Currently, a typical 5454 bit multiplier is composed of a parallel structured architecture with the encoder block to implement the Modified Booth's algorithm, a block to implement the data compression, and a 108-bit Carry Look-Ahead (CLA) adder. The key idea in the present paper is a power optimization for the data compressors based on a Window Detector. The role of the Window Detector is detecting the input data, activating a selected operation unit, choosing the optimized output data, and driving the next stage. It can reduce the power consumption drastically because only one selected operation unit (a Window) is activated. The power consumption of the proposed data compressors is reduced by about 33%, compared with that of the conventional multiplier; while the propagation delay is nearly same as that of the conventional one. Furthermore, the power consumption dependent on the input data transition is shown for both the static CMOS logic and the nMOS pass transistor logic.

We propose a high-sensitivity and wide-dynamic-range position sensor using logarithmic-response and correlation circuit. The 3-D measurement system using the proposed position sensor has advantages to applications, for example a walking robot and a recognition system on vehicles, which require both of availability in various backgrounds and safe light projection for human eyes. The position sensor with a 64 64 pixel array has been developed and successfully tested. We describe the sensitivity of position detection as SBR (Signal-to-Background Ratio). The minimum SBR of the sensor is -13.9 dB lower than standard sensors. High sensitivity under -10 dB SBR is realized in a dynamic range of 41.7 dB in terms of background illumination. Experimental results of position detection and 3-D measurement in a strong background illumination are also presented.

This paper demonstrates a pulse width controlled PLL without using an LPF. A pulse width controlled oscillator accepts the PFD output where its pulse width controls the oscillation frequency. In the pulse width controlled oscillator, the input pulse width is converted into soft thermometer code through a time to soft thermometer code converter and the code controls the ring oscillator frequency. By using this scheme, our PLL realizes LPF-less as well as quantization noise free operation. The prototype chip achieves 60 µm 20 µm layout area using 65 nm CMOS technology along with 1.73 ps rms jitter while consuming 2.81 mW under a 1.2 V supply with 3.125 GHz output frequency.

Dynamic performance of ultra-thin SIMOX (Separation by IMplanted OXgen) CMOS circuits has been studied using ring oscillators. A novel concept of current-delay product, along with an equivalent linear resistance of MOSFETs, is applied for deriving effective load capacitance of near 0.1 µm gate CMOS circuits. Calculation results showed quatitative agreement with measurement data. It was found that the gate-fringing capacitance limits the delay time is the case of under 0.2 µm gate-length. The lower bound of power-delay product of SIMOX/SOI is expected as low as 0.2 fJ for the gate length of 0.15 µm at the supply voltage of 1.5 V.

In this paper, we present a hierarchical multi-chip architecture which employs fully digital and word-parallel associative memories based on Hamming distance. High capacity scalability is critically important for associative memories since the required database capacity depends on the various applications. A multi-chip structure is most efficient for the capacity scalability as well as the standard memories, however, it is difficult for the conventional nearest-match associative memories. The present digital implementation is capable of detecting all the template data in order of the exact Hamming distance. Therefore, a hierarchical multi-chip structure is simply realized by using extra register buffers and an inter-chip pipelined priority decision circuit hierarchically embedded in multiple chips. It achieves fully chip- and word-parallel Hamming distance search with no throughput decrease, additional clock latency of O(log P), and inter-chip wires of O(P) in a P-chip structure. The feasibility of the architecture and circuit implementation has been demonstrated by post-layout simulations. The performance has been also estimated based on measurement results of a single-chip implementation.

This paper prsesnts a reduced swing signal data transmission method for the bus architectures in VLSIs, which consists of small size bus drivers of inverters, dual rail transmission lines, termination resistors and sense amplifiers for regenerating signal swing. The optimum value of signal swing and driving capacity of sense amplifier are given as functions of transmission line capacitance based on a criterion of areadelay2 for guideline. Using results of analysis, we propose a self-controlled data transmission module for the optimum reduced swing signal. Applying the method to a 32bit bus architecture, it is shown that total area, cycle time and total power consumption are 66,070[µm2], 0.90[ns], 32.2[mW], respectively, while those are 284,000[µm2], 1.12[ns], 173.4[mW], respectively, in the conventional chained buffer module. The proposed method is less noisy than the conventional chained buffer method.

A novel random number generation method based on chaotic sampling of regular waveform is proposed. A high speed IC truly random number generator based on this method is also presented. Simulation and experimental results, verifying the feasibility of the circuit, are given. Numerical binary data obtained according to the proposed method pass the four basic tests of FIPS-140-2, while experimental data pass the full NIST-800-22 random number test suite without post-processing.

