An FPGA Acceleration and Optimization Techniques for 2D LiDAR SLAM Algorithm

Sugiura, Keisuke; Matsutani, Hiroki

doi:10.1587/transinf.2020edp7174

Cited by 10 publications

(5 citation statements)

References 21 publications

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“…unless a good starting point is given, our previous accelerator only works in the frontend scan matching, where the initial guess is close to the globally optimal pose. In contrast, CSM core can handle backend loop detections with large initial errors as well as the frontend scan matching, which emphasizes the advantages of our proposal over [67] on both robustness and versatility. Our CSM core is able to produce results with the same quality as [66] using only one third the number of particles (50 and 16).…”

Section: Tablementioning

confidence: 99%

“…We also quote the results from various studies along with the execution environment, i.e., our previous work [67], GMapping with 50 particles [66], Google Cartographer [8], and Random Normal Matching [68], in Table 2. CSM core offers better accuracy than our previous work [67], where an FPGA-based accelerator for hill-climbing based scan matching is proposed and integrated to GMapping algorithm. Since hill-climbing method does not converge to a correct solution trans , and ε 2 rot are the accuracy metrics defined in Equations 10 and 11.…”

Section: E Accuracymentioning

confidence: 99%

“…Comparison of the trajectory errors between PF-SLAM with the proposed FPGA accelerator (16 particles) and other recent works, i.e., GMapping with FPGA accelerator for hill-climbing based scan matching (32 particles) [67], GMapping (50 particles) [66], Google Cartographer [8], and Random Normal Matching [68].…”

Section: Tablementioning

confidence: 99%

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A Universal LiDAR SLAM Accelerator System on Low-Cost FPGA

Sugiura

Matsutani

2022

IEEE Access

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LiDAR (Light Detection and Ranging) SLAM (Simultaneous Localization and Mapping) serves as a basis for indoor cleaning, navigation, and many other useful applications in both industry and household. From a series of LiDAR scans, it constructs an accurate, globally consistent model of the environment and estimates a robot position inside it. SLAM is inherently computationally intensive; it is a challenging problem to realize a fast and reliable SLAM system on mobile robots with a limited processing capability. To overcome such hurdles, in this paper, we propose a universal, low-power, and resource-efficient accelerator design for 2D LiDAR SLAM targeting resource-limited FPGAs. As scan matching is at the heart of SLAM, the proposed accelerator consists of dedicated scan matching cores on the programmable logic part, and provides software interfaces to facilitate the use. Our accelerator can be integrated to various SLAM methods including the ROS (Robot Operating System)-based ones, and users can switch to a different method without modifying and re-synthesizing the logic part. We integrate the accelerator into three widelyused methods, i.e., scan matching, particle filter, and graph-based SLAM. We evaluate the design in terms of resource utilization, speed, and quality of output results using real-world datasets. Experiment results on a Pynq-Z2 board demonstrate that our design accelerates scan matching and loop-closure detection tasks by up to 14.84x and 18.92x, yielding 4.67x, 4.00x, and 4.06x overall performance improvement in the above methods, respectively. Our design enables the real-time performance while consuming only 2.4W and maintaining accuracy, which is comparable to the software counterparts and even the state-of-the-art methods.INDEX TERMS SLAM, scan matching, FPGA.

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Section: Tablementioning

confidence: 99%

Section: E Accuracymentioning

confidence: 99%

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A Universal LiDAR SLAM Accelerator System on Low-Cost FPGA

Sugiura

Matsutani

2022

IEEE Access

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“…5 shows the visual description of a nine-square grid centered on the hit point, and neighboring unhit points are mainly utilized for the search box size when computing the score for the most likely laser beam strike in a kernel window. Parameters of Angle and linear displacement step increment size (lstep and astep) assumed the initial step size of the optimization step in the Hill-Climbing algorithm during the scan matching algorithm [28]. The Iterations parameter is the number of times the search step size changes during the optimization method in the scan matching algorithm.…”

Section: Initialization Parameters Classificationmentioning

confidence: 99%

An Extensive Analysis and Fine-Tuning of Gmapping’s Initialization Parameters

2023

IJIES

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Accurate localization and mapping are essential for autonomous navigation systems. The simultaneous localization and mapping (SLAM) algorithm, gmapping, is widely used for creating two-dimensional occupancy grid maps (2D-OGMs) due to its low cost and effectiveness in indoor environments. According to the SLAM interaction between localization and mapping terms, the evaluation of map accuracy implicitly means the evaluation of localization. This study focuses on improving the accuracy of the estimated 2D-OGMs by fine-tuning the 32 initialization parameters of gmapping using a turtlebot3-burger robot. An improved experimental procedure was developed, incorporating image registration and similarity measurement to evaluate the map accuracy. The results show a substantial improvement in map accuracy, from 78.84% to 94.18%. The study highlights the importance of fine-tuning the SLAM algorithm for improved map accuracy and provides valuable insights for developing autonomous navigation systems. The key contribution of this paper lies in the systematic classification, fine-tuning, and evaluation of the Gmapping initialization parameters.

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“…K. Sugiura and H. Matsutani present an efficient hardware implementation for Simultaneous Localization and Mapping (SLAM) methods [17], sustaining a relatively small number of particles, despite a very efficient data compression strategy. The speed up the process of matching scanning on the FPGA in 2D LiDAR SLAM method called GMapping is based on the Rao-Blackwellized Particle Filter algorithm.…”

Section: Related Workmentioning

confidence: 99%

An FPGA Overlay for Efficient Real-Time Localization in 1/10th Scale Autonomous Vehicles

Bernardi

Brilli

Capotondi

et al. 2022

2022 Design, Automation &Amp; Test in Europe Conference &Amp; Exhibition (DATE)

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Heterogeneous systems-on-chip (HeSoC) based on reconfigurable accelerators, such as Field-Programmable Gate Arrays (FPGA), represent an appealing option to deliver the performance/Watt required by the advanced perception and localization tasks employed in the design of Autonomous Vehicles. Different from software-programmed GPUs, FPGA development involves significant hardware design effort, which in the context of HeSoCs is further complicated by the system-level integration of HW and SW blocks. High-Level Synthesis is increasingly being adopted to ease hardware IP design, allowing engineers to quickly prototype their solutions. However, automated tools still lack the required maturity to efficiently build the complex hardware/software interaction between the host CPU and the FPGA accelerator(s). In this paper we present a fully integrated system design where a particle filter for LiDAR-based localization is efficiently deployed as FPGA logic, while the rest of the compute pipeline executes on programmable cores. This design constitutes the heart of a fully-functional 1/10th-scale racing autonomous car. In our design, accelerated IPs are controlled locally to the FPGA via a proxy core. Communication between the two and with the host CPU happens via shared memory banks also implemented as FPGA IPs. This allows for a scalable and easy-to-deploy solution both from the hardware and software viewpoint, while providing better performance and energy efficiency compared to state-ofthe-art solutions.

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An FPGA Acceleration and Optimization Techniques for 2D LiDAR SLAM Algorithm

Cited by 10 publications

References 21 publications

A Universal LiDAR SLAM Accelerator System on Low-Cost FPGA

A Universal LiDAR SLAM Accelerator System on Low-Cost FPGA

An Extensive Analysis and Fine-Tuning of Gmapping’s Initialization Parameters

An FPGA Overlay for Efficient Real-Time Localization in 1/10th Scale Autonomous Vehicles

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