A new memory cell arrangement for a gigabit-scale NAND DRAM is proposed. Although the conventional NAND DRAM in which memory cells are connected in series realizes the small die size, it faces a crucial array noise problem in the 1 gigabit generation and beyond because of its inherent noise of the open bitline arrangement. By introducing the new cell arrangement to a NAND DRAM, the folded bitline scheme is realized, resulting in good noise immunity. The basic operation of the proposed folded bitline scheme was successfully verified using the 64 kbit test chip. The die size of the proposed NAND DRAM with the folded bitline scheme (F-NAND DRAM) at the 1 Gbit generation is reduced to 63% of that of the conventional 1 Gbit DRAM with the folded bitline scheme, assuming the bitlines and the wordlines are fabricated with the same pitch. The new 4/4 bitline grouping scheme in which cell data are read out to four neighboring bitlines is also introduced to reduce the bitline-to-bitline coupling noise to half of that of the conventional folded bitline scheme. The array noise of the proposed F-NAND DRAM with the 4/4 bitline grouping scheme at 1 Gbit generation is reduced to 10% of the read-out signal, while that of the conventional NAND DRAM with open bitline scheme is 29%, and that of the conventional DRAM with the folded bitline scheme is 22%.

This paper reports on the design and performance of a very fast Track/Hold (T/H) circuit with GaAs Heterojunction Bipolar Transistor (HBT) to precede a 3GS/s 6 bit ADC. The T/H circuit employs a differential open-loop architecture for high-speed operation, and it consists of diode bridge switches, hold capacitors and output buffers. The differential structure as well as the output buffers suppress droop effects due to the small hFE (20) of our HBT. Measured results show that the T/H circuit has better than 6 bit linearity within an input range of 1.0 Vp-p with power dissipation of 990m W, and the bandwidth is 6 GHz in the track mode. The measured droop rate is 2.1mV/ns, the feedthrough is -46 dB 500 MHz and the hold pedestal is less than 10m V. Also a 3 GHz sampling operation of the T/H circuit was measured. The T/H circuit uses 43 HBTs, 24 Schottky barrier diodes and occupies a chip area of 1.4 1.75 mm2. We also describe the design and performance of a variable, gain amplifier with GaAs HBT to precede the T/H circuit as an input buffer and adjust its gain. These results support the possibility of meeting the requirements for a high-speed ADC system.

The concept of a basis matrix is introduced to investigate the trade-off between complexity and storage for multiplication in a finite field. The effect on the storage requirements of using polynomial and normal bases for element representation is also considered.

Periodic solutions of slow-fast systems called "canards," "ducks," or "lost solutions" are examined in a second order autonomous system. A characteristic feature of the canard is that the solution very slowly moves along the negative resistance of the slow curve. This feature comes from that the solution moves on or very close to a curve which is called slow manifolds or "rivers." To say reversely, solutions which move very close to the river are canards, this gives a heuristic definition of the canard. In this paper, the generation mechanism of the canard is examined using a piecewise linear system in which the cubic function is replaced by piecewise linear functions with three or four segments. Firstly, we pick out the rough characteristic feature of the vector field of the original nonlinear system with the cubic function. Then, using a piecewise linear model with three segments, it is shown that the slow manifold corresponding to the less eigenvalue of two positive real ones is the river in the segment which has the negative resistance. However, it is also shown that canards are never generated in the three segments piecewise linear model because of the existence of the "nodal type" invariant manifolds in the segment. In order to generate the canard, we propose a four segments piecewise linear model in which the property of the equilibrium point is an unstable focus.

Many efforts are currently underway to design wideband mobile communication systems. In this letter, we clarify the received signal level characteristics for wideband mobile radio channels in line-of-sight (LOS) microcells. We conduct several urban-area field experiments to measure the received signal levels for various receiver bandwidths from 300 kHz to 30 MHz and the power delay profile. The experimental results show that the fading depth of the received signal decreases as the normalized rms delay spread, defined as the product of receiver bandwidth and rms delay spread, increases. These results are useful in designing wideband microcell systems for urban areas.

