Abstract: Provided is a test apparatus for testing a device under test, including: a level comparing section that receives a signal under test output from the device under test and outputs a logical value, the logical value indicating a comparison result obtained by comparing a signal level of the signal under test with preset first threshold and second threshold; an acquiring section that acquires the logical value output from the level comparing section, according to a strobe signal supplied thereto; an expected value comparing circuit that determines whether the logical value acquired by the acquiring section corresponds to a preset expected value; and a threshold control section that sets an upper limit and a lower limit of a voltage of the eye mask to the level comparing section as the first threshold and the second threshold, when an eye mask test is performed for determining whether an eye opening of the signal under test is larger than a predefined eye mask.

Abstract: Techniques are provided herein to dynamically disable a hardware component in a processor device. Notifications for single-bit errors detected in a hardware component are received. The hardware component is disabled for a period of time when a number of single-bit errors exceeds a threshold. In addition, techniques are provided to permanently disable one or more hardware components in order to minimize the number of system malfunctions associated with single event upsets (SEUs).

Abstract: An image data test unit includes a data acquisition unit configured to acquire image data having individual frames, an image data temporary storage unit configured to receive the acquired image data from the data acquisition unit to store a certain amount of the image data, and a test calculation unit configured to sequentially receive the image data from the image data temporary storage unit to store a certain amount of the image data, and compare the stored image data with pre-set test elements. In addition, an image apparatus having the image data test unit and a method of testing image data using the image data test unit are also provided.

Abstract: A semiconductor device including an electronic circuit, a memory, and an error detecting module. The electronic circuit is configured to receive an input signal having been generated by a test module, and generate an output signal based on the input signal. The memory is configured to store a predetermined output value that is expected to be output from the electronic circuit based on the electronic receiving the input signal, wherein the predetermined output value is stored in the memory prior to the input signal being generated by the test module. The error detecting module is configured to (i) generate a sample value of the output signal, (ii) compare the sample value of the output signal to the predetermined output value stored in the memory, and (iii) generate a result signal that indicates whether the sample value of the output signal matches the predetermined output value.

Abstract: Methods and apparatuses are disclosed for testing multicore processors. In some embodiments, the tested multicore processor may include at least a first core and a second core, a data input coupled to a first scan chain in the first core and a second scan chain in the second core, and a multiplexer including at least a first input and a second input, the first input coupled with a data output of the first scan chain and the second input coupled with a data output of the second scan chain, the multiplexer further including an output that couples to one or more pins on a package of the processor, the multiplexer further including a select signal that couples to the one or more pins on the package of the processor, and wherein the data input couples to the one or more pins on the package of the processor.

Abstract: A valid-transmission verifying circuit and a semiconductor device including the same are provided. The valid-transmission verifying circuit provides data to an output circuit in correspondence with reference data, the valid-transmission verifying circuit comprising: a data receiving terminal receiving the reference data; a valid-transmission verifier including a reference load unit configured to sample the reference data, the data sampling operation is interrupted in response to a sampling control signal to determine whether the data sampling operation has been performed within a sampling time; and a selection switch providing the reference data to one of the normal output circuit and the valid-transmission verifier in response to a mode selection signal.

Abstract: A semiconductor integrated circuit includes memories, a BIST circuit, and an analyzer. The BIST circuit includes a test controller performing the test and generating a memory selection signal selecting a memory to be tested, an address generator generating write and read addresses, a data generator generating write data and an expected output value, and a control signal generator generating a control signal. The analyzer includes a memory output selector selecting output data, a bit comparator comparing the output data with the expected output value, an error detection unit determining whether there is an error in the memory, a plurality of pass/fail flag registers capable of storing a pass/fail flag, a repair analyzer analyzing a memory error and generating a repair analysis result, a plurality of repair analysis result registers capable of storing the repair analysis result, and an output unit outputting the pass/fail flag and the repair analysis result.

Abstract: Testing system capable of detecting different kinds of memory faults of a memory under I/O compression includes a data pattern selection circuit, writing pattern selection units, reading pattern selection units, and a data comparison circuit. The data pattern selection circuit converts a testing data into different data patterns by the writing pattern selection units and accordingly writes to the corresponding memory data ends in order to allow the corresponding memory cells to store the data with the corresponding data pattern. The data comparison circuit executes reverse-converting through the reading pattern selection units for comparing if the data stored in the memory cells corresponding to each memory data end are matched and accordingly determines if a failure memory cell exists in the memory.

