This is an unprecedented opportunity for an outstanding data science and AI PhD candidate interested in brain data analysis and AI, supervised by Dr Mahsa Salehi at Monash University. The successful candidate will join our world-leading team in Temporal Analytics Lab, a world leading research group uniquely combining research in time series forecasting, classification, segmentation, anomaly detection and learning in the context of non-stationary distributions. The candidate will also be connected to the Faculty of Information Technology. The Temporal Analytics Lab, directed by Dr Mahsa Salehi, is home to a range of innovative tools and projects – including the only current AI-focused Australian Laureate initiative led by world-renowned expert Distinguished Professor Geoff Webb, developing AI systems that can understand a continuously changing world. The Temporal Analytics Lab focuses on understanding patterns, making predictions and detecting unusual behaviour in data over time – driving outcomes such as proactive healthcare, reliable disaster predictions and thriving societies. Emotiv, a global neurotechnology company, will provide $10,000 p.a. stipend top-up and $2,000 p.a. travel support, plus access to $50,000 worth of neurotechnology facilities, computing resources, and AI infrastructure. We invite applications from outstanding PhD candidates with an undergraduate or postgraduate qualification in a computing discipline such as data science, artificial intelligence, machine learning or computer science. which has included training in qualitative research. This project aims to develop a scalable EEG foundation model capable of learning general-purpose representations of brain activity that can support diverse neurotechnology and multimodal AI applications. Specifically, the project objectives are as follows: To develop a general-purpose EEG foundation model that learns unified representations of brain activity from large and diverse EEG datasets with different configurations (e.g., number of channels, sampling frequency and resolution). To leverage large-scale self-supervised learning to train models on unlabeled EEG data, reducing reliance on expensive manual annotations. To improve cross-device and cross-task generalisation, enabling models trained on one dataset or device to adapt to others with minimal retraining. To improve detection and monitoring of medical conditions by leveraging new or existing medical datasets To support multimodal brain–AI applications, exploring how EEG representations can interact with language and visual models for tasks such as EEG-to-text decoding and EEG-guided generative systems. This project is expected to develop a novel EEG foundation model capable of learning unified representations of brain activity from heterogeneous datasets. The research will leverage large-scale EEG recordings collected from multiple devices and experimental paradigms through collaboration with Emotiv, a global neurotechnology company. The resulting model will support applications such as cognitive state estimation, brain–computer interfaces, and mental wellbeing monitoring. The learned representations will also enable integration with language and vision models, supporting emerging capabilities including EEG-to-text decoding and AI-driven neurotechnology applications.
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Job Type
Full-time
Career Level
Entry Level