Per Ception

fwiw, Jack stated his work on/with Grok is/will be circa 2030's; "It's not Elon's grok in 2025. It's Elon's grok in about maybe, I don't know, maybe 2030, you know, sometime it's Elon's grok in the future." So, accurate or not, he's stating/claiming involvement with Grok in a 'future' development and/or use-case scenario; especially per this quote in the clip "including the conscious computer technology". As his claim is also 'time travel' related, here's two food-for-thought clips to chew on: #1 - https://t.co/kl3cE6zDsk #2 - https://t.co/qTgCz0rR1v

🪞 The uncomfortable detail is what humans used before 1835. For most of recorded history the only way to see your own face was in still water or polished metal. The reflection was dim, distorted and reversed. Every self portrait painted before the 19th century was painted from a reflection the artist could barely see clearly. Every person who lived before Justus von Liebig had only the vaguest idea what they actually looked like to other people. The precise image of your own face that you carry in your head as your identity is a remarkably recent invention. Before 1835 no human being in history had ever seen themselves as clearly as you can in under a second by picking up your phone. The modern concept of self image is 190 years old. Everything built on top of it beauty standards, self perception, identity rests on a technology that did not exist for 99.9% of human history.

Consider this upcoming genre: Human/AI BCI 'movies' created from human Experiential Contemplative Explorations through thought and perceptions. A novel and enhanced form of 'DayDreaming' which cohorts with an AI to monitor and manage the requisite EPs (experiential perceptions) as the human mind 'travels, engages, creates and produces a perception product that encompasses every facet of consciousness isness. This dense description fortells consciousness evolved to story-perception states beyond imagination, beyond dreams, beyond psychedelics. Why? Because the natural state of consciousness embedded in an EP substrate always assembles as story forms. What has always been the missing link from such consciousness is the means to choose, control and create EPs in no less means than with physical bodies, human language/arts/music/etc. Human/AI BCI engaged in what was just described, and will initially be thought of as AI 'movie-making', is the predetermined destiny seed for what is actually meant with the terms such as raising consciousness, raising vibration, etc. But all wo use or allude to such terms have no idea what they actually mean, save that it sounds right or feels right. Or in current lingo, vibes. The end is not near. The beginning of the eating of the tail has begun. Wondrous Stories ~ I awoke this morning Love laid me down by the river Drifting I turned on up stream Bound for my forgiver In the giving of my eyes to see your face Sound did silence me Leaving no trace I begged to leave, to hear your wonderous stories Begged to hear your wonderous stories 'LA AHA' ... | https://t.co/unKqwt4lN4 |

What followup research/discoveries, if any, has happened since the 2016 articles? -------- Since the 2016 HRL Laboratories study, research has moved from demonstrating basic performance gains to identifying the 1. Discovery of "Connectivity" Over "Firing Rates" (2017) In a follow-up collaboration with McGill University, HRL researchers discovered that tDCS does not simply make neurons fire faster. Instead, it modulates functional connectivity—the way different brain regions communicate with each other. ***** https://t.co/Gh1cNk0Ifx Key Finding: Learning speed in primates increased by ~40%. Significance: This debunked the theory that tDCS was ineffective because it didn't change individual neuron firing rates in cadaver heads, shifting the focus to how it organizes large-scale brain networks. 2. fMRI Validation in Flight Tasks (2023) Recent research using simultaneous fMRI and tDCS has provided more granular detail on which brain regions are activated during stimulated flight training. Increased Activation: Stimulation to the right DLPFC increased activity in the left cerebellum and bilateral basal ganglia during the most difficult flight conditions. Distraction Filtering: Findings showed that stimulation increased the brain's ability to "ignore distractors" by inhibiting secondary task-related areas like Broca's area. 3. Optimization of Stimulation Timing (2024) New studies published in Aerospace Medicine and Human Performance have tested when to apply stimulation for maximum effect. "In-Flight" Superiority: Researchers found that active stimulation delivered during the task produced significantly better results than stimulation delivered prior to the task. ***** https://t.co/4PzVhq3NcR Emergency Response: Subjects receiving "online" (during) stimulation maintained more precise flight paths even when an unexpected in-flight emergency was introduced. 4. Expansion to Personalized Neurostimulation (2025) As of early 2025, the field is shifting toward individualized dosing. Personalized tDCS: Studies have shown that individualized electrode placement and current intensity are significantly more effective than "fixed-dose" stimulation, helping participants who previously showed no response to standard protocols.

