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ORCIDYasutoshi Makino
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2020 – today
- 2020
[j8]Shun Suzuki
, Masahiro Fujiwara, Yasutoshi Makino, Hiroyuki Shinoda:
Reducing Amplitude Fluctuation by Gradual Phase Shift in Midair Ultrasound Haptics. IEEE Trans. Haptics 13(1): 87-93 (2020)- [c88]Tao Morisaki, Masahiro Fujiwara, Yasutoshi Makino, Hiroyuki Shinoda:
Comparing Lateral Modulation and Amplitude Modulation in Phantom Sensation. EuroHaptics 2020: 122-130 - [c87]Kentaro Ariga, Masahiro Fujiwara, Yasutoshi Makino, Hiroyuki Shinoda:
Midair Haptic Presentation Using Concave Reflector. EuroHaptics 2020: 307-315 - [c86]Atsushi Matsubayashi, Yasutoshi Makino, Hiroyuki Shinoda:
Rendering Ultrasound Pressure Distribution on Hand Surface in Real-Time. EuroHaptics 2020: 407-415 - [c85]Emiri Sakiyama, Atsushi Matsubayashi, Daichi Matsumoto, Masahiro Fujiwara, Yasutoshi Makino, Hiroyuki Shinoda:
Midair Tactile Reproduction of Real Objects. EuroHaptics 2020: 425-433 - [c84]Seunggoo Rim, Shun Suzuki, Yutaro Toide, Masahiro Fujiwara, Yasutoshi Makino, Hiroyuki Shinoda:
Sound-Image Icon with Aerial Haptic Feedback. EuroHaptics 2020: 489-496 - [c83]Kohki Serizawa, Tao Morisaki, Charlotte Delfosse, Masahiro Fujiwara, Yasutoshi Makino, Hiroyuki Shinoda:
Super Haptoclone: Upper-Body Mutual Telexistence System with Haptic Feedback. SIGGRAPH Emerging Technologies 2020: 1:1-1:2 - [c82]Tao Morisaki, Ryoma Mori, Ryosuke Mori, Kohki Serizawa, Yasutoshi Makino, Yuta Itoh, Yuji Yamakawa, Hiroyuki Shinoda:
Hopping-Pong: Computational Curveball in Table Tennis by Noncontact Ultrasound Force. SIGGRAPH Emerging Technologies 2020: 11:1-11:2 - [c81]Mitsuru Nakajima, Yasutoshi Makino, Hiroyuki Shinoda:
Remote Cooling Sensation Presentation Controlling Mist in Midair. SII 2020: 1238-1241 - [c80]Ryoma Mori, Toki Furukawa, Yasutoshi Makino, Hiroyuki Shinoda:
Measurement of Disturbance-Induced Fall Behavior and Prediction Using Neural Network. SMC 2020: 2142-2149
2010 – 2019
- 2019
- [j7]Takuro Furumoto, Keisuke Hasegawa, Yasutoshi Makino, Hiroyuki Shinoda:
Three-Dimensional Manipulation of a Spherical Object Using Ultrasound Plane Waves. IEEE Robotics Autom. Lett. 4(1): 81-88 (2019) - [j6]Azuma Yoshimoto, Keisuke Hasegawa, Yasutoshi Makino, Hiroyuki Shinoda:
Midair Haptic Pursuit. IEEE Trans. Haptics 12(4): 652-657 (2019) - [c79]Shuya Suda, Yasutoshi Makino, Hiroyuki Shinoda:
Prediction of Volleyball Trajectory Using Skeletal Motions of Setter Player. AH 2019: 16:1-16:8 - [c78]Atsushi Matsubayashi, Yasutoshi Makino, Hiroyuki Shinoda:
Direct Finger Manipulation of 3D Object Image with Ultrasound Haptic Feedback. CHI 2019: 87 - [c77]Takuya Handa, Makiko Azuma, Toshihiro Shimizu, Satoru Kondo, Masahiro Fujiwara, Yasutoshi Makino, Hiroyuki Shinoda:
Ball-type Haptic Interface to Present Impact Points with Vibrations for Televised Ball-based Sporting Event. WHC 2019: 85-90 - [c76]Shun Suzuki, Masahiro Fujiwara, Yasutoshi Makino, Hiroyuki Shinoda:
