Abstract: A set of encoders within a transmitter (TX) physical layer (PHY) encode incoming data using a predefined encoder scheme by translating multiple data segments into a set of balanced bit sequences. Each data segment comprises a first number of bits and each balanced bit sequence comprises a second number of bits. A data striping component distributes the set of balanced bit sequences to a set of serializers by routing bits from particular bit positions in each balanced bit sequence to a corresponding serializer. The set of serializers generates serialized data based on the set of balanced bit sequences.

Abstract: Various embodiments described herein provide a multiple injection lock ring-based PI that can inject a plurality of clock signals, of different phases, at injection points disposed along the ring chain of the PI and lock phase to those received clock signals (injected clock signals). For instance, an embodiment described herein may provide a multiple injection lock ring-based PI that permits double injection, triple injection, or the like, of clock signals external into the PI.

Abstract: Aspects of the present disclosure include a dual path phase locked loop (PLL) circuit with a switched capacitor filter topology along with systems, method, devices, and other circuits related thereto. The dual path PLL circuit includes an integral path and a proportional path. Both the integral path and proportional path include a charge pump and a loop filter. The outputs of a phase frequency detector (PFD) are sent to both charge pumps. The output of the integral path charge pump is connected to a capacitor, and the voltage on capacitor is used as the integral path control voltage for a voltage-controlled oscillator (VCO). A switched capacitor network is connected to the output of the proportional path charge pump and used to generate the proportional path control voltage for the VCO. Together, the two control voltages dictate the VCO's output frequency.

Abstract: Aspects of the present disclosure include systems, methods, devices, and circuits for fast settling of a bias node. Consistent with some embodiments, a bias circuit may include a successive-approximation-register-analog-to-digital converter (SAR-ADC) based settling loop configured to perform a fast settling process for a heavily loaded bias node. The SAR-ADC based loop performs a SAR-ADC process that includes measuring a reference signal to determine a number of cells in a capacitor array that are involved in a charge sharing process while simultaneously completing the settling process for the bias node.

Abstract: A system and a method for detecting a low-frequency periodic signal (LFPS) include at least one comparator performing a threshold comparison on an analog input signal over a period of time. A sampling circuit generates digital signals by sampling an output of the at least one comparator. A digital detection circuit applies a set of detection rules to the digital signals. The detection rules are configured to detect a presence or an absence of an LFPS based on predefined criteria concerning characteristics of the digital signals.

Abstract: Embodiments relate to systems, methods and computer readable media to enable design and creation of receiver circuitry One embodiment is a receiver apparatus comprising a first resistor connected to a first receiver input, a first N-type metal oxide semiconductor (NMOS) field effect transistor (FET), a second NMOS FET, a trans-impedance amplifier wherein an input terminal of the trans-impedance amplifier is connected to a drain terminal of the second NMOS FET, and a complementary metal oxide semiconductor (CMOS) logic gate. Additional embodiments including other circuitry, associated methods, and media comprising instructions associated with generation of circuit design files are also described.

Abstract: Aspects of the present disclosure include a frequency-to-current (F2I) circuit and systems, methods, devices, and other circuits related thereto. The F2I circuit is implemented with a delta-modulator-based control loop to settle and maintain an operating point on a bias node. The control loop provides an integral of an output of a comparator, and the comparator compares it to a self-built voltage reference. Upon powering on the circuit, an integrator in the control loop starts to integrate the charge on both a bias voltage and an internal voltage to provide a settling process for the internal voltage to approximate the reference voltage and for the bias voltage to approximate a predetermined operating point of the bias node. After the circuit has settled, the comparator's output charge toggles and the internal voltage and bias voltage become sawtooth-like waveforms at the reference voltage and operating points, respectively.

Abstract: Embodiments relate to systems, methods and computer readable media to enable design and creation of memory driver circuitry using a voltage translation capacitor. One embodiment is high speed level translation memory driver apparatus comprising a plurality of field effect transistors (FETs), complementary metal oxide semiconductor (CMOS) logic gates to drive the FETs, and a voltage translation capacitor with a first terminal of the voltage translation capacitor connected to an output of a second CMOS logic gate and a second terminal of the voltage translation capacitor connected to a gate terminal of a first P-type FET. Additional embodiments including other circuitry, associated methods, and media comprising instructions associated with generation of circuit design files are also described.

Abstract: The present disclosure relates to a method for analog-to-digital converter based decision feedback equalization. The method may include providing an integrated circuit including a SerDes circuitry having a transmit circuitry and a receiver circuitry. The method may further include receiving a high-speed data stream at the receiver circuitry and converting the high-speed data stream to a digital signal using a successive approximation analog-to-digital converter. The method may also include providing the digital signal to a digital decision feedback equalization circuitry via the successive approximation analog-to-digital converter.

Abstract: The present disclosure relates to a method for Analog-to-Digital Converter Based Decision Feedback Equalization. The method may include providing an integrated circuit including a SERDES circuitry having a transmit circuitry and a receiver circuitry and receiving a high-speed data stream at the receiver circuitry. The method may also include converting the high-speed data stream to a digital signal using a successive approximation analog-to-digital converter and providing the digital signal to a digital decision feedback equalization circuitry via the successive approximation analog-to-digital converter. The method may also include generating an output signal at a phase locked loop and receiving the output signal at a multi-loop clock and data recovery circuitry.

Abstract: The present disclosure relates to a method, apparatus, and system for locking a phase locked loop (PLL). The method may include receiving a reference signal at a phase locked loop (PLL) circuitry having a first PLL circuitry and a second PLL circuitry. The first PLL circuitry may include a fixed frequency oscillator. The method may further include adjusting a division ratio using, at least in part, a fractional divider circuitry in communication with the fixed frequency oscillator, to generate a feedback signal having a substantially equal frequency and a substantially equal phase in relation to a reference frequency. The method may also include receiving the feedback signal and the reference frequency at a phase detector.