Abstract: A method for comparing data in a computer system having at least two execution units, the comparison of the data taking place in a comparison unit and each execution unit processing input data and generating output data, wherein one execution unit specifies to the comparison unit that the next piece of output data is to be compared to a piece of output data of the at least second execution unit, and thereupon a comparison of the at least two output data takes place.

Abstract: Methods, apparatuses and systems for physical link error data capture and analysis. A receiver is coupled to receive a data stream via a point-to-point serial link. A control circuit is coupled with the receiver to cause the receiver to selectively sample the data stream according to an offset parameter and an interval parameter. Comparison circuitry compares the data stream sample to expected data values to determine a bit error rate.

Abstract: A system and method of utilizing a network to correct flawed media data. The media device includes a processor, a memory, a network adapter, a removable media interface, an error-correction module, and a communication module. The network device enables the media device to connect to the network and server. The removable media interface enables a user to couple a removable medium to the media device. After a user inserts a removable medium into the removable media interface, the processor and error-correction module examines the removable medium for physical errors. If the number of detected errors exceeds a predetermined threshold, the media device, via the network adapter and the communication module, queries a server for correction data. This correction data may be utilized by the media device to enable successful processing of the data stored on the removable medium.

Abstract: Systems and methods of testing integrated circuits are disclosed. The systems include a test module configured to operate between automated testing equipment and an integrated circuit to be tested. The testing interface is configured to test time sensitive parameters of the integrated circuit. The testing interface includes components for generating addresses, commands, and test data to be conveyed to the integrated circuit as well as a clock adjustment component. By adjusting the clock synchronization controlling the test signals to be conveyed to the integrated circuit, set-up time and hold time can be tested. The systems are configured to test set-up time and hold time of individual data channels, for example, an individual address line of the integrated circuit.

Abstract: This invention relates to fault detection in electrical circuits, in particular it relates to fault detection for a plurality of adjacent input circuits. The invention provides a method and apparatus for detecting a control or communication fault on an analogue circuit by simulating said analogue circuit using a simulated circuit comprising digital circuit components; the simulated circuit receiving a control input to provide a first output; and the analogue circuit receiving said control input to provide a second output; and setting an error condition when the first output and the second output differ.

Abstract: A test system includes a computer and an interface device for accessing a scan chain on an application specific integrated circuit (ASIC) under test. The computer includes a memory that contains application software that when executed by the computer quantifies soft errors and soft error rates (SER) in storage elements on the ASIC. The interface device receives commands and data from the computer, translates the commands and data from a first protocol to a second protocol and communicates the commands and data in the second protocol to the ASIC. A method for measuring SER in the ASIC includes baseline, comparison, and latch up accesses of data in a scan chain in the ASIC. Between accesses, the ASIC is exposed to a neutron flux that accelerates the occurrence of soft errors due to ionizing radiation upon the ASIC.

Abstract: A system and method for verifying the receive path of an input/output device such as a network interface circuit. The device's operation with various different input sources (e.g., networks) and output sources (e.g., hosts, host buses) is modeled in a verification layer that employs multiple queues to simulate receipt of packets, calculation of destination addresses and storage of the packet data by the device. Call backs are employed to signal completion of events related to storage of packet data by the device and modeling of data processing within the verification layer. Processing of tokens within the verification layer to mimic the device's processing of corresponding packets is performed according to a dynamic DMA policy modeled on the device's policy. The policy is dynamic and can be updated or replaced during verification without interrupting the verification process.

Abstract: A test apparatus for testing a device under test includes a capture memory that stores thereon an output pattern received from the device under test, a header detecting section that reads the output pattern from the capture memory and detects a portion matching a predetermined header pattern in the output pattern, and a judging section that judges whether the output pattern is acceptable based on a result of comparison between a pattern, in the output pattern, which starts with the portion matching the predetermined header pattern and a corresponding expected value pattern.

Abstract: Methods and apparatus for processing failures during semiconductor device testing are described. Examples of the invention can relate to testing a device under test (DUT). Fail capture logic can be provided, coupled to test probes and memory, to indicate only first failures of failures detected on output pins of the DUT during a test for storage in the memory.

