- Milyen asztali (teljes vagy fél-) gépet vegyek?
- Házimozi belépő szinten
- Milyen házat vegyek?
- Milyen billentyűzetet vegyek?
- Azonnali notebookos kérdések órája
- NVIDIA GeForce RTX 5070 / 5070 Ti (GB205 / 203)
- Hamarosan megkezdődik a nubia 2,8K-s táblagépének szállítása
- Épített vízhűtés (nem kompakt) topic
- NVIDIA GeForce RTX 5080 / 5090 (GB203 / 202)
- Bambu Lab 3D nyomtatók
Új hozzászólás Aktív témák
-
HookR
addikt
válasz
S_x96x_S
#2743
üzenetére
A második linkeden van egy érdekes, látókör szélesítő komment, remélem nem gond, ha bemásolom:
olliej: "I still don’t understand what it is about avx2 that results in these kinds of issues - is it really just a matter of increased number of execution units running at once causing weird power and heat issues?"
paulmd: "Not increased number of execution units, but increased number of transistors, yeah.
A normal multiply does 1 number at a time (32 bit for simplicity). AVX2 can do up to 8 multiplications at a time. That's a huge amount more transistors firing all at once and that causes the voltage to start to droop.
AVX-512 takes that even further and now it's 16 multiplications per unit, oh and Intel moved from 1x256-bit unit per core on Haswell/Broadwell to 2x512-bit units on Skylake-X, so it's potentially 32 multiplications at a time.
Basically to prep for that much power being drawn all at once, the chip has to wind everything else down and switch to a higher-voltage mode to account for the voltage droop caused by all those transistors switching at once in one place.
At this level behavior is intensively analog and thermals/voltage both significantly affect transistor current draw and switching time, which feeds back into heat and power consumption.
This gets even more problematic on 7nm/10nm type nodes and especially in GPUs where you are doing a huge amount of vector arithmetic all the time. Essentially it is no longer possible to design processors that are 100% stable under all potential execution conditions, or even under normal operating conditions, so you have to have power watchdog circuitry that realizes when it's getting close to brownout/missing its timing conditions and slows itself down to stay stable. That's why AMD introduced clock stretching in a big way with Zen2 (despite the fact that it's nominally been around since Steamroller). NVIDIA piloted this with Pascal, AMD piloted it with Vega and brought it to CPU with Zen2. You simply cannot design the processor to be 100% stable at competitive clocks anymore. You have to have power management that's smart enough to withstand small transient power conditioning faults.
https://semiengineering.com/managing-voltage-drop-at-107nm/
https://semiengineering.com/power-delivery-affecting-performance-at-7nm/ "
Új hozzászólás Aktív témák
- Apple iPhone 14 Pro Max 128GB, Kártyafüggetlen, 1 Év Garanciával
- Új Apple iPhone 16 Pro 128GB, Kártyafüggetlen, 3 Év Garanciával
- Honor Magic7 Lite 512GB, Kártyafüggetlen, 1 Év Garanciával
- Honor 400 lite 256GB, Kártyafüggetlen, 1 Év Garanciával
- HP Prodesk 600G4 SFF - i5-8500, 16GB DDR4, 512GB NVMe SSD, ATI R5 430 2GB eladó!
- Dixit 4 Eredet (bontatlan, fóliás kártyacsomag)
- Microsoft Windows, Office & Vírusirtók: Akciók, Azonnali Szállítás, Garantált Minőség, Garancia!
- BESZÁMÍTÁS! ASUS ProArt Z790-CREATOR WIFI alaplap garanciával hibátlan működéssel
- LG UltraGear Gaming Monitorok: FRISS SZÁLLÍTMÁNY -30%
- Gamer Laptop, Gamer Monitor és Konzol Felvásárlás Magas Áron, Gyorsan és Egyszerűen!
Állásajánlatok
Cég: PC Trade Systems Kft.
Város: Szeged
Cég: CAMERA-PRO Hungary Kft
Város: Budapest