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A summary of the existing provisional and non-provisional patent applications, including their filing dates, application numbers, and claims relevant to resonant frequency computing (also referred to as harmonic quantum computing), is provided. **I. Strategic Overview of Patent Portfolio for Resonant Frequency/Harmonic Quantum Computing** The patent applications comprise a multi-layered intellectual property (IP) strategy designed to protect a new paradigm for quantum computing, transitioning from particle-centric systems to a robust, probabilistic, and bio-inspired analog framework. This strategy proceeds through a two-stage roadmap: from a cryogenic proving ground to an ambient bio-processor. The current patent draft for a "harmonic qubit" system is positioned as a novel _physical architecture_ optimized for a class of qubits where the quantized electromagnetic field state within the resonator is the qubit itself, not a field used to interact with discrete qubits. **II. Provisional Patent Applications Relevant to Resonant Frequency/Harmonic Quantum Computing** A. **Title:** Bio-Inspired Platform for Enhanced Quantum Coherence - **Application Type:** Utility - Provisional Application under 35 U.S.C. 111(b) - **Application Number:** 63/751,887 - **Filing Date:** January 31, 2025 - **First Named Inventor:** Rowan Brad Quni (Joint inventor listed in ADS: Bradley Gudzinas). - **Confirmation Number:** 6814 - **Relevant Claims/Inventive Concept:** This application provides a bio-inspired platform for enhancing quantum coherence. It incorporates structures derived from or inspired by biological components, such as neuronal microtubules, plant microtubules, bacterial cytoskeletons, or viral capsids, which sustain vibrational energy transfer at quantum-relevant frequencies. Mechanisms for coherence enhancement include phonon-mediated interactions, electron tunneling, and entanglement. The invention also encompasses synthetic and hybrid systems, such as artificial nanotubes or graphene-based materials, engineered to replicate these quantum coherence-enhancing properties. This application serves as foundational IP for enabling ambient-temperature bio-inspired processors, a future stage of development. B. **Title:** Quantum Processing Unit with Bio-Inspired Lattice Structure for Enhanced Qubit Coherence and Scalability - **Application Type:** Utility - Provisional Application under 35 U.S.C. 111(b) - **Application Number:** 63/751,846 - **Filing Date:** January 31, 2025 - **First Named Inventor:** Rowan Brad Quni - **Confirmation Number:** 2074 - **Relevant Claims/Inventive Concept:** This provisional describes a device and method that are structurally and functionally distinct from existing solutions. Key structural features include: - A bio-inspired, microtubule-like lattice structure (cylindrical, hexagonal geometry) that provides a tailored electromagnetic environment for qubits, designed to minimize decoherence. - A room-temperature stable hydrogel dielectric filling the lattice structure, mimicking ordered water in biological microtubules, with a high dielectric constant and low loss tangent at 10-30K. - Integration of high-temperature superconducting (HTS) materials (e.g., YBCO) for operation at 10-30K, a significant increase over millikelvin requirements. - A self-healing feature incorporating phase-change polymers for autonomous repair of microfractures. - Transmon qubits are integrated at specific nodes of the lattice structure. - Photonic interconnects (silicon nitride waveguides) enable optical control and communication. The associated method employs the microtubule-inspired lattice geometry to create a tailored electromagnetic environment that minimizes qubit decoherence, utilizes the hydrogel dielectric for enhanced coherence, and integrates HTS materials for higher temperature operation. The fabrication process involves creating the complex 3D lattice structure using CMOS-compatible methods and incorporating the hydrogel dielectric at room temperature. This invention aims to provide enhanced qubit coherence and scalability at elevated temperatures. C. **Title:** Analog Quantum Observation and Simulation System Using Non-Collapsing Probabilistic States - **Application Type:** Utility - Provisional Application under 35 U.S.C. 111(b) - **Application Numbers and Filing Dates:** - 63/766,414, filed March 04, 2025. - 63/772,770, filed March 17, 2025. - 63/780,399, filed March 30, 2025. - **First Named Inventor:** Bradley Gudzinas. - **Confirmation Numbers:** 4976 (for 63/766,414), 