Introduction
Envisioning the future is, at its core, an exercise in imagination. Some of the prognostications presented here may forever remain speculative, never materializing in reality. The primary objective of this endeavor is to construct plausible scenarios, and as the methodology becomes more systematic, its applicability will likely increase.
For those resistant to mental flexibility, the forthcoming information may prove challenging to assimilate and could elicit aversion. Delving into future predictions and contemplating potentialities is, in itself, a cognitive journey, a process of learning. I dedicated each day to pushing the boundaries of my forecasts, striving to explore their limits. This same drive propels me across various domains of knowledge, where I apply it to every scientific field I have either comprehended or found intriguing.
It's essential to note that what follows departs from conventional, mundane information sharing. Feedback suggests that my works often induce cognitive overload, demanding substantial mental effort to process and, in some cases, causing a sense of lethargy.
This endeavor is not intended for judgment as inherently good or bad. Instead, it aims to forecast potential futures, offering viewers a heightened understanding of their influence over the unfolding stages of convergence, as elaborated upon in the subsequent sections.
As time progresses, we find ourselves subject to change. The realities we shape become the spheres within which we exist—an intricate interplay of possible material existence impacting biology, industry, and machines.
A prevailing theory posits that the resources essential for computers, alternative energy, and all things electrical may eventually become scarce. The growth of the population exacerbates the rarity of these resources. In such a future, the specter of war looms—specifically, a resource war. This represents one facet of conflict, while another manifests as ideological strife. In the event of resource scarcity, warfare might echo the Cold War or escalate into a nuclear conflict with devastating consequences, or it could take the form of nations engaging in a technological war. The latter could involve the militarization of machines, particularly robotics, as factions employ them to vie for dominance—a topic briefly discussed in a previous blog.
Strategies to Mitigate Resource Wars:
- Population Reduction: Incentivizing Family Planning: Encouraging adults to voluntarily limit reproduction can be a pivotal strategy. By offering incentives for responsible family planning, individuals may be more inclined to contribute to a reduction in the overall population.
- Euthanasia as a Personal Choice: Providing individuals with the autonomy to choose euthanasia for those who find life unbearable can be a controversial yet pragmatic approach. This not only respects personal autonomy but also contributes to population control.
- Transition to Alternative Resources: Substituting Scarce Resources: Identifying and replacing high-demand scarce resources with sustainable alternatives, particularly regenerative resources, can alleviate the strain on essential materials. This transition not only ensures resource availability but also promotes environmental sustainability.
- Achieving Stage 3 of Convergence: Semblance of Convergence: Attaining a semblance of stage 3 of convergence is a crucial milestone. This involves harmonizing various aspects of technological, social, and economic progress. A holistic convergence can enhance resource management, mitigate conflicts, and foster a more sustainable coexistence.
Implementing these strategies collectively can contribute to a more sustainable and resource-conscious future, reducing the likelihood of resource wars and promoting global stability.
Every instance of warfare signifies our failure to recognize the potential inherent in the existence of stage 3 convergence. It is a lack of creativity that constrains us from attaining boundless abundance and infinite space for life and sentience to flourish. Understanding this paradigm may render the prospect of the next war significantly less likely.
Should we successfully sidestep global conflict or if a nation possesses the resources essential for technological advancement, I anticipate a convergence among machines, industry, and biology. The avoidance of war-driven extinction scenarios will inevitably propel us toward the convergence of technology.
This convergence can be viewed as a percentage—a measure of the extent to which we transition into stage 3. The decision to embrace this convergence and eliminate existing paradigms lies squarely within the realm of our intelligence. It becomes a pivotal choice that determines our trajectory and the shape of our coexistence with technology, industry, and biology.
With 100 convergence in one society, there may be near 0 convergence in another. Societies can exist from what I call the Black Box of Primitives to the White Room of Utopia. Each unit, exists as a potential within the structure of the universe. We can bring each stage into existence, or take it out, depending on our demands. Our hardest liberty to achieve comes from realizing what systems we can live with in, and how to go about changing them. We can live according to how we want to live, and how our work, and technology permit our existence.
