Monocular Depth Estimation using Synthetic Data for an Augmented Reality Training System in Laparoscopic Surgery
André Schreiber, Minsik Hong, Jerzy W. Rozenblit
Abstract
Depth estimation is an important challenge in the field of augmented reality. Supervised deep learning methods of depth estimation can be difficult to use in novel settings due to the need for labeled training data. The work presented in this paper overcomes the challenge in a laparoscopic surgical simulation environment by using synthetic data generation for RGB-D training data. We also provide a neural network architecture that can generate real-time 448x448 depth map outputs suitable for use in AR applications. Our approach shows satisfactory performance when tested on a non-synthetic test dataset with an RMSE of 2.50 cm, MAE of 1.04 cm, and δ < 1.25 of 0.987.
Topics & Concepts
Augmented realityComputer scienceArtificial intelligenceMonocularRGB color modelDeep learningArtificial neural networkSynthetic dataEstimationField (mathematics)Mean squared errorTraining (meteorology)Computer visionMachine learningMathematicsEngineeringStatisticsMeteorologyPure mathematicsPhysicsSystems engineeringRobotics and Sensor-Based LocalizationAdvanced Vision and ImagingAugmented Reality Applications