Abstract: In one embodiment, an integrated circuit current mirror circuit is disclosed. The integrated circuit current mirror circuit includes a reference circuit, an output circuit and a mode selector circuit. The reference circuit includes an input terminal that receives a reference current. The output circuit generates an output current that is proportional to the reference current. The output circuit is coupled to a load circuit. The output current is provided to the load circuit. The mode selector circuit is coupled to the reference circuit and the output circuit. The mode selector circuit receives a plurality of mode control signals having different voltage levels. The mode selector circuit selects one of the mode control signals. The selected mode control signal is routed to the reference circuit and the output circuit to place the current mirror circuit in a desired mode.

Abstract: Systems and methods are provided for adjusting gain of a receiver. Adaptation circuitry is operable to identify, based on a matrix representation of a receiver's output generated from horizontal and vertical sweeps of the receiver's output, an eye opening of the receiver's output. The adaptation circuitry is also operable to determine whether a size of the eye opening needs to be changed. When it is determined that the size of the eye opening needs to be changed, the adaptation circuitry is operable to generate a digital signal to change a gain setting of the receiver. When the signal at the receiver's output is under-equalized, the AC gain of the receiver is increased. When the signal at the receiver's output is over-equalized, the AC gain of the receiver is decreased.

Abstract: A driver circuit drives data to an output based on an input data signal in a transmission mode. The driver circuit includes transistors. A comparator generates a comparison output in a calibration mode based on a reference signal and a signal at the output of the driver circuit. A calibration control circuit adjusts an equivalent resistance of the transistors in the driver circuit based on the comparison output in the calibration mode. The equivalent resistance of the transistors in the driver circuit can be adjusted to support the transmission of data according to multiple different data transmission protocols using transmission links having different characteristic impedances. The equivalent resistance of the transistors in the driver circuit can also be adjusted to compensate for resistance in the package routing conductors and/or to compensate for parasitic resistance.

Abstract: One embodiment relates to an integrated circuit including multiple PMA modules, a plurality of multiple-purpose PLLs, multiple reference clock signal inputs, and a programmable clock network. Each PMA module includes multiple CDR circuits, receives multiple serial data signals, and outputs data from those signals in parallel form. The programmable clock network allows the reference clock signals to be selectively shared by the PMA modules and the multiple-purpose PLLs. Another embodiment relates to a method of providing clock signals for multiple purposes in an integrated circuit. Clock signals are generated by a plurality of multiple-purpose PLLs and are selectively distributed to PMA modules arranged at a side of the integrated circuit and to logic circuitry arranged in a core section of the integrated circuit. The clock signals are used by circuitry in the PMA modules for supporting a plurality of data communications channels. Other embodiments and features are also disclosed.

Abstract: A pre-emphasis circuitry that includes (1) a pre-emphasis voltage variation compensation (PVVC) engine having a transition detection circuit and (2) a compensation driver coupled to the PVVC engine is described. In one embodiment, the compensation driver reduces data dependent voltage variations in pre-emphasis provided by the pre-emphasis circuitry. In one embodiment, in response to a predetermined data pattern detected by the PVVC engine, the compensation driver provides an additional boost to performance critical capacitive nodes of the pre-emphasis circuitry. The additional boost causes the performance critical capacitive nodes to charge or discharge more rapidly. In one embodiment, the PVVC engine further includes a digital finite impulse response (FIR) filter coupled to the transition detection circuit.

Abstract: A driver circuit includes unit slice circuits that generate an output data signal based on an input data signal. The driver circuit reduces a voltage swing of the output data signal without changing a termination resistance of the driver circuit in response to decreasing a number of the unit slice circuits that generate the output data signal based on the input data signal.

Abstract: A circuit includes a first amplifier circuit and a second amplifier circuit. The second amplifier circuit includes an input coupled to an output of the first amplifier circuit. A pass gate circuit is coupled between first and second inputs of the first amplifier circuit. The pass gate circuit is on during calibration of the second amplifier circuit to short together signals at the first and the second inputs of the first amplifier circuit. The pass gate circuit is off during a normal mode of the first and the second amplifier circuits.

