To provide an environmental sensor with reduced power consumption. A semiconductor device includes a first sensor, a second sensor, a control circuit, a transmission amplifier, a modulation circuit, a memory device, an analog-to-digital converter circuit, and an antenna. The memory device and the analog-to-digital converter circuit each include a transistor in which an oxide semiconductor is formed in a channel region. The second sensor is an optical sensor, and has a function of transmitting a trigger signal to the control circuit when receiving laser light. The control circuit has a function of transmitting a control signal to the first sensor, the transmission amplifier, the modulation circuit, the memory device, and the analog-to-digital converter circuit when receiving the trigger signal. The first sensor is a sensor that senses a physical or chemical quantity, and the measured data is subjected to digital conversion by the analog-to-digital converter circuit and stored in the memory device. In addition, the data is transmitted as an electromagnetic wave signal from the antenna through the modulation circuit and the transmission amplifier.

A method for controlling power supply in a semiconductor device including a CPU and a PLD which can hold data even in an off state is provided. The semiconductor device includes a processor, a programmable logic device, and a state control circuit. The programmable logic device includes a first nonvolatile memory circuit and has a function of holding data obtained by arithmetic processing of the programmable logic device when it is turned off. The state control circuit obtains data on the amount of a task performed by the programmable logic device in accordance with an operation of the processor. The programmable logic device detects the state of progress of the task and outputs a signal to the state control circuit. The state control circuit monitors the amount of the task and the state of progress of the task and turns off the programmable logic device when the task is completed.

An electronic circuit includes a cell array including memory cells each including a bistable circuit that includes first and second inverter circuits, each having a first mode characterized by there being substantially no hysteresis in transfer characteristics and a second mode characterized by there being hysteresis in the transfer characteristics, and being switchable between the first and second modes, and a control circuit configured to, after powering off a first memory cell that store data that are not required to be retained, put the bistable circuit in a remaining second memory cell into the second mode, and supply a second power supply voltage that allows the bistable circuit in the second mode to retain data and is lower than a first power supply voltage supplied to the bistable circuit when data is read and/or written, to the bistable circuit in the second memory cell while maintaining the second mode.

Disclosed is a data storage circuit that stores target input data inputted to a data input terminal and outputs the stored data as target output data through a data output terminal. The data storage circuit includes a clock control circuit that outputs a master clock signal and a slave clock signal based on a reference clock signal, a master latch circuit that takes the target input data based on the master clock signal, holds the taken data, and outputs the taken data as master output data, a slave latch circuit that takes the master output data based on the slave clock signal, holds the taken data, and outputs the taken data as slave output data, and an output data generation circuit that generates the target output data.

A memory cell includes: a latch, powered by a first reference voltage and a second reference voltage different from the first reference voltage, and having a first connecting terminal and a second connecting terminal; a first programmable fuse, having a first terminal coupled to the first connecting terminal and a second terminal coupled to the second reference voltage; and a second programmable fuse, having a first terminal coupled to the second connecting terminal and a second terminal coupled to the second reference voltage.

To provide an environmental sensor with reduced power consumption.

A semiconductor device includes a first sensor, a second sensor, a control circuit, a transmission amplifier, a modulation circuit, a memory device, an analog-to-digital converter circuit, and an antenna. The memory device and the analog-to-digital converter circuit each include a transistor in which an oxide semiconductor is formed in a channel region. The second sensor is an optical sensor, and has a function of transmitting a trigger signal to the control circuit when receiving laser light. The control circuit has a function of transmitting a control signal to the first sensor, the transmission amplifier, the modulation circuit, the memory device, and the analog-to-digital converter circuit when receiving the trigger signal. The first sensor is a sensor that senses a physical or chemical quantity, and the measured data is subjected to digital conversion by the analog-to-digital converter circuit and stored in the memory device. In addition, the data is transmitted as an electromagnetic wave signal from the antenna through the modulation circuit and the transmission amplifier.

Memory devices might include a controller for access of an array of memory cells and a differential storage device comprising a pair of gate-connected non-volatile memory cells, wherein the controller is configured to cause the memory device to obtain information indicative of a data value stored in a particular memory cell of the array of memory cells, program additional data to the particular memory cell, determine if a power loss to the memory device is indicated while programming the additional data to the particular memory cell, and, if a power loss to the memory device is indicated, selectively program one memory cell of the pair of gate-connected non-volatile memory cells responsive to the information indicative of the data value stored in the particular memory cell.

A semiconductor device has a first memory circuit comprising a first memory cell comprising a first field effect transistor, a second memory circuit comprising a second memory cell comprising a second field effect transistor, and a regulator for converting the first power supply potential to a second voltage value lower than the voltage value of the first power supply potential. The second gate length of the second field effect transistor is longer than the first gate length of the first field effect transistor, the first memory cell is supplied with a second power supply potential through regulator, and the second memory cell is supplied with a first power supply potential.

A depletion-mode FeFET (“FeDFET”) is programmable to a first programmed state, under a first set of voltage biasing conditions, and to a second programmed state, under a second set of voltage biasing conditions. In both the first and second programmed states, the storage transistor has a threshold voltage that is not greater than 0 volts. A memory circuit may be organized as memory cells, with each memory cell including select transistors, transistor switches and FeDFETs in a static random-access memory (SRAM) cell configuration.

To provide an environmental sensor with reduced power consumption. A semiconductor device includes a first sensor, a second sensor, a control circuit, a transmission amplifier, a modulation circuit, a memory device, an analog-to-digital converter circuit, and an antenna. The memory device and the analog-to-digital converter circuit each include a transistor in which an oxide semiconductor is formed in a channel region. The second sensor is an optical sensor, and has a function of transmitting a trigger signal to the control circuit when receiving laser light. The control circuit has a function of transmitting a control signal to the first sensor, the transmission amplifier, the modulation circuit, the memory device, and the analog-to-digital converter circuit when receiving the trigger signal. The first sensor is a sensor that senses a physical or chemical quantity, and the measured data is subjected to digital conversion by the analog-to-digital converter circuit and stored in the memory device. In addition, the data is transmitted as an electromagnetic wave signal from the antenna through the modulation circuit and the transmission amplifier.