Circuitry is provided that includes programmable fabric with fine-grain routing wires and a separate programmable coarse-grain routing network that provides enhanced bandwidth, low latency, and deterministic routing behavior. The programmable coarse-grain routing network may be implemented on an active interposer die. The programmable fabric may be implemented on a top die that is stacked on the active interposer die. A protocol-based network on chip (NoC) may be overlaid on the coarse-grain routing network. Although the NoC protocol is nondeterministic, the coarse-grain routing network includes an array of programmable switch boxes linked together using a predetermined number of routing channels to provide deterministic routing. Pipeline registers may be interposed within the routing channels at fixed locations to guarantee timing closure.

An integrated circuit system includes: a storage element which stores in advance a plurality of pieces of circuit information and startup control circuit information used to configure a startup control logic circuit for selecting circuit information that has not failed in configuring a logic circuit; and an integrated circuit which, at the time of startup or when configuration of the logic circuit based on any of the plurality of pieces of circuit information has failed, configures the startup control logic circuit by reading the startup control circuit information from the storage element, causes the configured startup control logic circuit to select the circuit information that has not failed in configuring the logic circuit, reads the circuit information selected by the startup control logic circuit from the storage element, and configures the logic circuit according to the circuit information.

A semiconductor integrated circuit device having a control signal system for avoiding failure to check an indefinite signal propagation prevention circuit, for facilitating a check included in an automated tool, and for facilitating a power shutdown control inside a chip. In the semiconductor integrated circuit device, power shutdown priorities are provided by independent power domains (Area A to Area I). A method for preventing a power domain having a lower priority from being turned OFF when a circuit having a high priority is turned ON is also provided.

Low power very large scale integrated (VLSI) designs using a circuit failure in sequential cells as low voltage check for limit of operation of a design are provided. One such method involves the adding a plurality of bits for sequential elements in the design including sets of flip-flops, RAMs, ROMs and register files to add parity or single error correct and double error detect mechanism, a method to detect the parity errors or a single bit error and a double bit error in the sequential elements, starting at a voltage of operation at a nominal value and gradually lowering voltage setting till a first error is detected in the sequential elements, increasing the voltage of operation by predetermined step above a voltage of first fail to achieve an optimal voltage setting of a correct operation of the design, storing this optimal voltage setting in anon-volatile memory for a subsequent use.

Embodiments of the present disclosure pertain to reducing power consumption in a processor circuit. In one embodiment, a processor circuit comprises a plurality of data storage modules. The plurality of data storage modules each include one or more first multibit flip flop circuits having a first power consumption per bit and one or more second flip flop circuits having a second power consumption per bit. The first multibit flip flop circuits may have more bits than the second flip flop circuits. Additionally, the first power consumption per bit may be less than the second power consumption per bit such that power consumption is reduced when the first multibit flip flop circuits are used to store bits that change with a higher frequency than bits stored in the second flip flop circuits.

A circuit includes a voltage source, a transistor, a load current sensor, a hardware latch and a logic circuit. The transistor is connected between the voltage source and a load. The sensor emits a fault signal when the load current exceeds a predetermined value. The hardware latch sets a latch signal when it receives the fault signal and maintains the latch signal until it receives a rearm signal. The logic circuit receives the latch signal from the hardware latch and also receives a software command for controlling turning on and off of the circuit. When the latch signal is not set, the logic circuit converts the software command to a control voltage applied at a gate of the transistor, turning on the transistor to allow power delivery to the load. A system includes a microcontroller providing software commands and rearm signals to a plurality of circuits.

A semiconductor device includes a plurality of functional blocks, each being configured to provide at least one predetermined function. The functional blocks at least include a first functional block and a second functional block. The first functional block and the second functional block are coupled in serial with a predetermined current flowing therethrough.

Asynchronous circuit elements are described. Asynchronous circuit elements include a consensus element (c-element), completion tree, and validity tree. The c-element is implemented using adjustable threshold based multi-input capacitive circuitries. The completion tree comprises a plurality of c-elements organized in a tree formation. The validity tree comprises OR gates followed by c-elements. The multi-input capacitive circuitries include capacitive structures that may comprise linear dielectric, paraelectric dielectric, or ferroelectric dielectric. The capacitors can be planar or non-planar. The capacitors may be stacked vertically to reduce footprint of the various asynchronous circuitries.

Asynchronous circuit elements are described. Asynchronous circuit elements include a consensus element (c-element), completion tree, and validity tree. The c-element is implemented using adjustable threshold based multi-input capacitive circuitries. The completion tree comprises a plurality of c-elements organized in a tree formation. The validity tree comprises OR gates followed by c-elements. The multi-input capacitive circuitries include capacitive structures that may comprise linear dielectric, paraelectric dielectric, or ferroelectric dielectric. The capacitors can be planar or non-planar. The capacitors may be stacked vertically to reduce footprint of the various asynchronous circuitries.

A signal interface system and a data transmission method thereof are provided. The signal interface system includes a data line, a clock line, a master circuit, and at least one slave circuit. The master circuit has a main data pin coupled to the data line and a main clock pin coupled to the clock line. The at least one slave circuit has a secondary data pin coupled to the data line and a secondary clock pin coupled to the clock line. The master circuit transmits a main control data to the at least one slave circuit through the data line, and transmits an additional control data to the at least one slave circuit through the clock line.