This paper presents an 8-bit 200M-sample/s (Ms/s) analog-to-digital converter (ADC) applicable to liquid crystal display (LCD) driver systems. The ADC features such circuit techniques as a low-power and high-speed comparator, an open-loop sample-and-hold amplifier with a 3.4-ns acquisition time, a fully differential two step architecture, and a replica circuit. It is fabricated with a 0.8µm BiCMOS process onto an area of only 12mm2 and it dissipates 500mW from a single-5.2V power supply.

We propose an nn optical switch that is suitable for flexible and reliable optical access networks and for reconfigurable optical inter-module connections in large-scale processing systems. The switch consists of an intersecting waveguide matrix, matching oil, and microactuators. Switching is based on the movement of oil due to capillary pressure, which is controlled by the microactuator. The necessary switching conditions were calculated and the results showed that both the oil volume and the microactuator position must be controlled. A trial optical switch was fabricated to test the switching principle, and switching and self-holding were both confirmed. These results show the feasibility of a very small self-holding nn optical switch that uses a waveguide matrix and microactuators made by using microfabrication technologies.

A quantitative study is made on performance of neutron penumbral imaging with a toroidal-segment aperture, and it focused on isoplanaticity of aperture point spread function and effect of the non-isoplanaticity on the reconstructed images. The results show that the aperture point spread function is satisfactorily isoplanatic for a small field of view, while for a large field of view the point spread function is not satisfactorily isoplanatic resulting in some distortion in the reconstructed image and reduction of resolution.

Micromachined sensors and actuators applied with electrostatic fields are getting widely developed. At the same time, "electrets," which are dielectrics carrying non-equilibrium permanent space charges or polarization distribution, are in demand because they improve the transducer characteristics. In this paper, we have reported on our successful fabrication of silicon dioxide electrets with extremely superior long-term charge stability by plasma chemical vapor deposition (PCVD). We have also reported on the correlation between the deposition conditions, the long-term charge stability and thermally stimulated current (TSC). Finally, the characterization of the long-term stable electrets will be described and discussed.

In this paper, we show that a parity function with n variables can be computed by a threshold circuit of depth O((log n)/c) and size O((2clog n)/c), for all 1c [log(n+1)]-1. From this construction, we obtain an O(log n/log log n) upper bound for the depth of polylogarithmic size threshold circuits for parity functions. By using the result of Impagliazzo, Paturi and Saks[5], we also show an Ω (log n/log log n) lower bound for the depth of the threshold circuits. This is an answer to the open question posed in [11].

A design methodology of high performance deep submicron CMOS in very low voltage operation has been proposed from low power dissipation point of view. In low voltage operation, threshold voltage is restricted by performance, stability of CMOS circuits and power dissipation caused by standby and switching transient current. As a result, threshold voltage is established to be 0.15 V even at 1 V operation from these requirements. Moreover, according to this design, 0.15 µm CMOS was fabricated with reduction of parasitic effects. It achieved propagation delay time 50 psec at 1 V operation. This results confirms that this design methodology is promising to achieve high performance deep submicron CMOS devices for low power dissipation.

This paper describes an N-type and a P-type MOS cascode circuit based on the square-law characteristics of an MOS transistor in saturation region. The transconductance parameter ratios of an upper and a lower MOS transistor are set to be 1: n2 for the N-type MOS cascode circuit and n2: 1 for the P-type MOS cascode circuit. The N and P-type MOS cascode circuits are divided to four types by the difference of connections of input terminals. We consider the input-output relations of each type circuit. The second-order effects of the circuit such as channel length modulation effect, mobility reduction effect and device mismatch are analyzed. As applications, an analog voltage adder and a VT level shifter using MOS cascode circuits are presented. All of the proposed circuits are very simple and consist of only the N and P-type MOS cascode circuits. The proposed circuits aer confirmed by SPICE simulation with MOSIS 1.2µm CMOS process parameters.

This paper proposes a small 1/4Vcc bit-line swing scheme and a related sense amplifier scheme for low power 1 V operating DRAM. Using the proposed small bit-line swing scheme, the stress bias of memory cell transistor and capacitor is reduced to half that of the conventional DRAM, resulting in improvement of device reliability. The proposed sense amplifier scheme achieves high speed and stable sensing/restoring operation at 250mV bit-line swing, which is much smaller than threshold voltage. The proposed scheme reduces the total power dissipation of bit-line sensing/restoring operation to 40% of the conventional one. This paper also proposes a small 4F2 size memory cell and a new twisted bit-line scheme. The array noise is reduced to 8.6% of the conventional DRAM.