Midair Hand Guidance by an Ultrasound Virtual Handrail. WHC 2019: 271-276 - [c75]Atsushi Matsubayashi, Hiroki Oikawa, Saya Mizutani, Yasutoshi Makino, Hiroyuki Shinoda:
Display of Haptic Shape Using Ultrasound Pressure Distribution Forming Cross-Sectional Shape. WHC 2019: 419-424 - [c74]Saya Mizutani, Masahiro Fujiwara, Yasutoshi Makino, Hiroyuki Shinoda:
Thresholds of Haptic and Auditory Perception in Midair Facial Stimulation. HAVE 2019: 1-6 - [c73]Mitsuru Nakajima, Yasutoshi Makino, Hiroyuki Shinoda:
Displaying Pain Sensation in Midair by Thermal Grill Illusion. HAVE 2019: 1-5 - [c72]Emiri Sakiyama, Daichi Matsumoto, Masahiro Fujiwara, Yasutoshi Makino, Hiroyuki Shinoda:
Evaluation of Multi-Point Dynamic Pressure Reproduction Using Microphone-Based Tactile Sensor Array. HAVE 2019: 1-6 - [c71]Task Ohmori, Yuki Abe, Yu Someya, Masahiro Fujiwara, Yasutoshi Makino, Hiroyuki Shinoda:
ReFriction: Remote friction control on polystyrene foam by ultrasound phased array. SIGGRAPH ASIA Emerging Technologies 2019: 40-41 - [c70]Takuro Furumoto, Mitsuru Ito, Masahiro Fujiwara, Yasutoshi Makino, Hiroyuki Shinoda, Takaaki Kamigaki:
Three-dimensional Interaction Technique Using an Acoustically Manipulated Balloon. SIGGRAPH ASIA Emerging Technologies 2019: 51-52 - [c69]Takafumi Kurai, Yutaro Shioi, Yasutoshi Makino, Hiroyuki Shinoda:
Temporal Conditions Suitable for Predicting Human Motion in Walking. SMC 2019: 2986-2991 - [c68]Yasutoshi Makino, Yutaro Shioi, Yuuki Horiuchi, Hiroyuki Shinoda:
Interference of Projected Future Self. SMC 2019: 4113-4117 - [c67]Tao Morisaki, Ryoma Mori, Ryosuke Mori, Yasutoshi Makino, Yuta Itoh, Yuji Yamakawa, Hiroyuki Shinoda:
Hopping-Pong: Changing Trajectory of Moving Object Using Computational Ultrasound Force. ISS 2019: 123-133 - [c66]Takuro Furumoto, Masahiro Fujiwara, Yasutoshi Makino, Hiroyuki Shinoda:
BaLuna: Floating Balloon Screen Manipulated Using Ultrasound. VR 2019: 937-938 - 2018
- [c65]Shun Suzuki, Masahiro Fujiwara, Yasutoshi Makino, Hiroyuki Shinoda:
Midair Ultrasound Haptic Display with Large Workspace. AsiaHaptics 2018: 3-5 - [c64]Kentaro Yoshida, Yuuki Horiuchi, Tomohiro Ichiyama, Seki Inoue, Yasutoshi Makino, Hiroyuki Shinoda:
Estimation of Racket Grip Vibration from Tennis Video by Neural Network. AsiaHaptics 2018: 33-45 - [c63]Mitsuru Nakajima, Keisuke Hasegawa, Yasutoshi Makino, Hiroyuki Shinoda:
Remotely Displaying Cooling Sensation Using Ultrasound Mist Beam. AsiaHaptics 2018: 85-87 - [c62]Takuro Furumoto, Yutaro Toide, Masahiro Fujiwara, Yasutoshi Makino, Hiroyuki Shinoda:
Encounter-Type Haptic Feedback System Using an Acoustically Manipulated Floating Object. AsiaHaptics 2018: 183-186 - [c61]Tao Morisaki, Masahiro Fujiwara, Yasutoshi Makino, Hiroyuki Shinoda:
Controlling Robot Vehicle Using Hand-Gesture with Mid-Air Haptic Feedback. AsiaHaptics 2018: 268-271 - [c60]Kohki Serizawa, Yuichi Masuda, Shun Suzuki, Masahiro Fujiwara, Akihito Noda, Yasutoshi Makino, Hiroyuki Shinoda:
