![]() What this means is that the end user will most likely buy/build a new computer completely for every other Intel CPU generation, which generates a lot of profit for Intel, since they’re partnered with many pre-built PC companies.īy the way, a new Tick or Tock is expected to come out every year. This also means that you’ll need a new motherboard, and occasionally even a new generation of RAM (for example, Skylake will use DDR4 and DDR3 RAM where as most CPUs these days can use DDR3 or DDR2 RAM). Second, Intel’s CPUs use a new socket and chipset for every new Tock.I personally prefer Tock since heat, power consumption and mobility are not really my problems. Tock on the other hand offers a completely new chip with a big performance boost. Tick offers a smaller chip with lower heat generation and power consumption, which also allows it to be more mobile, and a small performance boost. First of all, it encourages people to upgrade every other generation, depending on whether the user likes Tick or Tock.So how does the Tick-Tock model benefit everyone? Well… Tick, “Haswell” architecture, 14nm) –> Skylake (6th Generation. Tock, “Haswell” architecture, 22nm) –> Broadwell (5th Generation. Tick, “Sandy Bridge” architecture, 22nm) –> Haswell (4th Generation. Tock, “Sandy Bridge” architecture, 32nm) –> Ivy Bridge (3rd Generation. Tick, “Nehalem” architecture, 32nm) –> Sandy Bridge (Intel 2nd Generation. Tock, “Nehalem” architecture, 45nm) –> Westmere (was considered a modification of Nehalem rather than a new generation. “ Intel 1st generation“, signaling the birth of the Intel Core ix series. P6 (Tick, 65nm manufacturing process) –> Merom (Tock, “Core” architecture, 65nm) –> Penryn (Tick, “Core” architecture, 45nm) –> Nehalem (a.k.a. Why the “Tock” comes first is because it’s the stronger sound of the two. Since the P6 microarchitecture (the CPU generation with the legendary Pentium 4), Intel has adopted a Tick-Tock Model, which means that for every microarchitecture, there’ll be a “Tock”, which is a chip using that architecture, and later a “Tick”, which is a die shrink of said chip (a die shrink is basically the same chip architecture made with a smaller manufacturing process). A “smaller” manufacturing process will allow the production of a smaller transistor, and that’ll be our discussing topic for today. That’s where manufacturing processes come in. I mean, just look at graphics cards!īut of course, in order to fit twice as many transistors in the same place, the transistors will need to get smaller. What this means to the computing industry is that the number of transistors in a processor (CPU, GPU, etc.) will double roughly every two years, which also means that there will be a component roughly twice as powerful every two years. This, of course, is not a scientific law but more of an observation. Moore’s Law (named after Intel co-founder Gordon Earle Moore) states: “ The number of transistors in a dense integrated circuit doubles every two years.” Intel 6th Generation) chips, and announced their Kaby Lake chips a while before that. Instead, I’ll provide some commentary and explanation on some more obscure stuff, like Moore’s Law and Intel’s Tick-Tock model, since Intel has just officially released their Skylake (a.k.a. However, I won’t introduce to you what a CPU is, since you should have already been familiar enough with this thing, even if you are just a complete newbie to this field. About time I make a blog post about the CPU, the most well-known part of a PC, and perhaps everything that can be classified as a “computer” ever. ![]()
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