Abstract: Self-aligned split-gate NAND flash memory cell array and process of fabrication in which rows of self-aligned split-gate cells are formed between a bit line diffusion and a common source diffusion in the active area of a substrate. Each cell has control and floating gates which are stacked and self-aligned with each other, and erase and select gates which are split from and self-aligned with the stacked gates, with select gates at both ends of each row which partially overlap the bit line the source diffusions. The channel regions beneath the erase gates are heavily doped to reduce the resistance of the channel between the bit line and source diffusions, and the floating gates are surrounded by the other gates in a manner which provides significantly enhanced high voltage coupling to the floating gates from the other gates.

Abstract: Self-aligned split-gate NAND flash memory cell array and process of fabrication in which rows of self-aligned split-gate cells are formed between a bit line diffusion and a common source diffusion in the active area of a substrate. Each cell has control and floating gates which are stacked and self-aligned with each other, and erase and select gates which are split from and self-aligned with the stacked gates, with select gates at both ends of each row which partially overlap the bit line the source diffusions. The channel regions beneath the erase gates are heavily doped to reduce the resistance of the channel between the bit line and source diffusions, and the floating gates are surrounded by the other gates in a manner which provides significantly enhanced high voltage coupling to the floating gates from the other gates.

Abstract: Self-aligned split-gate NAND flash memory cell array and process of fabrication in which rows of self-aligned split-gate cells are formed between a bit line diffusion and a common source diffusion in the active area of a substrate. Each cell has control and floating gates which are stacked and self-aligned with each other, and erase and select gates which are split from and self-aligned with the stacked gates, with select gates at both ends of each row which partially overlap the bit line the source diffusions. The channel regions beneath the erase gates are heavily doped to reduce the resistance of the channel between the bit line and source diffusions, and the floating gates are surrounded by the other gates in a manner which provides significantly enhanced high voltage coupling to the floating gates from the other gates.

Abstract: Self-aligned split-gate NAND flash memory cell array and process of fabrication in which rows of self-aligned split-gate cells are formed between a bit line diffusion and a common source diffusion in the active area of a substrate. Each cell has control and floating gates which are stacked and self-aligned with each other, and erase and select gates which are split from and self-aligned with the stacked gates, with select gates at both ends of each row which partially overlap the bit line the source diffusions. The channel regions beneath the erase gates are heavily doped to reduce the resistance of the channel between the bit line and source diffusions, and the floating gates are surrounded by the other gates in a manner which provides significantly enhanced high voltage coupling to the floating gates from the other gates.

Abstract: A capacitor having a low voltage coefficient, even though one electrode is a semiconductor and one is a metal, is described. Two parallel plate capacitors are formed side by side and then cross-connected. The bottom plate of one of the capacitors is connected to the top plate of the other capacitor, and vice versa. This arrangement causes the two capacitors to be polarized in opposite directions at all times so that the individual voltage coefficients cancel each other and give the combined structure a value that is about 2 ppm V. A process for manufacturing this capacitor is also described.

Abstract: An electrostatic discharge protective circuit formed by use of a silicon controller rectifier is coupled to an input port and an internal circuit for discharging electrostatic charges on the input port to ground. When the electrostatic charges are applied on the input port, a punch-through effect is created between a first P-type diffusion region and a second N-type diffusion region to turn on a parasitic NPN bipolar junction transistor. At the same time, a voltage is applied on a gate of the MOS transistor via a small-signal equivalent capacitor to turn on itself, thereby discharging the electrostatic charges. Accordingly, the trigger voltage of the silicon controller rectifier can be efficiently lowered to improve the electrostatic discharge protective capability of the silicon control rectifier.

Abstract: A capacitor having a low voltage coefficient, even though one electrode is a semiconductor and one is a metal, is described. Two parallel plate capacitors are formed side by side and then cross-connected. The bottom plate of one of the capacitors is connected to the top plate of the other capacitor, and vice versa. This arrangement causes the two capacitors to be polarized in opposite directions at all times so that the individual voltage coefficients cancel each other and give the combined structure a value that is about 2 ppm/V. A process for manufacturing this capacitor is also described.

Abstract: The present invention utilizes a CMOS (complementary metal-oxide-semiconductor) inverter, which includes a PMOS transistor and an NMOS transistor connected in cascade, and back-gate biasing circuits. The back-gate biasing circuit consists of capacitors and loads (active load or passive load). By providing a bias voltage to either one of bulks of the transistors or both of them, the constituted CMOS inverter demonstrates higher operation speed and lower standby current than the conventional one.

Abstract: This invention presents a new SRAM cell comprising only two MOSFETs: one is the access device for data transfer; and the other is operated as a high gain gated lateral BJT in the reverse base current mode so as to constitute the role of the storage flip-flop or latch. This invention also requires only one-sided peripheral circuitry for Read/Write function. Thus the chip area is greatly saved. In addition, the invention is fully compatible with the existing low-cost, high-yield standard CMOS process.

Abstract: This invention deals with the problem of an error voltage in a MOSFET analog switch sample and hold circuit caused by the turn off charge in the MOSFET analog switch. The invention provides a compensating circuit which can be adjusted to exactly compensate for the turn off charge which causes the error so that the error can be reduced to zero or nearly zero. The compensating circuit can be used in both open loop and closed loop sample and hold circuits. The compensating circuit can be used in combination with a Miller feedback circuit for eliminating the error voltage.