Whole Body Haptic Experience Using 2D Communication Wear. AsiaHaptics 2018: 331-333 - [c59]Tomoki Oji, Yasutoshi Makino, Hiroyuki Shinoda:
Weight Estimation of Lifted Object from Body Motions Using Neural Network. EuroHaptics (2) 2018: 3-13 - [c58]Yoshinori Inoue, Yasutoshi Makino, Hiroyuki Shinoda:
Estimation of the Pressing Force from Finger Image by Using Neural Network. EuroHaptics (2) 2018: 46-57 - [c57]Shun Suzuki, Keisuke Hasegawa, Yasutoshi Makino, Hiroyuki Shinoda:
Haptic Tracing of Midair Linear Trajectories Presented by Ultrasound Bessel Beams. EuroHaptics (1) 2018: 209-220 - [c56]Mitsuru Nakajima, Keisuke Hasegawa, Yasutoshi Makino, Hiroyuki Shinoda:
Remotely displaying cooling sensation via ultrasound-driven air flow. HAPTICS 2018: 340-343 - [c55]Tomohiro Ichiyama, Atsushi Matsubayashi, Yasutoshi Makino, Hiroyuki Shinoda:
Real-Time Control Operation Support of Unstable System by Visual Feedback. VR 2018: 581-582 - 2017
- [c54]Kentaro Yoshida, Seki Inoue, Yasutoshi Makino, Hiroyuki Shinoda:
VibVid: VIBration Estimation from VIDeo by using Neural Network. ICAT-EGVE 2017: 37-44 - [c53]Yuuki Horiuchi, Kentaro Yoshida, Yasutoshi Makino, Hiroyuki Shinoda:
Rubber hand illusion using invisible tactile stimulus. WHC 2017: 490-494 - [c52]Daichi Matsumoto, Keisuke Hasegawa, Yasutoshi Makino, Hiroyuki Shinoda:
Displaying variable stiffness by passive nonlinear spring using visuo-haptic interaction. WHC 2017: 587-592 - [c51]Kentaro Yoshida, Yuuki Horiuchi, Seki Inoue, Yasutoshi Makino, Hiroyuki Shinoda:
HaptoCloneAR: mutual haptic-optic interactive system with 2D image superimpose. SIGGRAPH Emerging Technologies 2017: 13:1-13:2 - [c50]Yuuki Horiuchi, Yasutoshi Makino, Hiroyuki Shinoda:
Computational foresight: realtime forecast of human body motion. SIGGRAPH ASIA Emerging Technologies 2017: 2:1-2:2 - [c49]Yuuki Horiuchi, Yasutoshi Makino, Hiroyuki Shinoda:
Computational Foresight: Forecasting Human Body Motion in Real-time for Reducing Delays in Interactive System. ISS 2017: 312-317 - 2016
- [j5]Keisuke Hasegawa, Tatsuma Sakurai, Yasutoshi Makino, Hiroyuki Shinoda:
Character Reading via Stylus Reproducing Normal Handwriting Motion. IEEE Trans. Haptics 9(1): 13-19 (2016) - [c48]Yuuki Horiuchi, Kazunori Odani, Yasutoshi Makino, Hiroyuki Shinoda:
Rubber Hand Illusion Using Tactile Projector. AsiaHaptics 2016: 41-46 - [c47]Seki Inoue, Yasutoshi Makino, Hiroyuki Shinoda:
Scalable Architecture for Airborne Ultrasound Tactile Display. AsiaHaptics 2016: 99-103 - [c46]Mitsuru Ito, Daisuke Wakuda, Yasutoshi Makino, Hiroyuki Shinoda:
Hybrid Focus Using 70 and 40 kHz Ultrasound in Mid-Air Tactile Display. AsiaHaptics 2016: 131-134 - [c45]Hirokazu Miyahara, Yasutoshi Makino, Hiroyuki Shinoda:
Inducing Wrist Twist During Arm Swing by Using Gyro Effect. AsiaHaptics 2016: 205-209 - [c44]Kyosuke Yamazaki, Keisuke Hasegawa, Yasutoshi Makino, Hiroyuki Shinoda:
Visuo-Tactile Interaction with Virtual Objects that Yields Kinetic Effects on Real Objects. AsiaHaptics 2016: 267-273 - [c43]Daichi Matsumoto, Ya Zhu, Yuya Tanaka, Kyosuke Yamazaki, Keisuke Hasegawa, Yasutoshi Makino, Hiroyuki Shinoda:
