Abstract: An area-efficient gated diode includes a semiconductor layer of a first conductivity type, an active region of a second conductivity type formed in the semiconductor layer proximate an upper surface of the semiconductor layer, and at least one trench electrode extending substantially vertically through the active region and at least partially into the semiconductor layer. A first terminal of the gated diode is electrically connected to the trench electrode, and at least a second terminal is electrically connected to the active region. The gated diode is operative in one of at least a first mode and a second mode as a function of a voltage potential applied between the first and second terminals. The first mode is characterized by the creation of an inversion layer in the semiconductor layer substantially surrounding the trench electrode.

Abstract: A semiconductor structure that includes at least one logic device region and at least one static random access memory (SRAM) device region wherein each device region includes a double gated field effect transistor (FET) wherein the back gate of each of the FET devices is doped to a specific level so as to improve the performance of the FET devices within the different device regions is provided. In particular, the back gate within the SRAM device region is more heavily doped than the back gate within the logic device region. In order to control short channel effects, the FET device within the logic device region includes a doped channel, while the FET device within the SRAM device region does not.

Abstract: A sense amplifier circuit comprises (1) an isolation device comprising a control terminal and first and second terminals, the first terminal of the isolation device coupled to a signal line, (2) a gated diode comprising first and second terminals, the first terminal of the gated diode coupled to the second terminal of the isolation device, and the second terminal of the gated diode coupled to a set line; and (3) control circuitry coupled to the control terminal of the isolation device and adapted to control voltage on the control terminal of the isolation device in order to enable and disable the isolation device. A latch circuit further comprises a precharge device comprising a control terminal and first and second terminals, the first terminal of the precharge device coupled to a power supply voltage, and the second terminal of the precharge device coupled to the first terminal of the isolation device.

Abstract: A memory cell for use in a memory array includes a storage element for storing a logical state of the memory cell, a write circuit and a read circuit. The write circuit is operative to selectively connect a first node of the storage element to at least a first write bit line in the memory array in response to a write signal for selectively writing the logical state of the memory cell. The read circuit includes a substantially high impedance input node connected to the storage element and an output node connectable to a read bit line of the memory array. The read circuit is configured to generate an output signal at the output node which is representative of the logical state of the storage element in response to a read signal applied to the read circuit. The memory cell is configured such that the write circuit is disabled during a read operation of the memory cell so as to substantially isolate the storage element from the first write bit line during the read operation.

Abstract: A sense amplifier circuit comprises (1) an isolation device comprising a control terminal and first and second terminals, the first terminal of the isolation device coupled to a signal line, (2) a gated diode comprising first and second terminals, the first terminal of the gated diode coupled to the second terminal of the isolation device, and the second terminal of the gated diode coupled to a set line; and (3) control circuitry coupled to the control terminal of the isolation device and adapted to control voltage on the control terminal of the isolation device in order to enable and disable the isolation device. A latch circuit further comprises a precharge device comprising a control terminal and first and second terminals, the first terminal of the precharge device coupled to a power supply voltage, and the second terminal of the precharge device coupled to the first terminal of the isolation device.

Abstract: An integrated circuit, such as a memory macro, includes multiple power rails supporting first and second voltage differentials, with the second voltage differential being smaller than the first voltage differential. Signal lines in the integrated circuit are driven with the small voltage swing, which is generated by small swing circuits. The integrated circuit further includes regeneration circuits, which are receiving small voltage swing inputs and are outputting first, or full voltage swings. The application of the small voltage swing to the signal lines saves power in the integrated circuit. A wide bandwidth, full-wordline I/O, memory integrated circuit has simultaneously operable connection paths between essentially all the memory cells that are attached to the same wordline and the corresponding I/O terminals, and it has a single ended data-line structure.

Abstract: Thermal mixing methods of forming a substantially relaxed and low-defect SGOI substrate material are provided. The methods include a patterning step which is used to form a structure containing at least SiGe islands formed atop a Ge resistant diffusion barrier layer. Patterning of the SiGe layer into islands changes the local forces acting at each of the island edges in such a way so that the relaxation force is greater than the forces that oppose relaxation. The absence of restoring forces at the edges of the patterned layers allows the final SiGe film to relax further than it would if the film was continuous.

Abstract: A method for compensating the threshold voltage roll-off using transistors containing back-gates or body nodes is provided. The method includes designing a semiconductor system or chip having a plurality of transistors with a channel length of Lnom. For the present invention, it is assumed that the channel length of these transistors at the completion of chip manufacturing is Lmax. This enables one to set the off-current to the maximum value of I-offmax which is done by setting the threshold voltage value to Vtmin. The Vtmin for these transistors is obtained during processing by using the proper implant dose. After manufacturing, the transistors are then tested to determine the off-current thereof. Some transistors within the system or chip will have an off-current value that meets a current specification. For those transistor devices, no further compensation is required. For other transistors within the system or chip, the off-current is not within the predetermined specification.

