How to Select Precision Amplifiers for Semiconductor Testers

Introduction

Semiconductor test equipment is an important and ever-evolving industry. As semiconductors and integrated circuits continue to become more advanced and stretch the limits on electronics, test equipment must continue to improve. Texas Instruments offers a wide variety of precision amplifiers that provide the best results for testing integrated circuits.

Voltage forcing, otherwise known as device under test (DUT) or load excitation, is a key subsystem. Forcing certain voltage conditions on the semiconductor device and observing how the semiconductor reacts is important to make sure the device responds correctly. Voltage forcing must be done accurately to provide the best end results. To get accurate results, the current and voltage being applied to the DUT is measured for feedback.

DUT or Load Excitation

When a voltage or signal is applied to a pin of a semiconductor device, the digital signal from the field-programmable gate array (FPGA) controls the digital-to-analog converter (DAC). The DAC output is delivered to the power amplifier, or a gain and power amplifier combination, to be gained. The power amplifier output is then applied to the semiconductor device pins.

Depending on the application of the semiconductor test equipment, a gain stage may be necessary. Using the power amplifier in a high-gain configuration limits bandwidth; therefore, the gain must be split between a gain amplifier and the power amplifier. This split allows for a wider bandwidth while still applying a high gain to the DAC output. Splitting the gain also helps offload some of the required precision. By taking some of the gain off the power amplifier, the offset voltage and noise are not amplified, which allows for better precision.

The power amplifier is the part of the circuit that drives the test voltage. One of the most important specifications of a power amplifier is the power supply range. Depending on the type of tester being designed, different power supply ranges may be required. Automated test equipment (ATE) requires a high supply range to test a broader variety of devices. For example, the OPA462 offers a supply voltage of up to 180 V. Memory test equipment requires a specified range of –10 V to +32 V, which the OPA454 op amp can accommodate with a supply voltage range of ±50 V.

Depending on the process technology, some amplifiers may exhibit long thermal tails where settling time suffers a great deal. This phenomenon is attributed to the offset voltage drift of the amplifier. Selecting a low offset drift amplifier helps reduce the settling time significantly, and is particularly true for JFETs.

Test signals are tightly controlled to provide accurate results; therefore, a low offset drift is required to meet tolerance requirements. In addition, fast settling and high slew rate are needed for quick results because test time has a major impact in device cost. Table 1 shows the OPA454, OPA455, and OPA462 precision specifications, as well as settling time and slew rate.

In addition to wide power supply ranges, precision, and fast settling, other features are necessary to maintain a robust output stage capable of driving a variety of loads. Features such as high output load drives, thermal protection, current limit protection, and an independent output disable can not only protect the circuit from overloads, but interface with low-voltage circuitry without compromising the input signal or power budgets.

Conclusion

Texas Instruments offers a wide variety of precision amplifiers that can be used across multiple platforms for ATE and memory testers. In DUT excitation, precision amplifiers are used to apply the correct voltage and measure the forced voltage for feedback.

Table 1-2 shows a summary of related devices.