Abstract: The present invention provides various circuits for injecting faults into a larger circuit, sometimes called circuit under test, or CUT. One type of fault injection circuit is a clock controlled fault injection circuit. This type of circuit uses internal scan chains as a way by which a fault injection operation is performed while a system clock is in the off state. Another type of fault injection circuit is a concurrent fault injection circuit. This type of fault injection circuit uses dedicated fault injection scan chains in parallel with or without internal scan chains. Yet another type of fault injection circuit is a hybrid fault injection circuit that uses both clock controlled and concurrent fault injection circuits. Other embodiments are disclosed and still other embodiments would be obvious to those of ordinary skill in the art upon understanding the full scope of the present disclosure.

Abstract: In an embodiment of the invention, variable test clock circuitry is provided within an integrated circuit desired to be tested. The variable test clock frequency implements a test clock control register that receives serial test data from a device tester and is configured to serially pass the received test data to scan test chains within the integrated circuit. The test clock control register stores test clock information. The test clock information is provided to a test clock generator where the test clock generator then produces test clock signals at a predetermined frequency. The test clock signal is then provided as a test clock frequency for the scan test chains within the integrated circuit. Methods are also disclosed for operating the variable test clock frequency.

Abstract: In an embodiment of the invention, variable test clock circuitry is provided within an integrated circuit desired to be tested. The variable test clock frequency implements a test clock control register that receives serial test data from a device tester and is configured to serially pass the received test data to scan test chains within the integrated circuit. The test clock control register stores test clock information. The test clock information is provided to a test clock generator where the test clock generator then produces test clock signals at a predetermined frequency. The test clock signal is then provided as a test clock frequency for the scan test chains within the integrated circuit. Methods are also disclosed for operating the variable test clock frequency.

Abstract: In an embodiment of the invention, variable test clock circuitry is provided within an integrated circuit desired to be tested. The variable test clock frequency implements a test clock control register that receives serial test data from a device tester and is configured to serially pass the received test data to scan test chains within the integrated circuit. The test clock control register stores test clock information. The test clock information is provided to a test clock generator where the test clock generator then produces test clock signals at a predetermined frequency. The test clock signal is then provided as a test clock frequency for the scan test chains within the integrated circuit. Methods are also disclosed for operating the variable test clock frequency.

Abstract: The present invention provides various circuits for injecting faults into a larger circuit, sometimes called circuit under test, or CUT. One type of fault injection circuit is a clock controlled fault injection circuit. This type of circuit uses internal scan chains as a way by which a fault injection operation is performed while a system clock is in the off state. Another type of fault injection circuit is a concurrent fault injection circuit. This type of fault injection circuit uses dedicated fault injection scan chains in parallel with or without internal scan chains. Yet another type of fault injection circuit is a hybrid fault injection circuit that uses both clock controlled and concurrent fault injection circuits. Other embodiments are disclosed and still other embodiments would be obvious to those of ordinary skill in the art upon understanding the full scope of the present disclosure.

Abstract: In an embodiment of the invention, variable test clock circuitry is provided within an integrated circuit desired to be tested. The variable test clock frequency implements a test clock control register that receives serial test data from a device tester and is configured to serially pass the received test data to scan test chains within the integrated circuit. The test clock control register stores test clock information. The test clock information is provided to a test clock generator where the test clock generator then produces test clock signals at a predetermined frequency. The test clock signal is then provided as a test clock frequency for the scan test chains within the integrated circuit. Methods are also disclosed for operating the variable test clock frequency.

Abstract: In an embodiment of the invention, variable test clock circuitry is provided within an integrated circuit desired to be tested. The variable test clock frequency implements a test clock control register that receives serial test data from a device tester and is configured to serially pass the received test data to scan test chains within the integrated circuit. The test clock control register stores test clock information. The test clock information is provided to a test clock generator where the test clock generator then produces test clock signals at a predetermined frequency. The test clock signal is then provided as a test clock frequency for the scan test chains within the integrated circuit. Methods are also disclosed for operating the variable test clock frequency.