A high-speed comparator circuit is provided. The circuit includes an amplifier portion, a latch portion, and a negative capacitance portion. The amplifier portion includes an input coupled to receive an analog signal and an output. The latch portion is coupled to the amplifier portion. The latch portion is configured to provide at the output a digital value based on the analog signal. The negative capacitance portion is coupled to the output. The negative capacitance portion is configured to cancel parasitic capacitance coupled at the first output.

A method for configuring a storage circuit, including: writing data via an input line into the storage circuit by a software write access; writing a bit-wise inverted form of the data via the input line into the storage circuit by a subsequent software write access; and generating an error signal if a comparison based on the written data and the written bit-wise inverted form of the data indicates a storage circuit configuration error, wherein the storage circuit permits hardware read access and lacks software read access.

A method for configuring a storage circuit, including: writing data via an input line into the storage circuit by a software write access; writing a bit-wise inverted form of the data via the input line into the storage circuit by a subsequent software write access; and generating an error signal if a comparison based on the written data and the written bit-wise inverted form of the data indicates a storage circuit configuration error, wherein the storage circuit permits hardware read access and lacks software read access.

In some examples, command decoders may have multiple command paths. In some examples, command signals from one command path may be provided to another command path from a node located between two latches of the command decoder, such as two latches of a flip-flop. In some examples, the command decoder may include separate flip-flops for different command modes. In some examples, the separate flip-flops may be tristate flip-flops. In some examples, the command decoder may include alternate logic circuits rather than a multiplexer.

In some examples, command decoders may have multiple command paths. In some examples, command signals from one command path may be provided to another command path from a node located between two latches of the command decoder, such as two latches of a flip-flop. In some examples, the command decoder may include separate flip-flops for different command modes. In some examples, the separate flip-flops may be tristate flip-flops. In some examples, the command decoder may include alternate logic circuits rather than a multiplexer.

An integrated circuit includes a programmable logic array. The programmable logic array incudes a plurality of logic elements arranged in rows and columns. Each logic element includes a direct output and a synchronized output. The direct output of each logic element is coupled to all other logic elements of higher rank, but is not coupled to logic elements of lower rank.

An integrated circuit includes a programmable logic array. The programmable logic array incudes a plurality of logic elements arranged in rows and columns. Each logic element includes a direct output and a synchronized output. The direct output of each logic element is coupled to all other logic elements of higher rank, but is not coupled to logic elements of lower rank.

A controller for a switching converter has a hysteresis generating circuit to provide an upper hysteresis limit and a lower hysteresis limit based on an output voltage, a switching control circuit for providing a switching control signal, and a frequency locking circuit for adjusting one of the upper hysteresis limit and the lower hysteresis limit based on the switching control signal and a clock signal. When the switching converter is in a first mode, a main switch of the switching converter is turned ON by comparing a current sense signal representative of a current flowing through the main switch with the lower hysteresis limit, and is turned OFF by comparing the current sense signal with the upper hysteresis limit. When the switching converter is in a second mode, the main switch is turned ON based on the clock signal, and is turned OFF based on the current sense signal.

A low latency comparator circuit with a local clock circuit is disclosed. A comparator circuit configured to compare a first input signal to a second input signal. The comparator circuit includes at least one regenerative latch circuit having a first and second inputs configured to receive the first and second input signals, respectively. The comparator circuit further includes a clock circuit configured to generate and provide a clock signal exclusively to circuitry in the comparator circuit, including the at least one regenerative latch circuit. At least one output latch circuit coupled to the at least one regenerative latch circuit and configured to provide a first output signal indicative of a comparison of the first and second input signals.

A low latency comparator circuit with a local clock circuit is disclosed. A comparator circuit configured to compare a first input signal to a second input signal. The comparator circuit includes at least one regenerative latch circuit having a first and second inputs configured to receive the first and second input signals, respectively. The comparator circuit further includes a clock circuit configured to generate and provide a clock signal exclusively to circuitry in the comparator circuit, including the at least one regenerative latch circuit. At least one output latch circuit coupled to the at least one regenerative latch circuit and configured to provide a first output signal indicative of a comparison of the first and second input signals.