e470 — Two Marvelous Mini-Brains

AI threads through a set of old and new games that span text based adventures from Infocom’s HHG2G to recent examples like Milton is Trapped, along with a conversation on FinalSpark’s Neuroplatform for biocomputing.

Photo by Michael Rowe Published 1 July 2024 Andy and Michael M get together to talk through the backlog of articles and stories from the past weeks.  While Michael R is away this time, in this episode Andy and Michael M pull on an AI thread exposed through a set of old and new games, discuss FinalSpark’s Neuroplatform for biocomputing and marvel at the immense immersiveness of the Calculating…

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Hey gang? Maybe let's sit on this concept a little more, figure out the ethical minutiae

OF COURSE THEY PUT IN A SUBSCRIPTION MODEL

You know what really grinds my gears?

Working with people who don't understand how a neural computer works.

Be it some mass ratio optimizing payload engineer, a logistics officer frustrated with the difficulties caused by our team's solutions or just our boss looking for reasons to fire us because they thought our initial cost estimate was "unrealistically high" and are now sorely disappointed at reality, these people are miserable to deal with. On the surface, their complaints make sense; we are seemingly doing a much worse job than everyone else is and anything we come up with creates lots of problems for them. Satisfying all their demands, however, is impossible. With this post I intend to educate my audience on

Neural Computers 101

so that my blog's engineer-heavy audience may understand the inevitable troubles those in my field seemingly summon out of thin air and so that you people will hopefully not bother us quite as much anymore.

First of all, neural matter is extremely resource heavy. Not by mass, mind you; a BNC of 2 kilograms requires only a few dozen grams of whatever standardized or specialized mix of sustenance is preferred in a single martian day. (I'm not going to bother converting that.) The inconvenient part is the sheer variety in the things they need and the waste products they create.

This is just a shortened list, but already it causes problems. If you want to create a self contained system to avoid having to refuel constantly, you will need a lot of mass and a lot of complexity. This is what a typical sustenance diagram for such a system looks like:

(Keep in mind, this diagram doesn't even have electricity drawn in.)

Typically these systems are even more complicated, with redundancies and extra steps. In any case, this is complicated, energy expensive and a nightmare to maintenance crew. I mean, just keeping the bacterial microbiome alive is a lot of effort!

Second of all, neural matter is extremely vulnerable. Most power plant and rocket designers just round away all temperature changes less than 100 K, but neural matter will outright die if its temperature is just a few kelvin off of the typical value. The same goes for a lot of other things - you'll need some serious temperature regulation, shock absorption, radiation shielding (damn it I wish we had access to the same stuff as those madmen in the JMR) and on top of all of that, you need to consider mental instability!

That last one is kind of the biggest pain in the ass for these things - we need to give them a damn game to play whenever they don't have any real work to deal with or they degrade and start to go insane. (Don't worry, I'm not stupid, I know these things aren't actually sentient, I'm just saying that to illustrate the way they work.) It can't even be the same game - you need to design one based on what the NC is designed to do! (Game is a misleading term by the way; it's not like a traditional video game. No graphics - just a set of variables, functions and parameters on a simple circuit board that the NC can influence.)

And lastly, neural computers are complicated. Dear Olympus are they complicated. There are so so many ways to build them, and the process of deriving which one to use is extremely difficult. You can't blame the NC team for an inappropriate computer if the damn specifications keep changing every week!

There's the always-on, calculation-heavy, simple and slow Pennington circuits, the iconic Gobbs cycle (Bloody love that thing!), the Anesuki thinknet and its derivatives, the Klenowicz for those insane venusians and so so many more frameworks for both ANCs and BNCs. Oh yeah, by the way, the acronyms ANC and BNC actually don't stand for Advanced and Basic Neural Computer respectively. They stand for Type A Neural Computer and Type B Neural Computer. It comes from that revolutionary paper written by Anesuki.

Wetware Is Here: Human Brain-Matter Computing (not fiction)

Swiss tech company Final Spark now offers Neuroplatform, the world’s first bioprocessing platform using human brain organoids (lab-grown mini-brains) to perform computational tasks instead of silicon chips.

The first such facility uses 16 human-brain organoids, which the company claims uses a million times less power than their silicon counterparts. 

