To prevent the reference clock frequency from rising too high, it is necessary to lower the CPU and memory multipliers. On our configuration, we achieved a stable BCLK Frequency of 148 MHz with no USB- or SATA-related issues. At the time of this writing, only three or four models do. If you plan on exploring BCLK Frequency, make sure the board you pick does indeed feature an external clock generator. But certain manufacturers include an external clock generator on their high-end platforms. Many motherboards do not allow the BCLK Frequency to be modified, locking it down to 100 MHz. But if 1.7V pushed our chip to "only" 98☌ after a few seconds, then the voltage needed to immediately hit 120☌ must have been close to 2V. We have no idea what voltage was applied when the temperature offsets were showing +120☌. The result? Nothing died, but we discovered a 1.1V software setting was really 1.7V on the board. So we grabbed our voltmeter and carefully read the supply voltage. Finally, as we were setting the voltage to 1.1V, the temperature spiked at 98☌. Several minutes later, we were at +114☌ again, just before another crash (at least the built-in protection features work). Cinebench R15 didn't even have a chance to display its first pixel. Suddenly, after setting the core voltage to 1.2V, the temperature shot from 50☌ to 120☌ in one-tenth of a second. We'd make our adjustments via Windows and observe their effect on temperatures. During testing, we fiddled with various voltage settings. We did find several bugs while using TurboV Core.
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