A signal modulation apparatus, a memory storage apparatus, and a signal modulation method are disclosed. The signal modulation apparatus includes an observation circuit, a signal modulation circuit, and a phase control circuit. The signal modulation circuit is configured to generate a second signal according to a first signal and a reference clock signal. A frequency of the first signal is different from a frequency of the second signal. The phase control circuit is configured to obtain an observation information via the observation circuit. The observation information reflects a process variation of at least one electronic component in the signal modulation apparatus. The phase control circuit is further configured to control an offset between the first signal and the reference clock signal according to the observation information.

A memory device, such as an MRAM memory, includes a memory array with a plurality of bit cells. The memory array is configured to store trimming information and store user data. A sense amplifier is configured to read the trimming information from the memory array, and a trimming register is configured to receive the trimming information from the sense amplifier. The sense amplifier is configured to receive the trimming information from the trimming register so as to operate in a trimmed mode for reading the user data from the memory array.

A memory device includes a system block for storing test information and includes a data block including memory cells connected to a plurality of low bank column lines and a plurality of high bank column lines. The memory device also includes a column repair controller configured to detect, based on the test information, a concurrent repair column line in which a low bank column line among the plurality of low bank column lines and a high bank column line the plurality of high bank column lines corresponding to the same column address are concurrent repaired.

A memory device includes a system block for storing test information and includes a data block including memory cells connected to a plurality of low bank column lines and a plurality of high bank column lines. The memory device also includes a column repair controller configured to detect, based on the test information, a concurrent repair column line in which a low bank column line among the plurality of low bank column lines and a high bank column line the plurality of high bank column lines corresponding to the same column address are concurrent repaired.

A system includes a memory device and a processing device coupled to the memory device. The processing device is configured to switch an operating mode of the memory device between a test mode and a non-test mode. The system further includes a test mode access component that is configured to access the memory device while the memory device is in the test mode to perform a test mode operation.

A system includes a memory device and a processing device coupled to the memory device. The processing device is configured to switch an operating mode of the memory device between a test mode and a non-test mode. The system further includes a test mode access component that is configured to access the memory device while the memory device is in the test mode to perform a test mode operation.

The present application relates to a semiconductor memory training method and related devices, belonging to the technical field of semiconductors. The method comprises: obtaining a stored historical training result of a semiconductor memory, the historical training result comprising a historical expected delay value and a historical expected voltage; setting a delay threshold and a current training voltage range, the delay threshold being less than or equal to the historical expected delay value, the current training voltage range comprising the historical expected voltage; obtaining a current minimum delay value for the semiconductor memory under the historical expected voltage; and using the stored historical training result as a current training result of the semiconductor memory, if the current minimum delay value for the semiconductor memory under the historical expected voltage is no less than the delay threshold.

Embodiments combine error correction code (ECC) and transparent memory built-in self-test (TMBIST) for memory fault detection and correction. An ECC encoder receives input data and provides ECC data for data words stored in memory. Input XOR circuits receive the input data and output XOR'ed data as payload data for the data words. Output XOR circuits receive the payload data and output XOR'ed data. An ECC decoder receives the ECC data and the XOR'ed output data and generates error messages. Either test data from a controller running a TMBIST process or application data from a processor executing an application is selected as the input data. Either test address/control signals from the controller or application address/control signals from the processor are selected for memory access. During active operation of the application, memory access is provided to the processor and the controller, and the memory is tested during the active operation.

A semiconductor device includes a memory array arranged in a matrix, a plurality of word lines provided corresponding to memory cell rows, a word driver for driving one of the plurality of word lines, a plurality of row select lines connected to the word driver, and a row decoder for outputting a row select signal to the plurality of row select lines based on input row address information. According to the embodiment, the semiconductor device can detect a failure of the address decoder in a simple method.

A semiconductor device includes a semiconductor die having a peripheral region surrounding, a defect detection circuit in the peripheral region, the defect detection circuit arranged in an open conduction loop, the defect detection circuit comprising a plurality of latch circuits and a plurality of defect detection conduction paths, each defect detection conduction path of the plurality of defect detection conduction paths connecting two adjacent latch circuits of the plurality of latch circuits, and a test control circuitry configured to perform (a) a test write operation by transferring bits of an input data pattern in a forward direction of the open conduction loop to cause the plurality of latch circuits to store the bits of the input data pattern in the plurality of latch circuits, and (b) a test read operation by transferring bits stored in the plurality of latch circuits in a backward direction of the open conduction loop.