A semiconductor device includes an error correction code circuit and a register circuit. The error correction code circuit is configured to generate first data according to second data. The register circuit is configured to generate reset information according to a difference between the first data and the second data, for adjusting a memory cell associated with the second data. A method is also disclosed herein.

A memory device, for executing an anneal computation with first state and a second state. The memory device includes a first memory array, a second memory array, a control circuit, a sensing circuit and a processing circuit. the control circuit selects a first horizontal row of memory units from the first memory array, and selects a second horizontal row of memory units from the second memory array. The sensing circuit computes a local energy value of the first state according to the current generated by the memory units of the first horizontal row, and computes a local energy value of the second state according to the current generated by the memory units of the second horizontal row. The processing circuit updates the first state and/or the second state according to the local energy value of the first state and the local energy value of the second state.

Described are technologies of all-digital camouflage circuits. The camouflage circuit can include a first chain of inverters, synthesized with a first standard cell with a first transistor threshold, and a second chain of inverters, synthesized with a second standard cell with a second transistor threshold that is different than the first transistor threshold. A first flip-flop receives a first output of the first chain as a data input and a second output of the second chain as a clock input. A second flip-flop receives the second output as a data input and the first output of the first chain as a clock input. Given the different transistor thresholds, one flip-flop always outputs an active signal that corresponds to an input signal applied to the first chain and the second chain. The other flip-flop always output a constant signal, such an always low signal.

Described are technologies of all-digital camouflage circuits. The camouflage circuit can include a first chain of inverters, synthesized with a first standard cell with a first transistor threshold, and a second chain of inverters, synthesized with a second standard cell with a second transistor threshold that is different than the first transistor threshold. A first flip-flop receives a first output of the first chain as a data input and a second output of the second chain as a clock input. A second flip-flop receives the second output as a data input and the first output of the first chain as a clock input. Given the different transistor thresholds, one flip-flop always outputs an active signal that corresponds to an input signal applied to the first chain and the second chain. The other flip-flop always output a constant signal, such an always low signal.

A power management circuit includes an inverter circuit and a latch circuit. The inverter circuit is configured to receive a first control signal from an inverter input terminal and generate a second control signal at an inverter output terminal. The first control signal carries power status information of a first supply voltage. The latch circuit has a latch supply terminal, a first latch input terminal and a second latch input terminal. The latch supply terminal is coupled to a second supply voltage becoming ready before the first supply voltage. The first latch input terminal and the second latch input terminal are coupled to the inverter output terminal and the inverter input terminal respectively. The latch circuit is configured to generate a third control signal according to respective signal levels of the first control signal and the second control signal, and accordingly perform power control of an integrated circuit.

A power management circuit includes an inverter circuit and a latch circuit. The inverter circuit is configured to receive a first control signal from an inverter input terminal and generate a second control signal at an inverter output terminal. The first control signal carries power status information of a first supply voltage. The latch circuit has a latch supply terminal, a first latch input terminal and a second latch input terminal. The latch supply terminal is coupled to a second supply voltage becoming ready before the first supply voltage. The first latch input terminal and the second latch input terminal are coupled to the inverter output terminal and the inverter input terminal respectively. The latch circuit is configured to generate a third control signal according to respective signal levels of the first control signal and the second control signal, and accordingly perform power control of an integrated circuit.

A four-input lookup table (“LUT4”) is modified to operate in a first mode as an ordinary LUT4 and in a second mode as a 1-bit adder providing a sum output and a carry output. A six-input lookup table (“LUT6”) is modified to operate in a first mode as an ordinary LUT6 with a single output and in a second mode as a 2-bit adder providing a sum output and a carry output. Both possible results for the two different possible carry inputs can be determined and selected between when the carry input is available, implementing a 2-bit carry-select adder when in the second mode and retaining the ability to operate as an ordinary LUT6 in the first mode. Using the novel LUT6 design in a circuit chip fabric allows a 2-bit adder slice to be built that efficiently makes use of the LUT6 without requiring additional logic blocks.

A four-input lookup table (“LUT4”) is modified to operate in a first mode as an ordinary LUT4 and in a second mode as a 1-bit adder providing a sum output and a carry output. A six-input lookup table (“LUT6”) is modified to operate in a first mode as an ordinary LUT6 with a single output and in a second mode as a 2-bit adder providing a sum output and a carry output. Both possible results for the two different possible carry inputs can be determined and selected between when the carry input is available, implementing a 2-bit carry-select adder when in the second mode and retaining the ability to operate as an ordinary LUT6 in the first mode. Using the novel LUT6 design in a circuit chip fabric allows a 2-bit adder slice to be built that efficiently makes use of the LUT6 without requiring additional logic blocks.

An arbitration control circuit in a pseudo-static random access memory (PSRAM) device includes a first arbiter circuit and a second arbiter circuit. The first arbiter circuit receives a normal access request signal and a refresh access request signal and generates a first output signal in response to a logical operation to arbitrate between the normal access reqeuest signal and the refresh access request signal. The second arbiter circuit configured to receive the first output signal and a delayed signal of the first output signal, and to generate a second output signal in response to a logical operation of the first output signal and the delayed signal. The second output signal has a first logical state indicative of granting the read or write access request and a second logical state indicative of granting the refresh access request to the memory cells of the PSRAM device.

An arbitration control circuit in a pseudo-static random access memory (PSRAM) device includes a first arbiter circuit and a second arbiter circuit. The first arbiter circuit receives a normal access request signal and a refresh access request signal and generates a first output signal in response to a logical operation to arbitrate between the normal access reqeuest signal and the refresh access request signal. The second arbiter circuit configured to receive the first output signal and a delayed signal of the first output signal, and to generate a second output signal in response to a logical operation of the first output signal and the delayed signal. The second output signal has a first logical state indicative of granting the read or write access request and a second logical state indicative of granting the refresh access request to the memory cells of the PSRAM device.