A FINITE UNIVERSE
Appendix sections
A1A2A3A4A5A6A7A8A9A10A11A12A13A14A15A16A17A18A19

Appendix

Quantitative Appendix

Finite-Boundary Redshift-Distance Framework

Plain-language companion: For a plain-language orientation before the calculations, see What the book is really asking and When rulers stop agreeing.

This appendix collects the equations, variables, fitted forms, diagnostic quantities, and replication steps used in the finite-boundary redshift-distance analysis. The purpose is reproducibility: a reader should be able to follow the calculation sequence from redshift data through finite-response coordinates, BAO/CMB diagnostics, projection targets, and register-scaling constants.

A1. Purpose, inputs, and notation

Calculation purpose: define the minimum data inputs, numerical settings, and fitting conventions needed to reproduce the diagnostic calculations.

All distance-dependent calculations require one consistent distance coordinate. If the plotted coordinate is \(d/1000\,\mathrm{Mpc}\), then \(d_b\) uses the same scaled unit and \(g_0\) uses the reciprocal unit. Dimensionless combinations such as \(g_0d_b\), \(A\), \(X\), and \(\chi\) are unchanged when the unit conversion is handled consistently.

Table A1-1. Minimum data inputs.

ProbeRequired quantitiesUsed for
Type Ia supernovae\(z\), distance modulus or distance coordinate \(d\), uncertainties where availableA2-A8 response fits, residuals, stability diagnostics
Supernova sky sectors\(z\), \(d\), right ascension, declinationA9 directional partitioning
BAO standard-ruler dataredshift, observable type \(D_M/r_d\), \(D_H/r_d\), or \(D_V/r_d\), value, uncertaintyA10, A14-A17 ruler diagnostics
Cosmic chronometersredshift, \(H(z)\), uncertainty, method groupA11 derivative-shape comparison
Time-dilation constraintspublished exponent \(b\), uncertainty, redshift range, object classA12 arrival-time constraint
Compressed CMB priors\(R\), \(\ell_A\), \(\omega_bh^2\), covariance matrix, \(z_*\)A13-A17 CMB and projection diagnostics
Register-scaling tests\(D=AG\), \(X=A/A_t\), \(\eta=g_{\mathrm{bar}}/g^\dagger\)A19 scaling constants and response-engine weighting

Table A1-2. Numerical settings.

SettingRepresentative value or ruleControls
Train/test split0.80 training fractionheld-out RMSE and overfit gap
Stability stressminimum rows per window 80; multiple upper-redshift windows; training fractions 0.7, 0.8, 0.9spread in \(d_b\) and finite-boundary win rate
BAO rangemaximum BAO redshift about 2.3; Ly\(\alpha\) points included where statedBAO shape comparison
Chronometer filtermaximum redshift about 1.97; locked \(d_b\approx2.04\) where statedderivative-shape comparison
CMB prior\(z_*\approx1089.92\); covariance-weighted compressed-prior statisticCMB distance-prior diagnostic
Shared-ruler testone common calibration scale \(S\) for BAO and CMB termsshared-ruler failure statistic
Separate-scale testindependent \(S_{\mathrm{BAO}}\) and \(S_{\mathrm{CMB}}\)CMB-to-BAO scale ratio
Projection targetpreserve BAO range while reaching the CMB-side compressed scalesharp transition and preferred projection law

Fitting convention

For one-parameter scale fits of the form \(Y_i=S F_i\), the diagnostic scale is selected by weighted least squares:

\[\chi^2(S)=\sum_i\left(\frac{Y_i-SF_i}{\sigma_i}\right)^2 \tag{A1.1}\]

When the prediction is linear in \(S\), the equivalent analytic solution is:

\[S=\frac{\sum_i Y_iF_i/\sigma_i^2}{\sum_i F_i^2/\sigma_i^2}. \tag{A1.2}\]

For mixed BAO/CMB tests where compressed CMB priors introduce covariance terms, the same principle is used, but the total objective may be evaluated by one-dimensional numerical minimization over the shared or separate scale.