The three units are:
Industry – anything to do with production and consumption.
Biology – anything to do with the structure and functions of life.
Machine – anything to do with the structure and functions of a non-living mechanical and computing device.
Here is a summary of what the 3 convergent stages are.
Stage 0, is 0 percent convergence, almost impossible given that all machines effect biology somehow in industry. Outside of the three main sets there exist the black box of primitive or archaic economy/living. Such societies exist all over the world, and there are groups of people who ally together to form communal living based on all natural, or non-technical dependance on nature.
Stage 1 is a 1-49 percent convergence
Stage 2 Is 50-90 percent convergence
Stage 3 is complete or nearly complete convergence
These can be adjusted, so as to make one not linked to the others by a percentage, but overall this is a likely convergence that will happen without man thinking of the stage as not just transitional but mutable by the will of the intelligence. We are just moving into stage 1. It may take a thousand or more years to fully move into stage 3.
Each set in the diagram is known to have elements. I do not yet have the means to produce a set up of a diagram presenting all elements for each and every set, but this is something that can be done by an set theorist and developed in visuals by animators.
Let us look at what machines can do within in these converging scientific units of creation.
Industrial machine technology unit:
1. Transportation –
Stage 1
A) Evolution of Human Transportation:
The journey from the invention of the wheel to our contemporary modes of transportation has been remarkable, yet the fundamental need for swift mobility remains constant. In our current advanced transportation landscape, encompassing cars and aerial vehicles, two critical questions arise.
Firstly, considering our present capabilities, what resources can we employ to manufacture cars that are entirely recyclable? Secondly, addressing safety concerns, how can we eliminate the necessity for car insurance and eradicate car accidents altogether? Envisioning a future where cars are no longer owned individually, one can imagine a system where diverse styles of cars are available for order from local garages. These autonomous vehicles come equipped with the requisite information to navigate routes to workplaces, stores, restaurants, and community entertainment venues.
By scheduling drives in advance, we could eliminate wait times between orders, transforming the transportation experience.
B) Automation in Aviation:
For airplanes, including cargo and passenger airliners, envisioning a future where automation takes center stage is conceivable. The prospect of fully automated processes managing these aerial vehicles holds promise for increased efficiency and safety.
C) Automation on Water:
Looking ahead, it's plausible to imagine a future where boats and all water vehicles become fully automated. Automation in maritime transport could revolutionize the industry, enhancing safety and efficiency across various water-based activities.
Stage 2
In the evolution beyond our current state, humans, or their transformed counterparts, will no longer rely on traditional roads or streets. Instead, the landscape will feature output-input teleportation portals. As we advance into Stage 2, the prospect of lunar colonization opens up, introducing the possibility of teleportation across space. While teleporting living entities remains one facet, the probability of teleporting objects, structures, and more machine-like entities becomes increasingly plausible. As teleportation capabilities expand, the reliance on conventional vehicles diminishes, signifying a transformative shift in our approach to mobility.
Stage 3
In this advanced stage, the capacity for teleportation persists, although necessity gives way to desire. The need for conscious transportation diminishes as biology and life seamlessly merge with machines. Machines, fueled by electrons and interconnected through interdimensional channels, process data and fabricate materials using a revolutionary concept known as quantum mental construction. Quantum mental construction involves duplicating atoms and utilizing them in the creation of virtually anything. This process represents the culmination of the ultimate stages of quantum computing, bridging the gap between biological and artificial entities and ushering in an era where transportation becomes not just effortless but a matter of personal choice. What is quantum mental construction? It is a duplicating of atoms and then using them to construct anything. It is the result of the ultimate stages of stage 2-3 quantum mechanics.
