Abstract: An active filter comprising an operational amplifier, and a controller configured to control the bandwidth of the operational amplifier based on a filter cutoff frequency setting and/or a noise performance setting.

Abstract: In an embodiment, an apparatus is disclosed that comprises a voltage regulator and a regulator booster. The voltage regulator is supplied by an input and is configured to generate a regulated output. The regulated output has a voltage corresponding to an operating point of the voltage regulator. The regulator booster is connected to the voltage regulator and, when activated, is configured to boost the voltage of the regulated output by a target amount. The target amount is at least a portion of a magnitude of a voltage droop relative to the operating point that is caused by a change in a current load on the regulated output.

Abstract: An integrated circuit is presented. The integrated circuit includes an internal circuit; a contact pad; and a protective element coupled between the internal circuit and the contact pad. The protective element is operable in a first state or a second state. In the first state the protective element passes a current between the internal circuit and the contact pad. When the current is above a threshold value the protective element changes from the first state to the second state to reduce or prevent the current from flowing between the internal circuit and the contact pad. The protective element may be used to prevent damage to an external circuit connected to the integrated circuit.

Abstract: A package for use with an integrated circuit having a contact pad is provided. The package includes an enclosure portion; a package pin for external connection; and a protective element coupled between the contact pad and the package pin. The protective element is operable in a first state or a second state. In the first state the protective element passes a current between the contact pad and the package pin. When the current is above a threshold value the protective element changes from the first state to the second state to prevent the current from flowing between the contact pad and the package pin.

Abstract: A regulator circuit is presented. The regulation circuit (530) has a regulation switch (131), a voltage comparator (537) with predetermined offset voltage and an adjuster. The regulation switch (131) has a first terminal coupled to a current source (132), a second terminal connectable to a load (110), and a control terminal. The voltage comparator (537) compares a sum voltage of the offset voltage added to a voltage at the second terminal with a control voltage at the control terminal, and generates a comparison signal. The adjuster adjusts the voltage at the second terminal based on the comparison signal to control a difference voltage between the control terminal and the second terminal of the regulation switch and to maintain the regulation switch operating in a desired region of operation.

Abstract: A semiconductor device includes a semiconductor substrate on which a temperature sensor is formed, a plurality of insulating films formed above the semiconductor substrate, a temperature measurement wiring pattern formed on a first insulating film which is one of the plurality of the insulating films, a detection electrode which is formed on the uppermost insulating film of the plurality of the insulating films to be arranged at a position corresponding to the first temperature measurement wiring pattern and is provided for contact a temperature measurement needle, and one or more via electrodes formed in one or more insulating film between the temperature measurement electrode and the detection electrode to couple between the temperature measurement electrode and the detection electrode.

Abstract: Apparatuses, systems, and methods for implementing a multi-driver architecture are described. The multi-driver architecture may include a first driver and a second driver configured to receive an input voltage. A predriver logic circuit may select one of the first driver and the second driver to convert the input voltage into an output voltage. A controller may be connected to the first driver and the second driver, and a switch may be connected between an output terminal of the first driver and the controller. The controller may be configured to control an internal resistance of the switch. In response to the first driver being selected by the predriver logic circuit, the first driver may output the output voltage at a constant impedance level.

Abstract: A part among a plurality of through vias formed in a non-transistor region is a floating via having a floating potential.

Abstract: Systems and methods for battery reactive impedance measurement is generally described. The method can include measuring a voltage of a battery cell. The method can further include measuring a current flowing through the battery cell. The method can further include determining a time offset based on the voltage and the current. The time offset can cause the voltage and current to be in-phase. The method can further include sampling the voltage and the current based on the time offset. The method can further include determining an impedance of the battery cell based on the sampled voltage and sampled shifted current.

Abstract: A system of a power device and a portable device for wireless charging of a battery of the portable device, which power device comprises a first antenna to emit a magnetic field and which portable device comprises a portable antenna exposed to the magnetic field and connected to a charge stage to rectify an antenna signal from the portable antenna and to provide a charge voltage (UI) to charge the battery wherein the power device comprises a second antenna realized identical as the first antenna and arranged in a distance (L) to the first antenna and on the same coil axis (A) as the first antenna to generate a Helmholtz magnetic field and wherein a first power amplifier directly connected to the first antenna and a second power amplifier directly connected to the second antenna are realized identical and on the same substrate.

Abstract: Apparatuses and methods for operating a power converter are described. An integrated circuit can be integrated in a high-side driver of a high-side fiend-effect transistor (FET) of the power converter. The integrated circuit can detect a phase node voltage of a power integrated circuit. The integrated circuit can, in response to the phase node voltage being less than a threshold voltage, operate a high-side FET of the power integrated circuit in a constant-current mode. The integrated circuit can, in response to the phase node voltage being greater than the threshold voltage, operate the high-side FET of the power integrated circuit in a constant-voltage mode.

