Abstract: An object of the present invention is to reduce jitter dependent on data patterns by an interface receiver. Another object of the present invention is to provide an LSI capable of automatically adjusting a delay time for jitter reduction so as to be able to control its setting for each device. Since the jitter dependent on the data patterns can be expected according to how the previous state is being placed, the state of data received by the receiver is held, and the timing provided to fetch input data is adjusted according to the held state and the input data. As a control mechanism lying in the receiver, for determining a delay time dependent on the form of mounting, a driver transmits and receives pulse data set at one-cycle intervals and pulse data set at two-cycle intervals as test patterns. The receiver has an automatic control mechanism for determining a delay time optimal to a system from the difference between a rising time of each of pulses different in pulse width and its falling time.

Abstract: A data transfer method is executed to transit a three-state transmitting circuit from a high-impedance state into a data output state, transmit a preamble (dummy data) onto a bus, and sequentially transmit the essential data. The shortening of a waveform caused in the first data piece after the transition from the high-impedance state into the data output state is executed against the preamble and no shortening of a waveform is not brought about in the essential data subsequent to the preamble. This makes it possible to exclude the limitation on speeding up the data transfer imposed by the shortening of the waveform.

Abstract: A motherboard for backplane buses is provided that reduces noise due to entry of external signals into signal wiring which interconnects modules, or noise due to any external signals entering a power supply after being routed around the power supply. An EBG pattern formed up of two wiring regions different from each other in impedance is periodically disposed in at least three arrays as part of the power supply layer(s) constituting a microstripline structure (one layer adjacent to a signal layer is a power supply layer, and the other layer is interposed in air) or a stripline structure (both layers adjacent to a signal layer are power supply layers); the part of the power supply layer(s) not being involved in signal transmission between the modules on the motherboard for backplane buses.

Abstract: In each of the information processing apparatuses connected to each other via a network, there is arranged a quality of service (QOS) table to which functions and performance thereof are registered. When an information processing apparatus is additionally linked with the network, a QOS table thereof is automatically registered to a local directory of the network such that an agent converts the contents of the QOS table into service information to be supplied via a user interface to the user. Thanks to the operation, information of functions and performance of each information processing apparatus connected to the network is converted into service information for the user. Consequently, the user can much more directly receive necessary services.

Abstract: In ultrahigh speed data transfer, a drive pulse is attenuated due to a skin effect and a dielectric loss, and a tail generated by a sub coupler extends as the drive pulse propagates on the main line. For that reason, an intersymbol interference becomes large, which causes jitters. In a memory system to which a plurality of DRAM memory modules are connected, in order to transfer data at high-speed, directional couplers are wired between a main controller and each of the modules, and the coupling lengths become longer with farther ends, thereby suppressing jitters. The directional couplers are wired between the main controller and each of the modules, and the coupling lengths are made longer with the farther ends with the results that the generated signal amounts are made constant, and jitters of the wiring and receiver delay are suppressed.

Abstract: A semiconductor storage employs a base substrate (101) having a command/address external terminal group (CA), a data input/output external terminal group (DQ), and a single chip select external terminal (CS), and also comprises a plurality of memory chips (110) to (113) mounted on a base substrate (101), each of which can individually carry out read and write operations. The terminals (CA), (DQ), and (CS) are connected to an interface chip (120). The interface chip (120) has a chip select signal generation circuit that can individually activate a plurality of memory chips (110) to (113) on the basis of an address signal fed by way of the terminal (CA) and on the basis of a chip select signal fed by way of the terminal (CS).

Abstract: As a power feed route in a semiconductor chip, a power feed route which reduces antiresonance impedance in the frequency range of tens of MHz is to be realized thereby to suppress power noise in a semiconductor device. By inserting structures which raise the resistance in the medium frequency band into parts where the resistance is intrinsically high, such as power wiring in a semiconductor package and capacitor interconnecting electrode parts, the antiresonance impedance in the medium frequency band can be effectively reduced while keeping the impedance low at the low frequency.

Abstract: In the case where high speed differential signals are transmitted in differential transmission lines through via holes with open-stubs, signal waveforms are distorted due to impedance mismatch in the open-stubs of the via holes, thus causing jitter, which has become an issue of high speed signals. For differential transmission lines that pass through via holes with open-stubs, a degree of coupling of the lines is decreased while the differential characteristic impedance is made constant. Thereby, the effects of backward cross talk noise caused by the coupling can be minimized, and thus jitter can be suppressed.

Abstract: In a memory module, a plurality of memories are mounted on a module base plate, impedance between Vref and Vss near each memory is coupled to Vss by a decoupling capacitor and a Vref plane to achieve low impedance configuration in a wide frequency range, Vref planes are individually provided for the respective memories, and the Vref planes are connected to each other by using a high impedance wire, or a high impedance chip part. Accordingly, a wiring technique for a module which allows effective reduction of self noise and propagation noise can be provided.

Abstract: In each of the information processing apparatuses connected to each other via a network, there is arranged a quality of service (QOS) table to which functions and performance thereof are registered. When an information processing apparatus is additionally linked with the network, a QOS table thereof is automatically registered to a local directory of the network such that an agent converts the contents of the QOS table into service information to be supplied via a user interface to the user. Thanks to the operation, information of functions and performance of each information processing apparatus connected to the network is converted into service information for the user. Consequently, the user can much more directly receive necessary services.

