Logic mechanisms operate to define the position of at least one mechanical output based on the position of two or more mechanical inputs, and employ at least one control element that functions to determine (at least in part) whether an output is moved, and which provides the same function in more than one position. Some mechanisms are configured to determine, based on the input positions, whether a path to transmit motion to an output exists or does not exist. Some mechanisms are configured to determine, based on the input positions, whether or not motion of a driven element can be accommodated without moving an output.

The invention relates to an electronic computing device for generating Boolean functions. The device comprises a conductive module comprising one or more first electrodes, to allow the application of electrical input signals to the conductive module, and one or more second electrodes, to make available electrical output signals from the conductive module. The device comprises one or more input terminals, each of which is selectively connectible to one of said one or more first electrodes for applying electrical input signals to said first electrodes during a step of processing of the device, and one or more output terminals, each of which is selectively connectible to one of said second electrodes to make electrical output signals available on said second electrodes during the step of processing.

The invention relates to an electronic computing device for generating Boolean functions. The device comprises a conductive module comprising one or more first electrodes, to allow the application of electrical input signals to the conductive module, and one or more second electrodes, to make available electrical output signals from the conductive module. The device comprises one or more input terminals, each of which is selectively connectible to one of said one or more first electrodes for applying electrical input signals to said first electrodes during a step of processing of the device, and one or more output terminals, each of which is selectively connectible to one of said second electrodes to make electrical output signals available on said second electrodes during the step of processing.

Logic mechanisms operate to define the position of at least one mechanical output based on the position of at least one mechanical input. Some mechanisms are configured to determine, based on the input position(s), whether a path to transmit motion to an output exists or does not exist. Some mechanisms are configured to determine, based on the input position(s), whether or not motion of a driven element can be accommodated without moving an output. Some mechanisms are configured to determine, based on the input position(s), whether or not one or more elements are constrained to transmit motion to an output.

Mechanisms can be designed to manage non-contact forces to reduce energy consumption and/or to control interactions between the parts. Management of non-contact forces is especially useful in micro-scale and nano-scale mechanisms, where van der Waals attraction between parts of the mechanism may be significant to the operation of the mechanism.

Logic mechanisms operate to define the position of at least one mechanical output based on the position of two or more mechanical inputs, and employ at least one control element that functions to determine (at least in part) whether an output is moved, and which provides the same function in more than one position. Some mechanisms are configured to determine, based on the input positions, whether a path to transmit motion to an output exists or does not exist. Some mechanisms are configured to determine, based on the input positions, whether or not motion of a driven element can be accommodated without moving an output.

In at least one illustrative embodiment, a microelectromechanical system (MEMS) includes a composable piezoelectric actuator electrically coupled to a terminal. In response to a voltage applied across electrodes of the actuator, a piezoelectric rod moves from an initial position to a displaced position. In an embodiment, the MEMS includes two terminals, a resistive element is coupled between the terminals, and when in the displaced position the rod contacts one of the terminals. In an embodiment, the MEMS includes three terminals, and when a threshold voltage is applied to one of the terminals, the rod moves to the displaced position and allows current to flow between the other two terminals. In an embodiment, the MEMS includes a primary set of actuators that are mechanically but not electrically connected to a secondary set of actuators. An output terminal is coupled to the second set of actuators. Other embodiments are described and claimed.

A differential mixed-signal logic processor is provided. The differential mixed-signal logic processor includes a plurality of mixed-signal multiplier branches for multiplication of an analog value A and a N-bit digital value B. Each of the plurality of mixed-signal multiplier branches include a first capacitor connected across a second capacitor and a third capacitor to provide a differential output across the second and third capacitors. A capacitance of the first capacitor is equal to half a capacitance of the second and third capacitors.

A differential mixed-signal logic processor is provided. The differential mixed-signal logic processor includes a plurality of mixed-signal multiplier branches for multiplication of an analog value A and a N-bit digital value B. Each of the plurality of mixed-signal multiplier branches include a first capacitor connected across a second capacitor and a third capacitor to provide a differential output across the second and third capacitors. A capacitance of the first capacitor is equal to half a capacitance of the second and third capacitors.

A differential mixed-signal logic processor is provided. The differential mixed-signal logic processor includes a plurality of mixed-signal multiplier branches for multiplication of an analog value A and a N-bit digital value B. Each of the plurality of mixed-signal multiplier branches include a first capacitor connected across a second capacitor and a third capacitor to provide a differential output across the second and third capacitors. A capacitance of the first capacitor is equal to half a capacitance of the second and third capacitors.