An Immersive Visuo-Haptic VR Environment with Pseudo-haptic Effects on Perceived Stiffness. AsiaHaptics 2016: 281-285 - [c42]Kentaro Yoshida, Koji Tanaka, Keisuke Hasegawa, Yasutoshi Makino, Hiroyuki Shinoda:
Character Recognition by Flick Movements Presented on Fingers. AsiaHaptics 2016: 425-431 - [c41]Kentaro Yoshida, Takaaki Kamigaki, Seki Inoue, Keisuke Hasegawa, Yasutoshi Makino, Hiroyuki Shinoda:
HaptoCloneAR (Haptic-Optical Clone with Augmented Reality) for Mutual Interactions with Midair 3D Floating Image and Superimposed 2D Display. AsiaHaptics 2016: 473-477 - [c40]Ryota Arai, Yasutoshi Makino, Hiroyuki Shinoda:
Magnification-Changeable Haptic-Optical Clone. AsiaHaptics 2016: 485-489 - [c39]Yuta Kimura, Yasutoshi Makino, Hiroyuki Shinoda:
Computer-Created Interactive 3D Image with Midair Haptic Feedback. AsiaHaptics 2016: 491-494 - [c38]Yasutoshi Makino, Yoshikazu Furuyama, Seki Inoue, Hiroyuki Shinoda:
HaptoClone (Haptic-Optical Clone) for Mutual Tele-Environment by Real-time 3D Image Transfer with Midair Force Feedback. CHI 2016: 1980-1990 - [c37]Mitsuru Ito, Daisuke Wakuda, Seki Inoue, Yasutoshi Makino, Hiroyuki Shinoda:
High Spatial Resolution Midair Tactile Display Using 70 kHz Ultrasound. EuroHaptics (1) 2016: 57-67 - [c36]Seki Inoue, Yasutoshi Makino, Hiroyuki Shinoda:
Mid-Air Ultrasonic Pressure Control on Skin by Adaptive Focusing. EuroHaptics (1) 2016: 68-77 - [c35]Koji Tanaka, Keisuke Hasegawa, Yasutoshi Makino, Hiroyuki Shinoda:
A Pocket-Size Alphabet Display with Letter Trajectories Presented to Fingers. EuroHaptics (1) 2016: 472-482 - [c34]Ryota Arai, Yasutoshi Makino, Hiroyuki Shinoda:
Acceptable Mismatch Between Scaled 3D Images and Tactile Stimulation. EuroHaptics (2) 2016: 501-509 - [c33]Yoshikazu Furuyama, Atsushi Matsubayashi, Yasutoshi Makino, Hiroyuki Shinoda:
X-SectionScope: cross-section projection in light field clone image. SIGGRAPH Emerging Technologies 2016: 22:1-22:2 - 2015
- [j4]Max Rheiner, Thomas Tobler, Fabian Troxler, Seki Inoue, Keisuke Hasegawa, Yasuaki Monnai, Yasutoshi Makino, Hiroyuki Shinoda, Jules Françoise, Norbert Schnell, Riccardo Borghesi, Frédéric Bevilacqua, Tuncay Cakmak, Holger Hager:
Demo hour. Interactions 22(2): 6-9 (2015) - [c32]Yoshikazu Furuyama, Yasutoshi Makino, Hiroyuki Shinoda:
X-Dimensional Display: Superimposing 2D Cross-Sectional Image inside 3D Wireframe Aerial Image. ICAT-EGVE 2015: 29-36 - [c31]Seki Inoue, Yasutoshi Makino, Hiroyuki Shinoda:
Active touch perception produced by airborne ultrasonic haptic hologram. World Haptics 2015: 362-367 - [c30]Keisuke Hasegawa, Yasuaki Monnai, Seki Inoue, Yoshikazu Furuyama, Yasutoshi Makino, Hiroyuki Shinoda:
Midair touch display. SIGGRAPH Emerging Technologies 2015: 18:1 - [c29]Yoshikazu Furuyama, Yasutoshi Makino, Hiroyuki Shinoda:
X-dimensional display: superimposing 2D cross sectional image inside 3D wireframe aerial image. SIGGRAPH Asia Emerging Technologies 2015: 28:1-28:2 - [c28]Yasutoshi Makino, Yoshikazu Furuyama, Hiroyuki Shinoda:
