Abstract: A method and software apparatus are provided for implementing a dynamically modifiable test flow for integrated circuit devices that adapts to the characteristics of each processed device lot. According to the method of the invention, a modified set of tests sufficient to ensure proper device function for a particular lot is performed, reducing test costs and increasing test capacity. The method and system of the invention periodically samples a predetermined sample number of devices using a full set of tests including a set of skippable tests. Depending upon the performance characteristics of the sample device group on the skippable tests, a number of skippable tests are skipped during a modified test flow. After a next set of devices is tested using the modified test flow, the full set of tests is again performed on another sample group, and the size and makeup of the modified test flow is adjusted according to the new results.

Abstract: A method and system are provided for increasing the accuracy of AC parametric testing. The invention provides a method of precisely estimating signal propagation delay time in an integrated circuit testing apparatus, wherein a plurality of signal propagation delay time measurements are taken and additional delay times are estimated by linearly interpolating the measured delays. A desired test point (desired output voltage at a given time) is established. Using a sample device, a slope is established on a time vs. voltage plot for a line through the desired test point. Where a desired test point falls between strobe times on a tester, linear extrapolation is used to calculate what voltages must be tested for at the two bracketing strobe times in order to guarantee the desired performance at the desired test point. One or more devices are then tested for the calculated voltages at the corresponding bracketing strobe times.

Abstract: A method is provided for scan testing that eliminates the need for balancing internal scan clock delays. According to the method of the invention, multiple scan clocks are provided, each being provided to a different set of flip-flops. The skew between the active edges of the scan clocks is deliberately increased to the point where each set of flip-flops has plenty of time to settle before the next set of flip-flops receives a clock pulse. Because scan testing is typically performed at clock speeds of only about 1 Megahertz, there is time for each of the scan clocks to pulse separately from all the others, without increasing the test time. The increased delay between scan clock pulses eliminates the need for balancing internal delays on the scan clock paths, thereby greatly reducing the number of placement and routing iterations required to achieve a functional design.

Abstract: A multi-state input drive structure is provided to forward externally generated high and low input signals, as well as to receive at least a third, internally generated, comparatively weak signal, preferably an oscillating signal, which triggers a third internally forwarded signal when neither of the high and low input signals is received. The inventive circuit drives three internally forwarded output signals from a single external signal source. Since this circuit may be duplicated for every pin on a device for which two cycle delays do not affect performance, availability of a third input state on N inputs allows 3.sup.N input codes as opposed to 2.sup.N for the conventional "high" and "low" levels normally available.

Abstract: A method is described for testing the programming function of integrated circuit device cells including floating gate elements. To accelerate the testing process, at most two programming pulses are needed, the two pulses being applied with the device at minimum and maximum power supply voltage levels specified for the device. First, the cell state after an initial programming pulse with the device at a minimum power supply voltage level, tested against a minimum reference voltage level, indicates whether the cell is programming properly. If not, testing ceases immediately and the device is rejected after the first pulse. Devices passing the first reading after the first pulse are subjected to a second reading at the target (higher) reference voltage. Devices passing after the second reading are designated as passing and are subjected to the next test in the test flow.

Abstract: In an FPGA having a hierarchical routing structure, additional routing lines are provided which have different destinations for different cells within a block. A pattern is chosen which allows signal lines to turn corners conveniently. In one embodiment having cells arranged into 4.times.4 blocks, cells on the diagonal of a block generate signals which are provided to switches which form one boundary of the block.