A semiconductor system according to an embodiment includes: a semiconductor system including a normal memory cell array and a redundancy memory cell array for repairing a defective cell among memory cells within the normal memory cell array, and configured to output to an external a fail flag generated according to a number of fail bits within read data output from the redundancy memory cell array; and a host configured to store an address corresponding to the read data into a selected register group from among a plurality of register groups, the selected register group being matched to the fail flag.

Memory devices are disclosed. A memory device may include a number of memory banks and a number of latch sets, wherein each latch set is associated with a memory bank. The device may also include a fuse array including a number of fuses. The device may further include circuitry configured to read data from a first set of fuses of the number of fuses and broadcast data from the first set of fuses to a first latch set of the number of latch sets. Further, in response to a repair result associated with the first set of fuses being a first state, the circuitry may be configured to read a second set of fuses and broadcast the second set of fuses to the first latch set. Methods of operating a memory device, and electronic systems are also disclosed.

A memory-testing circuit configured to perform a test of a memory comprising error-correcting code circuitry comprises repair circuitry configured to allocate a spare row or row block in the memory for a defective row or row block in the memory, a defective row or row block being a row or row block in which a memory word has a number of error bits greater than a preset number, wherein the test of the memory comprises: disabling the error-correcting code circuitry, performing a pre-repair operation, the pre-repair operation comprising: determining whether the memory has one or more defective rows or row blocks, and allocating one or more spare rows or row blocks for the one or more defective rows or row blocks if the one or more spare rows or row blocks are available, and performing a post-repair operation on the repaired memory.

A semiconductor device including an SRAM capable of sensing a defective memory cell that does not satisfy desired characteristics is provided. The semiconductor device includes a memory cell, a bit line pair being coupled to the memory cell and having a voltage changed towards a power-supply voltage and a ground voltage in accordance with data of the memory cell in a read mode, and a specifying circuit for specifying a bit line out of the bit line pair. In the semiconductor device, a wiring capacitance is coupled to the bit line specified by the specifying circuit and a voltage of the specified bit line is set to a voltage between a power voltage and a ground voltage in a test mode.

Methods, systems, and devices for modifiable repair solutions for a memory array are described to support storing repair information for a memory array within the memory array itself. A memory device may include the memory array and an on-die microprocessor, where the microprocessor may retrieve the repair information from the memory array and write the repair information to repair circuitry used for identifying defective memory addresses. The microprocessor may support techniques for identifying additional defects and updating the repair information during operation of the memory array. For example, the microprocessor may identify additional defects based on errors associated with one or more memory cells of the memory array or based on testing performed on one or more memory cells of the memory array. In some cases, a host device may identify additional defects and may notify the microprocessor of the additional defects.

Methods, systems, and devices for modifiable repair solutions for a memory array are described to support storing repair information for a memory array within the memory array itself. A memory device may include the memory array and an on-die microprocessor, where the microprocessor may retrieve the repair information from the memory array and write the repair information to repair circuitry used for identifying defective memory addresses. The microprocessor may support techniques for identifying additional defects and updating the repair information during operation of the memory array. For example, the microprocessor may identify additional defects based on errors associated with one or more memory cells of the memory array or based on testing performed on one or more memory cells of the memory array. In some cases, a host device may identify additional defects and may notify the microprocessor of the additional defects.

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.

Methods, systems, and devices for monitoring and adjusting access operations at a memory device are described to support integrating monitors or sensors for detecting memory device health issues, such as those resulting from device access or wear. The monitoring may include traffic monitoring of access operations performed at various components of the memory device, or may include sensors that may measure parameters of components of the memory device to detect wear. The traffic monitoring or the parameters measured by the sensors may be represented by a metric related to access operations for the memory device. The memory device may use the metric (e.g., along with a threshold) to determine whether to adjust a parameter associated with performing access operations received by the memory device, in order to implement a corrective action.

A storage system includes a controller part, a data storage part, and a transfer path of a signal that couples these parts. A driver included in the controller part transmits the signal including write data on the basis of a configured parameter, a receiver included in the data storage part receives the signal, and the write data included in the signal is written into a first storage area. The controller part reads the write data from the first storage area, determines whether or not a bit error exists in the write data, changes the parameter when the bit error exists to repeat similar determination and find an appropriate parameter at which the bit error no longer exists.

A semiconductor apparatus including a semiconductor chip is disclosed. The semiconductor chip includes a modular region and a test circuit. The modular region includes a plurality of modular areas each including a memory cell array with redundant bit lines and a peripheral memory area storing at least redundant addresses. The test circuit retrieves the redundant addresses intrinsic to the semiconductor chip. The distribution of the redundant addresses are randomly formed related to a part or a whole of the modular area of the modular region. The test circuit outputs a random number generated from physical properties intrinsic to the semiconductor chip according to a specification code received from a physical-chip-identification measuring device.