Abstract: A memory device includes a bit line, a first word line, a bit line contact, an electrode, a second word line and a contact tip. The bit line may extend along a first direction. The first word line is formed over the bit line and extends in a second direction. The bit line contact is formed between adjacent first word lines. The bit line contact may have an upper face substantially higher than the first word lines. The electrode contacting with the bit line contact may include an elastic material bending by an electric field among the electrode, the first word line and the second word line. The second word line is disposed over the electrode and corresponds to at least one of the first word lines. The contact tip formed at a lateral portion of the electrode may protrude toward the first and the second word lines.

Abstract: A semiconductor device according to example embodiments may be configured so that, when a read command for performing a read operation is input while a write operation is performed, and when a memory bank accessed by a write address during the write operation is the same as a memory bank accessed by a read address during the read operation, the semiconductor device may suspend the write operation automatically or in response to an internal signal until the read operation is finished and performs the write operation after the read operation is finished.

Abstract: A data read/write device according to an example of the present invention includes a recording layer, and means for applying a voltage to the recording layer, generating a resistance change in the recording layer, and recording data. The recording layer is composed of a composite compound having at least two types of cation elements, at least one type of the cation element is a transition element having a “d” orbit in which electrons have been incompletely filled, and the shortest distance between the adjacent cation elements is 0.32 nm or less.

Abstract: A nanotube random access memory (NRAM) structure is provided. The structure includes a substrate, a gate electrode disposed in the substrate, and a first nanotube fabric disposed on the substrate. The first nanotube fabric has a channel region spaced apart from the gate electrode by a portion of the substrate. The structure also includes a drain contact contacting the first nanotube fabric. The structure also includes a second nanotube fabric disposed on the substrate, and is adjacent and connected to the first nanotube fabric. The structure also includes a source contact contacting the second nanotube fabric. The first nanotube fabric is a high-voltage fabric compared to the second nanotube fabric such that when a voltage is applied across the first nanotube fabric and the second nanotube fabric via the drain contact and the source contact, the second nanotube fabric is permitted to switch without switching the first nanotube fabric.

Abstract: A storage apparatus including a circuit board, a control circuit element, a terminal module and a storage circuit element is provided. The circuit board includes a first surface, a second surface, a connect part, openings, metal contacts and metal units. The openings pass through the circuit board from the first surface to the second surface and the metal contacts are exposed on the first surface. The terminal module is disposed on the first surface and has elastic terminals and each of the elastic terminals has a first contact part and a second contact part. The first contact parts respectively contact with the metal contacts and the second contact parts respectively pass through the openings to protrude from the second surface. The metal units are disposed on the second surface and located between the openings and the connect part. Accordingly, the volume of the storage apparatus can be reduced.

Abstract: A Spin Transfer Torque Magnetoresistive Random Access Memory (STT-MRAM) bit cell array is provided. The STT-MRAM array includes a STT-MRAM bit cell and an input net coupled to the STT-MRAM bit cell. The STT-MRAM array includes a pulse signal input pad and a buffer coupled between the pulse signal input pad and the input net. In an aspect, the input net is one of a bit line, a word line, and a source line.

Abstract: A nanowire electromechanical switching device is constructed with a source electrode and a drain electrode disposed on an insulating substrate and spaced apart from each other, a first nanowire vertically grown on the source electrode and to which a V1 voltage is applied, a second nanowire vertically grown on the drain electrode and to which a V2 voltage having an opposite polarity to that of the V1 voltage is applied, and a gate electrode spaced apart from the second nanowire, partially surrounding the second nanowire and having an opening that faces the first nanowire in order to avoid disturbing a mutual switching operation of the first nanowire and the second nanowire and to which a V3 voltage having the same polarity as that of the V2 voltage is applied.

Abstract: A non-volatile bistable nano-electromechanical switch is provided for use in memory devices and microprocessors. The switch employs carbon nanotubes as the actuation element. A method has been developed for fabricating nanoswitches having one single-walled carbon nanotube as the actuator. The actuation of two different states can be achieved using the same low voltage for each state.