Table A1-3. Master glossary.

SymbolMeaningStatus
\(z\)observed redshiftdimensionless direct observable
\(d\)supplied distance coordinate used in supernova fittingMpc or scaled Mpc
\(A=\ln(1+z)\)accumulated path responsedimensionless
\(G(d)\)local response rateinverse distance
\(g_0\)near-origin response-rate scaleinverse distance
\(d_b\)finite-boundary distance scalesame units as \(d\)
\(p=g_0d_b\)dimensionless accumulated-response exponentdimensionless
\(x(z)\)inverted finite-boundary distance coordinatesame units as \(d_b\)
\(x\prime(z)\)derivative of model coordinate with respect to redshiftdistance per redshift
\(S\)nuisance calibration scalemaps model coordinate into BAO/CMB ratio units
\(S_{\mathrm{BAO}},S_{\mathrm{CMB}}\)separate effective calibration scalesdiagnostic scales
\(T(z),P_\star(z)\)projection factorsdimensionless
\(D=AG\)raw morphology response coordinatedimensionless times inverse distance, normalized before engine use
\(D_n=D/D_0\)normalized morphology responsedimensionless
\(X=A/A_t\)normalized projection coordinatedimensionless
\(\eta=g_{\mathrm{bar}}/g^\dagger\)weak-field compliance coordinatedimensionless
\(u=2GM/(Rc^2)\)compactness coordinatedimensionless
\(K_D,K_X,K_\eta,K_u\)register-scaling constants and compactness working exponentdimensionless

Table A1-4. Calculation map.

SectionCalculationPrimary output
A2redshift-to-response transform\(A(d)=\ln(1+z)\)
A3empirical redshift-distance formsfit parameters and residuals
A4candidate accumulated-response lawscandidate \(A(d)\) and \(G(d)\) forms
A5finite-boundary local-response law\(G(d)\), \(A(d)\), \(z(d)\)
A6inverted model coordinate\(x(z)\), \(x\prime(z)\)
A7fit statisticsRMSE, \(\chi^2\), AIC, BIC
A8stability diagnosticsoverfit gap and \(d_b\) spread
A9directional partitioningsector-specific \(d_b\) values
A10BAO standard-ruler shapeBAO ratio predictions and \(\chi^2_{\mathrm{BAO}}\)
A11chronometer derivative shapecalibrated derivative comparison
A12time-dilation exponentconstraint on \(b\)
A13compressed CMB priors\(\chi^2_{\mathrm{CMB}}\)
A14joint BAO+CMB shared rulershared-scale statistic
A15separate BAO/CMB scales\(S_{\mathrm{CMB}}/S_{\mathrm{BAO}}\)
A16redshift-dependent projectioncandidate \(T(z)\) behavior
A17sharp transition and preferred projectionBAO preservation plus CMB/JWST target behavior
A18replication chainend-to-end calculation sequence
A19unified registers and scaling constants\(C(X,\eta,u,D_n)\) and \(K\) values

A2. Accumulated redshift response

Calculation purpose: transform observed redshift into accumulated path response and define the local response derivative.

Inputs are observed redshift \(z\) and the distance coordinate \(d\). The transformation below is independent of the later choice of local response law.

\[A(d)=\ln(1+z) \tag{A2.1}\]
\[1+z=e^{A(d)} \tag{A2.2}\]
\[z(d)=e^{A(d)}-1 \tag{A2.3}\]

The path-response interpretation treats \(A(d)\) as the integral of a local response rate along the signal path:

\[A(d)=\int_0^d G(s)\,ds \tag{A2.4}\]
\[G(d)=\frac{dA}{dd}. \tag{A2.5}\]

If \(d\) is measured in Mpc, then \(G(d)\) has units of Mpc\(^{-1}\). The product \(G(s)ds\) is dimensionless.

