A semiconductor integrate circuit device includes: an output transistor connected between a voltage input terminal to which a DC voltage is input and a voltage output terminal; a control circuit that controls on/off of the output transistor; a proportional current generation circuit capable of generating a current proportionally smaller than a current flowing through the output transistor; an overcurrent detection circuit capable of detecting an overcurrent state of an output current by determining whether a current flowing through the output transistor is equal to or greater than a first predetermined current value, based on the current generated by the proportional current generation circuit; and a retry circuit that generates and outputs a signal for intermittently turning off the output transistor in response to the overcurrent detection circuit detecting the overcurrent state.

An apparatus includes a plurality of pixels arranged in an array, a first group of pixels that are arranged in a first direction among the plurality of pixels, a first line to which the first group is connected, a second group of pixels that are arranged in the first direction among the plurality of pixels, and a second line to which the second group is connected. The first line is connected to a first source. The second line is connected to a second source. The apparatus further includes a control unit configured to: (1) perform control to increase a current flowing through the second source while performing control to decrease a current flowing through the first source, or (2) suppress a variation of total amount of flowing current by changing the current flowing through the second source in response to a change in the current flowing through the first source.

Techniques and mechanisms for supplementing power delivery with a battery. In an embodiment, a voltage is provided at a first node with the battery to power a load circuit. A charger is coupled between the first node and a second node, wherein a capacitor is coupled to provide charge to the charger via the second node. In response to detecting a transition of the voltage below a threshold voltage level, controller logic operates switch circuitry of the charger to provide charge from the capacitor. Such operation maintains the voltage in a range of voltage levels which are each above a minimum voltage level required by the load. At least a portion of the range is below the threshold voltage level. In some embodiments, another voltage at the second node provides a basis for generating a control signal to throttle an operation of the load circuit.

Techniques and mechanisms for supplementing power delivery with a battery. In an embodiment, a voltage is provided at a first node with the battery to power a load circuit. A charger is coupled between the first node and a second node, wherein a capacitor is coupled to provide charge to the charger via the second node. In response to detecting a transition of the voltage below a threshold voltage level, controller logic operates switch circuitry of the charger to provide charge from the capacitor. Such operation maintains the voltage in a range of voltage levels which are each above a minimum voltage level required by the load. At least a portion of the range is below the threshold voltage level. In some embodiments, another voltage at the second node provides a basis for generating a control signal to throttle an operation of the load circuit.

A power distribution system and method has a controller and at least one semiconductor switch. The power distribution system additionally has an on status detector which detects the status of the semiconductor switches, and an overcurrent status circuit which checks for overcurrent conditions.

A power distribution system and method has a controller and at least one semiconductor switch. The power distribution system additionally has an on status detector which detects the status of the semiconductor switches, and an overcurrent status circuit which checks for overcurrent conditions.

An overcurrent protection circuit includes a current control part configured to control conductance of a transistor so as to limit an output current flowing when the transistor is turned on to a predetermined upper limit or less, and a duty control part configured to forcibly turning on/off the transistor at a predetermined duty ratio when a temperature protection circuit detects a temperature abnormality in a state where the current control part limits the output current.

An overcurrent protection circuit includes a current control part configured to control conductance of a transistor so as to limit an output current flowing when the transistor is turned on to a predetermined upper limit or less, and a duty control part configured to forcibly turning on/off the transistor at a predetermined duty ratio when a temperature protection circuit detects a temperature abnormality in a state where the current control part limits the output current.

A circuit for controlling electrical power is described herein. In accordance with one embodiment, the circuit comprises: a circuit node operably connected to a pass element configured to be switched on and off in accordance with a drive signal applied at the circuit node; a communication interface configured to receive data from an external controller operably connected to the communication interface; and a control circuit configured to generate, in a first mode of operation, the drive signal dependent on parameters of a first parameter set and based on data received via the communication interface, and to generate, in a second mode of operation, the drive signal dependent on parameters of a second parameter set while discarding data received via the communication interface.

A circuit for controlling electrical power is described herein. In accordance with one embodiment, the circuit comprises: a circuit node operably connected to a pass element configured to be switched on and off in accordance with a drive signal applied at the circuit node; a communication interface configured to receive data from an external controller operably connected to the communication interface; and a control circuit configured to generate, in a first mode of operation, the drive signal dependent on parameters of a first parameter set and based on data received via the communication interface, and to generate, in a second mode of operation, the drive signal dependent on parameters of a second parameter set while discarding data received via the communication interface.