Abstract: In an optical transmission system including at least one ring network configured by plural nodes, each node of the ring network is provided with the optical switch having connection configuration that the output in at least two directions of a signal input to the node is allowed and the output of the optical switch functions as input to another node included in the plural nodes.

Abstract: When threshold voltages of constituent transistors are reduced in order to operate an SRAM circuit at a low voltage, there is a problem in that a leakage current of the transistors is increased and, as a result, electric power consumption when the SRAM circuit is not operated while storing data is increased. Therefore, there is provided a technique for reducing the leakage current of MOS transistors in SRAM memory cells MC by controlling a potential of a source line ssl of the driver MOS transistors in the memory cells.

Abstract: A semiconductor integrated circuit which can respond to changes of the amount of retained data at the time of standby is provided. The semiconductor integrated circuit comprises a logic circuit (logic) and plural SRAM modules. The plural SRAM modules perform power control independently of the logic circuit, and an independent power control is performed among the plural SRAM modules. Specifically, one terminal and the other terminal of a potential control circuit of each SRAM module are coupled to a cell array and a local power line, respectively. The local power line of one SRAM module and the local power line of the other SRAM module share a shared local power line. A power switch of one SRAM module and a power switch of the other SRAM module are coupled in common to the shared local power line.

Abstract: A semiconductor device includes plural memory cells each having a first inverter and a second inverter, with an input of the first inverter being coupled to an output of the second inverter and an input of the second inverter being coupled to an output of the first inverter. The first and second inverters have drive transistors supplied with a source voltage where the source voltage is raised in response to a level shift of a control signal supplied to a switch of a control circuit. The control circuit further includes a resistance element in parallel with a MOS transistor connected as a diode.

Abstract: A semiconductor integrated circuit which can respond to changes of the amount of retained data at the time of standby is provided. The semiconductor integrated circuit comprises a logic circuit (logic) and plural SRAM modules. The plural SRAM modules perform power control independently of the logic circuit, and an independent power control is performed among the plural SRAM modules. Specifically, one terminal and the other terminal of a potential control circuit of each SRAM module are coupled to a cell array and a local power line, respectively. The local power line of one SRAM module and the local power line of the other SRAM module share a shared local power line. A power switch of one SRAM module and a power switch of the other SRAM module are coupled in common to the shared local power line.

Abstract: A logic circuit in a system LSI is provided with a power switch so as to cut off the switch at the time of standby, reducing leakage current. At the same time, an SRAM circuit of the system LSI controls a substrate bias to reduce leakage current.

Abstract: A semiconductor device includes: a first circuit block formed on a first semiconductor substrate having first and second sides extending in a first direction and third and fourth sides extending in a second direction intersecting with the first direction; a plurality of signal-line through vias that are connected to the first semiconductor substrate and transmit signals, which are output from the first circuit block, to a second circuit block formed on another second semiconductor substrate; and a plurality of power-supply through vias for supplying power to the first circuit block, and in the semiconductor device, the plurality of power-supply through vias are formed at edges of the first semiconductor substrate along the third and fourth sides and are formed in a plurality of rows in the first direction. Each circuit block has a power consuming mode in which power larger than the power consumption in a normal mode is consumed.

Abstract: A logic circuit in a system LSI is provided with a power switch so as to cut off the switch at the time of standby, reducing leakage current. At the same time, an SRAM circuit of the system LSI controls a substrate bias to reduce leakage current.

Abstract: An object of the present invention is to sufficiently supply power to three-dimensionally stacked LSI chips and to dispose common through vias in chips of different types. Also, another object is to propose a new test method for power-supply through silicon vias.

Abstract: To provide an LSI having a low power mode that can prevent an apparatus on which the LSI is mounted from resulting in performance degradation, etc. even when its electric power is not reduced in the low power mode. Devised is a circuit that instructs an operation mode and detects whether the LSI operates as specified by the mode, and that measures a current at the time of the low power mode in a pseudo manner and, if despite having shifted to the low power mode, the current is not reduced actually, issues an alarm signal.

Abstract: A CMOS circuit and a semiconductor device having small leakage current and a low threshold voltage, and which is operated at high speed and with a small voltage amplitude, including an output stage circuit having MOSTs configured such that when their gates and sources are respectively set to an equal voltage, subthreshold leakage currents substantially flow between their drains and sources, and upon deactivation, a voltage is applied to the gate of each of the MOSTs to cause a reverse bias to be applied between the gate and source of the MOST. Upon activation of the circuit, the MOST is held in a reverse bias state or controlled to a forward bias state according to an input voltage.

Abstract: High manufacturing yield is realized and variation in threshold voltage of each MOS transistor in a CMOS·SRAM is compensated. Body bias voltages are applied to wells for MOS transistors of each SRAM memory cell in any active mode of an information holding operation, a write operation and a read operation of an SRAM. Threshold voltages of PMOS and NMOS transistors of the SRAM are first measured. Control information is programmed into control memories according to results of determination. Levels of the body bias voltages are adjusted based on the programs so that variations in the threshold voltages of the MOS transistors of the CMOS·SRAM are controlled to a predetermined error span. Body bias voltage corresponding to a reverse body bias or an extremely shallow forward body bias is applied to a substrate for the MOS transistors with an operating voltage applied to the source of each MOS transistor.

