Abstract: Polysilicon diodes fabricated in standard CMOS logic processes can be used as program selectors for One-Time Programmable (OTP) devices, using electrical fuse, contact/via fuse, contact/via anti-fuse, or gate-oxide breakdown anti-fuse etc. as OTP element The diode can be constructed by P+/N+ implants on a polysilicon as a program selector. The OTP device can have an OTP element coupled to a polysilicon diode. The OTP devices can be used to construct a two-dimensional OTP memory with the N-terminals of the diodes in a row connected as a wordline and the OTP elements in a column connected as a bitline.

Abstract: A low-pin-count non-volatile (NVM) memory to be provided in an integrated circuit for a 3D IC to repair defects, trim devices, or adjust parameters is presented here. At least one die in a 3D IC can be built with at least one low-pin-count OTP memory. The low-pin-count OTP memory can be built with a serial interface such as I2C-like or SPI-like of interface. The pins of the low-pin-count OTP in at least one die can be coupled together to have only one set of low-pin-count bus for external access. With proper device ID, each die in a 3D IC can be accessed individually for soft programming, programming, erasing, or reading. This technique can improve the manufacture yield, device, circuit, or logic performance or to store configuration parameters for customization after 3D IC are built.

Abstract: The present invention provides a one time programmable (OTP) memory cell including a select gate transistor, a following gate transistor, and an antifuse varactor. The select gate transistor has a first gate terminal, a first drain terminal, a first source terminal, and two first source/drain extension areas respectively coupled to the first drain terminal and the first source terminal. The following gate transistor has a second gate terminal, a second drain terminal, a second source terminal coupled to the first drain terminal, and two second source/drain extension areas respectively coupled to the second drain terminal and the second source terminal. The antifuse varactor has a third gate terminal, a third drain terminal, a third source terminal coupled to the second drain terminal, and a third source/drain extension area coupled with the third drain terminal and the third source terminal for shorting the third drain terminal and the third source terminal.

Abstract: Disclosed herein is a fuse circuit including a storage unit capable of storing defective address information corresponding to mat information when a boot-up operation is performed, a driving control unit coupled between the storage unit and a first power source terminal, and capable of forming a current path between the storage unit and the first power source terminal in response to the defective address information transferred through a first data line and the mat information transferred through a second data line while blocking the current path between the storage unit and the first power source terminal when a normal operation is performed, and an output unit capable of outputting the defective address information stored in the storage unit when the normal operation is performed.

Abstract: Disturb from the reset to the set state may be reduced by creating an amorphous phase that is substantially free of crystal nuclei when programming the reset state in a phase change memory. In some embodiments, this can be achieved by using a current or a voltage to program that exceeds the threshold voltage of the phase change memory element, but does not exceed a safe current voltage which would cause a disturb.

Abstract: A programmable resistive device cell using at least one MOS device as selector can be programmed or read by turning on a source junction diode of the MOS or a channel of the MOS. A programmable resistive device cell can include at least one programmable resistive element and at least one MOS device. The programmable resistive element can be coupled to a first supply voltage line. The MOS can have a source coupled to the programmable resistive element, a bulk coupled to a drain, a drain coupled to a second supply voltage line, and a gate coupled to a third supply voltage line. The programmable resistive element can be configured to be programmable or readable by applying voltages to the first, second, and/or third supply voltage lines to turn on the source junction of the MOS and/or to turn on the channel of the MOS.

Abstract: The present invention provides a one time programmable (OTP) memory cell including a select gate transistor, a following gate transistor, and an antifuse varactor. The select gate transistor has a first gate terminal, a first drain terminal, a first source terminal, and two first source/drain extension areas respectively coupled to the first drain terminal and the first source terminal. The following gate transistor has a second gate terminal, a second drain terminal, a second source terminal coupled to the first drain terminal, and two second source/drain extension areas respectively coupled to the second drain terminal and the second source terminal. The antifuse varactor has a third gate terminal, a third drain terminal, a third source terminal coupled to the second drain terminal, and a third source/drain extension area coupled with the third drain terminal and the third source terminal for shorting the third drain terminal and the third source terminal.

