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113 results on '"Akai, Naoki"'

1. LiDAR-Inertial Odometry Based on Extended Kalman Filter

Author

Akai, Naoki and Nakao, Takumi

Subjects
Computer Science - Robotics
Abstract

LiDAR-Inertial Odometry (LIO) is typically implemented using an optimization-based approach, with the factor graph often being employed due to its capability to seamlessly integrate residuals from both LiDAR and IMU measurements. Conversely, a recent study has demonstrated that accurate LIO can also be achieved using a loosely-coupled method. Inspired by this advancements, we present a LIO method that leverages the recursive Bayes filter, solved via the Extended Kalman Filter (EKF) - herein referred to as KLIO. Within KLIO, prior and likelihood distributions are computed using IMU preintegration and scan matching between LiDAR and local map point clouds, and the pose, velocity, and IMU biases are updated through the EKF process. Through experiments with the Newer College dataset, we demonstrate that KLIO achieves precise trajectory tracking and mapping. Its accuracy is comparable to that of the state-of-the-art methods in both tightly- and loosely-coupled methods.

Published
2024

2. Spline-Interpolated Model Predictive Path Integral Control with Stein Variational Inference for Reactive Navigation

Author

Miura, Takato, Akai, Naoki, Honda, Kohei, and Hara, Susumu

Subjects
Computer Science - Robotics
Abstract

This paper presents a reactive navigation method that leverages a Model Predictive Path Integral (MPPI) control enhanced with spline interpolation for the control input sequence and Stein Variational Gradient Descent (SVGD). The MPPI framework addresses a nonlinear optimization problem by determining an optimal sequence of control inputs through a sampling-based approach. The efficacy of MPPI is significantly influenced by the sampling noise. To rapidly identify routes that circumvent large and/or newly detected obstacles, it is essential to employ high levels of sampling noise. However, such high noise levels result in jerky control input sequences, leading to non-smooth trajectories. To mitigate this issue, we propose the integration of spline interpolation within the MPPI process, enabling the generation of smooth control input sequences despite the utilization of substantial sampling noises. Nonetheless, the standard MPPI algorithm struggles in scenarios featuring multiple optimal or near-optimal solutions, such as environments with several viable obstacle avoidance paths, due to its assumption that the distribution over an optimal control input sequence can be closely approximated by a Gaussian distribution. To address this limitation, we extend our method by incorporating SVGD into the MPPI framework with spline interpolation. SVGD, rooted in the optimal transportation algorithm, possesses the unique ability to cluster samples around an optimal solution. Consequently, our approach facilitates robust reactive navigation by swiftly identifying obstacle avoidance paths while maintaining the smoothness of the control input sequences. The efficacy of our proposed method is validated on simulations with a quadrotor, demonstrating superior performance over existing baseline techniques.

Published
2024

3. Stein Variational Guided Model Predictive Path Integral Control: Proposal and Experiments with Fast Maneuvering Vehicles

Author

Honda, Kohei, Akai, Naoki, Suzuki, Kosuke, Aoki, Mizuho, Hosogaya, Hirotaka, Okuda, Hiroyuki, and Suzuki, Tatsuya

Subjects
Computer Science - Robotics, Computer Science - Information Theory
Abstract

This paper presents a novel Stochastic Optimal Control (SOC) method based on Model Predictive Path Integral control (MPPI), named Stein Variational Guided MPPI (SVG-MPPI), designed to handle rapidly shifting multimodal optimal action distributions. While MPPI can find a Gaussian-approximated optimal action distribution in closed form, i.e., without iterative solution updates, it struggles with the multimodality of the optimal distributions. This is due to the less representative nature of the Gaussian. To overcome this limitation, our method aims to identify a target mode of the optimal distribution and guide the solution to converge to fit it. In the proposed method, the target mode is roughly estimated using a modified Stein Variational Gradient Descent (SVGD) method and embedded into the MPPI algorithm to find a closed-form "mode-seeking" solution that covers only the target mode, thus preserving the fast convergence property of MPPI. Our simulation and real-world experimental results demonstrate that SVG-MPPI outperforms both the original MPPI and other state-of-the-art sampling-based SOC algorithms in terms of path-tracking and obstacle-avoidance capabilities. Source code: https://github.com/kohonda/proj-svg_mppi, Comment: 7 pages, 5 figures

