The invention is to provide a compact reconfigurable circuit implementing a LUT and a “hard” circuit. The present invention provides a reconfigurable circuit comprising: first wires disposed in a first direction; a second wire disposed in a second direction intersecting the first direction; a power line, a ground line and data input line or data input inverse line coupled to the said first wires one-to-one; a multiplexer, one of whose inputs is connected with the second wire; nonvolatile switch cells utilized to interconnect the first wires and second wire at the crosspoints, wherein every nonvolatile switch cell is constructed by at least one non-volatile resistive switch.

An example programmable device includes a configuration memory configured to store configuration data; a programmable logic having a configurable functionality based on the configuration data in the configuration memory; a signal conversion circuit; a digital processing circuit; an endpoint circuit coupled to the signal conversion circuit through the digital processing circuit; wherein the digital processing circuit includes a first one or more digital processing functions implemented as hardened circuits each having a predetermined functionality, and a second one or more processing functions implemented by the configurable functionality of the programmable logic.

A welding-type control system including configurable hardware, a hardware configuration memory device that configures the configurable hardware when loaded with configuration data, a processor, an input portal via which the processor can receive a file with the configuration data, and a memory with instructions that when executed by the processor cause the processor to transfer the configuration data in the file to the memory device. A controlled system including such a welding-type control system includes a welding system, a cladding system or a plasma cutting system.

A subsea electronics module for use in a subsea well installation, comprising: a backplane connecting a plurality of slots; a plurality of physical cards each supporting an electronic assembly having an identical architecture including a programmable logic module and a memory, the physical cards each being inserted into a respective slot of the backplane; and wherein the identical electronic assembly of each physical card is configured by program instructions stored in the memory thereon to be configured to perform in use a set of electronic functions of one of a plurality of different defined card roles in dependence on either one or both of: the position of the slot into which that card is inserted; an indication of a card role configuration selection for that card.

A programming system includes an upper computer, a calculation module, and a first signal conversion module. The calculation module includes a second signal conversion module and a programming interface. The upper computer is configured to convert programming data into first bus signals. When the calculation module is in a normal programming state, the second signal conversion module converts the first bus signals into first clock signals and first data signals to program the calculation module. When the calculation module is in a non-normal programming state, the first signal conversion module converts the first bus signals into second clock signals and second data signals to program the calculation module. A programming method is also provided.

This technology relates generally to integrated circuit technologies, and more particularly, to methods and systems for configuring a field programmable device. In one embodiment, a method for configuring a field programmable device is provided. The method comprises: identifying information associated with a plurality of logic functions associated with a plurality of subsystems to be implemented on a field programmable device; determining, based on the information, a set of attributes associated with each of the plurality of subsystems; determining, based on the set of attributes, a first value indicative of an estimation of a total number of the sequential logic blocks, and a second value indicative of an estimation of a total number of the combinational logic blocks, for implementing the plurality of logic functions; determining, based on the first and second values, to configure a first field programmable device for implementing the plurality of logic functions.

An integrated circuit according to an embodiment includes: a first block including a first logic block configured to perform a logical operation, a first switch block circuit configured to control connection and non-connection with the first logic block, and a second switch block circuit configured to control connection and non-connection with the first logic block; and a second block including a second logic block configured to perform a logical operation, a third switch block circuit configured to control connection and non-connection with the second logic block, and a fourth switch block circuit configured to control connection and non-connection with the second logic block, wherein the first switch block circuit is mutually connected with the third and fourth switch block circuits, and the second switch block circuit is mutually connected with the third and fourth switch block circuits.

A field-programmable analog array including an array of a plurality of programmable analog timing circuits, the field-programmable analog array being field-programmable to a plurality of analog or analog-to-digital conversion circuits, such as relaxation oscillators, phase shifters, phase interpolators, pulse width modulators, pseudo exponential digitally controlled oscillators, etc. through programming, without physical re-processing of circuit. A field-programmable mixed signal array according to an embodiment of the present invention comprises a plurality of field-programmable analog arrays, field-programmable digital blocks and field-programmable connecting wire blocks, the field-programmable mixed signal array being field-programmable to a plurality of analog, digital or analog-to-digital conversion circuits, such as digital pulse width modulators, time-digital converters, analog-digital converters, phase-locked loops, DC-DC, AC-DC and DC-AC converters through programming, without physical re-processing of circuit.

A method for implementing a matrix operation. A first digital result is determined for the matrix operation as a function of a first analog addition using a first memristor array, a second digital result being determined as a function of a second analog addition using a second memristor array, and the first result and the second result being digitally added. A device for implementing a matrix operation. The device includes at least one first memristor array and one second memristor array, a first analog-to-digital converter and a second analog-to-digital converter. The device is designed to determine a first digital result for the matrix operation as a function of a first analog addition using the first memristor array and of the first analog-to-digital converter, and to determine a second digital result as a function of a second analog addition using the second memristor array and of the second analog-to-digital converter.

An example programmable device includes a configuration memory configured to store configuration data; a programmable logic having a configurable functionality based on the configuration data in the configuration memory; a signal conversion circuit; a digital processing circuit; an endpoint circuit coupled to the signal conversion circuit through the digital processing circuit; wherein the digital processing circuit includes a first one or more digital processing functions implemented as hardened circuits each having a predetermined functionality, and a second one or more processing functions implemented by the configurable functionality of the programmable logic.