Abstract: A circuit comprises a control line and a two terminal semiconductor device having first and second terminals. The first terminal is coupled to a signal line, and the second terminal is coupled to the control line. The two terminal semiconductor device is adapted to have a capacitance when a voltage on the first terminal relative to the second terminal is above a threshold voltage and to have a smaller capacitance when a voltage on the first terminal relative to the second terminal is below the threshold voltage. The control line is coupled to a control signal and the signal line is coupled to a signal and is output of the circuit. A signal is placed on the signal line and voltage on the control line is modified (e.g., raised in the case of n-type devices, or lowered for a p-type devices). When the signal falls below the threshold voltage, the two terminal semiconductor device acts as a very small capacitor and the output of the circuit will be a small value.

Abstract: A memory cell comprises: (1) a write switch, the first terminal of the write switch coupled to an at least one bitline, the control terminal of the write switch coupled to the first control line; (2) a two terminal semiconductor, the first terminal of the two terminal semiconductor device coupled to the second terminal of the write switch, and the second terminal of the two terminal semiconductor device coupled to an at least one second control line, wherein the two terminal semiconductor device has a capacitance when a voltage on the first terminal relative to the second terminal is above a threshold voltage and has a lower capacitance when the voltage on the first terminal relative to the second terminal is less than the threshold voltage; (3) a read select switch, the control terminal of the read select switch coupled to an at least one second control line, the first terminal of the read select switch coupled to the at least one bitline; and (4) a read switch, the control terminal of the read switch couple

Abstract: A gated diode memory cell is provided, including one or more transistors, such as field effect transistors (“FETs”), and a gated diode in signal communication with the FETs such that the gate of the gated diode is in signal communication with the source of a first FET, wherein the gate of the gated diode forms one terminal of the storage cell and the source of the gated diode forms another terminal of the storage cell, the drain of the first FET being in signal communication with a bitline (“BL”) and the gate of the first FET being in signal communication with a write wordline (“WLw”), and the source of the gated diode being in signal communication with a read wordline (“WLr”).

Abstract: A random access memory (RAM) circuit is coupled to a write control line, a read control line, and one or more bitlines, and includes a write switch having a control terminal and first and second terminals. The first terminal of the write switch is coupled to the one or more bitlines, and the control terminal of the write switch is coupled to the write control line. The circuit includes a charge-storage device having first and second terminals, wherein a first terminal of the charge-storage device is coupled to the second terminal of the write switch and a second terminal of the charge-storage device is coupled to the read control line. The circuit includes a read switch having a control terminal and first and second terminals. The control terminal of the read switch is coupled to the first terminal of the charge-storage device and is coupled to the second terminal of the write switch.

Abstract: A DRAM is disclosed which includes a single ended bitline structure, a single ended global bitline structure, primary sense amplifiers with data storage and data write-back capability and with capability to decouple from the global bitlines, a full-wordline I/O structure where essentially all memory cell that belong to the same wordline are being operated on, and a pipelined architecture. The DRAM further includes a small voltage swing design. The primary sense amplifiers can include more than one amplification stages. Such a DRAM is suitable for applications in conjunction with processors as an embedded DRAM.

Abstract: A method of forming a silicon-on-insulator (SOI) metal oxide semiconductor field effect transistor (MOSFET) device is provided in which an implanted back-gate is formed into a Si-containing layer of an SOI wafer. The implanted back-gate thus formed is capable of controlling the threshold voltage of a polysilicon-containing front-gate which is formed over a portion of the implanted back-gate region. The implanted back-gate functions as a dynamic threshold voltage control system in the SOI MOSFET device because it is suitable for use during circuit/system active periods and during circuit/system idle periods.

Abstract: The present invention provides SOI CMOS technology whereby a polysilicon back-gate is used to control the threshold voltage of the front-gate device, and the nMOS and pMOS back-gates are switched independently of each other and the front gates. Specifically, the present invention provides a method of fabricating a back-gated fully depleted CMOS device in which the device's back-gate is self-aligned to the device's front-gate as well as the source/drain extension. Such a structure minimizes the capacitance, while enhancing the device and circuit performance. The back-gated fully depleted CMOS device of the present invention is fabricated using existing SIMOX (separation by ion implantation of oxygen) or bonded SOI wafers, wafer bonding and thinning, polySi etching, low-pressure chemical vapor deposition and chemical-mechanical polishing.

Abstract: An integrated circuit, such as a memory macro, includes multiple power rails supporting first and second voltage differentials, with the second voltage differential being smaller than the first voltage differential. Signal lines in the integrated circuit are driven with the small voltage swing, which is generated by small swing circuits. The integrated circuit further includes regeneration circuits, which are receiving small voltage swing inputs and are outputting first, or full voltage swings. The application of the small voltage swing to the signal lines saves power in the integrated circuit. A wide bandwidth, full-wordline I/O, memory integrated circuit has simultaneously operable connection paths between essentially all the memory cells that are attached to the same wordline and the corresponding I/O terminals, and it has a single ended data-line structure.

Abstract: A carrier for a semiconductor component is provided having passive components integrated in its substrate. The passive components include decoupling components, such as capacitors and resistors. A set of connections is integrated to provide a close electrical proximity to the supported components.

Abstract: A radiation detector formed using silicon-on-insulator technology. The radiation detector includes a silicon layer formed on an insulating substrate, wherein the silicon layer includes a PNPN structure, and a gate layer formed over the PNPN structure, wherein the gate layer includes a PN gate. Latch-up occurs in the radiation detector only in response to incident radiation.