Abstract: A circuit includes a phase detector circuit and a data detection circuit. The phase detector circuit generates first and second phase detection signals based on a data signal and a periodic signal. The data detection circuit includes logic circuitry that generates a logic signal based on the first and second phase detection signals. The data detection circuit also includes a plurality of delay elements that generate a series of delayed detection signals based on the logic signal. The data detection circuit generates a data detection signal indicating when the data signal contains data based on the series of delayed detection signals.

Abstract: Integrated circuits with high-speed communications capabilities are provided. Such types of integrated circuits may include clock data recovery (CDR) circuitry. The CDR circuitry may receive incoming data and may generate multiple clock signals that are used to latch the incoming data. The CDR circuitry may include data latching circuitry for separately latching even and odd data bits in alternating clock cycles. In particular, the data latching circuitry may be controlled using first, second, third, and fourth clock signals having different respective phase settings. The first and second clock signals may be used to capture even and odd data bits, respectively. The third and fourth clock signals may be used to sample data near the transition between the even and odd data bits. The phase of the first and second clock signals may be dynamically adjusted. The phase setting that yields the optimal link performance may be selected for normal operation.

Abstract: Systems and methods are provided for adjusting gain of a receiver. Adaptation circuitry is operable to identify, based on a matrix representation of a receiver's output generated from horizontal and vertical sweeps of the receiver's output, an eye opening of the receiver's output. The adaptation circuitry is also operable to determine whether a size of the eye opening needs to be changed. When it is determined that the size of the eye opening needs to be changed, the adaptation circuitry is operable to generate a digital signal to change a gain setting of the receiver. When the signal at the receiver's output is under-equalized, the AC gain of the receiver is increased. When the signal at the receiver's output is over-equalized, the AC gain of the receiver is decreased.

Abstract: A voltage-mode differential driver is disclosed. The differential driver includes two driver arms, each driver arm including a variable-impedance driver for driving a single-ended output signal. Each variable-impedance driver comprises multiple driver slices, where each driver slice includes a pre-driver circuit and a driver circuit. Advantageously, it has been determined that the disclosed voltage-mode driver design requires less power than conventional current-mode drivers. In one implementation, the disclosed voltage-mode driver design provides the capability of independently programming the delay of the two single-ended outputs so as to compensate for differential skew. Other embodiments and features are also disclosed.

Abstract: The present disclosure provides a floating-tap decision feedback equalization (DFE) circuit. In an exemplary implementation, the floating-tap DFE circuit may include a high-speed shift register, a deserializer and data selector, a bypass deserializer, a high-speed multiplexer and a tap generation circuit. In one aspect of the invention, the floating-tap DFE circuit may advantageously cover an entire tap range beyond a fixed tap range without holes over a range of data rates. Other embodiments, aspects and features are also disclosed.

Abstract: Systems and methods are provided for adjusting gain of a receiver. Adaptation circuitry is operable to identify, based on a matrix representation of a receiver's output generated from horizontal and vertical sweeps of the receiver's output, an eye opening of the receiver's output. The adaptation circuitry is also operable to determine whether a size of the eye opening needs to be changed. When it is determined that the size of the eye opening needs to be changed, the adaptation circuitry is operable to generate a digital signal to change a gain setting of the receiver. When the signal at the receiver's output is under-equalized, the AC gain of the receiver is increased. When the signal at the receiver's output is over-equalized, the AC gain of the receiver is decreased.

Abstract: In a programmable logic device with a number of different types of serial interfaces, different power supply filtering schemes are applied to different interfaces. For interfaces operating at the lowest data rates—e.g., 1 Gbps—circuit-board level filtering including one or more decoupling capacitors may be provided. For interfaces operating at somewhat higher data rates—e.g., 3 Gbps—modest on-package filtering also may be provided, which may include power-island decoupling. For interfaces operating at still higher data rates—e.g., 6 Gbps—more substantial on-package filtering, including one or more on-package decoupling capacitors, also may be provided. For interfaces operating at the highest data rates—e.g., 10 Gbps—on-die filtering, which may include one or more on-die filtering or regulating networks, may be provided. The on-die regulators may be programmably bypassable allowing a user to trade off performance for power savings.

