Recognition of Nutrition Intake Using Time-Frequency Decomposition in a Wearable Necklace Using a Piezoelectric Sensor

Alshurafa, Nabil; Kalantarian, Haik; Pourhomayoun, Mohammad; Liu, Jason J.; Sarin, Shruti; Shahbazi, Behnam; Sarrafzadeh, Majid

doi:10.1109/jsen.2015.2402652

Cited by 82 publications

(91 citation statements)

References 31 publications

(30 reference statements)

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“…Second, we have achieved a classification accuracy of 80.3% in real-life settings over 17 food categories. Our system outperforms the state-of-the-art piezoelectric sensor based method [13]. Third, we have developed a smartphone application that sends real-time feedback to the user about the number of swallows detected by the necklace for each food category, and suggests time for the next meal and exercise.…”

Section: Introductionmentioning

confidence: 99%

Food Intake Detection and Classification Using a Necklace-Type Piezoelectric Wearable Sensor System

Hussain

Javed

Cho

et al. 2018

IEICE Trans. Inf. & Syst.

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Automatic monitoring of food intake in free living conditions is still an open problem to solve. This paper presents a novel necklacetype wearable system embedded with a piezoelectric sensor to monitor ingestive behavior by detecting skin motion from the lower trachea. Detected events are incorporated for food classification. Unlike the previous stateof-the-art piezoelectric sensor based system that employs spectrogram features, we have tried to fully exploit time-domain based signals for optimal features. Through numerous evaluations on the length of a frame, we have found the best performance with a frame length of 70 samples (3.5 seconds). This demonstrates that the chewing sequence carries important information for food classification. Experimental results show the validity of the proposed algorithm for food intake detection and food classification in real-life scenarios. Our system yields an accuracy of 89.2% for food intake detection and 80.3% for food classification over 17 food categories. Additionally, our system is based on a smartphone app, which helps users live healthy by providing them with real-time feedback about their ingested food episodes and types.

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Section: Introductionmentioning

confidence: 99%

Food Intake Detection and Classification Using a Necklace-Type Piezoelectric Wearable Sensor System

Hussain

Javed

Cho

et al. 2018

IEICE Trans. Inf. & Syst.

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show abstract

“…The classifier achieved an average F-score of 96.28% for leave-one-out cross-validation (participant level). Several sensor systems have been presented where the accuracy of food intake detection varies from 80% to 96% [18], [19], [24], [25], [34]. For most of these sensor systems, their ability to detect food intake was tested when the participants were sedentary.…”

Section: Discussionmentioning

confidence: 99%

“…Another common limitation of the current techniques for food intake monitoring is the use of the epoch-based classification to detect chewing ([16], [18], [19], [23]–[25]) and to compute the number of chews. With this approach, the sensor signal is split into short segments (epochs) which then are classified either as chewing or no chewing.…”

Section: Introductionmentioning

confidence: 99%

Segmentation and Characterization of Chewing Bouts by Monitoring Temporalis Muscle Using Smart Glasses With Piezoelectric Sensor

Farooq

Sazonov

2017

IEEE J. Biomed. Health Inform.

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Several methods have been proposed for automatic and objective monitoring of food intake, but their performance suffers in the presence of speech and motion artifacts. This work presents a novel sensor system and algorithms for detection and characterization of chewing bouts from a piezoelectric strain sensor placed on the temporalis muscle. The proposed data acquisition device was incorporated into the temple of eyeglasses. The system was tested by ten participants in two part experiments, one under controlled laboratory conditions and the other in unrestricted free-living. The proposed food intake recognition method first performed an energy-based segmentation to isolate candidate chewing segments (instead of using epochs of fixed duration commonly reported in research literature), with the subsequent classification of the segments by linear Support Vector Machine models. On participant level (combining data from both laboratory and free-living experiments), with 10-fold leave-one-out cross-validation, chewing were recognized with average F-score of 96.28% and the resultant area under the curve was 0.97, which are higher than any of the previously reported results. A multivariate regression model was used to estimate chew counts from segments classified as chewing with an average mean absolute error of 3.83% on participant level. These results suggest that the proposed system is able to identify chewing segments in the presence of speech and motion artifacts, as well as automatically and accurately quantify chewing behavior, both under controlled laboratory conditions and unrestricted free-living.

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“…Use of such technology is beneficial for supporting healthy behavior and may have long‐term health benefits (for a review, please see Fritz, Huang, Murphy, and Zimmerman []). In addition to measuring physical activity, wearable sensors (e.g., wrist or necklace sensor) and nonwearable sensors (e.g., fork and tray) have been designed to accurately and objectively measure quantity and rate of food intake in an everyday environment (e.g., Alshurafa et al, ; Dong, Scisco, Wilson, Muth, & Hoover, ). However, these devices have not yet been tested with individuals with EDs.…”

Section: Sensor Technology In Physical Healthmentioning

confidence: 99%

“…For example, the ability for both wearable and nonwearable sensors to detect patterns and deviations in motion has allowed caregivers to predict and prevent dangerous situations (e.g., falling) in elderly patients with Parkinson's disease and Dementia (e.g., Yu, 2008 Fritz, Huang, Murphy, and Zimmerman [2014]). In addition to measuring physical activity, wearable sensors (e.g., wrist or necklace sensor) and nonwearable sensors (e.g., fork and tray) have been designed to accurately and objectively measure quantity and rate of food intake in an everyday environment (e.g., Alshurafa et al, 2015;Dong, Scisco, Wilson, Muth, & Hoover, 2014). However, these devices have not yet been tested with individuals with EDs.…”

Section: Sensor Technology In Physical Healthmentioning

confidence: 99%

Sensor technology implementation for research, treatment, and assessment of eating disorders

Levinson

Christian

Shankar‐Ram

et al. 2019

Intl J Eating Disorders

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Sensor technology has made huge technological advances in the past decade. Many sensor technologies (e.g., wearable wristbands) have been integrated into health research with the ability to substantially improve health outcomes and reduce health care costs. Despite the rapid technological developments in sensor technology, little research has examined sensor technology in eating disorders (EDs). The overarching aim of the current article is to briefly review the literature on sensor technology and health outcomes, including EDs, and discuss several potential ideas for the application of sensor technology in the treatment, assessment, and diagnosis of EDs. We will also present data from a feasibility case study with an ED participant and healthy control providing a brief example of how wearable sensor technology might be implemented in ED research. Overall, we will discuss how sensor technology could be used to improve treatment and assessment of EDs and represents an idea in need of more research in the ED field.

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Recognition of Nutrition Intake Using Time-Frequency Decomposition in a Wearable Necklace Using a Piezoelectric Sensor

Cited by 82 publications

References 31 publications

Food Intake Detection and Classification Using a Necklace-Type Piezoelectric Wearable Sensor System

Food Intake Detection and Classification Using a Necklace-Type Piezoelectric Wearable Sensor System

Segmentation and Characterization of Chewing Bouts by Monitoring Temporalis Muscle Using Smart Glasses With Piezoelectric Sensor

Sensor technology implementation for research, treatment, and assessment of eating disorders

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