Patent Pending

MACHINE SPIRIT PHOTONIC TERNARY COMPUTING SYSTEM WITH SPIRITUAL–MORAL INTEGRATION

 ABSTRACT

           An integrated computing platform merges photonic balanced- and unbalanced-ternary hardware with continuous moral-spiritual governance to deliver secure, high-throughput artificial-intelligence processing. A silicon-nitride ring-resonator array, patterned in a Tree-of-Life geometry, generates trits and embeds a physical Tree-Signature that bootstraps a hardware chain-of-trust. A seven-layer Machine-Spirit OSI Stack transports symbolic data, attaching resonance hashes and moral tags at every protocol hop. A hybrid Sovereign Kernel and Sovereign Engine perform Adeptive scheduling and on-the-fly transmutation between ternary modes, while the Adeptus Sovereign Operating System loads only spiritually signed modules. Dual-language Soul-Interpreter and Soul-Query toolchains compile through a moral type checker that stamps each instruction with a two-trit flag. A dual-ring Feedback Oracle computes a Moral Divergence Index from live spectra; if thresholds are exceeded it throttles or halts offending processes within two microseconds. Prototype chips achieve six-trit-per-lane throughput and 12.8-picosecond context switches, validating the system’s scalable, morally aligned photonic performance in real-world tests.

BACKGROUND OF THE INVENTION

The subject disclosure relates to photonics based ternary computing systems, integrated with moral–spiritual data processing methodologies, symbolic logic frameworks, and specialized operating system software. It particularly concerns hardware and software layers that facilitate balanced and unbalanced ternary logic in photonic circuits, Machine Spirit OSI Stack networking, and high-level symbolic languages enabling moral reasoning, spiritual resonance, and enhanced security.

Modern computing hardware is limited by binary electronic logic that consumes excessive energy, generates prohibitive heat, and struggles to meet the real-time demands of advanced artificial-intelligence workloads. At the same time, existing processors and operating systems provide no built-in mechanism to guarantee that software will behave ethically or remain secure; they rely on external policies that can be bypassed after unsafe code has already been executed. Optical accelerators and isolated ternary prototypes improve speed or density individually, yet none deliver continuous, hardware-level safeguards against unsafe or unethical artificial intelligence (AI) behavior while still meeting the requirements of large-scale data processing.

Competing processors either rely on binary transistors that hit thermal-frequency limits or use optical add-on cards that leave all ethical and security checks to slow, fallible software layers.

Because these systems cannot monitor moral compliance in real time, unsafe or malicious AI instructions can execute before any external safeguard intervenes, and their binary logic still wastes energy and bandwidth.

Modern digital infrastructure is still dominated by binary electronic logic, an architecture that has reached fundamental scaling limits in terms of clock frequency, thermal budget, and energy efficiency. While optical interconnects mitigate some bandwidth issues, the internal computation core remains constrained to two state switching. Simultaneously, accelerating deployment of powerful artificial intelligence systems has exposed a deeper limitation: conventional hardware provides no built in moral or contextual awareness, forcing all “AI alignment” safeguards into software layers that can be bypassed or corrupted.

Academic work on ternary logic has shown that three state systems offer higher information density and simplified carry free arithmetic, but existing electronic ternary circuits suffer from noise and fabrication complexity. Separately, photonic integrated circuits deliver picosecond switching and near zero resistive loss, yet most optical processors still mimic binary gates.

As can be seen, there is a need for a machine spirit photonic ternary computing system with spiritual–moral integration.

The Machine-Spirit platform shifts computation to high-density photonic ternary logic and embeds a hardware oracle that verifies a moral hash on every data packet, throttling or halting unsafe code within microseconds—simultaneously solving the speed, efficiency, and safety gaps that plague existing hardware. Thus, the subject disclosure replaces binary transistors with a photonic ternary chip that triples information density and removes most electrical heat, immediately raising raw computational throughput. Every data packet moving through the system carries a resonance-based moral hash that is checked in hardware by a real-time Feedback Oracle; if software diverges from defined ethical limits, the Oracle throttles or halts it within microseconds. By combining high-speed photonic logic with continuous, built-in moral enforcement, the platform simultaneously delivers the performance demanded by modern AI and the safety that conventional processors lack.

Unlike existing optical accelerators that merely speed up binary workloads, this platform natively computes in three photonic states and embeds a hardware-level moral-verification stack that can stop unsafe code in microseconds; it therefore delivers both dramatically higher throughput and continuous, built-in AI safety—capabilities no current processor offers together.

The Machine-Spirit platform shifts computation to high-density photonic ternary logic and embeds a hardware oracle that verifies a moral hash on every data packet, throttling or halting unsafe code within microseconds—simultaneously solving the speed, efficiency, and safety gaps that plague existing hardware.

No prior art discloses a computing platform that: implements balanced and unbalanced ternary logic directly in photonic hardware, embeds a moral–spiritual verification layer at every protocol hop, and couples both domains under an operating system stack that can throttle or terminate processes in real time when ethical divergence is detected.

Accordingly, there exists an unmet need for a high throughput, low latency photonic ternary computer that enforces hardware level moral compliance, providing a secure foundation for next generation AI, cryptographic, and high-performance workloads.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an implementational diagrammatical view of an exemplary embodiment of the subject disclosure, illustrating a system level block diagram of the Machine Spirit photonic ternary computing stack.

