Abstract: A built-in, at-speed BERT is provided that may be part of high-speed serial interface circuitry implemented on an integrated circuit. The built-in, at-speed BERT takes advantage of an existing clock data recovery (CDR) dual-loop architecture and built-in self test (BIST) circuitry. The built-in, at-speed BERT provides a low-cost solution for production testing of high-speed serial links, facilitating jitter analysis and evaluation of pre-emphasis and equalization performance. This further allows adaptation of pre-emphasis and equalization.

Abstract: Equalization circuitry that includes an analog equalizer and a decision feedback equalizer (DFE) is provided for high-speed backplane data communication. The analog equalizer reduces the number of taps that are required by the DFE, which lessens the error propagation of the DFE. Furthermore, the DFE includes a summing circuit and flip-flop circuitry. The flip-flop circuitry may be used as part of a phase detector by clock and data recovery circuitry. The summing circuit may further be embedded into the flip-flop circuitry to reduce the feedback path delay, thereby allowing for higher speed operation. The DFE may be extended to multiple taps by including additional flip-flops.

Abstract: Systems and methods for accurately and quickly simulating link performance of a transceiver operating with any given transmission medium are provided. Accurate and quick link simulations may be provided using a link simulation platform. The link simulation platform may simulate link performance using transceiver behavioral models (e.g., transmitter and receiver behavioral models) that incorporate silicon level parameters, which parameters enable the behavioral models to substantially emulate the actual behavior of the transceiver portions of the link.

Abstract: Switching and repeating applications using an impedance matched source follower improve performance of high speed links such as PCI Express, HDMI, DisplayPort and DVI by reducing attenuation and other degradation of high speed signals, including those with transmit pre-emphasis, by avoiding impedance discontinuities over process, voltage and temperature variations and by driving a broader range of loads, e.g., heavily capacitive loads. A circuit for switching or repeating signals on a single-ended or differential high speed link may comprise a source follower with input and output impedances matched to input and output transmission lines on the high speed link. The source follower is biased by a constant transconductance circuit, an external calibration circuit or other circuit to provide an essentially constant output impedance over process, voltage and temperature variations.

Abstract: A reduced power differential type termination circuit for use in SSTL, HSTL and other transmission line systems reduces power consumption. A differential type termination circuit may comprise first and second nodes for coupling, respectively, to first and second transmission lines; a first impedance coupled between the first transmission line and a third node; a second impedance coupled between the second transmission line and the third node; and a low direct current reference voltage generator for generating a reference voltage applied to the third node. The first and second transmission lines may transmit complimentary signals. The first and second impedances may be symmetric or asymmetric. The first impedance may match the second impedance. The first and second impedances may, respectively, match the impedances of the first and second transmission lines. The first and/or second impedances may include a bidirectional switch, such as a transmission gate, to enable and disable the termination circuit.

Abstract: Switching and repeating applications using an impedance matched source follower improve performance of high speed links such as PCI Express, HDMI, DisplayPort and DVI by reducing attenuation and other degradation of high speed signals, including those with transmit pre-emphasis, by avoiding impedance discontinuities over process, voltage and temperature variations and by driving a broader range of loads, e.g., heavily capacitive loads. A circuit for switching or repeating signals on a single-ended or differential high speed link may comprise a source follower with input and output impedances matched to input and output transmission lines on the high speed link. The source follower is biased by a constant transconductance circuit, an external calibration circuit or other circuit to provide an essentially constant output impedance over process, voltage and temperature variations.

Abstract: An integrated circuit (IC) includes a transmitter. The transmitter includes a pre-emphasis circuit. The pre-emphasis circuit pre-distorts an input signal by moving in time a sampling point of the input signal. The input signal is thus pre-distorted before transmission to a communication channel. The IC may optionally include a receiver. The receiver includes an equalization circuit. The equalization circuit equalizes a signal received from a communication channel by moving in time a sampling point of the signal received from the communication channel.

Abstract: A method and circuit for generating an adjustable delay signal is presented, wherein the delay can be linear and monotonic with high resolution delay steps. The circuit utilizes one or more serially coupled delay cells and a load cell. Each delay cell comprises an inverter, a nor-multiplexer, and a programmable capacitor, wherein a first control signal is used to control the operation of the nor-multiplexer and a second control signal is used to control capacitance of the programmable capacitor. Values of the first and the second control signals are selected based on any desired range of total delay time and any desired delay time for a specific application of the circuit.

Abstract: A reference clock receiver structure according to the invention is provided. The structure preferably includes an input buffer that is formed from a PMOS differentiated pair of transistors and a first supply voltage. The PMOS differential pair receives a pair of differential inputs, and produces a pair of differential outputs. The structure also includes a level shifter that is coupled to receive the pair of differential outputs from the input buffer to provide gain to the pair of differential outputs to form a gained pair of differential outputs. The level shifter that includes a second supply voltage. The second supply voltage may have a smaller magnitude than the first supply voltage. Finally, the structure includes a CMOS buffer that is coupled to receive the gained pair of differential outputs. The CMOS buffer boosts the gained pair of differential outputs and converts the gained differential pair outputs into a single signal.

Abstract: A dual-mode LVDS/CML transmitter allows a single circuit to operate as either an LVDS transmitter or a CML transmitter. The transmitter mode can be switched by activating or deactivating appropriate circuit elements, and changing the voltage or current produced by appropriate sources or sinks. This flexibility allows a single transmitter to operate well in both AC and DC coupling conditions, and facilitates interoperation with a greater variety of receivers.

