Abstract: A linear decibel-scale variable gain amplifier includes an amplifying stage for generating an output voltage according to a differential input voltage, and a gain-controlling stage for outputting a gain-controlling voltage to the amplifying stage according to a first controlling voltage and a second controlling voltage. A voltage gain of the linear decibel-scale variable gain amplifier is inversely proportional to a simple exponential function, and the value of the simple exponential function is determined by the difference between the first controlling voltage and the second controlling voltage. The value of the voltage gain is unaffected by changes of the thermal voltage.

Abstract: A variable gain amplifier having a linear decibel-scale gain comprises an amplifying stage for generating an output voltage according to a differential input voltage, and a gain-controlling stage for outputting a gain-controlling voltage to the amplifying stage according to a first controlling voltage and a second controlling voltage. A voltage gain of the variable gain amplifier is inversely proportional to a simple exponential function, and the value of the simple exponential function is determined by the difference between the first controlling voltage and the second controlling voltage.

Abstract: A pipeline ADC has a plurality of analog-to-digital conversion units cascaded in series to form a pipeline. An error correcting method for the pipeline ADC includes during a first mode, measuring the plurality of analog-to-digital conversion units utilizing an extra analog-to-digital conversion module; calculating a plurality of correction constant sets according to digital output values of the extra analog-to-digital conversion module in the measuring step; and during a second mode, correcting output signals of the plurality of analog-to-digital conversion units according to the correction constant sets.

Abstract: A method for detecting a phase difference between a first input signal and a second input signal is provided. The method contains: detecting the phase difference of the first and the second input signals to produce an output signal; generating a first voltage according to a first level of the output signal; generating a second voltage according to a second level of the output signal; and comparing the first voltage and the second voltage to produce the information regarding the phase difference between the first and the second input signals.

Abstract: The variable gain amplifier of the present invention includes at least an operation amplifier. By choosing one of output stages, a feedback resistor is selected and the gain of the variable gain amplifier is decided according to the resistance of the selected feedback resistor, as desired. By adjusting the gain of the variable gain amplifier, the received signals can be amplified or attenuated in accordance with design requirement. The variable gain amplifier can include a two-stage architecture, in which a first stage is used for coarse gain adjustment and a second stage is used for fine gain adjustment. The gain of the two-stage variable gain amplifier can be easily adjusted to a desired value.

Abstract: A circuit apparatus having compensation circuits for unequal input/output common mode voltages is presented. The apparatus includes a circuit unit, a feedback path and a current source. The circuit unit has at least an input terminal for receiving an input signal and at least an output terminal for generating an output signal. The input terminal configured to provide an input common mode voltage and the output terminal configured to provide an output common mode voltage. The feedback path couples the output terminal and the input terminal. The current source is coupled to the input terminal to supply a current. The voltage drop generated at the feedback path compensates the difference between the input common mode voltage and the output common mode voltage.

Abstract: A pipeline ADC includes a pipeline structure having a plurality of analog-to-digital converting units cascaded in series; and a correcting unit coupled to the pipeline structure for correcting an output value of the pipeline structure according to a set of calibration constants. One of the analog-to-digital converting units contains a capacitor switching circuit. During error measurement of the pipeline ADC, the capacitor switching circuit switches to change capacitance allocation of the analog-to-digital converting unit so as to obtain the set of calibration constants.

Abstract: A low pass filter includes a differential amplifier including a positive input end, a negative input end, a positive output end, and a negative output end. A first resistive device is coupled between the negative input end and a first node. A second resistive device is coupled between the positive input end and the first node. A third resistive device substantially the same as the second resistive device is coupled between the negative input end and a second node. A fourth resistive device substantially the same as the first resistive device is coupled between the positive input end and the second node. A first capacitive device is coupled between the negative input end and the positive output end. Finally, a second capacitive device substantially the same as the first capacitive device is coupled between the positive input end and the negative output end.

Abstract: The line driver with active termination includes: a differential amplifier having an inverting output terminal, a non-inverting output terminal, an inverting input terminal, and a non-inverting input terminal; a first resistor unit coupled to the inverting input terminal; a impedance matching resistor unit coupled to the non-inverting output terminal; and a resistive feedback network, having a plurality of resistors in symmetric configuration. The resistive feedback network further includes: a second resistor unit coupled to the impedance matching resistor unit and the inverting input terminal; a third resistor unit coupled to the non-inverting output terminal and the inverting input terminal; a fourth resistor unit coupled to the impedance matching resistor unit and the inverting input terminal; and a fifth resistor unit coupled to the inverting output terminal and the inverting input terminal.

Abstract: The invention is to provide a receiving end architecture comprising a variable gain amplifier, for outputting a pair of differential signals comprising a first signal and a second signal via a first and a second outputs respectively according to the receiving signal through adjusting the amplitude of the receiving signal; a mix-type sample-and-hold circuit for outputting a first sampled signal via a first end and a second sampled signal via a second end and then outputting the second sampled signal via the first end and the first sampled signal via the second end through performing sample-and-hold on the pair of differential signals; and an analog/digital converter coupled to the mix-type sample-and-hold circuit for generating a digital signal according to the first and the second sampled signals.

