Machine learning models trained using images can be used to generate image overlays by investigating which image areas contribute the most towards model outputs. A common approach used to accomplish this relies on blanking image regions using a sliding window and evaluating the change in model output. Unfortunately,this can be computationally expensive,as it requires numerous model evaluations. This paper shows that a Gaussian process approximation to this blanking approach produces outputs of similar quality,despite requiring significantly fewer model evaluations. This process is illustrated using a user-driven saliency generation problem. Here,pairwise image interest comparisons are used to infer underlying image interest and a Gaussian process model trained to predict the interest value of an image using image features extracted by a convolutional neural network. Interest overlays are generated by evaluating model change at blanking image regions selected using the prediction uncertainty of a Gaussian process regressor.
Reference:
Burke, M.G. 2017. Leveraging Gaussian process approximations for rapid image overlay production. SAWACMMM '17- Proceedings of the ACM Multimedia 2017 Workshop on South African Academic Participation, Mountain View, California, USA, October 23 - 23, 2017
Burke, M. G. (2017). Leveraging Gaussian process approximations for rapid image overlay production. ACM Digital Library. http://hdl.handle.net/10204/9726
Burke, Michael G. "Leveraging Gaussian process approximations for rapid image overlay production." (2017): http://hdl.handle.net/10204/9726
Burke MG, Leveraging Gaussian process approximations for rapid image overlay production; ACM Digital Library; 2017. http://hdl.handle.net/10204/9726 .
Copyright: 2017 The Author. Paper presented at SAWACMMM '17- Proceedings of the ACM Multimedia 2017 Workshop on South African Academic Participation, Mountain View, California, USA, October 23 - 23, 2017
