Abstract: A module substrate has a plurality of module data terminal pairs individually provided in association with respective chip data terminals in a plurality of memory chips, and a plurality of module data wirings which respectively connect between the plurality of module data terminal pairs. The plurality of module data wirings are connected to their corresponding chip data terminals and are configured so as to be available as a memory access data bus. In a memory system in which a plurality of memory modules are arranged in parallel, module data wirings of each of the individual memory modules are connected in serial form, and each of the individual module data wirings do not constitute branch wirings with respect to a data bus on a motherboard of the memory system. In the memory modules, parallel access for the number of bits corresponding to the width of the memory access data bus is assured.

Abstract: A semiconductor device integrated on a chip includes a memory cell array, multiple processing elements and multiple data transfer circuits which transfer data between memory cells and the processing elements over read paths and write paths provided separately. The divide is capable of transferring data from memory cells to the processing elements and from the processing elements to memory cells concurrently over the read paths and write paths, respectively, so that faster image data processing is accomplished, and also capable of processing data on once-activated word lines successively thereby to reduce the number of times of driving of each word line so that the power consumption is reduced.

Abstract: A module substrate has a plurality of module data terminal pairs individually provided in association with respective chip data terminals in a plurality of memory chips, and a plurality of module data wirings which respectively connect between the plurality of module data terminal pairs. The plurality of module data wirings are connected to their corresponding chip data terminals and are configured so as to be available as a memory access data bus. In a memory system in which a plurality of memory modules are arranged in parallel, module data wirings of each individual memory modules are connected in serial form, and each individual module data wirings do not constitute branch wirings with respect to a data bus on a motherboard of the memory system. In the memory modules, parallel access for the number of bits corresponding to the width of the memory access data bus is assured.

Abstract: A clock-generating circuit for forming internal clock signals by comparing a signal obtained by delaying, through a variable delay circuit, an input clock signal input through an external terminal with the input clock signal through a phase comparator circuit, and so controlling the delay time of the variable delay circuit that they are brought into agreement with each other, wherein the clock-generating circuit and an internal circuit to be operated by the clock signals formed thereby are formed on a common semiconductor substrate, and an element-forming region in which the clock-generating circuit is formed is electrically isolated from an element-forming region in which the digital circuit is constituted on the semiconductor substrate relying upon the element-isolation technology. The power-source passages, too, are formed independently of other digital circuits.

Abstract: A memory system comprises a controller capable of controlling a memory operation, and memory connectors capable of mounting memory modules therein, both of which are provided on a system board. Each of the memory modules has a plurality of memory chips connected to module data wirings and module power wirings respectively. The module data wirings of each memory module are connected in series form through series paths lying within the connectors. Each individual module data wirings do not constitute branch wirings to system data wirings on the system board. Thus, such signal reflection as caused by branching from the data wirings on the system board is not developed. Since the power is supplied in parallel from the system board through parallel paths lying within the connectors, the supply of the power is stabilized.

Abstract: A semiconductor memory device of a DDR configuration improved in glitch immunity and the convenience of use is to be provided. It is a dynamic type RAM the operation of whose internal circuit is controlled in synchronism with a clock signal; an input circuit is provided in which a second clock signal inputted when in write operation is used to take in a plurality of write data serially inputted in response to that signal into a plurality of first latch circuits, and said first clock signal is used to take the write data taken into the first latch circuits into the second latch circuit to convey them to an input/output data bus; a logic circuit is provided to mask, in accordance with the logic of the first clock signal and the second clock signal, any noise arising at the end of the second clock signal, and a third clock signal is generated and supplied to the first latch circuits which output the write data to at least the input of the second latch circuits.

Abstract: It is possible to reduce the voltage drop on sub-power supply lines for reducing the subthreshold current and thereby prevent the operating speed of a logic circuit from lowering. Main power supply lines are arranged along one side of a rectangular region including a MOS logic circuit whose subthreshold current must be reduced, and a plurality of sub-power supply lines are arranged on the region in the direction perpendicular to the main power supply lines. A plurality of switching MOS transistors for selectively electrically connecting the sub-power supply lines to the main power supply line are dispersedly arranged with respect to the main power supply line. By dispersedly arranging the switching MOS transistors with respect to the main power supply line, it is possible to reduce the equivalent resistance of the sub-power supply lines compared to the case where switching MOS transistors are provided at one place.

Abstract: A semiconductor memory device realizing a reduced cycle time while improving the ease of use is to be provided.

Abstract: A semiconductor integrated circuit includes a logic circuit which is formed of p-channel MIS transistors and n-channel MIS transistors, a first oscillation circuit of variable oscillation frequency which is formed of p-channel MIS transistors and n-channel MIS transistors, a control circuit which produces a control signal for controlling the threshold voltage of the p-channel and n-channel MIS transistors, and a second oscillation circuit which produces multiple reference clock signals of different frequencies depending on operation mode. The control circuit receives a reference clock signal and controls first oscillation circuit with the control signal so that the oscillation frequency of the first oscillation circuit corresponds to the frequency of the reference clock signal.

Abstract: A clock-generating circuit for forming internal clock signals by comparing a signal obtained by delaying, through a variable delay circuit, an input clock signal input through an external terminal with the input clock signal through a phase comparator circuit, and so controlling the delay time of the variable delay circuit that they are brought into agreement with each other, wherein the clock-generating circuit and an internal circuit to be operated by the clock signals formed thereby are formed on a common semiconductor substrate, and an element-forming region in which the clock-generating circuit is formed is electrically isolated from an element-forming region in which the digital circuit is constituted on the semiconductor substrate relying upon the element-isolation technology. The power-source passages, too, are formed independently of other digital circuits.

