Abstract: Various implementations described herein are directed to a circuit for translating an input signal from a source voltage domain to an output signal for a destination voltage domain that is is different than the source voltage domain. The circuit may include a level shifting portion configured to operate with a supply voltage that exceeds a stressing threshold of one or more components within the circuit. The level shifting portion may be configured to generate the output signal for the destination voltage domain based on the input signal and a power management signal. The circuit may include an isolating portion configured to isolate the one or more components from the supply voltage during activation and deactivation of the circuit based on the power management signal.

Abstract: An integrated circuit is provided with interface circuitry used to provide an interface between functional circuitry of the integrated circuit and components external to the integrated circuit. The interface circuitry includes a plurality of interface cells having interface components configured to operate from a first power supply. Each interface cell incorporates a power supply line section extending across its width and configured to cooperate with power supply line sections of other interface cells to provide a power supply line structure shared by the plurality of interface cells, for provision of the first power supply to the interface components. Each power supply line section includes a first supply line portion and a second supply line portion, the first supply line portion being sized to support a current carrying constraint of the interface circuitry, while the second supply line portion is sized insufficiently to support that current carrying constraint.

Abstract: An integrated circuit is provided with interface circuitry used to provide an interface between functional circuitry of the integrated circuit and components external to the integrated circuit. The functional circuitry is configured to operate from a first power supply and has a power supply distribution network associated therewith providing the first power supply to the functional components of the functional circuitry. The interface comprises a plurality of interface cells that have interface components operating from a second power supply different to the first power supply. A power supply line structure is shared by the plurality of interface cells, and arranged to provide the second power supply to the interface components. In addition, at least a subset of the interface cells include additional interface components that operate from the first power supply.

Abstract: Various implementations described herein are directed to a circuit for translating an input signal from a source voltage domain to an output signal for a destination voltage domain that is is different than the source voltage domain. The circuit may include a level shifting portion configured to operate with a supply voltage that exceeds a stressing threshold of one or more components within the circuit. The level shifting portion may be configured to generate the output signal for the destination voltage domain based on the input signal and a power management signal. The circuit may include an isolating portion configured to isolate the one or more components from the supply voltage during activation and deactivation of the circuit based on the power management signal.

Abstract: An integrated circuit is provided with interface circuitry used to provide an interface between functional circuitry of the integrated circuit and components external to the integrated circuit. The functional circuitry is configured to operate from a first power supply and has a power supply distribution network associated therewith providing the first power supply to the functional components of the functional circuitry. The interface comprises a plurality of interface cells that have interface components operating from a second power supply different to the first power supply. A power supply line structure is shared by the plurality of interface cells, and arranged to provide the second power supply to the interface components. In addition, at least a subset of the interface cells include additional interface components that operate from the first power supply.

Abstract: An integrated circuit is provided with interface circuitry used to provide an interface between functional circuitry of the integrated circuit and components external to the integrated circuit. The interface circuitry includes a plurality of interface cells having interface components configured to operate from a first power supply. Each interface cell incorporates a power supply line section extending across its width and configured to cooperate with power supply line sections of other interface cells to provide a power supply line structure shared by the plurality of interface cells, for provision of the first power supply to the interface components. Each power supply line section includes a first supply line portion and a second supply line portion, the first supply line portion being sized to support a current carrying constraint of the interface circuitry, whilst the second supply line portion is sized insufficiently to support that current carrying constraint.

Abstract: Circuitry comprises a high voltage rail providing a high voltage level corresponding to a higher voltage domain, an intermediate voltage source, a low voltage rail, and devices that operate in a lower voltage domain. First devices in an upper voltage region are powered between the high voltage rail and an intermediate voltage rail powered by the intermediate source. Second devices in a lower voltage region are powered between the intermediate and low rails. On power up, the intermediate source is powered before the high voltage rail. An isolating circuit connects the intermediate source to a node when the high voltage rail is powered and isolates the node from the intermediate source when the high voltage rail is not powered to impede current flow from the intermediate source to the high voltage rail.

Abstract: An electrostatic protection apparatus is disclosed that has a voltage level supply configured to supply a voltage level to an electrostatic discharge protection device and the electrostatic discharge protection device that protects a semiconductor electronic device from a rapidly increasing incoming current.

Abstract: Level shifting circuitry comprises a first level shifter and a second level shifter. In response to a falling edge transition of an input signal, the first level shifter generates a primary transition of a first intermediate signal faster than the second level shifter generates a secondary transition of a second intermediate signal. In response to a rising edge of the input signal, the second level shifter generates a primary transition of the second intermediate signal faster than the first level shifter generates a secondary transition of the first intermediate signal. Output switching circuitry is provided to switch an output signal between an output high voltage level and an output low voltage level in response to the primary transition of the first intermediate signal and the primary transition of the second intermediate signal.

Abstract: A cascoded level shifter is subdivided into a first voltage section and a second voltage section, the first voltage section having a lower voltage supply than the second voltage section, and a combined voltage across the first voltage section and the second voltage section corresponding to the high voltage range. The shifter includes an input node receiving an input signal, a cascoded device disposed in one of the first voltage section and the second voltage section, the cascoded device includes a driver switch connected in series with a cascode switch at a midpoint node, the cascode switch switching in dependence on a reference voltage of a reference node and the input signal, and reference voltage perturbation circuitry configured to cause a transient perturbation to the reference voltage in response to a transition of the input signal to cause the cascode switch to switch.

