Skip to content

Closing the Sim2Real Gap with NVIDIA Isaac Sim and NVIDIA Isaac Replicator

NVIDIA Isaac Replicator, built on the Omniverse Replicator SDK, can help you develop a cost-effective and reliable workflow to train computer vision models using synthetic data.

Synthetic data is an important tool in training machine learning models for computer vision applications. Researchers from NVIDIA have introduced a structured domain randomization system within Omniverse Replicator that can help you train and refine models using synthetic data.

Omniverse Replicator is an SDK built on the NVIDIA Omniverse platform that enables you to build custom synthetic data generation tools and workflows. The NVIDIA Isaac Sim development team used Omniverse Replicator SDK to build NVIDIA Isaac Replicator, a robotics-specific synthetic data generation toolkit, exposed within the NVIDIA Isaac Sim app.

We explored using synthetic data generated from synthetic environments for a recent project. Trimble plans to deploy Boston Dynamics’ Spot in a variety of indoor settings and construction environments. But Trimble had to develop a cost-effective and reliable workflow to train ML-based perception models so that Spot could autonomously operate in different indoor settings.
By generating data from a synthetic indoor environment using structured domain randomization within NVIDIA Isaac Replicator, you can train an off-the-shelf object detection model to detect doors in the real indoor environment.

Figure 1. A few images from the test set of real 1,000 images

Sim2Real domain gap

Given that synthetic data sets are generated using simulation, it is critical to close the gap between the simulation and the real world. This gap is called the domain gap, which can be divided into two pieces:

  • Appearance gap: The pixel level differences between two images. These differences can be a result of differences in object detail, materials, or in the case of synthetic data, differences in the capabilities of the rendering system used.​
  • Content gap:  Refers to the difference between the domains. This includes factors like the number of objects in the scene, their diversity of type and placement, and similar contextual information. ​

A critical tool for overcoming these domain gaps is domain randomization (DR), which increases the size of the domain generated for a synthetic dataset. DR helps ensure that we include the range that best matches reality, including long-tail anomalies. By generating a wider range of data, we might find that a neural network could learn to better generalize across the full scope of the problem​.

The appearance gap can be further closed with high fidelity 3D assets, and ray tracing or path tracing-based rendering, using physically based materials, such as those defined with the MDL. Validated sensor models and domain randomization of their parameters can also help here.

Creating the synthetic scene

We imported the BIM Model of the indoor scene into NVIDIA Isaac Sim from Trimble SketchUp through the NVIDIA Omniverse SketchUp Connector. However, it looked rough with a significant appearance gap between sim and reality. Video 1 shows Trimble_DR_v1.1.usd.

Video 1. Starting indoor scene after it was imported into NVIDIA Isaac Sim from Trimble SketchUp through SketchUp Omniverse Connector

To close the appearance gap, we used NVIDIA MDL to add some textures and materials to the doors, walls, and ceilings. That made the scene look more realistic.

Video 2. Indoor scene after adding MDL materials

To close the content gap between sim and reality, we added props such as desks, office chairs, computer devices, and cardboard boxes to the scene through Omniverse DeepSearch, an AI-enabled service. Omniverse DeepSearch enables you to use natural language inputs and imagery for searching through the entire catalog of untagged 3D assets, objects, and characters.

These assets are publicly available in NVIDIA Omniverse.

Figure 2. Omniverse DeepSearch makes it easy to tag and search across 3D models

We also added ceiling lights to the scene. To capture the variety in door orientation, a domain randomization (DR) component was added to randomize the rotation of the doors, and Xform was used to simulate door hinges. This enabled the doors to open, close, or stay ajar at different angles. Video 3 shows the resulting scene with all the props.

Video 3. Indoor scene after adding props

Synthetic data generation

At this point, the Iterative process of synthetic data generation (SDG) was started. For the object detection model, we used TAO DetectNet V2 with a ResNet-18 backbone for all the experiments.

We fixed all model hyperparameters constant at their default values, including the batch size, learning rate, and dataset augmentation config parameters. In synthetic data generation, you iteratively tune the dataset generation parameters instead of model hyperparameters.

