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This feature is only available on [[Intel]] microprocessors that support Turbo Boost and have the feature enabled and supported (e.g. most [[operating system|OSs]]). Under various workloads, especially once that are relatively low in power demands and are lightly threaded or not threaded at all, the processor can take advantage of the headroom by increasing the [[clock generator|clock]] frequency - while staying within thermal and electrical limits. The decision to kick into turbo boost is automatic and algorithmic in nature based on a number of factors such as: estimated current consumption, estimated power consumption, core temperature, and the number of active cores.
 
This feature is only available on [[Intel]] microprocessors that support Turbo Boost and have the feature enabled and supported (e.g. most [[operating system|OSs]]). Under various workloads, especially once that are relatively low in power demands and are lightly threaded or not threaded at all, the processor can take advantage of the headroom by increasing the [[clock generator|clock]] frequency - while staying within thermal and electrical limits. The decision to kick into turbo boost is automatic and algorithmic in nature based on a number of factors such as: estimated current consumption, estimated power consumption, core temperature, and the number of active cores.
  
The number of active cores, which Intel defines as cores in "C0" or "C1" states ("C3" and "C6" states are 'inactive'), dictates the upper limit. Generally, the more active cores, the lower the highest clock frequency Turbo Boost can allow as it's easier to exceed various electrical limits. For example, a [[dual-core]] 2 GHz MPU may allow a boost of 266.66 MHz (to 2266.66 MHz) when a single core is active but only 133.33 MHz (to 2133.33 MHz) when two cores are active.
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The number of active cores, which Intel defines as cores in "C0" or "C1" states ("C3" and "C6" states are 'inactive'), dictates the upper limit. Generally, the more active cores, the lower the highest clock frequency Turbo Boost can allow as it's easier to exceed various electrical limits. For example, a [[dual-core]] 2 GHz MPU may allow a boost of 266.66 MHz (to 2266.66 MHz) when a single core is active but only 133.33 MHz (to 2133.33 MHz) when two cores are active. (Note that if the thermal and electrical limits have been exceeded, Turbo Boost will be limited even further).
  
 
== See also==
 
== See also==
 
* {{intel|Dynamic Acceleration|Intel Dynamic Acceleration}} (IDA)
 
* {{intel|Dynamic Acceleration|Intel Dynamic Acceleration}} (IDA)

Revision as of 00:17, 28 April 2016

Turbo Boost Technology (TBT) is a microprocessor technology developed by Intel that attempts to enable temporary higher performance by opportunistically and automatically increasing the processor's clock frequency. This feature automatically kicks in on TBT-enabled processors when when there is sufficient power headroom - subject to power rating, temperature rating, and current limits.

History

Turbo Boost Technology 1.0 was first introduced announced in a white paper they published in November 2008. It was consequently introduced in the Nehalem microarchitecture. Turbo Boost 2.0 was introduced later in 2011 in the Sandy Bridge microarchitecture.

Mechanism

This feature is only available on Intel microprocessors that support Turbo Boost and have the feature enabled and supported (e.g. most OSs). Under various workloads, especially once that are relatively low in power demands and are lightly threaded or not threaded at all, the processor can take advantage of the headroom by increasing the clock frequency - while staying within thermal and electrical limits. The decision to kick into turbo boost is automatic and algorithmic in nature based on a number of factors such as: estimated current consumption, estimated power consumption, core temperature, and the number of active cores.

The number of active cores, which Intel defines as cores in "C0" or "C1" states ("C3" and "C6" states are 'inactive'), dictates the upper limit. Generally, the more active cores, the lower the highest clock frequency Turbo Boost can allow as it's easier to exceed various electrical limits. For example, a dual-core 2 GHz MPU may allow a boost of 266.66 MHz (to 2266.66 MHz) when a single core is active but only 133.33 MHz (to 2133.33 MHz) when two cores are active. (Note that if the thermal and electrical limits have been exceeded, Turbo Boost will be limited even further).

See also

designerIntel +
first launchedNovember 2008 +
instance oftechnology +
nameTurbo Boost Technology +