A memory device with built-in flexible redundancy is provided according to various aspects of the present disclosure. In certain aspects, a memory device includes a first sense amplifier, a second sense amplifier, a first comparator, a second comparator, a reference circuit, and a logic gate. During a redundant read operation, the first sense amplifier, the first comparator, and the reference circuit are used to read one copy of a redundant bit stored in the memory device, and the second sense amplifier, the second comparator, and the reference circuit are used to read another copy of the redundant bit stored in the memory device. The logic gate may then determine a bit value based on the bit values of the read copies of the redundant bit (e.g., determine a bit value of one if the bit value of at least one of the read copies of the redundant bit is one).

Methods, apparatuses and systems related to managing repair assets are described. An apparatus stores a repair segment locator and a repair address for each defect repair. The apparatus may be configured to selectively apply a repair asset to one of multiple sections according to the repair segment locator.

A memory circuit device and a memory test method are disclosed. The memory circuit device includes: a memory cell array, including storage lines and redundant storage lines; and a redundant decoder control circuit, configured to receive an address of a failed storage line from a testing device and activate a corresponding redundant storage line based on the address of the failed storage line, so that the redundant storage line can replace and store data in the failed storage line, wherein the address of the failed storage line is determined while testing operation status of the storage lines in the memory cell array. Embodiments of the present invention can improve repair efficiency of the memory circuit device through activating the associated redundant storage line by the redundant decoder control circuit based on the address of the failed storage line rather than under the control of an external controller.

Apparatuses, systems, and methods for fuse based device identification. A device may include a number of fuses which are used to encode permanent information on the device. The device may receive an identification request, and may generate an identification number based on the states of at least a portion of the fuses. For example, the device may include a hash generator, which may generate the identification number by using the fuse information as a seed for a hash algorithm.

A system includes a processor and a memory set coupled to the processor. The system also includes a repair circuit coupled to the memory set. The repair circuit includes a first repair circuit and a second repair circuit. The repair circuit also includes a test controller configured to select between the first repair circuit and the second repair circuit to perform an in-field self-repair of the memory set.

A device includes serial cyclic redundancy check (CRC) processing circuitry and parallel CRC processing circuitry. The serial CRS processing circuitry, in operation, generates a set of intermediate CRC bits based on a first set of seed bits and input data. The parallel CRC processing circuitry is coupled to the serial CRC processing circuitry, and, in operation, generates, using the set of intermediate CRC bits as a set of parallel seed bits and using null input bits, a set of output CRC bits corresponding to the input data.

A self-repair memory circuit includes a cell array, a controller, a row repair decoder, and a column repair decoder. The cell array includes rows and columns of memory cells. The controller receives an input indicating row repair or column repair, and a repair address shared by the row repair and the column repair of the cell array. The row repair decoder maps the repair address of a defective row to a redundant row of the cell array when the input indicates the row repair. The column repair decoder maps the repair address of a defective column to another column of the cell array when the input indicates the column repair.

A method and an apparatus for determining a repair location for a redundancy circuit, and a method for repairing an integrated circuit are provided. At least one fail bit of a chip to be repaired is determined. At least one initial repair location for the redundancy circuit is initially assigned according to the at least one fail bit. At least one potential fail line is determined according to the at least one initial repair location. At least one predicted repair location is determined according to the at least one potential fail line. Each of the at least one predicted repair location is a location with a higher probability that a new fail bit appears. At least one final repair location for the redundancy circuit is determined according to the at least one fail bit and the at least one predicted repair location.

The present disclosure in the field of memory technology proposes a programmable storage cell, a programmable storage array and a reading and writing method for the programmable storage array. The programmable storage cell includes: a first anti-fuse element connected between a first power terminal and an output terminal, a second anti-fuse element connected between the second power terminal and the output terminal, and a third switch unit connected to the output terminal, a third power terminal and a position signal terminal, where the third switch unit responds to the signal from the position signal terminal so as to connect the third power terminal and the output terminal. The programmable storage cell has a simple structure and a high reading speed.

A memory device including a memory cell array, a redundant fuse circuit and a memory controller is provided. The memory cell array includes multiple regular memory blocks and multiple redundant memory blocks. The redundant fuse circuit includes multiple fuse groups recording multiple repair information. Each repair information is associated with a corresponding one of the redundant memory blocks and includes a repair address, a first enable bit, and a second enable bit. The memory controller includes multiple determining circuits. Each of the multiple determining circuits generates a hit signal according to an operation address, the repair address, the first enable bit, and the second enable bit. When a target memory block is bad, and the determining circuit of the memory controller generates the hit signal, the memory controller disables the redundant memory block that is bad according to the hit signal.