Patent application number | Description | Published |
20120273773 | SEMICONDUCTOR DEVICE - Provided is a semiconductor device which has low power consumption and can operate at high speed. The semiconductor device includes a memory element including a first transistor including crystalline silicon in a channel formation region, a capacitor for storing data of the memory element, and a second transistor which is a switching element for controlling supply, storage, and release of charge in the capacitor. The second transistor is provided over an insulating film covering the first transistor. The first and second transistors have a source electrode or a drain electrode in common. | 11-01-2012 |
20120275214 | SEMICONDUCTOR DEVICE AND DRIVING METHOD THEREOF - In a memory module including a memory cell array including memory cells arranged in matrix, each including a first transistor using an oxide semiconductor and a first capacitor; a reference cell including a p-channel third transistor, a second capacitor, and a second transistor using an oxide semiconductor; and a refresh timing detection circuit including a resistor and a comparator, wherein when a potential is supplied to the first capacitor through the first transistor, a potential is supplied to the second capacitor through the second transistor, wherein a drain current value of the third transistor is changed in accordance with the potential stored in the second capacitor, and wherein when the drain current value of the third transistor is higher than a given value, a refresh operation of the memory cell array and the reference cell are performed. | 11-01-2012 |
20130069132 | SEMICONDUCTOR STORAGE DEVICE - Probability of malfunction of a semiconductor storage device is reduced. A shielding layer is provided between a memory cell array (e.g., a memory cell array including a transistor formed using an oxide semiconductor material) and a peripheral circuit (e.g., a peripheral circuit including a transistor formed using a semiconductor substrate), which are stacked. With this structure, the memory cell array and the peripheral circuit can be shielded from radiation noise generated between the memory cell array and the peripheral circuit. Thus, probability of malfunction of the semiconductor storage device can be reduced. | 03-21-2013 |
20130135185 | DRIVER CIRCUIT FOR DISPLAY DEVICE AND DISPLAY DEVICE INCLUDING THE DRIVER CIRCUIT - A display device driver circuit in which a lookup table can be written into a memory circuit within a retrace period even when the lookup table is constantly reconstructed in accordance with a change in the external environment and stored in the memory circuit, and data of the lookup table can be held even if supply of power supply voltage stops. In a driver circuit for a display device, a memory circuit including a transistor having a semiconductor layer containing an oxide semiconductor is used as a memory circuit that stores a lookup table for correcting image signals in accordance with a change in the external environment. | 05-30-2013 |
20130148411 | MEMORY DEVICE - A memory device including first to fourth memory cell arrays and a driver circuit including a pair of bit line driver circuits and a pair of word line driver circuits is provided. The first to fourth memory cell arrays are overlap with the driver circuit. Each of the pair of bit line driver circuits and a plurality of bit lines are connected through connection points on an edge along the boundary between the first and second memory cell arrays or on an edge along the boundary between the third and fourth memory cell arrays. Each of the pair of word line driver circuits and a plurality of word lines are connected through second connection points on an edge along the boundary between the first and fourth memory cell arrays or on an edge along the boundary between the second and third memory cell arrays. | 06-13-2013 |
20130155790 | STORAGE DEVICE - Noise attributed to signals of a word line, in first and second bit lines which are overlapped with the same word line in memory cells stacked in a three-dimensional manner is reduced in a storage device with a folded bit-line architecture. The storage device includes a driver circuit including a sense amplifier, and first and second memory cell arrays which are stacked each other. The first memory cell array includes a first memory cell electrically connected to the first bit line and a first word line, and the second memory cell array includes a second memory cell electrically connected to the second bit line and a second word line. The first and second bit lines are electrically connected to the sense amplifier in the folded bit-line architecture. The first word line, first bit line, second bit line, and second word line are disposed in this manner over the driver circuit. | 06-20-2013 |
