Abstract: A computing device apparatus facilitates use of a deep low power mode that includes powering off the device's CPU by including a software routine configured to be run by the CPU that effects saving to a non-volatile memory a state of the CPU and/or the device's peripherals before entering the deep low-power mode. The software routine can be configured to control this state storage in response to detecting a low power event, i.e., loss of power sufficient to run the CPU, or a software command to enter the deep low power mode to save power as part of an efficiency program. Then, upon wake up from the deep low power mode, the software routine is first run by the CPU to effect restoring from the non-volatile memory the state of the CPU and the peripherals before execution of a primary application for the central processing unit.

Abstract: A computing device apparatus facilitates use of a deep low power mode that includes powering off the device's CPU by including a hardware implemented process to trigger storage of data from the device's volatile storage elements in non-volatile memory in response to entering the low power mode. A hardware based power management unit controls the process including interrupting a normal processing order of the CPU and triggering the storage of the data in the non-volatile memory. In response to a wake-up event, the device is triggered to restore the data stored in the non-volatile memory to the volatile memory prior to execution of a wake up process for the CPU from the low power mode. The device includes a power storage element such as a capacitor that holds sufficient energy to complete the non-volatile data storage task prior to entering the low power mode.

Abstract: A computing device apparatus facilitates use of a deep low power mode that includes powering off the device's CPU by including a software routine configured to be run by the CPU that effects saving to a non-volatile memory a state of the CPU and/or the device's peripherals before entering the deep low-power mode. The software routine can be configured to control this state storage in response to detecting a low power event, i.e., loss of power sufficient to run the CPU, or a software command to enter the deep low power mode to save power as part of an efficiency program. Then, upon wake up from the deep low power mode, the software routine is first run by the CPU to effect restoring from the non-volatile memory the state of the CPU and the peripherals before execution of a primary application for the central processing unit.

Abstract: The invention relates to an electronic device which comprises a comparator coupled to monitor a first supply voltage level at a first supply voltage node. The comparator comprises a differential input transistor stage having one input coupled to the first supply voltage node and the other input coupled to receive a reference voltage level, a first current source configured to supply a current of a first magnitude, a second current source configured to supply a current of a second magnitude, and a capacitor. The first magnitude is greater than the second magnitude and the first current source is coupled with one side to the differential input stage for supplying the differential input stage and with the other side to a first node. The second current source is coupled with one side to the first node and with the other side to a second supply voltage node having a second supply voltage level and the capacitor is coupled with one side to the first node and with the other side to the first supply voltage node.

Abstract: The invention relates to an electronic device which comprises a comparator coupled to monitor a first supply voltage level at a first supply voltage node. The comparator comprises a differential input transistor stage having one input coupled to the first supply voltage node and the other input coupled to receive a reference voltage level, a first current source configured to supply a current of a first magnitude, a second current source configured to supply a current of a second magnitude, and a capacitor. The first magnitude is greater than the second magnitude and the first current source is coupled with one side to the differential input stage for supplying the differential input stage and with the other side to a first node. The second current source is coupled with one side to the first node and with the other side to a second supply voltage node having a second supply voltage level and the capacitor is coupled with one side to the first node and with the other side to the first supply voltage node.

Abstract: The present invention is applicable to an electronic device including a master, a slave, a bus coupling the master and the slave and a clock generator for providing a system clock to the master and slave. The clock generator determines whether the received data is correct on a cycle-by-cycle basis. The clock generator suppresses an edge of a next clock cycle of the system clock signal if the data is not to be correct. The clock generator allows the edge of a next clock cycle of the system clock signal if the data is correct.

Abstract: The present invention is applicable to an electronic device including a master, a slave, a bus coupling the master and the slave and a clock generator for providing a system clock to the master and slave. The clock generator determines whether the received data is correct on a cycle-by-cycle basis. The clock generator suppresses an edge of a next clock cycle of the system clock signal if the data is not to be correct. The clock generator allows the edge of a next clock cycle of the system clock signal if the data is correct.