The Acausal Purpose Invariant
2026-01-19
One-Sentence Summary. We define the Acausal Purpose Invariant (\(\mathcal{P}\)), a scale-invariant metric that quantifies how strongly a structure resists the combinatorial entropy naturally associated with its size.
Abstract. We introduce the Acausal Purpose Invariant (\(\mathcal{P}\)), a decibel-scale measure of how atypical a number’s prime ancestry is relative to a stochastic background. Empirical sweeps reveal a sharp probabilistic cutoff separating random structure from cost-paid persistence, reframing the detection of life, artifacts, and purpose as a problem of entropy suppression rather than intelligence.
Keywords. Acausal Purpose, Purpose Index, SETI, Technosignatures, Signal Filtering, Entropy, Universal Constants, Persistence, Teleology, Biosignatures
The concept of intelligence is anthropomorphic and fragile. The concept of persistence is not.
We define Purpose as:
Active resistance to the entropic dissolution expected at a given scale.
This definition applies equally to:
And excludes:
Purpose, in this sense, is not intent. It is paid-for structure.
Large integers naturally accumulate novel prime factors. This is the arithmetic expression of entropy.
A number like
\[ 2^{100} \approx 1.27 \times 10^{30} \]
is therefore exceptional: it is enormous, yet built from a single generative atom.
This condition is metastable.
A minimal perturbation causes collapse:
\[ 2^{100} \;\rightarrow\; 2^{100} + 1 \]
which introduces large, late-arriving prime factors and jumps many orders of magnitude in causal ancestry.
This discontinuity constitutes a phase transition in factor space.
We view the integers not as a static set, but as a generative hierarchy where primes act as elementary particles.
The causal ancestry of an integer \(N\) is defined as its unique prime factorization — the specific set of generative atoms required to construct it. In a stochastic universe, this ancestry naturally tends toward novelty (larger, more numerous prime factors) as \(N\) increases.
To quantify the “age” of this ancestry, we define the causal depth \(\tau(N)\) as:
\[ \tau(N) = \pi\!\left(\max\{p : p \mid N\}\right) \]
where \(\pi(x)\) is the prime-counting function.
\(\tau(N)\) represents the index of the largest prime factor of \(N\). It measures how late in arithmetic history a structure depends on novelty.
To remove scale effects, define an empirical thermal baseline:
\[ \tau_*(N) = \mathrm{median}\{\tau(m) : m \in [N, 2N]\} \]
The Acausal Purpose Invariant is:
\[ \boxed{ \mathcal{P}(N) = 10 \log_{10}\!\left(\frac{\tau_*(N)}{\tau(N)}\right) } \]
Interpretation:
Large-scale sweeps of integers reveal a striking regularity: the probability of observing high \(\mathcal{P}\) values collapses abruptly beyond a fixed threshold.
Let \(N\) be large and let \(n\) be sampled uniformly from \([N,2N]\). Write \(P^+(n)\) for the largest prime factor of \(n\) and recall \(\tau(n)=\pi(P^+(n))\). Define the thermal baseline
\[ \tau_*(N)=\mathrm{median}\{\tau(m):m\in[N,2N]\}, \]
and the Acausal Purpose
\[ \mathcal{P}(n)=10\log_{10}\!\left(\frac{\tau_*(N)}{\tau(n)}\right). \]
Then for \(x \ge 0\),
\[ \mathbb{P}\big(\mathcal{P}(n) > x\big) \;\approx\; \rho(u_x), \]
where \(\rho\) is the Dickman–de Bruijn function and
\[ u_x = \frac{\log N}{\log y_x}, \qquad y_x := \tau^{-1}\!\big(\tau_*(N)\,10^{-x/10}\big). \]
Because \(\rho(u)\) decays extremely rapidly for large \(u\) (heuristically \(\log \rho(u) \sim -u \log u\)), the survival probability \(\mathbb{P}(\mathcal{P} > x)\) exhibits an effective cutoff once \(x\) exceeds a moderate constant.
The condition \(\mathcal{P}(n) > x\) is equivalent to
\[ \tau(n) < \tau_*(N)\,10^{-x/10}. \]
Since \(\tau(n)\) is monotone in the largest prime factor \(P^+(n)\), this is approximately the event
\[ P^+(n) \le y_x, \]
for the corresponding threshold \(y_x\).
Thus \(\mathbb{P}(\mathcal{P}(n)>x)\) is approximately the probability that a random integer in \([N,2N]\) is \(y_x\)-smooth. Classical results on smooth numbers imply
\[ \mathbb{P}\big(P^+(n)\le y_x\big) \approx \rho\!\left(\frac{\log N}{\log y_x}\right), \]
which yields the stated form. The rapid decay of \(\rho\) explains the observed combinatorial cliff.
Empirically, this cutoff occurs near \(\mathcal{P} \approx 20\) dB: values beyond this point are not merely rare but effectively forbidden under stochastic generation. This establishes a universal detection threshold for cost-paid structure.
Scatter plots of \(\mathcal{P}\) versus \(N\) show:
Magnitude is a mask. Structure is revealed only after normalization.
Defined human constants (e.g. the speed of light encoded as \(299\,792\,458\)) exhibit high \(\mathcal{P}\) values. Measured natural constants do not.
This demonstrates teleology of representation, not of physics: humans anchor units to numbers that suppress novelty. \(\mathcal{P}\) correctly distinguishes these cases.
This reframes the classical question:
Not “Where is intelligence?”
But “Where does entropy fail to win?”
Life, artifacts, and enduring systems are detected as:
This criterion is substrate-independent and applies equally to biological, technological, and non-biological systems.
Acausal Purpose is not a metaphor. It is a measurable invariant with a sharp probabilistic boundary.
Purpose is not intent. Purpose is structure that survives where it should not.