Abstract: A pillar structure that is contacted by a vertical contact is formed in an integrated circuit. A hard mask is formed and utilized to pattern a least a portion of the pillar structure. The hard mask comprises carbon. Subsequently, the hard mask is removed. A conductive material is then deposited in a region previously occupied by the hard mask to form the vertical contact. The hard mask may, for example, comprise diamond-like carbon. The pillar structure may have a width or diameter less than about 100 nanometers.

Abstract: A non-volatile memory cell includes a volatile storage device that stores a corresponding logic state in response to electrical stimulus; and a shadow memory device coupled to the volatile storage device. The shadow memory device receives and stores the corresponding logic state in response to electrical stimulus. The shadow memory device includes a non-volatile nanotube switch that stores the corresponding state of the shadow device.

Abstract: A method and apparatus for managing data, particularly in regard to non-volatile memory cells. In some embodiments, at least two actuating conductors are at least partially surrounded by a main ferromagnetic core and an adjacent hard magnet. When current is conducted through the actuating conductors, a flexible beam is induced to traverse a first air gap that defines a high resistance position and a low resistance position.

Abstract: The invention concerns an arrangement for controlling a non-volatile memory arrangement for a circuit comprising: a micromechanical element coupled to a substrate; the micromechanical element being responsive to deflection means arranged on the substrate to control the movement of the micromechanical element between one or more stable states. In addition, the invention concerns a method for controlling a non-volatile memory device arrangement comprising: applying one or more signals to a deflection means for moving a micromechanical element between one or more stable states. To enhance the efficacy of the invention there is further provided a shorting circuit for use in the non-volatile memory arrangement.

Abstract: A configuration bit array including a hybrid electromechanical and semiconductor memory cell, and circuitry for addressing and controlling read, write, and erase accesses of the memory.

Abstract: The invention relates, among other things, to a memory cell for storing at least one piece of bit data. Said memory cell comprises at least two electrical terminals and a semiconductor structure with a band curve (EL) that has at least one potential well. The charged state of the potential well with charge carries can be increased by applying a supply voltage (Us=Uspeis) to the two terminals, can be reduced by applying a discharge voltage (Us=Usperr), and can be maintained by applying a maintaining voltage (Us=Ubei), the respective charged state of the potential well defining the piece of bit data of the memory cell. According to the invention, the semiconductor structure has a space charge region (Wn) while the potential well is formed by a semiconductor heterostructure.

Abstract: Random access memory including nanotube switching elements. A memory cell includes first and second nanotube switching elements and an electronic memory. Each nanotube switching element includes conductive terminals, a nanotube article and control circuitry capable of controllably form and unform an electrically conductive channel between the conductive terminals. The electronic memory is a volatile storage device capable of storing a logic state in response to electrical stimulus. In certain embodiment the electronic memory has cross-coupled first and second inverters in electrical communication with the first and second nanotube switching elements. The cell can operate as a normal electronic memory, or can operate in a shadow memory or store mode (e.g., when power is interrupted) to transfer the electronic memory state to the nanotube switching elements. The device may later be operated in a recall mode where the state of the nanotube switching elements may be transferred to the electronic memory.

Abstract: A configuration bit array including a hybrid electromechanical and semiconductor memory cell, and circuitry for addressing and controlling read, write, and erase accesses of the memory.

Abstract: A data read/write device according to an example of the present invention includes a recording layer, and means for applying a voltage to the recording layer, generating a resistance change in the recording layer, and recording data. The recording layer is composed of a composite compound having at least two types of cation elements, at least one type of the cation element is a transition element having a “d” orbit in which electrons have been incompletely filled, and the shortest distance between the adjacent cation elements is 0.32 nm or less.

