Neuron MOS binary-logic integrated circuits. I. Design fundamentalsand soft-hardware-logic circuit implementation

Described are the fundamental design principles for binary-logic circuits using a highly functional device called the neuron MOS transistor (νMOS), a single MOS transistor simulating the function of biological neurons. To facilitate logic design employing this transistor, a graphical technique called the floating-gate potential diagram has been developed. It is shown that any Boolean functions can be generated using a common circuit configuration of two-stage νMOS inverters. One of the most striking features of νMOS binary-logic application is the realization of a so-called soft hardware logic circuit. The circuit can be made to represent any logic function (AND, OR, NAND, NOR, exclusive-NOR, exclusive-OR, etc.) by adjusting external control signals without any modifications in its hardware configuration. The circuit allows real-time reconfigurable systems to be built. Test circuits were fabricated by a double-polysilicon CMOS process and their operation was experimentally verified     

Comparing MOS and bipolar integrated circuits

In terms of speed and speed/power performance, bipolar integrated circuits are superior to metal-oxide-semiconductor integrated circuits. This superiority is based on the high transconductance inherent in bipolar transistors and is technology-independent. For the MOS case, transconductance is highly technology-dependent, and hence the performance difference will probably diminish in the future. Comparisons of the two technologies in their mid-1966 forms are made; the bipolar performance advantage in most cases is between 10 and 100. MOS integrated circuits have an area-per-function advantage ratio of about 5 for equivalent-function circuits, but a ratio of between 5 and 10 when circuits exploiting the unique MOS properties are considered. In addition, MOS processing is simpler than bipolar processing by approximately 40 percent.     

Calculator-aided design of MOS integrated circuits

A set of programs has been developed for the characterization of the d.c. and transient behavior of MOS integrated circuits. The d.c. analysis program calculates and plots the voltage transfer and power dissipation characteristic of a MOS inverter approached from a new point of view. The algorithm enables the characterization of basic MOS IC cells on desktop calculators. The program for the transient characterization calculates and plots the output waveform of three simple MOS cells most often occurring in MOS IC's.The MOS transistor is simulated in terms of a four-terminal large signal model described by device processing parameters. Complex MOS IC's can be also characterized by appropriate combining of these programs.     

Protective device for MOS integrated circuits

Two protective devices for MOS integrated circuits have been extensively tested and proved feasible. They also perform more reliably than conventional Zener diodes. One of them has been used in the fabrication of a dual 25-bit MOS and MNOS integrated shift register and performed reliably.     

Harmonic performance of single-channel MOS integrated circuits

Using simple square-law models for both the MOSFET current-voltage characteristics and the relationship between the threshold voltage and the source-to-substrate voltage, simple expressions are presented for predicting the performance of the basic MOSFET circuits used in analog MOS technology. Using these expressions, the low-frequency gain and the second and third harmonic distortion performance of the enhancement-load inverters, enhancement-load source follower, depletion-load inverter, and depletion-load source follower can be easily predicted by hand calculations. The results obtained by using these expressions are compared with previously published measurements and calculations.     

Technology and performance of integrated complementary MOS circuits

The desirable characteristics of complementary MOS circuits are low standby power consumption, high speed, and high noise immunity. These require close control and matching of n- and p-channel transistor characteristics. Acceptable limits for mismatch between devices were derived based on circuit considerations and were related to process variables. Predicted performances were achieved using test circuits; feasibility of the technology has been shown. The reliability of fabricated test structures was evaluated.     

Computer-aided design and characterization of digital MOS integrated circuits

A computer-aided circuit-simulation method is developed to enable the design, characterization, and optimization of MOS integrated circuits. The computation of dc and transient characteristics is done in terms of physical device parameters extracted from processing information and incorporated in an analytical device model. It is demonstrated that any MOS circuit configuration (with its associated series resistances and parasitic devices) can be analyzed in terms of an equivalent inverter. Input-output transfer characteristics are obtained by superposition of the load and transistor I-V characteristics, providing the necessary information for dc > `worst-case' design. A simple device model was used to compute circuit transient response. All the computed characteristics are in good agreement with measurements performed on integrated circuits.     

Potential of MOS technologies for analog integrated circuits

Reviews the rapid progress in MOS analog circuit techniques over the past three years, and attempts to estimate the near-term attainable characteristics of MOS LSI circuits which incorporate both analog and digital functions.     

An optimized output stage for MOS integrated circuits

An output device for optimizing propagation delay and minimizing chip area is described. An optimum means of tapering the output stages to minimize propagation delay is determined. The minimum delay is a function of the capacitive load to node ratio, the number of output stages, and the interstage propagation delay. The effects on area are also presented. A figure of merit which is a function of area and propagation time is defined which is of use in designing output stages. An optimum exists which can be considered the best compromise between further decreasing propagation delay and increasing chip area. Data is also presented which allows a designer to determine the minimum chip area once the capacitive load and the maximum allowable delay are known.     

Shielded silicon gate complementary MOS integrated circuit

An electrostatic shield for complementary MOS integrated circuits was developed to minimize the adverse effects of stray electric fields created by the potentials in the metal interconnections. The process is compatible with silicon gate technology. n-doped polycrystalline silicon was used for all the gates and the shield. The effectiveness of the shield was demonstrated by constructing a special field plate over certain transistors. The threshold voltages obtained on a oriented silicon substrate ranged from 1.5 to 3 V for either channel. Integrated inverters performed satisfactorily from 3 to 15 V, limited at the low end by the threshold voltages and at the high end by the drain breakdown voltage of the n-channel transistors. The stability of the new structure with an n-doped silicon gate as measured by the shift inC-Vcurve under 200°C ± 20 V temperature-bias conditions was better than conventional aluminum gate or p-doped silicon gate devices, presumably due to the doping of gate oxide with phosphorous. The advantages of the new structure are: avoidance of field inversion, elimination of guard rings, and thinner and more stable oxides.     

