A system for outputting test data from cores to one communication interface. The system includes shared memories corresponding to the cores. Each shared memory includes a ring buffer and an array of slots. Each core generates a diagnostic message, and stores the generated diagnostic message in a select memory region of the ring buffer corresponding to a first empty slot of the array of slots. A selected core finds a first diagnostic message among diagnostic messages stored in the shared memories, and outputs the first diagnostic message to a personal computer through the communication interface.

A system for outputting test data from cores to one communication interface. The system includes shared memories corresponding to the cores. Each shared memory includes a ring buffer and an array of slots. Each core generates a diagnostic message, and stores the generated diagnostic message in a select memory region of the ring buffer corresponding to a first empty slot of the array of slots. A selected core finds a first diagnostic message among diagnostic messages stored in the shared memories, and outputs the first diagnostic message to a personal computer through the communication interface.

The disclosure provides a method and apparatus of interleaved on-chip testing. The method merges a test setup for analog components with a test setup for digital components and then interleaves the execution of the digital components with the analog components. This provides concurrency via a unified mode of operation. The apparatus includes a system-on-chip test access port (SoC TAP) in communication with a memory test access port (MTAP). A built-in self-test (BIST) controller communicates with the MTAP, a physical layer, and a memory. A multiplexer is in communication with the memory and a phase locked loop (PLL) through an AND gate.

Runtime memory BIST techniques are described herein. In one example, a system such as an SoC includes logic to schedule runtime testing of the memory that is non-destructive in multiple phases. Running testing of memory in multiple phases includes triggering a memory built-in self-test (BIST) testing of a subset of memory locations in a phase, where the processing logic is to pause access to the memory during the phase. The processing logic can resume access to the memory between testing phases. The next region of the memory can be tested in the phase that follows. This process can continue until the entire memory is tested, without requiring the system to be powered down.

A memory device according to one embodiment includes a memory cell array, bit lines, amplifier units, a controller, and a register. The memory cell array includes a memory cell that stores data nonvolatilely. The bit lines are connected to the memory cell array. The sense amplifier units are connected to the bit lines, respectively. The controller performs a write operation. The register stores status information of the write operation. The memory cell array includes a first storage region specified by a first address. The plurality of sense amplifier modules include a buffer region capable of storing data.

An electronic device may include: a control pulse generation circuit configured to selectively generate one of a first control pulse and a second control pulse on the basis of a reference code during a test period; and a voltage control code generation circuit configured to perform an addition operation or subtraction operation on a logic bit set of a voltage control code to set the voltage level of an operation voltage on the basis of the first and second control pulses.

A memory device to calibrate voltages used to read a group of memory cells. For example, the memory device measures first signal and noise characteristics of a group of memory cells by reading the group of memory cells at first test voltages that are separated from each other by a first voltage interval. An estimate of a read level of the group of memory cells is determined based on the first signal and noise characteristics. The memory device then measures second signal and noise characteristics of the group of memory cells by reading the group of memory cells at second test voltages that are separated from each other by a second voltage interval that is smaller than the first voltage interval. An optimized read voltage for the read level is computed from the second signal and noise characteristics.

A memory device to calibrate voltages used to read a group of memory cells. For example, the memory device measures first signal and noise characteristics of a group of memory cells by reading the group of memory cells at first test voltages that are separated from each other by a first voltage interval. An estimate of a read level of the group of memory cells is determined based on the first signal and noise characteristics. The memory device then measures second signal and noise characteristics of the group of memory cells by reading the group of memory cells at second test voltages that are separated from each other by a second voltage interval that is smaller than the first voltage interval. An optimized read voltage for the read level is computed from the second signal and noise characteristics.

A memory device includes a data storage circuit configured to store, when a write operation is performed, a first internal write data and a second internal write data in a memory cell array which is accessed by an internal address, and output, when a read operation is performed, data stored in a memory cell array which is accessed by the internal address, as internal read data; and a flag generation circuit configured to generate a flag for controlling generation of a data strobe signal, based on the internal read data.

A memory device includes a data storage circuit configured to store, when a write operation is performed, a first internal write data and a second internal write data in a memory cell array which is accessed by an internal address, and output, when a read operation is performed, data stored in a memory cell array which is accessed by the internal address, as internal read data; and a flag generation circuit configured to generate a flag for controlling generation of a data strobe signal, based on the internal read data.