Abstract: Integrated circuits may include partial reconfiguration (PR) circuitry for reconfiguring a portion of a memory array. The PR circuitry may include a host circuit, a control circuit, an address register, and first, second, and third data registers. The host circuit may send a series of PR instructions to the control circuit. The control circuit may include a decompression circuit for decompressing compressed instructions, a decryption circuit for decrypting encrypted instructions, an error checking circuit for detecting errors in the instructions, and a logic circuit. The address register may select a desired frame. The selected frame may be loaded into the third data register. The contents of the third data register may be shifted into the first data register. The contents of the first data register may be modified according to a desired logic function using the logic circuit, shifted into the second data register, and written into the selected frame.

Abstract: Power-on-reset circuitry is provided for integrated circuits such as programmable logic device integrated circuits. The power-on-reset circuitry may use comparator-based trip point voltage detectors to monitor power supply voltages. The trip point detectors may use circuitry to produce trip point voltages from a bandgap reference voltage. Controller logic may process signals from the trip point detectors to produce a corresponding power-on-reset signal. The power-on-reset circuitry may contain a noise filter that suppresses noise from power supply voltage spikes. Normal operation of the power-on-reset circuitry may be blocked during testing. The power-on-reset circuitry may be disabled when the bandgap reference voltage has not reached a desired level. The power-on-reset circuitry may be sensitive or insensitive to the power-up sequence used by the power supply signals.

Abstract: Power-on-reset circuitry is provided for integrated circuits such as programmable logic device integrated circuits. The power-on-reset circuitry may use comparator-based trip point voltage detectors to monitor power supply voltages. The trip point detectors may use circuitry to produce trip point voltages from a bandgap reference voltage. Controller logic may process signals from the trip point detectors to produce a corresponding power-on-reset signal. The power-on-reset circuitry may contain a noise filter that suppresses noise from power supply voltage spikes. Normal operation of the power-on-reset circuitry may be blocked during testing. The power-on-reset circuitry may be disabled when the bandgap reference voltage has not reached a desired level. The power-on-reset circuitry may be sensitive or insensitive to the power-up sequence used by the power supply signals.

Abstract: Power-on-reset circuitry is provided for integrated circuits such as programmable logic device integrated circuits. The power-on-reset circuitry may use comparator-based trip point voltage detectors to monitor power supply voltages. The trip point detectors may use circuitry to produce trip point voltages from a bandgap reference voltage. Controller logic may process signals from the trip point detectors to produce a corresponding power-on-reset signal. The power-on-reset circuitry may contain a noise filter that suppresses noise from power supply voltage spikes. Normal operation of the power-on-reset circuitry may be blocked during testing. The power-on-reset circuitry may be disabled when the bandgap reference voltage has not reached a desired level. The power-on-reset circuitry may be sensitive or insensitive to the power-up sequence used by the power supply signals.

Abstract: Integrated circuits may include partial reconfiguration (PR) circuitry for reconfiguring a portion of a memory array. The PR circuitry may include a host circuit, a control circuit, an address register, and first, second, and third data registers. The host circuit may send a series of PR instructions to the control circuit. The control circuit may include a decompression circuit for decompressing compressed instructions, a decryption circuit for decrypting encrypted instructions, an error checking circuit for detecting errors in the instructions, and a logic circuit. The address register may select a desired frame. The selected frame may be loaded into the third data register. The contents of the third data register may be shifted into the first data register. The contents of the first data register may be modified according to a desired logic function using the logic circuit, shifted into the second data register, and written into the selected frame.

Abstract: Provided is a method and system to transmit data to a configurable integrated circuit that features delaying a capture edge of a clock signal at a data latch to synchronize the receipt of data at the data latch that was transmitted in response to a storage device receiving a launch edge of the clock signal. The method includes transmitting the clock signal having the launch edge and the capture edge to the storage device. The data is launched from the storage device to the integrated circuit in response to the storage device sensing the launch edge. Receipt of the capture edge at the data latch is delayed for a predetermined time to compensate for a delay between transmitting the launch edge and launching the data to ensure the data is latched by the data latch. Also disclosed is a system that carries out the function of the method.

Abstract: A power-on-reset circuit determines when it is safe for a programmable device to access configuration data from an associated non-volatile memory following a reset operation. The power-on-reset circuit receives a bandgap reference voltage produced by the programmable device. A comparator circuit is used to trigger a self-clocking delay unit when the bandgap reference voltage reaches a threshold level. The self-clocking delay unit generates its own clock signal independent of the clock frequency of the programmable device. The self-clocking delay unit may use edge-dependent delay units in a feedback loop to generate the clock signal. Using its own clock signal, the self-clocking delay unit waits for a predetermined time period and the outputs a signal to be used to enable access to the associated non-volatile memory.