A3. Empirical redshift-distance forms

Calculation purpose: fit compact empirical redshift-distance curves before interpreting the result as accumulated response.

Inputs are supernova redshift and distance coordinate. Outputs are fitted curve parameters, predicted redshifts, residuals, and ranking statistics. These forms are empirical fits, not dynamical derivations.

\[z_{\mathrm{lin}}(d)=a d \tag{A3.1}\]
\[z_{\exp}(d)=e^{a d}-1 \tag{A3.2}\]
\[z_{\mathrm{pow}}(d)=(1+a d)^n-1 \tag{A3.3}\]
\[z_{\mathrm{quad}}(d)=a d+b d^2 \tag{A3.4}\]

A flat \(\Lambda\)CDM luminosity-distance reference is written schematically as:

\[d_L(z;H_0,\Omega_m)=\frac{c(1+z)}{H_0}\int_0^z \frac{du}{\sqrt{\Omega_m(1+u)^3+1-\Omega_m}}. \tag{A3.5}\]

Here \(a\), \(b\), and \(n\) are fitted empirical parameters; \(u\) is a dummy integration variable.

Table A3-1. Representative direct-fit performance.

Model formRepresentative RMSE
Power-law form0.0213
Linear Hubble form0.0488
Quadratic proxy0.0709
Exponential form0.1303

Minimal recipe: read \(z,d\); fit Equations (A3.1)-(A3.4); compute predicted redshifts and residuals using A7; rank by RMSE, AIC, BIC, and residual structure.

A4. Candidate accumulated-response laws

Calculation purpose: compare candidate forms for \(A(d)\) and their implied local response rates \(G(d)\).

Constant accumulation

\[A(d)=kd \tag{A4.1}\]
\[G(d)=k \tag{A4.2}\]

Quadratic deformation

\[A(d)=kd+\beta d^2 \tag{A4.3}\]
\[G(d)=k+2\beta d \tag{A4.4}\]

Logarithmic power-law shadow

\[A(d)=n\ln(1+a d) \tag{A4.5}\]
\[G(d)=\frac{na}{1+a d} \tag{A4.6}\]

Equations (A4.5)-(A4.6) bridge the empirical power-law fit and the finite-boundary interpretation: accumulated response grows logarithmically while the local rate declines with distance.

Cubic deformation

\[A(d)=kd+\beta d^2+\gamma d^3 \tag{A4.7}\]
\[G(d)=k+2\beta d+3\gamma d^2. \tag{A4.8}\]

Inputs are \(d\) and \(A(d)\) from A2. Fit each candidate response law, differentiate to obtain \(G(d)\), and compare residual structure.

A5. Finite-boundary local-response law

Calculation purpose: define the finite-boundary local-response law, integrate it, and recover \(z(d)\).

\[G(d)=\frac{g_0}{1+d/d_b} \tag{A5.1}\]
\[G(d)=\frac{g_0d_b}{d_b+d} \tag{A5.2}\]

\(g_0\) is the near-origin response-rate scale and \(d_b\) is the finite-boundary distance scale. If \(d\) and \(d_b\) are in Mpc, then \(g_0\) is in Mpc\(^{-1}\).

\[A(d)=\int_0^d \frac{g_0}{1+s/d_b}\,ds \tag{A5.3}\]
\[A(d)=g_0d_b\int_1^{1+d/d_b}\frac{du}{u} \tag{A5.4}\]
\[A(d)=g_0d_b\ln\!\left(1+\frac{d}{d_b}\right) \tag{A5.5}\]
\[z(d)=\exp\!\left[g_0d_b\ln\!\left(1+\frac{d}{d_b}\right)\right]-1 \tag{A5.6}\]
\[z(d)=\left(1+\frac{d}{d_b}\right)^{g_0d_b}-1. \tag{A5.7}\]

The dimensionless product \(g_0d_b\) controls the curvature of the redshift-distance relation.