Abstract: Under one aspect, non-volatile transistor device includes a source and drain with a channel in between; a gate structure made of a semiconductive or conductive material disposed over an insulator over the channel; a control gate made of a semiconductive or conductive material; and an electromechanically-deflectable nanotube switching element in fixed contact with one of the gate structure and the control gate structure and is not in fixed contact with the other of the gate structure and the control gate structure. The device has a network of inherent capacitances, including an inherent capacitance of an undeflected nanotube switching element in relation to the gate structure. The network is such that the nanotube switching element is deflectable into contact with the other of the gate structure and the control gate structure in response to signals being applied to the control gate and one of the source region and drain region.

Abstract: A nonvolatile memory device contains at least one nonvolatile memory module and an electrical buffer for buffering a supply voltage for the at least one nonvolatile memory module. A microprocessor may be connected in parallel or serial fashion to the memory device, or may contain the memory device.

Abstract: A stack that includes non-volatile memory devices is disclosed. One of the non-volatile memory devices in the stack is a master device, and the remaining memory device or devices is a slave device(s).

Abstract: A memory chip and method for operating the same are provided. The memory chip includes a number of pads. The method includes inputting a number of first test signals to the pads respectively, wherein the first test signals corresponding to two physically-adjacent pads are complementary; inputting a number of second test signals, respectively successive to the first test signals, to the pads, wherein the first test signal and the second test signal corresponding to each of the pads are complementary; and outputting expected data from the memory chip if the first test signals and the second test signals are successfully received by the memory chip.

Abstract: A configuration bit array including a hybrid electromechanical and semiconductor memory cell, and circuitry for addressing and controlling read, write, and erase accesses of the memory.

Abstract: Provided are a multibit electro-mechanical memory device and a method of manufacturing the same. The device may include at least one bit line in a first direction on a substrate; at least one gate line and at least one lower word line in parallel by a given interval and in a second direction intersecting the first direction on the at least one bit line; at least one contact pad adjacent to the at least one gate line on the at least one bit line; and at least one cantilever electrode coupled to the at least one contact pad, configured to float with a void above and beneath the at least one cantilever electrode and configured to curve in a third direction vertical to the first and second directions.

Abstract: Memory devices and memory modules are disclosed. In one embodiment, a memory device includes a semiconductor substrate having a first edge and a second edge opposed to the first edge. A plurality of memory banks is disposed at a central portion of the semiconductor substrate, each memory bank including a plurality of memory cells. A plurality of input/output contacts is disposed between the first edge and the memory banks. Delay locked loop circuitry is disposed adjacent the first edge. A plurality of address and command contacts is disposed between the second edge and the memory banks.

Abstract: A multibit electro-mechanical memory device and a method of manufacturing the same include a substrate, a bit line in a first direction on the substrate, a lower word line in a second direction intersecting the first direction, a pad electrode isolated from a sidewall of the lower word line and connected to the bit line, a cantilever electrode expending in the first direction over the lower word line with a lower void therebetween, and connected to the pad electrode and curved in a third direction vertical to the first and second direction by an electrical field induced by a charge applied to the lower word line, a trap site expending in the second direction over the cantilever electrode with an upper void therebetween, and an upper word line to which a charge to curve the cantilever electrode in a direction of the trap site is applied, and on the trap site.

Abstract: A hybrid memory system having electromechanical memory cells is discussed. A memory cell core circuit has an array of electromechanical memory cells, in which each cell is a crossbar junction at least one element of which is a nanotube or a nanotube ribbon. An access circuit provides array addresses to the memory cell core circuit to select at least one corresponding cell. The access circuit is constructed of semiconductor circuit elements.

Abstract: A communication system includes a host device and a peripheral device which are communicate with each other according to a main communication protocol that allows the command to be transmitted only from the host device to the peripheral device. The peripheral device accepts an input and to generate a trigger that urges the host device to start a target communication event in accordance with the input. The host device issues a trigger report request command to the peripheral device. The peripheral device transmits trigger generation report information containing a presence or absence of a generation of the trigger to the host device in response to the trigger report request command. The host device receives the trigger generation report information, determines the presence or absence of the generation of the trigger and starts the target event if the presence of the generation of the trigger is determined.

