Abstract: A signal input circuit and method and chip are disclosed. The signal input circuit includes a control signal input terminal configured for receiving a control signal; at least one common signal input terminal each configured for receiving a corresponding common signal; at least one first signal output terminal each configured for outputting a corresponding first signal; at least one first signal unit each configured for receiving said corresponding common signal and outputting said corresponding common signal as said corresponding first signal under control of said control signal; at least one second signal output terminal each configured for outputting a corresponding second signal; and at least one second signal unit each configured for receiving said corresponding common signal and outputting said corresponding common signal as said corresponding second signal under control of said control signal.

Abstract: A semiconductor apparatus comprises a power-up signal generation section configured to generate a power-up signal, a driver configured to drive and output the power-up signal, and a main circuit block configured to perform predetermined functions in response to an output from the driver, wherein the power-up signal generation section and an input terminal of the driver are connected by a disconnectable element.

Abstract: Disclosed herein is a power on reset (POR) circuit, including: a current mirror circuit adjusting ratio of current flowing in a circuit according to voltage supplied from power; an inverter driven according to output of the current mirror circuit to output a POR signal; a brown out detection (BOD) comparator electrically connected to the current mirror circuit and comparing the voltage supplied from the power with reference voltage to output a corresponding voltage signal according to the comparison result; a BOD controlling switch driven when the output of the BOD comparator is zero voltage (0V) to again operate a POR; and a current controlling switch installed in the current mirror circuit and driven when the output of the BOD comparator is zero voltage (0V) to control and supply current of the POR.

Abstract: A voltage translation circuit (116) provides an output analog voltage signal that has a translated voltage of the voltage of an input analog voltage signal over a range of values of the input analog voltage signal. The voltage translation circuit includes an input stage (202) having a circuit node and an input transistor (210) coupled between the circuit node and a power supply terminal, wherein a gate of the input transistor is coupled to receive the input analog voltage signal; a current path circuit (204) in parallel with the input transistor, wherein the current path includes a first transistor coupled between the circuit node and the power supply terminal; and a circuit coupled to provide a variable body bias voltage to a body of the first transistor.

Abstract: Circuit and method for resetting clock circuitry. The circuit includes a chain of cascading units, each of which receives an input of a number of parallel bit streams and outputs a different number of parallel bit streams. A chain of dividers provides one or more divided clock signals to the cascading units, wherein the divided clock signals are based on a gated common clock signal. An asynchronous reset signal is delivered to the dividers, and when asserted sets the dividers to a reset state. A clock source provides an ungated common clock signal. A clock gating circuit generates the gated common clock signal based on the ungated common clock signal, and is configured to hold the gated common clock signal while the asynchronous reset signal is asserted. The clock gating circuit provides the gated common clock signal to the dividers when the asynchronous reset signal is de-asserted.

Abstract: A method and apparatus for measuring the duration of a transient signal with high precision.

Abstract: According to embodiments, dual path loop filter circuits are described which have, for example, a single charge pump. The current flow in the DPLF circuit is architected to source, during an injection time period, a first current to the loop filter, sink, also during the injection time period, a second current from the loop filter, wherein the first current has a magnitude of ?*I and the second current has a magnitude of ?*I, and sink, during a linearization time period, a third current from the loop filter, wherein the third current has a magnitude of (???)*I.

Abstract: A phase/frequency detector for controlling a charge pump includes: a core circuit arranged to output a first phase signal and a second phase signal according to a phase/frequency difference between a reference clock signal and an input clock signal; and a timing circuit coupled to the core circuit and arranged to generate a first control signal and a second control signal for controlling the charge pump according to the first phase signal and the second phase signal, wherein only one of the first control signal and the second control signal is indicative of an enabled operation when the reference clock signal and the input clock signal are substantially identical in phase.