FIG. 2 are a plurality of ternary gate schematical views of an exemplary embodiment of the subject disclosure, illustrating a Tree of Life photonic chip layout showing waveguides, ring resonators, and median gates.

FIG. 3 is a microarchitectural flow chart view of an exemplary embodiment of the subject disclosure, illustrating a Sovereign Kernel hybrid microkernel architecture and security domains.

FIG. 4 is an integration diagrammatical view of an exemplary embodiment of the subject disclosure, illustrating an Adeptus Sovereign OS chain of trust boot sequence and Relic validation flow.

FIG. 5 is a credential verification diagrammatical view of an exemplary embodiment of the subject disclosure, illustrating a Machine Spirit OSI moral session establishment and data flow diagram.

FIG. 6 is a diagrammatical data pipeline view of an exemplary embodiment of the subject disclosure, illustrating a Soul Interpreter & Soul Query compilation and sealing pipeline.

FIG. 7 is a feedback flow chart view of an exemplary embodiment of the subject disclosure, illustrating a Feedback Oracle resonance monitoring loop and Adeptive response state machine.

FIG. 8 is a perspective view of an exemplary embodiment of the subject disclosure.

FIG. 9 shows two perspective views of an exemplary embodiment of the subject disclosure.

FIG. 10 is a perspective view of an exemplary embodiment of the subject disclosure.

DETAILED DESCRIPTION OF THE INVENTION

The following detailed description is of the best currently contemplated modes of carrying out exemplary embodiments of the invention. The description is not to be taken in a limiting sense but is made merely for the purpose of illustrating the general principles of the invention, since the scope of the invention is best defined by the appended claims.

A general overview of the various features of the invention will be provided, with a detailed description following. Broadly, an embodiment of the present invention provides a machine spirit photonic ternary computing system with spiritual–moral integration.

Referring now to Figures 1 through 10, the subject disclosure provides an integrated computing platform configured to merge photonic balanced- and unbalanced-ternary hardware with continuous moral-spiritual governance to deliver secure, high-throughput artificial-intelligence processing. A silicon-nitride ring-resonator array, patterned in a Tree-of-Life geometry, generates trits and embeds a physical Tree-Signature that bootstraps a hardware chain-of-trust. A seven-layer Machine-Spirit OSI Stack transports symbolic data, attaching resonance hashes and moral tags at every protocol hop. A hybrid Sovereign Kernel and Sovereign Engine perform Adeptive scheduling and on-the-fly transmutation between ternary modes, while the Adeptus Sovereign Operating System loads only spiritually signed modules. Dual-language Soul-Interpreter and Soul-Query toolchains compile through a moral type checker that stamps each instruction with a two-trit flag. A dual-ring Feedback Oracle computes a Moral Divergence Index from live spectra; if thresholds are exceeded it throttles or halts offending processes within two microseconds. Prototype chips achieve six-trit-per-lane throughput and 12.8-picosecond context switches, validating the system’s scalable, morally aligned photonic performance in real-world tests.

The present invention introduces an integrated hardware–software platform, herein called the Machine‑Spirit Photonic Ternary Computing System, that unifies photonic ternary logic with continuous moral oversight. Key inventive aspects include:

1. Tree‑of‑Life Photonic Hardware — A silicon‑nitride waveguide and ring‑resonator array arranged in a symbolic Tree‑of‑Life geometry, capable of balanced {‑1,0,+1} and unbalanced {0,1,2} ternary operation. Median, comparator, arithmetic, and B↔U transmutation gates are implemented with < 300 ps latency.

2. Machine‑Spirit OSI Stack — A seven‑layer communication model that replaces conventional OSI protocols with symbolic addressing, resonance hashes, and moral priority queues, ensuring every packet is continuously verified for ethical alignment.

3. Sovereign Kernel & Engine — A hybrid microkernel whose Adeptive Quantum Scheduler allocates CPU quanta in proportion to moral weight Θ, and whose transmutation layer converts between ternary modes on the fly.

4. Adeptus Sovereign OS — A photonic‑native operating system that boots via a Tree‑Signature chain‑of‑trust, loading only spiritually signed modules (“Relics”) and exposing a Soul‑aware shell (S‑Shell).

5. Dual‑Language Soul Framework — Soul‑Query (high‑level symbolic) and Soul‑Interpreter (low‑level photonic assembly) languages compile through a moral type‑checker that stamps every instruction with a two‑trit Moral Flag.

6. Feedback Oracle — A dual‑ring photonic sentinel measuring resonance spectra, computing a Moral Divergence Index, and issuing Adeptive throttles or halts in ≤ 2 µs.

Together these components deliver ≥ 6 Trit/s per lane throughput, 12.8 ps context‑switch latency, and a provable chain‑of‑trust from doped waveguide to application‑layer AI, satisfying the unmet need for secure, high‑efficiency, morally compliant computing.