Abstract: An electronic device of the present invention includes a shift register SR provided integrally with a substrate, a first line 11 connected with a connection terminal 101 electrically connectable with an outside device provided independently of the shift registers SR, second lines 12a through 12c via which output waveforms of the shift register SR are extracted, and switching sections 13a through 13c by which the first line 11 and the second lines 12a through 12c are switched between an electrically connected condition and an electrically disconnected condition. With this, even in a case where the electronic device of the present invention is a liquid crystal display device having a driver monolithic structure, output waveforms of a drive circuit (electronic circuit) can be inspected.

Abstract: A method for controlling the breakdown of an antifuse memory cell formed on a semiconductor substrate, including the steps of: applying a programming voltage; detecting a breakdown time; and interrupting the application of the programming voltage at a time following the breakdown time by a post-breakdown time.

Abstract: An e-fuse array circuit includes: an e-fuse transistor of a vertical gate type configured to have a gate for receiving a voltage of a program gate line and have one between a drain terminal and a source terminal floating; and a selection transistor of a buried gate type configured to have a gate for receiving a voltage of a word line gate line and electrically connect/disconnect the other one between the drain terminal and the source terminal with a bit line.

Abstract: A system for using selectable-delay bipolar logic circuitry within the address decoder of a MOS-based memory includes a MOS-based memory, which includes an array of a plurality of memory cells configured to store data; an address decoder including bipolar logic circuitry, where the address decoder is configured to accept a word including a plurality of bits and access the array of memory cells using the word; where the bipolar logic circuitry includes a plurality of bipolar transistor devices, where at least one bipolar transistor device has an adjustable gate bias and is configured to accept an input, wherein the gate bias is adjusted based on the input, where the gate bias determines a selectable gate delay.

Abstract: An integrated circuit is provided with operational mode header transistors which connect a virtual power rail to a VDD power supply. A controller circuit, responsive to a sensed voltage signal from a voltage sensor which reads the virtual rail voltage VVDD, generates a control signal which controls the operational mode transistors. The control signal is derived from an interface voltage power supply that provides higher voltage VDD IO than the VDD power supply and thus able to overdrive the operational mode transistors via either a gate bias voltage or a bulk bias voltage. The amount of leakage through the operational mode transistors is controlled in a closed loop feedback arrangement so as to maintain a predetermined target value or range for the virtual rail voltage. The operational mode transistor may also be controlled to support dynamic voltage and frequency scaling.

Abstract: A method includes creating a breakdown condition at a semiconductor transistor structure that includes an overlap region and a channel region. The breakdown condition is created by causing a first voltage difference between a gate of the semiconductor transistor structure and the overlap region to exceed a breakdown voltage of the semiconductor transistor structure while maintaining a second voltage difference between the gate and the channel region at less than the breakdown voltage.

Abstract: A nonvolatile memory device includes a memory cell array and a read/write circuit connected to the memory cell array through bit lines. The read method of the nonvolatile memory device includes receiving a security read request, receiving security information, and executing a security read operation in response to the security read request. The security read operation includes reading of security data from the memory cell array using the read/write circuit, storing of the read security data in a register, performing security decoding on the read security data stored in the register using the received security information, resetting the read/write circuit, and outputting a result of the security decoding.

Abstract: A programmable non-volatile memory including a memory cell includes a transistor acting as an anti-fuse and two diodes for access. The memory cell that can store two bits and includes a transistor acting as an anti-fuse and two diodes for access, wherein the cell transistor includes: the source electrode formed by a metal; the first diode as the source region contact structure; the drain electrode formed by a metal; and the second diode as the drain region contact structure wherein the cell transistor, the oxide layer between the source area and the gate is the first anti-fuse the first storage; the oxide layer between the drain area and the gate is the second anti-fuse the second storage; the two diodes are connected in series to access the two anti-fuses.

