GPU downclocks, it doesn't appear to be related to temperature or voltage issues.
GPU downclocks, it doesn't appear to be related to temperature or voltage issues.
Vellinious:
Boost 3.0 makes constant tweaks to clocks and voltages when temperatures rise. These changes occur regularly. I've noticed them working even at core temperatures as low as 15°C. You might manage to work around it by using the voltage/frequency curve to speed up the GPU.
That's intriguing, isn't it? Why would NVIDIA Pascal GPUs include this feature? It's a control mechanism. It lets faster GPUs operate efficiently at lower temperatures. It's quite fascinating to observe how it functions. The adjustments typically happen every 10°C or so, with minor variations.
Boost 3.0 continuously modifies clocks and voltages in response to rising temperatures. These changes occur without interruption. I've observed this behavior even at core temperatures as low as 15°C. To mitigate some effects, you can utilize the voltage/frequency curve to overclock the GPU.
Vellinious:
Boost 3.0 continuously tweaks clocks and voltages when temperatures rise. These changes occur all the time. I've noticed this with core temps as low as 15°C. You might mitigate it by leveraging the voltage/frequency curve to overclock the GPU.
Huh, that's intriguing—why would NVIDIA Pascal GPUs include this capability?
Interesting feature! Boost 3.0 continuously fine-tunes clocks and voltages when temperatures rise. Adjustments occur regularly, even at low core temperatures like 15°C. You can mitigate this by leveraging the voltage/frequency curve to overclock the GPU. This control is useful for GPUs that perform better at lower temps. It changes clock/voltage settings roughly every 10°C shift.