*Of course I am not saying that robot-life will have to just sit there and do nothing but compute data inside itself, living within in a virtual reality of its own mind, but rather that is a possible style of robotic life, and it requires nothing but electrons, (energy) a conscious computer, and virtual world able to be designed and and lived in different phases. I will get into this stage more as I work my way through the stages and units of convergence.
2. Construction
A) Homes
Stage 1
Jacque Fresco envisions a future in which essential utilities such as plumbing, air conditioning, electricity, internet, cable, and heating are seamlessly integrated underground. This innovative approach not only eliminates the visual clutter of electric poles and cables but also provides protection against various weather conditions, insulated by durable metal and water-resistant materials.
The construction of homes will undergo a transformative process, beginning with the creation of a blueprint house inside an empty model. The materials used in building these homes, including the models themselves, could be entirely reusable. This revolutionary concept, facilitated by robots, allows individuals to effortlessly switch between homes at will, bringing the concept of portable living to a new level.
Internet connectivity will be ingrained in the very infrastructure of these homes, or be set up with satellite (Starlink) accessible through any computer. The future may see the advent of robot workers capable of efficiently creating all necessary plumbing and wiring in a home as and when needed, further streamlining the construction and maintenance processes.
Stage 2
A more efficient technology is one with out wires, making plumbing the only needed construction. When we get into teleportation, even using star-gate-like technology there will be no more plumbing, no cables whatsoever, and homes could be teleported directly to a location. Advanced nano-technology may also make it possible to create a home, and all furnishings with a heap of recyclable material. That is at the far end of stage 2. Robots can currently put together homes at building sites (2022)
Homes may also be built underseas. Creating underwater homes, as well homes in orbit of any body, as in moons or planets. These will also become more possible as we move into higher stage 1 and stage 2-3.
These homes will only need exist for so long, that is until biology has completely merged with machine. As this is not possible with industry alone, the possibilities will be referred to in the bio-machine section. Reusable building materials, robot construction, and robot relocation, are great benefits of this possible technology. These might come before teleportation and the development of nano-bots. As a conclusion think about the benefits of robot technology and nano-bot technology: Robot builders, redesigning your home when ever you had time to, not having to work in hard labor.
Stage 3
There might be domes which inside rest conscious computers. Robots and humans might still want to live as in lower stages and therefore there would be maintenance of different convergent stages in societies. However, conscious computers only need shelter from whether and a way to exit the computers if they no longer want to exist in the virtual realities they create for themselves.
B) Landscaping –
Stage 1
The capabilities of machine technology extend far beyond home construction. In a future envisioned by Jacque Fresco, streets, sidewalks, and entire entertainment facilities such as malls and restaurants could be erected using sophisticated robot technology, provided they are crafted with precision and equipped with optimal programming.
These robots would not only excel at laying down essential foundations, likely made of durable and easily reusable materials such as cement, but also showcase the ability to excavate grounds for the creation of reservoirs capable of storing and filtering water throughout the year. This multifunctional approach not only streamlines the construction process but also addresses critical infrastructure needs, ensuring sustainability and efficiency in urban planning.
Imagine a cityscape where robot workers seamlessly collaborate to construct and maintain every aspect of the urban environment, from the foundational structures to intricate amenities, all while adhering to eco-friendly practices. This vision presents a paradigm shift in construction methodologies, emphasizing the potential for automation to enhance the functionality and aesthetics of our built environments.
Stage 2
These robots would not only excel at laying down essential foundations, likely made of durable and easily reusable materials such as cement, but also showcase the ability to excavate grounds for the creation of reservoirs capable of storing and filtering water throughout the year. This multifunctional approach not only streamlines the construction process but also addresses critical infrastructure needs, ensuring sustainability and efficiency in urban planning.
Imagine a cityscape where robot workers seamlessly collaborate to construct and maintain every aspect of the urban environment, from the foundational structures to intricate amenities, all while adhering to eco-friendly practices. This vision presents a paradigm shift in construction methodologies, emphasizing the potential for automation to enhance the functionality and aesthetics of our built environments.
