Abstract: Systems, methods, and devices for fractional realignment are disclosed herein. A feedback divider generates a feedback dividing clock signal based on a controlling oscillator frequency. A delta-sigma modulator is coupled to the feedback divider and generates a dividing ratio to the feedback divider. An accumulating phase adjustor is coupled to the delta-sigma modulator and (i) determines a difference between a frequency tuning word (FCW) and the dividing ratio and (ii) generates a coarse tuning word and a fine tuning word. A digital-to-time converter (DTC) is coupled to the accumulating phase adjustor and generates a first clock frequency based on a reference clock frequency, the coarse tuning word and the fine tuning word. A realignment pulse generator is coupled to the DTC and generates a realignment clock based on the first clock frequency having a period that is the same as a period of the controlling oscillator frequency.

Abstract: Hybrid phase lock loop (PLL) devices are provided that combine advantages of the digital controlled loop and the analog controlled loop. For example, a hybrid PLL includes a digital controlled loop that receives a reference input signal and an output signal of the hybrid PLL, and generates a digital tuning word. The hybrid PLL further includes an analog controlled loop that receives the reference input signal and the output signal of the hybrid PLL, and generates an output voltage. The hybrid PLL also includes a hybrid oscillator. An oscillator controller of the digital controlled loop controls the hybrid oscillator using the digital tuning word and disables the analog controlled loop during a frequency tracking operational mode of the hybrid PLL. The oscillator controller enables the analog controlled loop to control the hybrid oscillator during the phase tracking operational mode of the hybrid PLL.

Abstract: A multi-tap Differential Feedforward Equalizer (DFFE) configuration with both precursor and postcursor taps is provided. The DFFE has reduced noise and/or crosstalk characteristics when compared to a Feedforward Equalizer (FFE) since DFFE uses decision outputs of slicers as inputs to a finite impulse response (FIR) unlike FFE which uses actual analog signal inputs. The digital outputs of the tentative decision slicers are multiplied with tap coefficients to reduce noise. Further, since digital outputs are used as the multiplier inputs, the multipliers effectively work as adders which are less complex to implement. The decisions at the outputs of the tentative decision slicers are tentative and are used in a FIR filter to equalize the signal; the equalized signal may be provided as input to the next stage slicers. The bit-error-rate (BER) of the final stage decisions are lower or better than the BER of the previous stage tentative decisions.

Abstract: An optimized pulse shaping clock data recovery system is provided that includes a slicer configured to receive a signal and provide an initial set of tentative decisions to a decision feedforward equalizer, where the decision feedforward equalizer provides a fully equalized output signal. The slicer may be incorporated as part of decision feedback equalizer to provide better quality tentative decisions. The clock data recovery system also receives the first output signal that is partially equalized in such a way as to optimally shape it for a clock to sample it at an ideal location by providing an adjustment signal to the analog to digital controller.

Abstract: A semiconductor device includes a circuit layer and a nanopore layer. The nanopore layer is formed on the circuit layer and is formed with a pore therethrough. The circuit layer includes a circuit unit configured to drive a biomolecule through the pore and to detect a current associated with a resistance of the nanopore layer, whereby a characteristic of the biomolecule can be determined using the currents detected by the circuit unit.

Abstract: Circuits and methods for performing a clock and data recovery are disclosed. In one example, a circuit is disclosed. The circuit includes an FSM. The FSM includes: a first accumulator, a second accumulator, and a third accumulator. The first accumulator is configured to receive an input phase code representing a phase timing difference between a data signal and a clock signal at each FSM cycle, to accumulate input phase codes for different FSM cycles, and to generate a first order phase code at each FSM cycle. The second accumulator is coupled to the first accumulator and configured to accumulate the input phase codes and first order phase codes for different FSM cycles, and to generate a second order phase code at each FSM cycle. The third accumulator is coupled to the second accumulator and configured to accumulate the input phase codes and second order phase codes for different FSM cycles, and to generate a third order phase code at each FSM cycle.

