Methods and devices for speeding up the onset of a target current through an output leg of a current mirror are presented. Upon activation of the current mirror, a pre-charge current is sourced to a node of the current mirror that is common to the output leg and an input leg of the current mirror. Sourcing of the pre-charge current is based on sensing, by a first transistor, of a voltage at the common node. Pre-charging of the common node continues up to a cutoff voltage sensed at the common node. Sourcing of the pre-charge current is provided by a second transistor coupled to the common node. Based on the voltage sensed at the common node, the first transistor controls the sourcing of the pre-charge current by the second transistor. Such control is based on a portion of a current from a current source that flows through the first transistor.

The present disclosure provides an electronic circuit having one reference current terminal arranged to connect to a reference current generator, an MOS current mirror stage, an MOS push-pull amplifier stage operatively coupled to the current mirror stage and the current mode amplifier stage.

Various aspects relate to a startup circuit for a bandgap reference circuit, wherein a target voltage value is associated with the bandgap reference circuit, the target voltage value being indicative of a startup condition of the bandgap reference circuit that triggers a stable on-state of the bandgap reference circuit, wherein the startup circuit is configured to: provide a startup voltage at the bandgap reference circuit to trigger a start of an operation of the bandgap reference circuit; receive a feedback voltage, wherein the feedback voltage is representative of a startup condition of the bandgap reference circuit; and either increase the startup voltage at the bandgap reference circuit in the case that a voltage value of the feedback voltage is less than the target voltage value, or stop providing the startup voltage at the bandgap reference circuit in the case that the voltage value of the feedback voltage is equal to or greater than the target voltage value.

A memory device includes a voltage generator configured to generate a reference voltage for transmission to at least one component of the memory device. The voltage generator includes a first input to receive a first signal having a first voltage value. The voltage generator also includes a second input to receive a second signal having a second voltage value. The voltage generator further includes a first circuit configured to generate third voltage and a second circuit coupled to the first circuit to receive the third voltage value, wherein the second circuit receives the first signal and the second signal and is configured to utilize the third voltage value to facilitate comparison of the first voltage value and the second voltage value to generate an output voltage.

A reference current/voltage generator includes a current mirror unit and a current-mode temperature compensation unit. The current mirror unit generates a first current, a first sum current and a second sum current flowing through first to third terminals thereof, and the first current, the first sum current and the second sum current are in a multiple relationship. The current-mode temperature compensation unit is electrically connected to the second and third terminals of the current mirror unit, and when a voltage on the second terminal is equal to a voltage on the third terminal, the first sum current is a sum of a current proportional to absolute temperature (PTAT) and a current complementary to absolute temperature (CTAT). The first terminal of the current mirror unit is an output terminal of the reference current/voltage generator and configured to output the first current as a reference current.

A circuit is disclosed. The circuit includes a current detecting FET, configured to generate a current signal indicative of the value of the current flowing therethrough, an operational transconductance amplifier (OTA) configured to output a current in response to the voltage of the current signal, and a resistor configured to receive the current and to generate a voltage in response to the received current, where the generated voltage is indicative of the value of the current flowing through the current detecting FET. The current detecting FET is configured to become nonconductive in response to the generated voltage indicating that the current flowing through the current detecting FET is greater than a threshold.

A solid state relay and a method for controlling a signal path between an AC-signal output and a load in a power amplifier assembly are disclosed. The relay comprises a first and a second MOSFET having a common gate junction, a common source junction and wherein and wherein a drain terminal of a first MOSFET and a drain terminal of a second MOSFET form relay terminals. The solid state relay further comprises a control circuit comprising a positive side comprising a first controlled current generator configured to provide a first control current to the gate junction, and a negative side comprising a current mirror circuit configured to sink a second current from the source junction. Hereby, a generic solid state speaker relay has been disclosed. The relay performs up to the most stringent demands regarding pop/click on high quality products. It can be used to ground wire break, hot wire break and BTL (Bridge Tied Load) break. The design is rather tolerable to different MOSFETs and very competitive in quality and price.

An electronic device includes a current comparator to generate an output current based upon a difference between a current flowing in an output branch and a current flowing in an input branch. A pair of transistors is coupled to an output of the current comparator. A first amplifier has inputs coupled to the pair of transistors and to a reference voltage, the first amplifier being configured to subtract the reference voltage from a voltage across the pair of transistors and output a difference voltage. A second amplifier has inputs coupled to the difference voltage and to the reference voltage, the second amplifier being configured to subtract the difference voltage from the reference voltage and output a pulse skipping mode reference signal.

A bias current generator circuit includes a current path and a leakage control circuit. The current path is connected between a supply voltage and a ground level. The current path includes a transistor and a resistor. The transistor has a current channel connected in the current path. The resistor has an upper terminal and a lower terminal connected in the current path, and a well contact to allow a reverse leakage current of the resistor to flow through. The leakage control circuit is connected to the supply voltage. The leakage control circuit includes a driving transistor to provide a driving voltage to the well contact of the resistor, and to allow the reverse leakage current of the resistor to flow into the leakage control circuit.

The present disclosure relates to a constant current source calibration circuit, a constant current source drive circuit, a drive chip, and an electronic device. The current calibration circuit includes a resistor and a calibration circuit connected to the resistor for adjusting a voltage drop across two ends of the resistor; and a selector or a switch connected to the two ends of the resistor, and configured to select one end of the resistor to be connected to a constant current source output channel and the corresponding other end to be supplied with a first bias voltage VD. Since the first bias voltage VD is a fixed constant, the voltage drop across the two ends of the resistor is adjusted.