Abstract: A technique capable of achieving both improvement of mounting density and noise reduction for a semiconductor device is provided. An LSI mounted on a printed wiring board comprises a grounding BGA ball and a power BGA ball to get power supply from the printed wiring board, and the grounding BGA ball and the power BGA ball are arranged closely to each other. A decoupling capacitor is mounted on the printed wiring board and has a first terminal and a second terminal. The grounding BGA ball and the first terminal are connected by a first metal electrode plate, and the power BGA ball and the second terminal are connected by a second metal electrode plate. The first metal electrode plate and the second metal electrode plate interpose a dielectric film having a thickness equal to or smaller than 1 ?m therebetween.

Abstract: A semiconductor chip and a semiconductor device mounting the semiconductor chip capable of increasing a capacitance of a capacitor without reducing the number of signal bumps or power bumps of a package and the number of C4 solder balls of the semiconductor chip, and achieving a stable power supply with suppressing fluctuations of power at a resonance frequency without a limitation in a position to mount a capacitor for lowering noise of a signal transceiving interface block. In the semiconductor device, a via hole is provided to the semiconductor chip, a power-supply electrode connected to the via hole is provided to a back surface of the semiconductor chip, and a capacitor is mounted to the electrode on the back surface. And, a high-resistance material is used for a material of a power-supply via hole inside the semiconductor chip, thereby increasing the resistance and lowering the Q factor.

Abstract: Input circuit ensuring a noise margin for a reference voltage. A semiconductor chip 11a comprises a pad 14 that inputs a reference voltage Vref, an input circuit 13, a resistance element R1 connected between an input terminal of the input circuit 13 and the pad 14, a capacitance element C1 connected between the input terminal of the input circuit 13 and a power supply VDD, and a capacitance element C2 connected between the input terminal of the input circuit 13 and a ground VSS within the semiconductor chip. A resistance value of the resistance element R1 is set based on an impedance characteristic of a network, for supplying the reference voltage Vref.

Abstract: In a prior art, there has been a method in which a power supply line of an output buffer and that of a control circuit are independently provided so that the power supply noise occurring in the control circuit will not affect the output buffer. However, this method has had the problems that it increases both the number of power supply/grounding pins and power feed line inductance. The present invention provides a technique which, without causing the above two problems, i.e., (1) increased number of power supply/grounding pins and (2) increased power feed line inductance, prevents the noise causing a problem in a control circuit, from becoming routed around and induced into an output buffer.

Abstract: Stacked semiconductor device includes plural memory chips, stacked together, in which waveform distortion at high speed transmission is removed. Stacked semiconductor device 1 includes plural memory chips 11, 12 stacked together. Data strobe signal (DQS) and inverted data strobe signal (/DQS), as control signals for inputting/outputting data twice per cycle, are used as two single-ended data strobe signals. Data strobe signal and inverted data strobe signal mate with each other. Data strobe signal line for the data strobe signal L4 is connected to data strobe signal (DQS) pad of first memory chip 11. Inverted data strobe signal line for /DQS signal L5 is connected to inverted data strobe signal (/DQS) pad of second memory chip 12.

Abstract: The present invention realizes high density mounting along with achieving power source sharing by a digital semiconductor element and an analog semiconductor element in a semiconductor device. An power layer for analog is connected to one end of an EBG layer, a power layer for digital is connected to the other end of the EBG layer, ground terminals for the respective elements are connected to a common ground layer, and a ground layer for separating the power layer for analog and the EBG layer from each other is disposed between the power layer for analog and the EBG layer. Thereby, high density mounting is achieved along with reducing interference of power source to an analog chip.

Abstract: A clock is located at a position close to a plurality of memory modules connected to a memory controller and located away from the controller, and wiring is carried out so that read access is preferential for transmission of read data. With respect to write data, a delay amount corresponding to a round-trip propagation delay time to each of the modules is measured and writing of the write data is carried out while maintaining a known time relationship between the clock and data. To measure round-trip reflection, lines are wired between the modules and a location detection circuit in a 1:1 relationship, and the circuit measures a time taken from a signal output time of a driver having the same impedance as that of the wired lines to a reflected-wave reception time of a hysteresis receiver.

Abstract: In a prior art, there has been a method in which a power supply line of an output buffer and that of a control circuit are independently provided so that the power supply noise occurring in the control circuit will not affect the output buffer. However, this method has had the problems that it increases both the number of power supply/grounding pins and power feed line inductance. The present invention provides a technique which, without causing the above two problems, i.e., (1) increased number of power supply/grounding pins and (2) increased power feed line inductance, prevents the noise causing a problem in a control circuit, from becoming routed around and induced into an output buffer.

Abstract: In the case where high speed differential signals are transmitted in differential transmission lines through via holes with open-stubs, signal waveforms are distorted due to impedance mismatch in the open-stubs of the via holes, thus causing jitter, which has become an issue of high speed signals. For differential transmission lines that pass through via holes with open-stubs, a degree of coupling of the lines is decreased while the differential characteristic impedance is made constant. Thereby, the effects of backward cross talk noise caused by the coupling can be minimized, and thus jitter can be suppressed.

Abstract: The present invention provides a technique which, without causing two problems, i.e., (1) increased number of power supply/grounding pins and (2) increased power feed line inductance, prevents the noise causing a problem in a control circuit, from becoming routed around and induced into an output buffer. More specifically, the above can be realized by using either of two methods: (A) providing an on-chip bypass capacitor for the control circuit and isolating a power feed route of the control circuit from that of the output buffer in an AC-like manner, or (B) designing electrical parameters (inserting resistors) such that the oscillation mode of any electrical parameter noise induced into the power feed routes will change to overdamping.