Disclosed are a slew boost amplifier and a display driver having the same, which include a first current generation circuit configured to apply a first current to an upper current mirror circuit, a second current generation circuit configured to apply a second current to a lower current mirror circuit, and a comparison circuit configured to detect a difference between an input voltage and an output voltage and to apply the first current when the difference is greater than or equal to a first predetermined threshold and the second current generation circuit to apply the second current when the difference is less than a second predetermined threshold.

Disclosed are a slew boost amplifier and a display driver having the same, which include a first current generation circuit configured to apply a first current to an upper current mirror circuit, a second current generation circuit configured to apply a second current to a lower current mirror circuit, and a comparison circuit configured to detect a difference between an input voltage and an output voltage and to apply the first current when the difference is greater than or equal to a first predetermined threshold and the second current generation circuit to apply the second current when the difference is less than a second predetermined threshold.

A network element of a cable television (CATV) network, comprising one or more amplifier units for amplifying downstream signal transmission into one or more output channels; a temperature sensor configured to detect one or more of the following: ambient temperature of the network element, and/or one or more of components of the network element; a memory configured to store a predetermined correlation between the detected ambient temperature and a corresponding correction of a bias current for said one or more amplifier units; and a processing unit configured to control the bias current of said one or more amplifier units to be adjusted based on the predetermined correlation.

In an embodiment a device includes an input node configured to receive a first current, an output node configured to provide a second current determined by the first current, a first resistor having a first terminal connected to the input node and a second terminal coupled to a first node configured to receive a first supply voltage, a first MOS transistor having a source connected to the first node and a drain coupled to the output node of the device, a second resistor having a first terminal connected to a gate of the first MOS transistor, a biasing circuit configured to provide a biasing voltage on a second terminal of the second resistor and a first capacitor connected between the input node and the gate of the first MOS transistor.

An interface circuit includes a first amplifier circuit comprising a first input terminal configured to receive a first input signal, a second input terminal configured to receive a second input signal, a first output node configured to output a first output signal, a second output node configured to output a second output signal, and a variable impedance circuit comprising a first impedance circuit connected to the first output node, and a second impedance circuit connected to the second output node. A code generator circuit is configured to generate a first control code and a second control code. The first impedance circuit is configured to adjust an impedance thereof based on the first control code, and the second impedance circuit is configured to adjust an impedance thereof based on the second control code.

A system to regulate an output voltage based on a reference voltage is described. The system has an error amplifier to determine an error voltage by cumulating a deviation of a feedback voltage from the reference voltage, wherein the feedback voltage is indicative of the output voltage. The system has a PWM unit to generate a PWM control signal based on the error voltage. In addition, the system has a voltage setting unit to set the output voltage based on the PWM control signal. The system has a saturation detection unit to detect a saturation situation of the system. In addition, the system has a clamping means to interrupt a further build-up of the error voltage in the saturated direction while allowing a modification of the error voltage in an opposite direction, opposite to the saturated direction, if a saturation situation is detected.

A system to regulate an output voltage based on a reference voltage is described. The system has an error amplifier to determine an error voltage by cumulating a deviation of a feedback voltage from the reference voltage, wherein the feedback voltage is indicative of the output voltage. The system has a PWM unit to generate a PWM control signal based on the error voltage. In addition, the system has a voltage setting unit to set the output voltage based on the PWM control signal. The system has a saturation detection unit to detect a saturation situation of the system. . In addition, the system has a clamping means to interrupt a further build-up of the error voltage in the saturated direction while allowing a modification of the error voltage in an opposite direction, opposite to the saturated direction, if a saturation situation is detected.

An example apparatus includes: first buffer circuitry having an input and an output; second buffer circuitry having an input and an output; a resistor having a first terminal and a second terminal, the first terminal of the resistor coupled to the output of the first buffer circuitry, the second terminal of the resistor coupled to the output of the second buffer circuitry; third buffer circuitry having an input and an output, the input of the third buffer circuitry coupled to the input of the first buffer circuitry; and switch circuitry having a first terminal and a second terminal, the first terminal of the switch circuitry coupled to the input of the second buffer circuitry, the second terminal of the switch circuitry coupled to the output of the third buffer circuitry.

A source/sink LDO is provided with a pre-amplifier that pre-amplifies an error voltage equaling a difference between an output voltage and a reference voltage. The resulting pre-amplification reduces the dead band for the source/sink LDO by the gain of the pre-amplifier.