Post by ShrimpBrime on Jan 10, 2019 22:50:35 GMT -5
IBM Q System One featuring a 20-qubit processor basically for right now an introduction to commercial use as of this year 2019. This is a different level of computing and really still in the Alpha stages of understanding as quantum computing can be counter intuitive. But this next level computer will start to become more and more available for business to take a different approach as we move more into an era of robotics, AI and of course just improving technology altogether.
So the way a quantum computer thinks makes it easier for super large computation. As AI advances along, it will start writing faster and better algorithms that will help cure diseases and create better vaccines. In a nut shell thinking outside the X86 box with a wide variety of answers.
One of the problems with quantum anything is the possibility is always there, that for example, yes and no are the same answer at the same time as not being the same answer and thus why considered counter intuitive.
Like simple math for a quantum computer is difficult. 1+1 = 2 right? Well with quantum computing that answer could really not be 2 but 1 or 0 or 0 1 and 2 at the same time.
Any how, I think this technology needs another good 20 years of development and we may start seeing superior artificial results of what we can accomplish today.
So yea, here's a picture of that Q system One. Looks freaking cool.
IBM Q employs quantum science, systems engineering and industrial design to make quantum computing more reliable and stable.
Quantum computers are a radically different kind of computer based on the laws of quantum mechanics. IBM Q is building quantum computers with the potential to solve some problems beyond the reach of classical computers in such areas as financial services, pharmaceuticals and artificial intelligence. People today can access real quantum computers through the cloud to conduct research and explore new problems.
Today’s quantum computers include thousands of parts that work together to harness qubits to perform quantum computations. Qubits themselves are incredibly powerful, yet delicate. They quickly lose their special quantum properties, typically within 100 microseconds (for state-of-the-art superconducting qubits), due in part to electromagnetic environment, vibrations, and temperature fluctuations.
To make quantum computers more reliable and stable, IBM Q designed and built the world’s first integrated quantum computing system for commercial use: IBM Q System One.
IBM Q System One enables universal approximate superconducting quantum computers to operate beyond the confines of the research lab for the first time. www.research.ibm.com/ibm-q/system-one/
Quantum computers are a radically different kind of computer based on the laws of quantum mechanics. IBM Q is building quantum computers with the potential to solve some problems beyond the reach of classical computers in such areas as financial services, pharmaceuticals and artificial intelligence. People today can access real quantum computers through the cloud to conduct research and explore new problems.
Today’s quantum computers include thousands of parts that work together to harness qubits to perform quantum computations. Qubits themselves are incredibly powerful, yet delicate. They quickly lose their special quantum properties, typically within 100 microseconds (for state-of-the-art superconducting qubits), due in part to electromagnetic environment, vibrations, and temperature fluctuations.
To make quantum computers more reliable and stable, IBM Q designed and built the world’s first integrated quantum computing system for commercial use: IBM Q System One.
IBM Q System One enables universal approximate superconducting quantum computers to operate beyond the confines of the research lab for the first time. www.research.ibm.com/ibm-q/system-one/
So the way a quantum computer thinks makes it easier for super large computation. As AI advances along, it will start writing faster and better algorithms that will help cure diseases and create better vaccines. In a nut shell thinking outside the X86 box with a wide variety of answers.
Revolutionizing the molecule comparison process
Quantum computing has the potential to change the very definition of molecular comparison by enabling pharmaceutical and material science companies to develop methods to analyze larger-scale molecules. Today, companies can run hundreds of millions of comparisons on classical computers; however, they are limited only to molecules up to a certain size that a classical computer can actually compute. As quantum computers become more readily available, it will be possible to compare molecules that are much larger, which opens the door for more pharmaceutical advancements and cures for a range of diseases. www.accenture.com/us-en/success-biogen-quantum-computing-advance-drug-discovery
Quantum computing has the potential to change the very definition of molecular comparison by enabling pharmaceutical and material science companies to develop methods to analyze larger-scale molecules. Today, companies can run hundreds of millions of comparisons on classical computers; however, they are limited only to molecules up to a certain size that a classical computer can actually compute. As quantum computers become more readily available, it will be possible to compare molecules that are much larger, which opens the door for more pharmaceutical advancements and cures for a range of diseases. www.accenture.com/us-en/success-biogen-quantum-computing-advance-drug-discovery
Like simple math for a quantum computer is difficult. 1+1 = 2 right? Well with quantum computing that answer could really not be 2 but 1 or 0 or 0 1 and 2 at the same time.
Any how, I think this technology needs another good 20 years of development and we may start seeing superior artificial results of what we can accomplish today.
So yea, here's a picture of that Q system One. Looks freaking cool.
