Circuitry for optimization of power consumption in a system employing multiple electronic components, one of which is always powered on
First Claim
1. Circuitry for conserving power in a system having multiple electronic components, comprising:
- a power source;
a first electronic component operating at a first frequency and continuously powered on by the power source; and
a second electronic component operating at a second frequency different than that of the first frequency of the first electric component, the second electronic component being maintained in a powered off state in which no energy is consumed by the second electronic component until energized in response to a power enabling signal generated by the first electronic component based on demand of the particular function to be performed by the second electronic component.
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Accused Products
Abstract
Circuitry for conserving power in a system employing multiple electronic components of which a first electronic component operates at a first frequency and is continuously powered on by a power source. The system further includes a second electronic component operating at a second frequency different than that of the first frequency of the first electric component, the second electronic component being maintained in a powered off state in which no energy whatsoever is consumed by the second electronic component until energized in response to a power enabling signal generated by the first electronic component based on demand of the particular function to be performed by the second electronic component. The first and second electronic components may be processors, wherein the frequency of the first processor is lower than that of the second processor.
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Citations
20 Claims
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1. Circuitry for conserving power in a system having multiple electronic components, comprising:
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a power source;
a first electronic component operating at a first frequency and continuously powered on by the power source; and
a second electronic component operating at a second frequency different than that of the first frequency of the first electric component, the second electronic component being maintained in a powered off state in which no energy is consumed by the second electronic component until energized in response to a power enabling signal generated by the first electronic component based on demand of the particular function to be performed by the second electronic component. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
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9. A closed system including:
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an external control device;
an internal device separated from the external device by a boundary and adapted to receive communications from the external control device, the internal device comprising;
an internal power source;
a first processor operating at a first frequency and continuously powered by the internal power source;
a second processor operating at a second frequency higher than that of the first frequency of the first processor, the second processor being maintained in a powered off state in which no energy is consumed until powered on in response to a power enabling signal generated by the first processor based on demand to perform a particular task by the second processor;
a regulator electrically connected to adjust power supplied to the second processor;
a switch electrically connected between the internal power source and the regulator, the switch remaining in an open state until closed in response to the power enable signal generated by the first processor; and
a voltage level translator electrically coupled as an interface between the first and second processors operating at different supply voltage levels to translate a logic signal from a first power supply voltage of the first processor to a second power supply voltage of the second processor. - View Dependent Claims (10, 11, 12, 13)
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14. A method for optimizing power consumption in a system including a first electronic component operating at a first frequency and being continuously powered on by a power source, and a second electronic component electrically coupled to the first electronic component by a voltage level translator and operating at a second frequency different than that of the first frequency of the first electric component, the second electronic component being normally maintained in a powered off state in which no energy is consumed by the second electronic component, comprising the steps of:
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generating a power enable signal by the first electronic component;
energizing the second electronic component in response to receiving the power enable signal generated by the first electronic component; and
when the second electronic component is in an energized state, transmitting a logic data signal converted from a first power supply voltage of the first electronic component to a second power supply voltage of the second electronic component using a voltage level translator electrically coupled as an interface between the first and second electronic components operating at different supply voltage levels;
while prohibiting transmission of the data signal to the second electronic component while in a powered off state. - View Dependent Claims (15, 16, 17, 18, 19, 20)
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Specification