This paper demonstrates a PLL compiler that generates the final GDSII data from a specification of input and output frequencies with PVT corner conditions. A Pulse Width Controlled PLLs (PWPLL) is composed of digital blocks, and thus suitable for being designed using a standard cell library and being layed out with a commercially available place-and-route (P&R) tool. A PWPLL has 8 design parameters. Our PLL compiler decides the 8 parameters and confirms the PLL operation with the following functions: 1) calculates rough parameter values based on an analytical model, 2) generates SPICE and gate-level verilog netlists with given parameter values, 3) runs SPICE simulations and analyzes the waveform, to examine the oscillation frequency or the voltage of specified nodes at a given time, 4) changes the parameter values to an appropriate direction depending on the waveform analyses to obtain the optimized parameter values, 5) generates scripts that can be used in commercial design tools and invokes the tools with the gate-level verilog netlist to get the final LVS/DRC-verified GDSII data from a P&R and a verification tools, and finally 6) generates the necessary characteristic summary sheets from the post-layout SPICE simulations extracted from the GDSII. Our compiler was applied to an 0.18µm standard CMOS technology to design a PLL with 600MHz output, 600/16MHz input frequency, and confirms the PLL operation with 1.2mW power and 85µm×85µm layout area.

This paper demonstrates a power supply noise reduction using on-board stubs. A quarter-length stub attached to the power supply line of an LSI chip works as a band-eliminate filter, and suppresses the power supply noise of the designed frequency. Preliminary experiments show that 87% of the designed frequency noise component is suppressed when stub patterns are written on a power supply area on a PCB board for a 1.25 GHz operating LSI. The results show the possibility of the stub on-chip integration when the operating frequency of LSIs becomes higher and the stub length becomes shorter.

A system level approach for a memory power reduction is proposed in this paper. The basic idea is allocating frequently executed object codes into a small subprogram memory and optimizing supply voltage and threshold voltage of the subprogram memory. Since large scale memory contains a lot of direct paths from power supply to ground, power dissipation caused by subthreshold leakage current is more serious than dynamic power dissipation. Our approach optimizes the size of subprogram memory, supply voltage, and threshold voltage so as to minimize memory power dissipation including static power dissipation caused by leakage current. A heuristic algorithm which determines code allocation, supply voltage, and threshold voltage simultaneously so as to minimize power dissipation of memories is proposed as well. Our experiments with some benchmark programs demonstrate significant energy reductions up to 80% over a program memory which does not employ our approach.

This paper proposes an on-chip measurement method of PLL through fully digital interface. For the measurement of the PLL transfer function, we modulated the phase of the PLL input in triangular form using Digital-to-Time Converter (DTC) and read out the response by Time-to-Digital Converter (TDC). Combination of the DTC and TDC can obtain the transfer function of the PLL both in the magnitude domain and the phase domain. Since the DTC and TDC can be controlled and observed by digital signals, the measurement can be conducted without any high speed analog signal. Moreover, since the DTC and TDC can be designed symmetrically, the measurement method is robust against Process, Voltage, and Temperature (PVT) variations. At the same time, the employment of the TDC also enables a measurement of the PLL lock range by changing the division ratio of the divider. Two time domain circuits were designed using 180nm CMOS process and the HSPICE simulation results demonstrated the measurement of the transfer function and lock range.

We propose a shot reduction technique of character projection (CP) Electron Beam Direct Writing (EBDW) using combined cell stencil (CCS) or the advanced process technology. CP EBDW is expected both to reduce mask costs and to realize quick turn around time. One of major issue of the conventional CP EBDW, however, is a throughput of lithography. The throughput is determined by numbers of shots, which are proportional to numbers of cell instances in LSIs. The conventional shot reduction techniques focus on optimization of cell stencil extraction, without any modifications on designed LSI mask patterns. The proposed technique employs the proposed combined cell stencil, with proposed modified design flow, for further shot reduction. We demonstrate 22.4% shot reduction within 4.3% area increase for a microprocessor and 28.6% shot reduction for IWLS benchmarks compared with the conventional technique.

This paper presents a structural approach for synthesizing arbitrary multi-output multi-stage static CMOS circuits at the transistor level, targeting the reduction of transistor counts. To make the problem tractable, the solution space is restricted to the circuit structures which can be obtained by performing algebraic transformations on an arbitrary prime-and-irredundant two-level circuit. The proposed algorithm is guaranteed to find the optimal solution within the solution space. The circuit structures are implicitly enumerated via structural transformations on a single graph structure, then a dynamic-programming based algorithm efficiently finds the minimum solution among them. Experimental results on a benchmark suite targeting standard cell implementations demonstrate the feasibility and effectiveness of the proposed approach. We also demonstrated the efficiency of the proposed algorithm by a numerical analysis on randomly-generated problems.

