A logic cell, including a first capacitor connected between an application node for applying a supply voltage of the cell and a floating node for providing an output logic signal of the cell, and, connected in parallel with the first capacitor, an association in series of a second capacitor and a first variable-resistance element, the first variable-resistance element including a control electrode connected to an application node for applying a first input logic signal of the cell.

Apparatuses and methods for transmitting a command mode (e.g., operation mode) associated with a command between devices are disclosed. One device may be configured as a master and one or more devices may be configured as slaves. The command mode may be transmitted by the master to the slaves by setting a resting state of a clock signal transmitted between the devices and transitioning a device enable signal to an active state. The slaves may detect the resting state of the clock at the time the enable signal is transitioned to the active state in order to determine the command mode of the command. The devices may then execute the command in the mode indicated by the transmitted command mode.

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 LVDS device, comprising: a first pair of switches, operable to drive current from a first output to a second output through a differential signalling circuit; a second pair of switches, operable to drive current from the second output to the first output through the differential signalling circuit; a voltage limiter, connected in series with the first and second pair of switches, operable to receive a control voltage and, responsive to the control voltage, to limit a voltage at each of the first and second output to less than a clamping voltage when current is driven through the differential signalling circuit.

A low voltage differential signaling (LVDS) driver circuit, system, apparatus, and methodology are provided for controlling switching components in a primary current stage and a pre-emphasis current stage with an adaptive pre-emphasis gain tuning hardware control circuit arranged to provide control signals for periodically tuning a pre-emphasis gain setting for the secondary pre-emphasis current stage by selecting an optimum pre-emphasis gain setting from a plurality of pre-emphasis gain setting which minimizes an inter-symbol interference (ISI) jitter measure for the LVDS driver circuit.

A current-mode logic circuit is provided. The current-mode logic circuit includes a transmitter module. The transmitter module includes an output impedance circuit, a switch circuit, and a current source. The output impedance circuit provides an adjustable output resistor. The adjustable output resistor includes floating resistors and/or pull-up resistors. The switch circuit is coupled to the output impedance circuit. The switch circuit receives differential input signals, outputs differential output signals, and controls high-low level switching of the differential input signals and the differential output signals according to the adjustable output resistor. The current source is coupled to the output impedance circuit and the switch circuit. The current source provides currents to the output impedance circuit and the switch circuit. The floating resistors are resistors coupled between the differential output signals, and the pull-up resistors are resistors coupled between the differential output signals and a power source.

A current-mode logic circuit is provided. The current-mode logic circuit includes a transmitter module. The transmitter module includes an output impedance circuit, a switch circuit, and a current source. The output impedance circuit provides an adjustable output resistor. The adjustable output resistor includes floating resistors and/or pull-up resistors. The switch circuit is coupled to the output impedance circuit. The switch circuit receives differential input signals, outputs differential output signals, and controls high-low level switching of the differential input signals and the differential output signals according to the adjustable output resistor. The current source is coupled to the output impedance circuit and the switch circuit. The current source provides currents to the output impedance circuit and the switch circuit. The floating resistors are resistors coupled between the differential output signals, and the pull-up resistors are resistors coupled between the differential output signals and a power source.

Logic circuits, or logic gates, are disclosed comprising vertical transport field effect transistors and one or more active gates, wherein the number of C.sub.PP's for the logic circuit, in isolation, is equal to the number of active gates. The components of the logic circuit can be present in at least three different vertical circuit levels, including a circuit level comprising at least one horizontal plane passing through a conductive element that provides an input voltage to the one or more gate structures and another conductive element that provides an output voltage of the logic circuit, and another circuit level that comprises a horizontal plane passing through a conductive bridge from the N output to P output of the field effect transistors. Such logic circuits can include single-gate inverters, two-gate inverters, NOR2 logic gates, and NAND3 logic gates, among other more complicated logic circuits.

A current-mode logic circuit is provided. The current-mode logic circuit includes a transmitter module. The transmitter module includes an output impedance circuit, a switch circuit, and a current source. The output impedance circuit provides an adjustable output resistor. The adjustable output resistor includes floating resistors and/or pull-up resistors. The switch circuit is coupled to the output impedance circuit. The switch circuit receives differential input signals, outputs differential output signals, and controls high-low level switching of the differential input signals and the differential output signals according to the adjustable output resistor. The current source is coupled to the output impedance circuit and the switch circuit. The current source provides currents to the output impedance circuit and the switch circuit. The floating resistors are resistors coupled between the differential output signals, and the pull-up resistors are resistors coupled between the differential output signals and a power source.

A current-mode logic circuit is provided. The current-mode logic circuit includes a transmitter module. The transmitter module includes an output impedance circuit, a switch circuit, and a current source. The output impedance circuit provides an adjustable output resistor. The adjustable output resistor includes floating resistors and/or pull-up resistors. The switch circuit is coupled to the output impedance circuit. The switch circuit receives differential input signals, outputs differential output signals, and controls high-low level switching of the differential input signals and the differential output signals according to the adjustable output resistor. The current source is coupled to the output impedance circuit and the switch circuit. The current source provides currents to the output impedance circuit and the switch circuit. The floating resistors are resistors coupled between the differential output signals, and the pull-up resistors are resistors coupled between the differential output signals and a power source.