Abstract: In certain aspects of the disclosure, a protection circuit includes a first input/output (I/O) pin, a second I/O pad, a shunt clamp coupled to the first I/O pad, and a resistor coupled between the shunt clamp and the second I/O pad. The resistor has a first dynamic resistance at a voltage of 100 millivolts across the resistor, the resistor has a second dynamic resistance at a voltage of three volts across the resistor, and the second dynamic resistance is at least five times greater than the first dynamic resistance.

Abstract: In certain aspects of the disclosure, a protection circuit includes a first input/output (I/O) pin, a second I/O pad, a shunt clamp coupled to the first I/O pad, and a resistor coupled between the shunt clamp and the second I/O pad. The resistor has a first dynamic resistance at a voltage of 100 millivolts across the resistor, the resistor has a second dynamic resistance at a voltage of three volts across the resistor, and the second dynamic resistance is at least five times greater than the first dynamic resistance.

Abstract: A method of protecting a serializer/deserializer (SERDES) differential input/output (I/O) circuit includes detecting an electrostatic discharge event. The method also includes selectively disengaging a power supply terminal from a pair of I/O transistors of the SERDES differential I/O circuit in response to the detected electrostatic discharge event. The method further includes selectively disengaging a ground terminal from the pair of I/O transistors of the SERDES differential I/O circuit in response to the detected electrostatic discharge event.

Abstract: An apparatus is described. The apparatus includes an input device. The apparatus also includes a positive supply voltage pad. The apparatus further includes an input signal pad. The apparatus also includes a ground pad. The apparatus further includes charged-device model protection circuitry that protects the input device from electrostatic discharge. The charged-device model protection circuitry includes at least one of de-Q circuitry and a cascode device.

Abstract: An intergrated circuit (IC) package includes a die, a package substrate coupled to the die, and a first electrostatic discharge (ESD) protection component coupled to the package substrate, where the first electrostatic discharge (ESD) protection component is configured to provide package level electrostatic discharge (ESD) protection. In some implementations, the first electrostatic discharge (ESD) protection component is embedded in the package substrate. In some implementations, the die includes an internal electrostatic discharge (ESD) protection component configured to provide die level electrostatic discharge (ESD) protection. In some implementations, the internal electrostatic discharge (ESD) protection component and the first electrostatic discharge (ESD) protection component are configured to provide cumulative electrostatic discharge (ESD) protection for the die.

Abstract: A method of protecting a serializer/deserializer (SERDES) differential input/output (I/O) circuit includes detecting an electrostatic discharge event. The method also includes selectively disengaging a power supply terminal from a pair of I/O transistors of the SERDES differential I/O circuit in response to the detected electrostatic discharge event. The method further includes selectively disengaging a ground terminal from the pair of I/O transistors of the SERDES differential I/O circuit in response to the detected electrostatic discharge event.

Abstract: An integrated circuit (IC) package includes a die, a package substrate coupled to the die, and a first electrostatic discharge (ESD) protection component coupled to the package substrate, where the first electrostatic discharge (ESD) protection component is configured to provide package level electrostatic discharge (ESD) protection. In some implementations, the first electrostatic discharge (ESD) protection component is embedded in the package substrate. In some implementations, the die includes an internal electrostatic discharge (ESD) protection component configured to provide die level electrostatic discharge (ESD) protection. In some implementations, the internal electrostatic discharge (ESD) protection component and the first electrostatic discharge (ESD) protection component are configured to provide cumulative electrostatic discharge (ESD) protection for the die.

Abstract: A CMOS amplifier including electrostatic discharge (ESD) protection circuits is disclosed. In one embodiment, the CMOS amplifier may include a PMOS transistor, a NMOS transistor, primary protection diodes, and one or more auxiliary protection diodes to limit a voltage difference between terminals of the CMOS amplifier. In some embodiments, the auxiliary protection diodes may limit the voltage difference between an input terminal of the CMOS amplifier and a supply voltage, the input terminal of the CMOS amplifier and ground, and the input terminal and the output terminal of the CMOS amplifier.

Abstract: A CMOS amplifier including electrostatic discharge (ESD) protection circuits is disclosed. In one embodiment, the CMOS amplifier may include a PMOS transistor, a NMOS transistor, primary protection diodes, and one or more auxiliary protection diodes to limit a voltage difference between terminals of the CMOS amplifier. In some embodiments, the auxiliary protection diodes may limit the voltage difference between an input terminal of the CMOS amplifier and a supply voltage, the input terminal of the CMOS amplifier and ground, and the input terminal and the output terminal of the CMOS amplifier.

Abstract: A system interconnect includes a first resistor-capacitor (RC) clamp having a first RC time constant. The system interconnect also includes second RC clamps having a second RC time constant. The first and second RC clamps are arranged along the system interconnect. In addition, the first RC time constant is different from the second RC time constant.