Abstract: A PLL circuit comprises a phase frequency detector (PFD), a charge pump (CP), a low pass filter (LPF), a voltage controlled oscillator (VCO), a frequency divider (FD) and a reset module. The PFD receives a first and a second input signals, and outputs a first and a second adjustment parameters according to phase and frequency difference between the first and the second input signal. The CP is coupled to the PFD, generates a current according to the first and the second adjustment parameters. The LPF is coupled to the CP, and generates a voltage according to the current. The VCO is coupled to the LPF, and generates an oscillation frequency according to the voltage. The FD receives and divides the oscillation frequency, and generates the second input signal. The reset module generates a reset signal to feed to the FD, wherein the reset module receives the first signal.

Abstract: A semiconductor device includes a delay locked loop (DLL) configured to generate a DLL clock signal by delaying a reference clock signal in response to a second delay amount tracked using a first delay amount as an initial delay amount, and track the second delay amount again by adjusting the first delay amount in response to a reset signal, and a DLL controller configured to activate the reset signal when the second delay amount deviates from a given range.

Abstract: A semiconductor memory device includes a clock period reflector configured to reflect time corresponding to period information of an internal clock signal to an input data signal, a data-clock converter configured to generate a synchronization clock signal having phases corresponding to an output signal of the clock period reflector, and a synchronization output unit configured to synchronize and output the input data signal in response to the synchronization clock signal.

Abstract: A delay-locked loop (DLL) circuit having improved phase correction performance includes a variable delay unit configured to generate a DLL clock signal by delaying an input clock signal by a varied delay time in response to a delay control signal at timing corresponding to an update cycle signal, a delay model configured to generate a feedback clock signal by delaying the DLL clock signal for a predetermined delay time, a phase detection unit configured to output a result of the detection of the phase of the feedback clock signal based on a reference clock signal as the delay control signal, and an update cycle control unit configured to determine whether a cycle has been shifted or not in response to an external clock signal and the delay control signal and shift a cycle where the update cycle signal is generated based on a result of the determination.

Abstract: The present invention relates to a method and device for phase-frequency detection in a phase-lock loop circuit. The method comprises receiving compare edge of a reference clock signal and compare edge of a feedback clock signal, maintaining a phase/frequency detector, PFD, state machine with three PFD states, UP, DOWN, and IDLE, based on the received compare edges of the reference and feedback clock signals, recording current and previous time the state machine stays in UP or DOWN states, generating an UP or DOWN signal based on transition of PFD states and the comparison between recorded current time and recorded previous time; and outputting a digital control signal to a feedback frequency control device based on the UP or DOWN signal. A device and system is arranged to execute the method according to the present invention.

Abstract: A source driver with an automatic de-skew capability is configured to receive a data signal and a clock signal from a timing controller, which are configured to drive a liquid crystal display panel. The source driver includes a signal delay unit, a setup time register, a hold time register, a first signal delay unit, a second delay unit and a logic circuit. In one embodiment of the present disclosure, the first data delay signal is configured to sample the second clock delay signal and the second data delay signal is configured to sample the first clock delay signal.

Abstract: A duty cycle error accumulation circuit includes first to nth delay units and a feedback unit. The first to nth delay units receive a clock signal, a first input signal and a second input signal, respectively, to generate a first output signal and a second output signal by delaying one signal selected from first and second input signals based on a logic level of the clock signal. The feedback unit supplies second input signal to a kth delay unit based on second output signal of a (k+1)th delay unit. The first output signal of the kth delay unit is supplied to the (k+1)th delay unit as first input signal, and the clock signal is supplied to the first delay unit as first input signal and to the nth delay unit as second input signal. The duty cycle error accumulation circuit effectively corrects a duty cycle of a clock signal.

Abstract: A Schmitt trigger inverter circuit can include a first inverter. The first inverter can include a first pull-up device, a first pull-down device and a second pull-down device. The first inverter can receive an input signal. The Schmitt trigger inverter circuit can include a second inverter coupled in series with the first inverter and including an output that generates an output signal. The Schmitt trigger inverter circuit further can include a switch coupled to the output of the second inverter circuit and that is selectively enabled by the output signal. The switch can couple a predetermined reference voltage to a source terminal of the first pull-down device when in an enabled state. Coupling the predetermined reference voltage to the source terminal of the first pull-down device can alter a threshold voltage of the Schmitt trigger inverter circuit.

