Abstract: An adjustable setpoint ESD core clamp for ESD protection circuits is disclosed. The core clamp includes an SCR whose P+N trigger junction is referenced to a diode stack. The SCR is non-avalanche triggered into a low impedance state at a set value of VCC, as determined by the diode stack, which allows the ESD device to turn on at a lower voltage, thereby protecting internal circuitry.

Abstract: A metal silicide fuse for a semiconductor device. The fuse includes a conductive region positioned adjacent a common well of a first conductivity type, a terminal region positioned adjacent a well of a second conductivity type, and a narrowed region located between the terminal region and the conductive region and positioned adjacent a boundary between the two wells. Upon applying at least a programming current to the fuse, the fuse “blows” at the narrowed region. The diode or diodes between wells of different conductivity types wells and the Schottky diode or diodes between the remaining portions of the fuse and wells adjacent thereto control the flow of current through the remainder of the fuse and through the associated wells of the semiconductor device. When the fuse has been “blown,” the diodes and Schottky diodes prevent current of a normal operating voltage from flowing through the wells of the semiconductor device.

Abstract: A metal silicide fuse for a semiconductor device. The fuse includes a conductive region positioned adjacent a common well of a first conductivity type, a terminal region positioned adjacent a well of a second conductivity type, and a narrowed region located between the terminal region and the conductive region and positioned adjacent a boundary between the two wells. Upon applying at least a programming current to the fuse, the fuse “blows” at the narrowed region. The diodes between wells of different conductivity types wells and the Schottky diode or diodes between the remaining portions of the fuse and wells adjacent thereto control the flow of current through the remainder of the fuse and through the associated wells of the semiconductor device. When the fuse has been “blown,” the diodes and Schottky diodes prevent current of a normal operating voltage from flowing through the wells of the semiconductor device.

Abstract: A metal silicide fuse for a semiconductor device. The fuse includes a conductive region positioned adjacent a common well of a first conductivity type, a terminal region positioned adjacent a well of a second conductivity type, and a narrowed region located between the terminal region and the conductive region and positioned adjacent a boundary between the two wells. Upon applying at least a programming current to the fuse, the fuse “blows” at the narrowed region. The diode or diodes between wells of different conductivity types wells and the Schottky diode or diodes between the remaining portions of the fuse and wells adjacent thereto control the flow of current through the remainder of the fuse and through the associated wells of the semiconductor device. When the fuse has been “blown,” the diodes and Schottky diodes prevent current of a normal operating voltage from flowing through the wells of the semiconductor device.

Abstract: A metal silicide fuse for a semiconductor device. A conductive region of the fuse may be disposed adjacent a common well of semiconductive material of a first conductivity type. A terminal region of the fuse may be disposed adjacent a well of semiconductive material of a second conductivity type. A narrowed region of the fuse, which is disposed between the terminal region and the conductive region, is disposed adjacent a boundary between the two wells. Upon applying at least a programming current to the fuse, the fuse preferably “blows” at the narrowed region. The diode or diodes between the different conductivity type wells and the Schottky diode or diodes between the remaining portions of the fuse and adjacent wells of the semiconductor device control the flow of current through the remainder of the fuse and through the adjacent conductive wells of the semiconductor device.

Abstract: An integrated circuit anti-fuse is described which is fabricated as a capacitor using a layer of oxide. The two plates of the anti-fuse are coupled to appropriate voltage levels to rupture the oxide and form a conductive short between the plates. One of the plates is formed as a diffused well which is coupled to an external voltage during programming. The well is biased to an internal voltage during normal operation of the circuit incorporating the anti-fuse.

