Seiji Tokura scite author profile

Dinuclear manganese(III,IV) and (IV,IV) complexes, [Mn2(N4-py)2(O)2](ClO4)3·H2O (1) and [Mn2 (N4-py)2(O)2](ClO4)4·CH3CN·H2O (2), were prepared, where N4-py represents tris(2-pyridylmethyl)amine. Both complexes 1 and 2 exhibited strong antiferromagnetic interaction with J≈−159 and −137 cm−1, respectively. ESR spectrum of 1 showed a sixteen 55Mn hyperfine pattern at g=2, which is indicative of a Mn(III,IV) trapped valence state.

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Depth Image–Based Deep Learning of Grasp Planning for Textureless Planar-Faced Objects in Vision-Guided Robotic Bin-Picking

Jiang

Ishihara

Sugiyama

et al. 2020

Sensors

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Bin-picking of small parcels and other textureless planar-faced objects is a common task at warehouses. A general color image–based vision-guided robot picking system requires feature extraction and goal image preparation of various objects. However, feature extraction for goal image matching is difficult for textureless objects. Further, prior preparation of huge numbers of goal images is impractical at a warehouse. In this paper, we propose a novel depth image–based vision-guided robot bin-picking system for textureless planar-faced objects. Our method uses a deep convolutional neural network (DCNN) model that is trained on 15,000 annotated depth images synthetically generated in a physics simulator to directly predict grasp points without object segmentation. Unlike previous studies that predicted grasp points for a robot suction hand with only one vacuum cup, our DCNN also predicts optimal grasp patterns for a hand with two vacuum cups (left cup on, right cup on, or both cups on). Further, we propose a surface feature descriptor to extract surface features (center position and normal) and refine the predicted grasp point position, removing the need for texture features for vision-guided robot control and sim-to-real modification for DCNN model training. Experimental results demonstrate the efficiency of our system, namely that a robot with 7 degrees of freedom can pick randomly posed textureless boxes in a cluttered environment with a 97.5% success rate at speeds exceeding 1000 pieces per hour.

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Reduction of the gap between simulated and real environments in evolutionary robotics: a dynamically-rearranging neural network approach

Ishiguro

Tokura²,

Kondo³

et al.

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Person Following Robot with Vision-based and Sensor Fusion Tracking Algorithm

Sonoura¹,

Yoshimi

Nishiyama³

et al. 2008

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Seiji Tokura

Development of a Person Following Robot with Vision Based Target Detection

Dinuclear Manganese(III,IV) and Manganese(IV,IV) Complexes with Tris(2-pyridylmethyl)amine

Depth Image–Based Deep Learning of Grasp Planning for Textureless Planar-Faced Objects in Vision-Guided Robotic Bin-Picking

Reduction of the gap between simulated and real environments in evolutionary robotics: a dynamically-rearranging neural network approach

Person Following Robot with Vision-based and Sensor Fusion Tracking Algorithm

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