Abstract: The present invention provides an improvement of a 4-quadrant clock phase interpolator design to allow independent rotation of the output clocks in steps of 90°. This feature is useful in clock/data recovery where the 90° “jumps” can be used as a coarse control to re-align the data capture clock to achieve any desired data word alignment and/or receive bus clock alignment. The phase interpolator has a switching circuit comprising a single level of switches; a set of four transistor loads; and a set of four current sources operable to be switched by the switching circuit through to any of the set of four transistor loads.

Abstract: A semiconductor integrated circuit includes a rupture instructing pulse generation unit configured to generate a rupture instructing pulse signal in response to a fuse rupture command signal and an address; a first anti-fuse rupture unit configured to perform an operation for rupturing a first anti-fuse during an enable period of the rupture instructing pulse signal, and generate rupture information of the first anti-fuse; a pulse shifting unit configured to delay the rupture instructing pulse signal and generate a delayed rupture instructing pulse signal; and a second anti-fuse rupture unit configured to perform an operation for rupturing a second anti-fuse during an enable period of the delayed rupture instructing pulse signal, and generate rupture information of the second anti-fuse.

Abstract: This disclosure provides examples of circuits, devices, systems, and methods for generating a reference clock signal and delaying a received clock signal based on the reference clock signal. In one implementation, a circuit includes a control block configured to generate a control signal. The circuit includes an oscillator configured to generate a reference clock signal. The oscillator includes a plurality of delay elements each configured to receive the control signal and to introduce a delay in the reference clock signal based on the control signal. The delay elements of the oscillator are arranged to generate the reference clock signal. The circuit further includes a delay block configured to receive a clock signal and to generate a delayed clock signal. The delay block includes one or more delay elements each configured to receive the control signal and to introduce a delay in the clock signal based on the control signal.

Abstract: A voltage level shifting circuit with an input terminal and an output terminal. The level shifting circuit has a field-effect transistor (FET) switch with a gate attached to the input terminal, a drain attached to the output terminal and a source attached to a current changing mechanism. The current changing mechanism includes a current mirror circuit having an output connected between the source and an electrical earth. The output of the current mirror circuit is preferably adapted to change a current flowing between the drain and the source based on an input voltage applied to the gate.

Abstract: An amplifier has a first pull-up path coupled between a voltage supply node and an output node, and a pull-down path coupled between the output node and a ground supply node. A second pull-up path is coupled between the voltage supply node and the output node. The second pull-up path is actuated by a feedback signal and biased by a biasing signal. An inverter circuit is operable to invert the signal at the amplifier output node to generate the feedback signal. A biasing circuit is configured to generate the biasing signal. The biasing circuit is configured to control a relative strength of the pull-down path to the second pull-up path, wherein the pull-down path is stronger than the second pull-up path in a manner that is consistently present over all PVT corners.

Abstract: A return-type current-reuse mixer having a transconductance/amplification stage, a mixing stage, and a high-pass and a low-pass filter network. The transconductance/amplification stage has a current-reuse CMOS topology wherein an input frequency signal is converted into a frequency current, low-frequency components are removed from the frequency current by the high-pass filter network, the frequency current is fed into the mixing stage, modulation occurs in the mixing stage, and then an intermediate-frequency signal is generated and output. Once high-frequency components are removed from the intermediate-frequency signal by the low-pass filter network, the intermediate-frequency signal is sent again for input into the transconductance/amplification stage, then amplified in the transconductance/amplification stage and output. The mixer transconductance/amplification stage employs a current-reuse technique.

