Roughly speaking, an N-level digital logic system requires O(N) transistors in order to buffer/force a signal into one of N states, but only performs O(log(N)) more work with them relative to binary. Without the…
6 million gallons/yr / 40 inches/yr (average annual rainfall in NY) = 5.5 acres
I think the answer amounts to "anyone who has at least a rack full of Dell/HPE hardware". Dell manages an annual revenue of greater than $20B, so on-prem HW is clearly going strong, regardless of whether or not you…
Looking at the hardware, I'd wag somewhere in the $2-3M range. Depends on how big of a profit margin they want to make or how scrappy they feel like being (could probably go as low as ~$1M if they can make it up in…
Roughly, the power of a digital system is sum of the static power and the dynamic power (P=1/2 CV^2*F). 1. Discrete logic chips tend to be built in substantially larger process nodes (microns vs nanometers) that are…
You are now debugging a distributed system.
Roughly speaking, an N-level digital logic system requires O(N) transistors in order to buffer/force a signal into one of N states, but only performs O(log(N)) more work with them relative to binary. Without the…
6 million gallons/yr / 40 inches/yr (average annual rainfall in NY) = 5.5 acres
I think the answer amounts to "anyone who has at least a rack full of Dell/HPE hardware". Dell manages an annual revenue of greater than $20B, so on-prem HW is clearly going strong, regardless of whether or not you…
Looking at the hardware, I'd wag somewhere in the $2-3M range. Depends on how big of a profit margin they want to make or how scrappy they feel like being (could probably go as low as ~$1M if they can make it up in…
Roughly, the power of a digital system is sum of the static power and the dynamic power (P=1/2 CV^2*F). 1. Discrete logic chips tend to be built in substantially larger process nodes (microns vs nanometers) that are…
You are now debugging a distributed system.