A built-in self test system comprises an integrated circuit device comprising a plurality of functional units coupled to built-in self test circuitry; a low power control unit operable to switch the integrated circuit device into a low power mode and to generate a BIST wake-up signal during or before entering the low power mode; and a built-in self test control unit coupled to the built-in self test circuitry and the low power control unit and arranged to initiate a built-in self test when receiving the BIST wake-up signal.

A system for programming integrated circuit (IC) dies formed on a wafer includes a magnetic field transmitter that outputs a digital test program as a magnetic signal. At least one digital magnetic sensor (e.g., Hall effect sensor) is formed with the IC dies on the wafer. The digital magnetic sensor detects and receives the magnetic signal. A processor formed on the wafer converts the magnetic signal to the digital test program and the digital test program is stored in memory on the wafer in association with one of the IC dies. The magnetic field transmitter does not physically contact the dies, but can flood an entire surface of the wafer with the magnetic signal so that all of the IC dies are concurrently programmed with the digital test program.

A system for programming integrated circuit (IC) dies formed on a wafer includes a magnetic field transmitter that outputs a digital test program as a magnetic signal. At least one digital magnetic sensor (e.g., Hall effect sensor) is formed with the IC dies on the wafer. The digital magnetic sensor detects and receives the magnetic signal. A processor formed on the wafer converts the magnetic signal to the digital test program and the digital test program is stored in memory on the wafer in association with one of the IC dies. The magnetic field transmitter does not physically contact the dies, but can flood an entire surface of the wafer with the magnetic signal so that all of the IC dies are concurrently programmed with the digital test program.

Programmable integrated circuits with specialized processing blocks such as digital signal processing (DSP) blocks are provided. Each DSP block may include embedded built-in self-test circuitry implemented using existing input registers and output registers in the DSP blocks. The input registers may be selectively coupled in a loop to serve as a linear feedback shift register (LFSR). The output registers may be selectively coupled in a chain to serve as a multiple input signature register (MISR).

Configured in this way, the LIFR and the MISR circuits of the DSP blocks are not implemented using soft logic and can therefore easily meet performance criteria.

An integrated circuit (IC) is located on an IC chip and includes an integrated voltage regulator circuit that provides an internal supply voltage to the IC. A test mode signal can be received from an external pin of the IC chip. In response to the test mode signal, the IC can enter a test mode where the internal supply voltage is provided to components of the IC. Also in the test mode, voltage characteristics of the internal supply voltage are measured to produce an analog held value. The measurements occur in an analog domain and over a plurality of sample-and-hold windows. Upon completion of a measurement window, the analog held is converted to a digital value. The digital value is then stored in a memory circuit. The digital value is provided from the memory circuit to a reader device external to the IC.

Functionality for estimating characteristics of an on-chip noise signal can be implemented on a processing module. An on-chip noise signal is determined at an on-chip determination point of a computer chip. The on-chip noise signal is converted to a frequency-varying signal using a voltage-controlled oscillator implemented on the computer chip. The frequency-varying signal is measured at an off-chip measurement point and frequency information is extracted from the frequency-varying signal. The frequency information is converted to a voltage level associated with the on-chip noise signal based on the relationship between an input voltage provided to the voltage-controlled oscillator and an output frequency generated by the voltage-controlled oscillator.

A capacitive sensor and measurement circuitry is described that may be able to reproducibly measure miniscule capacitances and variations thereof. The capacitance may vary depending upon local environmental conditions such as mechanical stress (e.g., warpage or shear stress), mechanical pressure, temperature, and/or humidity. It may be desirable to provide a capacitor integrated into a semiconductor chip that is sufficiently small and sensitive to accurately measure conditions expected to be experienced by a semiconductor chip.

Packaged integrated circuit devices include an oscillator circuit having a resonator (e.g., quartz crystal, MEMs, etc.) associated therewith, which is configured to generate a periodic reference signal. A built-in self-test (BIST) circuit is provided, which is selectively electrically coupled to first and second terminals of the resonator during an operation by the BIST circuit to test at least one performance characteristic of the resonator, such as at least one failure mode. These test operations may occur during a built-in self-test time interval when the oscillator circuit is at least partially disabled. In this manner, built-in self-test circuitry may be utilized to provide an efficient means of testing a resonating element/structure using circuitry that is integrated within an oscillator chip and within a wafer-level chip-scale package (WLCSP) containing the resonator.

A semiconductor device capable of suppressing a sharp change in current consumption and a self-diagnosis control method thereof are provided. According to one embodiment, the semiconductor device 1 includes a logic circuit, which is a circuit to be diagnosed, a self-diagnostic circuit for diagnosing the logic circuit, and a diagnostic control circuit for controlling the diagnosis of the logic circuit by the self-diagnostic circuit, and the diagnostic control circuit includes a diagnostic abort control circuit for gradually stopping the diagnosis of the logic circuit by the self-diagnostic circuit when the semiconductor device receives a stop signal instructing the stop of the diagnosis of the logic circuit by the self-diagnostic circuit.

A semiconductor device capable of suppressing a sharp change in current consumption and a self-diagnosis control method thereof are provided. According to one embodiment, the semiconductor device 1 includes a logic circuit, which is a circuit to be diagnosed, a self-diagnostic circuit for diagnosing the logic circuit, and a diagnostic control circuit for controlling the diagnosis of the logic circuit by the self-diagnostic circuit, and the diagnostic control circuit includes a diagnostic abort control circuit for gradually stopping the diagnosis of the logic circuit by the self-diagnostic circuit when the semiconductor device receives a stop signal instructing the stop of the diagnosis of the logic circuit by the self-diagnostic circuit.