Matching Problems to Solutions: An Explainable Way of Solving Machine Learning Problems
This work addresses the problem of making ML accessible to domain experts without deep ML knowledge, though it appears incremental as it builds on existing problem-solving frameworks.
The paper tackles the challenge of helping non-expert domain specialists apply machine learning by developing a workbench that captures ML problem-solving knowledge, focusing on representing domain problems and ML solutions, and using a heuristic matching function to identify appropriate ML algorithms based on requirements and data characteristics.
Domain experts from all fields are called upon, working with data scientists, to explore the use of ML techniques to solve their problems. Starting from a domain problem/question, ML-based problem-solving typically involves three steps: (1) formulating the business problem (problem domain) as a data analysis problem (solution domain), (2) sketching a high-level ML-based solution pattern, given the domain requirements and the properties of the available data, and (3) designing and refining the different components of the solution pattern. There has to be a substantial body of ML problem solving knowledge that ML researchers agree on, and that ML practitioners routinely apply to solve the most common problems. Our work deals with capturing this body of knowledge, and embodying it in a ML problem solving workbench to helps domain specialists who are not ML experts to explore the ML solution space. This paper focuses on: 1) the representation of domain problems, ML problems, and the main ML solution artefacts, and 2) a heuristic matching function that helps identify the ML algorithm family that is most appropriate for the domain problem at hand, given the domain (expert) requirements, and the characteristics of the training data. We review related work and outline our strategy for validating the workbench