CAFS: Cost-Aware Features Selection Method for Multimodal Stress Monitoring on Wearable Devices

Adriana Arza Valdes, David Atienza Alonso, João Pedro de Matos Rodrigues, Niloofar Momeni, Maria del Carmen Sandi Perez
2021
Article

Résumé

Objective: Today, stress monitoring on wearable devices is challenged by the tension between high-detection accuracy and battery lifetime driven by multimodal data acquisition and processing. Limited research has addressed the classification cost on multimodal wearable sensors, particularly when the features are cost-dependent. Thus, we design a Cost-Aware Feature Selection (CAFS) methodology that trades-off between prediction-power and energy-cost for multimodal stress monitoring. Methods: CAFS selects the most important features under different energy-constraints, which allows us to obtain energy-scalable stress monitoring models. We further propose a self-aware stress monitoring method that intelligently switches among the energy-scalable models, reducing energy consumption. Results: Using CAFS methodology on experimental data and simulation, we reduce the energy-cost of the stress model designed without energy constraints up to 94.37%. We obtain 90.98% and 95.74% as the best accuracy and confidence values, respectively , on unseen data, outperforming state-of-the-art studies. Analyzing our interpretable and energy-scalable models, we showed that simple models using only heart rate (HR) or skin conductance level (SCL), confidently predict acute stress for HR > 93.30BP M and non-stress for SCL < 6.42µS, but, outside these values, a multimodal model using respiration and pulse wave's features is needed for confident classification. Our self-aware acute stress monitoring proposal saves 10x energy and provides 88.72% of accuracy on unseen data. Conclusion: We propose a comprehensive solution for the cost-aware acute stress monitoring design addressing the problem of selecting an optimized feature subset considering their cost-dependency and cost-constraints. Significant: Our design framework enables long-term and confident acute stress monitoring on wearable devices.

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https://infoscience.epfl.ch/record/288642?ln=fr

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Adriana Arza Valdes, David Atienza Alonso, João Pedro de Matos Rodrigues, Niloofar Momeni, Maria del Carmen Sandi Perez
2021
Article

Résumé

Official source

https://infoscience.epfl.ch/record/288642?ln=fr

À propos de ce résultat

Concepts associés (19)

Concepts associés

Chargement

Publications associées (6)

Publications associées

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Design of multimodal dialogue-based systems

Miroslav Melichar

Multimodal dialogue systems integrate advanced (often spoken) language technologies within human-computer interaction methods. Such complex systems cannot be designed without extensive human expertise and systematic design guidelines taking into account the limitations of the underlying technologies. Therefore, this thesis aims at reducing the time and effort needed to build such systems by creating application-independent techniques, tools and algorithms that automate the design process and make it accessible for non-expert application developers. The thesis proposes an interactive system prototyping methodology, which (together with its software implementation) allows for rapid building of multimodal dialogue-based information seeking systems. When designed with our methodology, even partially implemented system prototypes can immediately be tested with users through Wizard of Oz simulations (which are integrated into the methodology) that reveal user behavior and modality use models. Involving users in early development phases increases the chances for the targeted system to be well accepted by end-users. With respect to dialogue system design, we propose a two-layered dialogue model as a variant of the standard frame-based approach. The two layers of the proposed dialogue model correspond to local and global dialogue strategies. One of the important findings of our research is that the two-layered dialogue model is easily extendable to multimodal systems. The methodology is illustrated in full detail through the design and implementation of the Archivus system – a multimodal (mouse, pen, touchscreen, keyboard and voice) interface that allows users to access and search a database of recorded and annotated meetings (the Smart Meeting Room application). The final part of the thesis is dedicated to an overall qualitative evaluation of the Archivus system (user's performance, satisfaction, analysis of encountered problems) and to a quantitative evaluation of all the implemented dialogue strategies. Our methodology is intended (1) for designers of multimodal systems who want to quickly develop a multimodal system in their application domain, (2) for researchers who want to better understand human-machine multimodal interaction through experimenting with working prototypes, (3) for researchers who want to test new modalities within the context of a complete application, and (4) for researchers interested in new approaches to specific issues related to multimodal systems (e.g. the multimodal fusion problem).

EPFL2008

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Thanks to recent improvements in electronics, conductive materials and energy storage capabilities, we are now able to embed small circuits but also ultra-mobile PCs (UMPC) into clothes. These devices are able to sense, process and communicate information between the user and his/her context. During the first research phase, we have developed a set of wearable applications that aimed at assisting the user in various situations such as the teleoperation of a blimp, or the pedestrian navigation in an unknown indoor environment. Research on both of these experiments can be classified in three categories: First the multimodal interaction between the users, his/her wearable interface, and the environment. Second, the context sensing such as the location of the user. Third, the wireless communication between the embedded system and the surrounding or remote devices. Although the resulting functionalities were satisfying as expected, both systems implied the use of cumbersome equipment such as a Head-Mounted Display (HMD), or a UMPC, and thus were too restrictive. With the experience gained from these experiments, we have decided to pursue a different approach. Indeed, in order to develop a truly wearable system, we have focused our research on the design and development of wearable modules based on small 8-bit microcontrollers. In our vision, one module equals one functionality. The advantages are threefold: First, the applications are virtually unlimited as the wearable modules can be attached or removed on the fly. Second, the user only wears what is needed, thus eliminating the superfluous hardware. Third, compared to commercial wearable products, the user can change the garment without changing the functionalities, or on the opposite, s/he can change the functionalities without changing the garment. A special attention has been put in the design of magnetic connectors in order to facilitate the placement of the modules on the garment. Compared to alternative approaches such as the lilypad from Leah Buechley, our modules do not need to be sewn to the garment and thus can very easily be relocated or removed when washing the garment for example. The decision to opt for a wired bus has been motivated by several factors. Indeed, not only the modules consume less power, but also they are smaller and lighter as they don't need wireless functionalities, nor individual batteries. We have developed specific applications in order to demonstrate and evaluate our modular approach. The feedback collected from test users and the results of various evaluation techniques showed us that our system is comfortable, attractive and perceived as flexible and creative. We believe that this kind of approach may not only foster the involvement of the user in wearable computing applications, but it can also be seen as a rapid prototyping platform consisting of a set of tools that facilitate the development of wearable applications.

EPFL2010

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Energy-Aware Embedded Classifier Design for Real-Time Emotion Analysis

David Atienza Alonso, Srinivasan Murali, Manoj Padmanabhan, Francisco Javier Rincon Vallejos

Detection and classification of human emotions from multiple bio-signals has a wide variety of applications. Though electronic devices are available in the market today that acquire multiple body signals, the classification of human emotions in real-time, adapted to the tight energy budgets of wearable embedded systems is a big challenge. In this paper we present an embedded classifier for real-time emotion classification. We propose a system that operates at different energy budgeted modes, depending on the available energy, where each mode is constrained by an operating energy bound. The classifier has an offline training phase where feature selection is performed for each operating mode, with an energy-budget aware algorithm that we propose. Across the different operating modes, the classification accuracy ranges from 95% - 75% and 89% - 70% for arousal and valence respectively. The accuracy is traded off for less power consumption, which results in an increased battery life of up to 7.7 times (from 146.1 to 1126.9 hours).

IEEE Press2015

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Design of multimodal dialogue-based systems

Miroslav Melichar

EPFL2008

EPFL2010