These are not sentences we expected to write non-fictionally in this year of our world 2024.

news source: X

paper: X

Wetware Computers Market Segmentation and Forecast Analysis up to 2030

The Wetware Computers Market was valued at USD 0.26 billion in 2023-e and will surpass USD 3.0 billion by 2030; growing at a CAGR of 41.5% during 2024 - 2030. It’s becoming a tangible reality with the development of wetware computers. This burgeoning technology combines the complexities of human tissues, specifically neural cells, with traditional computing elements to create systems capable of astonishing processing capabilities. The wetware computers market, although still in its infancy, promises revolutionary changes across various sectors, including healthcare, artificial intelligence, and even environmental management. Here, we explore the current state, potential future, and implications of wetware computing.

Wetware computers are systems that combine biological materials with electronic computing elements to harness the best of both worlds: the remarkable efficiency and adaptability of biological systems alongside the precision and speed of electronic computation. This approach typically involves using neurons or other living cells interfaced with electronic devices, forming a bio-electronic hybrid that can process information in ways traditional silicon-based computers cannot.

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Current State of the Wetware Computers Market

As of now, the wetware computers market is largely experimental and driven by research institutions and pioneering startups. The field has seen significant advancements due to improvements in neuroscience, microfabrication, and biotechnology. Key players in this sector are working on different applications, from brain-computer interfaces and biosensors to more sophisticated neural network modeling that can mimic human brain activities.

Applications and Potential Impact

Healthcare: One of the most immediate impacts of wetware computing is expected in healthcare. Devices that better interface with the human nervous system can revolutionize the treatment of neurological disorders, provide advanced prosthetics, and even restore functions to damaged organs.

AI and Machine Learning: Wetware computers offer a unique angle on artificial intelligence. By mimicking the neurological structures and functions of the human brain, these systems could potentially operate in more human-like ways, offering solutions that are intuitive and capable of learning in a biomimetic fashion.

Environmental Monitoring: Another intriguing application is in the field of environmental monitoring and repair. Wetware systems could be developed to interact directly with biological ecosystems, helping to monitor, regulate, or repair environmental damage in ways that are harmonious with nature.

Challenges and Ethical Considerations

Despite the potential, there are significant challenges. The integration of living cells into electronic systems raises complex fabrication and maintenance issues, not to mention the ethical and regulatory hurdles concerning the use of biological materials.

Ethically, the field navigates complex terrain. As technologies that blur the lines between digital and biological, wetware computers necessitate a renewed discussion on privacy, consent, and the extent of human enhancement. The long-term impacts on society and individual identity also demand careful consideration.

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 Market Forecast and Opportunities

While still emerging, the market for wetware computers is expected to grow significantly as research progresses and applications begin to reach commercial viability. Investors and companies are eyeing this nascent market for its potential to offer breakthrough products and services.

For those in technology and biotech sectors, staying ahead means keeping an eye on this convergence of biology and electronics. Partnerships between academic institutions, healthcare providers, and tech companies will likely be crucial in navigating the roadmap from laboratory research to commercial products.

Conclusion

Wetware computers represent a fascinating frontier in both technology and biology. As this market continues to evolve, it promises not only to expand the capabilities of computing but to redefine the very boundaries of what computers can do. For anyone invested in the future of technology and its integration with biological systems, the wetware computers market is undeniably an area to watch.

i think we need to let moon be organic looking and also fat like she is in the game art

How Wetware Computers Are Being Used in Advanced Diagnostics

Wetware Computers: Pioneering the Next Era of Computing

As technology continues to evolve at a rapid pace, wetware computers stand out as a revolutionary innovation that blends biological elements with traditional computing. These cutting-edge systems promise to transform the landscape of computing, offering unparalleled efficiency and capabilities. This article delves deep into the realm of wetware computers, exploring their principles, current advancements, and future implications.

What Are Wetware Computers?

Wetware computers, also referred to as biocomputers or organic computers, incorporate biological materials with conventional hardware. Unlike traditional computers that depend on silicon-based semiconductors, wetware computers use living cells and tissues to execute computational tasks. This synergy of biology and technology unlocks new potential, leveraging the innate complexity and efficiency of biological systems.

Core Components of Wetware Computers

Wetware computers feature several distinct components that set them apart from conventional systems:

Living Cells: The foundation of wetware computers consists of living cells, such as neurons or engineered bacteria, which process information via biochemical reactions.

Biological Circuits: These circuits mimic the functions of electronic circuits, utilizing biological materials to transmit signals and perform logical operations.

