Friday, May 10, 2024

The Proxy Brain Framework

The Proxy Brain Framework serves as a mediator and interpreter of the intricate patterns connecting algorithmic codes within the Subconscious Component and the physical body. The Subconscious Component operates through preprogrammed codes and instinctual decision-making patterns. In contrast, the Conscious Component contributes logical, depository codes that support the formation of optimal choices.
The brain acts as the executor within this framework, managing processing cycles and transmitting algorithmic codes to the appropriate regions of the physical body. It governs all internal processing loops, dynamically shifting between open-loop and closed-loop instinctual modes in the Subconscious Component.
While the brain regulates current processing cycles, it cannot anticipate future decision models or respond proactively to evolving environmental demands. Its function is primarily regulatory, synchronizing the exchange of information between the Subconscious Component and the physical body.
Nevertheless, the brain framework maintains holistic awareness of serial decision-making sequences. It integrates various inference procedure blocks, aligning them with distinct time intervals. Though the Conscious and Subconscious Components share identical data units and network structures, the brain's complex and diverse networks can obstruct seamless integration with the more homogeneous networks of the Conscious/Subconscious domains.
Bridging this structural disparity requires vibrational frequency modulation, harmonizing data flow across these domains. Executed codes within the Decision-Making Map propagate through these vibrational frequencies, facilitating communication and coordination.

Example Scenario: Iterative Instinctual Cycle in a Drinking Water Task
 
The five-step synthetic process illustrates how instincts guide a simple, goal-directed action. Each step activates a vibrational resonance that forms a handshake between the Conscious Component and the Brain Framework, allowing the delivery and encoding of data into memory. This synchronization enables the brain to comprehend and anticipate the iterative pattern of actions as follows:
 
1- Walk ten yards toward the water bottle behind a closed door.
2- Pick up the key from the table.
3- Use the key to unlock and open the door.
4- Retrieve the water bottle from the shelf.
5- Drink the water.
 
Each stage in this process reflects a dynamic interaction between instinctual impulses and conscious awareness, mediated by the Proxy Brain Framework.
 

  
                                                                               

 
 
During the initial phase, the brain's memory system allocates algorithmic codes from the Subconscious Component and encodes them for transmission to the physical body. In the subsequent phase, the outcomes of actions, particularly within social contexts, are relayed back to the Subconscious Component through the Brain Framework, completing a feedback loop.
The Conscious Component organizes this process by utilizing distinct frequency bands to categorize and segregate memory segments within the brain, functioning as a primary cache. Daily interactions generate analogical algorithmic codes from Consciousness, which can be reproduced through the physical body as repeated or habitual actions.
Persistent data, especially that associated with reinforced experiences, may be labeled, stored within cellular memory, and later retrieved to enable faster or more efficient decision-making. However, despite this capacity for storage and replication, the Brain Framework remains limited: it cannot independently predict future decision models based solely on previously encoded patterns from the Conscious and Subconscious Components. (Figure 2)

 
                                                                                   

 
 
 
 Refined Observations on the Proxy Brain Framework and Algorithmic Decision Models
 
Observation 1: 
Within the Conscious Component, secondary memory retains long-term algorithmic data securely, serving as a repository for enduring information. In contrast, the Brain Framework's primary memory temporarily stores daily data for short-term access. Upon the biological system's extinction, this transient data seamlessly migrates to the secondary memory system within the Conscious Component, ensuring continuity.
 
Observation 2:
Human strategies for navigating social and existential challenges can be explored beyond the limitations of traditional academic paradigms. Establishing a transdisciplinary research platform that bridges academic rigor with universal insights and integrative principles can significantly advance our understanding of human behavior and contribute meaningfully to global progress.
 
Observation 3:
Optimal algorithmic codes within the Decision-Making Map are contingent upon achieving harmonic equilibrium between the Ego and Superego frameworks, the ideal activation of adaptive instincts, and the systematic deactivation of the Old open-loop instinct cycles (starvation instincts).
 
Observation 4:
Accurate decision modeling requires optimal alignment among the Subconscious, Conscious Components, and the Brain Framework. This alignment depends on a universal structure of compatible attribute type settings, where default attribute sets represent counterpart values within each domain. Resilient, encapsulated algorithms can be activated to address and transcend complex barriers to alignment.
 
Observation 5:
The Brain Framework is susceptible to disturbances and modifications caused by deterministic chaos factors, both internal (e.g., physical body dysfunctions) and external (e.g., socio-environmental variables beyond the subconscious/conscious reach). When multiple aggressive instincts are concurrently activated, they may deploy hostile or disruptive code patterns within the Decision-Making Map, functioning analogously to malware within biological systems.
 
Observation 6:
External stimuli can invoke decision-making processes beyond primitive instinctual reactions by integrating higher-order algorithmic patterns. A solitary real-world action may not always elicit a direct instinctual response. Instead, stored data within the brain's memory, linked to the Subconscious Component, can facilitate execution without direct subconscious engagement.
 
Observation 7:
External stimuli may initiate open-loop phases in instinctual cycles. Once triggered, the instinct's processing cycle must proceed through a sequence of actions followed by uninterrupted completion, ultimately achieving a closed-loop condition. These cycles originate from instincts that extend beyond the Subconscious Component and resonate through the Brain Framework via vibrational frequencies. The brain's memory retains awareness of these multiple concurrent instinctual processing cycles.
 
Observation 8:
By integrating with a robust central system, both Biological and Non-Biological Subsystems can bolster community resilience by reducing systemic vulnerability. These subsystems collaboratively address trauma and instability while operating under broader global variables and invisible regulatory functions defined and dictated by the central system. As they navigate multiple open-loop cycles of instincts, the subsystem of subconsciousness may encounter disorientation when adapting their decision-making models to a larger, dynamic environment.
 
Observation 9:
Goodwill, expressed through kindness and fairness toward nature and humanity, correlates with an optimal Network of Cooperative Instincts within the Subconscious Component. In contrast, humans embedded in aggressive environments often manifest a dominant Network of Competitive Instincts, which hinders the integration of friendly behaviors into the Decision-Making Map. Acts of goodwill represent foundational elements of harmonious social justice. Resilient logical structures in the Conscious Component and cooperative instinct networks can revitalize the Old open-loop cycle of instincts and redirect competitive tendencies toward more collaborative outcomes.
 
Observation 10:
System designers can refine the inherent characteristics of both Biological and Non-Biological Systems to achieve adaptive synchronization with evolving environmental conditions. While conceptual design depends on the logical integrity of operational frameworks, any unauthorized alteration of default algorithmic codes may result in unforeseen irregularities and disruptions in system performance.
 
Observation 11:
The Subconscious Component contains diverse instinctual arrays, each designed to sustain specific algorithmic behaviors supported by lifelong logical data accumulated in the Conscious Component. External stimuli can activate open-loop cycles within the Survival Instincts. The processing cycle, in turn, may call and activate numerous instincts to execute a single specific task within the Subconscious Component. These instincts collaborate to construct a multi-layered decision-making algorithm embedded within a complex map.
Different groups of instincts align to create unique decision-making models, reflecting the intricate interplay between various subconscious processes. In chaotic social environments, overlapping aggressive instincts can collide, resulting in paradoxical behaviors and erratic conduct, shaped by subconscious and conscious conflicts.

 

 

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