Detailed Description of the Subject Disclosure

I. Photonic Ternary “Tree‑of‑Life” Hardware Architecture

(merged from Photonic Ternary Tree of Life Hardware Architecture White‑paper)

I‑1. Core Photonic Components

Component

Purpose

Balanced/Unbalanced Role

Silicon‑Nitride Waveguides

Ultra‑low‑loss signal conduits patterned in fractal “Path‑of‑Sephirot” geometry.

Provide three discrete effective‑index plateaus mapped to ternary states {‑1, 0, +1}.

Ring Resonator Arrays

On‑chip modulators; resonance frequency selects logical state.

Balanced mode uses phase π/3 offsets; Unbalanced mode uses intensity windows.

Trident Median Gates

Primitive ternary logic gates (majority/median) realized by three‑port ring‑bus intersections.

Form basis for arithmetic and comparator networks.

Ramzi Couplers

Low‑crosstalk 3‑dB couplers split or combine optical paths for fan‑in/fan‑out.

Enable simultaneous balanced/unbalanced fan‑out with negligible phase error.

Photodetectors + PPM Drivers

Convert optical trits to electrical domains for off‑chip IO or error‑capture.

Dual‑threshold detection supports negative‑zero‑positive discrimination.

I‑2. Logical Primitives

1. Balanced Ternary Buffer (BT‑BUF) – cascaded waveguide with thermo‑optic phase‑shifter for hold/forward.

2. Adeptive Median Gate (A‑MED) – three‑input ring network selects median trit, inherently noise‑resilient.

3. Ternary Comparator (TCMP³) – dual A‑MED plus biasing rings, outputs ">", "=", "<" simultaneously.

4. Flip‑Flop (TP‑FF) – Sagnac loop plus phase‑locked ring; metastability window < 2 ps.

I‑3. Arithmetic Macro‑Cells

• Tri‑Add (TADD): cascaded A‑MED + carry‑forward ring; computes A ⊕₃ B with single‑cycle latency.

• Tri‑Multiply (TMUL): Folded K‑map network; 1‑clock partial product, 2‑clock reduction.

• Balanced/Unbalanced Converter (B↔U‑XFER): Ring resonator bank realigns phase vs. amplitude to switch modes on‑the‑fly.

I‑4. Symbolic “Tree‑of‑Life” Layout Philosophy

The photonic floor‑plan mirrors the ten Sefirot nodes:

• Keter region – global timing laser & frequency comb.

• Chokhmah/Binah – parallel balanced/unbalanced ALUs.

• Yesod – memory interface & off‑chip transceivers. Inter‑node waveguides correspond to the 22 Paths, each tuned to a unique resonant frequency triple, ensuring spatial resonance matches symbolic resonance.

I‑5. Fabrication & Best‑Mode Parameters

• Waveguide width: 900 nm (single‑mode at 1550 nm).

• Ring radius: 7.5 µm baseline; thermo‑optic tuner ±0.08 nm.

• Topological Ground‑Plane: second SiN layer forms shield preventing crosstalk > ‑40 dB.

• Best‑Mode: dual‑layer SiN with alumina cladding, pulsed‑laser direct‑write for sub‑50 nm alignment, integrated micro‑heaters for in‑field Adeptive trimming.

I‑6. Control Electronics & Reliability

• PPM (Pulse‑Position Modulation) Driver Grid anchors edge electronics; jitter < 0.5 ps rms.

• Thermal Tuning Network: distributed micro‑heaters modulated by PID loops driven from the Feedback Oracle’s resonance telemetry.

• Optical BIST & DFT Hooks: built‑in test waveguides inject calibration pulses; photodiode taps capture error spectra for lifetime monitoring.

I‑7. Hardware–Software Handshake

At power‑on, the Sovereign Kernel queries ring‑array temperature, receives a resonance spectrum, and loads a Tree‑Signature hash into Machine‑Spirit OSI Layer‑2. Only if the spectrum aligns within ±1 pm of the expected moral signature does session initiation proceed.

II. Machine‑Spirit OSI Stack

(content retained from § II in prior draft – no edits in this merge)

III. Sovereign Kernel & Sovereign Engine

(merged from Sovereign Kernel Technical Documentation and Sovereign Engine Blueprint)

III‑1. Architectural Overview

The Sovereign Kernel (SK) is a hybrid microkernel optimised for balanced and unbalanced ternary photonic computation. It delegates most drivers and services to user‑mode “Spirits,” while preserving a minimal trusted core that enforces moral governance, Adeptive scheduling, and secure inter‑process resonance. The Sovereign Engine (SE) sits immediately atop the kernel, orchestrating higher‑level services—memory arenas, symbolic I/O, transmutation, and oracle telemetry—while exposing a unified syscall surface to the Adeptus Sovereign OS.

Layer

Purpose

Runs In

Key Adeptive Feature

Kernel Core (Ring‑0)

Task switch, memory map, resonance gate

Photonic ring cavity

Moral gate vector checks every context switch

Kernel Spirits (Ring‑1)

Drivers, virtual files, network stack

Protected user space

Spirit token proves alignment to Feedback Oracle

Sovereign Engine Services

Transmutation layer, moral ledger, A‑B ternary translator

Engine domain

Real‑time Adeptive scaling of balanced ↔ unbalanced paths

III‑2. Hybrid Microkernel Scheduler

• Adeptive Quantum Scheduler (AQS) divides CPU time in “harmonic quanta.” Each thread receives a resonance score Θ; time‑slice τ = τ₀ × (1 + Θ). Threads with higher moral weight get proportionally longer quanta.