Abstract: A semiconductor device, includes: a first semiconductor layer having a first conductivity type; a pair of first electrodes arranged to be separated from each other in the first semiconductor layer; a second electrode provided on the first semiconductor layer between the pair of first electrodes with a dielectric film in between; and a pair of connection sections electrically connected to the pair of first electrodes, wherein one or both of the pair of first electrodes are divided into a first region and a second region, the first region and the second region being connected by a bridge section.

Abstract: An anti-fuse array includes: a plurality of first transistors having a matrix structure over a semiconductor substrate; a plurality of second transistors respectively disposed adjacent to first ends of the plurality of first transistors along a first direction of the matrix structure; and a plurality of third transistors respectively disposed at second ends of the plurality of first transistors along a second direction.

Abstract: A system may include circuitry and a magnetoresistive random access memory (MRAM) die including at least one MRAM cell. The circuitry may be configured to detect attempted tampering with the MRAM die and generate a signal based on the detected attempted tampering. The signal may be sufficient to damage or destroy at least one layer of the at least one MRAM cell or a fuse electrically connected to a read line of the at least one MRAM cell.

Abstract: According to an embodiment, a semiconductor memory includes word lines, a plurality of sets of a pair of bit lines, memory cells, a writing/reading circuit, and a word line selection circuit. In a state where inverted data of program data has been written to the memory cells, a stress is applied and the program data is programmed to the memory cells. The writing/reading circuit writes the inverted data of the same program data to a unit memory cell group made of memory cells connected to a set of a pair of bit lines at a time of programming, and reads data from the unit memory cell group by detecting a signal level of the pair of bit lines at a time of reading. The word line selection circuit simultaneously selects and drives two or more word lines of the word lines connected to the unit memory cell group.

Abstract: A one-time programmable memory array includes a first row conductor extending in a first row direction and disposed at a first elevation, a second row conductor extending in a second row direction and disposed at a second elevation and a column conductor extending in a column direction and disposed adjacent to the first row conductor and adjacent to the second row conductor. The array also includes a dielectric layer covering at least a portion of the column conductor, a fuse link coupled between the dielectric layer on the column conductor and the second row conductor.

Abstract: An anti-fuse circuit in which anti-fuse program data may be monitored outside of the anti-fuse circuit and a semiconductor device including the anti-fuse circuit are disclosed. The anti-fuse circuit includes an anti-fuse array, a data storage circuit, and a first selecting circuit. The anti-fuse array includes one or more anti-fuse blocks including a first anti-fuse block having a plurality of anti-fuse cells and the anti-fuse array is configured to store anti-fuse program data. The data storage circuit is configured to receive and store the anti-fuse program data from the anti-fuse array through one or more data buses. The first selecting circuit is configured to output anti-fuse program data of a selected anti-fuse block of the one or more anti-fuse blocks in response to a first selection signal.

Abstract: The semiconductor device includes a power source signal generator and a redundancy signal generator. The power source signal generator generates a fuse power source signal driven to have a target level of an internal voltage signal. The fuse power source signal is generated to have a lower level than the target level of the internal voltage signal by a certain level during a period from a moment that a deep power-down mode starts till a moment that a level of the internal voltage signal reaches a predetermined level after termination of the deep power-down mode. The redundancy signal generator latches a fuse data in response to a fuse reset signal and a fuse set signal to generate a redundancy signal while the fuse power source signal is supplied.

Abstract: A redundancy circuit includes a plurality of block address lines, a first fuse array storing a first data, a plurality of first local lines configured to supply a verification voltage to the first fuse array in response to a signal of a corresponding line among the plurality of block address lines, a second fuse array storing a second data, a plurality of second local lines configured to supply the verification voltage to the second fuse array in response to a signal of a corresponding line among the plurality of block address lines, and a plurality of verification lines configured to check the first data of the first fuse array and the second data of the second fuse array, wherein the plurality of verification lines are shared by the first fuse array and the second fuse array and are disposed between the first fuse array and the second fuse array.

Abstract: An antifuse apparatus can include a cantilever extending from a first electrode portion to terminate in a distal end. A second electrode portion can be spaced apart from the cantilever by an air gap. In response to a program voltage across the first and second electrode portions, the cantilever can be adapted to move from an unprogrammed condition, corresponding to an open circuit condition where the cantilever is spaced apart from the second electrode portion, to at least one permanent programmed condition, corresponding to a short circuit condition between the first and second electrode portions where the cantilever engages the second electrode portion.

