OP1400

The OP1400 is a 4-quadrant power amplifier featuring high-speed and low-latency closed loop communications for real-time digital simulation. The power amplifier is designed to be used as a power hardware-in-the-loop (PHIL) testing tool in combination with an OPAL-RT simulator to form a complete PHIL testing solution. Our OP1400 ensures precision and flexibility for demanding 4-quadrant PHIL applications.

Standard configurations *others available upon request

OP1400-10	Amplification units (5 kW)	1
OP1400-10	Available rated power	1 x 5 kW
OP1400-20	Amplification units (5 kW)	2
OP1400-20	Available rated power	2 x 5 kW
OP1400-30	Amplification units (5 kW)	3
OP1400-30	Available rated power	3 x 5 kW
OP1400-60	Amplification units (5 kW)	6
OP1400-60	Available rated power	6 x 5 kW

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Amplification unit electrical specifications

AC Mode rated voltage	3-phase, 120 VL-N (208 VL-L)
DC Mode rated voltage	0 to 400 VDC
Maximum transient current	20 A peak
Sourcing / sinking capability	100% source and sink, no dissipation

PHIL performance

Mode of operation	Voltage and current control
Closed-Loop Bandwidth	DC to 10 kHz (-3dB)
THD	< 0.75%
Time Delay Input to Output	5.5us to 8.3us
High Speed Communication Link	up to 6 Gbps SFP Link, compatible with OPAL-RT simulators

PHIL-ENABLED POWER SYSTEMS TESTING

Flexibility in a constantly changing world

Seamlessly integrate real and simulated components. Emulate grids, distributed energy resources (DERs), converters, and loads with high-fidelity testing for next-gen power systems.

Image illustrates a Power Hardware-in-the-Loop (PHIL) testing architecture. It shows how OPAL-RT’s real-time simulators and power amplifiers emulate various power system components—including the grid, DERs (Distributed Energy Resources), and loads—interfacing with real hardware through bidirectional signal and power exchange.

FEATURES

Optimize your testing and validation

High performance and fidelity

The OP1400 4-quadrant PHIL amplifier is equipped with up to 6 amplification units of 5 kW each, in current and voltage control modes. It offers a closed-loop bandwidth up to 10 kHz with a THD of less than 0.75 %. It has a non-dissipative, 100% power sinking capability.

Modular and integrated

The OP1400 components are rack-mounted, integrating seamlessly with the OPAL-RT simulator through low-power density amplifier units. Fully compatible with our platforms RT-LAB and HYPERSIM, it offers a streamlined solution for real-time simulation.

High-speed communication link

Leverage high-speed, low-latency 6.6 Gbps optical interfaces to seamlessly close the loop between the simulator and amplifier.

RESOURCES

Key considerations for choosing your PHIL amplifier

Power hardware-in-the-loop (PHIL) lets engineers test power equipment—such as converters, generators, and motors—while leveraging high-fidelity simulation. This approach enables flexible, non-destructive testing that isn’t feasible on traditional analog testbeds or real systems. Explore this white paper to understand the essential factors in selecting the right power amplifier for your PHIL testbed.

See white paper

SOFTWARE

Work with our compatible software platforms

Discover powerful solutions for HIL and RCP (rapid control prototyping) testing across power systems, power electronics, aerospace, and automotive sectors. Our software platforms are optimized to work seamlessly with the OP1400 4-quadrant power amplifier, helping you manage complex I/O configurations, communications protocols, and specialized applications—all designed to tackle time-to-market pressures and rising system complexity.

See our simulation systems

EMT Simulation and HIL Testing

HYPERSIM

High-fidelity platform for EMT simulation, SIL and HIL testing, ideal for validating control, protection, grid integration and large-scale stability across all stages of power system development.

Multi-Domain, Simulink®-based HIL

RT-LAB

Fully integrated with MATLAB/Simulink® and best combined with our various toolboxes to bring multi-domain Simscape™ Electrical™ and SimPowerSystems models to real time for fast control development.

FAQ

Find the answers to your questions

What is the OP1400 4-quadrant power amplifier used for?

Our OP1400 4-quadrant power amplifier is designed for real-time digital simulation environments, providing high-speed and low-latency closed-loop communications. We use it primarily as part of a Power Hardware-in-the-Loop (PHIL) testing setup, enabling engineers to seamlessly integrate real and simulated components like grids, DERs, converters, and loads.

What makes the 4-quadrant power amplifier ideal for PHIL testing?

We engineered the OP1400 4-quadrant power amplifier with full sourcing and sinking capabilities, rapid time delays of just 5.5 to 8.3 microseconds, and a closed-loop bandwidth up to 10 kHz. These features ensure high-fidelity emulation, minimal distortion (<0.75% THD), and robust communication links (up to 6 Gbps) with our OPAL-RT simulators, making it an ideal solution for flexible, non-destructive PHIL testing.

What configurations are available for the OP1400 4-quadrant power amplifier?

We offer standard OP1400 configurations based on amplification units of 5 kW each. Depending on your needs, you can choose from models delivering 5 kW, 10 kW, 15 kW, or 30 kW rated power. If required, we can provide custom configurations beyond these options to meet your specific testing requirements.

How does OPAL-RT’s OP1400 4-quadrant power amplifier enhance real-time simulation performance?

Our OP1400 4-quadrant power amplifier ensures that real components behave accurately within a simulated environment, thanks to its voltage and current control modes, high-speed SFP communication links, and precise transient handling (20 A peak). This real-time performance is critical for next-generation power systems development across industries like energy, automotive, and aerospace.

What should engineers consider when selecting a 4-quadrant power amplifier for PHIL applications?

When choosing a 4-quadrant power amplifier like the OP1400, engineers should consider factors such as closed-loop bandwidth, time delay, sourcing/sinking capabilities, transient response, and software compatibility. We offer a detailed white paper to guide you through these essential considerations, helping ensure you select the right amplifier to meet your PHIL testing goals.

Resources

Want to learn more?

PHIL simulation

Explore how power hardware-in-the-loop simulation is revolutionizing the HIL industry. Access presentations, webinars, success stories, and more.

Microgrid applications

Microgrids present unique challenges compared to traditional power grids. Discover our advanced testing solutions through brochures, webinars, demos, and success stories.

Support center

Get the help you need, all in one place. Whether it’s technical support, software downloads, or access to key resources, our support center is here to assist you quickly and efficiently.