Testing circuitry and methods are disclosed for use with analog neural memory in deep learning artificial neural networks. The analog neural memory comprises one or more arrays of non-volatile memory cells. The testing circuitry and methods can be utilized during sort tests, qualification tests, and other tests to verify programming operations of one or more cells.

A memory device comprises a memory array; a word line driver circuit including a charge pump circuit configured to generate a program voltage target to be applied to a word line to program a memory cell of the memory array, and a control loop to activate the charge pump circuit using a control signal according to a comparison of a pump circuit output voltage to the program voltage target; a sensor circuit that compares a duty cycle of the control signal to a specified duty cycle after the charge pump circuit output reaches the program voltage target, and provides an indication of current generated by the charge pump circuit according to the duty cycle; and logic circuitry that generates a fault indication when the current generated by the charge pump circuit is greater than a specified threshold current.

A method of testing a non-volatile memory (NVM) array includes heating the NVM array to a target temperature. While the NVM array is heated to the target temperature, a current distribution is obtained by measuring a plurality of currents of a subset of NVM cells of the NVM array, each NVM cell of the NVM array is programmed to one of a logically high state or a logically low state, and first and second pass/fail (P/F) tests on each NVM cell of the NVM array are performed. A bit error rate is calculated based on the current distribution and the first and second P/F tests.

The present disclosure relates to a detector comprising a comparator receiving on a voltage input a voltage value to be detected; a digital to analog converter coupled to a reference voltage potential having an output connected to another input of the comparator; and a Finite State Machine receiving an output of the comparator and producing digital outputs for inputs of a memory controller.

Testing circuitry and methods are disclosed for use with analog neural memory in deep learning artificial neural networks. The analog neural memory comprises one or more arrays of non-volatile memory cells. The testing circuitry and methods can be utilized during sort tests, qualification tests, and other tests to verify programming operations of one or more cells.

An apparatus and method for detecting leakage current in a non-volatile memory array. A reference current is connected to a leakage detection circuit. A reference code is determined for the leakage detection circuit coupled to a switching circuit. The reference code establishes a leakage current threshold. The reference current is disconnected from the leakage detection circuit and the switching circuit. Next, the leakage detection circuit is connected to a set of word lines of a storage block of a non-volatile memory array by way of the switching circuit. A memory current is generated within the set of word lines. A leakage code is determined for the set of word lines representing leakage current from the word lines in response to the memory current. The leakage code is compared with the reference code. If the leakage code exceeds the reference code, the storage block is deemed unusable.

The present invention is directed to a nonvolatile memory device that includes one or more memory sectors and a read circuit for sensing the resistance state of a magnetic memory cell in the memory sectors. The read circuit includes first and second input nodes; a sense amplifier having first and second input terminals; a reference resistor connected to the first input node at one end and the first input terminal at the other end; a multiplexer having a first input, a second input, and an output, with the first input being connected to the second input node and the output being connected to the second input terminal; a first target resistor and an offset resistor connected in series between the second input node and the second input; and first and second current sources connected to the first and second input terminals, respectively.

A current test circuit can include a sampling resister array with a control end connected with a main control component, a first end is connected with a power conversion circuit, and a second end configured to be connected with a component to be tested. The sampling resistor array includes at least two sampling branches, each having an analog switch and a sampling resistor connected serially. In the test, the main control component can generate a control signal according to the operating state of the component and gate at least one sampling branch of the sampling resistor array through the control signal, obtain voltage values at two ends of the sampling resistor array through a voltage test assembly, and determine the current of the component according to the voltage values at two ends of the sampling resistor array and resistance values of the sampling resistor array.

A nonvolatile memory device includes a memory cell array having cell strings that each includes memory cells stacked on a substrate in a direction perpendicular to the substrate. A row decoder is connected with the memory cells through word lines. The row decoder applies a setting voltage to at least one word line of the word lines and floats the at least one word line during a floating time. A page buffer circuit is connected with the cell strings through bit lines. The page buffer senses voltage changes of the bit lines after the at least one word line is floated during the floating time and outputs a page buffer signal as a sensing result. A counter counts a number of off-cells in response to the page buffer signal. A detecting circuit outputs a detection signal associated with a defect cell based on the number of off-cells.

A circuit for testing a memory and a test method thereof are provided. According to the circuit for testing a memory provided by the present disclosure, a switch control circuit is connected between a discharge end and a negative bias signal end of a Sub Wordline Drive (SWD) and configured to input a trigger signal, so that potential of a Word Line (WL) signal end in a to-be-tested circuit meets a preset potential suspension range. Then, it is determined whether there is leakage behavior between the WL signal end and a Bit Line (BL) signal end in the to-be-tested circuit by detecting whether the present level state of a stored signal in the to-be-tested circuit is consistent with an initial level state. The to-be-tested circuit is a corresponding circuit in a single memory.