Abstract: A power up detection method for a memory device and a memory device are disclosed. In a first phase, a test word is read from a read-only memory (ROM) row of a memory array of the memory device, and the test word is compared to predetermined ROM row data. If the test word matches the predetermined ROM row data, a second phase may be performed. In the second phase, first user data is read from a user-programmed row of the memory array at a first time. Second user data is read from the user-programmed row of the memory array at a second time different from the first time. The first user data is compared to the second user data. Successful power up of the memory device is determined when the first user data matches the second user data.

Abstract: A semiconductor integrated circuit includes a fuse circuit comprising a fuse configured to generate a fuse state signal corresponding to a rupture state of the fuse in response to an enable signal, a fuse state decision unit configured to determine whether or not the fuse state signal is normal based on a test signal, and generate an output enable signal according to a determination result, and a driving unit configured to output the fuse state signal in response to the output enable signal.

Abstract: A memory device including: a memory cell array including normal memory cells and spare memory cells arranged in rows and columns including normal columns including the normal memory cells and at least one spare column including spare memory cells, a segment match determining circuit configured to compare a segment address with row address information corresponding to a failed segment and to generate a load control signal, and a column match determining circuit configured to compare column address information corresponding to a failed column in response to the load control signal with a column address and to generate a column address replacement control signal, wherein the memory cells connected to fail columns of the fail segment are replaced with memory cells connected to columns of the spare memory cells in response to the column address replacement control signal.

Abstract: The present invention pertains to the technical field of one-time programmable memory (OTP), and in particular to a one-time programmable memory unit, OTP, and method of fabricating the same. The OTP unit comprises a lower electrode, an upper electrode and a storage medium layer placed between the upper electrode and the lower electrode, the storage medium layer comprises a first metal oxide layer and a second metal oxide layer, wherein an adjoining area for programming is formed between the first metal oxide layer and the second metal oxide layer. The OTP comprises a plurality of the above-described one-time programmable memory units arranged in rows and columns. The OTP unit and the OTP have such characteristics as low programming voltage, small unit area, being able to integrate into a back-end structure of integrated circuit, great process flexibility, and the method of fabricating the OTP unit and the OTP is relatively simple and low in cost.

Abstract: Methods and systems to stress-program a first integrated circuit (IC) block to output a pre-determined value upon activation/reset, such as to support time-zero compensation/trimming. To program, the first block is configured with first-block program parameters to cause the first block to output a pre-determined value. The first block is stressed while configured with the first-block program parameters, to cause the first block to output the pre-determined value without the first-block program parameters. The first block may include a latch designed as a fully balance circuit and may be asymmetrically stressed to alter a characteristic of one path relative to another. The pre-determined value may be selected to compensate for process corner variations and/or other random variations.

Abstract: A method of storing repair data of a memory array in a one-time programming memory (OTPM) includes performing a first test and repair of the memory array using a built-in self-test-and-repair (BISTR) module to determine first repair data. The method includes loading the first repair data in a repair memory and in a duplicated repair memory of the BISTR module. The method includes performing a second test and repair to determine second repair data. The method includes storing the second repair data in the repair memory of the BISTR module and in the repair memory of the memory array. The method includes processing the repair data in the repair memory and the duplicated repair memory of the BISTR module. The method includes storing the output of the logic gate in the repair memory of the memory array. The method includes storing content of the repair memory in the OTPM.

Abstract: Provided is an OTP memory cell including a first antifuse unit, a second antifuse unit, a select transistor, and a well region. The first and the second antifuse unit respectively include an antifuse layer and an antifuse gate disposed on a substrate in sequence. The select transistor includes a select gate, a gate dielectric layer, a first doped region, and a second doped region. The select gate is disposed on the substrate. The gate dielectric layer is disposed between the select gate and the substrate. The first and the second doped region are respectively disposed in the substrate at two sides of the select gate, wherein the second doped region is disposed in the substrate at the periphery of the first and the second antifuse unit. The well region is disposed in the substrate below the first and the second antifuse unit and is connected to the second doped region.