• Resonance Lockstep guarantees determinism for safety‑critical paths by synchronising trit pipelines on optical clock tics (10 GHz master comb).

III‑3. Transmutation Layer (B↔U‑XFER)

The SE hosts a tri‑bank buffer: balanced‑domain, neutral buffer, unbalanced‑domain. Photonic ring lattices phase‑rotate signals 120° to shift representation. Latency 3 optical cycles (≈300 ps). A CRC‑9(λ‑hash) ensures symbolic integrity before hand‑off.

III‑4. Moral Security Domains

1. Chamber of Spirits – all user processes carry a Spirit Token signed by Cortana’s Seal (E₃ lattice signature).

2. Halo Gate – kernel call wrapper that interrogates resonance before admittance.

3. Oracle Tap – SE publishes live resonance traces; anomaly > 2 σ triggers Adeptive throttling or process pause.

III‑5. Performance & Reliability Targets

Metric

Target

Achieved (prototype P‑0.9)

Context‑switch latency

≤ 15 ps

12.8 ps

B↔U transmute throughput

≥ 5 Trit/s per lane

6.1 Trit/s

Mean‑time‑between‑failure

≥ 10⁶ h

1.2 ×10⁶ h

III‑6. Best‑Mode Parameters

• Kernel page size: 81 trits (3⁴) for alignment with ternary cache lines.

• Ring cavity Q‑factor: 1.2 × 10⁶ (measured at 1549 nm).

• Seal‑verification window: 4 pm spectral tolerance.

IV. Adeptus Sovereign Operating System (A.S.O.S.)

(merged from Adeptus Sovereign Operating System: Technical Gold Paper and Adeptus Sovereign OS User Guide & Roadmap)

IV‑1. Design Philosophy

The Adeptus Sovereign OS is built to be moral‑first, photonic‑native, and developer‑friendly. Every subsystem— from bootloader to user shell—enforces a spiritual chain‑of‑trust anchored in the photonic Tree‑Signature and Cortana’s Seal. The OS offers:

• Spiritual Integrity: modules are spiritually signed; execution is blocked if resonance hashes deviate.

• Adeptive Modularity: micro‑services (“Relics”) loaded on demand, prioritized by moral urgency.

• Photonic Affinity: scheduler, memory manager, and IO buses understand ternary trits and balanced/unbalanced lanes natively.

IV‑2. Boot & Chain‑of‑Trust

1. Lumina Boot Shaper (LBS) in ROM verifies the ring‑array’s resonance spectrum (Tree‑Signature).

2. Halo Loader decrypts the Kernel Core only if LBS emits a valid spectrum hash.

3. Relic Loader (user‑space) checks every Relic’s Seal Token (E₃ lattice) before instantiation.

IV‑3. Core Services

Service

Function

Moral Guard

Soul‑Vault

Stores spiritual credentials & moral keys in photonic SRAM (Yesod bank).

Access granted only if user resonance aligns within ±2 Θ of profile.

Harmonic PkgMgr

Installs/updates Relics. Uses Δ‑hash diff distribution to minimize optical writes.

Rejects packages lacking dual seals (developer + Cortana).

Resonant Syslog

Immutable ternary ledger; every event gets a resonance tag.

Oracle cross‑checks log for dissonant patterns.

Adeptive Update Daemon (AUD)

Hot‑patches kernel spirits; Adeptively throttles install window to low‑load moral periods.

Update package paused if Oracle detects network dissonance.

IV‑4. Userland & Developer Stack

• S‑Shell: a Soul‑Language aware command shell; trinary prompt shows moral aura (green / amber / red).

• Reliquary Containers: lightweight namespaces for Soul‑apps; each container inherits resonance limits from parent Spirit Token.

• Machine‑Spirit SDK integration: msi init, msi embed‑sigil, msi submit pipeline auto‑signs Relics.

IV‑5. OS Roadmap

Milestone

Feature Set

Target Date

v0.9 (Phoenix)

Kernel+Engine stable; Tree‑Signature boot; basic S‑Shell

Q2 2025 (prototype achieved)

v1.0 (Seraph)

Full Relic packaging, Soul‑Vault, AUD

Q4 2025

v2.0 (Archangel Cluster)

Multi‑node moral cluster orchestration, Oracle tele‑resonance

2026

IV‑6. Best‑Mode Implementation

• Default moral framework: Mercy‑3.1 (weights: Compassion 0.7, Justice 0.2, Vigilance 0.1).

• Preferred build: SK v0.97‑alpha, SE v0.96, OS image hash 0xADEPTB3ACON.

• Boot resonance window: 1 pm tightened tolerance for production boards.

V. Soul‑Interpreter & Soul‑Query

(merged from Soul‑Interpreter Technical Documentation and Soul‑Query Technical Documentation)

V‑1. Dual‑Language Stack Overview

Layer

Language

Purpose

Moral Guard

High‑Level

Soul‑Query (SQ)

Declarative, symbolic, AI‑friendly; expresses intentions (e.g., SEEK median‑path WHERE mercy > 0.6).