Abstract: A device includes a snapback clamp circuit configured to clamp a supply voltage in response to the supply voltage exceeding a trigger voltage level. In at least one embodiment, the snapback clamp circuit includes a clamp transistor and a programmable resistance portion that is responsive to a control signal to calibrate the trigger voltage level. Alternatively or in addition, the snapback clamp circuit may include a programmable bias device configured to calibrate the trigger voltage level by biasing a gate terminal of the clamp transistor. In another particular embodiment, a method of calibrating a snapback clamp circuit is disclosed. In another particular embodiment, a method of operating an integrated circuit is disclosed.

Abstract: Techniques for reducing leakage current during normal operation of an electrostatic discharge (ESD) circuit are described herein. In one embodiment, a circuit comprises an internal circuit and an electrostatic discharge (ESD) rail clamp coupled in parallel to the internal circuit and between first and second power supply rails. The ESD rail clamp is operable to shunt ESD current from the first power supply rail to the second power supply rail via a low resistance shunt path. The ESD rail clamp comprises an ESD trigger circuit configured to detect an ESD event and a plurality of discharging transistors coupled in series. The ESD trigger circuit is configured to turn off the discharging transistors during normal operation and to turn on the discharging transistors to form the low resistance shunt path in response to detection of the ESD event.

Abstract: In a particular embodiment, a circuit includes a power supply, a ground, and a clamping transistor circuit coupled to the power supply and to the ground. The circuit further includes a disable clamp circuit. The disable clamp circuit is coupled to the power supply and is responsive to a second power supply input to selectively disable the clamping transistor circuit by modifying a charging current applied to a capacitor of the clamping transistor circuit. In a particular embodiment, modifying the charging current includes enabling a second charging path. Enabling the second charging path enables charging the capacitor at a higher charging rate than a charging rate associated with charging the capacitor via a first charging path.

Abstract: A system interconnect includes a first resistor-capacitor (RC) clamp having a first RC time constant. The system interconnect also includes second RC clamps having a second RC time constant. The first and second RC clamps are arranged along the system interconnect. In addition, the first RC time constant is different from the second RC time constant.

Abstract: An apparatus is described. The apparatus includes an input device. The apparatus also includes a positive supply voltage pad. The apparatus further includes an input signal pad. The apparatus also includes a ground pad. The apparatus further includes charged-device model protection circuitry that protects the input device from electrostatic discharge. The charged-device model protection circuitry includes at least one of de-Q circuitry and a cascode device.

Abstract: An apparatus is described. The apparatus includes an input device. The apparatus also includes a positive supply voltage pad. The apparatus further includes an input signal pad. The apparatus also includes a ground pad. The apparatus further includes charged-device model protection circuitry that protects the input device from electrostatic discharge. The charged-device model protection circuitry includes at least one of de-Q circuitry and a cascode device.

Abstract: A device includes a snapback clamp circuit configured to clamp a supply voltage in response to the supply voltage exceeding a trigger voltage level. In at least one embodiment, the snapback clamp circuit includes a clamp transistor and a programmable resistance portion that is responsive to a control signal to calibrate the trigger voltage level. Alternatively or in addition, the snapback clamp circuit may include a programmable bias device configured to calibrate the trigger voltage level by biasing a gate terminal of the clamp transistor. In another particular embodiment, a method of calibrating a snapback clamp circuit is disclosed. In another particular embodiment, a method of operating an integrated circuit is disclosed.

Abstract: In a particular embodiment, a circuit includes a power supply, a ground, and a clamping transistor circuit coupled to the power supply and to the ground. The circuit further includes a disable clamp circuit. The disable clamp circuit is coupled to the power supply and is responsive to a second power supply input to selectively disable the clamping transistor circuit by modifying a charging current applied to a capacitor of the clamping transistor circuit. In a particular embodiment, modifying the charging current includes enabling a second charging path. Enabling the second charging path enables charging the capacitor at a higher charging rate than a charging rate associated with charging the capacitor via a first charging path.

Abstract: The invention shows how diodes in a modern semiconductor process can be used as a very compact switch element in a Programmable Read Only Memory (PROM) using common integrated circuit fuse elements such as polysilicon and metal. This compact switch element allows very dense PROM arrays to be realized since diodes have the highest conduction density of any semiconductor device. The high conduction density is used to provide the relatively high current needed to blow the fuse element open. Since MOSFETs are typically used as fuse array switch elements, a relatively large area is required for the MOSFET to reach the current needed to blow the fuse element. Since diodes are two terminal switch elements unlike MOSFETs which are three terminal devices, methods are outlined on how to both read and write the arrays using this two terminal switch.

Abstract: This invention details how a low cost opto coupler can be made on Silicon On Insulator (SOI) using conventional integrated circuit processing methods. Specifically, metal and deposited insulating materials are use to realize a top reflector for directing light generated by a silicon PN junction diode to a silicon PN junction photo diode detector. The light generator or LED can be operated either in the avalanche mode or in the forward mode. Also, side reflectors are described as a means to contain the light to the LED-photo detector pair. Furthermore, a serpentine junction PN silicon LED is described for the avalanche mode of the silicon LED. For the forward mode, two LED structures are described in which hole and electrons combine in lightly doped regions away from heavily doped regions thereby increasing the LED conversion efficiency.