Abstract: Power regulator circuitry is provided for powering loads such as programmable memory element arrays on integrated circuits. The power regulator circuitry may have control circuitry that generates a first digital control signal to turn on and off a regulated power supply circuit and a second digital control signal to turn on and off a switch-based power supply circuit. The outputs of the regulated power supply circuit and switch-based power supply circuit may be connected to an output terminal for the power regulator circuitry. The first and second digital control signals may be used to ensure that the regulated power supply circuit is turned on before the switch-based power supply circuit is turned off. The switch-based power supply circuitry may contain serially connected transistors. The transistors may be turned off in an order that prevents latchup.

Abstract: Power-on-reset circuitry is provided for integrated circuits such as programmable logic device integrated circuits. The power-on-reset circuitry may use comparator-based trip point voltage detectors to monitor power supply voltages. The trip point detectors may use circuitry to produce trip point voltages from a bandgap reference voltage. Controller logic may process signals from the trip point detectors to produce a corresponding power-on-reset signal. The power-on-reset circuitry may contain a noise filter that suppresses noise from power supply voltage spikes. Normal operation of the power-on-reset circuitry may be blocked during testing. The power-on-reset circuitry may be disabled when the bandgap reference voltage has not reached a desired level. The power-on-reset circuitry may be sensitive or insensitive to the power-up sequence used by the power supply signals.

Abstract: Circuits, methods, and apparatus for low-skew input/output level-shift circuits. One low-skew input/output circuit includes a single-ended-to-differential converter, a level-shift circuit, and a differential-to-single-ended converter. The circuit employs a low-skew single-ended-to-differential converter that provides an output to a level-shift circuit. To reduce skew, the single-ended-to-differential converter includes multiple paths from the input to its inverting and non-inverting outputs. The level-shift circuit translates signal levels between voltages used by the core and voltages used by the input and output circuits of the integrated circuit. An output from the level-shifter is received by the differential-to-single-ended converter. This converter also includes multiple signal paths coupling inverting and non-inverting signal paths.

Abstract: Power-on-reset circuitry is provided for integrated circuits such as programmable logic device integrated circuits. The power-on-reset circuitry may use comparator-based trip point voltage detectors to monitor power supply voltages. The trip point detectors may use circuitry to produce trip point voltages from a bandgap reference voltage. Controller logic may process signals from the trip point detectors to produce a corresponding power-on-reset signal. The power-on-reset circuitry may contain a noise filter that suppresses noise from power supply voltage spikes. Normal operation of the power-on-reset circuitry may be blocked during testing. The power-on-reset circuitry may be disabled when the bandgap reference voltage has not reached a desired level. The power-on-reset circuitry may be sensitive or insensitive to the power-up sequence used by the power supply signals.

Abstract: Circuits, methods, and apparatus for low-skew input/output level-shift circuits. One low-skew input/output circuit includes a single-ended-to-differential converter, a level-shift circuit, and a differential-to-single-ended converter. The circuit employs a low-skew single-ended-to-differential converter that provides an output to a level-shift circuit. To reduce skew, the single-ended-to-differential converter includes multiple paths from the input to its inverting and non-inverting outputs. The level-shift circuit translates signal levels between voltages used by the core and voltages used by the input and output circuits of the integrated circuit. An output from the level-shifter is received by the differential-to-single-ended converter. This converter also includes multiple signal paths coupling inverting and non-inverting signal paths.

Abstract: Power-on-reset circuitry is provided for integrated circuits such as programmable logic device integrated circuits. The power-on-reset circuitry may use comparator-based trip point voltage detectors to monitor power supply voltages. The trip point detectors may use circuitry to produce trip point voltages from a bandgap reference voltage. Controller logic may process signals from the trip point detectors to produce a corresponding power-on-reset signal. The power-on-reset circuitry may contain a noise filter that suppresses noise from power supply voltage spikes. Normal operation of the power-on-reset circuitry may be blocked during testing. The power-on-reset circuitry may be disabled when the bandgap reference voltage has not reached a desired level. The power-on-reset circuitry may be sensitive or insensitive to the power-up sequence used by the power supply signals.

Abstract: A power-on-reset circuit determines when it is safe for a programmable device to access configuration data from an associated non-volatile memory following a reset operation. The power-on-reset circuit receives a bandgap reference voltage produced by the programmable device. A comparator circuit is used to trigger a self-clocking delay unit when the bandgap reference voltage reaches a threshold level. The self-clocking delay unit generates its own clock signal independent of the clock frequency of the programmable device. The self-clocking delay unit may use edge-dependent delay units in a feedback loop to generate the clock signal. Using its own clock signal, the self-clocking delay unit waits for a predetermined time period and the outputs a signal to be used to enable access to the associated non-volatile memory.