A6. Inverted distance-redshift coordinate

Calculation purpose: invert the finite-boundary redshift relation to obtain \(x(z)\) and \(x\prime(z)\).

\[1+z=\left(1+\frac{d}{d_b}\right)^{g_0d_b} \tag{A6.1}\]
\[(1+z)^{1/(g_0d_b)}=1+\frac{d}{d_b} \tag{A6.2}\]
\[x(z)=d_b\left[(1+z)^{1/(g_0d_b)}-1\right] \tag{A6.3}\]
\[x'(z)=\frac{dx}{dz}=\frac{1}{g_0}(1+z)^{1/(g_0d_b)-1}. \tag{A6.4}\]

\(x(z)\) is a model coordinate, not automatically a physical BAO or CMB distance. BAO and CMB comparisons require a calibration scale such as \(S\).

A7. Fit residuals and model-ranking quantities

Calculation purpose: compute residuals, goodness-of-fit quantities, and information criteria.

\[r_i=y_i-\widehat{y}_i \tag{A7.1}\]
\[\mathrm{RMSE}=\sqrt{\frac{1}{n_{\mathrm{data}}}\sum_{i=1}^{n_{\mathrm{data}}}r_i^2} \tag{A7.2}\]
\[\chi^2=\sum_{i=1}^{n_{\mathrm{data}}}\left(\frac{y_i-\widehat{y}_i}{\sigma_i}\right)^2 \tag{A7.3}\]
\[\chi^2_\nu=\frac{\chi^2}{n_{\mathrm{data}}-k_{\mathrm{par}}} \tag{A7.4}\]
\[\mathrm{RSS}=\sum_{i=1}^{n_{\mathrm{data}}}r_i^2 \tag{A7.5}\]
\[\mathrm{AIC}=2k_{\mathrm{par}}+n_{\mathrm{data}}\ln\!\left(\frac{\mathrm{RSS}}{n_{\mathrm{data}}}\right) \tag{A7.6}\]
\[\mathrm{BIC}=k_{\mathrm{par}}\ln(n_{\mathrm{data}})+n_{\mathrm{data}}\ln\!\left(\frac{\mathrm{RSS}}{n_{\mathrm{data}}}\right). \tag{A7.7}\]

Inputs are observed values, predicted values, optional uncertainties, and parameter counts. Outputs are residuals, RMSE, chi-square statistics, AIC, and BIC.

A8. Cross-validation and stability diagnostics

Calculation purpose: test prediction error and boundary-scale stability under split or redshift-window changes.

\[\mathrm{RMSE}_{\mathrm{train}}=\sqrt{\frac{1}{n_{\mathrm{train}}}\sum_{i\in\mathrm{train}}r_i^2} \tag{A8.1}\]
\[\mathrm{RMSE}_{\mathrm{test}}=\sqrt{\frac{1}{n_{\mathrm{test}}}\sum_{i\in\mathrm{test}}r_i^2} \tag{A8.2}\]
\[\Delta_{\mathrm{overfit}}=\mathrm{RMSE}_{\mathrm{test}}-\mathrm{RMSE}_{\mathrm{train}} \tag{A8.3}\]
\[\{d_{b,1},d_{b,2},\ldots,d_{b,N}\} \tag{A8.4}\]
\[\widetilde{d}_b=\mathrm{median}(d_{b,j}) \tag{A8.5}\]
\[\mathrm{CV}_{d_b}=\frac{\sigma(d_{b,j})}{\mu(d_{b,j})}. \tag{A8.6}\]

Representative stability values include median \(d_b\approx1.57\), coefficient of variation \(\approx0.26\), and finite-boundary win rate \(\approx97.6\%\).