9723 (for 63/772,770), 8318 (for 63/780,399). - **Relevant Claims/Inventive Concept:** This invention relates to analog quantum computing and information theory, proposing systems and methods for observing natural quantum processes without measurement-induced collapse and simulating them in analog computing machines. It leverages probabilistic, non-binary frameworks. Key innovations include: - Non-destructive quantum observation using Quantum Non-Demolition (QND) sensors or holographic detectors. - Analog quantum simulation hardware (e.g., superconducting circuits, photonic qumodes) for processing observed states as continuous probabilistic signals. - Rheostat-like quantum control mechanisms (e.g., tunable couplers, flux qubits) for probabilistic adjustment of quantum states, avoiding binary collapse. - Bio-inspired neuromorphic architectures, specifically microtubule-based qubit arrays, acting as quantum receptor sites for analog processing. - Liquid dielectric shielding for ambient-temperature operation. - A concept for utilizing decoherence as a controlled process. This patent translates an abstract information-theoretic framework into a functional, tangible system architecture. D. **Title:** Phase-Encoded Information System for Unified Storage and Processing - **Application Type:** Utility - Provisional Application under 35 U.S.C. 111(b) - **Application Number:** 63/784,100 - **Filing Date:** April 06, 2025 - **First Named Inventor:** Bradley Gudzinas - **Confirmation Number:** 9975 - **Relevant Claims/Inventive Concept:** This provisional focuses on a phase-encoded information system. While claims are not explicitly detailed in the provided sources, the title suggests relevance to the analog, continuous-variable processing aspects described in other applications, potentially using phase as an encoding mechanism for quantum information, which aligns with "encoding information in amplitude, phase, or frequency of analog signals". E. **Title:** Integrated Nanoscale Quantum Shield for Enhanced Coherent Operation at Elevated Temperatures - **Application Type:** Utility - Provisional Application under 35 U.S.C. 111(b) - **Application Number:** 63/824,935 - **Filing Date:** June 17, 2025 - **First Named Inventor:** Bradley Gudzinas - **Confirmation Number:** 4105 - **Relevant Claims/Inventive Concept:** This application describes integrated, multi-functional nanoscale shielding structures and tailored materials fabricated in proximity to a quantum medium. These structures locally engineer the environment (e.g., electromagnetic, phonon, thermal) by filtering, absorbing, or redirecting noise based on temperature-dependent material properties. This enables high coherence (long T2, low error rates) at significantly elevated cryogenic temperatures (4K, 77K, potentially >77K or room temperature), which reduces cryogenic overhead and enhances scalability, yield, and robustness across various qubit platforms. The invention addresses quantum decoherence necessitated by complex millikelvin cryogenics and external shielding. **III. Non-Provisional Patent Applications Relevant to Resonant Frequency/Harmonic Quantum Computing** A. **Title:** Bio-Inspired Platform for Enhanced Quantum Coherence - **Application Type:** Utility - Nonprovisional Application under 35 U.S.C. 111(a) - **Application Number:** 19/043,486 - **Filing Date:** February 02, 2025 - **Claims Benefit of:** U.S. Provisional Patent Application No. 63/751,887, filed January 31, 2025. - **First Named Inventor:** Rowan Brad Quni (Joint inventor listed in ADS: Bradley Gudzinas). - **Confirmation Number:** 8526 - **Relevant Claims/Inventive Concept:** This non-provisional application directly builds upon and formalizes the provisional application 63/751,887. Its claims encompass a platform for enhancing quantum coherence using structures derived from or inspired by biological components, such as neuronal microtubules, or synthetic mimics. The platform aims to sustain vibrational energy transfer at quantum-relevant frequencies and enhance coherence through phonon-mediated interactions, electron tunneling, and entanglement. This application specifically protects the enabling hardware for bio-inspired and ambient-temperature quantum computing. B. **Title:** Liquid Shielded Quantum Device - **Application Type:** Utility - Nonprovisional Application under 35 U.S.C. 111(a) - **Application Number:** 19/043,521 - **Filing Date:** February 03, 2025 - **Claims Benefit of:** U.S. Provisional Patent Application No. 63/751,887, filed January 31, 2025. - **First Named Inventor:** Rowan Brad