Abstract: A memory device includes a memory cell which has one cell selection section and a storage section which is connected in series with respect to the cell selection section and which is selected as an access target for writing or reading by the cell selection section, in which the storage section is provided with a plurality of memory elements which are able to be written one time only and where information is held by changing resistance values in a non-written state and a written state.

Abstract: An e-fuse array circuit includes a program gate line and a word line gate line that are stretched in parallel to each other, and a metal line formed over the program gate line and the word line gate line to cover the program gate line and the word line gate line, the metal line connected to the program gate line through a plurality of contact plugs disposed at a given distance.

Abstract: Methods and apparatus are provided for an integrated circuit with a programmable electrical connection. The apparatus includes an inactive area with a memory line passing over the inactive area. The memory line includes a programmable layer. An interlayer dielectric is positioned over the memory line and the inactive area, and an extending member extends through the interlayer dielectric. The extending member is electrically connected to the programmable layer of the memory line at a point above the inactive area.

Abstract: A method of programming a memory includes selecting a logic state for programming a first bitcell of the memory. A first one-time-programmable (OTP) element of the first bitcell is programmed using a first set of conditions intended to achieve a first target resistance in accordance with the selected logic state which results in a first degree of programming of the first OTP element. A second OTP element of the first bitcell is programmed using a second set of conditions different from the first set of conditions intended to achieve a second target resistance in accordance with the selected logic state which results in a second degree of programming of the second OTP element, wherein the first and second degrees of programming are visually indistinguishable.

Abstract: A low-pin-count non-volatile (NVM) memory to be provided in an integrated circuit. In one embodiment, the low-pin-count non-volatile (NVM) memory can use only one external control signal and one internal clock signal to generate start, stop, device ID, read/program/erase pattern, starting address, and actual read/program/erase cycles. When programming or erasing begins, toggling of the control signal increments/decrements a program or erase address and a pulse width of the control signal determines the actual program or erase time. A data out of the low-pin-count non-volatile (NVM) memory can be multiplexed with the control signal. Since the clock signal can be derived and shared from the system clock of the integrated circuit, the NVM memory need only have one external control pin for I/O transactions to realize a low-pin-count interface.

Abstract: The memory programming apparatus includes a memory reader configured to read a read data in a plurality of cells related with an address of a programmable memory; and a memory writer configured to record a write data on the plurality of cells to compare the write data with the read data, to generate a re-writing pattern, and to correct at least one mismatch cell among the plurality of cells. Accordingly, it may be possible to reduce a programming processing time and to increase a yield rate.

Abstract: Methods and systems that extend the capability of fuse elements, anti-fuse elements, and combinations thereof to enable multi-time programmable memory elements are provided. Accordingly, significantly reduced area requirements and control circuitry complexity of memory elements is enabled. The provided methods and systems can be used in non-volatile memory storage, and are suitable for use in system on chip (SoC) products.

Abstract: A test mode decoder configured to decode a test mode signal inputted a plurality of times and to generate preliminary fuse information, a count latch configured to count the preliminary fuse information in response to a count clock signal and to generate fuse information, and a fuse array block configured to store the fuse information can be included.

Abstract: A programmable memory is provided. The programmable memory has a select transistor that includes a gate, a source, and a drain. An anti-fuse device is connected to a drain region of the select transistor. The anti-fuse device includes a dielectric layer on an upper substrate of the drain region, a polysilicon layer on the dielectric layer, and an anti-fuse electrode line in contact with the drain region. The dielectric layer breaks down and the anti-fuse device is programmed when the select transistor is turned on and a high voltage is applied through the anti-fuse line.

Abstract: An OTP anti-fuse memory array without additional selectors and a manufacturing method are provided. Embodiments include forming wells of a first polarity in a substrate, forming a bitline of the first polarity in each well, and forming plural metal gates across each bitline, wherein no source/drain regions are formed between the metal gates.

