Abstract: Methods and devices for using high-speed serial links for scan testing are disclosed. The methods can work with any scheme of scan data compression or with uncompressed scan testing. The protocol and hardware to support high speed data transfer reside on both the tester and the device under test. Control data may be transferred along with scan data or be partially generated on chip. Clock signals for testing may be generated on chip as well. In various implementations, the SerDes (Serializer/Deserializer) may be shared with other applications. The Aurora Protocol may be used to transport industry standard protocols. To compensate for effects of asynchronous operation of a conventional high-speed serial link, buffers may be used. The high-speed serial interface may use a data conversion block to drive test cores.

Abstract: Techniques are disclosed for reducing the set of initial candidates in signature based diagnosis methodology. These techniques are based on a unique way of making optimum use of information from logic back-cone tracing along with equations that describe the test response compactor.

Abstract: On-chip high speed clock control techniques for testing circuits with multiple clock systems are disclosed. The techniques allow certain (e.g. compatible) high speed clocks to be activated with predefined waveforms during a capture period of a logic test, based on a clock control signal. The clock control signal may be supplied via a JTAG control port or via a scan chain load port. The clock control signal may also be generated by a BIST controller. The techniques may ensure glitch-free transitions from slow speed clocks during a shift period to fast speed clocks during a capture period.

Abstract: Methods and devices for using high-speed serial links for scan testing are disclosed. The methods can work with any scheme of scan data compression or with uncompressed scan testing. The protocol and hardware to support high speed data transfer reside on both the tester and the device under test. Control data may be transferred along with scan data or be partially generated on chip. Clock signals for testing may be generated on chip as well. In various implementations, the SerDes (Serializer/Deserializer) may be shared with other applications. The Aurora Protocol may be used to transport industry standard protocols. To compensate for effects of asynchronous operation of a conventional high-speed serial link, buffers may be used. The high-speed serial interface may use a data conversion block to drive test cores.

Abstract: On-chip high speed clock control techniques for testing circuits with multiple clock systems are disclosed. The techniques allow certain (e.g. compatible) high speed clocks to be activated with predefined waveforms during a capture period of a logic test, based on a clock control signal. The clock control signal may be supplied via a JTAG control port or via a scan chain load port. The clock control signal may also be generated by a BIST controller. The techniques may ensure glitch-free transitions from slow speed clocks during a shift period to fast speed clocks during a capture period.

Abstract: A jitter measurement system measures timing variations or “jitter” in a periodic signal waveform as provided, for example, by a phase-locked loop (PLL). In one implementation, the jitter measurement system includes a period gate generator that generates a gate signal with the instantaneous period of output signal waveform FVCO generated by the PLL. The gate signal includes a leading edge and a trailing edge and is delivered to a pair of triggered oscillators that provide respective oscillator output signals with substantially matched frequencies. The oscillators are triggered at the respective leading and trailing edges of the gate signal. The oscillator output signals are delivered to respective oscillation counters and to a coincidence detector. The oscillation counters count the periods of the respective oscillator output signals from when they are triggered until the coincidence detector detects coincidence between the signals (e.g., coincidence between the trailing edges of the signals).

Abstract: A jitter measurement system measures timing variations or “jitter” in a periodic signal waveform as provided, for example, by a phase-locked loop (PLL). In one implementation, the jitter measurement system includes a period gate generator that generates a gate signal with the instantaneous period of output signal waveform FVCO generated by the PLL. The gate signal includes a leading edge and a trailing edge and is delivered to a pair of triggered oscillators that provide respective oscillator output signals with substantially matched frequencies. The oscillators are triggered at the respective leading and trailing edges of the gate signal. The oscillator output signals are delivered to respective oscillation counters and to a coincidence detector. The oscillation counters count the periods of the respective oscillator output signals from when they are triggered until the coincidence detector detects coincidence between the signals (e.g., coincidence between the trailing edges of the signals).