20140068300 | MICROCONTROLLER - To provide a microcontroller that can operate in a low power consumption mode. The microcontroller includes a CPU, a memory, and a peripheral circuit such as a timer circuit. A register of the peripheral circuit is formed at an interface with a bus line. A power gate is provided for control of power supply, and the microcontroller can operate in the low power consumption mode where some circuits alone are active, in addition to in a normal operation mode where all circuits are active. A register with no power supply in the low power consumption mode, such as a register of the CPU, includes a volatile memory and a nonvolatile memory. | 03-06-2014 |
20140108836 | MICROCONTROLLER AND METHOD FOR MANUFACTURING THE SAME - A microcontroller which operates in a low power consumption mode is provided. A microcontroller includes a CPU, a memory, and a peripheral circuit such as a timer circuit. A register in the peripheral circuit is provided in an interface with a bus line. A power gate for controlling supply control is provided. The microcontroller can operate not only in a normal operation mode where all circuits are active, but also in a low power consumption mode where some of the circuits are active. A volatile memory and nonvolatile memory are provided in a register, such as a register of the CPU. Data in the volatile memory is backed up in the nonvolatile memory before the power supply is stopped. In the case where the operation mode returns to the normal mode, when power supply is started again, data in the nonvolatile memory is written back into the volatile memory. | 04-17-2014 |
20140121787 | CENTRAL CONTROL SYSTEM - Provided is a structure which is capable of central control of an electric device and a sensor device and a structure which can reduce power consumption of an electric device and a sensor device. A central control system includes at least a central control device, an output unit, and an electric device or a sensor device. The central control device performs arithmetic processing on information transmitted from the electric device or the sensor device and makes the output unit output information obtained by the arithmetic processing. It is possible to know the state of the electric device or the sensor device even apart from the electric device or the sensor device. The electric device or the sensor device includes a transistor which includes an activation layer using a semiconductor with the band gap wider than that of single crystal silicon. | 05-01-2014 |
20140310533 | SEMICONDUCTOR DEVICE AND METHOD FOR DRIVING THE SAME - An object is to solve all of the following problems caused when a volatile register and a non-volatile register are used as registers in a processor: degradation of the integrity of data stored in the non-volatile register; loss of data security due to the processor and a non-volatile memory device that are provided apart from each other; and slow data processing speed due to wiring delay or the like caused by these devices provided apart from each other. When data maintained in the volatile register is stored in the non-volatile register before supply of power supply voltage is stopped, the data is encrypted by an encryption circuit and stored in a non-volatile memory device that is provided separately from the processor. Then, the data stored in the non-volatile register is compared with the compressed and encrypted data stored in the non-volatile memory device. | 10-16-2014 |
20140355339 | DRIVING METHOD OF SEMICONDUCTOR DEVICE - In a memory cell including first to third transistors, the potential of a bit line is set to VDD or GND when data is written through the first transistor. In a standby period, the potential of the bit line is set to GND. In reading operation, the bit line is brought into a floating state at GND, and a source line is set to a potential VDD−α, consequently, the third transistor is turned on. Then, the potential of the source line is output according to the potential of a gate of the second transistor. Note that α is set so that the second transistor is surely off even when the potential of the gate of the second transistor becomes lower from VDD by ΔV in the standby period. That is, Vth+ΔV<α is satisfied where Vth is the threshold value of the second transistor. | 12-04-2014 |
20150054571 | CHARGE PUMP CIRCUIT AND SEMICONDUCTOR DEVICE INCLUDING THE SAME - Efficiency of a charge pump circuit is increased. The charge pump circuit includes serially connected fundamental circuits each including a diode-connected transistor and a capacitor. At least one transistor is provided with a back gate, and the back gate is connected to any node in the charge pump circuit. For example, the charge pump circuit is of a step-up type; in which case, if the transistor is an n-channel transistor, a back gate of the transistor in the last stage is connected to an output node of the charge pump circuit. Back gates of the transistors in the other stages are connected to an input node of the charge pump circuit. In this way, the voltage holding capability of the fundamental circuit in the last stage is increased, and the conversion efficiency can be increased because an increase in the threshold of the transistors in the other stages is prevented. | 02-26-2015 |