Abstract: When there is a difference in the lengths of the passages among the parallel data wirings or a difference in the load capacitances inclusive of parasitic elements, a difference in the propagation time among the data becomes no longer negligible. At the time of transmitting data at high speeds in a short period, in particular, the setup time for receiving the data and the holding time are no longer maintained, and the data are not normally transmitted. In a data transmitter provided to address this problem, the receiver for receiving parallel data is provided with a simultaneous arrival judging circuit for comparing phases of part or whole bits of the received data, and with a timing adjusting mechanism for adjusting phases among the parallel bits at a point of receiving data in the receiver based on the judged results of the simultaneous arrival judging circuit, so that the data bits arrive simultaneously at the receiver.

Abstract: A large difference in the lengths of the passages or a large difference in the load capacitances inclusive of parasitic elements of parallel data wirings can cause differences in the propagation time of data on the parallel data wirings. The invention provides a simultaneous arrival judging circuit for comparing phases of part or whole bits of data received from the parallel data wirings, and a timing adjusting mechanism for adjusting phases among parallel bits of the received data based on the judged results of the simultaneous arrival judging circuit, so that the data bits arrive simultaneously at a receiver.

Abstract: A semiconductor integrated circuit comprises a logic circuit which is formed of p-channel MIS transistors and n-channel MIS transistors, a first oscillation circuit of variable oscillation frequency which is formed of p-channel MIS transistors and n-channel MIS transistors, a control circuit which produces a control signal for controlling the threshold voltage of the p-channel and n-channel MIS transistors, and a second oscillation circuit which produces multiple preference clock signals of different frequencies depending on the operation mode. The control circuit receives a reference clock signal and controls the first oscillation circuit with the control signal so that the oscillation frequency of the first oscillation circuit is correspondent to the frequency of the reference clock signal.

Abstract: A field-effect semiconductor element implemented with a fewer number of elements and a reduced area and capable of storing data by itself without need for cooling at a cryogenic temperature, and a memory device employing the same. Gate-channel capacitance is set so small that whether or not a trap captures one electron or hole can definitely and distinctively be detected in terms of changes of a current of the semiconductor FET element. By detecting a change in a threshold voltage of the semiconductor element brought about by trapping of electron or hole in the trap, data storage can be realized at a room temperature.

Abstract: It is possible to reduce the voltage drop on sub-power supply lines for reducing the subthreshold current and thereby prevent the operating speed of a logic circuit from lowering. Main power supply lines are arranged along one side of a rectangular region including a MOS logic circuit whose subthreshold current must be reduced, and a plurality of sub-power supply lines are arranged on the region in the direction perpendicular to the main power supply lines. A plurality of switching MOS transistors for selectively electrically connecting the sub-power supply lines to the main power supply line are dispersedly arranged with respect to the main power supply line. By dispersedly arranging the switching MOS transistors with respect to the main power supply line, it is possible to reduce the equivalent resistance of the sub-power supply lines compared to the case where switching MOS transistors are provided at one place.

Abstract: A field-effect semiconductor element implemented with a fewer number of elements and a reduced area and capable of storing data by itself without need for cooling at a cryogenic temperature, and a memory device employing the same. Gate-channel capacitance is set so small that whether or not a trap captures one electron or hole can definitely and distinctively be detected in terms of changes of a current of the semiconductor FET element. By detecting a change in a threshold voltage of the semiconductor element brought about by trapping of electron or hole in the trap, data storage can be realized at a room temperature.

Abstract: A module substrate has a plurality of module data terminal pairs individually provided in association with respective chip data terminals in a plurality of memory chips, and a plurality of module data wirings which respectively connect between the plurality of module data terminal pairs. The plurality of module data wirings are connected to their corresponding chip data terminals and are configured so as to be available as a memory access data bus. In a memory system in which a plurality of memory modules are arranged in parallel, module data wirings of each individual memory modules are connected in serial form, and each individual module data wirings do not constitute branch wirings with respect to a data bus on a motherboard of the memory system. In the memory modules, parallel access for the number of bits corresponding to the width of the memory access data bus is assured.

Abstract: A field-effect semiconductor element implemented with a reduced number of elements and a reduced area and capable of storing data by itself without need for cooling at a cryogenic temperature, and a memory device employing the same. Gate-channel capacitance is set so small that whether or not a trap captures one electron or hole can definitely and distinctively be detected in terms of changes of a current of the semiconductor FET element. By detecting a change in a threshold voltage of the semiconductor element brought about by trapping of electron or hole in the trap, data storage can be realized at a room temperature. In accordance with one embodiment, a carrier confinement region, isolated from a channel and a gate of the semiconductor FET element, is provided to operate as a storage node for trapping the carrier or carriers.

Abstract: Control on the speed of operation of a delay loop from the output of a variable delay circuit to a delay control input thereof is performed. For example, frequency-dividing circuits are respectively placed at the input and output of the variable delay circuit. A signal obtained by frequency-dividing a signal outputted from the variable delay circuit is supplied to one input of a phase comparator through a dummy delay circuit, and a signal obtained by frequency-dividing the input of the variable delay circuit is supplied to the other input of the phase comparator. Phase control is performed according to the result of comparison between the phases of both signals.

Abstract: Disclosed is a one-chip ULSI which can carry out the fixed operation in a wide range of power supply voltage (1 V to 5.5 V). This one-chip ULSI is composed of a voltage converter circuit(s) which serves to a fixed internal voltage for a wide range of power supply voltage, an input/output buffer which can be adapted to several input/output levels, a dynamid RAM(s) which can operate at a power supply voltage of 2 V or less, etc. This one-chip ULSI can be applied to compact and portable electronic devices such as a lap-top type personal computer, an electronic pocket note book, a solid-state camera, etc.