Electrical computers and digital processing systems: support – Computer power control – Power conservation
Reexamination Certificate
1999-12-23
2003-05-13
Auve, Glenn A. (Department: 2181)
Electrical computers and digital processing systems: support
Computer power control
Power conservation
Reexamination Certificate
active
06564328
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Technical Field
The present invention relates to microprocessors and, in particular, to mechanisms for controlling power consumption in microprocessors.
2. Background Art
Modern processors include extensive execution resources to support concurrent processing of multiple instructions. A processor typically includes one or more integer, floating point, branch, and memory execution units to implement integer, floating point, branch, and load/store instructions, respectively. In addition, integer and floating point units typically include register files to maintain data relatively close to the processor core. One drawback to providing a processor with extensive execution resources is that significant amounts of power are required to run them. Different execution units may consume more or less power, depending on their size and the functions they implement, but the net effect of packing so much logic onto a relatively small process chip is to create the potential for significant power dissipation problems.
Few programs require the full range of a processor's execution resources for significant intervals. The power dissipated running a program depends on the nature of its component instructions and their potential for being executed in parallel. Programs typically include a variety of instruction types, but it is rare that enough instructions of the correct type are available to keep all of the processor's execution resources busy for significant time periods. For this reason, most processor employ a clock gating mechanism to cut off the clock delivered to execution resources when they are not being used and hence reduce power. In addition, different components of an execution resource can be turned on and off as instructions enter and exit the pipe stage serviced by the component. Consequently, the average program may dissipate relatively manageable power levels.
Some programs do activate many of a processor's execution resources for relatively long time intervals and, consequently, dissipate significantly greater power than average programs. Unless a mechanism is provided to limit the processor's power consumption, the processor is generally designed to handle programs that consume the highest power. This may require running the processor at less than its top performance level for all programs, independent of the power required to run the average program.
Power throttling is a strategy that has been proposed to handle the power consumption problems created by high performance processors. Power throttling reduces the performance of a processor when its power consumption gets too high. This may be done by temporarily reducing the rate at which the processor executes instructions until power consumption decreases to a safe level. Power throttling allows the processor to be designed for the power levels at which the average program runs. When a resource-hungry program runs, the processor reduces its instruction execution rate to maintain its power consumption within an established limit.
Proposed power-throttling mechanisms rely on analog parameters to monitor the power being dissipated by a processor. For example, a thermal throttling mechanism monitors the temperature of the processor chip and reduces the processor's execution speed when the temperature exceeds a threshold value. Other throttling schemes have been proposed to monitor the current consumed by a processor or the duty cycle of a pulse width modulator in a switching regulator.
These power-throttling mechanisms have a number of drawbacks. They introduce additional analog circuitry into a predominantly digital environment, i.e. the processor. They are prone to vary with changes in the processor's environment (temperature, voltage, composition). They may create low frequency variations in the processor's power level. They do not directly limit the power consumed by the processor, and they are not deterministic. That is, their behavior can not be predicted on a clock by clock basis.
The present invention addresses these and other deficiencies of available power throttling mechanisms.
SUMMARY OF THE INVENTION
The present invention provides a digital throttle to control the power consumption of a microprocessor.
In accordance with the present invention, a processor includes one or more functional units and the digital throttle. The digital throttle monitors activity states of the processor's functional units to estimate the processor's power consumption.
For one embodiment of the invention, the digital throttle includes one or more gate units, a monitor circuit, and a throttle circuit. Each gate unit controls the delivery of power delivery to a functional unit of the processor and provides a signal that indicates the activity state of its associated functional unit. The monitor circuit determines an estimated power consumption level for the processor from signals and compares the estimated power consumption with a threshold power level. The throttle circuit adjusts the instruction flow in the processor if the estimated power consumption level exceeds the threshold power level.
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Grochowski Edward T.
Joshi Vivek
Kling Ralph M.
Matthews Gregory S.
Sharma Vinod
Auve Glenn A.
Novakoski Leo V.
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