Weakly Supervised Learning for Evaluating Road Surface Condition from Wheelchair Driving Data

Watanabe, Toshio; Takahashi, Hiroki; Iwasawa, Yusuke; Matsuo, Yutaka; Yairi, Ikuko Eguchi

doi:10.3390/info11010002

Cited by 7 publications

(5 citation statements)

References 46 publications

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“…However, studies from [ 17 , 18 , 19 , 20 ] mainly focused on detecting the damages of a motorcar road and required a smartphone to be installed on the dashboard of a vehicle, thus the method is not suitable for wheelchair users. In contrast, Watanabe et al and Iwasawa et al [ 21 , 22 ] tried to recognize the status of the sidewalk by using acceleration data. However, this kind of data is not only largely sensitive to the outdoor conditions and inherent vibrations/noises of a wheelchair but also not feasible to provide users with intuitive information about the defects observed.…”

Section: Discussionmentioning

confidence: 99%

“…With a recent growth of computer vision and machine learning technologies, there have been various attempts to automatically detect and report defects on roads and sidewalks. Previous approaches primarily captured RGB road images or sensor data (e.g., accelerometer and gyroscope) and exploited deep learning and machine learning algorithms for both detecting road cracks/potholes [ 17 , 18 , 19 , 20 ] and recognizing sidewalk anomalies [ 21 , 22 ]. These methods can automatically detect the defects on the road surface but still have the following limitations: (1) the captured RGB images are not helpful to classify the road condition under low-light conditions (e.g., nighttime) and (2) sensors can produce noisy data or restrict the user’s natural movements, adversely affecting the overall performance.…”

Section: Introductionmentioning

confidence: 99%

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Classification of the Sidewalk Condition Using Self-Supervised Transfer Learning for Wheelchair Safety Driving

Yoon

Kim

Jeong

2022

Sensors

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The demand for wheelchairs has increased recently as the population of the elderly and patients with disorders increases. However, society still pays less attention to infrastructure that can threaten the wheelchair user, such as sidewalks with cracks/potholes. Although various studies have been proposed to recognize such challenges, they mainly depend on RGB images or IMU sensors, which are sensitive to outdoor conditions such as low illumination, bad weather, and unavoidable vibrations, resulting in unsatisfactory and unstable performance. In this paper, we introduce a novel system based on various convolutional neural networks (CNNs) to automatically classify the condition of sidewalks using images captured with depth and infrared modalities. Moreover, we compare the performance of training CNNs from scratch and the transfer learning approach, where the weights learned from the natural image domain (e.g., ImageNet) are fine-tuned to the depth and infrared image domain. In particular, we propose applying the ResNet-152 model pre-trained with self-supervised learning during transfer learning to leverage better image representations. Performance evaluation on the classification of the sidewalk condition was conducted with 100% and 10% of training data. The experimental results validate the effectiveness and feasibility of the proposed approach and bring future research directions.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Classification of the Sidewalk Condition Using Self-Supervised Transfer Learning for Wheelchair Safety Driving

Yoon

Kim

Jeong

2022

Sensors

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“…This section introduces our weakly supervised method to extract representations of road surface conditions [Watanabe et al, 2020]. Our method uses positional information collected while driving as low-cost weak supervision to learn road surface conditions and does not depend on human annotations.…”

Section: Methodsmentioning

confidence: 99%

Wheelchair Behavior Recognition for Visualizing Sidewalk Accessibility by Deep Neural Networks

Watanabe

Takahashi

Sato

et al. 2021

Communications in Computer and Information Science

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This paper introduces our methodology to estimate sidewalk accessibilities from wheelchair behavior via a triaxial accelerometer in a smartphone installed under a wheelchair seat. Our method recognizes sidewalk accessibilities from environmental factors, e.g. gradient, curbs, and gaps, which influence wheelchair bodies and become a burden for people with mobility difficulties. This paper developed and evaluated a prototype system that visualizes sidewalk accessibility information by extracting knowledge from wheelchair acceleration using deep neural networks. Firstly, we created a supervised convolutional neural network model to classify road surface conditions using wheelchair acceleration data. Secondly, we applied a weakly supervised method to extract representations of road surface conditions without manual annotations. Finally, we developed a self-supervised variational autoencoder to assess sidewalk barriers for wheelchair users. The results show that the proposed method estimates sidewalk accessibilities from wheelchair accelerations and extracts knowledge of accessibilities by weakly supervised and self-supervised approaches.

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“…The kernel sizes of each convolutional and pooling layer were nine, nine, six, six, and three, and the convolution depth (depth size) is 96, 96, 48, 48, 32 steps, stride size was one. This network was based on Evaluating Road Surface Condition from Wheelchair Driving Data [53].…”

Section: Comparison Of Learning Modelsmentioning

confidence: 99%

Stetho Touch: Touch Action Recognition System by Deep Learning with Stethoscope Acoustic Sensing

Masuda

Furukawa

Yairi

2022

Journal of Information Processing

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Developing a new IoT device input method that can reduce the burden on users has become an important issue. This paper proposed a system Stetho Touch that identifies touch actions using acoustic information obtained when a user's finger makes contact with a solid object. To investigate the method, we implemented a prototype of an acoustic sensing device consisting of a low-pressure melamine veneer table, a stethoscope, and an audio interface. The CNN-LSTM classification model of combining CNN and LSTM classified the five touch actions with accuracy 88.26%, f-score 87.26% in LOSO and accuracy 99.39, f-score 99.39 in 18-fold cross-validation. The contributions of this paper are the following; (1) proposed a touch action recognition method using acoustic information that is more natural and accurate than existing methods, (2) evaluated a touch action recognition method using Deep Learning that can be processed in real-time using acoustic time series raw data as input, and (3) proved the compensations for the user dependence of touch actions by providing a learning phase or performing sequential learning during use.

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Weakly Supervised Learning for Evaluating Road Surface Condition from Wheelchair Driving Data

Cited by 7 publications

References 46 publications

Classification of the Sidewalk Condition Using Self-Supervised Transfer Learning for Wheelchair Safety Driving

Classification of the Sidewalk Condition Using Self-Supervised Transfer Learning for Wheelchair Safety Driving

Wheelchair Behavior Recognition for Visualizing Sidewalk Accessibility by Deep Neural Networks

Stetho Touch: Touch Action Recognition System by Deep Learning with Stethoscope Acoustic Sensing

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