Abstract: Junction diodes fabricated in standard CMOS logic processes can be used as program selectors for One-Time Programmable (OTP) devices, such as electrical fuses. At least one portion of the electrical fuse can have at least one extended area to accelerate programming. An extended area is an extension of the fuse element beyond contact or via longer than required by design rules. The extended area also has reduced or substantially no current flowing through. The program selector can be at least one MOS. The OTP device can have the at least one OTP element coupled to at least one diode in a memory cell.

Abstract: A method of programming electrical fuses reliably is disclosed. If a programming current exceeds a critical current, disruptive mechanisms such as rupture, thermal runaway, decomposition, or melt, can be a dominant programming mechanism such that programming is not be very reliable. Advantageously, by controlled programming where programming current is maintained below the critical current, electromigration can be the sole programming mechanism and, as a result, programming can be deterministic and very reliable. In this method, fuses can be programmed in multiple shots with progressive resistance changes to determine a lower bound that all fuses can be programmed satisfactorily and an upper bound that at least one fuse can be determined failed. If programming within the lower and upper bounds, defects due to programming can be almost zero and, therefore, defects are essentially determined by pre-program defects.

Abstract: An One-Time Programmable (OTP) memory is built in at least one of semiconductor fin structures. The OTP memory has a plurality of OTP cells. At least one of the OTP cells can have at least one resistive element and at least one fin. The at least one resistive element can be built by an extended source/drain or a MOS gate. The at least one fin can be built on a common well or on an isolated structure that has at least one MOS gate dividing fins into at least one first active region and a second active region.

Abstract: A method of programming electrical fuses reliably is disclosed. If a programming current exceeds a critical current, disruptive mechanisms such as rupture, thermal runaway, decomposition, or melt, can be a dominant programming mechanism such that programming is not be very reliable. Advantageously, by controlled programming where programming current is maintained below the critical current, electromigration can be the sole programming mechanism and, as a result, programming can be deterministic and very reliable. In this method, fuses can be programmed in multiple shots with progressive resistance changes to determine a lower bound that all fuses can be programmed satisfactorily and an upper bound that at least one fuse can be determined failed. If programming within the lower and upper bounds, defects due to programming can be almost zero and, therefore, defects are essentially determined by pre-program defects.

Abstract: A programmable resistive memory has a plurality of programmable resistive devices (PRD) and at least one sensing circuit. The at least one of the programmable resistive device can include at least one programmable resistive element (PRE). The sensing circuit can include one PRD unit and a reference unit. Each unit has at least one capacitor to charge to a second supply voltage line and to discharge to the first supply voltage line through the PRE and the reference element, respectively. The capacitors are also coupled to comparators to monitor discharging voltages with respect to a reference voltage. By comparing the time difference when the comparators change their outputs, the magnitude of the PRE resistance with respect to the reference element resistance can be determined and converted into logic states.

Abstract: An One-Time Programmable (OTP) memory is built in at least one of semiconductor fin structures. The OTP memory has a plurality of OTP cells. At least one of the OTP cells can have at least one resistive element and at least one fin. The at least one resistive element can be built by an extended source/drain or a MOS gate. The at least one fin can be built on a common well or on an isolated structure that has at least one MOS gate dividing fins into at least one first active region and a second active region.

Abstract: Building programmable resistive devices in contact holes at the crossover of a plurality of conductor lines in more than two vertical layers is disclosed. There are plurality of first conductor lines and another plurality of second conductor lines that can be substantially perpendicular to each other, though in two different vertical layers. A diode and/or a programmable resistive element can be fabricated in the contact hole between the first and second conductor lines. The programmable resistive element can be coupled to another programmable resistive device or shared between two programmable devices whose diodes conducting currents in opposite directions and/or coupled to a common conductor line. The programmable resistive memory can be configured to be programmable by applying voltages to conduct current flowing through the programmable resistive element to change its resistance for a different logic state.

Abstract: A programmable resistive memory having a plurality of programmable resistive cells. At least one of the programmable resistive cell includes a programmable resistive element and at least one selector. The selector can be built in at least one fin structure and at least one active region divided by at least one MOS gate into a first active region and a second active region. The first active region can have a first type of dopant to provide a first terminal of the selector. The second active region can have a first or a second type of dopant to provide a second terminal of the selector. The MOS gate can provide a third terminal of the selector. The first terminal of the selector can be coupled to the first terminal of the programmable resistive element. The programmable resistive element can be programmed by conducting current flowing through the selector to thereby change the resistance state.