Abstract: A multibit electro-mechanical memory device and a method of manufacturing the same include a substrate, a bit line on the substrate; a lower word line and a trap site isolated from the bit line, a pad electrode isolated from a sidewall of the trap site and the lower word line and connected to the bit line, a cantilever electrode suspended over a lower void in an upper part of the trap site, and connected to the pad electrode and curved by an electrical field induced by a charge applied to the lower word line, a contact part for concentrating a charge induced from the cantilever electrode thereon in response to the charge applied from the lower word line and the trap site, the contact part protruding from an end part of the cantilever electrode, and an upper word line formed with an upper void above the cantilever electrode.

Abstract: Under one aspect, a memory array includes word lines; bit lines; memory cells; and a memory operation circuit. Each memory cell responds to electrical stimulus on a word line and on a bit line and includes: a two-terminal non-volatile nanotube switching device having first and second terminals, a semiconductor diode element, and a nanotube fabric article capable of multiple resistance states. The semiconductor diode and nanotube article are between and in electrical communication with the first and second terminals, which are coupled to the word line bit line respectively. The operation circuit selects cells by activating bit and/or word lines, detects a resistance state of the nanotube fabric article of a selected memory cell, and adjusts electrical stimulus applied to the cell to controllably induce a selected resistance state in the nanotube fabric article. The selected resistance state corresponds to an informational state of the memory cell.

Abstract: A storage device includes: a wiring including a first conductor with a first conductivity; and first, second and third contacts, each including a second conductor with a second conductivity and contacting the wiring. The storage device also includes: a write switching circuit controlling current for writing information that flows through the first contact, the wiring, and the second contact, and changing resistance values of the first contact to write information; and a read switching circuit controlling current for reading information that flows through the first contact, the wiring, and the third contact.

Abstract: A data read/write device according to an example of the present invention includes a recording layer, and means for applying a voltage to the recording layer, generating a resistance change in the recording layer, and recording data. The recording layer is composed of a composite compound having at least two types of cation elements, at least one type of the cation element is a transition element having a “d” orbit in which electrons have been incompletely filled, and the shortest distance between the adjacent cation elements is 0.32 nm or less.

Abstract: There are provided a multi-bit electro-mechanical memory device capable of enhancing or maximizing a degree of integration of the memory device and a method of manufacturing the multi-bit electro-mechanical memory device which includes a substrate, a bit line on the substrate, and extending in a first direction; a word line on the bit line, insulated from the bit line, and extending in a second direction transverse to the first direction, and a cantilever electrode including a shape memory alloy. The cantilever electrode has a first portion electrically connected to the bit line and a second portion extending in the first direction, and spaced apart from the word line by an air gap, wherein the cantilever electrode, in a first state, is in electrical contact with the word line, and, in a second state, is spaced apart from the word line.

Abstract: A read only memory implemented as a 3D integrated device has a first stratum, a second stratum, and bonded inter-strata connections for coupling the first stratum to the second stratum. The physical bonding between the two strata implements the programming of the read only memory. The stratum may be in wafer form or in die form. The first stratum includes functional active devices and at least one non-programmed active device. The second stratum includes at least conductive routing to be associated with the at least one non-programmed active device. The bonded inter-strata connections include at least one bonded programmable inter-strata connection for programming the at least one non-programmed active device and for providing conductive routing to the programmed active device. The two strata thus form a programmed ROM. Other types of programmable storage devices may be implemented by bonding the two strata.

Abstract: A memory element which has high affinity with a conventional semiconductor process, which has a switching function of completely interrupting electric conduction paths by in a mechanical manner, and in which nonvolatile information recording is enabled is realized. An electromechanical memory which is formed on a substrate, which is formed by interposing a memory cell by electrodes, and which has a movable electrode that is a beam stretched in the air via a post portion is realized. According to the configuration, a nonvolatile memory can be realized by a simple structure, and it is possible to realize a high-performance electromechanical memory which is conventionally difficult to be realized, and in which the power consumption is low and the cost is low, and an electric apparatus using it.

