Abstract: Methods and apparatus for delaying a clock signal for a multiple-data-rate interface. An apparatus provides an integrated circuit including a frequency divider configured to receive a first clock signal and a first variable-delay block configured to receive an output from the frequency divider. Also included is a phase detector configured to receive the first clock signal and an output from the first variable-delay block, and an up/down counter configured to receive an output from the phase detector. A second variable-delay block is configured to receive a second clock signal and a plurality of flip-flops are configured to receive an output from the second variable-delay block. The first variable-delay block and the second variable-delay block are configured to receive an output from the up/down counter.

Abstract: An input buffer circuit has a plurality of selectively enabled differential amplifier circuits, where each differential amplifier is configured for compatibility with a particular differential I/O standard and its corresponding input operating range. For example, the input buffer may have two differential amplifiers suitable for receiving LVDS differential input signals over a wide input operating range, and another differential amplifier suitable for receiving the PCML differential input signals. One or more control signals are provided to the input buffer, e.g., programmably, to selectively enable the required differential amplifier(s) for a given I/O standard.

Abstract: An input buffer circuit has a plurality of selectively enabled differential amplifier circuits, where each differential amplifier is configured for compatibility with a particular differential I/O standard and its corresponding input operating range. For example, the input buffer may have two differential amplifiers suitable for receiving LVDS differential input signals over a wide input operating range, and another differential amplifier suitable for receiving the PCML differential input signals. One or more control signals are provided to the input buffer, e.g., programmably, to selectively enable the required differential amplifier(s) for a given I/O standard.

Abstract: The present invention is directed to reducing errors due to floating values introduced during tristate and contention when modeling a register in RTL. In one embodiment, the floating values are replaced by predetermined desired values corresponding to the floating values which are both stored in a lookup table. In another embodiment, when a floating value is detected, that value is ignored and the previous clock value is retained.

Abstract: Circuits, methods, and apparatus that provide output drivers that consume relatively little integrated circuit area and provide fast output switching. An exemplary embodiment provides an output driver including pull-up and pull-down devices, each device driven by a pre-driver stage. The pre-driver for the pull-down device is supplied from an auxiliary power supply, which has a higher voltage than the supply seen by the pull-up device. The pre-driver for the pull-down is biased by a voltage that tracks the higher of the auxiliary and output supplies. In some embodiments, the output driver may be part of an input/output cell. In that case, the well for the pull-up device is biased by a voltage that tracks the highest of the output supply and input received voltage, while the pull-up predriver circuit bias is the higher between the auxiliary and output supplies and the input received voltage.

Abstract: Techniques are provided for controlling an on-chip termination resistance in an input or output (IO) buffer using calibration circuits. Each calibration circuit monitors the voltage between an external resistor and a group of on-chip transistors. When the effective resistance of the group of transistors matches the external resistance, the calibration circuit causes the effective resistance of drive transistors in the IO buffer to match the effective resistance of the group of on-chip transistors.

Abstract: Techniques are provided for controlling an on-chip termination resistance in an input or output (IO) buffer using a calibration circuit. The calibration circuit monitors the voltage between an external resistor and a group of on-chip transistors. When voltage between the external resistor and the group of transistors is within a selected range, the calibration circuit causes the effective resistance of the transistors to match the resistance of the external resistor as closely as possible. The calibration circuit enables another set of transistors in the IO buffer so that the effective on resistance of the transistors in the IO buffer closely match the resistance of the external resistor.

Abstract: An input buffer circuit has a plurality of selectively enabled differential amplifier circuits, where each differential amplifier is configured for compatibility with a particular differential I/O standard and its corresponding input operating range. For example, the input buffer may have two differential amplifiers suitable for receiving LVDS differential input signals over a wide input operating range, and another differential amplifier suitable for receiving the PCML differential input signals. One or more control signals are provided to the input buffer, e.g., programmably, to selectively enable the required differential amplifier(s) for a given I/O standard.

