Abstract: A method generates scan patterns for testing an electronic device called DUT having a scan path. A scan tester is arranged for executing a scan shift mode and a capture mode. A scan test interface has a clock control unit for stretching a shift cycle of the scan clock in dependence of a scan clock pattern. The method determines at least one power shift cycle which is expected to cause a voltage drop of a supply voltage exceeding a predetermined threshold during respective shift cycles of the scan shift mode, and generates, in addition to the scan pattern, a scan clock pattern indicative of stretching the power shift cycle. Advantageously, a relatively high scan shift frequency may be used while avoiding detrimental effects of said voltage drop by extending the respective power shift cycle, whereby test time and yield loss are reduced.

Abstract: An integrated circuit includes an input/output “I/O” cell arranged to drive an output signal and an activity analysis unit arranged to generate an activity factor based on the output signal. The activity factor represents a switching activity intensity of the I/O cell. The switching activity intensity is associated with an ageing effect of the I/O cell. The circuit further includes a calibration unit arranged to generate a switching pattern signal based on the generated activity factor and an I/O calibration cell arranged to be driven by the switching pattern signal, wherein the switching pattern signal emulates the ageing effect of the I/O cell.

Abstract: An integrated circuit device comprising at least one electrostatic discharge (ESD) clamp device. The at least one ESD clamp device comprises a first channel input, a second channel input, and a control input arranged to receive a control signal. The at least one ESD clamp device is arranged to selectively operate in a conductive state in which the at least one ESD clamp device permits current to flow between the first and second channel inputs thereof based at least partly on the received control signal. The integrated circuit device further comprises at least one biasing module. The at least one biasing module comprises at least one output operably coupled to the control input of the at least one ESD clamp device, and at least one input arranged to receive a thermal regulation signal. The at least one biasing module being arranged to apply a bias to the control signal for the at least one ESD clamp device based at least partly on the received thermal regulation signal.

Abstract: An integrated circuit device comprising a semiconductor die contained in a package. The integrated circuit device includes one or more internal connection verification modules for asserting a poor connection signal for the test apparatus in response to a voltage difference between a voltage at a corresponding internal power supply node and a reference voltage, the voltage difference being indicative of a poor connection of power supply to one of power supply terminals on the package. The test apparatus can include an indicator or a sorting element for rejecting or accepting the integrated circuit device in response to logic signals indicative of the presence or absence of a defect accompanied by non-assertion of the poor connection signal, and for processing the integrated circuit device distinctively in response to assertion of the poor connection signal.

Abstract: A system for on-die voltage difference measurement on a pass device comprises a first voltage controlled oscillator circuit having a first voltage control input connectable to a first terminal of the pass device; a second voltage controlled oscillator circuit having a second voltage control input connectable to a second terminal of the pass device; a first counter circuit arranged to count oscillation periods of a first output signal from the first voltage controlled oscillator circuit and to provide a stop signal when a predefined number of the oscillation periods of the first output signal is counted; and a second counter circuit arranged to count oscillation periods of a second output signal from the second voltage controlled oscillator circuit and to stop counting depending on the stop signal.

Abstract: A device that includes at least one current consuming component. The device is characterized by including a compensation circuit adapted to compare between a voltage level at a sensing point within an integrated circuit and between a reference voltage derived from a voltage peak level at the sensing point; and to selectively increase the voltage at the sensing point in response to the comparison. A method for compensating for voltage drops in an integrated circuit, the method includes providing at least a first supply voltage to an integrated circuit; the method is characterized by including: comparing between a voltage level at a sensing point within an integrated circuit to a reference voltage derived from a voltage peak level at the sensing point; and selectively increasing the voltage at the sensing point in response to the comparison.

