Guardat en:
| Autor principal: | |
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| Format: | Recurso digital |
| Idioma: | anglès |
| Publicat: |
Zenodo
2026
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| Matèries: | |
| Accés en línia: | https://doi.org/10.5281/zenodo.19821048 |
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- Canon² — Trust Layer Research Archive. Synthetic organisms operating within distributed deterministic ecosystems must acquire, transform, share, and release computational resources with the same guarantees of reproducibility and verifiability that govern their internal state and spatial behavior. Classical resource allocation systems—market-based pricing, first-come-first-served queuing, and round-robin scheduling—treat resource distribution as a best-effort optimization problem whose outcomes may vary across executions due to timing differences, contention resolution strategies, and demand fluctuation. Organism resource exchange requires a stronger guarantee: every resource transaction must produce identical allocation outcomes across all nodes in the distributed ecosystem, and every exchange must be traceable to the certificate chain that authorized it. I formalize Deterministic Organism Resource Exchange Protocols (D-OREP) as the architectural framework governing all resource acquisition, distribution, transformation, and release operations for synthetic organisms within distributed deterministic ecosystems. D-OREP ensures that every resource exchange is deterministically executed, certificate-bound, identity-preserving, and reproducible across all nodes. I integrate D-OREP with the Lume compiler's deterministic AST pipeline [4], Lume-V execution envelopes [11], Trust Layer certificate hierarchies [6], DAIGS cognitive substrates [7], LDIR multilingual inference semantics [8], SOR biological hierarchy [9], ZK-SRP state reversal protocols [1], G-DRSP global synchronization protocols [14], D-COCP cross-organism communication protocols [15], D-OLP lifecycle protocols [16], D-OMPP memory and persistence protocols [17], D-OMSCP mobility and spatial coordination protocols [18], and GUPAS governance pipelines [10]. Certificate-bound exchange anchors every resource transaction to the organism's verified identity and provenance chain. Intent-driven resource operations ensure that exchanges serve declared purposes validated by the Proof-of-Intent framework [13]. The resource exchange pipeline's six-stage architecture—detection, negotiation, arbitration, validation, certificate issuance, and multi-organism coordination—provides end-to-end determinism guarantees from initial resource assessment through cross-node verification. This work establishes what is, to my knowledge, the first complete resource exchange architecture for deterministic synthetic organisms.