Reducing Smartwatch Users’ Distraction with Convolutional Neural Network

Lee, Jemin; Kwon, Jinse; Kim, Hyungshin

doi:10.1155/2018/7689549

Cited by 6 publications

(17 citation statements)

References 22 publications

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“…Four of these methods, DISP, FGWS, RDE and MDRE have already been introduced in §2.2. We also add a detection method, MD, which simultaneously detects outof-distribution and adversarial samples (Lee et al, 2018). It first calculates the class-conditional Gaussian distribution of the features and then gives the adversarial confidence score of the samples by Mahalanobis distance.…”

Section: Baselinesmentioning

confidence: 99%

CASN:Class-Aware Score Network for Textual Adversarial Detection

Bao,

Zheng,

Ding

et al. 2023

Proceedings of the 61st Annual Meeting of the Association for Computational Linguistics (Volume 1: Long Papers)

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Adversarial detection aims to detect adversarial samples that threaten the security of deep neural networks, which is an essential step toward building robust AI systems. Density-based estimation is widely considered as an effective technique by explicitly modeling the distribution of normal data and identifying adversarial ones as outliers. However, these methods suffer from significant performance degradation when the adversarial samples lie close to the non-adversarial data manifold. To address this limitation, we propose a score-based generative method to implicitly model the data distribution. Our approach utilizes the gradient of the log-density data distribution and calculates the distribution gap between adversarial and normal samples through multi-step iterations using Langevin dynamics. In addition, we use supervised contrastive learning to guide the gradient estimation using label information, which avoids collapsing to a single data manifold and better preserves the anisotropy of the different labeled data distributions. Experimental results on three text classification tasks upon four advanced attack algorithms show that our approach is a significant improvement (+15.2 F1 score on average against previous SOTA) over previous detection methods.

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Section: Baselinesmentioning

confidence: 99%

CASN:Class-Aware Score Network for Textual Adversarial Detection

Bao,

Zheng,

Ding

et al. 2023

Proceedings of the 61st Annual Meeting of the Association for Computational Linguistics (Volume 1: Long Papers)

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“…NotificationListenerService 31 (launched Android API level 21) and NotificationManager 32 (launched Android API level 1) can collect the more specific notification information (e.g., notification app name, time, status, priority, text, category, sound, visibility). Currently, notification related Android APIs such as NotificationListenerService and NotificationManager are widely used along with AS API to study notification usage behaviors in existing studies (e.g., [17,15,100,25,14,32]). [106].…”

Section: Notification Api Frameworkmentioning

confidence: 99%

“…The US API provides functions to query app usage logs by specifying time units of day, month, and year, thereby retrieving the results specified by the interval which is a more granular and explicit query system [11]. Since 2014, the US API has been mainly used to collect app usage pattern data in many studies (e.g., [12,13,14,15]). However, the AS API is still exclusively used to track the user interface (UI) status information (e.g., UI changed status, interaction type, UI properties & hierarchy, and notification) in the present studies (e.g., [16,17,18,19]).…”

Section: Introductionmentioning

confidence: 99%

“…Along with the AS/US APIs, other Android built-in sensors and APIs are also used to collect mobile usage and sensor data for the research. These data can be collected using Android built-in hardware (HW) sensors (e.g., accelerometer, gyro, GPS, Wi-Fi, Bluetooth, proximity, light, compass, pressure) and APIs (e.g., Sensor APIs 11 , Wi-Fi APIs 12 , Google Location Services APIs 13 , Bluetooth APIs 14 ). In other words, we can use these Android built-in sensors and APIs to track a user's physical activity, physiological state, and surrounding context information (e.g., location, ambient environment) for the research as shown in Figure 1.…”

Section: Introductionmentioning

confidence: 99%

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A Systematic Survey on Android API Usage for Data-Driven Analytics with Smartphones

Lee,

Park,

Lee

2021

Preprint

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Recently, there has been an increase in industrial and academic research on data-driven analytics with smartphones based on the collection of app usage patterns and surrounding context data. The Android mobile operating system utilizes Usage Statistics API (US API) and Accessibility Service API (AS API) as representative APIs to passively collect app usage data. These APIs are used for various research purposes as they can collect app usage patterns (e.g., app status, usage time, app name, user interaction state, and smartphone use state) and fine-grained data (e.g., user interface elements & hierarchy and user interaction type & target & time) of each application. In addition, other sensing APIs help to collect the user's surroundings context (location, network, ambient environment) and device state data, along with AS/US API. In this review, we provide insights on the types of mobile usage and sensor data that can be collected for each research purpose by considering Android built-in APIs and sensors (AS/US API, and other sensing APIs). Moreover, we classify the research purposes of the surveyed papers into four categories and 17 sub-categories, and create a hierarchical structure for data classification, comprising three layers. We present the important trends in the usage of Android's built-in APIs and sensors, including AS/US API, the types of data collected using the presented APIs, and discuss the utilization of mobile usage and sensor data in future research.

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“…In the image domain, defence against adversarial attack can be 'proactive' or 'reactive' (Cohen et al, 2020), where proactive defence refers to improving the model's robustness (Madry et al, 2018;Gopinath et al, 2018;Cohen et al, 2019) and reactive defence focuses on detecting real adversarial examples before they are passed to neural networks (Feinman et al, 2017;Ma et al, 2018;Lee et al, 2018;Papernot and McDaniel, 2018). Broadly speaking, for reactive methods, the detection of adversarial examples involves taking a conceptualisation of the space of learned representations and the adversarial subspaces within them (Tanay and Griffin, 2016;Tramèr et al, 2017), and then characterising the differences in some function of the learned representations between the actual and the adversarial inputs produced by the DNN; for example, Ma et al (2018) applied a local intrinsic dimensionality (LID) measure to the learned representations and used that to successfully distinguish normal and adversarial images.…”

Section: Introductionmentioning

confidence: 99%

What Learned Representations and Influence Functions Can Tell Us About Adversarial Examples

Tonni,

Dras

2023

Findings of the Association for Computational Linguistics: IJCNLP-AACL 2023 (Findings)

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Adversarial examples, deliberately crafted using small perturbations to fool deep neural networks, were first studied in image processing and more recently in NLP. While approaches to detecting adversarial examples in NLP have largely relied on search over input perturbations, image processing has seen a range of techniques that aim to characterise adversarial subspaces over the learned representations.In this paper, we adapt two such approaches to NLP, one based on nearest neighbors and influence functions and one on Mahalanobis distances. The former in particular produces a state-of-the-art detector when compared against several strong baselines; moreover, the novel use of influence functions provides insight into how the nature of adversarial example subspaces in NLP relate to those in image processing, and also how they differ depending on the kind of NLP task.

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Reducing Smartwatch Users’ Distraction with Convolutional Neural Network

Cited by 6 publications

References 22 publications

CASN:Class-Aware Score Network for Textual Adversarial Detection

CASN:Class-Aware Score Network for Textual Adversarial Detection

A Systematic Survey on Android API Usage for Data-Driven Analytics with Smartphones

What Learned Representations and Influence Functions Can Tell Us About Adversarial Examples

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