Abstract: A method of functionally verifying a device under test having at least one processor and at least one memory is disclosed. The method includes creating verification data for the device under test using a constrained random verification data creation process executed on the at least one processor. The verification data includes input data and expected output data. The method further includes storing the verification data in the at least one memory. The method further includes processing the input data with the at least one processor to produce actual output data. The method further includes comparing the actual output data to the expected output data. When the actual output data does not equal the expected output data, the method further includes storing at least one inconsistency between the actual output data and the expected output data.

Abstract: A circuit for repairing defective memory of an integrated circuit is disclosed. The circuit includes blocks of memory; and interconnect elements providing data to each of the blocks of memory, where the interconnect elements enable coupling together the signals for programming the blocks of memory. The circuit also includes a directory of locations for defective memory cells of blocks of memory, where the directory of locations is common to the blocks of memory for storing locations of defective memory cells of the blocks of memory. Methods of repairing defective memory of an integrated circuit are also disclosed.

Abstract: The quality of data stored in a memory system is assessed by different methods, and the memory system is operated according to the assessed quality. The data quality can be assessed during read operations. Subsequent use of an Error Correction Code can utilize the quality indications to detect and reconstruct the data with improved effectiveness. Alternatively, a statistics of data quality can be constructed and digital data values can be associated in a modified manner to prevent data corruption. In both cases the corrective actions can be implemented specifically on the poor quality data, according to suitably chosen schedules, and with improved effectiveness because of the knowledge provided by the quality indications. These methods can be especially useful in high-density memory systems constructed of multi-level storage memory cells.

Abstract: A system and method corrects erroneous sections received in a memory by pre-filling at least a portion of memory with a pre-defined value. If a received data packet is valid, the valid received data packet is stored over the pre-defined values in the memory location associated with the valid data packet. Values associated with a data segment and an adjacent data segment in the memory are compared to the pre-defined value. When the values of each data segment match the pre-defined values, then each data segment is an erroneous data segment.

Abstract: In a random error signal generator, an M-sequence generation circuit outputs, in parallel, pieces of bit data stored in each register, a first generation circuit sequentially outputs first reference values C which are changed by a predetermined value in response to clocks, a second generation circuit outputs a second reference value D which is shifted from the first reference value C by a range value E which is determined depending on an error rate p. A comparison and determination unit outputs random error signals to be error bits when a numeric value A of the bit data output exists between the first and second reference values C, D. The random error signal has the error rate p, the number of times of error occurrences follows Poisson distribution, and a distribution of adjacent error occurrence intervals follows a geometric distribution.

Abstract: Method and apparatus for testing semiconductor devices with autonomous expected value generation is described. Examples of the invention can relate to apparatus for interfacing a tester and a semiconductor device under test (DUT). An apparatus can include output processing logic configured to receive test result signals from the DUT responsive to testing by the tester, the output processing logic voting a logic value of a majority of the test result signals as a correct logic value; and memory configured to store indications of whether each of the test result signals has the correct logic value.

Abstract: In one embodiment, a system model models characteristics of a real-world system. The system model includes a plurality of sub-portions that each correspond to a component of the real-world system. A plurality of test vectors are applied to the system model and coverage achieved by the test vectors on the sub-portions of the system model is measured. In response to a failure of the real world system, a suspected failed component of the real-world system is matched to a particular sub-portion of the system model. A test vector to be applied to the real-world system to test the suspected failed component is selected in response to coverage achieved on the particular sub-portion of the system model.

Abstract: A method, apparatus and computer program product are provided for implementing isolation of VLSI AC scan chain defects using structural Array Built In Self Test (ABIST) test patterns. An ABIST test pattern is applied to the device under test and multiple ABIST array algorithms are applied in a passing operating region and each scan chain is unloaded. The ABIST test pattern is applied to the device under test and multiple ABIST array algorithms are applied in a failing operating region for the device under test. Then the unload data from the passing operating region and the failing operating region are compared. The identified latches having different results are identified as potential AC defective latches. The identified potential AC defective latches are sent to a Physical Failure Analysis system.

Abstract: A programmable logic device, in accordance with one embodiment, includes a plurality of configuration memory cells, wherein at least one configuration memory cell is adapted to function as random access memory. Read/write circuitry writes to and reads from a corresponding first port of the configuration memory cells, including reading from the at least one configuration memory cell adapted to function as random access memory. Soft error detection logic checks for an error in data values stored by the plurality of configuration memory cells, including the at least one configuration memory cell adapted to function as random access memory. The soft error detection logic, for example, may thus be tested by changing a data value stored in the at least one configuration memory cell.

