Optimizing Dual Feedback Compensation in the OPA593 With a Current Booster for 1μF Capacitive Loads in ATE Applications
Abstract
Since the introduction of the OPA593, the power operational amplifier (PA) has gained traction in the test and measurement sector. Specifically designed for Automated Test Equipment (ATE) applications, the OPA593 can drive output voltages up to 80V and output currents up to ±250mA, all within a compact 4mm × 4mm WSON package. The OPA593 operates across the full industrial temperature range of -40°C to 125°C, providing exceptional DC precision and robust output current limiting features that cater to diverse design requirements in ATE applications.
This application note demonstrates how to compensate for the OPA593 PA and current booster configuration, enabling output driving currents up to ±1A. Additionally, the document explains the implementation of the op amp’s dual feedback compensation techniques when driving capacitive loads of up to 1μF, making sure of adequate phase margin, stabilizing loop gains through AC analysis, and achieving fast step time responses in ATE applications.
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1 Introduction
The OPA593 is a high-voltage, high-output-current power amplifier (PA) that operates on an 85V single supply or a ±42.5V dual-supply configuration, with the capability to source or sink current up to ±250mA. This article focuses on dual-supply rail configurations, favored for their programmable and flexible precision voltage regulator setups commonly used in automated test equipment (ATE) applications. While the OPA593 meets the output voltage requirements for most power voltage regulator applications, OPA593 does not provide sufficient current drive in certain scenarios. In such cases, combining the OPA593 with a current booster topology can enhance the current drive capabilities while maintaining the amplifier’s overall operating voltage range, bandwidth, accuracy, and responsiveness to timing requirements.
In practice, a large capacitive load is often connected to the output of a power amplifier stage. Capacitive loads serve several purposes, including decoupling, filtering high-frequency noise, reducing voltage spikes, stabilizing transient responses, and improving output voltage regulation at the device under test (DUT). However, adding capacitive loads can introduce undesirable phase lag, potentially leading to loop instability in the power amplifier's feedback system.
Driving large capacitive loads presents significant design challenges for engineers, particularly in compensating for stability issues. This application note addresses these challenges when using the OPA593 with a Darlington current booster configuration. The document also explores the trade-offs associated with this technique, especially when driving capacitive loads up to 1µF.
Figure 1-1 and Table 2-2 present the schematic discussed in this application note, which aims to meet (or exceed) the design requirements.
Figure 1-1 The OPA593 With a Current Booster Circuit Drives 1μF Capacitive Load, CL| Design Parameters | Composite Amplifier's Voltage Regulator Specifications |
|---|---|
| Input voltage range | Input swing up to ±5Vdc |
| Output voltage range | Output swing up to ±40Vdc |
| Output current range | OPA593 with current booster, driving up to ±1Adc |
| Output impedance | RL ≥ 40Ω |
| Closed-loop gains | 8V/V |
| Open-loop output impedance | Open loop output impedance, Zo < approximately 1Ω |
| Capacitive load | Low ESR (20mΩ), 1µF ceramic capacitive load and DUT |
| Effective bandwidth | Approximately 50kHz, cutoff frequency at the –3dB point |
| Step time behavior | Output rising/falling edge step-time response <100µs |
| Output voltage accuracy | Approximately 0.05% or better across full scale |