A9. Directional partitioning

Calculation purpose: fit the same finite-boundary accumulated-response law independently by sky sector.

\[A_j(d)=g_{0,j}d_{b,j}\ln\!\left(1+\frac{d}{d_{b,j}}\right) \tag{A9.1}\]
\[\mu_{d_b}=\frac{1}{N}\sum_{j=1}^N d_{b,j} \tag{A9.2}\]
\[\mathrm{CV}_{d_b}=\frac{\sqrt{\frac{1}{N-1}\sum_{j=1}^N(d_{b,j}-\mu_{d_b})^2}}{\mu_{d_b}}. \tag{A9.3}\]

Representative right-ascension-slice values are mean \(d_b\approx2.25\), coefficient of variation \(\approx0.077\), and max/min \(\approx1.23\).

A10. BAO standard-ruler diagnostics

Calculation purpose: compare BAO standard-ruler ratios against finite-boundary shape predictions.

The BAO comparison uses dimensionless standard-ruler ratios:

\[\frac{D_M(z)}{r_d} \tag{A10.1}\]
\[\frac{D_H(z)}{r_d} \tag{A10.2}\]
\[\frac{D_V(z)}{r_d}. \tag{A10.3}\]

Using a nuisance calibration scale \(S\), the diagnostic BAO predictions are:

\[\widehat{D_M/r_d}=Sx(z) \tag{A10.4}\]
\[\widehat{D_H/r_d}=Sx'(z) \tag{A10.5}\]
\[\widehat{D_V/r_d}=S\left[zx^2(z)x'(z)\right]^{1/3} \tag{A10.6}\]
\[\chi^2_{\mathrm{BAO}}=\sum_i\left(\frac{B_i-\widehat{B}_i}{\sigma_{B,i}}\right)^2 \tag{A10.7}\]

For a BAO point \(i\), let \(F_i\) be the corresponding model-shape term: \(x(z_i)\), \(x\prime(z_i)\), or \([z_i x^2(z_i)x\prime(z_i)]^{1/3}\).

\[\chi^2_{\mathrm{BAO}}(S)=\sum_i\left(\frac{B_i-SF_i}{\sigma_{B,i}}\right)^2 \tag{A10.8}\]
\[S_{\mathrm{BAO}}=\frac{\sum_i B_iF_i/\sigma_{B,i}^2}{\sum_i F_i^2/\sigma_{B,i}^2}. \tag{A10.9}\]

Representative simplified-shape values are \(\chi^2=11.8514\) for flat \(\Lambda\)CDM and \(\chi^2=28.1117\) for the finite-boundary case.

A11. Chronometer-style derivative comparison

Calculation purpose: compare chronometer \(H(z)\) trends with the inverse finite-boundary derivative shape.

\[H(z)=-\frac{1}{1+z}\frac{dz}{dt} \tag{A11.1}\]
\[H_{\mathrm{shape}}(z)\propto \frac{1}{x'(z)} \tag{A11.2}\]
\[H_{\mathrm{shape}}(z)\propto g_0(1+z)^{1-1/(g_0d_b)}. \tag{A11.3}\]

A calibration constant is required to express the diagnostic in km s\(^{-1}\) Mpc\(^{-1}\). This section compares shape, not a full expansion-history likelihood.

A12. Supernova time-dilation exponent

Calculation purpose: compare published supernova time-dilation exponents with the \(b=1\) and \(b=0\) cases.

\[\Delta t_{\mathrm{obs}}=\Delta t_{\mathrm{emit}}(1+z)^b \tag{A12.1}\]
\[b=1 \quad \text{standard arrival-time stretching} \tag{A12.2}\]
\[b=0 \quad \text{no arrival-time stretching} \tag{A12.3}\]
\[b\approx1.0062. \tag{A12.4}\]

The time-dilation result is an external constraint: a path-response redshift model must account for arrival-time stretching as well as wavelength shift.

