A system comprises at least one processor configured to perform technology mapping to map logic elements in a logic netlist to corresponding dual-rail modules in a library. The technology mapping results in a network of interconnected nodes and the mapped dual-rail modules are arranged at corresponding nodes of the network. The processor is configured to optimize the network and perform the technology mapping based on at least one satisfiability-don't-care condition. Performance analysis may be performed by calculating a cycle time of a pipeline node in the network based on a calculated pre-charging finish time and an evaluation finish time of a fanin node of the pipeline node.

A compensated comparator is provided, including a decision stage and a differential stage provided with two transistors connected by their sources, the differential stage being provided with compensation means to compensate the effects of a dispersion of the threshold voltages of the transistors forming the differential stage, the compensation means including first and second capacitors each connected to a gate of one of the two transistors, and being configured to memorize a voltage that is a function of a threshold voltage of the considered transistors.

A compensated comparator is provided, including a decision stage and a differential stage provided with two transistors connected by their sources, the differential stage being provided with compensation means to compensate the effects of a dispersion of the threshold voltages of the transistors forming the differential stage, the compensation means including first and second capacitors each connected to a gate of one of the two transistors, and being configured to memorize a voltage that is a function of a threshold voltage of the considered transistors.

A circuit includes a latch configured to update a stored state of the latch in response to an input data signal and a pulsed clock signal. The circuit includes a pulse generator configured to generate the pulsed clock signal based on an input clock signal, the input data signal, and a feedback signal indicative of a stored state of the latch. The pulse generator may be configured to generate a pulse enable signal based on the input data signal, the input clock signal, and the feedback signal. The pulsed clock signal may be based on the pulse enable signal and the input clock signal. The pulse generator may generate the pulsed clock signal to have a pulse of a first signal level in response to an indication that the stored state of the latch needs to change and generates the pulsed clock signal to have a second signal level, otherwise.

There is disclosed a self-timed processor. The self-timed processor includes trigger logic having a trigger input to receive an event trigger signal, a data input set to data value 1, a trigger output to send a trigger output signal when the event trigger signal is received, and a reset input to reset the trigger output signal. The processor also has a delay insensitive asynchronous logic (DIAL) block with multi-rail DIAL inputs to receive a multi-rail DIAL input having a) the trigger output signal, and b) data value 0; and data phase completion logic to output a completion signal indicating an end of a data propagate phase of the DIAL block to reset the trigger output signal when multi-rail data DIAL data process values of the DIAL block reach a DIAL valid state.

There is disclosed a self-timed processor. The self-timed processor includes trigger logic having a trigger input to receive an event trigger signal, a data input set to data value 1, a trigger output to send a trigger output signal when the event trigger signal is received, and a reset input to reset the trigger output signal. The processor also has a delay insensitive asynchronous logic (DIAL) block with multi-rail DIAL inputs to receive a multi-rail DIAL input having a) the trigger output signal, and b) data value 0; and data phase completion logic to output a completion signal indicating an end of a data propagate phase of the DIAL block to reset the trigger output signal when multi-rail data DIAL data process values of the DIAL block reach a DIAL valid state.

Reduced-power dynamic data circuits with wide-band energy recovery are described herein. In one embodiment, a circuit system comprises at least one sub-circuit in which at least one of the sub-circuits includes a capacitive output node that is driven between low and high states in a random manner for a time period and an inductive circuit path coupled to the capacitive output node. The inductive circuit path includes a transistor switch and an inductor connected in series to discharge and recharge the output node to a bias supply. A pulse generator circuit generates a pulse width that corresponds to a timing for driving the output node.

A circuit, method, and system are disclosed for sampling a signal. The system includes a sampler circuit configured to sample input signals when a clock signal is at a first level to produce sampled signals, a detection circuit that is coupled to the sampler circuit, and a feedback circuit that receives an output signal and generates the clock signal. The detection circuit pre-charges the sampled signals when the clock signal is at a second level and, using threshold adjusted inverters, detects voltage levels of each sampled signal to produce detected voltage level signals, where a threshold voltage of the threshold adjusted inverters is entirely outside of a transition voltage range of the sampler circuit. In response to one of the detected voltage level signals transitioning from the second level to the first level, the detection circuit transitions the output signal from the first level to the second level.

A drive capability of a dynamic logic circuit is improved. A logic circuit includes a dynamic logic circuit, a first output node, a first transistor that is diode-connected, and a capacitor. The dynamic logic circuit includes a second output node. The first transistor and transistors in the dynamic logic circuit have an n-type conductivity or a p-type conductivity. The first output node is electrically connected to a first terminal of the capacitor, and the second output node is electrically connected to a second terminal of the capacitor. A first terminal of the first transistor is electrically connected to the first output node, and a first voltage is input to a second terminal of the first transistor.

Reduced-power dynamic data circuits with wide-band energy recovery are described herein. In one embodiment, a circuit system comprises at least one sub-circuit in which at least one of the sub-circuits includes a capacitive output node that is driven between low and high states in a random manner for a time period and an inductive circuit path coupled to the capacitive output node. The inductive circuit path includes a transistor switch and an inductor connected in series to discharge and recharge the output node to a bias supply. A pulse generator circuit generates a pulse width that corresponds to a timing for driving the output node.