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cnblock
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Is it possible to use simple glucose to design a chemical computer, and therefore reflect the architecture and chemicals of the human brain?
You've said that you have a background in computer software. Have you studied computer hardware at all? What chemical processes do you propose for the flip/flop type memory "bit" elements? How would you tie those together into registers? What would you use for multiplexed busses?cnblock said:Is it possible to use simple glucose to design a chemical computer, and therefore reflect the architecture and chemicals of the human brain?
Or are you thinking more along the lines of a Neural Network model of brain processing? Again, what other chemicals and structures would you need to include in such a model?cnblock said:reflect the architecture and chemicals of the human brain?
I would assume that any computer would not be of the digital kind. Remember, at one stage, the analogue computer was doing calculations that were beyond the capabilities of its digital companion.berkeman said:What chemical processes do you propose for the flip/flop type memory "bit" elements?
sophiecentaur said:I would assume that any computer would not be of the digital kind. Remember, at one stage, the analogue computer was doing calculations that were beyond the capabilities of its digital companion.
The chemical control in plants and animals is certainly a function that could be described computer-like. It's just that the problems it can solve are of the non-numerical kind. The OP would need to decide what problem that chemical computer would be designed to solve (it would not be of a 'general purpose' device.
The brain is more than just chemical reactions. There is structure of the neurons and the larger neural networks and these things work in conjunction with the neural transmitters in a manner that we only superficially understand to produce thought.cnblock said:I was thinking that the wiki article suggested untested chemicals etc, whereas the human brain in fact has all the chemical components mapped already. What we essentially gain is a computer with essentially unlimited registers, therefore it can process really really fast. Glucose makes sense to me, and somebody in the know should ask around about this idea. Chemical computers could be one of the next Turing machines, or some kind of video processing thing which will be really really fast, or some kind of future AI which could quite literally be possible in a development cycle if my idea proves correct.
Glucose is not a semiconductor so it can't be used as if it was.cnblock said:Is it possible to use simple glucose to design a chemical computer, and therefore reflect the architecture and chemicals of the human brain?
Chemical computers use chemical reactions to perform calculations instead of traditional electronic components. The reactions are controlled by enzymes, which act as the "logic gates" of the computer. Glucose is used as the input and the output of the reactions is measured as a change in color or light intensity.
Glucose-based computers have the potential to be much smaller and more energy-efficient than traditional electronic computers. They also have the ability to perform complex calculations in parallel, allowing for faster processing speeds.
One major limitation of chemical computers is their current lack of reliability. The reactions can be affected by external factors such as temperature and pH, which can lead to errors in the calculations. Additionally, the technology is still in its early stages and has not been fully tested or optimized.
Designing and programming chemical computers involves identifying the appropriate enzymes and chemical reactions to use for specific calculations. Researchers also need to develop methods for controlling and measuring the reactions. Programming can be done through the use of algorithms and molecular logic gates.
Chemical computers have the potential to be used in various fields such as biomedical research, environmental monitoring, and data encryption. They could also be used in developing countries where traditional electronic computers may not be easily accessible. However, more research and development is needed before they can be fully integrated into practical applications.