Published
2023

4. Efficient Solution to 3D-LiDAR-based Monte Carlo Localization with Fusion of Measurement Model Optimization via Importance Sampling

Author

Akai, Naoki

Subjects
Computer Science - Robotics
Abstract

This paper presents an efficient solution to 3D-LiDAR-based Monte Carlo localization (MCL). MCL robustly works if particles are exactly sampled around the ground truth. An inertial navigation system (INS) can be used for accurate sampling, but many particles are still needed to be used for solving the 3D localization problem even if INS is available. In particular, huge number of particles are necessary if INS is not available and it makes infeasible to perform 3D MCL in terms of the computational cost. Scan matching (SM), that is optimization-based localization, efficiently works even though INS is not available because SM can ignore movement constraints of a robot and/or device in its optimization process. However, SM sometimes determines an infeasible estimate against movement. We consider that MCL and SM have complemental advantages and disadvantages and propose a fusion method of MCL and SM. Because SM is considered as optimization of a measurement model in terms of the probabilistic modeling, we perform measurement model optimization as SM. The optimization result is then used to approximate the measurement model distribution and the approximated distribution is used to sample particles. The sampled particles are fused with MCL via importance sampling. As a result, the advantages of MCL and SM can be simultaneously utilized while mitigating their disadvantages. Experiments are conducted on the KITTI dataset and other two open datasets. Results show that the presented method can be run on a single CPU thread and accurately perform localization even if INS is not available., Comment: 8 pages, 4 figures

Published
2023

5. SLAMER: Simultaneous Localization and Map-Assisted Environment Recognition

Author

Akai, Naoki

Subjects
Computer Science - Robotics
Abstract

This paper presents a simultaneous localization and map-assisted environment recognition (SLAMER) method. Mobile robots usually have an environment map and environment information can be assigned to the map. Important information for mobile robots such as no entry zone can be predicted if localization has succeeded since relative pose of them can be known. However, this prediction is failed when localization does not work. Uncertainty of pose estimate must be considered for robustly using the map information. In addition, robots have external sensors and environment information can be recognized using the sensors. This on-line recognition of course contains uncertainty; however, it has to be fused with the map information for robust environment recognition since the map also contains uncertainty owing to over time. SLAMER can simultaneously cope with these uncertainties and achieves accurate localization and environment recognition. In this paper, we demonstrate LiDAR-based implementation of SLAMER in two cases. In the first case, we use the SemanticKITTI dataset and show that SLAMER achieves accurate estimate more than traditional methods. In the second case, we use an indoor mobile robot and show that unmeasurable environmental objects such as open doors and no entry lines can be recognized.

Published
2022

6. Reliable Monte Carlo Localization for Mobile Robots

Author

Akai, Naoki

Subjects
Computer Science - Robotics
Abstract

Reliability is a key factor for realizing safety guarantee of full autonomous robot systems. In this paper, we focus on reliability in mobile robot localization. Monte Carlo localization (MCL) is widely used for mobile robot localization. However, it is still difficult to guarantee its safety because there are no methods determining reliability for MCL estimate. This paper presents a novel localization framework that enables robust localization, reliability estimation, and quick re-localization, simultaneously. The presented method can be implemented using similar estimation manner to that of MCL. The method can increase localization robustness to environment changes by estimating known and unknown obstacles while performing localization; however, localization failure of course occurs by unanticipated errors. The method also includes a reliability estimation function that enables us to know whether localization has failed. Additionally, the method can seamlessly integrate a global localization method via importance sampling. Consequently, quick re-localization from failures can be realized while mitigating noisy influence of global localization. Through three types of experiments, we show that reliable MCL that performs robust localization, self-failure detection, and quick failure recovery can be realized.

Published
2022

9. Experimental Study on Low-Speed Control for Motorcycles Using SPACAR Model and Gain-Scheduling Control

Author

Hara, Susumu, Tsuchiya, Mitsuo, Kimura, Tetsuya, Akai, Naoki, Hara, Susumu, Tsuchiya, Mitsuo, Kimura, Tetsuya, and Akai, Naoki

Abstract

Recently, many studies have presented on realizing novel mobility technologies with consideration for aging society. The aim of these studies is to establish autonomous driving technology (ADT). The objects of ADT are mainly four-wheel motor vehicles. On the other hand, ADT for motorcycles has not been fully addressed yet. Motorcycles have straight-line stability in the state of high-speed driving. However, their stability tends to diminish when being driven at extremely low speed. This study addresses how a motorcycle should be stabilized under low-speed driving. From the viewpoint of actual use, including high-speed driving, major structural changes should be avoided. In order to obtain a linearized motorcycle model without skidding, a model based on SPACAR, a finite element method computation program, is introduced. Furthermore, velocity-dependent gain-scheduling control is applied to utilize the feedback control gains obtained by the linearized model with respect to velocity. Following the deceleration simulation success in the authors’ previous paper, we mainly verify the experimental investigation of the above model and control system design. The gain-scheduling method is improved from that in the previous simulation study. The experimental responses show stable driving at 1.5 km/h.