Abstract: A switching circuit according to one embodiment includes first to fourth semiconductor switch elements. A pulse-like signal is applied to each input terminal of the switch elements such that when the first and fourth switch elements are in an ON (OFF) state, the remaining switch elements are in an OFF (ON) state. The switching circuit includes first and second capacitance elements. The first capacitance elements connected between an output terminal of the second semiconductor switch element and the second capacitance elements connected between an input terminal of the second semiconductor switch element and an output terminal of the fourth semiconductor switch element has a capacitance to reduce a parasitic capacitance between the input and output terminals of each of the fourth and second switch elements at a frequency N times (N is an integer of 1 or more) as high as a clock frequency of the pulse-like signal.

Abstract: A sampled CMOS switch includes first and second NMOS devices in series between input and output nodes. The first and second NMOS devices are activated by a sample signal. A pair of low-voltage DEPMOS devices is connected in a “T” configuration between the input and output nodes. The low-voltage DEPMOS devices are activated by an inverted sample signal. A feedback circuit includes the DEPMOS devices together with a third high-voltage NMOS device and a current source. The third NMOS device is controlled by a signal on the input node. A switch switchably connects an analog voltage source to a source of the third NMOS device and gates of the DEPMOS devices in accordance with a phase of an inverted sample signal. The construction of the sampled CMOS switch enables the protection of the gate oxide insulation of the low-voltage DEPMOS transistors from high voltage damage.

Abstract: An apparatus relating generally to an analog multiplexer is disclosed. In such an apparatus, the analog multiplexer has first select circuits and at least one second select circuit. The first select circuits have respective input nodes and output nodes. The output nodes are all coupled to one another to provide an output node of the analog multiplexer. The first select circuits are coupled to a first supply voltage of a first supply domain. The at least one second select circuit is coupled to a second supply voltage of a second supply domain different from the first supply domain. The at least one second select circuit has an input port and an output port. The output port is coupled to an input node of the input nodes.

Abstract: A power semiconductor device includes first and second power semiconductor elements connected in parallel to each other and a drive control unit. The drive control unit turns on or off each of the first and second power semiconductor elements in response to an ON instruction and an OFF instruction repeatedly received from outside. Specifically, the drive control unit can switch between a case where the first and second power semiconductor elements are simultaneously turned on and a case where one of the first and second power semiconductor elements is turned on first and thereafter the other thereof is turned on, in response to the ON instruction. The drive control unit turns off one of the first and second power semiconductor elements first and thereafter turns off the other thereof, in response to the OFF instruction.

Abstract: A sensor circuit performs a method for sensing on-chip characteristics. The method includes generating a first voltage using a drive current through a first set of transistors that are operating in saturation mode and generating a second voltage using subthreshold leakage current from a second set of transistors that are in subthreshold mode. The method further includes comparing the second voltage to the first voltage to sense an on-chip characteristic. The sensed on-chip characteristic can be temperature and/or gate length variation.

Abstract: Various embodiments of a method and apparatus for performing adaptive voltage adjustment based on temperature value are disclosed. In one embodiment, and integrated circuit (IC) includes logic circuitry having at least one temperature sensor therein. The IC also includes a power management circuit coupled to receive temperature readings from the temperature sensor. The power management circuit is configured to determine a temperature of the IC based on a temperature reading received from the temperature sensor. The power management circuit may compare the determined temperature to a temperature threshold. If the temperature exceeds a temperature threshold value, the power management circuit may cause the operating voltage to be reduced by an amount equivalent to a voltage guard band.

Abstract: An arrangement for detecting local light irradiation in an illegal attack attempt to intentionally induce a malfunction or faulty condition is formed on a small chip occupancy area so as to provide high detection sensitivity. In a region containing a logic circuit, a plurality of series-coupled detection inverters are distributively disposed as photodetector elements having a constant logical value of primary-stage input. When at least one of the series-coupled detection inverters is irradiated with light, an output thereof is inverted, thereby producing a final output through the series-coupled detection inverters. Based on the final output thus produced, local light irradiation can be detected.

