Field Computing and Gebits May Be the Answer CTCE proposes transforming the topology of electromagnetic fields into a new foundation for computation, authentication, and consensus. At its core lies the Gebit — a unique vibrational pattern generated by specific physical conditions, impossible to replicate without the original emitter. Just as DNA uniquely identifies a living being, the Gebit becomes the vibrational signature of a digital and physical entity.

1. Field Signature Each CTCE device is capable of emitting Gebits with unique topologies, functioning as an energetic biometric imprint. This signature can: • Authenticate blockchain transactions with inviolable validation; • Prove custody of physical (RWAs) or digital (NFTs) assets; • Serve as a decentralized identity, immune to digital theft or forgery; • Preserve privacy and anonymity through a physically unique cryptographic layer.

2. Proof of Coherence Unlike traditional proof of work, which resolves arbitrary hashes, proof of coherence rewards the maintenance of stable Gebits in space and time. CTCE miners generate value by sustaining coherent resonance, creating a form of computing that is purposeful, energy-efficient, and informationally valuable per watt.

3. Vibrational Self-Custody The Gebit-emitting hardware generates its wallet based on entropy embedded in its physical configuration. There are no digital keys to hack — you are your wallet. Your signature is inseparable from the body that emits it. Like a vibrational NFT, your identity is uncopyable. Even in a world where everything digital can be cloned, your electromagnetic pattern cannot exist in two places at once. Combined with password-protected cryptography, this ensures anonymity, sovereignty, and immunity to remote attacks.

Advantages of CTCE • Native quantum resistance: independent of vulnerable mathematical algorithms; • Impossible to clone: Gebits require specific physical conditions — like trying to reproduce a thought without access to the mind that formed it; • Energy efficiency: coherence-based validation consumes fewer resources and produces useful topological knowledge; • Physical-digital integration: sensors validate context, location, and presence — ideal for RWAs; • Temporal locking: every Gebit is anchored to a timeline, preventing backdating or tampering; • True digital sovereignty: identity is self-hosted and cryptographically bound to its emitter.

Scalable and Practical Applications

1. NFTs with Vibrational Bodies • NFTs authenticated through Gebits ensure both digital and physical uniqueness; • Example: An artist mints an NFT tied to a CTCE device — it can only be transferred if the original field signature is present.

2. Physically Validated DAOs • Membership and voting validated by physical presence or specific CTCE devices; • MVP: DAO with smart contracts that recognize field signatures.

3. Tokenized Real-World Assets (RWAs) • Artworks, property, or commodities tokenized via Gebits linked to sensors; • MVP: Tokenization of a physical asset with real-time field validation.

4. Decentralized Identity (DID) • CTCE wallets act as sovereign identities, eliminating bureaucratic KYC steps; • MVP: A mobile app using local CTCE hardware for dApp authentication.

5. Cryptography for Restricted Environments • Use cases in aerospace, military, and biomedical sectors, where physical validation is critical; • Example: Satellites that authenticate communication via vibrational signatures.

Conclusion: A Revolution Begins CTCE does not replace blockchains — it transcends them. By anchoring authentication in the physics of electromagnetic fields, it establishes a layer of trust that protects identity, freedom, and self-custody in a vulnerable digital world. Gebits are more than signatures. They are the vibrational voice of a new computational era. Join us. Not just to mine blocks, but to sustain coherence. Not just to secure transactions, but to encode identity. Not to repeat the past — but to tune into the future.

CTCE Challenge:

Test the Future of Computing with Electromagnetic Fields!

Greetings, innovators!

I am an independent Brazilian researcher, and I invite you to be part of a technological revolution: Topological Computing of Electromagnetic Fields (CTCE). After years of studies and validations with artificial intelligence, my theory proposes processing information using Gebits – topological geometries of electromagnetic fields – with energy efficiency and massive parallelism. Now, we need you to test its foundations!

The Challenge: Three Phases to Prove CTCE Using accessible components (breadboard, Hall sensors, coils, LEDs), we propose experiments in three stages:

Phase 1: Build Basic Prototype Objective: Build a prototype that demonstrates the formation of Gebits, encoding simple data (e.g.: lighting LEDs in patterns). How: Follow the scheme that will be available here on the blog (soon). Use Hall sensors to detect fields and transducers to modulate signals. Deadline: 3 months (September 2025).

As exemplified in this simulation:

https://claude.ai/public/artifacts/3f77fb02-e6e5-40d3-bba9-9ae8d31ac304

Phase 2: Build a Simplified Calculator Objective: Create a basic calculator that performs operations (e.g., addition, subtraction) using Gebits in a processing volume. How: Adapt the prototype to process arithmetic logic via field interactions, with visual output (e.g., 7-segment display). Deadline: 6 months (December 2025).

Phase 3: Build and Run Doom Objective: Consolidate CTCE by running classic Doom (or a simplified version) with Gebits, processing graphics and logic in real time. How: Use the open source Doom code and simulate/process with Gebits, integrating topology sensors. Deadline: 12 months (June 2026). Incentive: Innovation: Test a technology that can revolutionize cryptography, DeFi, Bitcoin mining, and AI. Accessibility: Use cheap and common components, available in any maker lab. Impact: Contribute to a theory with the potential to change computing, with applications in self-custody and digital security.

Rewards: Earn 1 NFT CTCE Tokens (Polygon), as a record of participation and co-authorship in the project, for each completed phase, in addition to joining the team if you wish.

Who are we looking for? Developers: Programmers and electronics engineers to create prototypes. Academics: Physics and computer science researchers to validate simulations. Crypto Investors: Support the project with BTC donations or DeFi partnerships. Enthusiasts: Makers and gamers to experiment and spread the word.

