A failure diagnostic apparatus includes a path calculation unit which calculates, for each input pattern to a diagnosis target cell, a path affecting an output value of the diagnosis target cell when a failure is assumed as an activation path, a path classification unit which classifies the activation path associated with the input pattern for which the diagnosis target cell has passed a test and the activation path associated with the input pattern for which the diagnosis target cell has failed the test, a path narrowing unit which calculates a first failure candidate path, a second failure candidate path and a normal path of the diagnosis target cell based on classified activation paths, and a result output unit which outputs information on the first failure candidate path, the second failure candidate path and the normal path.

Various embodiments may include methods and systems for monitoring characteristics of a system-on-a-chip. Various embodiments may include inputting, from a test data input connection, test data to a first scan chain section including a first group of logic gates located within a first region of the SoC. Various embodiments may include providing, from a first clock gate associated with the first region of the SoC, a clock signal to the first group of logic gates. Various embodiments may include measuring, using a first sensor, the characteristics at a second region of the SoC in response to providing the clock signal to the first group of logic gates. Embodiments may further include processing or analyzing measured characteristics to determine a testing result.

The disclosure describes a novel method and apparatus for improving interposers to include embedded monitoring instruments for real time monitoring digital signals, analog signals, voltage signals and temperature sensors located in the interposer. An embedded monitor trigger unit controls the starting and stopping of the real time monitoring operations. The embedded monitoring instruments are accessible via an 1149.1 TAP interface on the interposer.

A circuit includes a test data input (TDI) pin receiving a test data input signal, a test data out (TDO) pin outputting a test data output signal, and debugging test access port (TAP) having a test data input coupled to the TDI pin and a bypass register having an input coupled to the test data input of the debugging TAP. A multiplexer has inputs coupled to the TDI pin and the debugging TAP. A testing TAP has a test data input coupled to the output of the multiplexer, and a data register having an input coupled to the test data input of the testing TAP. The multiplexer switches so the test data input signal is selectively coupled to the input of the data register of the testing TAP so the output of the debugging TAP is selectively coupled to the input of the data register of the testing TAP.

A device including a management logic unit and a user logic unit, where the management logic unit comprises a Peripheral Component Interconnect Express (PCIe) module, and the PCIe module comprises a first physical functional unit and a second physical functional unit. The first physical functional unit is configured to receive a user logic loading request initiated by the second physical functional unit, where the user logic loading request carries a user logic identifier; obtain a user logic file based on the user logic identifier; and burn the user logic file into the user logic unit via a PCIe configuration channel. The present disclosure solves the technical problem that an existing FPGA cannot be deployed in the cloud due to the need for connecting to a JTAG cable when being remotely configured or debugged.

The disclosure describes a novel method and apparatuses for allowing a controller to select and access different types of access ports in a device. The selecting and accessing of the access ports is achieved using only the dedicated TDI, TMS, TCK, and TDO signal terminals of the device. The selecting and accessing of device access ports can be achieved when a single device is connected to the controller, when multiple devices are placed in a daisy-chain arrangement and connected to the controller, or when multiple devices are placed in a addressable parallel arrangement and connected to the controller. Additional embodiments are also provided and described in the disclosure.

The present invention provides a method, device, and system for testing devices under testing (DUTs). The method comprises: sending a scan activated signal and a synchronous clock signal via the second signal line, and sending a first preset signal via the serial signal line, wherein each bit of the first preset signal is transmitted to a corresponding scan chain unit in a sequence of serial connection of the plurality of scan chain units with according to the synchronous clock signal, the corresponding scan chain unit is one of the plurality of scan chain units connected serially and coupled to the plurality of DUTs via a third signal line; sending a scan deactivated signal via the second signal line, to deactivate the scan chain units from identifying and receiving the first preset signal; and sending a second preset signal via the second signal line, and sending a test signal via the first signal line.

The present disclosure describes exemplary methods and systems that are applicable for hardware authentication, counterfeit detection, and in-field tamper detection in both printed circuit board and/or integrated circuit levels by utilizing random variations in boundary-scan path delay and/or current in the industry-standard JTAG-based design-for-test structure to generate unique device identifiers.

The present disclosure describes using the JTAG Tap's TMS and/or TCK terminals as general purpose serial Input/Output (I/O) Manchester coded communication terminals. The Tap's TMS and/or TCK terminal can be used as a serial I/O communication channel between; (1) an IC and an external controller, (2) between a first and second IC, or (3) between a first and second core circuit within an IC. The use of the TMS and/or TCK terminal as serial I/O channels, as described, does not effect the standardized operation of the JTAG Tap, since the TMS and/or TCK I/O operations occur while the Tap is placed in a non-active steady state.

A network device including access and test ports, an interface, and first and second controllers. The interface receives an Ethernet frame transmitted over an Ethernet network to the network device. The Ethernet frame includes bits for testing or debugging the memory-mapped device and is received at the interface based on an output of a host device. The first controller converts the Ethernet frame to a first access frame. The test port receives a diagnostic signal transmitted from the host device to the network device. The second controller converts the diagnostic signal to a second access frame and controls passage of the access frames to the memory-mapped device via the access port. The first controller tests or debugs the memory-mapped device based on data received from a register of the memory-mapped device. The data is written in the register based on the first and second access frames.