Abstract: An evaluation circuit and method for detecting faulty data words in a data stream is disclosed. In one embodiment the evaluation circuit according to the invention includes a first linear automaton circuit and also a second linear automaton circuit connected in parallel, each having a set of states z, which have a common input line for receiving a data stream Tn. The first linear automaton circuit and the second linear automaton circuit are designed such that a first signature and a second signature, respectively, can be calculated. Situated downstream of the two linear automaton circuits are respectively a first logic combination gate and a second logic combination gate, which compare the signature respectively calculated by the linear automaton circuit with a predeterminable good signature and output a comparison value.

Abstract: A multi-strobe circuit that latches a signal to be tested, an evaluation target, at each edge timing of a multi-strobe signal having a plurality of edges. An oscillator oscillates at a predetermined frequency in synchronization with a reference strobe signal. A latch circuit latches the signal to be tested at an edge timing of an output signal of the oscillator. A gate circuit is provided between a clock terminal of the latch circuit and the oscillator, and makes the output signal of the oscillator pass therethrough for a predetermined period. A clock transfer circuit loads the output signal of the latch circuit at an edge timing of the output signal of the oscillator and performs retiming on the output signal of the latch circuit by using a reference clock.

Abstract: A semiconductor device test circuit includes a data producing unit to produce first test data to be fed into a semiconductor device, and expected value data; a first data retaining unit to retain the first test data, and feed the first test data into the semiconductor device; a second data retaining unit to retain the expected value data; a comparison unit to compare output data outputted through the first data retaining unit and the expected value data outputted from the second data retaining unit to supply data indicating comparison result between the output data and the expected value data; and a switching unit to switch the data fed into the second data retaining unit between the expected value data and the output data, wherein the first data retaining unit and the second data retaining unit form parts of a scan chain into which second test data may externally be fed.

Abstract: Mechanisms for controlling an operation of one or more cores on an integrated circuit chip are provided. The mechanisms retrieve, from an on-chip non-volatile memory of the integrated circuit chip, baseline chip characteristics data representing operational characteristics of the one or more cores prior to the integrated circuit chip being operational in the data processing system. Current operational characteristics data of the one or more cores are compared with the baseline chip characteristics data. Deviations of the current operational characteristics data from the baseline chip characteristics data are determined and used to determine modifications to an operation of the one or more cores. Control signals are sent to one or more on-chip management units based on the determined modifications to cause the operation of the one or more cores to be modified.

Abstract: Example embodiments relate to a method and system of testing a memory module having the process of receiving single ended input signals via differential input terminals through which differential pairs of packet signals may be received from a testing equipment, wherein a number of terminals of the testing equipment may be different from a number of terminals of the memory module, and testing memory chips of the memory module based on the single ended input signals.

Abstract: A system for testing electronic circuits is configured to receive a test signal and an ideal response signal and output a test result signal. The system for testing electronic circuits includes a circuit portion to be tested, a comparator and a comparison result recorder. The circuit portion to be tested receives a test signal from a test instrument, and outputs a system response signal. The comparator receives the system response signal from the circuit portion to be tested and receives an ideal response signal from the test instrument. Then, the comparator outputs a comparison result according to the system response signal and the ideal response signal. The comparison result recorder receives and records the comparison result. The comparison result recorder may record comparison results within a period of test time. The test instrument can obtain a record of the comparison results from the comparison result recorder.

Abstract: An image data test unit includes a data acquisition unit configured to acquire image data having individual frames, an image data temporary storage unit configured to receive the acquired image data from the data acquisition unit to store a certain amount of the image data, and a test calculation unit configured to sequentially receive the image data from the image data temporary storage unit to store a certain amount of the image data, and compare the stored image data with pre-set test elements. In addition, an image apparatus having the image data test unit and a method of testing image data using the image data test unit are also provided.

Abstract: One embodiment provides a runtime programmable system which comprises methods and apparatuses for testing a multi-port memory device to detect a multi-port memory fault, in addition to typical single-port memory faults that can be activated when accessing a single port of a memory device. More specifically, the system comprises a number of mechanisms which can be configured to activate and detect any realistic fault which affects the memory device when two simultaneous memory access operations are performed. During operation, the system can receive an instruction sequence, which implements a new test procedure for testing the memory device, while the memory device is being tested. Furthermore, the system can implement a built-in self-test (BIST) solution for testing any multi-port memory device, and can generate tests targeted to a specific memory design based in part on information from the instruction sequence.