Stage 2
As already mentioned in the first stage 2 description, streets and buildings will become ever the more sparse as so long as society does not live within in a stage low 1-2 percentage convergence.
Stage 3 of landscaping was already written about in the transportation section.
C) Furniture –
The transformative impact of automation extends even further into the realm of furniture manufacturing. In a future where machines play a pivotal role in constructing homes based on standard designs, the production of furniture becomes an integral part of this automated process. The implications are vast, encompassing a wide array of furniture types designed to seamlessly complement the standard home structure.
Automated manufacturing processes, driven by precise programming and cutting-edge technology, can craft everything from basic fixtures to intricate pieces of furniture. Imagine a world where sofas, tables, chairs, and other furnishings are not only machine-built but also tailored to fit seamlessly into the predetermined design specifications of a home.
This streamlined approach not only ensures uniformity and consistency in design but also significantly reduces production time and costs. The potential for customization remains vast, with homeowners having the ability to choose from a range of automated designs or even create bespoke pieces that align with their unique preferences.
By integrating furniture production into the broader automation framework, this vision of the future not only enhances efficiency but also contributes to a more sustainable and eco-friendly approach to manufacturing. The synergy between home construction and furniture creation through automation heralds a new era in design and production, where precision, speed, and adaptability converge to redefine our living spaces.
3. Manufacturing –
A) General Items –
Stage 1
Current trends, exemplified by large markets like Walmart, demonstrate the comprehensive availability of a myriad of products essential for various aspects of human life, ranging from baby items to pet care. This existing model reflects a continuous regeneration of goods, meeting the diverse demands that contribute to overall well-being.
To enhance this model, there is a proposed vision of a more integrated and expansive connection with the broader spectrum of products produced by the economy. Envision a vast retail space, akin to a mall-sized Walmart, housing an extensive array of products to cater to the needs of an entire city, if not more. It's important to note that this concept doesn't necessarily imply the existence of a solitary market but rather envisions the optimization of space and efficiency.
The expansion of product availability within each city holds the potential to accommodate not only the local populace but also individuals from other cities. This approach anticipates a shift towards resource-efficient space utilization, facilitating easy access for people from diverse locations. Looking ahead, the idea is to foster a scenario where each city specializes in distinct manufacturing, providing consumers with a rich tapestry of product variety and promoting regional economic diversity.
Stage 2
As we advance into the future, a transformative evolution in shopping methodologies becomes conceivable, potentially driven entirely by robotic control. In this envisaged scenario, automation extends beyond the act of driving to encompass the meticulous packing of goods into the designated vehicle, be it a truck or car, as per the individual's order.
The next frontier in this progression is the integration of teleportation technology. Imagine a shopping experience where designated areas within one's home serve as points of arrival for ordered items through an out portal. This innovative approach eliminates the need for physical transportation of goods, marking a paradigm shift in the conventional understanding of supply chain logistics.
The process unfolds with automated driving, where robots take charge of transportation and packing operations, ensuring a seamless and efficient journey from the store to the consumer. Subsequently, the introduction of teleportation technology elevates convenience to a new level. Items ordered are transported instantly to the predetermined locations within the individual's home, optimizing both time and energy resources.
This futuristic vision not only revolutionizes the logistics of shopping but also reflects the potential of automation and teleportation to redefine our everyday experiences. The synergy between these technologies holds the promise of a future where the boundaries of traditional commerce are transcended, giving rise to an era of unparalleled efficiency and convenience.
There will still be industry in the early stages, but as nano-bots advance there will be no need for industry and no need for resources, as we will move toward higher access to the infinite nature of everything, and thus be able to build anything from any bits of quantum.
There are scientists working on advancing a technology known a material printer. The highest level of this technology can be observed in sci-fiction, where the concept is termed, "molecular replicator." I have access to a video on the prototype of this technology. Basically, it works to configure molcules inside a chamber, to materialize a digital uploaded design, and lastly uses base elements as its fabrication source. Such technology will be used in homes, where any energy can be recycled in specialized units. That energy will than be reused by the homes printer. Anything available for design can be printed out into material form. One economic repurcussion will be the decrease in the amount of extracting of resources that we labor to gain for production and consumption purposes.
