Disclosed embodiments include an electronic system with a power on reset (POR) circuit. The POR circuit includes first voltage detection circuitry to perform a first detection on a supply voltage and to output a first control signal in response to the first detection, second voltage detection circuitry to perform a second detection on the supply voltage and to output a second control signal in response to the second detection, and third voltage detection circuitry to perform a third detection on the supply voltage and to output at least one third control signal in response to the third detection. The POR circuit further has sequencing circuitry with a first input to receive the at least one third control signal and to output a reset signal in response to the at least one third control signal.

A power down detection circuit and a semiconductor storage apparatus, which can adjust a power down detection level while suppressing temperature dependence, are provided. The power down detection circuit includes a BGR circuit, a trimming circuit, a resistance division circuit, and a comparator. The BGR circuit generates a reference voltage based on a supply voltage. The trimming circuit adjusts the reference voltage based on a trimming signal to generate a reference voltage for power down detection. The resistance division circuit generates an internal voltage lower than the supply voltage. The comparator detects that the internal voltage is lower than the reference voltage for power down detection and outputs a reset signal.

A power on reset circuit comprises terminals for reference and supply potentials and a voltage divider coupled therebetween. First and second transistors of a bandgap circuit are resistively coupled to the reference potential terminal and have bases connected to the voltage divider. Current mirrors couple the collectors of the first and second transistors to an output terminal providing an output signal indicating a power on reset condition. A first compensation transistor is coupled between the collector of one of the transistors and the reference potential terminal, and a second compensation transistor is coupled between the output terminal and the reference potential terminal to compensate the effect of parasitic substrate currents in response to an external interference.

A method, system, and related component for detecting properness of a PG pin power-on timing sequence are provided. The method comprises: obtaining a pull-up level of a PG pin of a VR chip (S101); determining a value of a pull-up resistor of the PG pin, as a first resistance, when a current injected into the VR chip by using the pull-up level is equal to a maximum withstand current of the VR chip (S102); obtaining an equivalent resistance to ground when the PG pin is at a low level, and calculating, based on the equivalent resistance to ground, a value of the pull-up resistor of the PG pin, as a second resistance, when an output voltage of the PG pin is equal to a preset interference voltage limit value (S103); and outputting first prompt information when it is determined that an actual resistance of the pull-up resistor is lower than the first resistance or the second resistance (S104). The foregoing solution is applied, to determine whether a power-on timing sequence of PG pins in a VR chip is proper, thereby avoiding an incorrect action of a subsequent circuit.

A method, system, and related component for detecting properness of a PG pin power-on timing sequence are provided. The method comprises: obtaining a pull-up level of a PG pin of a VR chip (S101); determining a value of a pull-up resistor of the PG pin, as a first resistance, when a current injected into the VR chip by using the pull-up level is equal to a maximum withstand current of the VR chip (S102); obtaining an equivalent resistance to ground when the PG pin is at a low level, and calculating, based on the equivalent resistance to ground, a value of the pull-up resistor of the PG pin, as a second resistance, when an output voltage of the PG pin is equal to a preset interference voltage limit value (S103); and outputting first prompt information when it is determined that an actual resistance of the pull-up resistor is lower than the first resistance or the second resistance (S104). The foregoing solution is applied, to determine whether a power-on timing sequence of PG pins in a VR chip is proper, thereby avoiding an incorrect action of a subsequent circuit.

Embodiments of power-on reset (POR) circuits are described. In one embodiment, a POR circuit includes a primary ladder circuit connected to a supply voltage and configured to generate a reference signal for a reset signal in response to the supply voltage and a secondary ladder circuit connected to the supply voltage and configured to bias the primary ladder circuit in response to the supply voltage.

To provide a hysteresis comparator having a small circuit area and low power consumption. The hysteresis comparator includes a comparator, a switch, a first capacitor, a second capacitor, and a logic circuit. A first terminal of the switch is electrically connected to one of a pair of conductive regions of the first capacitor, one of a pair of conductive regions of the second capacitor, and a first input terminal of the comparator. An output terminal of the comparator is electrically connected to an input terminal of the logic circuit. An output terminal of the logic circuit is electrically connected to the other of the pair of conductive regions of the second capacitor. The logic circuit has a function of generating an inverted signal of a signal input to the input terminal of the logic circuit and outputting the inverted signal to the output terminal of the logic circuit. A reference potential is input to the first input terminal of the comparator and the reference potential is held by the switch. Due to change in the potential of the output terminal of the comparator, the reference potential is changed by capacitive coupling of the second capacitor.

To provide a hysteresis comparator having a small circuit area and low power consumption. The hysteresis comparator includes a comparator, a switch, a first capacitor, a second capacitor, and a logic circuit. A first terminal of the switch is electrically connected to one of a pair of conductive regions of the first capacitor, one of a pair of conductive regions of the second capacitor, and a first input terminal of the comparator. An output terminal of the comparator is electrically connected to an input terminal of the logic circuit. An output terminal of the logic circuit is electrically connected to the other of the pair of conductive regions of the second capacitor. The logic circuit has a function of generating an inverted signal of a signal input to the input terminal of the logic circuit and outputting the inverted signal to the output terminal of the logic circuit. A reference potential is input to the first input terminal of the comparator and the reference potential is held by the switch. Due to change in the potential of the output terminal of the comparator, the reference potential is changed by capacitive coupling of the second capacitor.

A voltage monitoring circuit includes an initializing circuit that outputs an initialization signal generated by delaying a power supply voltage as much as a first delay time, a switching circuit that outputs a switching signal in response to a reset signal, a voltage detecting circuit that outputs a detection signal based on the power supply voltage and stops an operation in response to the switching signal, and an output circuit that outputs the reset signal based on the initialization signal and the detection signal.

To obtain a highly reliable electronic control device capable of reliably causing a microcomputer to perform normal termination and normal re-activation by controlling a power supply voltage. According to the present invention, an electronic control device 25 includes a microcomputer 18, a power supply control unit 20 that controls a power supply voltage of the microcomputer, and a capacitor 19 provided between the power supply control unit and the microcomputer. The power supply control unit 20 includes a power supply unit 24 that supplies a first power supply voltage V1 to the microcomputer by turning ON an activation signal for activating the microcomputer, and stops the supply of the power supply voltage by turning the activation signal OFF, a reset control unit 14 that generates a Low reset signal by turning the activation signal OFF, and a discharge control unit 12 that discharges electric charges of the capacitor when acquiring the Low reset signal.