Abstract: Disclosed are methods, systems and devices, such as a device including a data location, a quantizing circuit coupled to the data location, and a test module coupled to the quantizing circuit. The quantizing circuit may include an analog-to-digital converter, a switch coupled to the memory element and a feedback signal path coupled to the output of the analog-to-digital converter and to the switch.

Abstract: An I/O compression apparatus, for testing a memory array and/or a logic circuit, is comprised of a selectable compression circuit that outputs compressed test data from the memory array/logic circuit. An I/O scan register is coupled to each I/O pad for converting serial data to parallel and parallel data to serial in response to a test mode select signal, a test data input, and a test clock.

Abstract: An integrated circuit (70) having parallel scan paths (824-842, 924-942) includes a pair or pairs of scan distributor (800,900) and scan collector (844,944) circuits. The scan paths apply stimulus test data to functional circuits (702) on the integrated circuit and receive response test data from the functional circuits. A scan distributor circuit (800) receives serial test data from a peripheral bond pad (802) and distributes it to each parallel scan path. A scan collector circuit (844) collects test data from the parallel scan paths and applies it to a peripheral bond pad (866). This enables more parallel scan paths of shorter length to connect to the functional circuits. The scan distributor and collector circuits can be respectively connected in series to provide parallel connections to more parallel scan paths. Additionally multiplexer circuits (886,890) can selectively connect pairs of scan distributor and collector circuits together.

Abstract: Each of a plurality of nonmatching detection circuits is provided for each bit, compares bit output of memory with an expected value corresponding to the bit output, and outputs a nonmatching detection signal when the bit output does not match the value. A selection circuit selects and outputs the output of one or more nonmatching detection circuits in the plurality of nonmatching detection circuits. When the selection circuit outputs at least one nonmatching detection signal, a nonmatching result holding circuit holds the value of the nonmatching detection signal.

Abstract: Detecting brown-out in a system having a non-volatile memory (NVM) includes loading data in the NVM, wherein a next step in loading is performed on a location in the NVM that is logically sequential to an immediately preceding loading. A pair of adjacent locations include one with possible data and another that is empty. Determining which of the two, if at all, have experienced brownout includes using two different sense references. One has a higher standard for detecting a logic high and the other higher standard for detecting a logic low. Results from using the two different references are compared. If the results are the same for both references, then there is no brownout. If the results are different for either there has been a brownout. The location with the different results is set to an invalid state as the location that has experienced the brownout.

Abstract: A semiconductor integrated circuit includes a clock generator for generating a second clock signal having a frequency that varies over time by using a first clock signal having a fixed frequency, a test circuit for generating a digital signal according to a difference between a first frequency corresponding to the first clock signal and a second frequency corresponding to the second clock signal by a digital logic operation based on the first clock signal and the second clock signal, and a signal path for outputting the digital signal generated by the test circuit.

Abstract: A test pattern generation method for determining if a combinational portion 17 is defective, by applying test patterns to a semiconductor integrated circuit 10 and comparing responses to the test patterns with expected responses, the method including: a first step of generating test patterns having logic bits for detecting defects and unspecified bits; a second step of selecting critical paths 19, 19a, 19b generated by the application of the test patterns; a third step of identifying critical gates on the critical paths 19, 19a, 19b; and a fourth step of determining unspecified bits so that a critical capture transition metric, which indicates the number of the critical gates whose states are changed, is reduced; wherein by reducing the critical capture transition metric, output delays from the critical paths 19, 19a, 19b are prevented, and thereby false testing can be avoided.

Abstract: A memory hub device with test logic is configured to communicate with memory devices via multiple hub device ports, and is also configured to communicate on one or more busses in an upstream and downstream direction. The test logic includes a built-in self test apparatus providing logic to simultaneously and independently test the memory devices interfaced to one or more of the hub device ports using read and write data patterns. The test logic also includes configuration registers to hold fault and diagnostic information, and to initiate one or more tests. The memory hub device can further include command collision detection logic, a trace array, buffer transmit mode logic, trigger logic, clock adjustment logic, transparent mode logic, and a configured command sequencer, as well as additional features.