Analysis of harmonic distortion in single-channel MOS integrated circuits

Presents a general analysis for the calculation of harmonic distortion in single-channel monolithic analog MOS integrated circuits. Power series expressions are obtained for basic stages often used in an analog MOS technology. These include the depletion load inverter, enhancement load inverter, depletion load source follower, enhancement load source follower, and the differential pair. From the power series expressions, the second-order harmonic distortion is calculated. These results are compared with data obtained from a test chip.     

Behavior of analog MOS integrated circuits at high temperatures

Thermal effects on small-signal characteristics of MOS transistors are studied and parameters of MOS amplifiers operating at high temperatures are calculated. The predicted performance has been experimentally verified and high-temperature measurements of an operational amplifier and a switched-capacitor precision amplifier are presented.     

VMOS—A new MOS integrated circuit technology

A new V-groove MOS integrated circuit technology (VMOS) is described. It makes use of preferential etching of silicon to define the channels of the MOS transistors. The fabrication involves either a three or four mask process and is capable of producing either silicon gate or standard metal gate transistors. The technology results in very short channel length devices using non-critical alignment tolerances. Despite the short channel length, the VMOS transistor exhibits lower output conductance and higher breakdown voltage than a standard MOS transistor.A first order theory is presented for the VMOS transistor along with measurements made on test devices of various channel lengths. Some integrated circuit applications of the technology are also presented, including an R-S fiip-flop and a 27-stage bucket brigade shift register. The advantages of the VMOS technology in such applications are discussed.     

In-process voltage stressing to increase reliability of MOS integrated circuits

Time-dependent dielectric breakdown of gate oxides is one of the principal failure mechanisms of MOS integrated circuits. Voltage stressing of completed devices, which has been used to screen oxide defects and to thereby increase product reliability, is less effective with scaled high-density MOS integrated circuits because of limitations in the voltage which can be applied. Inprocess voltage stressing of silicon wafers, prior to completion of wafer processing, offers a feasible technique for achieving an effective voltage screen. Several possible techniques for inprocess voltage stressing are described, and the advantages and limitations of these are outlined. Data are presented showing typical fast-ramp dielectric breakdown distributions for MOS transistor arrays with an oxide thickness of 35 and 50 nm. Time-dependent dielectric breakdown distribution data on devices from the same wafers indicate that with all MOS transistors of an integrated circuit connected in parallel, as in one type of inprocess voltage stressing, defective oxide sites can be screened in periods of time ranging from a few seconds to hours. Inprocess voltage stressing, by decreasing susceptibility of completed devices to time-dependent dielectric breakdown, can substantially increase MOS integrated circuit reliability.     

Computer analysis of the double-diffused MOS transistor for integrated circuits

The effective length of an MOS transistor can be made narrow by using double diffusion similar to a bipolar transistor. Computations were conducted for an n-channel double-diffused transistor with different surface concentrations, channel lengths, channel gradients, surface-states densities, and substrate concentrations. A shorter channel length and a higher surface-state density, e.g.langle1, 1, 1ranglecrystal, gave a higher drain current and transconductance. The maximum transconductance in many cases occurs at low gate voltages. The computations indicate that a gain-bandwidth product in the gigahertz range can be expected when the graded channel region is less than 1 µm. The difference between an n-type substrate and a p-type substrate is not substantial. The analysis is also useful in predicting the performance of any integrated logic circuit using the diffused enhancement transistor as the active switch and a depletion-mode transistor (without a diffused channel) as the load device. The computation indicates that satisfactory performance can be obtained using a load device with the same geometry and an ON voltage of only a fraction of a volt, This revelation indicates that double-diffused channel MOS transistors not only give higher speed but also smaller chip area for integrated circuits and a lower supply voltage (hence less power dissipation).     

Topology dependence of floating gate faults in MOS integrated circuits

Models for floating gate faults in MOS integrated circuits are introduced. It is experimentally demonstrated that these models are mask-topology-dependent. The logic state of the gate can be stuck-at, undefined or influenced. In the case of an influenced gate a `pseudo-MOS transistor? is defined.     

An MOS integrated circuit for digital filtering and level detection

An LSI circuit for digital signal processing has been designed and manufactured in 5 V n-channel MOS technology. Its main functions are to implement digital filters of the cascaded biquadratic form and to perform level detection operations. The frequency response of the filter is controlled by coefficients supplied from an external memory. The device, known by the acronym FAD (filter and detect), operates from a single-phase clock and can process up to 64000 samples/s at the maximum permissible clock rate of 2048 kbit/s. Although FAD was designed for one particular requirement, it has sufficient flexibility for use in a variety of application.     

Thermal incremental equivalent circuits of integrated circuit devices

A procedure of thermal stability design of integrated-circuit devices, based on the use of thermal incremental equivalent circuits, is described. These circuits may be derived by inspection from the dc equivalent circuit. They offer insight into the interdependence of various components in determining temperature variations and simplify the conventional analysis.     

Analogue MOS current-mode circuits for three-dimensional integrated smart image sensor

An image processing technique using analogue MOS current-mode circuits is presented. This approach is of interest in smart image sensors based on three-dimensional (or multi-layered) VLSI structures. High-performance smart image sensors with high resolution can be realised because the number of transistors required for image processing in each pixel is greatly reduced.<>