Abstract: A clock data recovery loop that can be used over a wide range of data rates and maintain second-order behavior includes a nonlinear (e.g., Bang-Bang) phase detector, a charge pump, an RC loop filter, and signal generator (e.g., a voltage controlled oscillator (VCO)). At low data rates, the loop may be operated with the charge pump and loop filter with stable second-order behavior, with the resistor R of the loop filter serving as a proportional path. A separate proportional path is also provided that provides phase detector output directly to a control input of the VCO, while the resistor R of the loop filter is also bypassed. As increasing data rates give rise to third-order effects, the separate proportional path may be activated to maintain second-order behavior.

Abstract: Pre-emphasis circuitry and methods for signal transmission provide multiple levels of output signal amplification over one or more baud periods after an input signal transition. The multiple, gradually decreasing levels of output signal amplification reduce power consumption and better approximate the desired signal response.

Abstract: A received clock signal is aligned (“eye centered”) with a received data signal by recovering a separate clock from the data signal and comparing and aligning the received clock with the recovered clock by delaying one or both of the received clock and the received data as necessary. After the necessary delays are set, the comparison/alignment circuitry can be turned off, until the next time alignment is necessary, to conserve power. In a multiple channel system, any combination of each received data channel, the received clock, or individual branches of the received clock in each channel can be delayed as necessary. Each channel can have its own comparison/alignment circuitry so that all channels can be aligned simultaneously, or re-usable circuitry can be provided for connection sequentially to each channel where sequential alignment of the channels is fast enough.

Abstract: A dynamic frequency divider circuit with improved leakage tolerance supports a wide frequency range. During the evaluation phase, (1) the input signals can be prevented from changing states, (2) the leakage can be reduced, or (3) both can be implemented to generate the correct output signals. In a architecture-level approach, two dynamic flip-flops can be coupled together. In a circuit-level approach, the dynamic flip-flop can include (1) two additional clocked PMOS transistor added to the inputs of the dynamic flip-flop, or (2) two additional pull-up PMOS transistors to counteract the subthreshold leakage in the NMOS transistors.

Abstract: A reference clock receiver structure according to the invention is provided. The structure preferably includes an input buffer that is formed from a PMOS differentiated pair of transistors and a first supply voltage. The PMOS differential pair receives a pair of differential inputs, and produces a pair of differential outputs. The structure also includes a level shifter that is coupled to receive the pair of differential outputs from the input buffer to provide gain to the pair of differential outputs to form a gained pair of differential outputs. The level shifter that includes a second supply voltage. The second supply voltage may have a smaller magnitude than the first supply voltage. Finally, the structure includes a CMOS buffer that is coupled to receive the gained pair of differential outputs. The CMOS buffer boosts the gained pair of differential outputs and converts the gained differential pair outputs into a single signal.

Abstract: Voltage controlled oscillator (“VCO”) circuitry includes LC tank or ring VCO circuitry and frequency divider circuitry that divides the frequency output by the oscillator circuitry by a selectable integer factor that is at least 2 in the case of a ring oscillator or at least 4 in the case of an LC tank oscillator. This arrangement allows the oscillator circuitry to operate at frequencies that are higher than the desired final output frequencies, which has such advantages as reducing the size and power consumption of the oscillator circuitry, and allowing the circuitry as a whole to have a wide range of operating frequencies while reducing the frequency range over which the oscillator circuitry may be required to operate.

Abstract: An integrated circuit (IC) includes a ring oscillator. One may tune the ring oscillator by controlling a power supply of the ring oscillator. One may further tune ring oscillator by varying a capacitance of at least one varactor. Using the tuning techniques, one may tune the output frequency of the ring oscillator to a desired frequency.

Abstract: Charge pump circuitry is provided that is insensitive to charge sharing and current mismatch effects. The charge pump circuitry has an output node at which a charge pump output voltage is provided. A first current source charges the output node to increase the output voltage or a second current source discharge the output node to decrease the output voltage. The charge pump circuitry uses a unit-gain op-amp circuit to prevent charge sharing effects from affecting the output voltage when switching between discharging and charging operations. A low-pass filter is used to reduce feedback noise on the output node. A replica feedback circuit prevents current mismatch between the currents produced by the first and second current sources. The first and second current sources may be formed using programmable transistors that are adjusted by static control signals provided by programmable elements to further minimize current mismatch.

Abstract: A reference clock receiver structure according to the invention is provided. The structure preferably includes an input buffer that is formed from a PMOS differentiated pair of transistors and a first supply voltage. The PMOS differential pair receives a pair of differential inputs, and produces a pair of differential outputs. The structure also includes a level shifter that is coupled to receive the pair of differential outputs from the input buffer to provide gain to the pair of differential outputs to form a gained pair of differential outputs. The level shifter that includes a second supply voltage. The second supply voltage may have a smaller magnitude than the first supply voltage. Finally, the structure includes a CMOS buffer that is coupled to receive the gained pair of differential outputs. The CMOS buffer boosts the gained pair of differential outputs and converts the gained differential pair outputs into a single signal.

Abstract: Data transmitter circuitry on a programmable logic device (“PLD”) includes a plurality of channels of serializer circuitry, and a plurality of clock multiplier units (“CMUs”), each of which is associated with a respective subplurality of the serializer channels. Each CMU includes multiple reference clock signal sources, multiple phase-locked loop (“PLL”) circuits, and circuitry for allowing any PLL to get its reference input from any of the reference sources. Raw and centrally processed clock signals produced by each CMU are distributed to the serializer channels associated with that CMU and, at least in the case of the centrally processed signals, to the serializer channels associated with another CMU. The signal that controls release of parallel data to each serializer channel can be an output signal of that channel, or it can be an output signal of any CMU from which that channel can get a clock signal.