Towards robust personal assistant robots: Experience gained in the SRS project

Qiu, Renxi; Ji, Ze; Noyvirt, Alexandre; Soroka, Anthony John; Setchi, Rossitza; Pham, Duc Truong; Xu, Shiyi; Shivarov, N.; Pigini, Lucia; Arbeiter, Georg; Weißhardt, Florian; Graf, Birgit; Mast, Marcus; Blasi, Lorenzo; Facal, David; Rooker, Martijn; López, Rafael Lemuz; Li, D.; Liu, B.; Kronreif, Gernot; Smrž, Pavel

doi:10.1109/iros.2012.6385727

Cited by 21 publications

(11 citation statements)

References 28 publications

(38 reference statements)

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“…• An underlying control architecture that allows recognition of robot failure states and smooth handover of control between robot and human remote operators [5] • System-assisted, semi-autonomous telemanipulation with offline trajectory execution and editing of 3D collision maps by the user for high controllability of the telemanipulation result yet safe, collision-free operation • Remote navigation with several control modes of different autonomy, with and without collision avoidance • An ecological visualization approach that integrates data from various sensors as well as other data like a robot model and collision indicators into a single 3D representation of the remote environment [16] • Visualization of colored point clouds enhanced by global 3D environment mapping [16,45] with a freely adjustable viewpoint for high situation awareness • Reliance on low-cost interaction devices in form of a standard mouse for viewpoint adjustments and a 3D mouse for precise and intuitive 6-DOF gripper positioning and 3-DOF robot navigation • Avoidance of the need for human compensation of displaycontrol misalignment by the ability to control robot and gripper in the coordinate system of the remote operator's chosen viewpoint on the 3D scene • Optional stereoscopic display mode using contemporary active shutter technology While most of these approaches have been used previously in an isolated form in various domains (e.g., [3,4,6,22,27,29,32,[36][37][38][39]46]), our user interface integrates them into a coherent experience, highly focused on real-world applications.…”

Section: Innovations Of the Evaluated User Interfacementioning

confidence: 99%

“…2. Its foundation is a control architecture that enables the robot to recognize failure states, contact human remote operators for assistance, and reassume control afterwards [5]. Local elderly people are equipped with a portable, smartphone- User interface concept with three user groups: elderly people at home, remote relatives, and professional teleassistants sized multi-touch device so the robot can be commanded from any position in the apartment.…”

Section: Overall Usage Conceptmentioning

confidence: 99%

“…If a robot is unable to carry out a task or fails during execution, a human operator may take control remotely, solve the problem, and hand back control to the robot [3][4][5][6][7]. The system may further assist the operator during teleoperation.…”

Section: Introductionmentioning

confidence: 99%

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Semi-Autonomous Domestic Service Robots: Evaluation of a User Interface for Remote Manipulation and Navigation With Focus on Effects of Stereoscopic Display

Mast

Materna

Španěl

et al. 2014

Int J of Soc Robotics

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In this article, we evaluate a novel type of user interface for remotely resolving challenging situations for service robots in domestic environments. Our focus is on potential advantages of stereoscopic display. The user interface is based on a control architecture that allows involvement of a remote human operator when the robot encounters a problem. It offers semi-autonomous remote manipulation and navigation with low-cost interaction devices, incorporates global 3D environment mapping, and follows an ecological visualization approach that integrates 2D laser data, 3D depth camera data, RGB data, a robot model, constantly updated global 2D and 3D environment maps, and indicators into a single 3D scene with user-adjustable viewpoints and optional viewpoint-based control. We carried out an experiment with 28 participants in a home-like environment investigating the utility of stereoscopic display for three types of task: defining the shape of an unknown or unrecognized object to be grasped, positioning the gripper for semiautonomous reaching and grasping, and navigating the robot around obstacles. Participants were able to successfully complete all tasks and highly approved the user interface in both monoscopic and stereoscopic display modes. They were significantly faster under stereoscopic display in positioning the M. Mast (B) · M. Burmester gripper. For the other two task types, there was a tendency for faster task completion in stereo mode that would need to be verified in further studies. We did not find significant differences in perceived workload between display types for any type of task. We conclude that stereoscopic display seems to be a useful optional display mode for this type of user interface but that its utility may vary depending on the task.

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Section: Innovations Of the Evaluated User Interfacementioning

confidence: 99%

Section: Overall Usage Conceptmentioning

confidence: 99%

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Semi-Autonomous Domestic Service Robots: Evaluation of a User Interface for Remote Manipulation and Navigation With Focus on Effects of Stereoscopic Display

Mast

Materna

Španěl

et al. 2014

Int J of Soc Robotics

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“…In terms of the difficulties experienced by the elderly, standing up and sitting down rank in the top three on the list of the most expected homecare assistances [22]. Therefore, an assistive chair that will assist the elderly in need is in demand, and could possibly delay age-related impairment and further change their lifestyle to reduce the risk of potential diseases.…”

Section: Sedentry Lifestylementioning

confidence: 99%

A survey on assistive chair and related integrated sensing techniques

Oyekan

et al. 2013

2013 International Conference on Manipulation, Manufacturing and Measurement on the Nanoscale

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This paper presents a survey of the current approaches of sit-to-stand assistive chairs. Sitting in a chair and standing up from a seated position are common activities performed by humans on a daily basis. However, older people often encounter difficulties with these activities. The difficulties may cause substantial decreasing of the elderly mobility, leading to inactive participation in society and increasing the risk of chronic diseases that may cause premature death. Therefore, assisting older people to overcome these difficulties has significance for their independent living and active ageing. The assistive devices can be allocated in terms of market available ones and experimental prototypes. Both classes of these devices are discussed in this survey. We also discuss sensing techniques that are currently used with experimental prototypes in addition to those that could be used and build a high level taxonomy of sensing techniques. Following from this survey, a chair capable of delivering assistance-as-needed is proposed.

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“…One of the promising applications is a robot which lives with and takes care of the elderly. Such an assistive robot usually has mobility, object recognition and manipulation skills, and interaction abilities, and assists residents in various ways (e.g., [2], [3], [4], [5]). These works mainly focus on robot operations and human robot interaction.…”

Section: Introductionmentioning

confidence: 99%

Mobile monitoring of physical states of indoor environments for personal support

Kani

Miura

2015

2015 IEEE/SICE International Symposium on System Integration (SII)

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Mobile service robots are expected to operate in our daily life soon, as mobile robot technologies such as SLAM are rapidly developing. As a new application area of the technologies, we propose mobile monitoring and support robot (MMSR), which maintains a residential environment to be comfortable, safe, and secure. A key to realizing MMSRs is monitoring the physical state of the environment. By using a mobile robot as a mobile sensor base, an MMSR can efficiently obtain only necessary environmental information such as the temperature of the location of a person. It can then do supporting actions such as controlling appliances to make the environment more comfortable. We have developed and tested a prototype of MMSR to show the potential feasibility of MMSR concept.Index Terms-Mobile monitoring and support robot, physical state monitoring, personal service robot.

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Towards robust personal assistant robots: Experience gained in the SRS project

Cited by 21 publications

References 28 publications

Semi-Autonomous Domestic Service Robots: Evaluation of a User Interface for Remote Manipulation and Navigation With Focus on Effects of Stereoscopic Display

Semi-Autonomous Domestic Service Robots: Evaluation of a User Interface for Remote Manipulation and Navigation With Focus on Effects of Stereoscopic Display

A survey on assistive chair and related integrated sensing techniques

Mobile monitoring of physical states of indoor environments for personal support

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