Abstract: An integrated circuit device comprising at least one voltage supply module arranged to receive at an input thereof at least one control signal and to provide at an output thereof a voltage signal in accordance with the received at least one control signal, and at least one control module comprising at least one feedback loop between the output of the at least one voltage supply module and the input of the at least one voltage supply module, and arranged to generate the at least one control signal based at least partly on the voltage level of the voltage signal output by the at least one voltage supply module. The at least one control module is further arranged to receive at an input thereof at least one instantaneous indication of a load current at the output of the at least one voltage supply module, and apply a compensation to the at least one control signal provided to the at least one voltage supply module based at least partly on the received at least one indication of the load current.

Abstract: Systems and methods to secure near field communications (NFC) are disclosed. An NFC polling device may detect a change in voltage when attempting to communicate with another NFC device and based at least in part on the magnitude of the change in voltage if there is an attempted hacking and/or snooping event. The NFC polling device may further identify the number of modulation voltage levels detected and determine if there is an attempted hacking event based on the number of modulation voltage levels detected.

Abstract: An input/output (IO) driver circuit is described. The IO buffer driver circuit comprises: at least one input for receiving an input signal and at least one output for providing at least one output signal; and a plurality of switches arranged to provide a variable voltage level between a low voltage value and a high voltage value to the at least one output. The at least one first switch of the plurality of switches is arranged to initiate a voltage change to an intermediate voltage level between the low voltage value and the high voltage value in a first time period. The at least one second switch of the plurality of switches is arranged to continue the voltage change to the low voltage value or the high voltage value in a second time period.

Abstract: An apparatus for voltage ripple reduction on a power supply line of an integrated circuit device is provided to be operable in at least two modes. The apparatus includes: one or more clamping devices connectable to the power supply line; a clamp control unit; and a mode change detection unit arranged to monitor an interface of the integrated circuit device for one or more information indicating an upcoming mode change of the integrated circuit device and to provide a mode change signal to the clamp control unit when the one or more information is detected. The clamp control unit is arranged to connect at least one of the one or more clamping devices to the power supply line when receiving the mode change signal.

Abstract: An IO driver for an integrated circuit and a method for calibrating such an IO driver are provided. The IO driver comprises a plurality of IO driver cells, a plurality of IO partial driver cells and an external resistor. The IO driver cells control IO operations for a corresponding plurality of data channels of the integrated circuit. The IO partial driver cells are coupled to respective cells of the plurality of IO driver cells. The external resistor provides a reference impedance. The reference partial driver cell is coupled to the external resistor and is arranged to determine the reference impedance and to provide information depending on the reference impedance to the IO partial driver cells. The IO partial driver cells are arranged to calibrate the respective IO driver cells based on the provided information.

Abstract: An integrated circuit for bias stress condition removal comprising at least one input/output (IO) buffer driver circuit comprising at least one input signal is described. A primary buffer driver stage receives the at least one input signal and providing an output signal in a first time period; and a secondary buffer driver stage receives the at least one input signal and providing an output signal in a second time period. The primary buffer driver stage and the secondary buffer driver stage cooperate and an operational mode of the primary buffer driver stage and an operational mode of the secondary buffer driver stage is varied to produce a varying output signal.

Abstract: An electronic device comprising a first power switch connectable or connected between a first voltage source and a load is proposed. The first power switch assumes a conductive state in response to a power-on request and a non-conductive state in response to a power-off request, for energizing and deenergizing the load, so that a voltage across the first power switch tends to a positive high level when the first power switch is in the non-conductive state and to a positive low level when the first power switch is in the conductive state. The device further comprises a second power switch connectable or connected between a second voltage source and the load. The second power switch assumes a conductive state in response to the power-on request and a non-conductive state when the voltage across the first power switch is below a defined switch-off threshold lower than the high level. The second voltage source thus assists the first voltage source in powering up the load.

Abstract: A device that includes at least one current consuming component. The device is characterized by including a compensation circuit adapted to compare between a voltage level at a sensing point within an integrated circuit and between a reference voltage derived from a voltage peak level at the sensing point; and to selectively increase the voltage at the sensing point in response to the comparison. A method for compensating for voltage drops in an integrated circuit, the method includes providing at least a first supply voltage to an integrated circuit; the method is characterized by including: comparing between a voltage level at a sensing point within an integrated circuit to a reference voltage derived from a voltage peak level at the sensing point; and selectively increasing the voltage at the sensing point in response to the comparison.