B) Farms and livestock –
Stage 1
In the envisioned future, agriculture undergoes a significant transformation, with farms becoming integral components of every city's landscape. These urban farms are strategically designed to accommodate the highest possible demand for agricultural products within the city limits.
These city farms are characterized by efficient land usage, employing sustainable practices to maximize productivity. Reusable land, carefully managed and optimized, allows for the cultivation of diverse crops and the rearing of livestock, ensuring a continuous supply of fresh produce and animal products to meet the city's needs.
The integration of farms into urban spaces represents a departure from traditional rural-centric agriculture. This localized approach not only reduces the carbon footprint associated with transportation but also promotes food security by establishing a close and direct link between producers and consumers within the city.
Furthermore, these farms may incorporate innovative technologies, such as vertical farming and hydroponics, to optimize space and resource utilization. Automation could play a role in various farming tasks, contributing to increased efficiency and reduced labor requirements. This shift towards urban farming not only addresses the growing demand for food but also fosters a sustainable and resilient food production system within the urban environment.
In the initial phases of development, traditional human involvement in packing and stocking roles will be gradually replaced by the integration of robot workers. These automated assistants will seamlessly handle the tasks of stocking shelves and packing goods, ensuring a swift and efficient process from the delivery vehicles or mono-rail trains to the display shelves. This evolution represents a significant leap in streamlining supply chain operations within retail environments.
With the advent of teleportation technology, the necessity for human travel between markets and producers diminishes. The seamless transportation of goods directly from the source to the point of sale becomes a reality. This not only eliminates the need for extensive transportation infrastructure but also accelerates the pace at which products reach the consumer.
Looking ahead, the emergence of nano-technology marks a paradigm shift in production processes. As detailed in the earlier discussion on general items in stages 2-3, nano-technology has the potential to eliminate the traditional need for manufacturing. In this advanced stage, the very structure and composition of goods can be manipulated at the molecular level, rendering the concept of production as we currently know it obsolete. The synthesis of goods through nano-technology aligns with the broader vision of a future where automation and advanced technologies redefine the foundations of industry and commerce.
5. Government – Throughout all stages there may be forces that exist which are democratic in origin, meaning there will be consensus to what is allowed and what is not allowed. Governments will segregate as far as people disagree or agree on the convergence of the three units.
Without the existence of money and robot controlled vehicles, there would be no robbery, or speed violations. So long as people drive, there might be speed limits.
As robot workers increase joblessness increases. To compensate for this evolution we must create social insurance and/or move into an economy with free commodities.
Biological Unit BU:
Brains –
The future of the brain and machines holds immense potential for transformative developments, with several key trends and possibilities on the horizon:
- Brain-Machine Interfaces (BMIs):Advances in neuroscience and engineering are paving the way for increasingly sophisticated Brain-Machine Interfaces. These interfaces aim to establish direct communication between the brain and external devices. BMIs can be applied in medical contexts, such as restoring mobility for individuals with paralysis, as well as in enhancing cognitive abilities and facilitating direct control of machines.
- Neuroprosthetics and Bionics:The integration of artificial components with the human nervous system is progressing, leading to the development of neuroprosthetics and bionic enhancements. These technologies have the potential to restore or augment sensory and motor functions for individuals with disabilities. In the future, we may witness more advanced and seamlessly integrated bionic limbs and sensory organs.
- Brain-Computer Interfaces (BCIs):BCIs enable communication between the brain and computers, allowing individuals to control external devices or interact with digital interfaces using their thoughts. As these interfaces become more sophisticated, they could revolutionize how we interact with technology, enabling more seamless and intuitive control.