Figure 3. The iterative process of synthetic data generation where dataset generation parameters are tuned based on feedback from model evaluation

The Trimble v1.3 scene contains 500 ray-traced images and environment props and no DR components except for Door Rotation. The door Texture was held fixed. Training on this scene resulted in 5% AP on the real test set (~1,000 images).

Figure 4. Model’s predictions on real images after being trained on synthetic indoor scene from Video 3

As you can see from the model’s prediction on real images, the model was failing to detect real doors adequately because it overfits to the texture of the simulated door. The model’s poor performance on the synthetic validation dataset with different textured doors confirmed this.

Another observation was that the lighting was held steady and constant in simulation, whereas reality has a variety of lighting conditions.

To prevent overfitting to the texture of the doors, we applied randomization to the door texture, randomizing between 30 different wood-like textures. To vary the lighting, we added DR over the ceiling lights to randomize the movement, intensity, and color of lights. Now that we were randomizing the texture of the door, it was important to give the model some learning signal on what makes a door besides its rectangular shape. We added realistic metallic door handles, kick plates, and door frames to all the doors in the scene. Training on 500 images from this improved scene yielded 57% AP on the real test set.

Video 4. Indoor scene after adding DR components for door rotation, texture, and color and movement of lights

This model was doing better than before, but it was still making false positive predictions on potted plants and QR codes on the walls in test real images. It was also doing poorly on the corridor images where we had multiple doors lined up. It had a lot of false positives in low-temperature lighting conditions (Figure 5).

a) Low temperature light with yellow hue along with QR codes on walls

b) Lots of QR codes on walls all over real images

c) Shiny granite floor with potted plants

d) Corridor with carpet floor and lots of doors
Figure 5. Model’s predictions on real images after being trained on improved synthetic indoor scene from Video 4

To make the model robust to noise like QR codes on walls, we applied DR over the texture of the walls with different textures, including QR codes and other synthetic textures.

We added a few potted plants to the scene. We already had a corridor, so to generate synthetic data from it, two cameras were added along the corridor along with ceiling lights.

We added DR over light temperature, along with intensity, movement, and color, to have the model better generalize in different lighting conditions. We also noticed a variety of floors like shiny granite, carpet, and tiles in real images. To model these, we applied DR to randomize the material of the floor between different kinds of carpet, marble, tiles, and granite materials.

Similarly, we added a DR component to randomize the texture of the ceiling between different colors and different kinds of materials. We also added a DR visibility component to randomly add a few carts in the corridor in simulation, hoping to minimize the model’s false positives over carts in real images.

The synthetic dataset of 4,000 images generated from this scene got around 87% AP on the real test set by training only on synthetic data, achieving decent Sim2Real performance.

Video 5. Final scene with more DR components

Figure 6 shows a few inferences on real images from the final model.

Figure 6. Model’s predictions on real images after being trained on final synthetic indoor scene from Video 5

Synthetic data generation in Omniverse

Using Omniverse connectors, MDL, and easy-to-use tools like DeepSearch, it’s possible for ML engineers and data scientists with no background in 3D design to create synthetic scenes.

NVIDIA Isaac Replicator makes it easy to bridge the Sim2Real gap by generating synthetic data with structured domain randomization. This way, Omniverse makes synthetic data generation accessible for you to bootstrap perception-based ML projects.

The approach presented here should be scalable, and it should be possible to increase the number of objects of interest and easily generate new synthetic data every time you want to detect additional new objects.

For more information, see the following resources:

  • NVIDIA Omniverse
  • Omniverse Replicator for DRIVE Sim and Isaac Sim
  • Isaac Replicator post
  • Omniverse Launcher
  • Omniverse Code app
  • Omniverse Replicator tutorials
  • Synthetic Data Generation using the Omniverse Replicator SDK GTC session

If you have any questions, post them in the Omniverse Synthetic Data, Omniverse Code, or Omniverse Isaac Sim forums.

Source:: NVIDIA