OSE Crypto: Difference between revisions
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***Calculation: steel per acre is $1/lb, and 1kWhr/kg - 5000 lb/day minimum - or $2M value generation per year with minimum capital depreciation afforded by [[Modular Design]]. | ***Calculation: steel per acre is $1/lb, and 1kWhr/kg - 5000 lb/day minimum - or $2M value generation per year with minimum capital depreciation afforded by [[Modular Design]]. | ||
***If this is silicon, 11kwhr/kg [https://www.quora.com/How-many-kWh-electricity-are-necessary-for-producing-1-kg-of-pure-silicium-from-sand] - and this is sufficient purity for transistors [https://sinovoltaics.com/learning-center/solar-cells/silicon-si-solar-cells-produced/] - then we have a 1 milligram per 1 kW transistors (1MW/gram easily [https://www.abb-conversations.com/2015/11/thyristors-the-heart-of-hvdc/] at $1 each. For silicon, we can produce about 40 tons of silicon with the PV array. At $1/kW, we have thus $40B revenue from silicon production per acre, a high value crop. | ***If this is silicon, 11kwhr/kg [https://www.quora.com/How-many-kWh-electricity-are-necessary-for-producing-1-kg-of-pure-silicium-from-sand] - and this is sufficient purity for transistors [https://sinovoltaics.com/learning-center/solar-cells/silicon-si-solar-cells-produced/] - then we have a 1 milligram per 1 kW transistors (1MW/gram easily [https://www.abb-conversations.com/2015/11/thyristors-the-heart-of-hvdc/] at $1 each. For silicon, we can produce about 40 tons of silicon with the PV array. At $1/kW, we have thus $40B revenue from silicon production per acre, a high value crop. | ||
*As such, it contains [[Limited Digitality]] or is [[Digitally Responsible]]. Meaning that it enjoys a large measure of digital scalability, but has a check-and-balance of providing material needs. The 'responsible' part comes from the system producing essential (material) as opposed to digital needs. | *As such, it contains [[Limited Digitality]] or is [[Digitally Responsible]]. Meaning that it enjoys a large measure of digital scalability, but has a check-and-balance of providing material needs. The 'responsible' part comes from the system producing essential (material) as opposed to digital needs. Ie, it has a component of firm grounding in reality, which is useful in today's (2022) world. | ||
*It must avoid the artificial scarcity of traditional proof of work or stake algorithms | *It must avoid the artificial scarcity of traditional proof of work or stake algorithms | ||
*On-chain verified productive capacity would be key. Thus, the Open Source Microfactory Standard becomes of prime importance as the next evolution human-created-systems transparency: an agreed-upon standard of decentralized production (few thousand square feet, up to home lot size, or the size of the [[Tower of Wisdom]] | *On-chain verified productive capacity would be key. Thus, the Open Source Microfactory Standard becomes of prime importance as the next evolution human-created-systems transparency: an agreed-upon standard of decentralized production (few thousand square feet, up to home lot size, or the size of the [[Tower of Wisdom]] | ||
Revision as of 01:31, 12 September 2022
Digital Responsibility
Building upon the concept of the OSE Bank, OSE Crypto must have these properties.
- It is digito-phisically backed by productive potential, as opposed to actual production, (or as opposed to virtual backing of proofs of work or stake). This is to avoid inventory, to remain digital and non-scarce thus avoiding artificial scarcity. Remaining scalable because the productive potential is infinite, or at the very minimum 1000x what we have today. Based on solar energy Kardashev scale.
- While actual product is sound backing, product does not necessarily satisfy longevity (ex, strawberries), and can thus be poor backing for a currency.
- Flexible Digital Fabrication affords infinite productive potential, and is thus scalable.
- Local PV + materials production facilities are the ultimate backing, at a value of $400k/acre. If they cover cement, steel, hydrogen, aluminum, silicon, and biomass - then these form 80% of the entire material economy.
- Calculation: steel per acre is $1/lb, and 1kWhr/kg - 5000 lb/day minimum - or $2M value generation per year with minimum capital depreciation afforded by Modular Design.
- If this is silicon, 11kwhr/kg [1] - and this is sufficient purity for transistors [2] - then we have a 1 milligram per 1 kW transistors (1MW/gram easily [3] at $1 each. For silicon, we can produce about 40 tons of silicon with the PV array. At $1/kW, we have thus $40B revenue from silicon production per acre, a high value crop.
- As such, it contains Limited Digitality or is Digitally Responsible. Meaning that it enjoys a large measure of digital scalability, but has a check-and-balance of providing material needs. The 'responsible' part comes from the system producing essential (material) as opposed to digital needs. Ie, it has a component of firm grounding in reality, which is useful in today's (2022) world.
- It must avoid the artificial scarcity of traditional proof of work or stake algorithms
- On-chain verified productive capacity would be key. Thus, the Open Source Microfactory Standard becomes of prime importance as the next evolution human-created-systems transparency: an agreed-upon standard of decentralized production (few thousand square feet, up to home lot size, or the size of the Tower of Wisdom
Open Source Microfactory Standard
Phases
Phase narrative is being developed at Technological Recursion
- Amish with Power Tools
- Basic workshop - steel or wood.
- Basic Advanced Workshop
- Replicable Open Source Microfactory for the Open Source Everything Store. 80-100% of consumer goods made from external feedstocks but closed loop circular economy due to local manufacturing/repair infrastructure.
- Advanced production - this means precision machining, air bearings, semiconductors, and what is generally considered to be high tech. However, because it is open source collaborative, it is Appropriate High Tech.