Abstract: Many inventions are disclosed. Some aspects are directed to MEMS, and/or methods for use with and/or for fabricating MEMS, that supply, store, and/or trap charge on a mechanical structure disposed in a chamber. Various structures may be disposed in the chamber and employed in supplying, storing and/or trapping charge on the mechanical structure. In some aspects, a breakable link, a thermionic electron source and/or a movable mechanical structure are employed. The breakable link may comprise a fuse. In one embodiment, the movable mechanical structure is driven to resonate. In some aspects, the electrical charge enables a transducer to convert vibrational energy to electrical energy, which may be used to power circuit(s), device(s) and/or other purpose(s). In some aspects, the electrical charge is employed in changing the resonant frequency of a mechanical structure and/or generating an electrostatic force, which may be repulsive.

Abstract: Apparatus and method for supplying electrical power to a device. A system on chip (SOC) integrated circuit includes a first region having a processing core and a second region characterized as an always on domain (AOD) power island electrically isolated from the first region and having a power control block. A first power supply module is used to apply power to the first region, and a second power supply module is used to apply power to the second region. The second power supply module includes a main switch between the first power supply module and a host input voltage terminal. The power control block initiates a low power mode by transitioning the main switch to an open state. This causes the first region to receive no electrical power while the second region continuously receives power during the low power mode.

Abstract: A semiconductor device includes an internal voltage input buffer configured to determine voltage levels of a pull-up driving node and a pull-down driving node as a result of a comparison between a voltage level of an internal voltage node and a voltage level of a reference voltage node such that the pull-up driving node and the pull-down driving node to maintain a voltage level difference, and an internal voltage driving block configured to pull-up drive the internal voltage node in response to the voltage level of the pull-up driving node and pull-down drive the internal voltage node in response to the voltage level of the pull-down driving node.

Abstract: A semiconductor integrated circuit includes a first internal voltage generator including a PMOS and a first comparator, and a second internal voltage generator including an NMOS, a second comparator, and a voltage pump generator configured to provide a pumping power voltage to the second comparator. A power control circuit switchably enables an output from the first internal voltage generator during a power-on of the semiconductor integrated circuit and enables an output from the second internal voltage generator after the power-on.

Abstract: An integrated circuit comprising: a first core circuit configured to operate at a first clock rate for carrying out a first range of tasks; and a second core circuit configured to operate in a first mode and a second mode, the second core circuit being configured to operate at a second clock rate for carrying out a second range of tasks in the second mode and being configured to operate in the second mode when the first core circuit carries out the first range of tasks, the second clock rate being greater than the first clock rate.

Abstract: A switching circuit device has a first transistor which has a drain coupled to a high-potential terminal, a source coupled to a low-potential power supply, and, a driving circuit, which outputs, to a gate of the first transistor in response to an input control signal, a pulse having a potential higher than a threshold voltage of the first transistor and a potential of the low-potential power supply, wherein the driving circuit has a first inverter including a second transistor provided between the gate and the source of the first transistor, wherein when the first transistor changes from on to off due to the pulse, the second transistor conducts and short-circuits the gate and the source of the first transistor.

Abstract: Apparatus and methods are also disclosed related to tuning a quality factor of an LC circuit. In some implementations, the LC circuit can be embodied in a low-noise amplifier (LNA). A quality factor adjustment circuit can increase and/or decrease conductance across the LC circuit. This can stabilize a parasitic resistance in parallel with the LC circuit. In this way, a gain of the LC circuit can be stabilized.

Abstract: A switching amplifier with an embedded harmonic rejection filter is disclosed. In an exemplary design, the switching amplifier includes a generator circuit and a plurality of output circuits. The generator circuit receives an input signal and a carrier signal at a carrier frequency and generates a plurality of versions of a drive signal associated with different delays. The drive signal may be a pulse width modulation (PWM) signal. The plurality of versions of the drive signal may be generated by delaying the carrier signal, or the input signal, or the drive signal. The output circuits receive the plurality of versions of the drive signal and provide an output signal. The output circuits have outputs that are coupled together and implement a finite impulse response (FIR) filter based on the plurality of versions of the drive signal. The FIR filter has a frequency response with zeros at harmonics of the carrier frequency.