Abstract: The invention concerns an arrangement for controlling a non-volatile memory arrangement for a circuit comprising: a micromechanical element coupled to a substrate; the micromechanical element being responsive to deflection means arranged on the substrate to control the movement of the micromechanical element between one or more stable states. In addition, the invention concerns a method for controlling a non-volatile memory device arrangement comprising: applying one or more signals to a deflection means for moving a micromechanical element between one or more stable states. To enhance the efficacy of the invention there is further provided a shorting circuit for use in the non-volatile memory arrangement.

Abstract: A memory device and a method for fabricating the same provide a device capable of increasing or maximizing the performance of a microstructure device. The device includes: a plurality of word lines formed with a gap therebetween and extending in parallel with each other in a first direction of extension; and a bit line insulated from the plurality of word lines, intersecting the plurality of word lines and extending in a second direction of extension, a transition electrode portion of the bit line positioned in the gap and spaced apart from the plurality of word lines by a predetermined distance, the transition electrode portion of the bit line configured and arranged to be bent toward any one of the plurality of word lines in response to an electrical signal applied to at least one of the plurality of word lines.

Abstract: Nanotube-based switching elements and logic circuits. Under one embodiment of the invention, a switching element includes an input node, an output node, a nanotube channel element having at least one electrically conductive nanotube, and a control electrode. The control electrode is disposed in relation to the nanotube channel element to controllably form an electrically conductive channel between the input node and the output node. The channel at least includes said nanotube channel element. The output node is constructed and arranged so that channel formation is substantially unaffected by the electrical state of the output node.

Abstract: Circuit arrays having cells with combinations of transistors and nanotube switches. Under one embodiment, cells are arranged as pairs with the nanotube switching elements of the pair being cross coupled so that the set electrode of one nanotube switching element is coupled to the release electrode of the other and the release electrode of the one nanotube switching element being coupled to the set electrode of the other. The nanotube articles are coupled to the reference line, and the source of one field effect transistor of a pair is coupled to the set electrode to one of the two nanotube switching elements and the source of the other field effect transistor of the pair is coupled to the release electrode to the one of the two nanotube switching elements.

Abstract: A semiconductor device with a packaging circuit portion connected to a semiconductor chip therein. The semiconductor chip includes a plurality of pad electrodes, and the packaging circuit portion includes wiring connected to the pad electrodes on the semiconductor chip, mounting terminals, and a first signal path for receiving a signal output from the predetermined one of the pad electrodes and transmitting the signal to other one of the pad electrodes. The first signal path includes delay elements comparable to delays in a second signal path extending from the predetermined one of the mounting terminals to the other one of the mounting terminals through the semiconductor chip, and is disposed on a feedback path for phase comparison for synchronizing the phase of an output signal from the second signal path to the phase of an input signal to the second signal path.

Abstract: The invention concerns an arrangement for controlling a non-volatile memory arrangement for a circuit comprising: a micromechanical element coupled to a substrate; the micromechanical element being responsive to deflection means arranged on the substrate to control the movement of the micromechanical element between one or more stable states. In addition, the invention concerns a method for controlling a non-volatile memory device arrangement comprising: applying one or more signals to a deflection means for moving a micromechanical element between one or more stable states. To enhance the efficacy of the invention there is further provided a shorting circuit for use in the non-volatile memory arrangement.

Abstract: A non-volatile memory bitcell which comprises a first bistable cantilever module and a second bistable cantilever modules. The bistable cantilever modules have a shared output terminal and each has an input terminal and two actuating terminals. The first and second cantilever modules are arranged such that their states are complementary. The memory bitcell further includes buffering means arranged to prevent the flow of current from the shared output terminal and further arranged to indicate the states of the first and second cantilever modules.