Abstract: Circuits and methods are described for producing a DLL clock signal with adjustable phase shift using a processed control signal. In one embodiment of the invention, a DLL circuit is provided that includes a main and smaller variable delay circuits, a phase detector and an up down counter that provides a main control signal to adjust the delay by the main variable delay circuit. When the DLL circuit is locked, an arithmetic logic unit (ALU) produces a processed control signal based on the main control signal, an ALU control signal and an offset control signal, and the processed control signal is provided to the smaller variable delay circuit. By adjusting the ALU control and offset control signals, the phase shift introduced on the DLL control signal by the smaller variable delay circuit can be adjusted. In another embodiment of the invention, a second up down counter is used in place of an ALU for providing a dynamically adjustable phase shift in accordance with the principles of the present invention.

Abstract: Phase comparators for use in loop circuits (i.e., DLL circuits and PLL circuits) are provided. The phase comparators include a phase detector for comparing a reference clock signal and a feedback signal derived from the loop circuit generated internal clock signal. The phase comparators also include a low-pass noise filter for filtering out erroneously detected phase differences between the reference clock signal and the feedback signal by requiring a certain net number of leading or lagging detections before the compensation circuitry of the loop circuit (i.e., the controlled delay line in a DLL circuit or the controlled oscillator in a PLL circuit) is adjusted. The number of net measurements required before these adjustments take place depends on a programmable bandwidth signal provided to the phase comparator.

Abstract: Methods and apparatus for delaying a clock signal for a multiple-data-rate interface. An apparatus provides an integrated circuit including a frequency divider configured to receive a first clock signal and a first variable-delay block configured to receive an output from the frequency divider. Also included is a phase detector configured to receive the first clock signal and an output from the first variable-delay block, and an up/down counter configured to receive an output from the phase detector. A second variable-delay block is configured to receive a second clock signal and a plurality of flip-flops are configured to receive an output from the second variable-delay block. The first variable-delay block and the second variable-delay block are configured to receive an output from the up/down counter.

Abstract: A supply voltage detection circuit determines when the voltage for any one of the power supply signals received by an integrated circuit device is below its steady state level, as may occur during a hot socket condition when the device is inserted in or removed from a powered-on system. A first detection circuit determines when the first supply voltage level is below its steady state level, and a second detection circuit determines when the second supply voltage level is below its steady state level. A logic circuit provides a detected condition signal that disables current flow through an input/output terminal associated with the supply voltage detection circuit. The circuit is able to rapidly detect hot socket conditions for a wide range of power supply signal levels, including low supply signal levels, while limiting leakage current effects.

Abstract: A programmable I/O element for an I/O terminal of a logic array is suitable for operating according to high speed I/O modes such as double data rate and zero bus turnaround. The I/O element may include an input block with two registers for registering input signals from the terminal upon alternate clock edges. In addition or alternatively, it may include an output block with two registers that separately register output signals from the array on the same clock edge and a multiplexer that alternately outputs those signals. For bidirectional terminals, the multiplexer output is connectable to the I/O terminal via an output buffer, and an output enable block provides an enable signal to a gating input of the output buffer. Programmable delays may be included in the input, output, and output enable paths, in particular to provide a slower turn-on time than turn-off time for the output buffer.

Abstract: Circuits and methods are described for producing a DLL clock signal with adjustable phase shift using a processed control signal. In one embodiment of the invention, a DLL circuit is provided that includes a main and smaller variable delay circuits, a phase detector and an up down counter that provides a main control signal to adjust the delay by the main variable delay circuit. When the DLL circuit is locked, an arithmetic logic unit (ALU) produces a processed control signal based on the main control signal, an ALU control signal and an offset control signal, and the processed control signal is provided to the smaller variable delay circuit. By adjusting the ALU control and offset control signals, the phase shift introduced on the DLL control signal by the smaller variable delay circuit can be adjusted. In another embodiment of the invention, a second up down counter is used in place of an ALU for providing a dynamically adjustable phase shift in accordance with the principles of the present invention.