Interface Technologies: Advanced interfaces are developed to facilitate communication between biological components and electronic hardware, ensuring smooth integration.

The Mechanisms of Wetware Computing

Biological Processing Units (BPUs)

At the core of wetware computing are biological processing units (BPUs), akin to central processing units (CPUs) in traditional computers. BPUs exploit the natural processing abilities of biological cells to perform complex computations. For instance, neurons can form intricate networks that process information simultaneously, offering significant advantages in speed and efficiency over traditional silicon-based processors.

Biochemical Logic Gates

Biochemical logic gates are crucial elements of wetware computers, operating similarly to electronic logic gates. These gates employ biochemical reactions to execute logical operations such as AND, OR, and NOT. By harnessing these reactions, wetware computers achieve highly efficient and parallel processing capabilities.

Synthetic Biology and Genetic Modification

Progress in synthetic biology and genetic modification has been instrumental in advancing wetware computers. Scientists can now engineer cells to exhibit specific behaviors and responses, tailoring them for particular computational tasks. This customization is essential for creating dependable and scalable wetware systems.

Potential Applications of Wetware Computers

Wetware computers have immense potential across a variety of fields, including:

Medical Research and Healthcare

In medical research, wetware computers can simulate complex biological processes, providing insights into disease mechanisms and potential treatments. In healthcare, these systems could lead to the development of advanced diagnostic tools and personalized medicine, where treatments are tailored to the individual’s unique biological profile.

Environmental Monitoring

Wetware computers can be deployed for environmental monitoring, using genetically engineered organisms to detect and respond to pollutants. These biocomputers can offer real-time data on environmental conditions, aiding in pollution management and mitigation.

Neuroscience and Brain-Computer Interfaces

The fusion of biological components with computing paves the way for significant advancements in neuroscience and brain-computer interfaces (BCIs). Wetware computers can help develop sophisticated BCIs, enabling direct communication between the human brain and external devices. This technology holds great promise for medical rehabilitation, enhancing the quality of life for individuals with neurological conditions.

Current Progress and Challenges

Advancements in Wetware Computing

Recent advancements in wetware computing have shown the feasibility of integrating biological components with electronic systems. Researchers have successfully created basic biocomputers capable of performing fundamental logical operations and processing information. These milestones highlight the potential of wetware computers to complement and eventually surpass traditional computing technologies.

Challenges and Obstacles

Despite promising progress, wetware computing faces several challenges:

Stability and Reliability: Biological systems are inherently complex and can be unstable. Ensuring the stability and reliability of biocomputers remains a significant challenge.

Scalability: Scaling wetware computing systems to handle more complex and large-scale computations is a critical hurdle.

Ethical Considerations: The use of living organisms in computing raises ethical questions regarding the manipulation of life forms for technological purposes.

The Future Prospects of Wetware Computers

The future of wetware computers is promising, with ongoing research and development aimed at overcoming current limitations and unlocking their full potential. As technology advances, we anticipate several key trends:

Hybrid Computing Models

Wetware computers are likely to complement traditional computing systems, creating hybrid models that leverage the strengths of both. This integration could lead to more efficient and powerful computing solutions, addressing complex problems that are currently beyond our reach.

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Advancements in Synthetic Biology

Continued advancements in synthetic biology will enable the creation of more sophisticated biological components for wetware computers. Improved genetic engineering techniques will allow for greater precision and control, enhancing the performance and reliability of these systems.

Ethical and Regulatory Frameworks

As wetware computing technology advances, the development of robust ethical and regulatory frameworks will be essential. These frameworks will ensure that the use of biological components in computing is conducted responsibly and ethically, addressing concerns related to the manipulation of life forms.

Conclusion

Wetware computers represent a transformative leap in the field of computing, merging the biological and technological worlds in unprecedented ways. The potential applications of this technology are vast, from medical research and healthcare to environmental monitoring and neuroscience. While challenges remain, the continued progress in this area promises to revolutionize the way we approach computation, offering new possibilities and efficiencies.