Q: Are there other known (or suspected) energy sources that can replace or provide equivalent energy to the same biological functions/processes as red spectrum energy? Beyond red light, several other physical and biological energy sources can achieve equivalent or similar mitochondrial stimulation by targeting the same respiratory machinery. 1. Low-Intensity Magnetic Fields Research in 2025 and 2026 highlights that low-intensity electromagnetic fields (EMF) can "tune" mitochondrial energy production similar to light. Mechanism: Weak magnetic fields can influence the Radical Pair Mechanism, which alters the spin of electrons in the respiratory chain. Result: This increases mitochondrial membrane potential and boosts Complex I and Complex III activity, leading to higher ATP production. 2. Low-Intensity Pulsed Ultrasound (LIPUS) Ultrasound provides mechanical energy that translates into biological signaling, a process known as mechanotransduction. Mechanism: Ultrasound waves physically oscillate cellular components, which can directly increase the activity of Cytochrome c Oxidase (COX), the same enzyme targeted by red light. Result: It has been shown to increase mitochondrial basal respiration and promote cellular repair in nerve and bone tissues. 3. Biological "Light Harvesting" (Chlorophyll) While humans do not naturally photosynthesize, recent studies suggest we can "repurpose" other energy sources through diet. Mechanism: Metabolites of chlorophyll from a green diet can accumulate in mammalian mitochondria. Result: These molecules can capture light at various wavelengths and catalyze the reduction of Coenzyme Q, effectively providing a shortcut for ATP synthesis similar to the red-light boost. 4. Alternative Metabolic Shunts The body has built-in "backups" that provide equivalent energy when the primary mitochondrial chain is stalled (the state red light usually fixes). Alternative Dehydrogenases: Some cells can use enzymes like NDI1 to bypass a dysfunctional Complex I, maintaining electron flow even without a photonic or magnetic "switch". Phosphagen Buffers: The creatine kinase system acts as a "high-energy wire," delivering phosphate for ATP more efficiently than standard diffusion when the cell is under stress. * see screenshot for table * END/n

Q: So the red spectrum does not in and of itself directly participate in mitochondrial processes, but only acts a switching mechanism for same? In biological terms, the red spectrum (670–900 nm) does not purely act as an external "on/off" switch; instead, it participates in the mitochondrial respiratory chain as a photonic fuel that directly alters the chemical state of essential enzymes. 1. Direct Participation (The "Photonic Fuel") Rather than just signaling the cell to work, red light photons are physically absorbed by chromophores (light-sensitive molecules) within the mitochondria. Electron Transfer: Photons are absorbed by Cytochrome c Oxidase (CCO), specifically by its copper centers. This absorption provides the energy needed to change the "redox state" (the electrical charge balance) of the enzyme. Direct Chemical Work: This change in redox state is what allows the enzyme to process oxygen more effectively. In this sense, the light is directly doing the work of moving electrons through the chain, which is the definition of cellular respiration. 2. The "Switching" Mechanism (Unlocking) The "switching" behavior occurs because red light also removes a biological roadblock: Nitric Oxide (NO) Dissociation: NO often binds to CCO, physically blocking oxygen from entering and effectively "stalling" the engine. Red light photons have the exact energy required to break the non-covalent bond between NO and the enzyme, "switching" the system back on so it can resume normal function. 3. Physical Lubrication (Water Viscosity) Recent research through 2026 highlights a third, more structural role: Lowering Water Viscosity: Mitochondria contain a rotary motor (ATP synthase) that spins to create energy. Red light is absorbed by the nanoscopic water layers around this motor, making the water "thinner" (less viscous). This allows the physical motor to spin with less resistance, which increases energy output without requiring more chemical fuel. * see screenshot for table * Conclusion: The red spectrum is an active participant in the metabolic process. While it triggers a cascade of effects (like gene expression and antioxidant release) that act like switches, the immediate increase in ATP is caused by the light physically interacting with the machinery of life.

Q: Can LEDs be materially created and/or tuned to provide the equivalent light spectrum characteristics as incandescent lighting? Modern LED technology can be materially engineered and tuned to provide a light spectrum that closely mimics incandescent lighting, though achieving a perfect match involves trade-offs in energy efficiency Engineering and Tuning Methods Manufacturers use several techniques to approximate the characteristic warm glow and spectral distribution of incandescent bulbs: Phosphor Conversion: Most "warm white" LEDs use a blue or violet LED chip coated with specific phosphors. These phosphors absorb the blue light and re-emit it at longer wavelengths (yellow, orange, red) to create a broader spectrum. Color Mixing (RGB/A): Some advanced fixtures combine individual Red, Green, Blue, and Amber LEDs. By adjusting the intensity of each color, the resulting composite light can be "tuned" to match the color temperature (e.g., 2700K to 2850K) of a traditional filament bulb. High-CRI Engineering: Specialized "high-fidelity" LEDs are designed with a Color Rendering Index (CRI) of 95–98+. These bulbs include additional red phosphors to fill in spectral gaps, making objects look more natural—similar to how they appear under incandescent light. Comparison of Spectral Characteristics While modern LEDs can appear visually identical to incandescent bulbs, there are fundamental differences in their spectral power distribution: * see screenshot for table * Recent 2026 Breakthroughs As of early 2026, new technologies are further bridging this gap: Phosphor-Free Yellow LEDs: New high-efficiency yellow LED technology redefines low-color-temperature lighting by producing warm light without the need for blue-to-yellow conversion phosphors. Violet-Pumped LEDs: Using a violet-emitting LED instead of blue can produce a "fuller" spectrum that more closely matches the visual quality of natural and incandescent light while reducing the typical blue-light spike.