The Deep Process of the Conscious Component Creates Timelessness

Humans invented the concept of time as a tool to manage life circumstances and pursue predictable outcomes. However, time itself may be an illusion. In philosophy and theoretical physics, time in a non-physical domain is often described not as a fundamental aspect of reality, but as a mental framework humans use to interpret change, causality, and sequences of events. In non-physical realms, time may lose relevance entirely, its flow may halt, dissolve, or operate under principles unlike those of the physical world, as reflected in fictional ideas such as the timeless Quantum Realm.

During extended periods of deep decision-making, the Conscious Component relies on algorithmic processes beyond its ordinary modules. These processes function through a Global Consciousness system, which operates on principles of timelessness. When the Conscious Component enters this state, it no longer sends signals to the brain regarding the passage of time or its internal activities.

As a result, the brain may not transmit signals about the body's physiological needs, such as hunger, thirst, and fatigue, because the Conscious Component is temporarily functioning outside the physical time algorithm. In this intensely focused state, the Conscious Component may not receive complete sensory or bodily information, creating the experience of detachment from the physical environment. Over prolonged periods, the existence of time itself becomes an obstacle to the processing taking place within Consciousness. (Fig. 1,2)

In contrast, the Subconscious Component operates through algorithmic codes shaped by environmental context. It functions similarly to an autopilot system, guiding routine behaviors and social interactions without requiring input from the Conscious Component's logical processes. Much of daily human behavior emerges from these subconscious modules rather than deliberate reasoning. Because the Subconscious Component is embedded in the physical environment, its algorithmic operations can alter one's perception of time. In these states, individuals may experience a sense of time being expanded or distorted within the physical world. (Fig. 1,2)

 

                                                                                   

 

                                                                               

Observation 1:

Because the brain is largely excluded from consciously participating in long-term planning, humans may experience a sense of timelessness along their evolutionary path. Thus, it arises from the hypothesis that the Conscious Component exists in a non-physical realm where time functions differently. Even so, the Conscious Component can still expand algorithmic awareness by running multiple threads that guide decision-making. These threads can structure sequential pathways and coordinate parallel layers of tasks in the physical world through the brain’s architecture. In this way, the Conscious Component enables humans to pursue and realize goals in material reality. However, even as the Conscious Component and the brain operate together, humans may continue to feel a sense of timelessness throughout their evolutionary development. The depth of the Conscious Component’s engagement in goal-driven decision-making can influence how strongly humans feel this timelessness phenomenon.

Illness can bind a person more tightly to the physical domain, as intense pain disrupts the vibrational frequencies associated with the Conscious Component and the non-physical realm, often accompanied by a heightened awareness of the prolonged passage of time. Consequently, those experiencing severe pain frequently perceive time as moving much more slowly. In contrast, states of happiness, love, and inner peace within the physical world can create and sustain intentions, wishes, and desires within the Conscious Component, where such impulses instantly form connective threads that influence the physical domain. Over time, individuals may even develop a sense of timelessness while remaining fully engaged within the existential physical world and the evolutionary path of life. A crucial key to activating algorithmic functions within the Conscious Component lies in consciously setting intentions that generate dynamic forces within it. Intention acts as an inner compass, guiding choices, sharpening focus, strengthening resilience, and enhancing overall well-being by aligning the individual with optimal algorithmic codes in the Subconscious Component. In this way, intention empowers people to live deliberately rather than reactively.

A Single Bias Network in the Brain Framework

When a single cognitive or perceptual network within the brain becomes distorted, often due to external pressures, environmental stressors, or maladaptive conditioning, it can disrupt the system’s broader neurosynchrony. This malfunction alters the brain’s vibrational frequency patterns, reshaping the algorithmic instructions that guide interpretation, prediction, and choice. As a result, the decision-making pathways diverge from the Brain Framework’s default functional architecture, causing misalignment with the mechanisms designed for coherence, adaptation, and internal stability. (Fig.1,2)

Such disruptions extend beyond individual cognition. When the brain’s natural synchronization algorithms fail to operate at their optimal range, the patterns that govern social behavior become compromised. Individuals may respond in ways that are mismatched to their environment, less adaptive, less resonant with social cues, and less capable of generating constructive relational dynamics. Over time, these misalignments can amplify feedback loops of confusion or conflict, resulting in chaotic conditions that extend not only to personal development but also to broader social structures. (Fig.1,2)

Within an interconnected world community, the cumulative effect of many such biased or desynchronized networks becomes increasingly significant over time. These disturbances shape collective behaviors, influence cultural norms, and may alter the trajectory of human systems. In this sense, a single bias network does not exist in isolation; it becomes part of a larger pattern that influences and is influenced by humanity’s shared ecological, social, and cognitive landscape. (Fig.1,2)

 

                                                                 

                                                                          

 

Observation 1:

Within the brain’s functional architecture, the corresponding network-level operational profile is situated primarily within the Conscious Component. At this level, multiple neural networks operate not as isolated processing units but as dynamically interacting systems. These default algorithmic codes communicate through patterned vibrational frequencies, exchanging algorithmic patterns that exceed the constraints of their own structural design. In fact, each network participates in a larger computational ecology, where information is continuously transformed, reinterpreted, and redistributed. (Fig.1,2)

Because of this integrative framework, a single biased code emerging in any one network can propagate across the system. Such a bias may extend from the Brain Framework into the Conscious and Subconscious Components, and vice versa, from the Conscious Component back into Brain-level processing. This bidirectional flow allows distortions, preferences, or misalignments within one domain to influence the other, sometimes subtly and sometimes dramatically. (Fig.1,2)

When biased codes enter the Conscious Component, they can directly affect the reshaping of algorithmic decisions, the interpretation of inputs, and the recalibration of instance parameters that guide moment-to-moment cognition. Over time, these influences may alter the system’s broader decision landscapes, modifying how information is evaluated, prioritized, or filtered. Figures 1 and 2 illustrate how these cross-component transmissions occur, highlighting the pathways through which vibrational integration and eventually, a new algorithmic exchange reshape the brain’s operational dynamics.