A13. CMB compressed distance-prior quantities

Calculation purpose: evaluate compressed CMB distance-prior consistency using \(x(z_*)\) and the prior covariance.

\[\mathbf{p}=\left(R,\ell_A,\omega_bh^2\right)^T \tag{A13.1}\]
\[\ell_A=\pi\frac{D_M(z_*)}{r_s(z_*)} \tag{A13.2}\]
\[x(z_*)=d_b\left[(1+z_*)^{1/(g_0d_b)}-1\right] \tag{A13.3}\]
\[D_{M,\mathrm{model}}(z_*)=S_{\mathrm{CMB}}x(z_*) \tag{A13.4}\]
\[\ell_{A,\mathrm{model}}=\pi\frac{S_{\mathrm{CMB}}x(z_*)}{r_s(z_*)} \tag{A13.5}\]
\[R_{\mathrm{model}}=\frac{\sqrt{\Omega_m}H_0}{c}S_{\mathrm{CMB}}x(z_*) \tag{A13.6}\]
\[\chi^2_{\mathrm{CMB}}=(\mathbf{p}_{\mathrm{model}}-\mathbf{p}_{\mathrm{obs}})^TC^{-1}(\mathbf{p}_{\mathrm{model}}-\mathbf{p}_{\mathrm{obs}}). \tag{A13.7}\]

\(z_*\) is held near 1089.92 in these diagnostics. This is a compressed-prior comparison, not a full anisotropy-spectrum fit.

A14. Joint BAO+CMB shared-ruler test

Calculation purpose: test whether one calibration scale can satisfy both BAO ratios and compressed CMB-prior distances.

\[S_{\mathrm{BAO}}=S_{\mathrm{CMB}}=S \tag{A14.1}\]
\[D_M/r_d\approx Sx(z) \tag{A14.2}\]
\[\ell_A\approx\pi Sx(z_*) \tag{A14.3}\]
\[\chi^2_{\mathrm{total}}=\chi^2_{\mathrm{BAO}}+w_{\mathrm{CMB}}\chi^2_{\mathrm{CMB}} \tag{A14.4}\]
\[\chi^2_{\mathrm{total}}(S)=\chi^2_{\mathrm{BAO}}(S)+w_{\mathrm{CMB}}\chi^2_{\mathrm{CMB}}(S). \tag{A14.5}\]

Representative shared-ruler values are total \(\chi^2=11.8573\) and reduced \(\chi^2=0.9121\) for flat \(\Lambda\)CDM. For the locked finite-boundary case, BAO \(\chi^2=7730.6214\), CMB \(\chi^2=2.1744\), and total \(\chi^2=7732.7958\). The failure is dominated by the BAO term under one shared scale.

A15. Separate BAO and CMB effective scales

Calculation purpose: fit BAO-side and CMB-side effective scales separately and compute their ratio.

\[S_{\mathrm{ratio}}=\frac{S_{\mathrm{CMB}}}{S_{\mathrm{BAO}}} \tag{A15.1}\]
\[S_{\mathrm{ratio}}=0.390906. \tag{A15.2}\]

The separate-scale diagnostic repeats the scale minimization twice: once for BAO-only terms and once for CMB-prior terms. The ratio is the recovery target for projection functions.

A16. Redshift-dependent projection factor

Calculation purpose: test redshift-dependent projection factors that preserve BAO ratios while reaching the CMB-side scale target.

\[S_{\mathrm{eff}}(z)=S_0T(z) \tag{A16.1}\]
\[T(z)\approx1\quad\text{for BAO redshifts} \tag{A16.2}\]
\[T(z_*)\approx0.390906 \tag{A16.3}\]
\[T_1(z)=(1+z)^{-q} \tag{A16.4}\]
\[T_2(z)=\frac{1}{1+q\,x(z)/d_b} \tag{A16.5}\]
\[T_3(z)=\left(1+\frac{x(z)}{d_b}\right)^{-q}. \tag{A16.6}\]

Broad, gentle transformations tend to disturb the BAO redshift range before reaching the CMB-side target. The useful target keeps \(T(z_i)\approx1\) across BAO while driving \(T(z_*)\) toward the separated-scale value.