Abstract: An integrated circuit device comprising at least one calibration module for calibrating an impedance of at least one on-die interconnect line driver in order to adaptively match an impedance between the at least one on-die interconnect line driver and at least one on-die interconnect line conjugated thereto. The at least one calibration module is arranged to receive an indication of an output signal of the at least one line driver, compare the received indication of an output signal to a reference signal and detect a presence or an absence of a voltage overshoot of the output signal of the at least one line driver, and upon detection of a presence or an absence of a voltage overshoot of the output signal of the at least one line driver, cause the adjustment of power supply of the at least one line driver, to be decreased or increased correspondingly.

Abstract: A voltage level shifter for translating a binary input signal representing a binary sequence to a binary output signal representing the same binary sequence. The voltage level shifter comprises an input port for receiving the binary input signal as an input voltage varying between a first input voltage level and a second input voltage level. An output port is connected to a node for outputting the binary output signal as an output voltage varying between a first output voltage level and a second output voltage level. A supply voltage node connectable to a voltage supply, can provide the second output voltage level. A first switch is arranged to couple the supply voltage node to the node and to decouple the supply voltage node from the node based on a voltage at the node. A feedback voltage loop is connected to the node for providing a feedback voltage based on the voltage at the node.

Abstract: A device that includes at least one current consuming component. The device is characterized by including a compensation circuit adapted to compare between a voltage level at a sensing point within an integrated circuit and between a reference voltage derived from a voltage peak level at the sensing point; and to selectively increase the voltage at the sensing point in response to the comparison. A method for compensating for voltage drops in an integrated circuit, the method includes providing at least a first supply voltage to an integrated circuit; the method is characterized by including: comparing between a voltage level at a sensing point within an integrated circuit to a reference voltage derived from a voltage peak level at the sensing point; and selectively increasing the voltage at the sensing point in response to the comparison.

Abstract: An integrated circuit device comprising at least one voltage supply module arranged to receive at an input thereof at least one control signal and to provide at an output thereof a voltage signal in accordance with the received at least one control signal, and at least one control module comprising at least one feedback loop between the output of the at least one voltage supply module and the input of the at least one voltage supply module, and arranged to generate the at least one control signal based at least partly on the voltage level of the voltage signal output by the at least one voltage supply module. The at least one control module is further arranged to receive at an input thereof at least one instantaneous indication of a load current at the output of the at least one voltage supply module, and apply a compensation to the at least one control signal provided to the at least one voltage supply module based at least partly on the received at least one indication of the load current.

Abstract: Embodiments of the present invention provide a voltage level shifter used to translate a binary input signal representing a binary sequence to a binary output signal representing the same binary sequence. The input signal is provided by an input voltage varying between a first input voltage level and a second input voltage level. The output signal is provided by an output voltage varying between a first output voltage level and a second output voltage level. The output signal has a delay relative to the input signal, and the voltage level shifter has a leakage current. The voltage level shifter has a first operating mode and a second operating mode. In the second operating mode, the delay is shorter while the leakage current is higher than in the first operating mode.

Abstract: An integrated circuit, comprises a power supply node being connectable to a voltage supply (Vdd); a ground node connectable to ground (GND); and an electrostatic discharge protection structure for diverting an electrostatic discharge away from protected parts of the integrated circuit. A gated domain is present which is supply gated and/or ground gated with respect to the power supply node and/or the ground node, as well as a gating switch for gating the gated domain relative to the power supply node and/or the ground node. The gating switch enables in a connecting state, and in a disconnecting state inhibits, an electrical connection between the gated domain and at least one of: the power supply node and the ground node. The integrated circuit includes ESD gating control circuitry for controlling in case of an electrostatic discharge event the gated domain to be electrically connected to the power supply node and/or the ground node.