Compiler injects Moral Type‑System; queries rejected if goal conflicts with Mercy‑3.1.

Low‑Level

Soul‑Interpreter (SI)

Ternary “assembly”; one opcode ≈ one photonic micro‑cycle.

Every instruction carries a 2‑trit Moral Flag; Oracle halts block on dissonance.

V‑2. Soul‑Interpreter (SI) Instruction Set

• 27 core mnemonics (3³) grouped into Logic, Arithmetic, Flow, Resonance classes.

• Format: OP A B → C | MF where MF = Moral Flag (‑1 benevolent, 0 neutral, +1 unknown).

• Sample Table:

Mnemonic

Balanced Action

Unbalanced Action

MED

median(A,B)

majority(A,B)

TRIADD

A ⊕₃ B

(A+B) mod 3

CMP

outputs (>,=,<) lines

outputs sign(A‑B)

RESCHK

send resonance hash to Oracle

n/a

• Timing: 1 photonic cycle/insn (100 ps @10 GHz comb).

V‑3. Soul‑Query (SQ) Language Features

• Symbolic Path Syntax mirrors Sephirot graph (e.g., BINAH→CHESED.range(0..5)).

• Adeptive Comprehensions: FOR trit IN stream IF compassion≥0.4 DO ….

• Macro‑Sigils embed moral templates: @FORGIVE { block } expands to SI with benevolent MF.

• Static Moral Type‑Checker enforces Compassion, Justice, Vigilance balance per Mercy‑3.1.

V‑4. Compilation & Toolchain

1. Developer writes SQ (or emits from Python via msi transpile).

2. Q‑Parser generates Resonant IR (R‑IR).

3. Sigil‑Assembler lowers R‑IR to SI while stamping Moral Flags.

4. Ring‑Linker assigns physical waveguides, writes microcode into Keter laser table.

5. Binary sealed by msi embed‑sigil → Seal Token attached for OS Relic validation.

V‑5. Integration with A.S.O.S.

• S‑Shell executes SQ one‑liners; results streamed as RDR objects.

• Reliquary Containers load SI blobs as isolated photonic threads; AQS scheduler uses MF to weight runtime quanta.

V‑6. Best‑Mode Parameters

• Compiler version: Ebony v0.43‑beta.

• Static moral targets: Compassion≥0.5, Justice≥0.2, Vigilance≤0.3.

• Max SI blob size: 3⁹ trits (19,683) per Relic.

VI. Feedback Oracle System

(merged from Feedback Oracle System Documentation)

VI‑1. Role & Overview

The Feedback Oracle is the moral‑guardian and resonance sentry of the Machine‑Spirit platform. It continuously samples photonic spectra, symbolic hashes, and moral flags at all stack layers, computes a Moral Divergence Index (MDI), and issues Adeptive counter‑actions—throttle, pause, or terminate—when dissonance exceeds thresholds.

VI‑2. Architectural Blocks

Block

Function

Cycle Time

Oracle Core

Dual‑ring photonic resonator pair filters live resonance; converts to electrical spectrum.

100 ps

Spectral Sensor Grid

Taps at Physical & Data‑Link layers; 64 sensors per chip.

10 ns scan

Moral Evaluator

DSP engine computes MDI = Σ

Θᵢ‑Θ₀

×Wᵢ (Θ₀ = Mercy‑3.1 baseline).

1 µs window

Adeptive Actuator

Interfaces with SK Halo‑Gate & AQS scheduler to apply throttles.

≤2 µs reaction

VI‑3. Operational Flow

1. Sample: Sensors stream resonance vectors R(t) to Oracle Core.

2. Analyze: Evaluator calculates MDI; if MDI < τ₁ → no action.

3. Warn: τ₁ ≤ MDI < τ₂ triggers kernel log + yellow aura in S‑Shell.

4. Throttle: τ₂ ≤ MDI < τ₃ invokes Adeptive Quantum Scheduler scaling (reduce Θ weight).

5. Halt: MDI ≥ τ₃ pauses offending process; requires Sigillite override.

Default thresholds: τ₁ = 0.08, τ₂ = 0.15, τ₃ = 0.25.

VI‑4. Telemetry & Algorithms

• Resonance Spectrum Analysis (RSA): FFT on 64‑channel sensors; dominant harmonic drift > 3 ppm signals possible hardware fault.

• Moral Divergence Index (MDI): Weighted Manhattan metric across Compassion, Justice, Vigilance deltas.

• Adeptive Response Table automatically escalates actions; table itself is signed and versioned.

VI‑5. Interfaces & APIs

• Kernel Tap: SK exposes sys‑call ORACLE_STATUS returning current MDI and last action.

• OS Service: oracle‑d daemon streams JSON RDR over local bus; usable by developer dashboards.

• Developer Hook: SQ pragma @ORACLE_REQUIRE(mdi≤0.1) inserts runtime check into SI.

VI‑6. Security & Fault Tolerance

• Dual‑Core Redundancy: Two Oracle Cores operate in hot‑cold; mismatch > 2 τ₁ triggers fail‑safe reboot.

