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Root-cause analysis can be achieved by automatically correlating the failed bin results from the packaged parts during FT against all available manufacturing test data prior to this FT stage. The goal is to look for a parameter upstream that can predict this downstream issue seen during FT and correct the problem there.

• Real-time, automated production control through the use of preconfigured libraries of recipes, algorithms, and scripting support facilitates test quality controls.

For example, a device under test (DUT) stuck in a socket can cause the untested chip to ship as a good unit. In a normal run, parametric data should be different for each tested part. Through observations of data reported in real time, a technician can be flagged when the data does not change, indicating that there is a problem, and then abort the test and remove the stuck part.

Another example pertains to bad chip trimming. This is the case where misaligned test equipment requiring recalibration can manifest in a parametric shift of results during chip testing. If not corrected in a timely manner, this situation may lead to good parts failing and potentially being discarded (in other words, unnecessary yield loss). At a minimum, you will be required to retest many parts, potentially upwards of a full lot.

Here is an example of one of the sites on a tester load board that is testing differently from the other test sites. With analytics, you can check for parametric shifts between sites and when the difference is greater than a certain percentage, you can notify the test engineer or operator or, if granted permission, can halt the equipment until this issue gets resolved. Note that you do not have to wait for the difference in parametric results between sites to be great enough that the parts fail. The goal is to catch this type of issue before the parts fail, running the risk of losing significant yield.

Using edge computing technology, however, you can detect gaps between sites immediately as they occur, which will prevent loss of potential good chips and limit any unnecessary retest.

• Enhanced WS efficiencies. WS is a time-consuming, expensive step in the production process, commonly requiring several hours to test just one wafer in a lot. A bad probe site as noted in the previous use case, whether from corrosion, dirt, or a calibration issue, can cause dies tested on these faulty sites to fail one or more tests. Dies on the wafer that failed a test will get retested. Some may pass. But others, if retested by the same faulty sites, will end up failing again. Eventually, these failed dies will be binned out and discarded¡ªpotentially resulting in the loss of good parts. Data analytics can help to quickly identify these test equipment-related issues by observing consecutive fails on a particular probe site. However, the benefit of real-time analysis is that this issue can be resolved as it occurs within the testing of the same wafer before testing is completed. Otherwise, you¡¯d have to wait for an STDF file to be created once the wafer has been fully tested to find you have this issue, forcing you to effectively retest the entire wafer again and endure additional test costs.

• Screening for outliers. In dynamic part average testing (DPAT), some parameters don¡¯t have appropriate limits, while others have no limits at all, allowing ¡°all¡± parts to pass and continue through manufacturing, including potential bad parts. Bad parts that go through production are considered quality escapes, which ultimately end up failing in your customer¡¯s end product while in use. A good analytics tool would be able to inform you that your parametric tests do not have any limits and if you request a solution from the tool, it can automatically apply test limits based on the parametric distribution of results after a statistically significant number of units have been tested and results gathered.One common approach is to wait for 100 packaged dies during FT to be tested for a sufficient data sample size and then apply a  distribution on the data to create the new test limits. If part identification is available (e.g. ECID), then you know which of these parts would fail if the new test limits were applied. In this case, you can reload those parts that were not tested with the new test limits again on the tester to uncover their identity. If they are the ones that would have failed with the new limits, you can simply bin them out and remove them as failed parts without having to actually perform any retest. However, if there is no part identification, then you will need to rerun all previously tested parts that passed on the tester before the new test limits were applied, since you have no way to identify which of these previously passed parts would actually fail under the new limits. Thus, you have to rerun each of the previously passed parts again on the tester for that given parametric test. The question becomes, how fast can I find this issue of having no test limit so I can not only prevent quality escapes but also limit how much retesting has to be done?The biggest benefit of real-time edge analytics is realized when there is no part identification and your parts are now packaged and going through FT. The traditional method of creating and analyzing an STDF file happens only when testing of one lot or sub-lot has been completed. With no part identification and finding out you have no limits on a parametric test, you will have to retest that entire lot or sub-lot once you have applied limits. Any part that fails the new limit will be screened at that point.Real-time analytics enables you to find this issue as it occurs at the beginning of testing one lot or sub-lot. This saves a tremendous amount of tester time by a factor of how many packaged parts there are in one lot or sub-lot. For example, the analytics tool will tell you immediately that you have a test without any limits, allowing you to continue to test your desired ¡°sample¡± amount of parts before establishing your test limits, which would only limit you from having to retest that small sample amount. Optionally, you can have the test stop immediately and have the test engineer look to correct the test program by adding the intended spec limits.Advantest  provides a high-performance, highly secure edge compute and analytics solution delivering fast algorithmic AI decision-making with millisecond latencies during test execution. ACS Edge can be used in outlier screening and for DPAT, for which real-time, in-situ decision-making during the packaged unit testing process has proven beneficial. For example, ACE Edge provides real-time analysis with minimal test time overhead while also not having to re-socket devices for retest even if there is no chip ID within the device.

Summary

Applications such as AI, high-performance computing, and 5G are leading to more complex IC designs and packaging, making it more challenging to achieve high yield and quality while keeping test costs under control. Extending the advantages of silicon lifecycle management analytics in the silicon manufacturing supply chain, Advantest and ÁùºÏ²ÊÖ±²¥¿ª½± are providing chip manufacturers with real-time access to insights that can help them improve product yield, quality, and costs, ultimately delivering on enhanced engineering productivity and time-to-market for your products.