Abstract: A metal silicide fuse for a semiconductor device. The fuse includes a conductive region positioned adjacent a common well of a first conductivity type, a terminal region positioned adjacent a well of a second conductivity type, and a narrowed region located between the terminal region and the conductive region and positioned adjacent a boundary between the two wells. Upon applying at least a programming current to the fuse, the fuse “blows” at the narrowed region. The diode or diodes between wells of different conductivity types wells and the Schottky diode or diodes between the remaining portions of the fuse and wells adjacent thereto control the flow of current through the remainder of the fuse and through the associated wells of the semiconductor device. When the fuse has been “blown”, the diodes and Schottky diodes prevent current of a normal operating voltage from flowing through the wells of the semiconductor device.

Abstract: An integrated circuit anti-fuse is described which is fabricated as a capacitor using a layer of oxide. The two plates of the anti-fuse are coupled to appropriate voltage levels to rupture the oxide and form a conductive short between the plates. One of the plates is formed as a diffused well which is coupled to an external voltage during programming. The well is biased to an internal voltage during normal operation of the circuit incorporating the anti-fuse.

Abstract: A circuit and method provide isolated modulation of SRAM bitline voltage levels for improved voltage bump retention testing of the SRAM cells. A first FET is connected to Vcc, bitline load gates of the SRAM cell, and test mode operation control logic. A second FET is connected to the bitline load gates, the test mode logic, and an external pin of the SRAM device. During test mode operation, the first FET disables Vcc to the bitlines, and the second FET enables the internal bitline voltage levels to be modulated by a voltage supply received through the external pin of the device. Modulation of the bitline voltage levels is isolated from normal operating voltage levels of peripheral circuitry such as the wordlines. An alternate embodiment provides a CMOS transmission gate in place of the second FET.

Abstract: The present invention is embodied in a method and apparatus which provides a ROM embedded in a SRAM array utilizing the existing support circuitry of the SRAM array. By disabling or not disabling SRAM cells by removing or not removing the ground or power connections to each cell in different combinations, a pair of SRAM cells can be used to permanently store a specified logic state, i.e. function as a ROM cell. Additionally, a single SRAM cell and a reference signal can also be programmed to function as a ROM cell.

Abstract: An integrated circuit anti-fuse is described which is fabricated as a capacitor using a layer of oxide. The two plates of the anti-fuse are coupled to appropriate voltage levels to rupture the oxide and form a conductive short between the plates. One of the plates is formed as a diffused well which is coupled to an external voltage during programming. The well is biased to an internal voltage during normal operation of the circuit incorporating the anti-fuse.

Abstract: A circuit and method provide isolated modulation of SRAM bitline voltage levels for improved voltage bump retention testing of the SRAM cells. A first FET is connected to Vcc, bitline load gates of the SRAM cell, and test mode operation control logic. A second FET is connected to the bitline load gates, the test mode logic, and an external pin of the SRAM device. During test mode operation, the first FET disables Vcc to the bitlines, and the second FET enables the internal bitline voltage levels to be modulated by a voltage supply received through the external pin of the device. Modulation of the bitline voltage levels is isolated from normal operating voltage levels of peripheral circuitry such as the wordlines. An alternate embodiment provides a CMOS transmission gate in place of the second FET.

Abstract: An integrated circuit anti-fuse is described which is fabricated as a capacitor using a layer of oxide. The two plates of the anti-fuse are coupled to appropriate voltage levels to rupture the oxide and form a conductive short between the plates. One of the plates is formed as a diffused well which is coupled to an external voltage during programming. The well is biased to an internal voltage during normal operation of the circuit incorporating the anti-fuse.

Abstract: A circuit and method provide isolated modulation of SRAM bitline voltage levels for improved voltage bump retention testing of the SRAM cells. A first FET is connected to Vcc, bitline load gates of the SRAM cell, and test mode operation control logic. A second FET is connected to the bitline load gates, the test mode logic, and an external pin of the SRAM device. During test mode operation, the first FET disables Vcc to the bitlines, and the second FET enables the internal bitline voltage levels to be modulated by a voltage supply received through the external pin of the device. Modulation of the bitline voltage levels is isolated from normal operating voltage levels of peripheral circuitry such as the wordlines. An alternate embodiment provides a CMOS transmission gate in place of the second FET.