Abstract: For determining a power consumption of electrical circuitry, at least one device executes at least a portion of a software application having an effect on a current through the electrical circuitry. A current is generated through a transistor for mirroring the current through the electrical circuitry. In response to a control word, a reference current is generated. In response to executing the portion of the software application, the control word is varied to determine a value thereof that causes the reference current to approximately equal the current through the transistor, in a manner that correlates the effect of the portion of the software application on the current through the electrical circuitry.

Abstract: This disclosure describes techniques for transferring data from an analog-to-digital converter (ADC) to a host device. The techniques may determine whether an ADC is operating in a quiet conversion time period, and selectively deactivate a digital data output of the ADC when the ADC is operating in the quiet conversion time period. This may allow an ADC to transfer data during both the conversion and acquisition phases of the ADC (rather than just during the acquisition phase), thereby increasing the data throughput of the ADC for a given transfer clock speed. The techniques may further allow data to be transferred during the conversion phase of an ADC without requiring a host device to be aware of the quiet conversion time period requirements of the ADC. In this way, the data throughput of an ADC data transfer may be increased with relatively little additional complexity added to a host device.

Abstract: This disclosure describes techniques for transferring data from an analog-to-digital converter (ADC) to a host device. The techniques may determine whether an ADC is operating in a quiet conversion time period, and selectively deactivate a digital data output of the ADC when the ADC is operating in the quiet conversion time period. This may allow an ADC to transfer data during both the conversion and acquisition phases of the ADC (rather than just during the acquisition phase), thereby increasing the data throughput of the ADC for a given transfer clock speed. The techniques may further allow data to be transferred during the conversion phase of an ADC without requiring a host device to be aware of the quiet conversion time period requirements of the ADC. In this way, the data throughput of an ADC data transfer may be increased with relatively little additional complexity added to a host device.

Abstract: For determining a power consumption of electrical circuitry, at least one device executes at least a portion of a software application having an effect on a current through the electrical circuitry. A current is generated through a transistor for mirroring the current through the electrical circuitry. In response to a control word, a reference current is generated. In response to executing the portion of the software application, the control word is varied to determine a value thereof that causes the reference current to approximately equal the current through the transistor, in a manner that correlates the effect of the portion of the software application on the current through the electrical circuitry.

Abstract: An aspect of the present invention simplifies the implementation of complex clock designs in field programmable devices (FPD). To implement a circuit logic containing base sequential elements (e.g., D flip-flops) with corresponding circuit clocks, a number of modified sequential elements equaling the number of base sequential elements may be employed. Each modified sequential element (contained in FPD) receives a global clock, corresponding circuit clock and a data value. A base sequential element (contained in modified sequential element) transitions to a next state only after occurrence of a transition on a corresponding circuit clock and the transition to said next state may be timed according to the global clock. By timing the transitions according to the global clock, several undesired results may be avoided.

Abstract: An aspect of the present invention simplifies the implementation of complex clock designs in field programmable devices (FPD). To implement a circuit logic containing base sequential elements (e.g., D flip-flops) with corresponding circuit clocks, a number of modified sequential elements equaling the number of base sequential elements may be employed. Each modified sequential element (contained in FPD) receives a global clock, corresponding circuit clock and a data value. A base sequential element (contained in modified sequential element) transitions to a next state only after occurrence of a transition on a corresponding circuit clock and the transition to said next state may be timed according to the global clock. By timing the transitions according to the global clock, several undesired results may be avoided.