A variable level power clamping circuit that may be used for the bypass path of an RF receiver having a low-noise amplifier (LNA). Impedance transform circuitry is used to transform the impedance of a signal path to a higher or lower impedance at a clamping circuit, causing the voltage at the clamping circuit to be, respectively, higher (thus clamping at a lower power level) or lower (thus clamping at a higher power level), and then transform the impedance after the clamping circuit to another value, such as to the impedance of the signal path. In a variant embodiment, the clamping circuit and an impedance matching element coupled to an LNA amplification path are re-purposed by selectively connecting those circuit elements to the LNA bypass path through a suitable impedance transform element when in a bypass mode.

A switchable amplifier and comparator circuit includes an operational amplifier having an inverting input, a non-inverting input, a first differential output and a second differential output, the first differential output switchably coupled to the inverting input and the second differential output switchably coupled to the non-inverting input. A first feedback capacitor is coupled to the inverting input and switchably coupled to the first differential output, a second feedback capacitor is coupled to the non-inverting input and switchably coupled to the second differential output. A capacitive load is switchably coupled between the first differential output and the second differential output. A diode clamp circuit is switchably coupled between the first differential output and the second differential output. A resistive load is switchably coupled between the first differential output and the second differential output.

An amplifier circuit includes a potential relation between a common emitter amplifier circuit (amplifier circuit body) including an NPN transistor (bipolar transistor) and a clamp circuit which maintains a potential relation between a base-collector of the NPN transistor of the common emitter amplifier circuit. The clamp circuit includes a level shift circuit and a clamp diode for suppressing a decrease in the collector potential of the NPN transistor of the common emitter amplifier circuit.

A system includes: 1) a buffer circuit; 2) circuitry coupled to an input of the buffer circuit; 3) a load coupled to an output of the buffer circuit; and 4) a clamp circuit coupled between an input of the buffer circuit and the output of the buffer circuit. The clamp circuit includes: 1) a bipolar junction transistor (BJT); 2) a first resistor with a first end coupled to a base terminal of the BJT and with a second end coupled to a collector terminal of the BJT; and 3) a second resistor with a first end coupled to the collector terminal of the BJT and with a second end coupled to the input of the buffer circuit. The second resistor is between an output of the circuitry and the input of the buffer circuit.

Concurrent electrostatic discharge and surge protection clamps in power amplifiers. In some embodiments, a semiconductor die can include a semiconductor substrate and an integrated circuit implemented on the semiconductor substrate. The integrated circuit can include a power amplifier and a controller. The semiconductor die can further include a clamp circuit implemented on the semiconductor substrate and configured to provide electrostatic discharge protection and surge protection for at least some of the integrated circuit.

A clamp circuit can control a clamp transistor such that a change in a photodiode current detection voltage signal in an optical receiver circuit can control the clamp transistor to change state when a difference of a clamp voltage and the photodiode current detection voltage signal exceeds a threshold voltage of the clamp transistor. Using a feedback loop, the clamp circuit can accurately clamp a current when the photodiode current is larger than a detect current threshold.

A variable level power clamping circuit that may be used for the bypass path of an RF receiver having a low-noise amplifier (LNA). Impedance transform circuitry is used to transform the impedance of a signal path to a higher or lower impedance at a clamping circuit, causing the voltage at the clamping circuit to be, respectively, higher (thus clamping at a lower power level) or lower (thus clamping at a higher power level), and then transform the impedance after the clamping circuit to another value, such as to the impedance of the signal path. In a variant embodiment, the clamping circuit and an impedance matching element coupled to an LNA amplification path are re-purposed by selectively connecting those circuit elements to the LNA bypass path through a suitable impedance transform element when in a bypass mode.

Systems and methods are provided for improved stability of driver amplifiers. In one example, a system includes an NMOSFET power device operable to generate a current signal at a drain terminal. The system further includes a current comparison amplifier operable to amplify a difference signal comprising a difference between a replica current signal of the NMOSFET power device and a reference current signal to drive a current comparison amplifier voltage output signal. The system further includes a PMOSFET clamp device comprising a source terminal coupled to a gate terminal of the NMOSFET power device operable to limit a voltage at the gate terminal of the NMOSFET power device responsive to the current comparison amplifier voltage output signal.

Devices, systems and methods for clamping output voltages of op-amps while minimizing post-clamping recovery delays are described. A circuit, which controls transitions between two operating modes, may include a first comparator for comparing an output voltage with a clamping voltage and outputting a first mode signal, a second comparator for comparing an input voltage with a reference voltage and outputting a second mode signal. A first logic component may receive the mode signals, perform a logical operation, and output a logic signal. A duplex output, based on a value of the logic signal, may output a track signal and an inversely corresponding hold signal, such track and hold signals being used by an op-amp circuit to configure adjusting blocks used to control transients during mode transitions.

An amplification device includes an amplification circuit and a protection circuit. The amplification circuit includes a transistor having a first terminal for outputting an amplified radio frequency signal, a second terminal, and a control terminal coupled to the input terminal of the amplification circuit for receiving a radio frequency signal to be amplified. The protection circuit has a first terminal coupled to the output terminal or the input terminal of the amplification circuit, and a second terminal. The protection circuit includes a switch and a first voltage clamping unit. The switch unit is turned on or turned off according to a control signal. The first voltage clamping unit is coupled to the switch unit for clamping a voltage at the first terminal of the protection circuit within a predetermined region when the switch unit is turned on.