Abstract: An output stage structure includes first and second PMOS transistors and first and second NMOS transistors, wherein the MOS transistors are manufactured with a twin well process. The first PMOS transistor has a source coupled to a supply voltage (VDD), and a gate coupled to the first voltage. The second PMOS transistor has a source coupled to a drain of the first PMOS transistor, a gate coupled to the second voltage, and a drain coupled to an output pad. The first NMOS transistor has a drain coupled to the output pad, and a gate coupled to the third voltage. The second NMOS transistor has a drain coupled to source of the first NMOS transistor, a gate coupled to the fourth voltage, and a source coupled to ground.

Abstract: An amplifying circuit with a variable supply voltage and a method thereof are disclosed. The amplifying circuit employs a voltage converter to adjust the supply voltage, thereby upgrading the energy efficiency of the circuit. The circuit also includes a control device, which can generate a control signal for controlling the voltage converter according to an output signal or input signal of the circuit.

Abstract: A pipeline ADC has a plurality of analog-to-digital conversion units cascaded in series to form a pipeline. An error correcting method for the pipeline ADC includes during a first mode, measuring the plurality of analog-to-digital conversion units utilizing an extra analog-to-digital conversion module; calculating a plurality of correction constant sets according to digital output values of the extra analog-to-digital conversion module in the measuring step; and during a second mode, correcting output signals of the plurality of analog-to-digital conversion units according to the correction constant sets.

Abstract: A pipeline ADC includes a pipeline structure having a plurality of analog-to-digital converting units cascaded in series; and a correcting unit coupled to the pipeline structure for correcting an output value of the pipeline structure according to a set of calibration constants. One of the analog-to-digital converting units contains a capacitor switching circuit. During error measurement of the pipeline ADC, the capacitor switching circuit switches to change capacitance allocation of the analog-to-digital converting unit so as to obtain the set of calibration constants.

Abstract: A pipeline ADC for converting an analog input signal to a digital output signal includes: a plurality of analog-to-digital converting units cascading in series to form a pipeline including a plurality of digital output ends; a calculation unit coupled to the analog-to-digital converting units for generating a plurality of calibration parameters in a first mode according to signals at the digital output ends; and a calibration unit coupled to the calculation unit and the analog-to-digital converting units for calibrating signals at the digital output ends in a second mode according to the calibration parameters, so as to generate the digital output signal.

Abstract: A processor with an adjustable operating frequency and method thereof. The pipeline processor includes a clock providing module for providing a reference clock, and a processing core coupled to the clock providing module for processing a first instruction according to the reference clock. The clock providing module contains a multi-phase clock generator for generating a plurality of original clocks with different phases, and a phase selector for selecting an original clock to generate the reference clock according to the first instruction.

Abstract: A cascaded diode structure with a deep N-well for effectively reducing the leakage current of the P-type substrate by floating the base of a parasitic transistor in the cascaded diode structure. The cascaded diode structure includes a P-type substrate, a deep N-well formed on the P-type substrate, a plurality of elemental diodes formed on the deep N-well, and a plurality of connecting parts for cascading the elemental diodes. Each elemental diode includes a P-well formed on the deep N-well, a heavily doped P-type region formed on the P-well, and a heavily doped N-type region formed on the P-well.

Abstract: The present invention discloses an impedance matching circuit with automatic adjustment and a method thereof. The impedance matching circuit comprises: a resistor, for receiving a reference voltage and generating a reference current; a detection unit, for detecting resistance variation and generating a plurality of comparison voltages according to said reference current; a comparison unit, for comparing said reference voltage with said comparison voltages, and generating a control signal; and a composite resistor unit, for receiving said control signal and generating a matched impedance. Therefore, a matched impedance value can be obtained within a designed range in despite of the manufacturing process and the operation environment.

Abstract: A method and device for calibrating in-phase and quadrature-phase (IQ) mismatch. The device is used in a direct down-conversion circuit of a communication system. The device has a first mixer for mixing an RF signal with a first carrier signal, so as to generate an in-phase analog signal; a second mixer for mixing the RF signal with a second carrier signal, so as to generate a quadrature-phase analog signal; an operation unit for executing a Least Mean Square (LMS) algorithm and thereby generating a compensation signal according to the in-phase analog signal and the quadrature-phase analog signal; and a calibration unit for compensating the in-phase analog signal and the quadrature-phase analog signal according to the compensation signal, so as to calibrate the IQ mismatch between the in-phase analog signal and the quadrature-phase analog signal.

Abstract: A method and an apparatus of IQ mismatch calibration in a radio communication system. The method includes receiving a radio frequency signal, mixing the radio frequency signal with a first carrier to generate an In-phase analog signal, mixing the radio frequency signal with a second carrier to generate a Quadrature-phase analog signal, detecting a phase offset between the In-phase analog signal and the Quadrature-phase analog signal, computing at least a tuning parameter according to the phase offset, and calibrating at least one of the In-phase analog signal and the Quadrature-phase analog signal according to at least one of the phase offset and the tuning parameter such that the In-phase analog signal and the Quadrature-phase analog signal are orthogonal after calibration.