A reference voltage circuit includes: a first and a second NPN transistor having a collector and a base shorted and diode-connected, the second NPN transistor having an emitter connected to a first potential node and operating at a higher current density; a first resistor connected in series with the first NPN transistor; a second resistor having one end connected to a circuit with the first NPN transistor and the first resistor connected in series; a third resistor having one end connected to the collector of the second NPN transistor; a connection point to which the other ends of the second and the third resistor are connected; an arithmetic amplifier circuit having an inverting input terminal, a non-inverting input terminal, and an output terminal respectively connected to the second resistor, the third resistor, and the connection point; and a current supply circuit connected to the collector of the first NPN transistor.

An enhanced current mirror can be utilized to accurately control a bias current associated with an amplifier. A current controller component (CCC) can employ the enhanced current mirror and can be associated with the amplifier. The CCC can comprise a comparator that can compare an adjusted supply voltage level to a reference voltage level, the adjusted supply voltage level relating to a supply voltage level of a supply voltage supplied to the amplifier and CCC. The CCC can control switching of an operational state of a transistor of the comparator to switch in or out a resistance of a reference resistor component associated with the supply voltage, based on a result of the comparison of the adjusted supply voltage level to the reference voltage level, to facilitate accurately controlling an amount of bias current associated with the amplifier. The CCC and amplifier can be situated on the same die.

An electronic device includes a semiconductor substrate and a bidirectional transistor switch formed on the substrate, the bidirectional switch including a first source node, a second source node and a common drain node. A first transistor is formed on the substrate and includes a first source terminal, a first drain terminal and a first gate terminal, wherein the first source terminal is connected to the substrate, the first drain terminal is connected to the first source node and the first gate terminal is connected to the second source node. A second transistor is formed on the substrate and includes a second source terminal, a second drain terminal and a second gate terminal, wherein the second source terminal is connected to the substrate, the second drain terminal is connected to the second source node and the second gate terminal is connected to the first source node.

A switching converter includes a voltage conversion circuit providing an output voltage from an input voltage and a PWM voltage generated in response to first and second oscillating voltages. The input stage of a transconductor circuit provides an input reference current following a difference between a reference voltage and a voltage dependent on the output voltage and according to a transconductance, and an output stage for providing an output reference current from the input reference current. A phase shifter shifts an oscillating reference voltage according to the output reference current to obtain the first and second oscillating voltages. The transconductance is controlled in response to the input voltage resulting in a change of the input reference current. Compensation for that change is provided by subtracting a variable compensation current from the input reference current, where the variable compensation current is generated in response to the input voltage.

A semiconductor device that outputs a reset signal for controlling a reset operation of a reset target circuit connected to a first power supply and a second power supply having a voltage lower than a voltage of the first power supply, the semiconductor device including: a power supply voltage monitoring circuit connected to the first power supply and the second power supply, the power supply voltage monitoring circuit monitors the voltage of the first power supply, wherein the power supply voltage monitoring circuit includes a first transistor having a first conductive type and a second transistor having a second conductive type different from the first conductive type, and wherein the reset signal is switched when the voltage of the first power supply is equal to or greater than a sum of a threshold voltage of the first transistor, and a threshold voltage of the second transistor.

A reference voltage circuit includes a first circuit including a first PN junction device and a first resistor connected in series between a power supply node and a first node, and a second resistor connected between the first node and an intermediate node, and a third resistor connected between the intermediate node and a reference voltage output node, and a second circuit including a second PN junction device connected between the power supply node and a second node and a fourth resistor connected between the second node and the intermediate node. A feedback current causes voltage across the first resistor to offset changes in voltage across the first PN junction device. A correction current is applied to boost and or sink current in the voltage reference generator to extend the operating temperature range.

A reference current source includes a reference current path, a first output current path and a second output current path. The reference current path includes a diode-connected first transistor, a diode-connected second transistor, and a first resistor that are connected in series between a first fixed potential and a second fixed potential. The first output current path includes a third transistor having a gate connected to a gate of the second transistor, forming a current mirror together with the second transistor, and a second resistor interposed between the third transistor and the first fixed potential. The second output current path includes a voltage-current conversion circuit to which a potential of a third node between the third transistor and the second resistor in the first output current path is applied and through which a reference current flows.

Provided are an LDO, an MCU, a fingerprint module and a terminal device. The LDO includes: a reference voltage generating circuit and a source follower connected to the reference voltage generating circuit. The reference voltage generating circuit is used to generate a reference voltage that changes with temperature to offset a voltage change caused by a voltage between a first terminal and a second terminal of the source follower changing with time, so that an output voltage of the second terminal of the source follower does not change with temperature. The LDO omits an operational amplifier EA and a resistor divider feedback network in the prior art, which not only has a simple circuit structure, but also can achieve ultra-low power consumption.

A circuit arrangement is provided where the arrangement of a feedback resistor between a first branch and a second branch enables that a voltage is provided at an output terminal in an efficient way, this means with a high settling speed and a low current consumption. The feedback resistor is arranged between a reference node and the output terminal, where the reference node is connected to a current mirror. The circuit arrangement can be employed as a gate driver. Furthermore, a driver block and a method of driving a circuit arrangement are provided.

A ring-oscillator control circuit (100) including voltage reference (110), a ring oscillator (120), a power supply (130, 140) and a supply controller (150). The supply controller (150) is configured to select the power supply (130, 140) among an energy storage (130) and an energy source (140) such as to supply the ring oscillator (120) in function of the voltage reference (110).