Abstract: A self-test controller includes a memory configured to store a test patterns, configuration registers, and a memory data component. The test patterns are encoded in the memory using various techniques in order to save storage space. By using the configuration parameters, the memory data component is configured to decode the test patterns and perform multiple built-in self-test on a multitude of test cores. The described techniques allow for built-in self-test to be performed dynamically while utilizing less space in the memory.

Abstract: Disclosed are methods and apparatus for implementing a memory controller, such as a bus integrated memory controller (BIMC) that includes a memory built-in-self-test (MBIST) controller or logic. The MBIST controller is configured for testing at least one memory device, such as stacked low power double data rate (LPDDR) memories in a system on a chip or similar constructions that make external testing of the memory device difficult. The MBIST controller may be implemented within a standard memory controller and includes a memory translation logic configured to translate signals for testing the at least one memory device into signals in a format that is usable by the at least one memory device, where the translation logic serves to effectuate a memory representation.

Abstract: A self-test controller includes a memory configured to store a test patterns, configuration registers, and a memory data component. The test patterns are encoded in the memory using various techniques in order to save storage space. By using the configuration parameters, the memory data component is configured to decode the test patterns and perform multiple built-in self-test on a multitude of test cores. The described techniques allow for built-in self-test to be performed dynamically while utilizing less space in the memory.

Abstract: A method and apparatus for reducing memory built-in self-test (MBIST) area by optimizing the number of interfaces required for testing a given set of memories is provided. The method begins when memories of a same configuration are grouped together. One memory is then selected from each of the groups. MBIST insertion is then performed for a selected group of memories, and the selected group of memories contains memories of different configurations. Control logic is used to select each group of memories separately. The memory group under test may also be selected using programmable user bits. An apparatus is also provided. The apparatus includes: a controller, at least one memory interface in communication with the controller, at least one control logic cloud in communication with the at least one memory interface; and at least one bit bus.

Abstract: A method and apparatus for continuous write and read operations during memory testing. The method comprises: controlling a signal generator; triggering a write address and a data field operation each memory cycle; triggering a write signal to write to a memory each memory clock cycle; and reading a read address and a read data operation to the memory. An additional embodiment provides an apparatus for advanced memory latency testing. The apparatus includes a data generator trigger in communication with a signal generator and an address generator trigger also in communication with the signal generator.

Abstract: Embodiments described herein provide a method and apparatus for multi-level clock gate control for testing electronic devices. The method begins when the number of clock gate controls from root level to the last leaf level are identified and then ranked from the root to last leaf level. A number of test enable commands for testing at least one block of an electronic device are determined. These commands selectively connect and disconnect the test enable commands based on the ranked clock gate levels. The apparatus includes a chain of at least two uncompressed flip-flops with additional flip-flops added to provide multi-level clock gate control during testing. An OR gate in communication with each added flip-flop provides the logic functions to selectively connect and disconnect the test enable command A decompressor and a compressor is in communication with the chain of at flip-flops and the OR gates.

Abstract: A method and apparatus for continuous write and read operations during memory testing. The method comprises: controlling a signal generator; triggering a write address and a data field operation each memory cycle; triggering a write signal to write to a memory each memory clock cycle; and reading a read address and a read data operation to the memory. An additional embodiment provides an apparatus for advanced memory latency testing. The apparatus includes a data generator trigger in communication with a signal generator and an address generator trigger also in communication with the signal generator.

Abstract: Embodiments contained in the disclosure provide a method for memory built-in self-testing (MBIST). The method begins when a testing program is loaded, which may be from an MBIST controller. Once the testing program is loaded MBIST testing begins. During testing, memory failures are determined and written to a failure indicator register. The writing to the failure indicator register occurs in parallel with the ongoing MBIST testing. An apparatus is also provided. The apparatus includes a memory data read/write block, a memory register, a memory addressor, and a memory read/write controller. The apparatus communicates with the memories under test through a memory address and data bus.

Abstract: A method and apparatus for testing an electronic device with multiple cores is provided. The method begins when at least one scan is input for scan configuring. A signal having a predetermined number of bits is then input to a decoder. The decoder then outputs at least one assigned test channel based on the output of the decoder. A test control block then switches at least one selected scan in channel to a test control block. A hard macro scan out of channels is then input to a channel maximization device which allocates or re-allocates the channels for testing. Testing proceeds once the channels are allocated. An apparatus includes a programmable scan configuration block for adjusting the number of scan out channels to maximize testing resources and a predetermined bit register in communication with the programmable scan configuration block.

Abstract: A method and apparatus for testing a device memory. The method begins with a generated data and address width from an automatic testing system. The generated data width and the generated address width is compared with the required data width and address width of a device under test and used to set a user bit. If the generated data width and address width match the required data and address width, the user bit is set to zero. If the generated data width and address width do not match the required data width and address width, the user bit is set to 1. The user bit provides address control and data control during testing. The apparatus includes a wireless test access protocol that is electrically connected to a glue logic module. A wireless test access port is electrically connected to the glue logic module as is the device under test.

Abstract: Embodiments contained in the disclosure provide a method for memory built-in self-testing (MBIST). The method begins when a testing program is loaded, which may be from an MBIST controller. Once the testing program is loaded MBIST testing begins. During testing, memory failures are determined and written to a failure indicator register. The writing to the failure indicator register occurs in parallel with the ongoing MBIST testing. An apparatus is also provided. The apparatus includes a memory data read/write block, a memory register, a memory addressor, and a memory read/write controller. The apparatus communicates with the memories under test through a memory address and data bus.

Abstract: A method and apparatus for reducing memory built-in self-test (MBIST) area by optimizing the number of interfaces required for testing a given set of memories is provided. The method begins when memories of a same configuration are grouped together. One memory is then selected from each of the groups. MBIST insertion is then performed for a selected group of memories, and the selected group of memories contains memories of different configurations. Control logic is used to select each group of memories separately. The memory group under test may also be selected using programmable user bits. An apparatus is also provided. The apparatus includes: a controller, at least one memory interface in communication with the controller, at least one control logic cloud in communication with the at least one memory interface; and at least one bit bus.