Abstract: A method of programming electrical fuses reliably is disclosed. If a programming current exceeds a critical current, disruptive mechanisms such as rupture, thermal runaway, decomposition, or melt, can be a dominant programming mechanism such that programming is not be very reliable. Advantageously, by controlled programming where programming current is maintained below the critical current, electromigration can be the sole programming mechanism and, as a result, programming can be deterministic and very reliable. In this method, fuses can be programmed in multiple shots with progressive resistance changes to determine a lower bound that all fuses can be programmed satisfactorily and an upper bound that at least one fuse can be determined failed. If programming within the lower and upper bounds, defects due to programming can be almost zero and, therefore, defects are essentially determined by pre-program defects.

Abstract: An integrated One-Time Programmable (OTP) memory to emulate an Multiple-Time Programmable (MTP) memory with a built-in program count tracking and block address mapping is disclosed. The integrated OTP memory has at least one non-volatile block register and count register to respectively store block sizes and program counts for different block/count configurations. The count register can be programmed before each round of programming occurs to indicate a new block for access. The integrated OTP memory also can generate a block address based on values from the count and block registers. By combining the block address with the lower bits of an input address, a final address can be generated and used to access different blocks (associated with different program counts) in the OTP memory to mimic an MTP memory.

Abstract: Building programmable resistive devices in contact holes at the crossover of a plurality of conductor lines in more than two vertical layers is disclosed. There are plurality of first conductor lines and another plurality of second conductor lines that can be substantially perpendicular to each other, though in two different vertical layers. A diode and/or a programmable resistive element can be fabricated in the contact hole between the first and second conductor lines. The programmable resistive element can be coupled to another programmable resistive device or shared between two programmable devices whose diodes conducting currents in opposite directions and/or coupled to a common conductor line. The programmable resistive memory can be configured to be programmable by applying voltages to conduct current flowing through the programmable resistive element to change its resistance for a different logic state.

Abstract: Junction diodes fabricated in standard CMOS logic processes can be used as program selectors with at least one heat sink or heater to assist programming for One-Time Programmable (OTP) devices, such as electrical fuse, contact/via fuse, contact/via anti-fuse, or gate-oxide breakdown anti-fuse, etc. The heat sink can be at least one thin oxide area, extended OTP element area, or other conductors coupled to the OTP element to assist programming. A heater can be at least one high resistance area such as an unsilicided polysilicon, unsilicided active region, contact, via, or combined in serial, or interconnect to generate heat to assist programming. The OTP device has at least one OTP element coupled to at least one diode in a memory cell. The diode can be constructed by P+ and N+ active regions in a CMOS N well, or on an isolated active region as the P and N terminals of the diode.

Abstract: An OTP (One-Time Programmable) memory including OTP memory cells that utilize OTP elements fabricated in CMOS FinFET processes. The OTP memory cell can also include at least one selector built upon at least one fin structure that has at least one CMOS gate to divide the fin structure into at least a first and a second active region. The selector can be implemented as a MOS device, dummy-gate diode, or Schottky diode as selector such as by using different types of source/drain implants. The OTP element that can be implemented as polysilicon, silicided polysilicon, CMOS metal gate, any layers of metal as interconnect, or active region. In one embodiment, the OTP element can be a fin structure and can be built upon the same fin structure as the at least one of the selector. By using different source/drain implant schemes on the two active regions, the selector can be turned on as MOS device, MOS device and/or diode, dummy-gate diode, or Schottky diode.

Abstract: A method of programming electrical fuses reliably is disclosed. If a programming current exceeds a critical current, disruptive mechanisms such as rupture, thermal runaway, decomposition, or melt, can be a dominant programming mechanism such that programming is not be very reliable. Advantageously, by controlled programming where programming current is maintained below the critical current, electromigration can be the sole programming mechanism and, as a result, programming can be deterministic and very reliable. In this method, fuses can be programmed in multiple shots with progressive resistance changes to determine a lower bound that all fuses can be programmed satisfactorily and an upper bound that at least one fuse can be determined failed. If programming within the lower and upper bounds, defects due to programming can be almost zero and, therefore, defects are essentially determined by pre-program defects.

