Floating point | Units of frequency
In computing, floating point operations per second (FLOPS, flops or flop/s) is a measure of computer performance, useful in fields of scientific computations that require floating-point calculations. For such cases, it is a more accurate measure than measuring instructions per second. (Wikipedia).
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From playlist Miscellaneous
An intro to the core protocols of the Internet, including IPv4, TCP, UDP, and HTTP. Part of a larger series teaching programming. See codeschool.org
From playlist The Internet
From playlist Related Videos: Devour, Digest, YouTube Poop
Donuts are paralyzed with embarrassment (and as a result unable to escape) when someone is laughing at them.
From playlist Videos with my cats!
A different way at trying to quit smoking!
From playlist Funny Videos, Parodies, Odds and ends!
This 59 second video gives you a glimpse of what Flipping Physics is all about. Algebra Based Physics Videos: http://www.flippingphysics.com/algebra.html Calculus Based Physics Videos (AP Physics C): http://www.flippingphysics.com/calculus.html
From playlist Miscellaneous
ELEC2141 Digital Circuit Design - Lecture 19
ELEC2141 Week 7 Lecture 2: Sequential Circuit Design
From playlist ELEC2141 Digital Circuit Design
Latches and Flip-Flops 5 – D Type Flip Flop
This is the fifth in a series of videos about latches and flip-flops. These bi-stable combinations of logic gates form the basis of computer memory, counters, shift registers, and more. In particular, this video covers the D type flip flop, that is, a master slave configured combination
From playlist Latches and Flip-Flops
Latches and Flip-Flops 6 - The JK Flip Flop
This is the sixth in a series of computer science and electronics lessons about latches and flip-flops. In particular, this video covers the JK flip flop, which is one of the most versatile flip flops. It is widely used in shift registers, ripple counters, event detectors, frequency divi
From playlist Latches and Flip-Flops
Vacuum Tube Computer P.06 –Building a New Results Register
In this episode, we take a stab at trying to solve our issue with the results register by building a completely new register. We end up with a weird concoction of our Proof of Concept wired into a breadboard, but the results speak for themselves! Also, we’re now on Discord, Reddit and Twi
From playlist Vacuum Tube Computer
Addressing Memory (Pt1) - Computerphile
Each BIT in memory doesn't have it's own unique wiring, they share connections - Dr 'Heartbleed' Bagley explains how we address them. Binary: Plusses & Minuses (Why We Use Two's Complement): http://youtu.be/lKTsv6iVxV4 Flip Flops, Latches & Memory Details: http://youtu.be/-Ecf7lb4aZ0 Do
From playlist How Computer Memory Works
Vacuum Tube Computer P.09 – Building the 4-bit Instruction Register
Straight up, this is the coolest looking piece of electronics I’ve ever built! It looks awesome, it works great, I couldn’t be happier. So, come along as we go through the journey of building the first finalized part of our vacuum tube computer. Also, check out these episodes I reference:
From playlist Vacuum Tube Computer
Error detection: Parity checking
Parity checking is a basic technique for detecting errors in data transmission. This video explains how it works and walks through building hardware to compute and check parity. The hardware is based on my previous video: https://youtu.be/eq5YpKHXJDM Code from this video: https://github.
From playlist Error detection
How a quartz watch works - its heart beats 32,768 times a second
Get 75% off NordVPN with this link: https://nordvpn.com/steve and use the promo code steve to get the first 30 days free. Quartz watches have a tiny crystal tuning fork inside that vibrates at 2^15 Hz and there's a really clever reason for that. This video also talks a bit about how mecha
From playlist Best of
CMOS Process Variations: A Critical Operation Point Hypothesis
April 2, 2008 lecture by Janak H. Patel for the Stanford University Computer Systems Colloquium (EE380). Prevailing understanding of a chip's behavior under large process variations with statistical delay assumptions leads one to conclude that a small number of errors are likely as we p
From playlist Lecture Collection | Computer Systems Laboratory Colloquium (2007-2008)
An effective solution to the "racing" problem described in my previous video (https://youtu.be/st3mUEub99E) is the master-slave JK flip-flop which comprises two SR latches. In this video I explain how it works, build, and test it. Support me on Patreon: https://www.patreon.com/beneater Y
From playlist Building an 8-bit breadboard computer!