Monday, 19 January 2015
Timeline
2020-2022 = End of Moore's Law = slower growth in computer performance
2025 = commercial ($10,000) driverless cars
2030 = fusion propulsion (nasa)
2030-2035 = graphene computers (in the lab)
2035 = manned mission to mars (nasa)
2035 = affordable ($300) driverless cars
2030-2050 = mars colony (spacex or nasa)
2030-2050 = commercial fusion power
Thoughts
(Work in Progress)
Computers
Improvements in silicon have already slowed down since 2005-2007, and are coming to an end sometime around 2020-2022.
Already, the 2010 update to the International Technology Roadmap for Semiconductors predicted that growth would slow at the end of 2013, with transistor counts and densities doubling only every three years instead of two years.
Successor technologies (graphene, etc) won't be ready for commercialization until the 2030s at the earliest, so there will be a gap. Already large tech companies are pushing cloud computing as a way to fill that gap, but it's only an increase in services not raw processing.
Past
Present
Early 21st Century
Late 21st Century
Likely:
* Healthspan
* Mars Colony
* Asteroid Mining
* Thorium
* Solar Panels
* Graphene and other nanomaterials
* Cognitive Science
* Improvements to task-specific AI
* Improved Batteries
* Improved Robotics
Hopeful:
* Longevity (could be soon, could be later)
* Fusion (we'll have it late century, but near future is a long shot)
* Weak AGI (despite AI improvements, there has been little progress towards AGI)
* Warp Drive (but we wouldn't have the energy to use it for at least a century)
* Robotic limbs (relies on batteries)
* Electric cars (relies on batteries)
I'm not sure what else, lots of corporate PR hype to sift through, hard to tell what's serious and what's just marketing anymore.
=====
Technology comes from people, not from itself.
Technological progress multiplied 30 fold along with 1st world population growth, and especially numbe
r of people working in R&D. The population of 1st world countries will not grow exponentially in the n
ext century, so while progress will continue from the 1st world it will not increase noticeably.
As other populous countries (china, india, brazil, indonesia) increase their R&D investment, they are
becoming new drivers of technological progress. The effect on economies may cause a power shift later
this century, with major geopolitical consequences.
Technology follows logistic curves, not exponentials.
The cost of pharmaceutical research has increased over the last 50 years. link
If Wirth's Law outlives Moore's Law, expect computers to actually get slower.
3D printers are changing a lot of industries, but will never beat conventional manufacturing for cost-effectiveness.
Other fields haven't seen the exponential portion of their logistic curve yet.
Biotech in particlar is going to boom over the next few decades, the same way computers boomed since the 80s.
Driverless cars will be available by 2025, affordable by 2035, and will be the majority of motor vehicles by 2050.
AI, robotics, and automation will continue to improve, but there is a long way to go to replace everything humans can do.
Fusion power and Mars colonization are both expected to happen around 2030-2050.
Graphene will take longer, but may see some early applications in the next decade, and will be huge (like plastic and silicon combined) when it booms.
Nanobots will be important in medicine and pharmaceuticals, but like 3D printers they will not beat conventional manufacturing for cost-effectiveness on large objects. There will be limitations due to size, energy sources, etc. No cameras, no wifi, no utility fog.
Not sure what else.
Moore's Law
(Work in Progress)
"Moore's Law is dead" - Gordon Moore
Moore’s law is no longer expected to deliver improved transistor cost scaling at or below the 20nm node.
Up until now, the cost per transistor of a new technology has always been cheaper. Now we face a scenario in which the cost of new transistors will be more expensive. That means more transistors = bad, which puts profound pressure on the R&D pipeline in different ways.
The other drivers of Moore's Law -- clock speed and Instructions per Clock -- plateaued a long time ago.
New Technologies
It takes 15-20 years to move tech from theory to consumer hardware. There's a lot of theory out there, and no commercialized replacements. We are approaching the point where feature sizes can be described by atomic widths. There is no room to get much smaller or more perfect.
Graphene is decades away. So are carbon nanotubes. SiGe doesn't scale well; InGaAs is fragile and has poor manufacturing characteristics, a host of other problems affect every other alternate substrate.
Optical computers.
Impact
Computers are expected to be 30x faster in 50 years.
Whatever alternate means of computing we use (spin, magnetic charge, measuring electron positions) will likely be confined to huge labs and expensive installations. You can do quantum computing today, but not without a hefty supply of liquid nitrogen.
Fusion Power
Fusion Power projects:
* 2050 ITER (France)
* 2030-2050 NIF (USA)
* 2030-2050 ??? (Japan)
* China?
* India?
* Russia?
http://en.wikipedia.org/wiki/ITER
According to researchers at a demonstration reactor in Japan, a fusion generator should be feasible in the 2030s and no later than the 2050s. Japan is pursuing its own research program with several operational facilities that are exploring several fusion paths.
http://en.wikipedia.org/wiki/DEMO
DEMO (DEMOnstration Power Plant) is a proposed nuclear fusion power plant that is intended to build upon the expected success of the ITER experimental nuclear fusion reactor. The objectives of DEMO are usually understood to lie somewhere between those of ITER and a "first of a kind" commercial station. As a prototype commercial fusion reactor, DEMO could make fusion energy available by 2033. Subsequent commercial fusion reactors could be built for nearly a quarter of the cost of DEMO if things go according to plan.
http://en.wikipedia.org/wiki/National_Ignition_Facility
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