Abstract: Circuits, methods, and apparatus that provide output drivers that consume relatively little integrated circuit area and provide fast output switching. An exemplary embodiment provides an output driver including pull-up and pull-down devices, each device driven by a pre-driver stage. The pre-driver for the pull-down device is supplied from an auxiliary power supply, which has a higher voltage than the supply seen by the pull-up device. The pre-driver for the pull-down is biased by a voltage that tracks the higher of the auxiliary and output supplies. In some embodiments, the output driver may be part of an input/output cell. In that case, the well for the pull-up device is biased by a voltage that tracks the highest of the output supply and input received voltage, while the pull-up predriver circuit bias is the higher between the auxiliary and output supplies and the input received voltage.

Abstract: Phase comparators for use in loop circuits (i.e., DLL circuits and PLL circuits) are provided. The phase comparators include a phase detector for comparing a reference clock signal and a feedback signal derived from the loop circuit generated internal clock signal. The phase comparators also include a low-pass noise filter for filtering out erroneously detected phase differences between the reference clock signal and the feedback signal by requiring a certain net number of leading or lagging detections before the compensation circuitry of the loop circuit (i.e., the controlled delay line in a DLL circuit or the controlled oscillator in a PLL circuit) is adjusted. The number of net measurements required before these adjustments take place depends on a programmable bandwidth signal provided to the phase comparator.

Abstract: Phase comparators for use in loop circuits (i.e., DLL circuits and PLL circuits) are provided. The phase comparators include a phase detector for comparing a reference clock signal and a feedback signal derived from the loop circuit generated internal clock signal. The phase comparators also include a low-pass noise filter for filtering out erroneously detected phase differences between the reference clock signal and the feedback signal by requiring a certain net number of leading or lagging detections before the compensation circuitry of the loop circuit (i.e., the controlled delay line in a DLL circuit or the controlled oscillator in a PLL circuit) is adjusted. The number of net measurements required before these adjustments take place depends on a programmable bandwidth signal provided to the phase comparator.

Abstract: Circuits, methods, and apparatus for protecting devices in an output stage from over-voltage conditions caused by high supply and input voltages. Embodiments provide over-voltage protection that operates over a range of voltage levels, and that can be optimized for performance at different voltage levels. An exemplary embodiment of the present invention uses stacked devices to protect n and p-channel output devices from excess supply and input voltages. These stacked devices are biased by voltages received at their gates. These gate voltages vary as a function of supply voltage to maintain performance. Other embodiments of the present invention provide a body bias switch that generates a bias for the bulk of p-channel output devices. This bias tracks the higher of a supply or input voltage, such that parasitic drain-to-bulk diodes do not conduct. A switch may be provided that shorts the bulk connection to VCC under appropriate conditions.

Abstract: A supply voltage detection circuit determines when the voltage for any one of the power supply signals received by an integrated circuit device is below its steady state level, as may occur during a hot socket condition when the device is inserted in or removed from a powered-on system. A first detection circuit determines when the first supply voltage level is below its steady state level, and a second detection circuit determines when the second supply voltage level is below its steady state level. A logic circuit provides a detected condition signal that disables current flow through an input/output terminal associated with the supply voltage detection circuit. The circuit is able to rapidly detect hot socket conditions for a wide range of power supply signal levels, including low supply signal levels, while limiting leakage current effects.

Abstract: A programmable I/O element for an I/O terminal of a logic array is suitable for operating according to high speed I/O modes such as double data rate and zero bus turnaround. The I/O element may include an input block with two registers for registering input signals from the terminal upon alternate clock edges. In addition or alternatively, it may include an output block with two registers that separately register output signals from the array on the same clock edge and a multiplexer that alternately outputs those signals. For bidirectional terminals, the multiplexer output is connectable to the I/O terminal via an output buffer, and an output enable block provides an enable signal to a gating input of the output buffer. Programmable delays may be included in the input, output, and output enable paths, in particular to provide a slower turn-on time than turn-off time for the output buffer.