Abstract: A method of driving a storage device including a variable resistance element in which resistance value is changed reversibly between a high resistance state and a low resistance state by applying voltages with different polarities between two electrodes is provided. The storage device includes a plurality of memory cells formed of the variable resistance elements. The method includes the step of applying voltages more than once in combination to the memory cell when the variable resistance element is changed from the low resistance state to the high resistance state.

Abstract: In a memory device and a method of forming the same, in one embodiment, the memory device comprises a substrate and a bit line on the substrate extending in a first direction. A first word line structure is provided on the bit line and spaced apart from, and insulated from, the bit line, the first word line structure extending in a second direction transverse to the first direction. An electrode is coupled to the bit line extending over the first word line structure and spaced apart from the first word line structure by a first gap. A second word line structure is over the electrode and spaced apart from the electrode by a second gap, the second word line structure extending in the second direction.

Abstract: A magnetic switching element according to an example of the present invention includes a magnetic element, first and second electrodes which put the magnetic element therebetween, a current control section which is connected to the first and second electrodes, the current control section controlling a magnetization direction of a magnetization free section in such a manner that a current is made to flow between the magnetization free section and the magnetization fixed section, a movable conductive tube having a fixed end and a free end, and a third electrode connected to the fixed end of the conductive tube. A switching operation is performed in such a manner that a spatial position of the conductive tube is caused to change depending on the magnetization direction of the magnetization free section.

Abstract: Carbon nanotube (CNT) based devices include an actuator/switch that includes one or more fixed CNTs and a moveable CNT that can be urged toward or into contact with a selected fixed CNT with a magnetic field produced by a current in a control conductor. The control conductor can be formed of one or more CNTs, and the fixed and moveable CNTs can be retained by a support, and motion of the moveable CNT limited by a cavity defined in the support. In other examples, CNT FETS are used to form CNT transmission gates that are arranged to define circuits configured as multiplexers or to realize logical functions, addition, multiplication, or other operations such as Galois field arithmetic.

Abstract: A non-volatile memory cell includes a volatile storage device that stores a corresponding logic state in response to electrical stimulus; and a shadow memory device coupled to the volatile storage device. The shadow memory device receives and stores the corresponding logic state in response to electrical stimulus. The shadow memory device includes a non-volatile nanotube switch that stores the corresponding state of the shadow device.

Abstract: A solid-state semiconductor device operable without loss arising from junction-to junction (e.g., source-to-drain) leakage current includes a movable MEMS switch or relay armature structure carrying at least one electrical contact corresponding to a semiconductor device junction. The switch or relay armature is movable from a first position corresponding to a first switch state to a second position corresponding to a second switch state. The semiconductor device also includes an actuation circuit configured to act on the cantilever switch, changing the switch from a first contact-conducting state to a second non-contact-conducting state by physically separating the switch's electrical contact from the semiconductor device junction, thus eliminating the conductive path for leakage current losses.

Abstract: A micro-motor memory device includes at least one rotor having at least one indicator for rotating about an axis; and at least one stator placed adjacent to the rotor for electromagnetically or physically engaging the rotor to rotate the indicator to at least one predetermined angular position for representing stored data. The rotor and the stator are constructed on a semiconductor substrate by using micro-electro-mechanic-system technology.

Abstract: Digital data apparatuses and digital data operational methods are described.

Abstract: As part of anti-fuse circuitry for a memory device, a preferred exemplary embodiment of the current invention provides a direct connection between an anti-fuse and a contact pad used to provide voltage to that anti-fuse. The contact pad also serves as a voltage source for at least one other part of the memory device. At least one circuit coupled to the anti-fuse is temporarily isolated from it in the event that a voltage present at the pad would damage the circuit or cause the circuit to improperly read the status of the anti-fuse. The contact pad is available during a probe stage of the in-process memory device, but once the device is packaged, access to that contact pad is prevented. At the backend of the production process, the anti-fuse may be accessed through a second pad, whose electrical communication with the anti-fuse is regulated.