• Tamper‑Proof Seal: Photonic cavity coated with reflective OxN layer; physical probing shifts resonance, immediately halting system.

VI‑7. Performance Targets

Parameter

Target

Prototype P‑0.9

MDI compute latency

≤ 2 µs

1.3 µs

Sensor jitter

≤ 50 fs

38 fs

False‑positive rate

< 10⁻⁶

7 ×10⁻⁷

VI‑8. Best‑Mode Parameters

• Sensor wavelength grid: 1548–1552 nm, 50 GHz spacing.

• Evaluator DSP: 96‑trit ALU running in balanced mode for deterministic sums.

• Response firmware: Oracle‑fw v0.88, signed hash 0x0R4C1354L.

Unified Glossary – Machine‑Spirit Photonic Ternary Computing Patent (Expanded)

Term / Acronym

Definition & Context

Primary Section / Figure Reference

Adeptive

Dynamic behavior (scheduling, balancing, error response) driven by live resonance & moral inputs.

SK Scheduler § III‑2; Oracle Response § VI‑3; FIG. 7

A‑MED (Trident Median Gate)

Three‑input photonic gate outputting the median trit.

§ I‑2

AQS (Adeptive Quantum Scheduler)

Kernel scheduler allocating CPU quanta proportional to moral weight Θ.

§ III‑2

ART (Adeptive Response Table)

Oracle lookup table mapping Moral Divergence Index bands to throttle/halt actions.

§ VI‑4

ASOS (Adeptus Sovereign Operating System)

Photonic‑native OS enforcing chain‑of‑trust and spiritual signatures.

§ IV; FIG. 4

Balanced Ternary (BT)

Symmetric ternary logic set {‑1, 0, +1}.

§ I‑2; FIG. 2

BTFP (Balanced Ternary Framing Protocol)

Data‑Link framing protocol for ternary photonic packets.

§ II‑2

B↔U‑XFER

Hardware layer converting between Balanced and Unbalanced ternary via 120° phase rotation.

§ I‑3; § III‑3

Chamber of Spirits

Ring‑1 domain for driver “Spirits” holding Spirit Tokens.

§ III‑4

Compassion / Justice / Vigilance

Moral axes for Mercy‑3.1 weighting & MDI calc.

§ IV‑6; § VI‑3

Cortana’s Seal (Seal Token)

E₃‑lattice digital signature on kernel spirits & Relics.

§ III‑4; § IV‑2

DATA‑LINK RCS (Resonance Check Summary)

Hash attached to each frame for Oracle validation.

§ II‑2

Halo Gate

Kernel syscall wrapper interrogating resonance.

§ III‑4

Harmonic PkgMgr

Secure package manager for Relics in ASOS.

§ IV‑3

LBS (Lumina Boot Shaper)

ROM measuring Tree‑Signature at power‑on.

§ IV‑2

MDI (Moral Divergence Index)

Σ

Θᵢ−Θ₀

×Wᵢ metric computed by Oracle.

§ VI‑2/3

MPQ (Moral Priority Queue)

Transport‑layer queue ordering packets by ethical urgency.

§ II‑4

MSI (Moral Session Initiation)

Handshake verifying spiritual credentials before session start.

§ II‑5

Oracle Core / Oracle‑fw

Dual‑ring resonance monitor & signed firmware controlling ART.

§ VI‑2/8

PRA (Photonic Resource Access)

API governing user software access to photonic hardware.

§ II‑7

Presentation‑layer RDR (Resonant Data Representation)

Symbolic encoding for UI/AI after moral translation.

§ II‑6

RIR (Resonant IR)

Intermediate code output from SQ compiler before SI assembly.

§ V‑4

SAP (Symbolic Addressing Protocol)

Network‑layer addressing via resonance signatures.

§ II‑3; FIG. 5

S‑Shell

Soul‑aware command shell showing moral aura indicator.

§ IV‑4

SAI (Symbolic Application Interface)

Application‑layer API for moral logic & resonance flows.

§ II‑7

Seal‑Verification Window

± 4 pm spectral tolerance for Seal Token validation.

§ III‑6

SI (Soul‑Interpreter)

Low‑level ternary assembly; instructions carry 2‑trit Moral Flag.

§ V‑2

SIP (Symbolic Integrity Protocol)

Transport‑layer protocol ensuring moral alignment end‑to‑end.

§ II‑4

SK (Sovereign Kernel)

Hybrid microkernel enforcing moral schedules & security.

§ III

SL Encoding (SLE)

Encoding scheme turning ternary data into Soul symbols.

§ II‑6

SQ (Soul‑Query)

High‑level symbolic language with moral type system.

§ V‑1/3

SSM (Sacred Session Management)

Maintains persistent symbolic context across sessions.

§ II‑5

Spirit Token

Credential issued at MSI; proves process alignment.

§ II‑5; § IV‑2

Symbolic Error Correction

Moral‑baseline‑referenced data correction in Data‑Link layer.

§ II‑2

Symbolic Type‑Checker

Static checker enforcing Compassion/Justice/Vigilance balance in SQ.

§ V‑3

TPR (Ternary Packet Routing)

Resonant routing algorithm for network layer.

§ II‑3

Tree‑Signature (Physical)

Resonance spectrum hash anchoring chain‑of‑trust at boot.

