DEF0208canonicalv1E₁ Layer (Physics)
E₁ = (H_τ-enriched objects, sector admissibility via 4+1 decomposition, spectral projection onto sectors, sector couplings as canonical lifts of ι_τ). Domain: Books IV-V. Physics as enrichment.
Payload
E₁ Layer (Physics)
E₁ = (H_τ-enriched objects, sector admissibility via 4+1 decomposition, spectral projection onto sectors, sector couplings as canonical lifts of ι_τ). Domain: Books IV-V. Physics as enrichment.
E₁ Layer (Physics)
Summary
E₁ = (H_τ-enriched objects, sector admissibility via 4+1 decomposition, spectral projection onto sectors, sector couplings as canonical lifts of ι_τ). Domain: Books IV-V. Physics as enrichment.
Statement
%
\label{def:e1-layer}
$\Estage{1}$ denotes Category~$\T$
equipped with the self-enrichment data
earned in Part~VIII.
Explicitly, $\Estage{1}$ adds to~$\Estage{0}$
the following structures:
\begin{enumerate}
\item \textbf{Hom objects as $\T$-objects.}
For all $A, B \in \Obj(\T)$,
the morphism space $\Hom(A,B) \in \Obj(\T)$
(II.D53, II.D54,
Chapter~\ref{ch:tau-self-enrichment}).
Each Hom object has an NF address,
inherits bipolar decomposition,
and satisfies tower coherence.
\item \textbf{The Yoneda embedding.}
$\T \hookrightarrow [\T^{\op}, \T]$
is a full and faithful functor
(II.T36,
Chapter~\ref{ch:yoneda-theorem}).
This makes every $\T$-object
representable by the morphisms into it.
\item \textbf{2-categorical structure.}
2-morphisms
$\Hom(\Hom(A,B), \Hom(C,D))$
are $\T$-objects
(II.D55, II.D56,
Chapter~\ref{ch:two-categories}).
Morphisms between morphisms
are first-class citizens.
\item \textbf{Internal function spaces.}
The internal Hom
$[A,B] \in \Obj(\T)$
replaces the external function set
$\{f \colon A \to B\}$.
Function spaces are objects,
not meta-level collections.
\item \textbf{The Code/Decode bijection.}
$\mathrm{Code} \colon \mathcal{O}(\tau^3)
\to \mathrm{Streams}(R_\tau, H_\tau)$
and its inverse $\mathrm{Decode}$
(II.T35,
Chapter~\ref{ch:code-decode})
internalize the Mutual Determination
as a coding-theoretic bijection.
\item \textbf{Self-referential capability.}
$\T$ can talk about its own morphisms,
compare them,
and transform them---all
within its own language
(Remark~\ref{rem:self-description}, II.R15).
\end{enumerate}
\noindent
The transition $\Estage{0} \to \Estage{1}$
is what Part~VIII accomplishes.
$\Estage{1}$ is not a different category;
it is the \emph{same} category~$\T$,
now recognized as carrying self-enrichment structure
that was latent in $\Estage{0}$
but not yet articulated.
Proof / Justification
This item is definitional. No manuscript proof is required.
Source Context
- Registry source:
book-03.jsonlline 12 - Manuscript source:
2nd-edition/book-ii-categorical-holomorphy/02_mainmatter/part08/ch45-self-describing.texlines 571-639
Lean / Formalization Notes
- Formalization:
formalized - Module:
TauLib.BookIII.Enrichment.LayerTemplate - Name:
e1_layer_book3
Dependencies
- Canonical: III.D05, III.D06
Related Results
Generated by later projection phases.
Related Publications
Generated by later projection phases.
Revision Notes
- 2026-04-24: Initial pilot migration.
Identifiers
Aliases & legacy IDs
III.D07e-layer-physicsRelease lines
corpus_v3_workingcorpus_v2Relations
Formalized by (1)
Appears in (1)
Downstream uses (computed) (2)
Items in the corpus that reference this one via load-bearing relations. Computed from the full corpus-v3 graph at build time.
Sources
Version & History
Status disclaimer
A Corpus Item page reports the program's current internal record for this item. It does not imply external verification, scientific consensus, or final proof unless explicitly stated. Read it together with its dependencies, formalization status, and the program's overall stance.