Methods, systems, and devices for leakage source detection are described. In some cases, a testing device may scan a first set of access lines of a memory die that have a first length and a second set of access lines of the memory die that have a second length different than the first length. The testing device may determine a first error rate associated with the first set of access lines and a second error rate associated with the second set of access lines. The testing device may categorize a performance of the memory die based on the first and second error rates. In some cases, the testing device may determine a third error rate associated with a type of error based on the first and second error rates and may categorize the performance of the memory die based on the third error rate.

Systems and methods are disclosed for testing a device under test (DUT) by receiving a test pattern for a functional test, wherein the test pattern includes a test vector, an expected test result, and an expected power consumption; instructing the test system to run a repetitive loop using a selected functional test as the stimulus; at selected steps in the functional test, measuring power consumption of the DUT; and validating the DUT based on validating the test vector and the power consumption with one or more expected test result patterns and expected power consumption patterns.

A method for identifying a short circuit at a circuit node may include activating a current source to drive a signal at the circuit node, and sampling a voltage level at the circuit node at a particular time. The method may further include determining that the circuit node is not shorted to another circuit node if the voltage level at the first circuit node exceeds a threshold value; and determining that the first circuit node is shorted to another circuit node if the voltage level at the first circuit node does not exceed the threshold value.

A variety of applications can include devices or methods that provide read processing of data in memory cells of a memory de vice without predetermined read levels for the memory cells identified. A read process is provided to vary a selected access line gate voltage over time, creating a time-variate sequence where memory cell turn-on correlates with programmed threshold voltage. Total string current of data lines of a group of strings of memory cells of the memory device can be monitored during a read operation of selected memory cells of the strings to which a ramp voltage with positive slope is applied to an access line coupled to the selected memory cells. Selected values of the change of the total current with respect to time, from the monitoring of the total current, are determined. Read points to capture data are based on the determined selected values. Additional devices, systems, and methods are discussed.

Memory programming methods and memory systems are described. One example memory programming method includes first applying a first signal to a memory cell to attempt to program the memory cell to a desired state, wherein the first signal corresponds to the desired state, after the first applying, determining that the memory cell failed to place in the desired state, after the determining, second applying a second signal to the memory cell, wherein the second signal corresponds to another state which is different than the desired state, and after the second applying, third applying a third signal to the memory cell to program the memory cell to the desired state, wherein the third signal corresponds to the desired state. Additional method and apparatus are described.

Disclosed herein is a semiconductor device including a non-volatile memory unit. The non-volatile memory unit has a subject current path disposed in a semiconductor integrated circuit and a fuse element inserted in series on the subject current path, and changes output data according to a voltage between both ends of the fuse element when supply of a subject current to the subject current path is intended. A current supply part that switches the subject current between a plurality of stages is disposed in the non-volatile memory unit.

Provided are multi-chip packages. A multi-chip package includes a first memory chip and a second memory chip on a printed circuit board; a memory controller electrically connected to the first memory chip and the second memory chip via a first bonding wire and a second bonding wire; and a strength control module configured to control a drive strength of each of a first output driver of the first memory chip and a second output driver of the second memory chip, wherein the memory controller includes an interface circuit configured to receive each of first test data and second test data from the first output driver and the second output driver in which the drive strength is set by the strength control module, and output detection data for detecting whether the first bonding wire and the bonding wire are short-circuited based on the first and second test data.

To improve a reliability of a semiconductor device, a memory cell array is formed in a product region of an SOI substrate, and a test cell array is formed in a scribe region of the SOI substrate. A plurality of regions is formed in each of the memory cell array and the test cell array. The plurality of regions formed in the test cell array is the same configuration as the plurality of regions formed in the memory cell array. A plurality of plugs is formed in the plurality of regions, respectively. Also, it can determine whether or not a leak path is occurred in the memory cell array, by inspecting whether or not a conduction between the plurality of plugs is confirmed.

A method of improving stability of a memory device having a controller configured to program each of a plurality of non-volatile memory cells within a range of programming states bounded by a minimum program state and a maximum program state. The method includes testing the memory cells to confirm the memory cells are operational, programming each of the memory cells to a mid-program state, and baking the memory device at a high temperature while the memory cells are programmed to the mid-program state. Each memory cell has a first threshold voltage when programmed in the minimum program state, a second threshold voltage when programmed in the maximum program state, and a third threshold voltage when programmed in the mid-program state. The third threshold voltage is substantially at a mid-point between the first and second threshold voltages, and corresponds to a substantially logarithmic mid-point of read currents.

Methods, systems, and devices for leakage source detection are described. In some cases, a testing device may scan a first set of access lines of a memory die that have a first length and a second set of access lines of the memory die that have a second length different than the first length. The testing device may determine a first error rate associated with the first set of access lines and a second error rate associated with the second set of access lines. The testing device may categorize a performance of the memory die based on the first and second error rates. In some cases, the testing device may determine a third error rate associated with a type of error based on the first and second error rates and may categorize the performance of the memory die based on the third error rate.