Abstract: Disclosed herein is a semiconductor device that includes a plurality of memory cells assigned with addresses that are different from each other, a redundant memory cell replacing a defective memory cell among the memory cells, a fuse circuit storing an address of the defective memory cell, an access control circuit accessing the redundant memory cell when the address of the defective memory cell stored in the fuse circuit is supplied, and a roll call circuit outputting the address of the defective memory cell to outside the semiconductor device in a serial manner.

Abstract: A memory module is provided. A plurality of DRAMs is mounted on a PCB. At least one DRAM has an operating parameter different from other DRAMs according to a position where the at least one DRAM is mounted on the PCB.

Abstract: A semiconductor device comprises a bit determination circuit to count the number of bits at a first level in an input address signal formed of a plurality of bits and to output a result indicating whether or not a value of the count exceeds a predetermined determination threshold value, as a bit determination result signal, and a selection control circuit to select a non-volatile program element to be cut off, based on the bit determination result signal and the address signal. Additional apparatus and methods are described.

Abstract: An apparatus includes a semiconductor fuse array, disposed on a die, into which is programmed configuration data. The semiconductor fuse array has a first plurality of semiconductor fuses and a second plurality of semiconductor fuses. The first plurality of semiconductor fuses is configured to store the configuration data in an encoded and compressed format. The second plurality of semiconductor fuses is configured to store first fuse correction data that indicates locations and values corresponding to a first one or more fuses within the first plurality of fuses whose states are to be changed from that which was previously stored.

Abstract: A one-time programmable memory includes a first one-time programmable memory cell including a fuse core having an input terminal for receiving a trim signal, an output terminal for providing a sense signal, and a fuse. The fuse core conducts current through the fuse in response to the trim signal. The one-time programmable memory cell also includes a sense circuit having an input terminal coupled to the output terminal of the fuse core, and an output terminal for providing a termination signal, and a logic circuit having a first input terminal for receiving a program enable signal, a second input terminal for receiving a data signal, a third input terminal coupled to the output terminal of the sense circuit for receiving the termination signal, and an output terminal coupled to the input terminal of the fuse core for providing the trim signal.

Abstract: A thin gate-oxide dual-mode PMOS transistor is disclosed that has a first mode of operation in which a switched n-well for the dual-mode PMOS transistor is biased to a high voltage. The dual-mode PMOS transistor has a second mode of operation in which the switched n-well is biased to a low voltage that is lower than the high voltage. The dual-mode PMOS transistor has a size and gate-oxide thickness each having a magnitude that cannot accommodate a permanent tie to the high voltage. An n-well voltage switching circuit is configured to bias the switched n-well to prevent voltage damage to the dual-mode PMOS transistor without the use of native transistors.

Abstract: A semiconductor device has an electrical fuse element including: a first filament; a second filament connected to the first filament; and a series readout section connected to an end of the first filament opposite to another end of the first filament connected to the second filament, the series readout section reading series resistance of the first filament and the second filament.

Abstract: A semiconductor memory device includes a nonvolatile device array including write-once nonvolatile devices arranged in rows and columns, row select lines, a row control circuit connected to the row select lines, column select lines, a column control circuit connected to the column select lines, a flip-flop circuit provided at least on a side of the nonvolatile device array opposite to the row control circuit or on a side of the nonvolatile device array opposite to the column control circuit, and an inactivation unit configured to inactivate the row select lines or the column select lines based on a first control signal.

Abstract: A programmable resistive device cell using at least one MOS device as selector can be programmed or read by turning on a source junction diode of the MOS or a channel of the MOS. A programmable resistive device cell can include at least one programmable resistive element and at least one MOS device. The programmable resistive element can be coupled to a first supply voltage line. The MOS can have a source coupled to the programmable resistive element, a bulk coupled to a drain, a drain coupled to a second supply voltage line, and a gate coupled to a third supply voltage line. The programmable resistive element can be configured to be programmable or readable by applying voltages to the first, second, and/or third supply voltage lines to turn on the source junction of the MOS and/or to turn on the channel of the MOS.