Bigger CPU
Have you checked your motherboard recently? Even though the CPU is obviously the most important thing in your PC, it still has as much dedicated space as it did in 1993. I mean, the whole CPU packet is about the size of a few post stamps, which raises a question. If they want a competitive edge, why not Intel or AMD just make their CPUs bigger? Consider how many cores and how much more efficient it would be if we had a CPU equivalent to grilled cheese. Or am I missing something here? In response, we contacted our friends Matthew Hurwitz at AMD and Ben Benson at Intel, And we would like to thank both of them for their insight. Another easy way to guess this is to think About how a car engine works. Even in a small car, you can be said to throw high performance, A 10-cylinder engine instead of a four-cylinder banger that takes you to your cubicle job. But apparently, a 10-cylinder engine is more expensive to produce than an inline line. And even though CPUs are much smaller than car engines, adding more transistors is not really cheap. Don't say that if you make the chips bigger, Manufacturers get a few CPUs with silicon storage, driving costs per unit. In addition, a larger death means that there is a higher chance of a given CPU with errors. CPU execution is a very complex process And not all the pieces we just showed you will be used. In fact, a large part of the CPU is discarded at the factory because of very small defects that can damage performance or make the chip unusable. So producers do not want to add to the pressure that will push their harvest of chips down, damaging their jeans. But even if the yield was close to 100%, it does not make a ton of ideas for producers to make a big die. You see, it is actually very difficult to produce a large CPU with tons of cores running at the same clock speed as a CPU with fewer and smaller calls. Not only do you have to fight against overheating, but it can also be detrimental to the speed of today's CPU clock, even a few inches can make it difficult to keep everything in sync, forcing you to run low clocks. This is especially true if you are trying to back up that extra processing power with additional cache memory. This is part of the reason that if you have ever looked at high-density CPUs, you will have noticed that the clock tides are usually lower than standard chips. Similar to Wi-Fi trading between speed and bandwidth, CPU design is a trade-off between speed and death size.
Or especially, a basic calculation. So instead of trying to make bigger CPUs with more transistors, manufacturers instead, think about how the processor will be used and prepare for that.Because a large CPU dies will have to work at low clock speeds, it may not be ideal for a game like playback, where trying to get faster performance with a single cable is usually the best way to go. In addition, simply forcing the performance by adding multiple transistors does not always bring good results anyway. Instead, the CPU build can be customized with some use cases in mind, such as Fast Sync Video on Intel platforms to assist with transcoding, or AMD installation of PCI Express Gen 4 to enable high-speed storage. So keep in mind that big isn't always good, and unless they make the CPU packages too big, where can you put all the fun RGB? Speaking of which, where can you put all that fun, log in to our sponsor ... See Private Internet Access, a VPN that hides your IP address and encrypts your internet traffic. PIA has a reliable service with thousands of servers in many countries, and no bandwidth caps. PIA provides configurable encryption and an online kill switch to keep you in control of your communications and privacy. And when you combine PIA with good privacy browsing habits, you can make websites think you're foreign. With one account, you can connect up to 10 devices simultaneously with their Windows, Mac, Android, iOS, and Linux clients, and you can try it without risk for 30 days, Just go to internetinternetaccess.com TechQuickie. We will be able to connect down below.
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