Introduced herein is a technique that reliably measures on-die noise of logic in a chip. The introduced technique places a noise measurement system in partitions of the chip that are expected to cause the most noise. The introduced technique utilizes a continuous free-running clock that feeds functional frequency to the noise measurement circuit throughout the noise measurement scan test. This allows the noise measurement circuit to measure the voltage noise of the logic during a shift phase, which was not possible in the conventional noise measurement method. Also, by being able to measure the voltage noise during a shift phase and hence in both phases of the scan test, the introduced technique can perform a more comprehensive noise measurement not only during ATE testing but as part of IST in the field.

A test circuit includes one or more sensors adapted to be formed on a wafer, each sensor detecting one or more wafer characterization data in a stressed condition; a stress generator controlling the one or more sensors to place the one or more sensors under stress during wafer manufacturing; memory coupled to the one or more sensors to store wafer characteristics under the stressed condition; and an interface coupled to the memory to communicate the wafer characterization data to a tester.

A burn-in board for testing the operational integrity of memory devices includes local heating elements for each memory device under test. Each socket on the burn-in board may include a pair of opposed latch heads which move between open positions allowing a memory device to be mounted in the socket, and closed positions where the latch heads rest against the memory device to secure the device in the socket. Local heating elements may be integrated into the latch heads to ensure even heating of each memory device in the burn-in board.

A circuit includes a power transistor having a main current path between a first supply node and an output pin for connecting a load. A resistance formed by a chip metallization is arranged between the main current path of the power transistor and the output pin. The circuit includes a current measuring circuit coupled to the power transistor and including a sense transistor coupled to the power transistor. The current measuring circuit delivers a measurement current representing a load current flowing through the power transistor. An amplifier circuit generates an amplifier output signal representing the voltage across the resistance, and a control circuit outputs a signal representing the measurement current in a first mode and a signal dependent on the amplifier output signal in a second mode.

A ring oscillator system for characterizing substrate strain including, a substrate including a through-substrate-via, at least two ring oscillators, wherein a first ring oscillator is closer to the through-substrate-via than a second ring oscillator, and a logic difference circuit that is configured to receive an input from at least the first ring oscillator and the second ring oscillator, and detect a difference between the signal frequency of the first ring oscillator and the signal frequency of the second ring oscillator.

An apparatus includes a resistor and a circuit. The resistor may be fabricated on a die using a semiconductor process. The circuit may be fabricated on the die using the semiconductor process and may be configured to (i) generate a measurement voltage at a node of the resistor as a function of a capacitance value and a frequency of a clock signal and (ii) generate a codeword in response to the measurement voltage. The codeword generally has a plurality of possible values. A particular value of the possible values may verify that the voltage is between a plurality of threshold voltages.

An apparatus and method for testing gallium nitride field effect transistors (GaN FETs) are disclosed herein. In some embodiments, the apparatus includes: a high side GaN FET, a low side GaN FET, a high side driver coupled to a gate of the high side GaN FET, a low side driver coupled to a gate of the low side GaN FET, and a driver circuit coupled to the high side and low side drivers and configured to generate drive signals capable of driving the high and low side GaN FETs, wherein the high and low side GaN FETs and transistors, within the high and low side drivers and the driver circuit, are patterned on a same semiconductor device layer during a front-end-of-line (FEOL) process.

A bonded structure is disclosed. The bonded structure can include a first semiconductor element having a first front side and a first back side opposite the first front side. The bonded structure can include a second semiconductor element having a second front side and a second back side opposite the second front side, the first front side of the first semiconductor element directly bonded to the second front side of the second semiconductor element along a bond interface without an adhesive. The bonded structure can include security circuitry extending across the bond interface, the security circuitry electrically connected to the first and second semiconductor elements

Embodiments of the invention include a method of preparing an integrated circuit (IC) chip to participate in test operations. The method includes accessing a back surface of the IC chip and adding a back-surface topography to the back surface. A surface area of the back-surface topography is greater than a surface area of the back surface.

An integrated circuit includes an I/O pad and a protection device coupled to the I/O pad and a first supply node. A transient event detector includes a latch; a first transistor having a first current electrode coupled to the I/O pad, a control electrode coupled to a first supply node, and a second current electrode coupled to a data input of the latch, wherein the latch is configured to store an indication that a transient event occurred. An event level sensor includes a first transistor having a first current electrode coupled to the I/O pad, a control electrode coupled to the protection device, and a second current electrode coupled to a load circuit; a rectifier device coupled between the second current electrode and a capacitor; a second transistor having a control electrode coupled to the capacitor; and an output circuit configured to place a current on a first sense bus proportional to a current through the load circuit.