Abstract: A method of programming electrical fuses reliably is disclosed. If a programming current exceeds a critical current, disruptive mechanisms such as rupture, thermal runaway, decomposition, or melt, can be a dominant programming mechanism such that programming is not be very reliable. Advantageously, by controlled programming where programming current is maintained below the critical current, electromigration can be the sole programming mechanism and, as a result, programming can be deterministic and very reliable. In this method, fuses can be programmed in multiple shots with progressive resistance changes to determine a lower bound that all fuses can be programmed satisfactorily and an upper bound that at least one fuse can be determined failed. If programming within the lower and upper bounds, defects due to programming can be almost zero and, therefore, defects are essentially determined by pre-program defects.

Abstract: Junction diodes fabricated in standard CMOS logic processes can be used as program selectors for One-Time Programmable (OTP) devices, such as electrical fuses. At least one portion of the electrical fuse can have at least one extended area to accelerate programming. An extended area is an extension of the fuse element beyond contact or via longer than required by design rules. The extended area also has reduced or substantially no current flowing through. The program selector can be at least one MOS. The OTP device can have the at least one OTP element coupled to at least one diode in a memory cell.

Abstract: A method of programming electrical fuses reliably is disclosed. If a programming current exceeds a critical current, disruptive mechanisms such as rupture, thermal runaway, decomposition, or melt, can be a dominant programming mechanism such that programming is not be very reliable. Advantageously, by controlled programming where programming current is maintained below the critical current, electromigration can be the sole programming mechanism and, as a result, programming can be deterministic and very reliable. In this method, fuses can be programmed in multiple shots with progressive resistance changes to determine a lower bound that all fuses can be programmed satisfactorily and an upper bound that at least one fuse can be determined failed. If programming within the lower and upper bounds, defects due to programming can be almost zero and, therefore, defects are essentially determined by pre-program defects.

Abstract: A programmable resistive memory having a plurality of programmable resistive cells. At least one of the programmable resistive cell includes a programmable resistive element and at least one selector. The selector can be built in at least one fin structure and at least one active region divided by at least one MOS gate into a first active region and a second active region. The first active region can have a first type of dopant to provide a first terminal of the selector. The second active region can have a first or a second type of dopant to provide a second terminal of the selector. The MOS gate can provide a third terminal of the selector. The first terminal of the selector can be coupled to the first terminal of the programmable resistive element. The programmable resistive element can be programmed by conducting current flowing through the selector to thereby change the resistance state.

Abstract: An OTP (One-Time Programmable) memory including OTP memory cells that utilize OTP elements fabricated in CMOS FinFET processes. The OTP memory cell can also include at least one selector built upon at least one fin structure that has at least one CMOS gate to divide the fin structure into at least a first and a second active region. The selector can be implemented as a MOS device, dummy-gate diode, or Schottky diode as selector such as by using different types of source/drain implants. The OTP element that can be implemented as polysilicon, silicided polysilicon, CMOS metal gate, any layers of metal as interconnect, or active region. In one embodiment, the OTP element can be a fin structure and can be built upon the same fin structure as the at least one of the selector. By using different source/drain implant schemes on the two active regions, the selector can be turned on as MOS device, MOS device and/or diode, dummy-gate diode, or Schottky diode.

Abstract: Junction diodes fabricated in standard CMOS logic processes can be used as program selectors with at least one heat sink or heater to assist programming for One-Time Programmable (OTP) devices, such as electrical fuse, contact/via fuse, contact/via anti-fuse, or gate-oxide breakdown anti-fuse, etc. The heat sink can be at least one thin oxide area, extended OTP element area, or other conductors coupled to the OTP element to assist programming. A heater can be at least one high resistance area such as an unsilicided polysilicon, unsilicided active region, contact, via, or combined in serial, or interconnect to generate heat to assist programming. The OTP device has at least one OTP element coupled to at least one diode in a memory cell. The diode can be constructed by P+ and N+ active regions in a CMOS N well, or on an isolated active region as the P and N terminals of the diode.