A communication device, a communication system and an operation method thereof are provided. The communication device includes a micro-controller unit (MCU) and a field programmable gate array (FPGA). The FPGA is coupled to the MCU, and is configured to execute a first communication protocol to work with the MCU so as to communicate with another communication device in a first period, and meanwhile the FPGA is programmed with a second communication protocol by the MCU in the same first period. The FPGA is controlled by a switch pulse output from the MCU to terminate the first period, and switched from the first communication protocol to the second communication protocol, and then executes the second communication protocol to work with the MCU so as to communicate with the another communication device in a second period.

Provided is a load drive slope control device that can reduce EMI noise, and power loss and heat generation when a drive transistor is turned on and off, and can prevent excessive high temperature-induced damage to the drive transistor at an excessive high temperature. Disclosed is a load drive control device including: a drive transistor that drives a load; a pre-driver that drives the drive transistor via an ON/OFF control terminal of the drive transistor; a capacitor that is connected to an input side of the pre-driver, a first current source that is ON/OFF controlled by a first signal, and generates current which is charged to the capacitor; and a second current source that is ON/OFF controlled by a second signal, and generates current for discharging the capacitor, in which an output voltage from the pre-driver is changed by charging or discharging the capacitor, the drive transistor is turned on and off by the output voltage from the pre-driver, and a linear ascending gradient and a linear descending gradient of the waveform of a voltage driving the load are obtained by turning on and off the drive transistor.

A semiconductor device connectable between a first power-supply line connected to a power source and through which power is continuously supplied to a first circuit, and a second power-supply line that is not directly connected to the power source and is connected to a second circuit, includes a first switch connectable between the first and second power-supply lines and turned on in response to a signal for supplying power to the second circuit, a second switch connectable between the first and second power-supply lines and having a current supply capability higher than the first switch, and a control circuit configured to turn on the second switch when the first switch is turned on and a voltage applied to the second power-supply line has reached a threshold.

An electronic component is described which includes a first transistor encased in a first package, the first transistor being mounted over a first conductive portion of the first package, and a second transistor encased in a second package, the second transistor being mounted over a second conductive portion of the second package. The component further includes a substrate comprising an insulating layer between a first metal layer and a second metal layer. The first package is on one side of the substrate with the first conductive portion being electrically connected to the first metal layer, and the second package is on another side of the substrate with the second conductive portion being electrically connected to the second metal layer. The first package is opposite the second package, with at least 50% of a first area of the first conductive portion being opposite a second area of the second conductive portion.

Disclosed herein are switching or other active FET configurations that implement a branch design with one or more interior FETs of a main path coupled in parallel with one or more auxiliary FETs of an auxiliary path. Such designs include a circuit assembly for performing a switching function that includes a branch with a plurality of auxiliary FETs coupled in series and a main FET coupled in parallel with an interior FET of the plurality of auxiliary FETs. The body nodes of the FETs can be interconnected and/or connected to a body bias network. The body nodes of the FETs can be connected to body bias networks to enable individual body bias voltages to be used for individual or groups of FETs.

A switching circuit has a primary MOSFET switch connected between first and second terminals that are connected to a power line and a load represented as a resistance and inductance. The primary switch is operable by primary control commands to assume a conductive or non-conductive state. Four protection branches are connected in parallel with the primary switch, each having a series connected resistive element and a secondary MOSFET switch operable by branch control commands received at branch command terminals to assume a conductive or non-conductive state. A timing circuit applies branch turn off control commands in sequence to the branch command terminals, each delayed by a different predetermined time interval relative to when a primary turn off control command is applied to the primary switch.

A switch circuit is provided. The switch circuit includes a P-type transistor switch and a first P-type control transistor. The P-type transistor switch includes a first control end, a first output end, and a first input end. The first input end receives a first input signal whose logic level is one. The first P-type control transistor is coupled to the first input end and the first control end. The first P-type control transistor includes a second control end. The second control end receives a second input signal whose logic level is zero to turn on the first P-type control transistor. When the first P-type control transistor is turned on, the first input signal is transmitted to the first control end of the P-type transistor switch to turn off the P-type transistor switch.

A driver for a power field-effect transistor includes a first and second circuits that apply respective charge currents to a gate of the power field-effect transistor when a control signal has a first logic value and the voltage between the gate and the source is smaller than a first threshold voltage and greater than a second threshold voltage. Third and fourth circuits apply respective discharge currents to the gate when the control signal has a second logic value and the voltage between the gate and the source is greater than a third threshold voltage and smaller than a fourth threshold voltage. The driver may include at least one field-effect transistor configured to generate at least one of the first, second, third or fourth threshold voltage.

A gate drive circuit includes: an input terminal; a first circuit path inserted into a line connecting the input terminal and a gate of a power transistor; a second circuit path connected in parallel to the first circuit path; and a third circuit path connected in parallel to the second circuit path. The first circuit path includes a gate resistor (Rgon). The second circuit path includes a first capacitor and a first resistor connected in series. The third circuit path includes a second capacitor and a second resistor connected in series. The second capacitor has a capacitance value greater than a capacitance value of the first capacitor. The second resistor has a resistance value greater than a resistance value of the first resistor. The gate resistor (Rgon) has a resistance value greater than the resistance value of the second resistor.

A switch includes an input terminal and an output terminal. The switch also includes a first stack having transistors coupled in series, and a second stack having transistors coupled in series. The first stack and the second stack are connected in parallel with one another.