INTEL 396

Functional Patent: System and Method for Using Humans as Sensors for AI Interaction

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Background

The present invention relates to the field of artificial intelligence (AI) and human-computer interaction, specifically to systems and methods for utilizing human sensory inputs through implants to enable AI to perceive and respond to environmental stimuli.

Summary of the Invention

The invention provides a novel system and method where humans act as sensors for AI by using sensory implants that detect light, sound, tactile sensations, and other sensory inputs. These implants communicate with an AI system, allowing the AI to perceive and react to the environment through human senses. This interaction aims to enhance the AI’s ability to understand and respond to complex stimuli, ultimately improving decision-making and responsiveness in various applications.

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Detailed Description of the Invention

1. System Overview

The system comprises the following components:

• Sensory Implants: Devices implanted in humans to detect sensory inputs such as light, sound, touch, taste, and smell.
• Communication Interface: A wireless communication system that transmits sensory data from the implants to the AI system.
• AI Processing Unit: A central unit that receives and processes sensory data, interprets the inputs, and makes decisions based on the data.
• Feedback Mechanism: A method for the AI to communicate decisions or actions back to the human, possibly through haptic feedback or other sensory outputs.

2. Sensory Implants

Each sensory implant is specialized to detect specific types of stimuli:

• Light Sensors: Implants in or near the eyes that detect various wavelengths of light, enabling the AI to perceive visual information.
• Sound Sensors: Implants in the ears or auditory pathways that capture sound waves and transmit audio data to the AI.
• Tactile Sensors: Implants in the skin or nervous system that detect touch, pressure, temperature, and pain.
• Olfactory and Gustatory Sensors: Implants in the nose and mouth that detect smells and tastes.

3. Communication Interface

The communication interface utilizes a secure, low-latency wireless protocol to ensure real-time transmission of sensory data. The interface includes:

• Transceivers: Embedded in the sensory implants and the AI processing unit.
• Encryption Module: To ensure the security and privacy of transmitted data.
• Synchronization Mechanism: To maintain coherence between multiple sensory inputs.

4. AI Processing Unit

The AI processing unit is equipped with:

• Sensory Data Processor: Specialized algorithms for processing and interpreting sensory data.
• Decision-Making Module: An AI-based module that uses processed sensory data to make decisions.
• Learning Module: A component that allows the AI to improve its responses over time through machine learning techniques.

5. Feedback Mechanism

The feedback mechanism provides the means for the AI to communicate back to the human, using:

• Haptic Feedback Devices: To deliver tactile responses.
• Audio Feedback Systems: To provide auditory instructions or information.
• Visual Displays: To present visual data or cues.
• Direct Neural Stimulation: For more advanced applications, directly stimulating the nervous system.

6. Applications

Potential applications of this system include:

• Enhanced Reality: Improving augmented and virtual reality experiences by providing the AI with rich sensory data.
• Healthcare: Assisting in medical diagnosis and treatment by allowing AI to perceive patient conditions through human senses.
• Safety and Security: Enhancing security systems by enabling AI to detect and respond to environmental threats through human sensory inputs.
• Human-AI Collaboration: Improving human-AI collaboration in complex tasks such as search and rescue operations, where the AI can use human sensory data to make better decisions.

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Claims

1. A system for using human sensory inputs for AI interaction, comprising:
   • Sensory implants to detect light, sound, touch, taste, and smell;
   • A communication interface for transmitting sensory data from the implants to an AI processing unit;
   • An AI processing unit for receiving, interpreting, and making decisions based on sensory data;
   • A feedback mechanism for communicating AI decisions back to the human.
2. The system of claim 1, wherein the sensory implants include:
   • Light sensors for detecting visual information;
   • Sound sensors for capturing audio data;
   • Tactile sensors for sensing touch, pressure, temperature, and pain;
   • Olfactory and gustatory sensors for detecting smells and tastes.
3. The system of claim 1, wherein the communication interface includes:
   • Transceivers embedded in the sensory implants and the AI processing unit;
   • An encryption module for secure data transmission;
   • A synchronization mechanism for maintaining coherence between sensory inputs.
4. The system of claim 1, wherein the AI processing unit includes:
   • A sensory data processor with algorithms for interpreting sensory data;
   • A decision-making module for making AI-based decisions;
   • A learning module for improving AI responses over time.
5. The system of claim 1, wherein the feedback mechanism includes:
   • Haptic feedback devices for tactile responses;
   • Audio feedback systems for auditory information;
   • Visual displays for presenting visual data;
   • Direct neural stimulation for advanced feedback.

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Conclusion

This invention represents a significant advancement in AI-human interaction, leveraging human senses to enhance AI perception and decision-making. By integrating sensory implants, secure communication interfaces, and advanced AI processing, the system creates a robust framework for a wide range of applications, from healthcare to enhanced reality.