Quick note: This testing is after our delid, so we’re using liquid metal – but it’s still the same test across all versions of the setting, so not a big deal. Enabling the 4.7GHz forced all-core Turbo pushes us to 145W, a substantial 42% increase in power consumption for our 8.9% increase in Cinebench performance. With the complete stock, Intel-specified configuration, power consumption measures at about 102W during Cinebench testing. We’re measuring at the EPS12V rails here, so this is not wall power and is representative almost exclusively of the CPU power consumption. Power Consumption with Multi-Core EnhancementĪs for the non-free aspect of “multicore enhancement” options, power consumption for that Cinebench test looks like this chart.
That’s one immediate reason you might want to avoid this setting, or a reason that crashes could be caused without much explanation as to why.
#HOW TO ENABLE TURBO BOOST I7 7700 MANUAL#
The voltage couldn’t sustain the all-core Turbo at 4.7GHz, despite our manual overclocks sustaining at 4.9GHz for these tests. Our next set of tests focuses on power consumption and thermals, and we intended to use Blender for the benchmark – but it just wasn’t stable on the ASUS Z370 board with multi-core enhancement enabled. Enabling multi-core enhancement options boosts that to about 1578 marks, for an 8.9% performance uplift as a result of the 4.7GHz all-core Turbo.
The difference from all-core Turbo enhancements is immediately visible in Cinebench: Disabled, with the clocks generally locking to 4.3GHz all-core (per Intel’s spec), our multi-pass average sits at 1448 cb marks. The feature auto-locks frequency to its maximum setting in all conditions, which means that testing conducted with it enabled will result in unrealistically high power consumption, unrealistically high voltage, and unrealistically high scores. What we’re demonstrating today is the impact of multi-core enhancement – a feature present on both AMD and Intel boards – and how the feature can cause confusion in the user base. When more threads are engaged, the boost is lower (in compliance with stability and lower voltage). With lower thread engagement applications, depending on if it’s Ryzen or Threadripper, AMD can add an additional +100MHz to +200MHz to the boosted speed. AMD employs XFR on Ryzen onward, or Extended Frequency Range, and leverages its boosting also on a per-thread level. Intel and AMD both do something similar to the above: With the 8700K, Intel uses Turbo Boost with different frequencies as dependent on thread engagement, where single-core utilization boosts the highest (4.7GHz) and six-core utilization boosts the lowest (4.3GHz, over 3.7GHz base). Stock Intel Turbo Boost Behavior on Coffee Lake Enabling multi-core enhancement means that the CPU ignores the Intel spec, instead locking all-core Turbo to the single-core Turbo speeds, which means a few things: (1) Higher voltage is now necessary, and therefore higher power draw and heat (2) instability can be introduced to the system, as we observed in Blender on the ASUS Maximus X Hero with multi-core enhancement on the 8700K (3) performance is bolstered in-step with higher all-core Turbo. Multi-core “enhancement” options are either enabled, disabled, or “auto” in motherboard BIOS, where “auto” has somewhat nebulous behavior, depending on board maker. This primarily sets forth to highlight what “Multi-Core Enhancement” is, and why you may want to leave it off when using a CPU without overclocking. This content piece aims to explain how Turbo Boost works on Intel’s i7-8700K, 8600K, and other Coffee Lake CPUs. Please note that this impacts Cinebench scores and POVRay scores, but not gaming scores.
#HOW TO ENABLE TURBO BOOST I7 7700 UPDATE#
UPDATE: We've issued an update to our initial 8700K review, pursuant to interesting findings on the Gigabyte F2 BIOS revision.