Midnight Pals: Hackin'

King: i can't believe elon's grok is pretending i'm friends with him King: i need to stop that AI before everyone believes it! King: i've got to hire a hacker King: franz, you've got to help me Franz Kafka: what? me? Barker: steve, no

Kafka: i'm not a hacker King: oh i thought franz was a hacker Barker: what gave you THAT impression? King: you know, with the cat ear headphones and the striped thigh socks Barker: no steve that's something ENTIRELY different Kafka: n-no it isn't, on second thought yes I'm totally a hacker

Kafka: it means i'm a hacker, nothing else Barker: sure franz Kafka: it does! it totally means i'm a hacker! Barker: franz, go play with your blahaj plush, the adults are talking here

Barker: you know who you need? you need william gibson Barker: the best hacker money can buy King: william gibson? how do i contact him? Barker: you don't Barker: he'll contact you

King: can you really hack grok, william? William Gibson: [wearing black duster and fingerless black gloves] my hacker name is shadow gigabyte King: oh sorry Gibson: can i hack grok? listen kid i was cyberbyting the megabyte mainframe when you were just rebooting your motherboard mouse data bandwidth modem email King: wow!

Gibson: my CPU is a neural net processer, a learning computer King: wow he really sounds like he knows what he's talking about! King: that definitely sounds like hacker talk to me Gibson: CD Rom Gibson: internet Joe Hill: dad can i talk to you for a second King: not now joe daddy's hiring a hacker

Gibson: [wildly slapping keyboard] i'll re-index the mega bit blaster cyber codex Gibson: [wildly slapping keyboard] now we'll cybersecurity the lock box data center King: hey what happens if you push that button? Gibson: what the-- no!! [klaxons sound] King: what's that mean? Gibson: shit Gibson: we've got company

Gibson: sentient cyber virus electronic guard cyberbots Gibson: real high tech Gibson: state of the art in bio-tech wetware neural-data scrapers Gibson: [putting on sunglasses with red laser scope] and they ain't friendly

King: what are we going to do?! Gibson: kid, you keep your hands to yourself unless you wanna become roadkill on the information super highway!!! Gibson: hold on to your CPU (central processing unit)!!!

Gibson: [wildly slapping keyboard] gotta reconfigure the darkweb logistics for ethernet wavetech Gibson: [wildly slapping keyboard] upload the memory downloader for dumpware backup Gibson: [wildly slapping keyboard] uncodify the cyberpatch modifer aaaaand Gibson: i'm in

King: wow, you hacked twitter?? how did you do it? Gibson: the greatest hackers never reveal their secrets [earlier] Gibson: [wearing fake mustache] hey elon its me catturd Gibson: could you give me your password? Elon Musk: sure it's "picklerick420"!

Been thinking about wetware. Biologically-based computation tech. Thin neural membranes, trapped between plexiglass sheets, bathed in cerebrospinal fluid. Humming server banks, rows of neural sheets and thick cords of synaptic fibre. Workers in clean suits gently nudging along samples of artificial mind, destined for an offshore compfarm in Hong Kong, long outliving whatever cents-on-the-dollar guinea pig the stem cells were harvested from.

Could you give your best explanation for what exactly wetware is?

In science fiction, "wetware" is often the name for a brain-computer interface. In reality, wetware is a Don't-Create-The-Torment-Nexus sort of deal where despite many stories of the horrors possible from making such an invention without proper care, oversight and ethical concerns, certain ultra-rich people have rushed the development of wetware by abusing animal and human subjects with few actual benefits just so they can tell shareholders that they invented wetware.

Now, I know what you're thinking, isn't this a fake fact blog? Or is he gonna promote his own novels with their many cyberpunk elements? Or did he sneak in a clever reference to Neuromancer or Ghost in the Shell above that I missed? Or did he load that question into my mind through the wetware he deleted my memory of getting?

No, I'm just tired and my sides and back hurt and I'm typing almost randomly while watching Elden Ring lore videos and I just want this fucking kidney shit to be OVER because I can't think straight.

Sorry everyone I'm not braining well these days but hopefully soon I'll be back and not just typing to try to ignore the ugh.

Nah, I'm down for it. It's weird, but if we're talking lab-grown brain tissue, what's the harm in it? The material demands for churning out microchips has also led to some pretty fucked up mining operations in third-world countries, and a drastic reduction in computing energy demands would be a godsend for the environment. Furthermore, you'd be replacing inorganic parts with biodegradable tissue, so it would be easier to dispose old computers in environmentally friendly ways. Obviously this technology is still in its infancy, and there's a lot of concerns to sort out (including ethical!), but I'd say wetware is worth exploring.