Abstract: An amplifier component (1) provides a chip housing (40) and at least two amplifier elements (31, 32). Between at least two connections (51, 52 and 61, 62) of each amplifier element (31, 32), a parasitic capacitance (81, 82) is formed, wherein this parasitic capacitance (81, 82) is compensated by an inductive compensation element (2). The compensation element (2) itself is formed between two connecting contacts (101, 102) outside of the chip housing (40) by a connecting lug (2).

Abstract: An amplifier circuit capable of reducing load of a circuit at the previous stage by providing increased input impedance producing less noises. The amplifier circuit includes a fully-differential operational amplifier composed of an inverting input terminal, a non-inverting input terminal receiving a signal different from a signal to be input to the inverting input terminal, an inverting output terminal with the same polarity of the inverting input terminal, and a non-inverting output terminal with reverse polarity; an input impedance element with one end connected to the inverting input terminal; an input impedance element with one end connected to the non-inverting input terminal; and positive feedback impedance elements, with one end of connected to the other end of the input impedance element and the other end connected to the inverting output terminal or to the non-inverting output terminal.

Abstract: An apparatus of a hybrid power modulator using interleaving switching is provided. The apparatus includes a linear switching unit for generating an output signal by comparing an envelope input signal and a feedback signal, an interleaving signal generator for generating an interleaving switching signal arranged not to supply the signal to input stages of P-type Metal-Oxide-Semiconductor (MOS) Field Effect Transistors (FETs) and N-type MOS FETs of power cells at the same time by comparing the output signal and a reference signal, and a switching amplifying unit for determining a level of the switching signal using the interleaving switching signal. Hence, the hybrid power modulator using the interleaving switching method in the envelope signal of the wide bandwidth maintains high efficiency and high linearity. In addition, the buck converter can use the single inductor by preventing the simultaneous on/off of the power cells.

Abstract: Embodiments of the present invention include a method and system for control of a multiple-input-single output (MISO) device. For example, the method includes determining a change in power output level from a first power output level to a second power output level of the MISO device. The method also includes varying one or more weights associated with respective one or more controls of the MISO device to cause the change in power output. The one or more controls can include one or more of (a) a phase control of one or more input signals to the MISO device, (b) a bias control of the MISO device, and (c) an amplitude control of the input signals to the MISO device.

Abstract: An exemplary system comprises a linearizer, a power amplifier, and a feedback block. The linearizer may be configured to use a predistortion control signal to add predistortion to a receive signal to generate a predistorted signal. The power amplifier may be configured to amplify power of the predistorted signal to generate a first amplified signal. The power amplifier may also add high side and low side amplifier distortion to the predistorted signal. The high side and low side amplifier distortion may cancel at least a portion of the predistortion. The feedback block may be configured to capture a feedback signal based on a previous amplified signal from the power amplifier, to determine high side and low side distortion of the captured feedback signal, and to generate the predistortion control signal based on the determined high side and low side distortion.

Abstract: A digitally-controlled power amplifier (DPA) with bandpass filtering includes a radio-frequency (RF) clock input, an amplitude control word (ACW) input, and a plurality of DPA cells. The RF clock input is arranged for receiving an RF clock. The ACW input is arranged for receiving a digital ACW signal. The DPA cells are coupled to the RF clock and the digital ACW signal, wherein at least one of the DPA cells is gradually turned on and off in response to at least one bit of the digital ACW signal.

Abstract: A circuitry (120) adapted to operate in a high-temperature environment of a turbine engine is provided. The circuitry may include a differential amplifier (122) having an input terminal (124) coupled to a sensing element to receive a voltage indicative of a sensed parameter. A hybrid load circuitry (125) may be AC-coupled to the differential amplifier. The hybrid load circuitry may include a resistor-capacitor circuit (134) arranged to provide a path to an AC signal component with respect to the drain terminal of the switch (e.g., 126) of a differential pair of semiconductor switches 126, 128, which receives the voltage indicative of the sensed parameter.