HaptoClone (Haptic-Optical Clone): Mid-air Haptic-Optical Human-Human Interaction with Perfect Synchronization. SUI 2015: 139 - [i1]Keisuke Hasegawa, Tatsuma Sakurai, Yasutoshi Makino, Hiroyuki Shinoda:
Transmitting Full Set of Alphabet Letters to Human Hand via Writing Motion with 5-minute Training. CoRR abs/1503.07401 (2015) - 2014
- [c27]Yasutoshi Makino:
Thumbnail Input for Head-Mounted Display. AsiaHaptics 2014: 197-200 - [c26]Masa Ogata, Yuta Sugiura, Yasutoshi Makino, Masahiko Inami, Michita Imai:
Augmenting a Wearable Display with Skin Surface as an Expanded Input Area. HCI (9) 2014: 606-614 - [c25]Seki Inoue, Koseki J. Kobayashi-Kirschvink, Yasuaki Monnai, Keisuke Hasegawa, Yasutoshi Makino, Hiroyuki Shinoda:
HORN: the hapt-optic reconstruction. SIGGRAPH Emerging Technologies 2014: 11:1 - 2013
- [c24]Yasutoshi Makino, Yuta Sugiura, Masayasu Ogata, Masahiko Inami:
Tangential force sensing system on forearm. AH 2013: 29-34 - [c23]Yasutoshi Makino, Takashi Maeno:
Paired vibratory stimulation for haptic feedback. AH 2013: 47-50 - [c22]Shimon Akiyama, Katsunari Sato, Yasutoshi Makino, Takashi Maeno:
ThermOn: thermo-musical interface for an enhanced emotional experience. ISWC 2013: 45-52 - [c21]Masayasu Ogata, Yuta Sugiura, Yasutoshi Makino, Masahiko Inami, Michita Imai:
SenSkin: adapting skin as a soft interface. UIST 2013: 539-544 - 2012
- [c20]Yuta Sugiura, Calista Lee, Masayasu Ogata, Anusha I. Withana, Yasutoshi Makino, Daisuke Sakamoto, Masahiko Inami, Takeo Igarashi:
PINOKY: a ring that animates your plush toys. CHI 2012: 725-734 - [c19]Yuta Sugiura, Calista Lee, Masayasu Ogata, Anusha I. Withana, Yasutoshi Makino, Daisuke Sakamoto, Masahiko Inami, Takeo Igarashi:
PINOKY: a ring-like device that gives movement to any plush toy. CHI Extended Abstracts 2012: 1443-1444 - [c18]Shimon Akiyama, Katsunari Sato, Yasutoshi Makino, Takashi Maeno:
Presentation of thermal sensation through preliminary adjustment of adapting skin temperature. HAPTICS 2012: 355-358 - [c17]Maisarah Binti Ridzuan, Yasutoshi Makino, Kenjiro Takemura:
Direct Touch Haptic Display Using Immersive Illusion with Interactive Virtual Finger. EuroHaptics (1) 2012: 432-444 - [c16]Yoichi Watanabe, Yasutoshi Makino, Katsunari Sato, Takashi Maeno:
Contact Force and Finger Angles Estimation for Touch Panel by Detecting Transmitted Light on Fingernail. EuroHaptics (1) 2012: 601-612 - [c15]Yasutoshi Makino, Akiko Kamigori, Takashi Maeno:
Wireless wearable vibration sensor for touch-based life log system. INSS 2012: 1-4 - [c14]Katsunari Sato, Yoichi Watanabe, Yasutoshi Makino, Takashi Maeno:
Vision-based force sensor for touch panel devices using built-in camera. SCIS&ISIS 2012: 852-855 - [c13]Shimon Akiyama, Katsunari Sato, Yasutoshi Makino, Takashi Maeno:
EffectON - Enriching impressions of motions and physically changing motions via synchronous sound effects. SCIS&ISIS 2012: 856-860 - 2011
- [c12]Yasutoshi Makino, Takashi Maeno, Hiroyuki Shinoda:
Perceptual characteristic of multi-spectral vibrations beyond the human perceivable frequency range. World Haptics 2011: 439-443 - [c11]Kei Nakatsuma, Hiroyuki Shinoda, Yasutoshi Makino, Katsunari Sato, Takashi Maeno:
Touch interface on back of the hand. SIGGRAPH Emerging Technologies 2011: 19 - [c10]Kei Nakatsuma, Hiroyuki Shinoda, Yasutoshi Makino, Katsunari Sato, Takashi Maeno:
Touch interface on back of the hand. SIGGRAPH Posters 2011: 39 - 2010
- [j3]Anusha I. Withana, Yasutoshi Makino, Makoto Kondo, Maki Sugimoto, Kakehi Gota, Masahiko Inami:
ImpAct: Immersive haptic stylus to enable direct touch and manipulation for surface computing. Comput. Entertain. 8(2): 9:1-9:16 (2010) - [j2]Hiroyuki Shinoda, Yasutoshi Makino, Naoshi Yamahira, Hiroto Itai:
Two-Dimensional Wireless Power Supply to Ubiquitous Robots Using Microwaves. J. Robotics Mechatronics 22(6): 777-783 (2010) - [j1]Hiroyuki Shinoda, Hiromasa Chigusa, Yasutoshi Makino:
Flexible Tactile Sensor Skin Using Wireless Sensor Elements Coupled with 2D Microwaves. J. Robotics Mechatronics 22(6): 784-789 (2010) - [c9]Yasutoshi Makino, Masakazu Murao, Takashi Maeno:
Life Log System Based on Tactile Sound. EuroHaptics (1) 2010: 292-297 - [c8]Anusha I. Withana, Makoto Kondo, Kakehi Gota, Yasutoshi Makino, Maki Sugimoto, Masahiko Inami:
ImpAct: enabling direct touch and manipulation for surface computing. UIST (Adjunct Volume) 2010: 411-412
2000 – 2009
- 2008
- [c7]Kei Nakatsuma, Yasutoshi Makino, Hiroyuki Shinoda, Hiroto Itai:
Two-dimensional communication. SIGGRAPH New Tech Demos 2008: 40 - [c6]Kei Nakatsuma, Yasutoshi Makino, Hiroyuki Shinoda:
Node self-localization in the "Two-Dimensional Communication" networks. SIGGRAPH Posters 2008: 93 - 2007
- [c5]Hiromasa Chigusa, Yasutoshi Makino, Hiroyuki Shinoda:
Large Area Sensor Skin based on Two-Dimensional Signal Transmission Technology. WHC 2007: 151-156 - [c4]Yasutoshi Makino, Hiroyuki Shinoda:
Comfortable Wristband Interface Measuring Myoelectric Pattern. WHC 2007: 433-438 - 2005
- [c3]Yasutoshi Makino, Hiroyuki Shinoda:
Selective Stimulation to Superficial Mechanoreceptors by Temporal Control of Suction Pressure. WHC 2005: 229-234 - 2004
- [c2]Yasutoshi Makino, Naoya Asamura, Hiroyuki Shinoda:
Multi Primitive Tactile Display Based on Suction Pressure Control. HAPTICS 2004: 90-97 - [c1]Yasutoshi Makino, Naoya Asamura, Hiroyuki Shinoda:
A Whole Palm Tactile Display using Suction Pressure. ICRA 2004: 1524-1529
Coauthor Index
[j8] [c88] [c87] [c86] [c85] [c84] [c83] [c82] [c81] [c80] [j7] [j6] [c79] [c78] [c77] [c76] [c75] [c74] [c73] [c72] [c71] [c70] [c69] [c68] [c67] [c66] [c65] [c64] [c63] [c62] [c61] [c60] [c59] [c58] [c57] [c56] [c55] [c54] [c53] [c52] [c51] [c50] [c49] [j5] [c48] [c47] [c46] [c45] [c44] [c43] [c42] [c41] [c40] [c39] [c38] [c37] [c36] [c35] [c34] [c33] [j4] [c32] [c31] [c30] [c29] [c28] [i1] [c25] [c12] [c11] [c10] [j2] [j1] [c7] [c6] [c5] [c4] [c3] [c2] [c1]
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