The present invention relates to: a spectral leakage-based loopback method for a built-in self-test (BIST), achieving cost efficiency by accurately predicting the nonlinearity of a mixed-signal circuit in a loopback mode; and a system therefor, the method comprising the steps of: modeling a correlation by deriving the transfer function of a loopback path; generating a digitally synthesized single-tone sine wave input signal by means of an on-chip DSP core so as to sample same in a nonlinear DAC channel, and supplying a DAC output signal to a nonlinear ADC channel through an analog loopback path so as to measure each of the DAC channel and the ADC channel for a process test; and performing post-processing by means of the on-chip DSP core and predicting the harmonics of the two separate DAC and ADC channels.

A test assembly for testing an antenna-in-package (AiP) device includes a socket over a circuit board, where the socket includes an opening for receiving the AiP device; a plunger configured to move along sidewalls of the opening, where during testing of the AiP device, the plunger is configured to cause the AiP device to be pressed towards the circuit board such that the AiP device is operatively coupled to the circuit board via input/output connections of the AiP device and of the circuit board; and a loadboard disposed within the socket and between the plunger and the AiP device, where the loadboard includes a coupling structure configured to be electromagnetically coupled to a transmit antenna and to a receive antenna of the AiP device, so that testing signals transmitted by the transmit antenna are conveyed to the receive antenna externally relative to the AiP device through the coupling structure.

A high-speed signal subsystem testing system includes a processing system having a transmitter and a receiver, a loop back subsystem coupled to the transmitter and receiver to provide a testing communication path between the transmitter and the receiver, and a communication path testing engine coupled to the transmitter and the receiver. The communication path testing engine generates test signal(s) and transmits the test signal(s) via the transmitter and through the testing communication path provided by the loop back subsystem and, in response, receives test signal result(s) via the receiver and through the testing communication path provided by the loop back subsystem, The communication path testing engine processes the test signal result(s) to generate a testing impedance profile for the testing communication path, and compares the testing impedance profile to an expected impedance profile to determine whether a testing communication path issue exists in the testing communication path.

A system includes a first integrated circuit including a first interface circuit with a first transmit pin and a first receive pin, and a first test circuit. The system also includes a second integrated circuit including a second interface circuit with a second receive pin coupled to the first transmit pin, and a second transmit pin coupled to the first receive pin. The second integrated circuit further includes a second test circuit configured to route signals from the second receive pin to the second transmit pin, such that the sent test signal is received by the second receive pin, bypasses the second test circuit, and is routed to the second transmit pin. The first test circuit is further configured to receive the routed test signal on the first receive pin via the second conductive path.

Circuits, methods, and systems are provided which facilitate testing of asynchronous circuits having one or more global or local feedback loops. A circuit includes a data path and a scan path. The data path has an input configured to receive a data input signal, and a first output. The scan path includes a first multiplexer having a first input configured to receive the data input signal, a latch coupled to an output of the first multiplexer, a scan isolator coupled to an output of the latch, and a second multiplexer having a first input coupled to the first output of the data path and a second input coupled to an output of the scan isolator. The second multiplexer is configured to output a data output signal.

A low voltage differential signaling (LVDS) receiver includes a receiver circuit including first and second inputs coupled to first and second conductive pads, respectively, and an output coupled to an input of a digital controller, and a dummy transmitter circuit including a first input coupled to receive a common mode voltage (VCM) tune signal, a second input coupled to a loopback input signal, a third input coupled to a loopback enable signal, a first output coupled to the first input of the receiver circuit, and a second output coupled to the second input of the receiver circuit. When a test mode of operation is enabled, the digital controller asserts the loopback enable signal, and the dummy transmitter circuit generates a pair of test differential signals based on the VCM tune signal, wherein the VCM tune signal varies to test the LVDS receiver over a range of common mode voltages.

A semiconductor chip includes a first wireless communication circuit, a local oscillator (LO) buffer, and an auxiliary path. The first wireless communication circuit has a signal path, wherein the signal path has a mixer input port and a signal node distinct from the mixer input port. The auxiliary path is used to electrically connect the LO buffer to the signal node of the signal path. The LO buffer is reused for a loop-back test function through the auxiliary path.

A system includes a first integrated circuit including a first interface circuit with a first transmit pin and a first receive pin, and a first test circuit. The system also includes a second integrated circuit including a second interface circuit with a second receive pin coupled to the first transmit pin, and a second transmit pin coupled to the first receive pin. The second integrated circuit further includes a second test circuit configured to route signals from the second receive pin to the second transmit pin, such that the sent test signal is received by the second receive pin, bypasses the second test circuit, and is routed to the second transmit pin. The first test circuit is further configured to receive the routed test signal on the first receive pin via the second conductive path.

Systems, methods, and storage media for detecting a security intrusion of a network device are disclosed. Exemplary implementations may include a method involving, in the network device including a processor, monitor a light signal associated with a security enabled port of the network device; and in response to detecting a change in the light signal, initiate a security alert.

The first logic wafer is attached to a supporting wafer, which adds sufficient depth to this bonded structure such that the first logic wafer may be thinned during the manufacturing process. The first logic wafer is thinned such that the through silicon vias may be etched in the substrate of the first logic wafer so as to provide adequate connectivity to a second logic wafer, which is bonded to the first logic wafer. The second logic wafer adds sufficient depth to this bonded structure to allow the supporting wafer to then be thinned to enable through silicon vias to be added to the supporting wafer so as to provide appropriate connectivity for the entire stacked structure. The thinned supporting wafer is retained in the finished stacked wafer structure and may comprise additional components (e.g. capacitors) supporting the operation of the processing circuitry in the logic wafers.