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 circuit having a tracking loop and a realignment loop is disclosed. The circuit includes: a phase frequency detector (PFD) module for comparing a phase difference of a first input signal and a second input signal; a pump module for converting PFD phase error to charge, wherein the pump module further comprises a low pass filter (LPF); an adjustable realignment module for adjusting a realignment strength, the adjustable realignment module receives a first plurality of inputs from the PFD module, the adjustable realignment module transmits a second plurality of outputs to the pump module; and a ring oscillator unit, the ring oscillator unit receives a first input from the pump module and a second input from the adjustable realignment module, and based on the first and second inputs produces a feedback signal.

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: A micro-electro mechanical system (MEMS) humidity sensor includes a first substrate, a second substrate and a sensing structure. The second substrate is substantially parallel to the first substrate. The sensing structure is between the first substrate and the second substrate, and bonded to a portion of the first substrate and a portion of the second substrate, in which the second substrate includes a conductive layer facing the sensing structure, and a first space between the first substrate and the sensing structure is communicated with or isolated from outside, and a second space between the conductive layer and the sensing structure is communicated with an atmosphere, and the sensing structure, the second space and the conductive layer constitute a capacitor configured to measure permittivity of the atmosphere, and humidity of the atmosphere is derived from the permittivity of the atmosphere, pressure of the atmosphere and temperature.

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: A fluidic cartridge and methods of operation are described. The fluidic cartridge includes a substrate having a plurality of contact pads designed to electrically couple with an analyzer, a semiconductor chip having a sensor array, and a reference electrode. The fluidic cartridge includes a first fluidic channel having an inlet and coupled to a second fluidic channel, the second fluidic channel being aligned such that the sensor array and the reference electrode are disposed within the second fluidic channel. A first plug is disposed at the first inlet. The first plug includes a compliant material configured to be punctured by a capillary without leaking fluid through the first plug.

Abstract: An on-chip heater in a concentric rings configuration having non-uniform spacing between heating elements provides improved radial temperature uniformity and low power consumption compared to circular or square heating elements. On-chip heaters are suitable for integration and use with on-chip sensors that require tight temperature control.

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: Biosensor devices and methods of forming the same are provided. A cavity is formed in a substrate and is configured to receive one or more charged molecules. A transistor is formed in the substrate and includes a source region, a drain region, and a channel region that are spatially separated from the cavity in a lateral direction. A gate of the transistor is disposed below the cavity and extends between the cavity and the source, drain, and channel regions. A voltage potential of the gate is based on a number of the charged molecules in the cavity.

Abstract: A micro-electro mechanical system (MEMS) humidity sensor includes a first substrate, a second substrate and a sensing structure. The second substrate is substantially parallel to the first substrate. The sensing structure is between the first substrate and the second substrate, and bonded to a portion of the first substrate and a portion of the second substrate, in which the second substrate includes a conductive layer facing the sensing structure, and a first space between the first substrate and the sensing structure is communicated with or isolated from outside, and a second space between the conductive layer and the sensing structure is communicated with an atmosphere, and the sensing structure, the second space and the conductive layer constitute a capacitor configured to measure permittivity of the atmosphere, and humidity of the atmosphere is derived from the permittivity of the atmosphere, pressure of the atmosphere and temperature.

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: An out-of-band (OOB) detection circuit includes: a positive input node; a negative input node; a resistive circuit comprising a first resistor coupled between a first supply node and a first node, a variable resistor coupled between the first node and a second node, and a second resistor coupled between the second node and a ground; a first comparator configured to compare a difference between a positive input signal received at the positive input node and a negative input signal received at the negative input node against a positive threshold value, and a second comparator configured to compare the difference between the positive input signal received at the positive input node and the negative input signal received at the negative input node against a negative threshold value.

Abstract: Methods and apparatus are described for synchronously stepping at least one of a data phase interpolator (PI) code or a crossing PI code in a clock and data recovery (CDR) circuit until one or more preset criteria are satisfied. One example method generally includes determining that a condition has been met; based on the determination, stepping, in a CDR circuit, at least one of a data PI code or a crossing PI code for each cycle of a clock; stopping the stepping based on one or more criteria to generate a predetermined state of the data PI code and the crossing PI code, wherein the predetermined state comprises an offset between the data PI code and the crossing PI code; receiving a data stream; and performing clock and data recovery on the data stream based on the offset between the data PI code and the crossing PI code.

Abstract: A data receiver implemented in an integrated circuit is described. The data receiver comprises an input receiving a data signal; a first equalization circuit coupled to receive the data signal, wherein the first equalization circuit is used to receive the data of the data signal; and a second equalization circuit coupled to receive the data signal, wherein the second equalization circuit is used to adjust a clock phase offset.

Abstract: In one embodiment, a differential amplifier is provided. Gates of a first differential pair of transistors, of a first conductivity type, and a second pair or transistors, of a second conductivity type are coupled to first and second input terminals of the differential amplifier. A first pair of adjustable current sources are configured to adjust respective tail currents of the first differential pair of transistors in response to a first bias current control signal. A second pair of adjustable current sources are configured to adjust respective tail currents of the second differential pair of transistors in response to the first bias current control signal. A third pair of adjustable current sources are configured to adjust respective currents through the second differential pair of transistors in response to a second bias current control signal.

Abstract: In one embodiment of the invention, a circuit arrangement is provided. The circuit arrangement includes a plurality of differential amplifiers, coupled in parallel, including at least a first differential amplifier and a second differential amplifier. Each differential amplifier includes an adjustable current control circuit coupled to limit a tail current passing through the differential amplifier.

Abstract: A data receiver implemented in an integrated circuit is described. The data receiver comprises an input receiving a data signal; a first equalization circuit coupled to receive the data signal, wherein the first equalization circuit is used to receive the data of the data signal; and a second equalization circuit coupled to receive the data signal, wherein the second equalization circuit is used to adjust a clock phase offset.

Abstract: A receiver in an integrated circuit device is described. The circuit comprises a receiver having a clock and data recovery circuit coupled to receive data signals modulated with a transmitter clock signal; and a clock generator coupled to receive an output of the clock and data recovery circuit, the clock generator providing a modulated reference clock to the receiver, based upon a reference clock signal which is independent of the transmitter clock signal; wherein the modulated reference clock provided to the receiver is synchronized with the transmitter clock signal. A method of receiving data in an integrated circuit is also described.

Abstract: In an apparatus, a receiver includes a clock data recovery module to provide a dense distribution of waveform edges across an adjustment range, and an eye scan circuit to obtain samples at a first sample position and a second sample position to provide an error count for a sample count for the samples. An eye scan module, coupled to the receiver, is configured to: scan for the samples at the first sample position of a first type for each of a plurality of sample positions of a second type to obtain an error count for a sample count for each of the plurality of sample positions; locate a threshold BER from the scan; determine an amount and a direction of a sample offset at the threshold BER from a reference location; and adjust either the first sample position or the second sample position responsive to the amount and the direction.

Abstract: In one embodiment, a differential amplifier is provided. Gates of a first differential pair of transistors, of a first conductivity type, and a second pair or transistors, of a second conductivity type are coupled to first and second input terminals of the differential amplifier. A first pair of adjustable current sources are configured to adjust respective tail currents of the first differential pair of transistors in response to a first bias current control signal. A second pair of adjustable current sources are configured to adjust respective tail currents of the second differential pair of transistors in response to the first bias current control signal. A third pair of adjustable current sources are configured to adjust respective currents through the second differential pair of transistors in response to a second bias current control signal.