SoC Test and Verification -> Modular ASICs ease test problems

Since modular arrays don't sacrifice large amounts of silicon to reprogrammable wiring, they provide functional densities between five and 10 times that of FPGAs with the same process technology. In addition, by not adding the delays associated with reprogramming wiring, mod ular arrays exhibit up to two times the performance of FPGAs. To overcome the long and painful process of achieving timing convergence with large FPGAs, modular arrays contain an unusually high percentage of buffers that may be automatically used by proprietary software to enable timing convergence without resorting to iterations of the placement process. Lightspeed provides families of devices that are pin- and RAM-compatible with FPGAs and families that offer densities beyond FPGAs as alternatives to conventional ASICs.

While the performance, capacity and cost advantages of modular arrays relative to FPGAs are certainly attractive, it is the enabling AutoTest technology that separates modular arrays from conventional ASICs and makes test completely transparent to the user; that is, the user never has to think about it.

Most conventional ASIC technologies are tested using a test architecture known as "scan." The layout flow for conventional ASICs starts with the step known as "scan insertion.. The f irst step in inserting structures for scan testing is to replace all flip-flops in the design with scan flops. The most common variety of scan flip-flop contains a multiplexer prior to the D input so that test data can be shifted into the flip-flop during test mode or alternately a normal logic signal can be stored during normal user operation.

To obtain reasonable coverage levels of detectable stuck-at faults, it is typically required that the design be fully synchronous. Hence, we have the first DFT rule. In general, not following DFT rules reduces fault coverage, and as fault coverage is lowered the defect rate for devices is increased. Historically, ASIC suppliers prefer to see fault coverages greater than 90 percent. However, for designs with 1 million gates on 0.25-micron design rules, 90 percent coverage would produce a defect rate of 0.35 percent — unacceptable considering these defects will not be found until devices have been assembled on printed-circuit boards.

Another common DFT ru le requires the modification of logic driving asynchronous sets and resets on flip-flops so that they can be controlled from an external pin during test. The next DFT rule requires that redundant logic not appear in the design. Unfortunately, it is very common in FPGA designs to utilize redundant structures to reduce the loading on high-fanout nets. Experienced ASIC designers are all too familiar with the design flow for conventional ASICs. They know the degree to which DFT rules and test point insertion, as well as scan chain routing and timing, can cause a highly iterative process where the designer must continually get. These iterations characteristically go on for three to six months or more before an acceptable level of test coverage has been achieved with both the user design and the test logic running at speed.

Some companies supplying conventional ASICs are positioning certain product lines as "FPGA conversion solutions," with claims of a simplified and "seamless" design flow. The problem is that these solutions are essentially scan-based conventional ASICs — usually based on embedded array technology — where the supplier is willing to take on more of the burden of the conversion process in order to get the business.

In the end, designs originally created for FPGAs will rarely meet all the DFT rules required to reach acceptable levels of fault coverage when migrated to a conventional ASIC solution. A different approach is required to make ASIC speed, capacity and cost available to FPGA users without requiring modifications to their existing designs.