Visual-Inertial Odometry on Chip: An Algorithm-and-Hardware Co-design Approach

Zhang, Zhengdong; Suleiman, Amr; Carlone, Luca; Sze, Vivienne; Karaman, Sertaç

doi:10.15607/rss.2017.xiii.028

Cited by 43 publications

(41 citation statements)

References 47 publications

(49 reference statements)

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“…• Persistent localization: While current VINS are able to provide accurate 3D motion tracking, but, in smallscale friendly environments, they are not robust enough for long-term, large-scale, safety-critical deployments, e.g., autonomous driving, in part due to resource constraints [95,97,164]. As such, it is demanding to enable persistent VINS even in challenging conditions (such as bad lighting and motions), e.g., by efficiently integrating loop closures or building and utilizing novel maps.…”

Section: Discussionmentioning

confidence: 99%

Visual-Inertial Navigation: A Concise Review

Huang

2019

2019 International Conference on Robotics and Automation (ICRA)

278

119

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As inertial and visual sensors are becoming ubiquitous, visual-inertial navigation systems (VINS) have prevailed in a wide range of applications from mobile augmented reality to aerial navigation to autonomous driving, in part because of the complementary sensing capabilities and the decreasing costs and size of the sensors. In this paper, we survey thoroughly the research efforts taken in this field and strive to provide a concise but complete review of the related work -which is unfortunately missing in the literature while being greatly demanded by researchers and engineers -in the hope to accelerate the VINS research and beyond in our society as a whole.where δq describes the small rotation that causes the true and estimated attitude to coincide. The advantage of this parametrization permits a minimal representation, 3 × 3 covariance matrix E I θ I θ T , for the attitude uncertainty.

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Section: Discussionmentioning

confidence: 99%

Visual-Inertial Navigation: A Concise Review

Huang

2019

2019 International Conference on Robotics and Automation (ICRA)

278

119

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“…For the design space of the "computation", we actually considered the joint selection of the computing board and the visual-inertial navigation (VIN) algorithm used for state estimation. Considering them as a single component has the advantage of allowing the use of statistics reported in other papers, e.g., stating that a VIN algorithm runs at a given framerate on a given computer [1]. Therefore our modules are M .…”

Section: A Autonomous Drone Co-designmentioning

confidence: 99%

“…Recent advances in sensor design and rapid prototyping are enabling the manufacturing of low-cost robots with advanced sensing and perception capabilities. For instance, one can implement high-precision visual-inertial navigation with inexpensive camera and MEMS inertial measurement units [1]. Similarly, modern embedded CPU-GPU [2] offer high-performance computing in a compact form-factor and at a relatively affordable cost.…”

Section: Introductionmentioning

confidence: 99%

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Robot Co-design: Beyond the Monotone Case

Carlone

Pinciroli

2019

2019 International Conference on Robotics and Automation (ICRA)

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Recent advances in 3D printing and manufacturing of miniaturized robotic hardware and computing are paving the way to build inexpensive and disposable robots. This will have a large impact on several applications including scientific discovery (e.g., hurricane monitoring), search-and-rescue (e.g., operation in confined spaces), and entertainment (e.g., nano drones). The need for inexpensive and task-specific robots clashes with the current practice, where human experts are in charge of designing hardware and software aspects of the robotic platform. This makes the robot design process expensive and time consuming, and ultimately unsuitable for small-volumes low-cost applications. This paper considers the computational robot codesign problem, which aims to create an automatic algorithm that selects the best robotic modules (sensing, actuation, computing) in order to maximize the performance on a task, while satisfying given specifications (e.g., maximum cost of the resulting design). We propose a binary optimization formulation of the co-design problem and show that such formulation generalizes previous work based on strong modeling assumptions. We show that the proposed formulation can solve relatively large co-design problems in seconds and with minimal human intervention. We demonstrate the proposed approach in two applications: the codesign of an autonomous drone racing platform and the co-design of a multi-robot system.

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“…1, right). Exploring the co-design space between VO (with inertial) algorithm and hardware illuminates parametric settings that improve VO output [11]. Building more efficient VO/VSLAM algorithms, in parallel with better hardware integration, is important to realizing the goal of accurate, low-latency VSLAM.…”

mentioning

confidence: 99%

Good Feature Matching: Toward Accurate, Robust VO/VSLAM With Low Latency

Zhao

Vela

2020

IEEE Trans. Robot.

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Analysis of state-of-the-art VO/VSLAM system exposes a gap in balancing performance (accuracy & robustness) and efficiency (latency). Feature-based systems exhibit good performance, yet have higher latency due to explicit data association; direct & semidirect systems have lower latency, but are inapplicable in some target scenarios or exhibit lower accuracy than feature-based ones. This paper aims to fill the performanceefficiency gap with an enhancement applied to feature-based VSLAM. We present good feature matching, an active map-toframe feature matching method. Feature matching effort is tied to submatrix selection, which has combinatorial time complexity and requires choosing a scoring metric. Via simulation, the Max-logDet matrix revealing metric is shown to perform best. For real-time applicability, the combination of deterministic selection and randomized acceleration is studied. The proposed algorithm is integrated into monocular & stereo feature-based VSLAM systems. Extensive evaluations on multiple benchmarks and compute hardware quantify the latency reduction and the accuracy & robustness preservation.Index Terms-visual odometry (VO), visual simultaneous localization and mapping (VSLAM), feature selection, active matching

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Visual-Inertial Odometry on Chip: An Algorithm-and-Hardware Co-design Approach

Cited by 43 publications

References 47 publications

Visual-Inertial Navigation: A Concise Review

Visual-Inertial Navigation: A Concise Review

Robot Co-design: Beyond the Monotone Case

Good Feature Matching: Toward Accurate, Robust VO/VSLAM With Low Latency

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