Abstract: Conventionally, current detection in load switches is implemented by monitoring the voltage across a small value sense resistor in series with the load switch, where the differential voltage across is applied to a comparator to generate a control signal corresponding to a light load condition, a normal load condition, or an over-load condition. Detecting the light load condition, however, can be difficult to determine using this arrangement due to the low differential voltage. Here, however, a integrated circuit (IC) is provided that employs an internal voltage supply and comparators to examine the load current to determine whether a light load condition is present, which does not suffer from the same problems.

Abstract: A methodology for controlling FET switch-on with VGS temperature compensation is based on establishing a VGS clamping voltage with PTAT and CTAT voltage references with complimentary temperature coefficients. In one embodiment, the methodology can include: (a) generating a PTAT current from a PTAT ?VBE current source including a ?VBE resistor; (b) supplying the PTAT current to the gate node to control FET switch-on; and (c) establishing a temperature compensated VGS clamping voltage at the gate node. The VGS clamping voltage can be established with gate control circuitry that includes the PTAT and CTAT voltage references. A PTAT voltage VPTAT is dropped across a PTAT resistor RPTAT characterized by a temperature coefficient substantially the same as the ?VBE resistor. The CTAT voltage VCTAT is dropped across one or more CTAT VBE component(s) each characterized by a VBE,CTAT voltage drop with a CTAT temperature coefficient.

Abstract: An IC generally comprises enable pin, ground pin, input pin, output pin, load switch, control circuitry, and level shifter. Load switch is coupled between the input pin and output pin and receives a negative voltage through the input pin. The control circuitry is coupled to the enable pin, the ground pin, and the load switch and controls the load switch and uses ground pin as positive supply rail and input pin as an internal ground. Voltage applied to the input terminal is negative, enabling pulling of the gate of a transistor of a level shifter to ground turns transistor as “on,” enabling a negative output signal to be provided through output pin VOUT. Therefore, the output signal (at output pin VOUT) can be ground (applied to the ground pin GND) when the transistor is “off” and can be the negative voltage (applied to the input pin VIN) when transistor is “on.

Abstract: An IC generally comprises enable pin, ground pin, input pin, output pin, load switch, control circuitry, and level shifter. Load switch is coupled between input pin and output pin and receives a negative voltage through the input pin. The control circuitry is coupled to the enable pin, the ground pin, and the load switch and controls the load switch and uses ground pin as positive supply rail and input pin as an internal ground. Voltage applied to the input terminal is negative, enabling pulling of the gate of a transistor of a level shifter to ground turns transistor as “on,” enabling a negative output signal to be provided through output pin VOUT. Therefore, the output signal (at output pin VOUT) can be ground (applied to the ground pin GND) when the transistor is “off” and can be the negative voltage (applied to the input pin VIN) when transistor is “on.

Abstract: Conventionally, current detection in load switches is implemented by monitoring the voltage across a small value sense resistor in series with the load switch, where the differential voltage across is applied to a comparator to generate a control signal corresponding to a light load condition, a normal load condition, or an over-load condition. Detecting the light load condition, however, can be difficult to determine using this arrangement due to the low differential voltage. Here, however, a integrated circuit (IC) is provided that employs an internal voltage supply and comparators to examine the load current to determine whether a light load condition is present, which does not suffer from the same problems.

Abstract: Load switches are relatively common and in use with a variety of applications, and conventional load switches have been designed to have continually operating protection circuitry, which can consume a great deal of power. Here, a load switch integrated circuit (IC) is provided where a controller within the IC activates and deactivates various protection circuits in a sequence, allowing the protection circuit to protect the IC while also reducing power consumption.

Abstract: Load switches are relatively common and in use with a variety of applications, and conventional load switches have been designed to have continually operating protection circuitry, which can consume a great deal of power. Here, a load switch integrated circuit (IC) is provided where a controller within the IC activates and deactivates various protection circuits in a sequence, allowing the protection circuit to protect the IC while also reducing power consumption.

Abstract: A bias generator circuit with improved phase margin without RC compensation includes: a first transistor MP4; a second transistor MP3 coupled in parallel with the first transistor MP4; an amplifier A1 having a first input coupled to the first and second transistors MP4 and MP3, and to a gate of the second transistor MP3, and a second input coupled to a control voltage node VCTRL; a third transistor MN4 coupled in series with the first transistor MP4; a fourth transistor MN2 coupled in series with the third transistor MN4 and having a gate coupled to an output of the amplifier A1; a fifth transistor MP1; a sixth transistor MP2 coupled in parallel with the fifth transistor MP1; a seventh transistor MN3 coupled in series with the fifth transistor MP1; and an eighth transistor MN1 coupled in series with the seventh transistor MN3 and having a gate coupled to a gate of the fourth transistor MN2.

Abstract: A bias generator circuit with improved phase margin without RC compensation includes: a first transistor MP4; a second transistor MP3 coupled in parallel with the first transistor MP4; an amplifier A1 having a first input coupled to the first and second transistors MP4 and MP3, and to a gate of the second transistor MP3, and a second input coupled to a control voltage node VCTRL; a third transistor MN4 coupled in series with the first transistor MP4; a fourth transistor MN2 coupled in series with the third transistor MN4 and having a gate coupled to an output of the amplifier A1; a fifth transistor MP1; a sixth transistor MP2 coupled in parallel with the fifth transistor MP1; a seventh transistor MN3 coupled in series with the fifth transistor MP1; and an eighth transistor MN1 coupled in series with the seventh transistor MN3 and having a gate coupled to a gate of the fourth transistor MN2.