Part II: Identity Thesis

Effective Rank: Concentration vs. Distribution

Introduction

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Effective Rank: Concentration vs. Distribution

The dimensionality of a system’s active representation can be quantified through the effective rank of its state covariance $C$ :

\effrank = \frac{(\tr C)^2}{\tr(C^2)} = \frac{\left(\sum_i \lambda_i\right)^2}{\sum_i \lambda_i^2}

When $\effrank \approx 1$ , all variance is concentrated in a single dimension—the system is maximally collapsed. When $\effrank \approx n$ , variance distributes uniformly across all available dimensions—the system is maximally expanded.

Phenomenal Correspondence

High rank: Many degrees of freedom active; distributed, expansive experience. Low rank: Collapsed into narrow subspace; concentrated, focused, or trapped experience.

Effective Rank in Discrete Substrate

For a pattern in a CA, record its trajectory $\mathbf{x}_1, \mathbf{x}_2, …, \mathbf{x}_T$ (configuration at each timestep). Each configuration is a point in ${0,1}^n$ . Compute the covariance matrix $C$ of these binary vectors treated as $\R^n$ points.

For a glider: the trajectory lies on a low-dimensional manifold (position $\times$ position $\times$ phase $\approx 3$ – $4$ effective dimensions out of $n$ cells). $\effrank$ is small.

For a complex evolving pattern: the trajectory may explore many independent dimensions. $\effrank$ is large.

The thesis predicts this maps to phenomenology:

Joy: high $\effrank$ (expansive, many active possibilities)
Suffering: low $\effrank$ (collapsed, trapped in narrow manifold)

In discrete substrate, this is not metaphor but measurement.