Abstract: An active noise cancellation (ANC) system is presented. The ANC system includes a transducer; a first microphone; and a first adaptive filter coupled to a calculator. The calculator generates an error signal based on a difference between a filtered input signal and a signal from the first microphone. The filtered input signal is based on a first transfer function estimate of the transducer-to-first microphone transfer function via a first acoustic path. The calculator updates coefficients of the first adaptive filter using the error signal and generates with the first adaptive filter a first noise-cancellation signal.

Abstract: A switched-mode power supply, such as a constant on time regulator, is presented. The switched-mode power supply includes a high side power switch coupled to a low side power switch at a switching node. A ramp injection circuit is coupled to the switching node and a ramp switch is coupled to the ramp injection circuit are also provided. A driver is used to drive the high side power switch and the low side power switch and to control the ramp switch. The driver turns off the ramp switch when the switch-mode power supply enters a tri-state, and turns the ramp switch back on when the switch-mode power supply exists the tri-state. The tri-state occurs when the switched-mode power supply operates in a discontinuous current mode, when both the high side power switch and the low side power switch are turned off.

Abstract: A switching converter with adjustable on-time is presented. The switching converter includes an inductor coupled to a power switch; a pulse generator generating a pulsed signal to switch the power switch and a controller. The pulsed signal has an on-time adjustable between a first value and a second value, the first value being shorter than the second value. The controller identifies a mode of operation between a continuous conduction mode and a discontinuous conduction mode and sets the on-time to the second value when a continuous conduction mode is identified. The controller also measures a duration between successive inductor current pulses, compares the duration with a first threshold value and maintains the on-time to the second value as long as the duration is less than the first threshold value. When the duration increases above the first threshold value the controller sets the on-time to the first value.

Abstract: A method of controlling a multilevel power converter may include measuring an input voltage at a converter input, determining a half input voltage based on the input voltage; measuring a flying capacitor voltage across the flying capacitor; determining an error voltage based on a difference between the flying capacitor voltage and the half input voltage; generating an inductor current window having an inductor peak current and a valley inductor current; modulating the inductor peak current into an upper inductor peak current and a lower inductor peak current based on the error voltage; and operating the multilevel power converter to produce an output current through an inductor to a converter output, the output current being within the inductor current window and based on a sequence of pulse width modulation states.

Abstract: A semiconductor device includes a processor unit, a memory storing a boot program, a reset controller and an address check unit. The reset controller controls a reset for the processor unit based on a reset request and outputs a boot address for the boot program to be executed after reset release to the processor unit. The address check unit performs a tampering check for the boot address output from the reset controller and outputs a boot address error signal based on a tampering check result.

Abstract: Systems and methods for detecting a plunger movement condition with respect to a solenoid coil are described. A method may include generating a first derivative signal waveform of a current flowing in the solenoid coil, identifying whether there is at least one zero crossing point in the first derivative signal waveform, and detecting the plunger movement condition according to an identification result indicating whether there is at least one zero crossing point in the first derivative signal waveform.

Abstract: Apparatuses, devices, and methods for operating a multi-level voltage converter are described. A semiconductor device can include a circuit, where the circuit can include a plurality of current sources. The circuit can be configured to measure a flying capacitor voltage across a flying capacitor of a multi-level voltage converter. The circuit can be further configured to compare the flying capacitor voltage with a voltage level equivalent to an intermediate voltage that is between ground and an input voltage being provided to the multi-level voltage converter. The circuit can be further configured to, based on a result of the comparison, switch a current source among the plurality of current sources to maintain the flying capacitor voltage at the intermediate voltage.

Abstract: Systems and methods for operating a voltage converter are described. A circuit can multiply a digital code by a predetermined multiplier to obtain a product. The digital code can represent a desired output voltage of the voltage converter. The predetermined multiplier can cause the product to be maintained within a predetermined window. The product can be maintained within the predetermined window to cause an output of a reference digital-to-analog converter of the voltage converter to be maintained within a predetermined voltage window. The circuit can receive a feedback voltage indicating an output voltage of the voltage converter. The circuit can divide the feedback voltage by a divisor to obtain a divided voltage. The divisor can correspond to the digital code. The circuit can send the divided voltage to an error amplifier of the voltage converter.

Abstract: A torque map generation system includes a motor, an inverter that drives the motor, a controller that controls the inverter, a torque sensor coupled to the motor, a power analyzer coupled to the torque sensor and a torque map generator that measures a current vector value of the motor by switching a MTPA (Maximum Torque Per Ampere) method and a square wave method based on a voltage utilization ratio of the inverter, wherein the torque map generator utilizes a measurement result by the MTPA method when the torque map generator uses the square wave method.