IT BEGINS

OnThisDay in 1791 “father of the computer” Charles Babbage was born. On his death 80 yrs later, as he himself requested, his brain was donated to science. See pictures of the "wetware" behind the "hardware" and read a detailed description here: https://publicdomainreview.org/collection/a-description-of-the-brain-of-mr-charles-babbage-1909 #OTD

got the latest wetware meat computer, it throbs and undulates like a Great Beast;... "what are the specs ?" uhgh.,., nerd, its resistant to all but the STRONGEST coronal mass ejections and produces minimal sarin emissions, artifical gameing conmputer is oVER, this is the NEW WORLD, and if you can't afford to feed your PC a limb every week to maintain a steady 60 fps then you will never make it, get out of my way

Normalize wetware. (I'd put in that post from toskarin that goes "I want ETERNAL games with HYPERREALISTIC graphics made by COMPUTERS THAT WERE ONCE PEOPLE and i'm not kidding)

for anyone who hasn't had the simple pleasure of coming across the term wetware before:

I'm just a simple piece of wetware

Unveiling the Potential: Wetware Computers Market Explodes with Innovation

In the realm of technological innovation, where the boundaries between science fiction and reality blur, wetware computers emerge as a fascinating frontier. Unlike traditional hardware, wetware computers are not built from silicon and metal but are instead composed of living biological material, such as neurons or DNA. This revolutionary approach to computing holds immense promise, igniting a surge of interest and investment in the Wetware Computers Market.

The concept of wetware computing draws inspiration from the most powerful computing system known to humanity: the human brain. Mimicking the brain's structure and functionality, wetware computers leverage biological components to perform complex computations with unparalleled efficiency and adaptability. This paradigm shift in computing heralds a new era of neuromorphic computing, where machines can learn, reason, and evolve in ways reminiscent of the human mind.

One of the most compelling applications of wetware computers lies in the realm of artificial intelligence (AI). Traditional AI systems often struggle with tasks that humans excel at, such as natural language processing and pattern recognition. Wetware computers, with their biological substrate, offer a more intuitive and seamless approach to AI, enabling machines to comprehend and interact with the world in a manner akin to human cognition.

Biocomputing, a subset of wetware computing, explores the integration of biological components, such as DNA molecules, into computational systems. DNA, with its remarkable data storage capacity and self-replicating nature, presents a tantalizing opportunity for developing ultra-compact and energy-efficient computing devices. Researchers envision DNA-based computers capable of solving complex problems in fields ranging from healthcare to environmental monitoring.

Another exciting avenue in the wetware computers market is the advancement of brain-computer interfaces (BCIs). BCIs establish direct communication pathways between the human brain and external devices, enabling individuals to control computers, prosthetics, or even smart appliances using their thoughts alone. With wetware-based BCIs, the potential for seamless integration and enhanced performance skyrockets, paving the way for transformative applications in healthcare, accessibility, and human augmentation.

The wetware computers market is not without its challenges and ethical considerations. As with any emerging technology, questions regarding safety, reliability, and privacy abound. Ensuring the ethical use of wetware technologies, safeguarding against potential misuse or unintended consequences, requires robust regulatory frameworks and interdisciplinary collaboration between scientists, ethicists, and policymakers.

Despite these challenges, the wetware computers market is poised for exponential growth and innovation. Companies and research institutions worldwide are investing heavily in R&D efforts to unlock the full potential of biological computing. From startups pushing the boundaries of biocomputing to established tech giants exploring neuromorphic architectures, the landscape is abuzz with creativity and ambition.

In addition to AI, biocomputing, and BCIs, wetware computers hold promise across diverse domains, including robotics, drug discovery, and environmental monitoring. Imagine robots endowed with biological brains, capable of learning and adapting to dynamic environments with human-like agility. Picture a future where personalized medicine is powered by DNA-based computing, revolutionizing healthcare delivery and treatment outcomes.

As the wetware computers market continues to evolve, collaborations between academia, industry, and government will be instrumental in driving innovation and addressing societal concerns. Interdisciplinary research initiatives, funding support for cutting-edge projects, and public engagement efforts are essential for navigating the complexities of this transformative technology landscape.

In conclusion, the rise of wetware computers represents a paradigm shift in computing, with profound implications for AI, biotechnology, and human-machine interaction. By harnessing the power of living biological material, we embark on a journey towards smarter, more adaptable, and ethically conscious computing systems. As we tread this uncharted territory, let us embrace the challenges and opportunities that lie ahead, shaping a future where wetware computers empower us to realize the full extent of our technological imagination.