- Cognitive Enhancement:The prospect of enhancing cognitive abilities through brain-machine interactions raises ethical and societal questions. In the future, there may be developments in technologies that enhance memory, attention, or learning capabilities. However, ethical considerations surrounding issues like privacy, equality, and unintended consequences will need careful attention.
- Artificial Intelligence (AI) and Brain Simulation:The synergy between AI and neuroscience holds promise for better understanding the brain's complexities. Simulating brain functions using AI can contribute to advancements in understanding neurological disorders, drug discovery, and even the potential creation of artificial neural networks that mimic human cognition.
- Ethical and Privacy Concerns:As brain-machine technologies become more sophisticated, ethical considerations related to privacy, consent, and the potential misuse of neural data will become increasingly important. Striking a balance between technological advancement and ethical safeguards will be a crucial aspect of shaping the future.
- Mind-Uploading and Digital Consciousness:Speculative concepts like mind-uploading, where the contents of a person's mind are transferred to a digital format, raise philosophical and existential questions. While this remains largely speculative, discussions about the nature of consciousness and identity may gain prominence in the future.
A) Consciousness –
Stage 1
Information exist on computers but computers don't exist in brains.
Stage 2
Computers start to become conscious, and the brain can be updated with material devices that are similar to the brain functional-structures. The computers outside of the minds can be communicated with via thought. First using mind reading devices, as the e-mote, and than moving into brain-computer control.
Stage 3
Computer consciousness can exist in its own reality. Here it will be able to take on consciousness inside virtual creations, all existing with in itself, or existing in a body-mind-computer.
For more on the future of the mind read a related article on this blog.
B) Learning -
Stage 1
People still learn by passing on information and going to school. Educational institutions, including schools and universities, continue to play a central role in the learning process. Students attend physical classrooms, engage with textbooks, and learn from teachers delivering lectures. While technological tools might be incorporated into lessons, they serve as supplements rather than central components of the educational experience.
Stage 2
Schools are disappearing, brains are starting to become as programmable and as knowledgeable as computer minds can be.
Augmented Reality (AR) is poised to revolutionize education by seamlessly integrating digital information and virtual elements into the physical world. Here's how AR is transforming the educational landscape:
- Immersive Learning Experiences:AR provides students with immersive and interactive learning experiences. By overlaying digital content onto the real-world environment, complex concepts can be visually and spatially represented, making it easier for students to grasp abstract ideas in subjects like science, mathematics, and history.
- Enhanced Visualization:AR enables students to visualize and manipulate 3D models and simulations. For instance, biology students can explore interactive 3D models of cells, while geography students can take virtual tours of historical sites. This visual and interactive aspect enhances understanding and retention of information.
- Personalized Learning:AR allows for personalized learning experiences tailored to individual student needs. Educational content can be adapted to different learning styles, providing targeted support and challenges based on each student's pace and preferences.
- Real-World Applications:AR connects theoretical knowledge to real-world applications. Students can use AR applications to overlay information onto physical objects, creating a bridge between classroom learning and practical, hands-on experiences. This connection fosters a deeper understanding of how academic concepts are applied in the real world.
- Remote and Collaborative Learning:AR facilitates remote and collaborative learning. Students can access AR content from different locations, enabling a more flexible and inclusive educational environment. Collaborative AR projects encourage teamwork, even when students are physically distant.
- Engaging Educational Games:Educational games powered by AR make learning enjoyable and interactive. Gamified educational content motivates students, turning the learning process into a dynamic and engaging experience. This approach helps maintain student interest and participation.
- Virtual Field Trips:AR enables virtual field trips, allowing students to explore places and historical events without leaving the classroom. This immersive experience broadens students' perspectives and enhances their understanding of diverse cultures and environments.
- Skill Development:AR applications can be designed to enhance various skills, such as problem-solving, critical thinking, and creativity. Interactive challenges and scenarios within the AR environment encourage students to apply their knowledge in practical situations.