A17. Sharp transition and preferred projection law

Calculation purpose: define projection laws that preserve the BAO range while reaching high-redshift CMB/JWST targets.

BAO-preserving high-redshift recovery target

\[T(z)=1-\frac{\Delta z^m}{z^m+z_t^m} \tag{A17.1}\]
\[\lim_{z\ll z_t}T(z)\approx1 \tag{A17.2}\]
\[\lim_{z\gg z_t}T(z)\approx1-\Delta \tag{A17.3}\]
\[1-\Delta\approx0.390906 \tag{A17.4}\]
\[\Delta\approx1-0.390906=0.609094. \tag{A17.5}\]

A schematic fitting objective combines BAO preservation, CMB-prior behavior, and a penalty for disturbing the BAO range:

\[\Phi=\chi^2_{\mathrm{BAO}}(T)+w_{\mathrm{CMB}}\chi^2_{\mathrm{CMB}}(T)+\lambda_{\mathrm{BAO}}\sum_{z_i\in\mathrm{BAO}}[T(z_i)-1]^2. \tag{A17.6}\]

Preferred JWST-centered projection law

Chapter 4 also uses a preferred projection law centered in the high-redshift galaxy regime. This construction preserves BAO behavior, shifts the JWST mass-size register, and approaches the compressed CMB-side band:

\[P_\star(z)=1-\frac{\Delta z^n}{z^n+z_s^n} \tag{A17.7}\]
\[P_\star(z)=1-\frac{0.627714\,z^8}{z^8+8^8}. \tag{A17.8}\]
\[M_{\star,\mathrm{FD}}\approx P_\star^2M_{\star,\mathrm{standard}},\qquad R_{e,\mathrm{FD}}\approx\frac{R_{e,\mathrm{standard}}}{P_\star}. \tag{A17.9}\]

Table A17-1. Preferred projection-law anchor behavior.

Regime\(z\)\(P_\star\)Mass ratio \(P_\star^2\)Radius ratio \(1/P_\star\)
BAO high end2.3approximately 1.000approximately 1.000approximately 1.000
JWST shoulder80.6861430.47081.4574
CMB side1089.920.3722860.13862.6861

The transition laws are recovery targets and diagnostic constructions. They specify the scale and redshift behavior that a physical mechanism would need to produce.

A18. Compact replication chain

Calculation purpose: list the minimum end-to-end dependency chain for reproducing the appendix calculations.

The finite-boundary calculation can be summarized as:

\[G(d)=\frac{g_0}{1+d/d_b}\]
\[A(d)=\int_0^dG(s)\,ds\]
\[A(d)=g_0d_b\ln\!\left(1+\frac{d}{d_b}\right)\]
\[1+z=e^{A(d)}\]
\[z(d)=\left(1+\frac{d}{d_b}\right)^{g_0d_b}-1\]
\[x(z)=d_b\left[(1+z)^{1/(g_0d_b)}-1\right]\]
\[\frac{D_M}{r_d}=Sx(z),\qquad \frac{D_H}{r_d}=Sx'(z),\qquad \frac{D_V}{r_d}=S\left[zx^2(z)x'(z)\right]^{1/3}\]
\[S_{\mathrm{eff}}(z)=S_0T(z)\]
\[T(z)=1-\frac{\Delta z^m}{z^m+z_t^m}\]
\[T(z)\approx1\ \text{across BAO},\qquad T(z_*)\approx0.390906\ \text{near the CMB-prior regime}.\]

A complete implementation should reproduce the empirical supernova fit, accumulated-response transform, finite-boundary mechanism fit, stability tests, BAO shape comparison, chronometer and time-dilation checks, CMB-prior comparison, shared-ruler failure, separate-scale ratio, projection target, and register-scaling constants.

