An embodiment of a semiconductor apparatus may include technology to convert an analog voltage level of a memory cell of a multi-level memory to a multi-bit digital value, and determine a single-bit value of the memory cell based on the multi-bit digital value. Some embodiments may also include technology to track a temporal history of accesses to the memory cell for a duration in excess of ten seconds, and determine the single-bit value of the memory cell based on the multi-bit digital value and the temporal history. Other embodiments are disclosed and claimed.

An integrated circuit includes a memory core and a built-in self-test (BIST) controller. The memory core has an array of memory cells located at intersections of a plurality of word lines and a plurality of bit line pairs. The BIST controller is coupled to the memory core and has a mission mode and a built-in self-test mode. When in the mission mode, the BIST controller performs read and write accesses using precharge on demand. When in the built-in self-test mode, the BIST controller performs a floating bit line test by draining a voltage on true and complement bit lines of a selected bit line pair and subsequently precharging the true and complement bit lines of the selected bit line pair, before reading or writing data using the true and complement bit lines of the selected bit line pair.

A semiconductor memory device includes memory cells coupled to a word line; and a peripheral circuit configured to read first to kth page data from the memory cells by sequentially applying first to kth test voltages to the word line, where k is a natural number greater than 3, wherein the peripheral circuit is configured to gradually reduce times during which the first to kth test voltages are applied to the word line.

A memory cell readable through a bit line and addressable through a word line can be stressed by applying a stress voltage to the bit line for a stress voltage time, and addressing the memory cell through the word line for an addressing time included within the stress voltage time. The memory cell can be tested by writing a data value into the memory cell, stressing the memory cell, reading the stored value from the memory cell, and determining whether the stored value corresponds to the data value. A testable memory array can include a memory cell addressable through a word line and readable through a bit line, a precharge circuit, a stress circuit, and an array built-in self test (ABIST) circuit. The ABIST circuit can be configured to stress the memory cell by applying a stress signal to the stress circuit.

Memory devices are disclosed. A memory device may include a number of column planes, and at least one circuit. The at least one circuit may be configured to receive test result data for a column address for each column plane of the number of column planes of the memory array. The at least one circuit may also be configured to convert the test result data to a first result responsive to only one bit of a number of bits of the number of column planes failing a test for the column address. Further, the at least one circuit may be configured to convert the test result data to a second result responsive to only one column plane failing the test for the column address and more than one bit of the one column plane being defective. Methods of testing a memory device, and electronic systems are also disclosed.

A defect detecting method for a Word Line (WL) driving circuit includes: m WLs correspondingly connected to m different WL driving circuits are selected from a memory cell array and corresponding WL driving circuit arrays to serve as m WLs to be tested, one of which is set as a first WL and the remaining m-1 ones are set as second WLs; first potential is written into memory cells correspondingly connected to the m WLs to be tested; second potential is written into memory cells correspondingly connected to the first WL; real-time potentials of the memory cells connected to respective second WLs are sequentially read, and when difference value between the real-time potential of one target memory cell and the first potential is greater than first pre-set value, it is determined that the WL driving circuit connected to the second WL corresponding to the target memory cell has a defect.

A Fail Bit (FB) repair method and device can be applied to repairing an FB in a chip. The method includes: a bank to be repaired including multiple target repair banks in a chip to be repaired is determined; first repair processing is performed on a first FB in each target repair bank by using a redundant circuit; a second FB position determination step is executed to determine a bit position of a second FB, and second repair processing is performed on the second FB; unrepaired FBs in each target repair bank is determined, and the second FB position determination step is recursively executed to obtain a test repair position of each unrepaired FB to perform third repair processing on the unrepaired FB according to the test repair position.

A method and device for Fail Bit (FB) repairing. The method includes: a bank to be repaired of a chip to be repaired is determined; first repair processing is performed on first FBs in each target repair bank using a redundant circuit; second FBs are determined, and second repair processing is performed on the second FBs through a state judgment repair operation; for each target repair bank, unrepaired FBs in the target repair bank is determined, and candidate repair combinations and candidate repair costs of the unrepaired FBs are determined using an optimal combined detection manner; and a target repair cost is determined according to the candidate repair costs, and a target repair solution corresponding to the target repair cost is determined to perform repair processing on the unrepaired FBs according to the target repair solution.

Disclosed herein is an apparatus that includes a first semiconductor chip, and a first TSV penetrating the first semiconductor chip. The first semiconductor chip includes a first resistor coupled between a first power supply and a first node, a switch circuit coupled between the first node and the first TSV, a pad electrode operatively coupled to the first node, and a constant current source operatively coupled to either one of the first node and the pad electrode.

A semiconductor system includes: a first semiconductor device suitable for outputting a command; and a second semiconductor device suitable for activating a test enable signal based on the command, generating a counting signal representing a toggling number of a row active signal for an activation period of the test enable signal, increasing and outputting an address when the counting signal reaches a target activation number, and deactivating the test enable signal when the counting signal reaches the target activation number and the address has a maximum value.