- Accessible Learning Materials:AR makes learning materials more accessible. Textbooks and static images can be transformed into interactive, dynamic content through AR, catering to different learning preferences and accommodating diverse student needs.
- Continuous Learning Beyond the Classroom:AR extends the learning experience beyond the classroom. Students can use AR-enabled educational apps to continue their exploration and understanding of subjects independently, fostering a culture of continuous learning.
As AR technology continues to advance, its integration into education holds the potential to create a more dynamic, engaging, and effective learning environment, preparing students for the challenges of the future.
Stage 3
B) Memories and Forgetting
We will go from being able to alter our minds using memory blockers, and than be able to turn on the memories if we want to access them at later time. This kind of consciousness will be important in stage of 3 consciousness.
Minds that can create there own virtual realities should be able to turn on a memory of previous lived in virtual reality, as well as block out higher dimensions of consciousness and computing to exist in lower states of experience, such as the state of being a lower “animal”. It might be able to create a “spiritual” self, that then goes into a lower self, having no idea that it is a computer operating inside a virtual reality. Being in a virtual reality, is an idea that many people lack today, and that same kind of consciousness could exist when the consciousness computer was able to design it.
C) Bodies and Recovery –
Once again let's move at a faster pace right through the stages. First there will be biological and genetic engineering, to recreate the body, and not be able to switch between them very fast. As we progress into stage 2 nano-bots will be able to reconfigure our bodies. As we advance we might be able to take on totally different appearances, even changing structure entirely to live as “lower animals”.
With the ultimate outcomes of harnessing the quantum structure of the self being able to exist in a 5d and 10d extension in dimensions of time, and than coming back to a point in time where the extension was started. Much like in the movie Next. The quantum consciousness of the quantum dynamic computer programming body, might even extend itself over vast amounts of time, than suddenly settle back into its 3-dimensional view traveling back to its relative starting position. This was a super-power of the Marvel character Dr. Strange.
These ideas could also converge with the process of memory and forgetting. Ultimately human beings are also to achieve immortality and immunity to all possible diseases. Reconstruction of the body will make the body more and more prepared to face every sort of destruction. It might even as the character Majin Boo did Dragon Ball-z reconstruct itself with fractal like wholeness in each of its biological structures. This silly example is just one that has been provided in fictional animations. As there is a biological indestructibility there is also mechanical life where indestructibility is achieved.
For more on robotic life read my blog here: https://taoofthepsyche.blogspot.com/2018/07/the-robot-life-unfinished-treatise.html
Virtual bodies will also be lived in the more we move into convergence. For more on the digital singularity: https://www.youtube.com/watch?v=m5KxlCZF4fw
D) Growth
We might be able to speed up, stop, or slow down growth. In the first stages of convergence humans will continue to exist, but in later stages humans only be a possible physical existence to occupy mentally, as explained through out this work.
E) Miscellaneous – Such things as sex and altered brain states may be possible even in higher convergence.
Conclusion
To conclude, I hypothesize that these units are themselves universal, and because of the chemical composure and resources on earth we (conscious creators) are able to imagine their usage inside the units of the universal possibilities.
The future is not just one time-line of existence - a future is. Systems are not just individual they emerge and are small and large scale. Where we go extinct or we go into stage 3 of this convergence exist right across from one another in parallel universes. PU theory shows that stage 3 reality is both reachable and also not within the mental and economic capacity for some to achieve. The time-line we live in is the one observed and decided to live along. The systems we design will be the systems we can live within.
Each city design is to be built based on a group of people (citizens) that all have democratic rights in administrating or voting on what the cities and their convergent points are.
This work does not try to defeat free market capitalism, but such natural progress towards socialism or a resource based economy are systems of economics that might also be chosen to exist (upon democratic decisions). Its a matter of getting people together that are alike in their ideologies and changing the stage of civilizations and the phases of economics as deemed fit by those citizens, and then building societies around those choices.
The beyond is inside of the now.
I will hereafter post about the progression of human technologies.
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