This paper is concerned with a point-oriented finite volume time domain (FVTD) method in the Cartesian coordinate system for analyzing electromagnetic wave scattering by arbitrary shaped metallic gratings. The perfectly matched layer (PML) is used for the absorbing boundary conditions (ABC's) in the directions corresponding to transmitted and reflected wave regions. An FVTD version of the Floquet's theorm is described to impose the periodic condition in the direction where conducting rods are located periodically. The boundary conditions for a conductor rod which is not well suited to the Cartesian coordinate system are satisfied in an average fashion by introducing image fields at image points. It is shown that the present method gives accurate numerical results. Numerical calculations are also carried out for thick conducting rods which seem difficult to deal with in an analytical way.

Petri nets are widely recognized as a powerful model for discrete event systems. Petri nets have both graphical and mathematical features. Graphical feature provides an environment to design and to comprehend discrete event systems. Mathematical feature provides an analysis power for verifying several properties of such systems. Several analysis techniques have been proposed so far, such as a reachability (coverability) graph method, a matrix equation approach, reduction or decomposition techniques, a symbolic model method and an unfolding method. The unfolding method was introduced to avoid generating the reachability graph. Unfoldings are often used in the verification of asynchronous circuits. This paper focuses on an analysis of finite state systems, i.e., bounded nets, and discuss a reachability problem and a upper bound problem. Relations between these problems and an unfolding have been clarified to provide a novel method to resolve these problems.

The printed dipole on a semi-infinite substrate is investigated. The solution is based on the moment method in the Fourier transform domain. We analyze far-field and near-field radiation patterns for a printed dipole. Therefore, we make radiation fields clear.

In the estimation of SAR (specific absorption rate) for a human phantom model, we proposed a method for using a double-loop probe to correct for the effects of the magnetic field reflected off the surface of the phantom. By comparing our experimental results with those obtained using an electric-field prove method, we were able to confim the accuracy of corrections made for the effects of a reflected magnetic field.

A piece of information on the polarization effects on the effective dielectric constant εeff of a medium whose dielectric circular cylinders are randomly distributed is obtained by analyzing εeff for both E-wave and H-wave incidences. Our numerical analysis shows clearly the difference of εeff between E-wave and H-wave incidences and also shows the difference of εeff between our method and the Foldy's approximation.

The estimation of model parameter is essentially important for an MRF image model to work well. Because the maximum likelihood estimate (MLE), which is statistically optimal, is too difficult to implement, the conventional estimates such as the maximum pseudo-likelihood estimate (MPLE), the coding method estimate (CME), and the least-squares estimate (LSE) are all based on the (conditional) pixel probabilities for simplicity. However, the conventional pixel-based estimators are not very satisfactorily accurate, especially when the interactions of pixels are strong. We therefore propose two window-based estimators to improve the estimation accuracy: the adjoining-conditional-window (ACW) scheme and the separated-conditional-window (SCW) scheme. The replacement of the pixel probabilities by the joint probabilities of window pixels was inspired by the fact that the pixels in an image present information in a joint way and hence the more pixels we deal with the joint probabilities of, the more accurate the estimate should be. The window-based estimators include the pixel-based ones as special cases. We present respectively the relationship between the MLE and each of the two window-based estimates. Through the relationships we provide a unified view that the conventional pixel-based estimates and our window-based estimates all approximate the MLE. The accuracy of all the estimates can be described by two types of superiority: the cross-scheme superiority that an ACW estimate is more accurate than the SCW estimate with the same window size, and the in-scheme superiority that an ACW (or SCW) estimate more accurate than another ACW (or SCW) estimate which uses smaller window size. The experimental results showed the two types of superiority and particularly the significant improvement in estimation accuracy due to using window probabilities instead of pixel probabilities.

The electromagnetic force of evanescent field acting on dielectric slab is studied with the use of Maxwell stress tensor. The results show that dielectrics slab may receive always an attractive force when the incident wave is evanescent field while a pressure or an attractive force when the wave is propagating one. The magnitude of the attractive force by evanescent field is much larger than that of the propagating wave. And here some numerical examples are given.