A19. Unified registers, scaling constants, and limits

Calculation purpose: collect the dimensionless response registers, the register-scaling constants, and the main interpretation limits.

The chapter model organizes projection depth, morphology, weak-field gravity, and compactness as separate but linked registers:

\[D=A\,G,\qquad D_n=\frac{D}{D_0} \tag{A19.1}\]
\[X=\frac{A}{A_t},\qquad A_t=\ln(1+z_t) \tag{A19.2}\]
\[\eta=\frac{g_{\mathrm{bar}}}{g^\dagger} \tag{A19.3}\]
\[u=\frac{2GM}{Rc^2} \tag{A19.4}\]
\[C=C(X,\eta,u,D_n). \tag{A19.5}\]

The register-scaling analysis gives the following recovered dimensionless constants:

\[K_D\approx0.504869,\qquad K_X\approx0.980376,\qquad K_\eta\approx0.666348 \tag{A19.6}\]
\[K_D\sim\frac{1}{2},\qquad K_X\sim1,\qquad K_\eta\sim\frac{2}{3}. \tag{A19.7}\]

An initial compactness-sector test was attempted using black-hole mass and lag-radius information, but it did not isolate a stable empirical \(K_u\). Two compactness interpretations remain: \(K_u\sim1/3\) for radialized collapse scaling, or \(K_u\sim0\) if compactness behaves mainly as a saturation threshold. The full cosmology adopts \(K_u=1/3\) as the working compactness exponent.

\[K_u=\frac{1}{3}\quad\text{(working compactness value)} \tag{A19.8}\]

Table A19-1. Register-scaling constants.

RegisterQuantityRecovered \(K\)Simple formInterpretation
Morphology/path response\(D=A\,G\)0.504869\(1/2\)transport-like weakening response
Projection coordinate\(X=A/A_t\)0.980376\(1\)coherent projection ordering
Weak-field compliance\(\eta=g_{\mathrm{bar}}/g^\dagger\)0.666348\(2/3\)dimensional coupling in the low-acceleration register
Compactness\(u=2GM/(Rc^2)\)not empirically isolatedworking \(1/3\); alternate \(0\)radial collapse scaling or saturation threshold

A diagnostic scaled-response form can be written as:

\[C_{\mathrm{scaled}}=C\!\left(X^{K_X},\eta^{K_\eta},u^{K_u},D_n^{K_D}\right),\qquad K_u=\frac{1}{3}. \tag{A19.9}\]

Equation (A19.9) is a response-weighting diagnostic. It does not replace the final physical field equation; it records how the measured registers and the working compactness exponent enter the finite-response engine after their characteristic scaling has been identified or predicted.

Limits of interpretation

The supernova distance coordinate \(d\) is used as supplied. Changes in distance calibration alter fitted scale values.

BAO \(\chi^2\) values in this appendix are shape-compatibility diagnostics unless full covariance matrices are included.

The compressed CMB-prior comparison uses priors rather than a full CMB anisotropy-spectrum fit.

The nuisance scale \(S\) absorbs ruler calibration and separates redshift-dependent shape from absolute sound-horizon derivation.

The projection functions \(T(z)\) and \(P_\star(z)\) identify required recovery behavior. They do not by themselves derive the underlying physical mechanism.

The compactness exponent \(K_u=1/3\) is a working value for the full cosmology, not a recovered empirical constant. A stronger black-hole compactness test must distinguish this radial-collapse scaling interpretation from the \(K_u\sim0\) saturation-threshold interpretation.

The chronometer comparison is a derivative-shape comparison unless an explicit calibration is supplied.

The time-dilation result constrains interpretation: a path-response redshift model must account for arrival-time stretching as well as wavelength change.

Substituting a different public compilation, calibration, covariance treatment, or split protocol is a new numerical test and will not reproduce the representative values exactly.