This paper demonstrates a feedforward active substrate noise cancelling technique using a power supply di/dt detector. Since the substrate is usually tied with the ground line with a low impedance, the substrate noise is closely related to the ground bounce which is proportional to the di/dt when inductance is dominant on the ground line impedance. Our active cancelling detects the di/dt of the power supply, and injects an anti-phase current into the substrate so that the di/dt-proportional substrate noise is cancelled out. Our first trial shows that 34% substrate noise reduction is achieved on our test circuit, and the theoretical analysis shows that the optimized canceller design will enhance the substrate noise suppression ratio up to 56%.

This paper describes the design and development of a module generator for a dual-rail PLA with embedded 2-input logic cells for 0.35 µm CMOS technology. In order to automatically generate logic-cell based PLA layouts from circuit specifications, a module generator as a design automation tool of logic-cell based PLA is developed with a structural improvement. This module generator is based on a timing-driven design methodology and consists of logic synthesis, transistor sizing and logic cell generation, stimulus generation, HDL model generation parts. This generator uses a design constraint to achieve a flexible transistor sizing in a logic cell generation part. In addition, generated logic cells can be easily adapted to a layout generator. The layout is generated by using 0.35 µm, 3-metal-layer CMOS technology. Moreover, an HDL model generator is developed to create delay behavior models easily and quickly with precise timing parameters. The design complexity which is becoming an important issue for VLSI circuits can be reduced partially and human caused errors are minimized by module generator. A PLA layout in GDS-II form and an HDL model behavior of a Boolean function which has 64-bit input, 1-bit output and 220 product term can be generated within 8 minutes on a SunUltraSPARC-III 900 MHz processor. A very short time is required to compile the module, and this makes it feasible for designers to try many different design configurations in order to get the better one.

A compact new test structure using shift register circuits for extracting components of the capacitance matrix of the multi-layer interconnections has been proposed. An extraction method of the capacitance matrix is also presented. As a result of fabrication, capacitance values obtained by measurement are in good agreement with the numerical calculation. We also showed an estimation method of the measurement errors.

This paper presents a decoupling capacitance boosting method for the resonant supply noise reduction by fast voltage hopping of DVS systems. The proposed method utilizes a foot transistor as a switch between a conventional decoupling capacitor (decap) and GND. The switching controls of the foot transistor depending on the supply noise states achieve an effective noise reduction as well as fast settling time compared with the conventional passive decaps. The measurement results of a test chip fabricated in a 0.18 µm CMOS technology show 12X boost of effective decap value, and 65.8% supply noise reduction with 96% settling time improvement.

In this paper, we present a 0.18-µm CMOS fully integrated X-band shock wave generator (SWG) with an on-chip dipole antenna and a digitally programmable delay circuit (DPDC) for pulse beam-formability in short-range and hand-held microwave active imaging applications. This chip includes a SWG, a 5-bit DPDC and an on-chip wide-band meandering dipole antenna. By using an integrated transformer, output pulse of the SWG is sent to the on-chip meandering dipole antenna. The SWG operates based on damping conditions to produce a 0.4-V peak-to-peak (p-p) pulse amplitude at the antenna input terminals in HSPICE simulation. The DPDC is designed to adjust delays of shock-wave outputs for the purpose of steering beams in antenna array systems. The wide-band dipole antenna element designed in the meandering shape is located in the top metal of a 5-metal-layer 0.18-µm CMOS chip. By simulating in Momentum of ADS 2009, the minimum value of antenna's return loss, S 11, and antenna's bandwidth (BW) are -19.37 dB and 25.3 GHz, respectively. The measured return loss of a stand-alone integrated meandering dipole is from -26 dB to -10 dB with frequency range of 7.5-12 GHz. In measurements of the SWG with the integrated antenna, by using a 20-dB standard gain horn antenna placed at a 38-mm distance from the chip's surface, a 1.1-mVp-p shock wave with a 9-11-GHz frequency response is received. A measured 3-ps pulse delay resolution is also obtained. These results prove that our proposed circuit is suitable for the purpose of fully integrated pulse beam-forming system.

This paper proposes a cell layout synthesis method via Boolean Satisfiability (SAT). Cell layout synthesis problems are first transformed into SAT problems by our formulations. Our method realizes a high-speed layout synthesis for CMOS logic cells and guarantees to generate the minimum-width cells with routability under our layout styles. It considers complementary P-/N-MOSFETs individually during transistor placement, and can generate smaller width layout compared with pairing the complementary P-/N-MOSFETs case. To demonstrate the effectiveness of our SAT-based cell synthesis, we present experimental results which compare it with the 0-1 ILP-based transistor placement method and a commercial cell generation tool. The experimental results show that our SAT-based method can generate minimum-width placements in much shorter run time than the 0-1 ILP-based transistor placement method, and can generate the cell layouts of 32 static dual CMOS logic circuits in 54% run time compared with the commercial tool. Area increase of our method without compaction is only 3% compared with the commercial tool with compaction.