A discrete state event-driven (DSED) simulation method for simulation of a power electronic system is disclosed. With respect to continuous states and discrete events in the power electronic system, the method includes: numerical integration of the continuous states with a flexible adaptive (FA) algorithm having both variable step-size and variable order; and location of the discrete events with an event-driven (ED) mechanism, in which active events are picked out and pre-scheduled before their occurrence while passive events are located by iterative search. The proposed to DSED simulation method can achieve significant improvement in simulation efficiency, with remarkably reduced computational costs at the same level of numerical accuracy. The proposed DSED simulation method is particularly applicable for complex power electronic systems with modular combined topology and high switching frequency.

A management apparatus (10) includes: a storage (103) that stores information indicating a correspondence between at least one virtual network function (VNF) operating on a server and a programmable logic circuit (FPGA) capable of operating at least part of a virtual network function; and a controller (106) that causes first and second servers to perform migration of a virtual network function operating on a programmable logic circuit of the first server to the second server, on the basis of the correspondence information.

A physical quantity measurement device includes a sensor element having a coupling capacitance formed between a drive electrode and a detection electrode, and a circuit device having a drive circuit adapted to supply a drive signal to the drive electrode, a detection circuit adapted to detect physical quantity information corresponding to a physical quantity based on a detection signal from the detection electrode, and a fault diagnosis circuit, and the fault diagnosis circuit has an electrostatic leakage component extraction circuit adapted to extract an electrostatic leakage component due to the coupling capacitance from one of the detection signal and an amplified signal of the detection signal, and performs a fault diagnosis based on the electrostatic leakage component extracted.

A physical quantity measurement device includes a sensor element having a coupling capacitance formed between a drive electrode and a detection electrode, and a circuit device having a drive circuit adapted to supply a drive signal to the drive electrode, a detection circuit adapted to detect physical quantity information corresponding to a physical quantity based on a detection signal from the detection electrode, and a fault diagnosis circuit, and the fault diagnosis circuit has an electrostatic leakage component extraction circuit adapted to extract an electrostatic leakage component due to the coupling capacitance from one of the detection signal and an amplified signal of the detection signal, and performs a fault diagnosis based on the electrostatic leakage component extracted.

Improved computer-implemented tools for use in modeling/simulating spatial charge distributions for electrophysiological systems are provided. The improvements are in three areas: (1) the use of solid angles to calculate quantities of free charge and/or bound charge in calculation cells and/or the movement of quantities of free charge across one or more faces of a calculation cell; (2) the use of flattened calculations cells having only two faces with substantial areas as seen from the free charge and/or the bound charge of the electrophysiological system; and (3) the use of at least two spatial charge distributions, specifically, at least one for bound charge and at least one for free charge, so as to include the effects of relative dielectric constants greater than 1.0 for part or all of an electrophysiological system. The three improvements can be used individually or in combinations.

Disclosed examples include non-volatile counter systems to generate and store a counter value according to a sensor pulse signal, and power circuits to generate first and second supply voltage signals to power first and second power domain circuits using power from the sensor pulse signal, including a switch connected between first and second power domain supply nodes, a boost circuit, and a control circuit to selectively cause the switch to disconnect the first and second power domain circuits from one another after the first supply voltage signal rises above a threshold voltage in a given pulse of the sensor pulse signal, and to cause the boost circuit to boost the second supply voltage signal after the regulator output is disconnected from the second power domain supply node in the given pulse.

Disclosed examples include non-volatile counter systems to generate and store a counter value according to a sensor pulse signal, and power circuits to generate first and second supply voltage signals to power first and second power domain circuits using power from the sensor pulse signal, including a switch connected between first and second power domain supply nodes, a boost circuit, and a control circuit to selectively cause the switch to disconnect the first and second power domain circuits from one another after the first supply voltage signal rises above a threshold voltage in a given pulse of the sensor pulse signal, and to cause the boost circuit to boost the second supply voltage signal after the regulator output is disconnected from the second power domain supply node in the given pulse.

A random number generation system and a random number generation method thereof are provided. The random number generation system includes a random number generator, a random number selection circuit, and a random number logic circuit. The random number generator receives the random number request signal to provide a first random number sequence with n bits, where n is a positive integer. The random number selection circuit receives the random number request signal to provide a bit selection signal with n bits, wherein the bit selection signal is a time varying signal and is determined by the received random number request signal. The random number logic circuit receives the random number request signal, the first random number sequence and the bit selection signal, and in response to the random number request signal to adjust the first random number sequence using the bit selection signal to provide the second random number sequence.

A random number generation system and a random number generation method thereof are provided. The random number generation system includes a random number generator, a random number selection circuit, and a random number logic circuit. The random number generator receives the random number request signal to provide a first random number sequence with n bits, where n is a positive integer. The random number selection circuit receives the random number request signal to provide a bit selection signal with n bits, wherein the bit selection signal is a time varying signal and is determined by the received random number request signal. The random number logic circuit receives the random number request signal, the first random number sequence and the bit selection signal, and in response to the random number request signal to adjust the first random number sequence using the bit selection signal to provide the second random number sequence.

Disclosed examples include non-volatile counter systems to generate and store a counter value according to a sensor pulse signal, and power circuits to generate first and second supply voltage signals to power first and second power domain circuits using power from the sensor pulse signal, including a switch connected between first and second power domain supply nodes, a boost circuit, and a control circuit to selectively cause the switch to disconnect the first and second power domain circuits from one another after the first supply voltage signal rises above a threshold voltage in a given pulse of the sensor pulse signal, and to cause the boost circuit to boost the second supply voltage signal after the regulator output is disconnected from the second power domain supply node in the given pulse.