Abstract: A circuit includes phase detection, frequency adjustment, sampler, and control circuits. The phase detection circuit compares phases of first and second periodic signals to generate a control signal. The frequency adjustment circuit adjusts a frequency of the second periodic signal and a frequency of a third periodic signal based on the control signal. The sampler circuit samples a data signal to generate a sampled data signal in response to the third periodic signal. The control circuit adjusts the frequency of the third periodic signal based on the data signal changing from a first data rate to a second data rate while maintaining the frequency of the second periodic signal constant. The control circuit adjusts the frequency of the second periodic signal and the frequency of the third periodic signal based on the data signal changing from the second data rate to a third data rate.

Abstract: A voltage-mode differential driver is disclosed. The differential driver includes two driver arms, each driver arm including a variable-impedance driver for driving a single-ended output signal. Each variable-impedance driver comprises multiple driver slices, where each driver slice includes a pre-driver circuit and a driver circuit. Advantageously, it has been determined that the disclosed voltage-mode driver design requires less power than conventional current-mode drivers. In one implementation, the disclosed voltage-mode driver design provides the capability of independently programming the delay of the two single-ended outputs so as to compensate for differential skew. Other embodiments and features are also disclosed.

Abstract: A phase-locked loop circuit includes an oscillator circuit that generates a clock signal. The oscillator circuit has gears. Each of the gears of the oscillator circuit corresponds to a respective frequency range of the clock signal. A gear control circuit includes a regulator circuit that provides a supply voltage to the oscillator circuit. Each of the gears of the oscillator circuit corresponds to a different supply voltage provided by the regulator circuit. The regulator circuit varies the supply voltage to change a selected one of the gears of the oscillator circuit. The gear control circuit varies the supply voltage for one of the gears of the oscillator circuit to adjust a frequency range of that gear of the oscillator circuit.

Abstract: Systems and methods are provided for adjusting gain of a receiver. Adaptation circuitry is operable to identify, based on a matrix representation of a receiver's output generated from horizontal and vertical sweeps of the receiver's output, an eye opening of the receiver's output. The adaptation circuitry is also operable to determine whether a size of the eye opening needs to be changed. When it is determined that the size of the eye opening needs to be changed, the adaptation circuitry is operable to generate a digital signal to change a gain setting of the receiver. When the signal at the receiver's output is under-equalized, the AC gain of the receiver is increased. When the signal at the receiver's output is over-equalized, the AC gain of the receiver is decreased.

Abstract: Systems and methods are provided for reducing jitter due to power supply noise in an integrated circuit by drawing additional current. The additional current causes the total current to generally have a frequency higher than a resonant frequency of the integrated circuit and/or a power distribution network of the integrated circuit. In one example, a power distribution network may supply power to components of an integrated circuit and data driver circuitry may draw first current to drive a data signal. Compensation circuitry may draw second current at times when the data driver circuitry is not drawing the first current, thereby causing a net of the first and second current to be higher than a resonant frequency range of the integrated circuit device and/or a component of the integrated circuit device (e.g., the power distribution network).

Abstract: An integrated circuit (“IC”) may include clock and data recovery (“CDR”) circuitry for recovering data information from an input serial data signal. The CDR circuitry may include a reference clock loop and a data loop. A retimed (recovered) data signal output by the CDR circuitry is monitored by other control circuitry on the IC for a communication change request contained in that signal. Responsive to such a request, the control circuitry can change an operating parameter of the CDR circuitry (e.g., a frequency division factor used in either of the above-mentioned loops). This can help the IC support communication protocols that employ auto-speed negotiation.