A method for at least one of identifying and compensating for system errors in a measurement system is disclosed, wherein the measurement system comprises a signal generator and a signal analyzer. The method comprises: generating a test signal via the signal generator, the test signal having predetermined properties; forwarding the test signal to a device under test; processing the test signal via the device under test, thereby generating a transmission signal; receiving the transmission signal via the signal analyzer; determining a response function of the device under test based on the test signal and based on the transmission signal; and determining at least one periodic component of the response function. Further, a measurement system as well as a calibration system are disclosed.

An integrated circuit (IC) includes a debug controller, a debug state machine (DSM), and an extended performance monitor counter (EPMC). The debug controller that selectively outputs debug data on a debug interconnect. The DSM identifies an event based on the debug data and an event list and outputs a DSM indication that identifies the event. The EPMC indicates a plurality of detected events including the identified event. The EPMC indicates the identified event in response to the DSM indication.

A method for detecting non-convergence error in a transient circuit simulation wherein a circuit netlist and control statements associated with a circuit for the transient circuit simulation are received. A transient circuit simulation is performed responsive to a time point. Whether a non-convergence error has occurred during transient circuit simulation is determined. A transient debug mode is actuated responsive to determination of occurrence of the non-convergence error. The steps of performing the transient circuit simulation and determining whether a non-convergence error has occurred are repeated after actuation of the transient debug mode. Results of the transient circuit simulation are provided responsive to a determination of non-occurrence of a non-convergence error.

A method of reconfiguring a current debug configuration of a debug unit connected to a peripheral circuit on an integrated circuit chip. The method comprises the debug unit collecting debug data of the peripheral circuit and outputting the debug data in a message stream. The debug unit receives a debug reconfiguration command. The debug unit transmits an indication of the current debug configuration, then reconfigures the current debug configuration to a new debug configuration in accordance with the debug reconfiguration command, then transmits an indication of the new debug configuration. The indication of the current debug configuration and the indication of the new debug configuration are transmitted adjacent to the debug data in the message stream.

An embedded logic analyzer of an integrated circuit includes a comparison block configured to generate a capture data signal and a plurality of comparison enable signals based on an input data signal from one of function blocks included in the integrated circuit such that the comparison enable signals are activated respectively based on different comparison conditions; an operation block configured to perform a logic operation on the comparison enable signals to generate a data enable signal indicating a data capture timing; and packer circuitry configured to generate a packer data signal including capture data and capture time information based on the capture data signal, the data enable signal and a time information signal.

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.

A method for at least one of identifying and compensating for system errors in a measurement system is disclosed, wherein the measurement system comprises a signal generator and a signal analyzer. The method comprises: generating a test signal via the signal generator, the test signal having predetermined properties; forwarding the test signal to a device under test; processing the test signal via the device under test, thereby generating a transmission signal; receiving the transmission signal via the signal analyzer; determining a response function of the device under test based on the test signal and based on the transmission signal; and determining at least one periodic component of the response function. Further, a measurement system as well as a calibration system are disclosed.

A joint test action group transmission system includes a host terminal and a slave terminal. The slave terminal includes a test access port (TAP) circuit, an internal memory, and a memory interface controller. The TAP circuit includes a test data register set. The memory interface controller stores the data received from the TAP circuit to the internal memory. The host terminal transmits a set of download instruction bits to the TAP circuit to have the TAP circuit select the test data register set, and have the TAP circuit enter a data shift status to receive a data package through the test data register set. During the process of receiving the data package, the TAP circuit remains in the data shift status to receive the address and at least one piece of data stored in the data package continuously.

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.

The present disclosure provides a multi-core processor. The multi-core processor comprises a plurality of cores and a debug circuit, the debug circuit comprising debug circuits in the same number as that of the cores, transmission controllers in the same number as that of the cores, and a master control circuit, each of the debug circuits being connected to one core and one transmission controller, respectively, and all transmission controllers being connected to the master control circuit. Each of the debug circuits is configured to generate a debug event signal and respond to the generated debug event signal or received debug event signals generated by other debug circuits. Each of the transmission controllers is configured to respectively control transmission of the debug event signal between the respectively connected debug circuit and the master control circuit. The master control circuit is configured to forward debug event signals among different transmission controllers. The present disclosure can realize rapid configuration and control of debug event signal transmission, and at the same time lower power consumption of a debug circuit.