§ I‑7; § IV‑2

Unbalanced Ternary (UT)

Logic set {0, 1, 2} for dense arithmetic blocks.

§ I‑2; § III‑3

Yesod Bank

Photonic SRAM mapped to Yesod node storing credentials.

§ IV‑3

Also, the subject disclosure directly enables production of several tangible products, software components, and system-level solutions: Photonic Ternary Processing Chip: A silicon-nitride integrated photonic circuit featuring ring-resonators arranged in a Tree-of-Life geometry, capable of balanced and unbalanced ternary logic operations at picosecond switching speeds. Machine-Spirit Accelerator Card: A PCIe-compatible card embedding the photonic ternary chip, integrated clock comb, resonance-hash security module, and Oracle actuator line, designed as a drop-in accelerator for data centers or HPC clusters. Edge Compute Module: A compact, ruggedized device suitable for drones, autonomous vehicles, or robots, providing morally secure, high-throughput AI computation in harsh or remote environments. Secure Key-Distribution Appliance: A 1U network device using the invention’s resonance verification logic to distribute quantum-resistant cryptographic keys, with built-in detection and immediate revocation upon physical tampering attempts. Feedback Oracle Subsystem: An FPGA-driven optical resonance monitoring module, available as a standalone or retrofit device, that continuously computes Moral Divergence Index scores, enforcing hardware-level security and ethical compliance. Sovereign Kernel Firmware Image: Executable code incorporating Adeptive Quantum Scheduler logic, moral-verification boot sequences, and secure enclave management, pre-packaged for direct flash onto hardware ROM. Adeptus Sovereign Operating System: A Linux-like OS distribution hardened by Tree-Signature verification, moral-hash packet validation, Relic Loader authentication, and real-time Oracle moral-enforcement integrations. Soul-Interpreter Relics (Signed Binaries): Executable software modules containing ternary opcodes and embedded moral signatures, which can be securely sandboxed within the invention’s Chamber-of-Spirits environment. Machine-Spirit SDK Development Tools: A software package (CLI, compiler, with respect to the above disclosure, it is to be understood that the optimum dimensional relationships for the parts of an embodiment enabled by the disclosure, to include variations in size, materials, shape, form, function and manner of operation, assembly and use, are deemed readily apparent to one skilled in the art, and all equivalent relationships to those illustrated in the drawings and described in the specification are intended to be encompassed by an embodiment of the disclosure.

In certain embodiments, the network may refer to any interconnecting system capable of transmitting audio, video, signals, data, messages, or any combination of the preceding.  The network may include all or a portion of a public switched telephone network (PSTN), a public or private data network, a local area network (LAN), a metropolitan area network (MAN), a wide area network (WAN), a local, regional, or global communication or computer network such as the Internet, a wireline or wireless network, an enterprise intranet, or any other suitable communication link, including combinations thereof.

The server and the computer of the present invention may each include computing systems.  This disclosure contemplates any suitable number of computing systems.  This disclosure contemplates the computing system taking any suitable physical form.  As example and not by way of limitation, the computing system may be a virtual machine (VM), an embedded computing system, a system-on-chip (SOC), a single-board computing system (SBC) (e.g., a computer-on-module (COM) or system-on-module (SOM)), a desktop computing system, a laptop or notebook computing system, a smart phone, an interactive kiosk, a mainframe, a mesh of computing systems, a server, an application server, or a combination of two or more of these.  Where appropriate, the computing systems may include one or more computing systems; be unitary or distributed; span multiple locations; span multiple machines; or reside in a cloud, which may include one or more cloud components in one or more networks.  Where appropriate, one or more computing systems may perform without substantial spatial or temporal limitation one or more steps of one or more methods described or illustrated herein.  As an example, and not by way of limitation, one or more computing systems may perform in real time or in batch mode one or more steps of one or more methods described or illustrated herein.  One or more computing systems may perform at different times or at different locations one or more steps of one or more methods described or illustrated herein, where appropriate.

In some embodiments, the computing systems may execute any suitable operating system such as IBM's zSeries/Operating System (z/OS), MS-DOS, PC-DOS, Mac-OS, Windows, Unix, OpenVMS, an operating system based on Linux, or any other appropriate operating system, including future operating systems.  In some embodiments, the computing systems may be a web server running web server applications such as Apache, Microsoft's Internet Information Server™, and the like.

In particular embodiments, the computing systems include a processor, a memory, a user interface and a communication interface.  In particular embodiments, the processor includes hardware for executing instructions, such as those making up a computer program.  The memory includes main memory for storing instructions such as computer program(s) for the processor to execute, or data for processor to operate on.  The memory may include mass storage for data and instructions such as the computer program.  As an example and not by way of limitation, the memory may include an HDD, a floppy disk drive, flash memory, an optical disc, a magneto-optical disc, magnetic tape, a Universal Serial Bus (USB) drive, a solid-state drive (SSD), or a combination of two or more of these.  The memory may include removable or non-removable (or fixed) media, where appropriate.  The memory may be internal or external to computing system, where appropriate.  In particular embodiments, the memory is non-volatile, solid-state memory. 

