There is provided a differential signal transmission circuit that includes a first output terminal, a second output terminal connected to the first output terminal via a load resistor, a high-side transistor formed of a p-channel MOSFET and connected between an application terminal of a power supply voltage and the first output terminal, a low-side transistor formed of an n-channel MOSFET and connected between an application terminal of a ground potential and the second output terminal, a high-side pre-driver configured to drive the high-side transistor, a low-side pre-driver configured to drive the low-side transistor, a first resistance part connected between an output end of the high-side pre-driver and a gate of the high-side transistor, and a second resistance part connected between an output end of the low-side pre-driver and a gate of the low-side transistor.

This document discusses, among other things, apparatus and methods for an edge rate driver for a power converter switch. In an example, the driver can include an input node configured to receive a pulse width modulated signal, a first switch configured to couple a control node of the power converter switch to a supply voltage during a first state, a second switch configured to couple the control node of the power converter switch to a reference voltage during a second state, and a first current source configured to supply charge current to the first switch when the power converter switch transitions from the second state to the first state, the charge current configured to charge a parasitic capacitance of the power converter switch.

This document discusses, among other things, apparatus and methods for an edge rate driver for a power converter switch. In an example, the driver can include an input node configured to receive a pulse width modulated signal, a first switch configured to couple a control node of the power converter switch to a supply voltage during a first state, a second switch configured to couple the control node of the power converter switch to a reference voltage during a second state, and a first current source configured to supply charge current to the first switch when the power converter switch transitions from the second state to the first state, the charge current configured to charge a parasitic capacitance of the power converter switch.

A bootstrap circuit integrated to a voltage converter integrated circuit (IC) and a voltage converter IC for a switch mode voltage regulator. The bootstrap circuit is used to provide a bootstrap voltage signal for driving a high side switch of the voltage converter IC. The bootstrap circuit has a pre-charger and a bootstrap capacitor. The pre-charger provides a first bootstrap signal to pre-charge a control terminal of the high side switch, and the bootstrap capacitor provides a second bootstrap signal to enhance the charge of the control terminal of the high side switch.

Disclosed herein is a driver circuit including a first group of transistors provided between first and second nodes and including n of the transistor(s) where n is equal to or greater than one, and a second group of transistors provided in parallel with the first group of transistors and including m of the transistor(s) where m is equal to or greater than one and not equal to n, the m transistors being connected together in series. The n-channel transistor in the first group and at least one of the two n-channel transistors in the second group have their gate connected to an input node.

A high-side switching transistor of a rectifier circuit is driven by a high-side driver circuit to supply current to an output node. The high-side driver circuit is powered between a capacitive bootstrap node and the output node. A boot charge circuit charges the bootstrap capacitor by supplying current to the bootstrap node. The boot charge circuit includes: a first current path that selectively supplies a first charging current to the bootstrap node when the rectifier circuit is operating in a switching mode; and a second current path that selectively supplies a second charging current to the bootstrap node when the rectifier circuit is operating in a reset mode.

A pre-driver for driving an LVDS (Low Voltage Differential Signaling) driving circuit is provided. The pre-driver includes a first inverter, a high-pass filter, and a second inverter. The first inverter has an input terminal coupled to an input node of the pre-driver, and an output terminal coupled to a first node. The high-pass filter is coupled between the first node and a second node. The second inverter has an input terminal coupled to the second node, and an output terminal coupled to an output node of the pre-driver. The high-pass filter is configured to improve a high-frequency response of the pre-driver.

A pre-driver for driving an LVDS (Low Voltage Differential Signaling) driving circuit is provided. The pre-driver includes a first inverter, a high-pass filter, and a second inverter. The first inverter has an input terminal coupled to an input node of the pre-driver, and an output terminal coupled to a first node. The high-pass filter is coupled between the first node and a second node. The second inverter has an input terminal coupled to the second node, and an output terminal coupled to an output node of the pre-driver. The high-pass filter is configured to improve a high-frequency response of the pre-driver.

An embodiment of the present invention relates to a low-power broadband asynchronous BPSK demodulation method and a configuration of a circuit thereof. In connection with a configuration of a BPSK demodulation circuit, there may be provided a low-power wideband asynchronous binary phase shift keying demodulation circuit comprising: a sideband separation and lower sideband signal delay unit; a data demodulation unit; and a data clock restoration unit.

A three-dimension (3D) memory device and an operation method thereof are provided. The 3D memory device includes: a memory array including a plurality of memory cells; a controller coupled to the memory array; and a match circuit coupled to memory array, wherein in data search and match, the controller selects from the memory cells a plurality of target memory cells sharing a same target global signal line, and the controller selects a plurality of target word lines sharing the target global signal line as a plurality of target search lines, wherein a search data sends to the target memory cells via the target search lines for data matching; the target global signal line is precharged; and outputting a match address based on whether a voltage on the target global signal line is pulled down or not.