Abstract: A controlling circuit for ring oscillator is provided. First and second transistors of a first conductive type are coupled in series and between a node and a first power source. Third and fourth transistors of a second conductive type are coupled in parallel and between the node and a second power source. The node is coupled to a delay chain of the ring oscillator. The second and third transistors form a pseudo pass-gate inverter. An input of the pseudo pass-gate inverter is configured to receive an output signal of the delay chain. The first and fourth transistors are controlled by a realignment signal. When the realignment signal is in a realignment state, the first transistor is turned off and the fourth transistor is turned on, and when the realignment signal is in a normal state, the first transistor is turned on and the fourth transistor is turned off.

Abstract: Phase-locked loops (PLLs) are provided. A PLL includes a voltage-controlled oscillator (VCO), a frequency divider, a track-and-hold charge pump, and a frequency tracking circuit. The VCO is configured to provide an output clock corresponding to a pumping current. The frequency divider is configured to divide the output clock to provide a feedback signal. The track-and-hold charge pump is configured to provide the pumping current according to a reference clock and the feedback signal. The frequency tracking circuit is configured to decrease frequency error between the feedback signal and the reference clock. The track-and-hold charge pump includes a pumping switch and a pulse width modulator (PWM). The PWM is configured to provide a PWM signal to control the pumping switch according to the reference clock, so as to provide the pumping current corresponding to the feedback signal.

Abstract: Hybrid phase lock loop (PLL) devices are provided that combine advantages of the digital controlled loop and the analog controlled loop. For example, a hybrid PLL includes a digital controlled loop that receives a reference input signal and an output signal of the hybrid PLL, and generates a digital tuning word. The hybrid PLL further includes an analog controlled loop that receives the reference input signal and the output signal of the hybrid PLL, and generates an output voltage. The hybrid PLL also includes a hybrid oscillator. An oscillator controller of the digital controlled loop controls the hybrid oscillator using the digital tuning word and disables the analog controlled loop during a frequency tracking operational mode of the hybrid PLL. The oscillator controller enables the analog controlled loop to control the hybrid oscillator during the phase tracking operational mode of the hybrid PLL.

Abstract: Circuits and methods for performing a clock and data recovery are disclosed. In one example, a circuit is disclosed. The circuit includes an FSM. The FSM includes: a first accumulator, a second accumulator, and a third accumulator. The first accumulator is configured to receive an input phase code representing a phase timing difference between a data signal and a clock signal at each FSM cycle, to accumulate input phase codes for different FSM cycles, and to generate a first order phase code at each FSM cycle. The second accumulator is coupled to the first accumulator and configured to accumulate the input phase codes and first order phase codes for different FSM cycles, and to generate a second order phase code at each FSM cycle. The third accumulator is coupled to the second accumulator and configured to accumulate the input phase codes and second order phase codes for different FSM cycles, and to generate a third order phase code at each FSM cycle.

Abstract: Track-and-hold charge pumps and PLL are provided. A track-and-hold charge pump includes a track-and-hold circuit, a transconductance amplifier, a pulse width modulator (PWM), and a pumping switch coupled to the transconductance amplifier. The track-and-hold circuit samples an input signal according to a reference clock. The transconductance amplifier converts the sampled input signal into a current. The PWM provides a PWM signal according to the reference clock. The pumping switch is controlled by the PWM signal, to provide an output current according to the current.

Abstract: Hybrid phase lock loop (PLL) devices are provided that combine advantages of the digital controlled loop and the analog controlled loop. For example, a hybrid PLL includes a digital controlled loop that receives a reference input signal and an output signal of the hybrid PLL, and generates a digital tuning word. The hybrid PLL further includes an analog controlled loop that receives the reference input signal and the output signal of the hybrid PLL, and generates an output voltage. The hybrid PLL also includes a hybrid oscillator. An oscillator controller of the digital controlled loop controls the hybrid oscillator using the digital tuning word and disables the analog controlled loop during a frequency tracking operation mode of the hybrid PLL. The oscillator controller enables the analog controlled loop to control the hybrid oscillator during the phase tracking operation mode of the hybrid PLL.

Abstract: A ring oscillator is provided. The ring oscillator includes a pseudo pass-gate inverter, a third transistor, a fourth transistor and a delay chain. The pseudo pass-gate inverter includes a first transistor and a second transistor in series. The third transistor is connected in series with the pseudo pass-gate inverter. The drain of the fourth transistor is connected to an output of the pseudo pass-gate inverter. The gate of the fourth transistor is connected to the gate of the third transistor to receive the realignment signal. The delay chain includes a plurality of delay cells. An input of the delay chain is connected to the output of the pseudo pass-gate inverter. When the realignment signal is in a realignment state, the third transistor is turned off, the fourth transistor is turned on.

