Logic, formal models, language as explicit reasoning, and computational design.
Open boundary
Independent platform validation and wins over equal-feature baselines remain required.
Version lineage
Supersedes: FRC 787.787 v1.0 (DOI 10.5281/zenodo.21266620)
On this page
FRC 787.787 v1.1 separates three objects previously called Lambda. Lambda_obs=Lambda0 ln C_obs is an operational transform of preregistered observables; Lambda_eq is an observation-derived target; Lambda_dyn is an optional latent reaction-diffusion state that relaxes toward that target. A transport model must select Lambda_obs or separately validated Lambda_dyn before scoring. Support for Lambda_dyn requires improvement over the observation-only model and an equal-feature non-Lambda latent baseline. Even successful residual prediction would not establish a fundamental field. The nested baselines, negative controls, six test cards, and numerical regime pilot are retained. The pilot calibrates a chosen PDE and does not validate a physical Lambda-Flight mechanism.
