Abstract: A two-stage op amp has a transconductance cell in a second stage modified to match a transconductance cell in a first stage. A transconductance swap network is inserted between transconductance cells and trans-impedance cells, such as current-steering networks, current mirrors, or drivers connected to the transconductance cells. The transconductance swap network directly connects the first transconductance cell to the first stage trans-impedance cell during a second clock phase, but crosses-over the first transconductance cell to the second-stage trans-impedance cell during a first clock phase. A first switched-capacitor network drives the gates of differential transistors in the first transconductance cell by alternately sampling an input and feedback, and equalizing to reset inputs. A second first switched-capacitor network drives differential transistors in the second transconductance cell, but during opposite clock phases.

Abstract: A two-stage op amp has a transconductance cell in a second stage modified to match a transconductance cell in a first stage. A transconductance swap network is inserted between transconductance cells and trans-impedance cells, such as current-steering networks, current mirrors, or drivers connected to the transconductance cells. The transconductance swap network directly connects the first transconductance cell to the first stage trans-impedance cell during a second clock phase, but crosses-over the first transconductance cell to the second-stage trans-impedance cell during a first clock phase. A first switched-capacitor network drives the gates of differential transistors in the first transconductance cell by alternately sampling an input and feedback, and equalizing to reset inputs. A second first switched-capacitor network drives differential transistors in the second transconductance cell, but during opposite clock phases.

Abstract: A Digital Phase-Locked Loop (DPLL) has a digitally-controlled oscillator (DCO) that generates an output clock frequency determined by a digital input with most-significant-bits (MSB's) and a least-significant-bit (LSB). The LSB is generated by a Pulse-Width-Modulation (PWM) controller clocked by a control clock that is the output clock divided by C. A reference clock is compared to a feedback clock that is the output clock divided by M. The PWM controller generates M/C LSB's for each reference clock period and loads them in parallel to a parallel-to-serial shift register that serially delivers the LSBs. The pulse width is determined by a fine digital loop filter that filters phase comparison results using a fine time resolution. A coarse digital loop filter generates the MSB's from phase comparison results using a coarse time resolution. LSB waveforms are dithered by randomly selecting high-going or low-going pulses and randomly adjusting pulse widths.

Abstract: A Digital Phase-Locked Loop (DPLL) has a digitally-controlled oscillator (DCO) that generates an output clock frequency determined by a digital input with most-significant-bits (MSB's) and a least-significant-bit (LSB). The LSB is generated by a Pulse-Width-Modulation (PWM) controller clocked by a control clock that is the output clock divided by C. A reference clock is compared to a feedback clock that is the output clock divided by M. The PWM controller generates M/C LSB's for each reference clock period and loads them in parallel to a parallel-to-serial shift register that serially delivers the LSBs. The pulse width is determined by a fine digital loop filter that filters phase comparison results using a fine time resolution. A coarse digital loop filter generates the MSB's from phase comparison results using a coarse time resolution. LSB waveforms are dithered by randomly selecting high-going or low-going pulses and randomly adjusting pulse widths.

Abstract: Disclosed are a device and a method for calibrating a frequency of a transponder applicable to an RFID system. The device may comprises: a pulse generating unit configured to generate a sequence of pulses based on a PIE symbol sequence from an interrogator of the RFID system; a counting unit configured to count clock cycles of a clock signal based on the generated pulses, wherein the transponder operates based on the clock signal; and a calibrating unit configured to calibrate a frequency of the clock signal towards a target frequency based on a comparison of the counted number of clock cycles with a reference number associated with the target frequency.