Abstract: An integrated circuit may include an over-capability detection circuit coupled to an I/O pad which provides a shut-off signal to a latch controlling an ESD protection shunting component. The ESD protection shunting component is coupled between the I/O pad and a reference node of the integrated circuit. The over-capability detection circuit provides the shut-off signal when safe operating conditions are resumed after a voltage excursion at the I/O pad. After receiving the shut-off signal, the latch biases the ESD protection shunting component into an off-state.

Abstract: An ESD monitor device may take the form of an integrated circuit with a plurality of monitor components available at each I/O site of the ESD monitor device. Each monitor component has a physical structure which provides scalable ESD robustness. The monitor components are connected in parallel to an ESD bus. An integrated circuit may be formed by processing an ESD monitor device through one or more process steps of an integrated circuit manufacturing line, and subsequently measuring the ESD monitor device. Parameters of a process step of the manufacturing line may be adjusted to reduce ESD events at the process step, based on measurement results from the ESD monitor device. The integrated circuit may subsequently be processed through the adjusted process step.

Abstract: An integrated circuit with either a normally open MEMS ESD protection switch coupled between a bond pad and an internal circuit or a normally closed MEMS ESD protection switch coupled between the bond pad and a common reference of the integrated circuit. At least one of a control bond pad and an enable logic circuit is coupled to a control terminal of the MEMS ESD protection switch.

Abstract: An integrated circuit may include an over-capability detection circuit coupled to an I/O pad which provides a shut-off signal to a latch controlling an ESD protection shunting component. The ESD protection shunting component is coupled between the I/O pad and a reference node of the integrated circuit. The over-capability detection circuit provides the shut-off signal when safe operating conditions are resumed after a voltage excursion at the I/O pad. After receiving the shut-off signal, the latch biases the ESD protection shunting component into an off-state.

Abstract: An integrated circuit may include an over-capability detection circuit coupled to an I/O pad which provides a shut-off signal to a latch controlling an ESD protection shunting component. The ESD protection shunting component is coupled between the I/O pad and a reference node of the integrated circuit. The over-capability detection circuit provides the shut-off signal when safe operating conditions are resumed after a voltage excursion at the I/O pad. After receiving the shut-off signal, the latch biases the ESD protection shunting component into an off-state.

Abstract: An ESD monitor device may take the form of an integrated circuit with a plurality of monitor components available at each I/O site of the ESD monitor device. Each monitor component has a physical structure which provides scalable ESD robustness. The monitor components are connected in parallel to an ESD bus. An integrated circuit may be formed by processing an ESD monitor device through one or more process steps of an integrated circuit manufacturing line, and subsequently measuring the ESD monitor device. Parameters of a process step of the manufacturing line may be adjusted to reduce ESD events at the process step, based on measurement results from the ESD monitor device. The integrated circuit may subsequently be processed through the adjusted process step.

Abstract: An integrated circuit may include an over-capability detection circuit coupled to an I/O pad which provides a shut-off signal to a latch controlling an ESD protection shunting component. The ESD protection shunting component is coupled between the I/O pad and a reference node of the integrated circuit. The over-capability detection circuit provides the shut-off signal when safe operating conditions are resumed after a voltage excursion at the I/O pad. After receiving the shut-off signal, the latch biases the ESD protection shunting component into an off-state.

Abstract: An integrated circuit with either a normally open MEMS ESD protection switch coupled between a bond pad and an internal circuit or a normally closed MEMS ESD protection switch coupled between the bond pad and a common reference of the integrated circuit. At least one of a control bond pad and an enable logic circuit is coupled to a control terminal of the MEMS ESD protection switch.

Abstract: Various apparatuses, methods and systems for protecting a driver from electrostatic discharge are disclosed herein. For example, some exemplary embodiments provide a driver, including a buffer, a leakage path blocking transistor connected to an output of the buffer, and an output driver connected to an output of the leakage path blocking transistor. Current from the output driver to the buffer is substantially blocked by the leakage path blocking transistor.

Abstract: Various apparatuses, methods and systems for protecting a driver from electrostatic discharge are disclosed herein. For example, some exemplary embodiments provide a driver, including a buffer, a leakage path blocking transistor connected to an output of the buffer, and an output driver connected to an output of the leakage path blocking transistor. Current from the output driver to the buffer is substantially blocked by the leakage path blocking transistor.

Abstract: An apparatus for reducing current leakage between an input locus and at least one power rail for a system includes, for each respective power rail: (a) A first diode unit coupled between the input locus and a coupling locus. The first diode unit is configured to effect substantially zero potential drop during normal operation of the apparatus. (b) A second diode unit coupled between the coupling locus and the respective power rail. The second diode unit is configured to present no forward bias during normal operation of the apparatus. The first and second diode units cooperate to effect current flow between the input locus and the respective power rail during a predetermined operational condition of the apparatus.