Skip to content

Advancing Spatial-Temporal Rock Fracture Prediction with Virtual Camera-Based Data Augmentation

Notifications You must be signed in to change notification settings

GEO-ATLAS/Rock-Camera

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 

History

1 Commit
 
 
 
 

Repository files navigation

Advancing Spatial-Temporal Rock Fracture Prediction with Virtual Camera-Based Data Augmentation

Abstract

Predicting rock fractures in unexcavated areas is a critical yet challenging aspect of geotechnical projects. This task involves forecasting the fracture mapping sequences for unexcavated rock faces using the sequences from excavated ones, which is well-suited for spatial-temporal deep learning techniques. Fracture mapping sequences for deep learning model training can be achieved based on field photography. However, the main obstacle lies in the insufficient availability of high-quality photos. Existing data augmentation techniques rely on slices taken from Discrete Fracture Network (DFN) models. However, slices differ significantly from actual photos taken from the field. To overcome this limitation, this study introduces a new framework that uses Virtual Camera Technology (VCT) to generate “virtual photos” from DFN models. The external (e.g., camera location, direction) and internal parameters (e.g., focal length, resolution, sensor size) of cameras can be considered in this method. The “virtual photos” generated from the VCT and conventional slicing method have been extensively compared. The framework is designed to adapt to any distribution of field fractures and camera settings, serving as a universal tool for practical applications. The whole framework has been packaged as an open-source tool for rock “photos” generation. An open-source benchmark database has also been established based on this tool. To validate the framework's feasibility, the Predictive Recurrent Neural Network (PredRNN) method is applied to the generated database. A high degree of similarity is observed between the predicted mapping sequences and the ground truth. The model successfully captured the dynamic changes in fracture patterns across different sections, thereby confirming the framework's practical utility.

Data Demo

FixStep Animation

Figure 1: FixStep Mapping with color-image

FixStep Animation 2

Figure 2: FixStep Mapping with binary-image

NRandStep Animation

Figure 3: RandStep Mapping with color-image

NRandStep Animation 2

Figure 4: RandStep Mapping with binary-image

Usage

If you are using a sequence forecasting model like PredRNN for rock fracture mapping prediction, you may need a substantial amount of data. Here, we provide a tool to synthesize all the data you need!

full code and data set

coming soon

About

Advancing Spatial-Temporal Rock Fracture Prediction with Virtual Camera-Based Data Augmentation

Resources

Stars

Watchers

Forks

Releases

No releases published

Packages

No packages published