Circuits, semiconductor devices, and systems are provided. An illustrative circuit includes a first pair of transistors cross-coupled with a second pair of transistors. The circuit may further include a gain control circuit coupled with the first pair of transistors and the second pair of transistors, where the gain control circuit provides an error compensation for a beta variation effect in at least one of the first pair of transistors and the second pair of transistors.

A continuous time linear equalizer (CTLE), comprising: a first transconductance gain circuit configured to amplify an input voltage signal with a first transconductance gain to generate a first current signal; a second transconductance gain circuit configured to amplify the input voltage signal with a second transconductance gain to generate a second current signal, wherein the second transconductance gain circuit is configured to reuse the first current signal to generate the second current signal; and at least one resistor through which the first current signal and the second current signal flow to generate an output voltage signal.

The present invention provides a transducer protection system and method. A transducer module at least comprises a transducer, and a signal source is used for generating a first signal; a protection module is used for predicting an actual displacement and/or temperature of the transducer according to the first signal, an amplification factor of the power amplifier and built-in transducer parameters to generate a prediction result, comparing the prediction result with a preset value to generate an analysis result, and regulating the first signal to form a second signal according to the analysis result; a power amplifier is used for receiving the second signal, and performing power amplification on the second signal to form a driving signal; and the transducer module is used for receiving the driving signal, and at least one transducer in the transducer module can work according to the driving signal.

A distributed amplifier system comprising an impedance matching network configured to match an input impedance to an output impedance of the signal source, and a DC block configured to block DC components in the input signal. A variable gain amplifier adjusts the gain applied to the input signal based on a gain control signal to generate a gain adjusted signal. An emitter follower circuit receives and processes the gain adjusted signal to introduce gain peaking to create a modified signal. A distributed amplifier receives and amplifies the modified signal from the emitter follower circuit, to create an amplified signal. The distributed amplifier includes a termination network and one or more impedance matching elements configured for gain shaping the amplified signal. The gain peaking introduced by the emitter follower circuit is controlled by a variable current source. The distributed amplifier may be an open collector distributed amplifier.

Methods related to amplification of radio-frequency signals. In some embodiments, a method for amplifying a radio-frequency signal can include configuring a gain stage to be in a selected one of a plurality of gain settings, with at least some of the gain settings resulting in different phases for the radio-frequency signal. The method can further include adjusting the phase of the radio-frequency signal for the selected gain setting, such that the adjusted phase is part of desired phases adjusted from the different phases.

The disclosure relates to a current converter circuit. Example embodiments include a current converter circuit (600) for converting a linear input current (Ictrl_lin) to an exponential output current (Ictrl_sum), the current converter circuit (600) comprising first and second current converters (601, 602), each of which comprises: an input current branch (603.sub.1, 603.sub.2) with an input current source (604.sub.1, 604.sub.2) connected in series with a tuning voltage circuit (605.sub.1, 605.sub.2) and a tuning resistor (606.sub.1, 606.sub.2) between a supply voltage line (607) and a common voltage line (608); and an output current branch (609.sub.1, 609.sub.2) with an output transistor (610.sub.1, 610.sub.2) having a collector connected to an output node (611.sub.1, 611.sub.2), a emitter connected to the common voltage line (608) and a base connected to the tuning voltage circuit (605.sub.1, 605.sub.2), wherein the output nodes (611.sub.1, 611.sub.2) of the first and second current converters (601, 602) are connected to a summing output node (612) of the current converter circuit (600)

The present invention relates to a conversion device, or commonly called transimpedance amplifier, able to convert an input electric current (Id) from a current source such as a photonic sensor (D) into an output voltage (Vo) and comprising an integrated electronic circuit comprising, inter alia, a resistive component (Rf) of adjustable value and a capacitive component (Cf) of adjustable value. The invention also relates to a method for determining the values of the resistive component and of the capacitive component.

An amplifier includes a gain stage having a gain stage input and a gain stage output and an impedance matching circuit connected to the gain stage output, the impedance matching circuit including an input and an output. The amplifier also includes a coupling circuit connected to the input of the impedance matching circuit and a shorting circuit connected to the output of the impedance matching circuit. The coupling circuit provides a voltage to the shorting circuit that causes the shorting circuit create a short to ground through a reflecting capacitor which causes a reflection to be provided to the output of the impedance matching circuit and that is transmitted to the coupling circuit to increase the voltage provided to the shorting circuit by the coupling circuit.

An automatic gain control (AGC) attenuator for an amplifier. In one example, the AGC attenuator includes a first transistor stack including a plurality of first banks of current steering differential transistor pairs and configured to receive a radio frequency (RF) input signal and output a first attenuated RF signal. Each first bank of the plurality of first banks is configured to attenuate the RF input signal by a predetermined value. The AGC attenuator also includes a second transistor stack that includes a plurality of second banks of current steering differential transistor pairs. The second transistor stack is cascoded to the first transistor stack, and is configured to receive the first attenuated RF signal and output a second attenuated RF signal. Each second bank of the plurality of second banks is configured to attenuate the first attenuated RF signal by a predetermined value.

The present disclosure provides for a togglable audio ducking device preferably with a mechanically triggered pressure-sensitive floor pad that detects pressure when a user's body weight is in the proximity of the microphone. The mechanically triggered pressure-sensitive floor pad may allow the user to effectively reduce ambient noise bleed into microphones without muting the microphone (i.e. audio ducking). In other embodiments, the togglable audio ducking device may be operated using a magnetic switch attached to a microphone stand, which is triggered when the microphone stand rotates in a particular direction to a certain degree.