Abstract: Circuits and methods for performing a clock and data recovery are disclosed. In one example, a circuit is disclosed. The circuit includes an FSM. The FSM includes: a first accumulator, a second accumulator, and a third accumulator. The first accumulator is configured to receive an input phase code representing a phase timing difference between a data signal and a clock signal at each FSM cycle, to accumulate input phase codes for different FSM cycles, and to generate a first order phase code at each FSM cycle. The second accumulator is coupled to the first accumulator and configured to accumulate the input phase codes and first order phase codes for different FSM cycles, and to generate a second order phase code at each FSM cycle. The third accumulator is coupled to the second accumulator and configured to accumulate the input phase codes and second order phase codes for different FSM cycles, and to generate a third order phase code at each FSM cycle.

Abstract: Hybrid phase lock loop (PLL) devices are provided that combine advantages of the digital controlled loop and the analog controlled loop. For example, a hybrid PLL includes a digital controlled loop that receives a reference input signal and an output signal of the hybrid PLL, and generates a digital tuning word. The hybrid PLL further includes an analog controlled loop that receives the reference input signal and the output signal of the hybrid PLL, and generates an output voltage. The hybrid PLL also includes a hybrid oscillator. An oscillator controller of the digital controlled loop controls the hybrid oscillator using the digital tuning word and disables the analog controlled loop during a frequency tracking operation mode of the hybrid PLL. The oscillator controller enables the analog controlled loop to control the hybrid oscillator during the phase tracking operation mode of the hybrid PLL.

Abstract: A biologically sensitive field effect transistor includes a substrate, a first control gate and a second control gate. The substrate has a first side and a second side opposite to the first side, a source region and a drain region. The first control gate is disposed on the first side of the substrate. The second control gate is disposed on the second side of the substrate. The second control gate includes a sensing film disposed on the second side of the substrate. A voltage biasing between the source region and the second control gate is smaller than a threshold voltage of the second control gate.

Abstract: Circuits and methods for performing a clock and data recovery are disclosed. In one example, a clock and data recovery circuit is disclosed. The circuit includes a third order digital filter, e.g. a finite state machine (FSM) that includes three accumulators connected in series. Among the three accumulators, a first accumulator receives an input phase code representing a phase timing difference between a data signal and a clock signal at each FSM cycle and accumulates input phase codes for different FSM cycles to generate a first order phase code at each FSM cycle; a second accumulator accumulates the input phase codes and first order phase codes for different FSM cycles to generate a second order phase code at each FSM cycle; and a third accumulator accumulates the input phase codes and second order phase codes for different FSM cycles to generate a third order phase code at each FSM cycle.

Abstract: Circuits and methods for performing a clock and data recovery are disclosed. In one example, a clock and data recovery circuit is disclosed. The circuit includes a third order digital filter, e.g. a finite state machine (FSM) that includes three accumulators connected in series. Among the three accumulators, a first accumulator receives an input phase code representing a phase timing difference between a data signal and a clock signal at each FSM cycle and accumulates input phase codes for different FSM cycles to generate a first order phase code at each FSM cycle; a second accumulator accumulates the input phase codes and first order phase codes for different FSM cycles to generate a second order phase code at each FSM cycle; and a third accumulator accumulates the input phase codes and second order phase codes for different FSM cycles to generate a third order phase code at each FSM cycle.

Abstract: A semiconductor device includes a circuit layer and a nanopore layer. The nanopore layer is formed on the circuit layer and is formed with a pore therethrough. The circuit layer includes a circuit unit configured to drive a biomolecule through the pore and to detect a current associated with a resistance of the nanopore layer, whereby a characteristic of the biomolecule can be determined using the currents detected by the circuit unit.

Abstract: A biologically sensitive field effect transistor includes a substrate, a first control gate and a second control gate. The substrate has a first side and a second side opposite to the first side, a source region and a drain region. The first control gate is disposed on the first side of the substrate. The second control gate is disposed on the second side of the substrate. The second control gate includes a sensing film disposed on the second side of the substrate. A voltage biasing between the source region and the second control gate is smaller than a threshold voltage of the second control gate.