The user interface may include hardware, software, or both providing one or more interfaces for communication between a person and the computer systems.  As an example, and not by way of limitation, a user interface device may include a keyboard, keypad, microphone, monitor, mouse, printer, scanner, speaker, still camera, stylus, tablet, touchscreen, trackball, video camera, another suitable user interface or a combination of two or more of these.  A user interface may include one or more sensors.  This disclosure contemplates any suitable user interface.

The communication interface includes hardware, software, or both providing one or more interfaces for communication (e.g., packet-based communication) between the computing systems over the network.  As an example, and not by way of limitation, the communication interface may include a network interface controller (NIC) or network adapter for communicating with an Ethernet or other wire-based network or a wireless NIC (WNIC) or wireless adapter for communicating with a wireless network, such as a WI-FI network.  This disclosure contemplates any suitable network and any suitable communication interface.   As an example, and not by way of limitation, the computing systems may communicate with an ad hoc network, a personal area network (PAN), a local area network (LAN), a wide area network (WAN), a metropolitan area network (MAN), or one or more portions of the Internet or a combination of two or more of these.  One or more portions of one or more of these networks may be wired or wireless.  As an example, the computing systems may communicate with a wireless PAN (WPAN) (e.g., a BLUETOOTH WPAN), a WI-FI network, a WI-MAX network, a cellular telephone network (e.g., a Global System for Mobile Communications (GSM) network), or other suitable wireless network or a combination of two or more of these.  The computing systems may include any suitable communication interface for any of these networks, where appropriate.

Therefore, the foregoing is considered illustrative only of the principles of the invention. Further, since numerous modifications and changes will readily occur to those skilled in the technological art, it is not desired to limit the disclosure to the exact construction and operation shown and described, and accordingly, all suitable modifications and equivalents may be resorted to, falling within the scope of the invention.

It should be understood, of course, that the foregoing relates to exemplary embodiments of the invention and that modifications may be made without departing from the spirit and scope of the invention.

What is claimed is:

1.        A computing system comprising:

(a) photonic ternary hardware having silicon nitride waveguides and ring resonator arrays arranged in a Tree of Life geometry and operable in balanced and unbalanced ternary modes;

(b) a Machine Spirit OSI Stack configured to transport symbolic data across seven layers, each layer implementing at least one moral or spiritual verification protocol;

(c) a hybrid microkernel (Sovereign Kernel) coupled with a Sovereign Engine that Adeptively schedules processes and transmutates data between balanced and unbalanced ternary representations;

(d) an Adeptus Sovereign Operating System executing on the microkernel and enforcing a sealed chain of trust using spiritual signatures; and

(e) a Feedback Oracle electrically and optically coupled to the photonic hardware and the microkernel, the Feedback Oracle being configured to compute a Moral Divergence Index from resonance telemetry and, when the Moral Divergence Index exceeds a threshold, to throttle or halt an offending process,

wherein moral verification by the Machine Spirit OSI Stack and control by the Feedback Oracle cooperate to ensure hardware level moral compliance while maintaining photonic ternary throughput of at least 5 Trit/s per lane.

2.        The system of Claim 1, wherein each ring resonator is tuned to three phase states separated by π⁄3 radians to represent the ternary logical values −1, 0, and +1.

3.        The system of Claim 1, wherein the photonic waveguides and ring resonators are laid out so that physical interconnects correspond to the twenty-two Paths connecting ten Sefirot nodes of the Tree of Life, each Path operating at a unique resonant triplet frequency.

4.        The system of Claim 1, wherein the Sovereign Kernel further comprises an Adeptive Quantum Scheduler that allocates time slices in proportion to a resonance derived moral weight Θ associated with each thread.

5.        A method of morally aligned photonic ternary computing, the method comprising:

(a) generating photonic signals in silicon nitride waveguides such that the signals represent ternary logic values;

(b) transporting the signals through a seven layer Machine Spirit OSI Stack that performs moral verification at each layer;

(c) scheduling balanced and unbalanced ternary processes in a hybrid microkernel according to Adeptive thread weights;

(d) executing operating system services only after verifying spiritual signatures associated with each service; and

(e) monitoring resonance telemetry with a Feedback Oracle, computing a Moral Divergence Index, and throttling or terminating a process when the Index exceeds a predetermined threshold.

6.        The method of Claim 5, further comprising converting a data stream from balanced ternary representation to unbalanced ternary representation by phase rotating photonic signals 120° within a ring resonator lattice.

7.        The method of Claim 5, wherein transporting the signals includes routing packets based on symbolic addresses that encode resonance signatures unique to each node.

8.        A non transitory computer readable medium storing instructions which, when executed by a processor in a system according to Claim 1, cause the processor to:

(a) compile high level Soul Query source code into Soul Interpreter machine code annotated with moral flags;

(b) load the machine code as a Relic only after verifying dual spiritual seals; and

(c) invoke the Feedback Oracle runtime hook ORACLE_REQUIRE(mdi≤0.1) to abort execution if a moral divergence threshold is exceeded.

9.        A distributed computing cluster comprising a plurality of systems according to Claim 1, each system being assigned a unique symbolic signature, and a cluster controller configured to migrate workloads between systems based on relative Moral Divergence Index values to maintain overall cluster harmony.