Published
2024

11. Low‐Speed Control Experiment of Motorcycles Using SPACAR Model

Author

Hara, Susumu, Tsuchiya, Mitsuo, Kimura, Tetsuya, Akai, Naoki, Hara, Susumu, Tsuchiya, Mitsuo, Kimura, Tetsuya, and Akai, Naoki

Abstract

The main stream of development of autonomous driving technology (ADT) is for four-wheel motor vehicles. ADT for motorcycles has received scant attention. The motorcycle stability tends to diminish when being driven at extremely low speed. This study addresses how a motorcycle should be stabilized under low-speed driving. To obtain a linearized motorcycle model without skidding, we introduce a model based on SPACAR, a finite element method computation program. Moreover, velocity-dependent gain-scheduling linear quadratic regulator (LQR) is applied. The experimental results demonstrate stabilized driving responses at 1.5 km/h, which is slower than a person's typical walking speed.

Published
2023

28. Online Activities in Tsukuba Challenge 2020

Author

HARA, Yoshitaka, primary, OKADA, Yoshito, additional, AKAI, Naoki, additional, YOKOZUKA, Masashi, additional, TOMIZAWA, Tetsuo, additional, DATE, Hisashi, additional, KURODA, Yoji, additional, and TSUBOUCHI, Takashi, additional

Published
2021
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38. Towards Predictive Driving through Blind Intersections

Author

Yuki Yoshihara, Hiroshi Murase, Luis Yoichi Morales, and Akai Naoki

Subjects
050210 logistics & transportation, 0209 industrial biotechnology, Computer science, business.industry, 05 social sciences, 02 engineering and technology, Function (mathematics), Machine learning, computer.software_genre, 020901 industrial engineering & automation, Hausdorff distance, 0502 economics and business, Trajectory, Feature (machine learning), State (computer science), Artificial intelligence, business, computer, Intersection (aeronautics)
Abstract

This paper presents an approach for predictive driving when facing blind intersections based on expert data. Expert drivers anticipate and avoid potential dangerous situations. In most cases these complex behaviors cannot be reproduced by state of the art planning approaches. We present an analysis of expert drivers while passing through blind intersections, we extract useful driving features to model the intersection and propose a cost function based on those features. We use inverse reinforcement learning to extract a feature-based cost function and learn its parameters from driver data. Finally, feature weights are computed based on collected expert driving data (using 211 trajectories). Evaluation was performed in terms of trajectory and speed using modified Hausdorff distance. Experimental results show that the planner is capable of computing trajectories comparable to those ones of the expert drivers when facing blind intersections.

Published
2018
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45. Low‐Speed Control Experiment of Motorcycles Using SPACAR Model.

Author

Hara, Susumu, Tsuchiya, Mitsuo, Kimura, Tetsuya, and Akai, Naoki

Subjects
MOTORCYCLING, WALKING speed, AUTONOMOUS vehicles, MOTORCYCLES, MOTOR vehicles, FINITE element method, ELECTRICAL engineers
Abstract

The main stream of development of autonomous driving technology (ADT) is for four‐wheel motor vehicles. ADT for motorcycles has received scant attention. The motorcycle stability tends to diminish when being driven at extremely low speed. This study addresses how a motorcycle should be stabilized under low‐speed driving. To obtain a linearized motorcycle model without skidding, we introduce a model based on SPACAR, a finite element method computation program. Moreover, velocity‐dependent gain‐scheduling linear quadratic regulator (LQR) is applied. The experimental results demonstrate stabilized driving responses at 1.5 km/h, which is slower than a person's typical walking speed. © 2021 Institute of Electrical Engineers of Japan. Published by Wiley Periodicals LLC. [ABSTRACT FROM AUTHOR]

Published
2022
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