Field Computing and Gebits May Be the Answer CTCE proposes transforming the topology of electromagnetic fields into a new foundation for computation, authentication, and consensus. At its core lies the Gebit — a unique vibrational pattern generated by specific physical conditions, impossible to replicate without the original emitter. Just as DNA uniquely identifies a living being, the Gebit becomes the vibrational signature of a digital and physical entity.

1. Field Signature Each CTCE device is capable of emitting Gebits with unique topologies, functioning as an energetic biometric imprint. This signature can: • Authenticate blockchain transactions with inviolable validation; • Prove custody of physical (RWAs) or digital (NFTs) assets; • Serve as a decentralized identity, immune to digital theft or forgery; • Preserve privacy and anonymity through a physically unique cryptographic layer.

2. Proof of Coherence Unlike traditional proof of work, which resolves arbitrary hashes, proof of coherence rewards the maintenance of stable Gebits in space and time. CTCE miners generate value by sustaining coherent resonance, creating a form of computing that is purposeful, energy-efficient, and informationally valuable per watt.

3. Vibrational Self-Custody The Gebit-emitting hardware generates its wallet based on entropy embedded in its physical configuration. There are no digital keys to hack — you are your wallet. Your signature is inseparable from the body that emits it. Like a vibrational NFT, your identity is uncopyable. Even in a world where everything digital can be cloned, your electromagnetic pattern cannot exist in two places at once. Combined with password-protected cryptography, this ensures anonymity, sovereignty, and immunity to remote attacks.

Advantages of CTCE • Native quantum resistance: independent of vulnerable mathematical algorithms; • Impossible to clone: Gebits require specific physical conditions — like trying to reproduce a thought without access to the mind that formed it; • Energy efficiency: coherence-based validation consumes fewer resources and produces useful topological knowledge; • Physical-digital integration: sensors validate context, location, and presence — ideal for RWAs; • Temporal locking: every Gebit is anchored to a timeline, preventing backdating or tampering; • True digital sovereignty: identity is self-hosted and cryptographically bound to its emitter.

Scalable and Practical Applications

1. NFTs with Vibrational Bodies • NFTs authenticated through Gebits ensure both digital and physical uniqueness; • Example: An artist mints an NFT tied to a CTCE device — it can only be transferred if the original field signature is present.

2. Physically Validated DAOs • Membership and voting validated by physical presence or specific CTCE devices; • MVP: DAO with smart contracts that recognize field signatures.

3. Tokenized Real-World Assets (RWAs) • Artworks, property, or commodities tokenized via Gebits linked to sensors; • MVP: Tokenization of a physical asset with real-time field validation.

4. Decentralized Identity (DID) • CTCE wallets act as sovereign identities, eliminating bureaucratic KYC steps; • MVP: A mobile app using local CTCE hardware for dApp authentication.

5. Cryptography for Restricted Environments • Use cases in aerospace, military, and biomedical sectors, where physical validation is critical; • Example: Satellites that authenticate communication via vibrational signatures.

Conclusion: A Revolution Begins CTCE does not replace blockchains — it transcends them. By anchoring authentication in the physics of electromagnetic fields, it establishes a layer of trust that protects identity, freedom, and self-custody in a vulnerable digital world. Gebits are more than signatures. They are the vibrational voice of a new computational era. Join us. Not just to mine blocks, but to sustain coherence. Not just to secure transactions, but to encode identity. Not to repeat the past — but to tune into the future.

CTCE Challenge:

Test the Future of Computing with Electromagnetic Fields!

Greetings, innovators!

I am an independent Brazilian researcher, and I invite you to be part of a technological revolution: Topological Computing of Electromagnetic Fields (CTCE). After years of studies and validations with artificial intelligence, my theory proposes processing information using Gebits – topological geometries of electromagnetic fields – with energy efficiency and massive parallelism. Now, we need you to test its foundations!

The Challenge: Three Phases to Prove CTCE Using accessible components (breadboard, Hall sensors, coils, LEDs), we propose experiments in three stages:

Phase 1: Build Basic Prototype Objective: Build a prototype that demonstrates the formation of Gebits, encoding simple data (e.g.: lighting LEDs in patterns). How: Follow the scheme that will be available here on the blog (soon). Use Hall sensors to detect fields and transducers to modulate signals. Deadline: 3 months (September 2025).

As exemplified in this simulation:

https://claude.ai/public/artifacts/3f77fb02-e6e5-40d3-bba9-9ae8d31ac304

Phase 2: Build a Simplified Calculator Objective: Create a basic calculator that performs operations (e.g., addition, subtraction) using Gebits in a processing volume. How: Adapt the prototype to process arithmetic logic via field interactions, with visual output (e.g., 7-segment display). Deadline: 6 months (December 2025).

Phase 3: Build and Run Doom Objective: Consolidate CTCE by running classic Doom (or a simplified version) with Gebits, processing graphics and logic in real time. How: Use the open source Doom code and simulate/process with Gebits, integrating topology sensors. Deadline: 12 months (June 2026). Incentive: Innovation: Test a technology that can revolutionize cryptography, DeFi, Bitcoin mining, and AI. Accessibility: Use cheap and common components, available in any maker lab. Impact: Contribute to a theory with the potential to change computing, with applications in self-custody and digital security.

Rewards: Earn 1 NFT CTCE Tokens (Polygon), as a record of participation and co-authorship in the project, for each completed phase, in addition to joining the team if you wish.

Who are we looking for? Developers: Programmers and electronics engineers to create prototypes. Academics: Physics and computer science researchers to validate simulations. Crypto Investors: Support the project with BTC donations or DeFi partnerships. Enthusiasts: Makers and gamers to experiment and spread the word.