Abstract: In certain embodiments, circuits and methods for time gain compensation are provided. A circuit includes a first op-amp that is configured to compare a first and a second input voltage signal received from first and second input circuits, respectively, and output a first op-amp output signal. A control circuit coupled with a first semiconductor element of the second input circuit is configured to vary a first resistance value of the first semiconductor element to control the first op-amp output signal. The first op-amp output signal includes a relatively high voltage signal and a relative low voltage signal when an input control voltage signal corresponds to a first reference voltage and a second reference voltage signal, respectively associated with the first op-amp. The first op-amp output signal is input to a gate terminal of a load semiconductor element so-as to vary an impedance of the load semiconductor element.

Abstract: Disclosed is a Class-AB/B amplifier comprising a first output stage including a first plurality of amplification devices and a second output stage including a second plurality of amplification devices. According to one embodiment, the first output stage operates when the Class-AB/B amplifier is in a quiescent state and the second output stage operates when the Class-AB/B amplifier is in an active state. The Class-AB/B amplifier also comprises a level shifting circuit that adjusts a control voltage of the second output stage, where the level shifting circuit is adapted to activate the second output stage when the Class-AB/B amplifier enters the active state. Embodiments of the Class-AB/B amplifier may include a level shifting circuit that implements either a fixed or signal-dependent level shift, and a quiescent control circuit that substantially eliminates any systematic offset arising from the active feedback circuit inside the replica bias circuit.

Abstract: Methods and devices provide for power amplification in a push pull power amplifier. A circuit comprises an input stage, a power amplifier stage and an output stage. The input stage provides a plurality of control voltages based on a control current. The input stage may include a transformer with a primary side and two secondary sides. A power amplifier stage comprises an NMOS transistor and a PMOS transistor arranged in a push-pull configuration to generate a plurality of amplified signals. The transistors may be in a common gate arrangement. The output stage combines the amplified signals and generates an output voltage. The output stage may include a transformer with two primary sides and a secondary side.

Abstract: The apparatus and method thereof accurately sense and convert a radio frequency (RF) current signal to direct current (DC) independent of process variation and temperature, and without requiring high speed, high voltage amplifiers for its operation. The apparatus comprises an AC coupled circuit that couples the RF signal from the main device to a sense device with an N:M ratio, a low pass filter system that extracts the DC content of the RF current signal, and a negative feedback loop that forces the DC content of the main device and the sensed device to be equal. Exemplary embodiments include a current sensor that provides feedback to protect an RF power amplifier from over-current condition, and a RF power detection and control in a RF power amplifier (PA) that multiplies the sensed output current by the sensed output voltage to be used as a feedback to control the PA's bias.

Abstract: Apparatus and methods for frequency compensation of an amplifier are provided. In one embodiment, an integrated circuit (IC) includes an amplifier configured to amplify an input signal to generate an output signal. The IC further includes an output pad configured to receive an output signal from the amplifier and a control pad for controlling the closed-loop bandwidth of the amplifier. A compensation capacitor is electrically connected between an input of the inverting amplification block and an output of the inverting amplification block, and a switchable capacitor is electrically connected between the input of the inverting amplification block and the control pad. The control pad can be electrically connected to a DC voltage source or to the output pad to control the amplifier's closed-loop bandwidth.

Abstract: An operational amplifier includes an operational amplifier circuit having at least one output node and an output stage coupled to the output node, the output stage containing an output and first MOS transistor employed in a common source amplifier mode, a frequency compensation capacitor coupled between the output of the output stage and the gate of the first transistor circuit by means of a second MOS transistor employed in a common gate amplifier mode. The other node of the capacitor and the output of the output stage are coupled to the amplifier output node with a resistor.