Quni (Joint inventor listed in ADS: Bradley Gudzinas). - **Confirmation Number:** 1143 - **Relevant Claims/Inventive Concept:** This non-provisional specifically claims a "Liquid Shielded Quantum Device." This directly relates to the "liquid dielectric shielding for ambient-temperature operation" innovation outlined in the "Analog Quantum Observation and Simulation System" patent, and the "Room-Temperature Stable Dielectric (Hydrogel)" described in the "Quantum Processing Unit" provisional. The concept involves protecting quantum activity sites from environmental noise using liquid dielectrics or cytosolic shielding mechanisms, inspired by cellular systems. This is a revolutionary claim that challenges the cryogenic paradigm by proposing coherence maintenance at ambient temperatures. C. **Title:** Phase-Encoded Information System for Unified Storage and Processing - **Application Type:** Utility - Nonprovisional Application under 35 U.S.C. 111(a) - **Application Number:** 19/171,267 - **Filing Date:** April 06, 2025 - **First Named Inventor:** Bradley Gudzinas - **Confirmation Number:** 1693 - **Relevant Claims/Inventive Concept:** This non-provisional application is the continuation of provisional 63/784,100. While the specific claims are not detailed, the title "Phase-Encoded Information System" suggests a focus on methods of encoding and processing information using phase, which aligns with analog quantum simulation hardware that avoids binary discretization by encoding information in amplitude, phase, or frequency of analog signals. This implies continuous-variable operations relevant to resonant frequency computing paradigms. **IV. Collective Relevance to Resonant Frequency Computing (Harmonic Quantum Computing)** The collective body of applications outlines a comprehensive strategy for advancing resonant frequency (harmonic) quantum computing. - The foundational concept involves using the **quantized electromagnetic field state within a resonator as the qubit itself** (h-qubit), rather than using fields to interact with discrete qubits. This shifts the paradigm towards "bosonic qubits". - The novelty of the h-qubit system lies in its **holistic, system-level approach**, specifically the combination of a **3D superconducting lattice architecture**, a **tailored cryogenic dielectric filler**, and **integrated nanoscale multi-modal noise mitigation**. - Specific claims for the 3D lattice of interconnected cavities (Claim R1) and the unique dielectric filler (hydrogel/ordered liquid) (Claim R3) are present in the current draft. - Integrated nanoscale quantum shields are further detailed to provide enhanced coherence at elevated temperatures, aiming to reduce cryogenic overhead. - The portfolio strategically addresses **prior art in Circuit Quantum Electrodynamics (cQED)** by distinguishing the invention as a novel _physical architecture_ optimized for field-state qubits, rather than merely using cavities to mediate interactions between discrete qubits. - A key aspect is the transition from current cryogenic systems to **ambient bio-processors**. This involves: - Developing **bio-inspired lattice materials** that mimic the resonant field properties of cryogenic superconducting lattices but operate at room temperature, leveraging structures like neuronal microtubules. - Utilizing **bio-inspired liquid dielectrics or hydrogels** to replace cryogenic dielectrics, mimicking natural shielding mechanisms. - The "Analog Quantum Observation and Simulation System" patents introduce methods for **non-destructive quantum observation** and **rheostat-like quantum control**, which are essential for manipulating continuous probabilistic states inherent to harmonic quantum computing. This system explicitly claims "bio-inspired qubit arrays" and "liquid dielectric shielding for ambient-temperature operation". - The strategic value lies in owning both the problem's definition in the cryogenic domain and its potential elegant solution in the bio-inspired, ambient domain, thereby creating a defensible IP position. The cryogenic requirement for current harmonic quantum computing is justified by the necessity to eliminate thermal noise and enable superconductivity for high-Q resonators. This contrasts with hypothesized quantum biology, where sophisticated natural shielding mechanisms are proposed. The engineered systems are currently incapable of room-temperature operation with equivalent coherence without such external cooling. However, the development roadmap explicitly plans to replace this "brute force" cooling with biomimicry in future stages.