An analog circuit has a first plurality of transistors that are connected as a first selectable resistance in the analog circuit, and a second plurality of transistors that are connected as a second selectable resistance in the analog circuit. In an unlocked state of the analog circuit, the first selectable resistance matches the second selectable resistance within a designed ratio and tolerance. In a locked state of the analog circuit, the first selectable resistance and the second selectable resistance do not match within the designed ratio and tolerance. A controller retrieves a logic lock key from an off-chip memory and selects the first and second selectable resistances, thereby setting the analog circuit to its unlocked state, by sending respective first and second portions of the logic lock key to operate the first and second pluralities of transistors.

A voltage-controlled oscillator is provided. A semiconductor device includes a first circuit and a second circuit. The first circuit has a function of holding a first potential and a function of controlling the level of a third potential supplied to the second circuit according to a second potential based on the first potential. The second circuit has a function of outputting a second signal based on a first signal input to the second circuit. The delay time from input of the first signal to the second circuit to output of the second signal from the second circuit is determined by the third potential.

An integrated circuit to drive a plurality of fluid actuation devices includes a contact pad and a programmable pulldown device. The programmable pulldown device is electrically coupled to the contact pad. The programmable pulldown device is settable to any one of a plurality of resistances.

The present technology relates to a semiconductor apparatus, a production method, and an electronic apparatus that enable semiconductor apparatuses to be laminated and the laminated semiconductor apparatuses to be identified. A semiconductor apparatus that is laminated and integrated with a plurality of semiconductor apparatuses, includes a first penetrating electrode for connecting with the other semiconductor apparatuses and a second penetrating electrode that connects the first penetrating electrode and an internal device, the second penetrating electrode being arranged at a position that differs for each of the laminated semiconductor apparatuses. The second penetrating electrode indicates a lamination position at a time of lamination. An address of each of the laminated semiconductor apparatuses in a lamination direction is identified by writing using external signals after lamination. The present technology is applicable to a memory chip and an FPGA chip.

Technology for editing PLD code to be programmed into a PLD are provided. The technology includes an interface, a storage system, and a processing system configured to obtain a PLD code, with the PLD code comprising one or more logic instruction blocks and corresponding block parameters for each logic instruction block, with the PLD code being intended for programming into the PLD, compare the one or more logic instruction blocks of the PLD code to a subset of the library of logic instruction blocks applicable to the PLD according to the library of PLD devices, determine inconsistent logic instruction blocks of the one or more logic instruction blocks, indicate the inconsistent logic instruction blocks, and correct the inconsistent logic instruction blocks using the subset of the library of logic instruction blocks.

An integrated circuit (IC) includes a first circuit implemented using programmable circuitry of the IC, and a second circuit implemented using hardened circuitry of the IC. The IC further includes a configurable interface circuit to couple the first circuit to the second circuit using ready/valid signaling with a configurable ready-latency value.

The subject matter of the present invention is a motor vehicle engine control electronic computer including an electric circuit (1B) for managing at least one piece of electrical equipment (2) of the vehicle. The electric circuit includes at least one module (20B) for digital connection to a piece of electrical equipment of the vehicle and a microcontroller (10) including at least one digital input port (110). The digital connection module includes a connector (210) for linking to the electrical equipment, a link (220) for connecting to the digital input port of the microcontroller and a diode package (230B1), connected firstly to the battery (B) voltage of the vehicle and secondly to the ground (M), including two diodes (231B-1, 231B-2) linked to each other at a midpoint (232) and being configurable to operate with a common anode or with a common cathode.

Hybrid Hall Effect Devices implemented with Spin Transfer Torque write capability are configured as magnetoelectronic (ME) devices. These devices are useable as circuit building blocks in reconfigurable processing systems, including as logic circuits, non-volatile switches and memory cells.

Described is an apparatus which comprises: a first power supply; a second power supply lower than the first power supply; first and second transistors coupled in series and to be biased, the first and second transistors coupled to a pad; a first pull-up transistor coupled to the first power supply and to one of the first or second transistors; a pull-down transistor coupled to one of the first or second transistors; and a second pull-up transistor coupled to the second power supply, the pull-down transistor, and to one of the first or second transistors.

Systems for monitoring or control can include reconfigurable input and output channels. Such reconfigurable channels can include as few as a single terminal and a ground pin, or such channels can include three or four terminal configuration such as for use in four-terminal resistance measurements. Channel reconfiguration can be accomplished such as using software-enabled or firmware-enabled control of channel hardware. Such channel hardware can include analog-to-digital and digital-to-analog conversion capability, including use of a digital-to-analog converter to provide field power or biasing. In an example, the interface circuit can provide a selectable impedance.