A system-on-chip includes a first scan register being in a first core and being closest to an input port of the first core; an inverting circuit on a feedback path of the first scan register; a second scan register in the first core; and a logic circuit on a data path between the first scan register and the second scan register. In a test mode for an AT-SPEED test of the logic circuit, the inverting circuit generates test data by inverting scan data that are output from the first scan register, the first scan register stores the test data in response to a first pulse of a clock signal, the logic circuit generates result data based on the test data that are output from the first scan register, and the second scan register stores the result data in response to a second pulse of the clock signal.

An error rate measuring apparatus that inputs a PAM4 signal of a known pattern as a test signal to a device under test W, receives a signal from the device under test W compliant with the input of the test signal, and measures whether or not an FEC operation of the device under test W is possible based on a comparison result of the received signal and the test signal includes an operation unit that sets one Codeword length and one FEC Symbol length of the FEC as a setting parameter to the signal received from the device under test W according to a communication standard of the device under test W, and a display unit that parallel-displays MSB data and LSB data of each piece of symbol string data obtained by receiving and converting the signal from the device under test W on a display screen.

A system and method for performing scan chain testing is disclosed. Scan cells, in the form of scan chains, are inserted into circuit designs for testing those circuit designs. The integrity of the scan chains is checked for defects before testing the circuit under test. In order to do so, various scan chain patterns, including one or both of U-turn and Z-turn patterns, are used in order to generate scan chain test data. The scan chain test data is analyzed in order to identify one or both of a type of defect (e.g., a timing fault, stuck-at fault, etc.) or a location of the defect. Further, the scan chain testing is performed using chain patterns with adaptive length.

A system-on-chip includes a first scan register being in a first core and being closest to an input port of the first core; an inverting circuit on a feedback path of the first scan register; a second scan register in the first core; and a logic circuit on a data path between the first scan register and the second scan register. In a test mode for an AT-SPEED test of the logic circuit, the inverting circuit generates test data by inverting scan data that are output from the first scan register, the first scan register stores the test data in response to a first pulse of a clock signal, the logic circuit generates result data based on the test data that are output from the first scan register, and the second scan register stores the result data in response to a second pulse of the clock signal.

The disclosure provides an online test data record and offline data conversion analysis system and a method thereof. In the present disclosure, the test process information of the production line testing system performed on the circuit board to be tested is generated into online test result data in a database file format, and the offline analysis system receives the online test data from the production line testing system. The offline analysis system reads the corresponding data in the online test result data according to the designated data in the data designated instruction, and generates the offline test result data in the designated file format of the data designated instruction, and the offline analysis system perform the data analysis for the offline test result according to the analysis instruction.

A system and method for performing scan chain testing is disclosed. Scan cells, in the form of scan chains, may be inserted into circuit designs for testing those circuit designs. Because the scan chains themselves may be defective, the integrity of scan chains may be checked first before testing the circuit under test. In order to do so, various scan chain patterns, including one or both of U-turn and Z-turn patterns, may be used in order to generate scan chain test data. The scan chain test data may then be analyzed in order to identify one or both of a type of defect (e.g., a timing fault, stuck-at fault, etc.) or a location of the defect. Further, the scan chain testing may be performed using chain patterns with adaptive length.

Embodiments are directed to a computer implemented method and system for the testing, characterization and diagnostics of integrated circuits. A system might include a device under test, such as an integrated circuit, that includes an adaptive microcontroller. The method includes loading a testing program for execution by the adaptive microcontroller, causing the microcontroller to execute the testing program. Once results from the testing program are received, the testing program can be adaptively modified based on the results. The modified testing program can be run again. The testing program can modify parameters of the integrated circuit that are not externally accessible. Other embodiments are also disclosed.

A system-on-chip includes a first scan register being in a first core and being closest to an input port of the first core; an inverting circuit on a feedback path of the first scan register; a second scan register in the first core; and a logic circuit on a data path between the first scan register and the second scan register. In a test mode for an AT-SPEED test of the logic circuit, the inverting circuit generates test data by inverting scan data that are output from the first scan register, the first scan register stores the test data in response to a first pulse of a clock signal, the logic circuit generates result data based on the test data that are output from the first scan register, and the second scan register stores the result data in response to a second pulse of the clock signal.

A method of detecting faults in a register bank is disclosed. The register bank includes at least one chain of registers. The method comprises sequentially shifting parameters stored in each register of the chain to an output node of the chain and inverting each parameter and feeding each parameter back to an input node of that chain, and sequentially shifting the inverted parameters through the chain until all the non-inverted parameters have been output at the output node. A first checksum of the parameters output at the output node is calculated. The inverted parameters in each register of the chain are sequentially shifted to the output node of the chain. A second checksum of the inverted parameters output at the output node is calculated, and the first and second checksums are compared.

A digital circuit includes a scan chain which loads data into and unloads data from the digital circuit. Checking circuitry is coupled to the scan chain and generates a first digital signature based on data indicative of a pre-testing status of the digital circuit as the data is unloaded from the digital circuit via the scan chain. When testing is completed, the data is restored to the digital circuit via the scan chain. The checking circuitry generates a second digital signature as the data is loaded into the digital circuit. The first digital signature is compared to the second digital signature to verify an integrity of the process. A specific data pattern may be loaded into the scan chain as the data is unloaded. An output of the scan chain may be monitored to detect the pattern and an error signal may be generated based on when the pattern is detected.