Abstract: The need for mediation operation is eliminated by adoption of a connection topology in which a circuit for executing one transmission (TR—00T), and a circuit for executing a plurality of receptions (TR—10R, TR—20R, TR—30R) are connected to one penetration-electrode group (for example, TSVGL—0). In order to implement the connection topology even in the case of piling up a plurality of LSIs one after another, in particular, a programmable memory element for designating respective penetration-electrode ports for use in transmit, or for us in receive, and address allocation of the respective penetration-electrode ports is mounted in stacked LSIs.

Abstract: Back-gate voltage control provides a high speed and low power consumption LSI operable in a wide temperature range in which a MOS transistor having back gates is used specifically according to operating characteristics of a circuit. In the LSI, an FD-SOI structure having an embedded oxide film layer is used and a lower semiconductor region of the embedded oxide film layer is used as a back gate. A voltage for back gates in logic circuits having a small load in logic circuit block is controlled in response to activation of the block from outside of the block. Transistors, in which the gate and the back gate are connected to each other, are used for the circuit generating the back gate driving signal, and logic circuits having a heavy load such as circuit block output section, and the back gates are directly controlled according to a gate input signal.

Abstract: The semiconductor device makes a comparison between a word-line timing signal for determining a word-line activation time and a reference signal, applies a back-gate bias for enlarging a read margin when the result of the comparison represents a low condition of the read margin, and applies a back-gate bias for enlarging a write margin when the comparison result represents a low condition of the write margin. The reference signal is selected depending on whether to compensate an operating margin fluctuating according to the word-line activation time (or word-line pulse width), or to compensate an operating margin fluctuating according to the process fluctuation (or variation in threshold voltage). By controlling the back-gate biases according to the word-line pulse width, an operating margin fluctuating according to the word-line pulse width, and an operating margin fluctuating owing to the variation in threshold voltage during its fabrication are improved.

Abstract: Information technology equipment includes a circuit block, a local power source line for supplying a power source to the circuit block, a power source line, and a first transistor which is provided with a source-drain path thereof between the power source line and the local power source line, in which the first transistor is controlled to an OFF state in a first state, and is controlled to an ON state in a second state, and when the first state is shifted to the second state, the first transistor is controlled such that a rate of changing a current flowing in the source-drain path of the first transistor does not exceed a predetermined value.

Abstract: The invention provides a semiconductor integrated circuit device provided with an SRAM that satisfies the requirements for both the SNM and the write margin with a low supply voltage. The semiconductor integrated circuit device include: multiple static memory cells provided in correspondence with multiple word lines and multiple complimentary bit lines; multiple memory cell power supply lines that each supply an operational voltage to each of the multiple memory cells connected to the multiple complimentary bit lines each; multiple power supply circuits comprised of resistive units that each supply a power supply voltage to the memory cell power supply lines each; and a pre-charge circuit that supplies a pre-charge voltage corresponding to the power supply voltage to the complimentary bit lines, wherein the memory cell power supply lines are made to have coupling capacitances to thereby transmit a write signal on corresponding complimentary bit lines.

Abstract: A CMOS circuit and a semiconductor device having small leakage current and a low threshold voltage, and which is operated at high speed and with a small voltage amplitude, including an output stage circuit having MOSTs configured such that when their gates and sources are respectively set to an equal voltage, subthreshold leakage currents substantially flow between their drains and sources, and upon deactivation, a voltage is applied to the gate of each of the MOSTs to cause a reverse bias to be applied between the gate and source of the MOST. Upon activation of the circuit, the MOST is held in a reverse bias state or controlled to a forward bias state according to an input voltage.

Abstract: Objects of the invention are to minimize power consumption while maintaining the required information processing capabilities of an LSI chip by supplying multiple voltages to the LSI chip such that its circuit blocks receive necessary voltages and to prevent an increase in the chip area of the LSI chip and performance degradation of signal wires, which may result from the supply of the multiple voltages, by reducing the number of power supply wires. In an LSI chip to which two voltages are supplied, high voltage wires are more densely spaced than low voltage wires. By selectively applying voltages based on circuit block performance, it is possible to reduce power consumption while maintaining the amount of information processed by the LSI chip.

Abstract: An object of the present invention is to provide a technique of reducing the leakage current of a drive circuit for driving a circuit that must retain a potential (or information) when in its standby state. A semiconductor integrated circuit device of the present invention includes a drive circuit for driving a circuit block. This drive circuit is made up of a double gate transistor with gates having different gate oxide film thicknesses. When the circuit block is in its standby state, the gate of the double gate transistor having a thinner gate oxide film is turned off and that having a thicker gate oxide film is turned on. This arrangement allows a reduction in the leakage currents of both the circuit block and the drive circuit while allowing the drive circuit to deliver or cut off power to the circuit block.