Abstract: Circuitry, operating in a high voltage domain, including a high and low voltage inputs, and including a plurality of devices designed to operate optimally powered in a native voltage domain that is lower voltage than said high voltage domain and some devices arranged in two sets. The circuitry including a further input for receiving the high native voltage level. Each set having at least one device, a first set being arranged to receive an intermediate low reference voltage level as a low voltage level signal and the high voltage level as a high voltage level signal and the second set being arranged to receive the high native voltage level as a high voltage level signal and the low voltage level as a low voltage level signal. The intermediate low reference voltage level includes a voltage level generated by subtracting the high native voltage level from the high voltage level.

Abstract: A cascoded input-output device is provided configured to receive at an input node a lower voltage input signal and to generate at an output node a higher voltage output signal. The input-output device is split into two voltage domains to enable output signals in a larger range to be generated, while the components of the input-output device individually operate in a smaller range. By applying a selected bias voltage to a protected node of the cascoded input-output device, first changing that selected bias voltage in response to a transition of the input signal and then switching that selected bias voltage back when the output signal reaches a predetermined level, that node is protected, either avoiding stress-inducing voltage swings or providing a switching speed increasing charge boost.

Abstract: An electrostatic protection apparatus is disclosed that has a voltage level supply configured to supply a voltage level to an electrostatic discharge protection device and the electrostatic discharge protection device that protects a semiconductor electronic device from a rapidly increasing incoming current.

Abstract: Level shifting circuitry comprises a first level shifter and a second level shifter. In response to a falling edge transition of an input signal, the first level shifter generates a primary transition of a first intermediate signal faster than the second level shifter generates a secondary transition of a second intermediate signal. In response to a rising edge of the input signal, the second level shifter generates a primary transition of the second intermediate signal faster than the first level shifter generates a secondary transition of the first intermediate signal. Output switching circuitry is provided to switch an output signal between an output high voltage level and an output low voltage level in response to the primary transition of the first intermediate signal and the primary transition of the second intermediate signal.

Abstract: An apparatus is disclosed for receiving input signals in a first higher voltage domain and for generating and outputting signals in a second lower voltage domain, said apparatus comprising: an input pad; output circuitry, said output circuitry being configured to switch to output a first predetermined value in response to a rising input signal exceeding an upper threshold value and to switch to output a second predetermined value in response to a falling input signal falling below a lower threshold value; a first input path; a second input path; and a controllable connecting path between said first and second inputs.

Abstract: A cascoded level shifter is subdivided into a first voltage section and a second voltage section, the first voltage section having a lower voltage supply than the second voltage section, and a combined voltage across the first voltage section and the second voltage section corresponding to the high voltage range. The shifter includes an input node receiving an input signal, a cascoded device disposed in one of the first voltage section and the second voltage section, the cascoded device includes a driver switch connected in series with a cascode switch at a midpoint node, the cascode switch switching in dependence on a reference voltage of a reference node and the input signal, and reference voltage perturbation circuitry configured to cause a transient perturbation to the reference voltage in response to a transition of the input signal to cause the cascode switch to switch.

Abstract: A cascoded level shifter for receiving an input signal in a low voltage range and for generating an output signal in a high voltage range is disclosed.

Abstract: Circuitry is disclosed that comprises: a high voltage rail for providing a high voltage level corresponding to a first higher voltage domain; an intermediate voltage source, a low voltage rail; and a plurality of devices configured to operate in a second lower voltage domain; said circuitry being configured such that a first set of said plurality of devices are arranged in an upper voltage region where they are powered between said high voltage rail and an intermediate voltage rail powered by said intermediate voltage source and a second set of said plurality of devices are arranged in a lower voltage region where they are powered between said intermediate voltage rail and said low voltage rail, said circuitry being configured such that on power up said intermediate voltage source is powered before said high voltage rail, said circuitry further comprising: an isolating circuit arranged in said upper voltage region, said isolating circuit comprising at least one switching device for connecting said intermediat

Abstract: An apparatus is disclosed for receiving input signals in a first higher voltage domain and for generating and outputting signals in a second lower voltage domain, said apparatus comprising: an input pad for receiving said input signals in said first higher voltage domain; output circuitry comprising a plurality of devices arranged between a high voltage source of said second lower voltage domain and a low voltage source, said plurality of devices being arranged in a first set and a second set, said first set being arranged between said high voltage source and said output and said second set being arranged between said output and said low voltage source, said output circuitry being configured to switch to output a first predetermined value in response to a rising input signal exceeding an upper threshold value and to switch to output a second predetermined value in response to a falling input signal falling below a lower threshold value; a first input path for sending said received input signals to a first inp

Abstract: A cascoded input-output device is provided configured to receive at an input node a lower voltage input signal and to generate at an output node a higher voltage output signal. The input-output device is split into two voltage domains to enable output signals in a larger range to be generated, whilst the components of the input-output device individually operate in a smaller range. By applying a selected bias voltage to a protected node of the cascoded input-output device, first changing that selected bias voltage in response to a transition of the input signal and then switching that selected bias voltage back when the output signal reaches a predetermined level, that node is protected, either avoiding stress-inducing voltage swings or providing a switching speed increasing charge boost.