Abstract: A test circuit of a semiconductor memory device for performing a test in cooperation with a tester having a plurality of input/output pins connected to a plurality of input/output lines. The test circuit may include a first comparing unit adapted to compare, on a bit-by-bit basis, read data that may be read from memory cells corresponding to an address with expected data, and to output the comparison results as first comparison signals, a second comparing unit adapted to perform a logic operation on the first comparison signals and to generate a flag signal when determining a failure of at least one of the memory cells on the basis of the operation result, and a storage unit adapted to store the first comparison signals in response to the flag signal.

Abstract: A mechanism for exploiting the data gathered about a system model during the system design phase to aid the identification of errors subsequently detected in a deployed system based on the system model is disclosed. The present invention utilizes the coverage analysis from the design phase that is originally created to determine whether the system model as designed meets the specified system requirements. Included in the coverage analysis report is the analysis of which sets of test vectors utilized in simulating the system model excited individual components and sections of the system model. The present invention uses the information associated with the test vectors to select appropriate test vectors to use to perform directed testing of the deployed system so as to confirm a suspected fault.

Abstract: A method for detecting microprocessor hardware faults includes sending at least one input signal to a logic block within the microprocessor, collecting an output response to the input signal from the logic block, and determining whether the output response matches an expected output response of the logic block.

Abstract: A method for handling watchdog events of an electronic device includes detecting a watchdog fault in a normal mode, which is a watchdog event in which a watchdog trigger is not correctly serviced; entering from the normal mode into a first escalation level of nx escalation levels upon detection of the watchdog fault, wherein nx is an integer equal to or greater than 1; detecting correct watchdog events, which are watchdog events in which a watchdog trigger is correctly serviced; and concurrently detecting watchdog faults, leaving the first escalation level if a first escalation condition is met, and recovering in a recovering step back from any of the nx escalation levels to a previous level or mode, if a de-escalation condition is met. An electronic device embodiment includes a CPU and program instructions for carrying out the method.

Abstract: A method for handling watchdog events of an electronic device includes detecting a watchdog fault in a normal mode, which is a watchdog event in which a watchdog trigger is not correctly serviced; entering from the normal mode into a first escalation level of nx escalation levels upon detection of the watchdog fault, wherein nx is an integer equal to or greater than 1; detecting correct watchdog events, which are watchdog events in which a watchdog trigger is correctly serviced; and concurrently detecting watchdog faults, leaving the first escalation level if a first escalation condition is met. An electronic device embodiment includes a CPU and program instructions for carrying out the method.

Abstract: A method and apparatus to compact test responses containing unknown values or multiple fault effects in a deterministic test environment. The proposed selective compactor employs a linear compactor with selection circuitry for selectively passing test responses to the compactor. In one embodiment, gating logic is controlled by a control register, a decoder, and flag registers. This circuitry, in conjunction with any conventional parallel test-response compaction scheme, allows control circuitry to selectively enable serial outputs of desired scan chains to be fed into a parallel compactor at a particular clock rate. A first flag register determines whether all, or only some, scan chain outputs are enabled and fed through the compactor. A second flag register determines if the scan chain selected by the selector register is enabled and all other scan chains are disabled, or the selected scan chain is disabled and all other scan chains are enabled.

Abstract: The present invention provides a method and system for improving memory testing efficiency, raising the speed of memory testing, detecting memory failures occurring at the memory operating frequency, and reducing data reported for redundancy repair analysis. The memory testing system includes a first memory tester extracting failed memory location information from the memory at a higher memory operating frequency, an external memory tester receiving failed memory location information at a lower memory tester frequency, and an interface between the first memory tester and the external memory tester. The memory testing method uses data strobes at the memory tester frequency to clock out failed memory location information obtained at the higher memory operating frequency. In addition, the inventive method reports only enough information to the external memory tester for it to determine row, column and single bit failures repairable with the available redundant resources.

Abstract: A system and method for testing a memory array are disclosed which may include establishing a stored data vector, including a plurality of data bits, within at least one circuit; applying one or more logical operations on the stored data vector to generate a succession of original data vectors at the at least one circuit; transmitting the succession of original data vectors through a memory array to provide a succession of exercised data vectors; comparing the succession of exercised data vectors to the succession of respective original data vectors; and determining whether the memory array passes or fails based on the comparing step.