Large aperture at low cost three-dimensional time-of-flight range sensor using scanning micromirrors and synchronous detector switching

Bogatscher, Siegwart; Streck, Andreas; Fox, Maik; Meinzer, S.; Heussner, Nico; Stork, Wilhelm

doi:10.1364/ao.53.001570

Cited by 8 publications

(6 citation statements)

References 25 publications

(29 reference statements)

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“…There are several types of motorized optomechanical scanners. The most common one is built with multiple channels of transmitters and receivers stacked vertically and rotated by a motor to generate a full 360 • FoV with multiple horizontal lines (Figure 2c) [27]. The signals and power may have to be wirelessly transmitted from the rotating part to the base board [25].…”

Section: Motorized Optomechanical Scanning Lidarmentioning

confidence: 99%

“…The signals and power may have to be wirelessly transmitted from the rotating part to the base board [25]. Such LiDAR are not power-efficient and are vulnerable to mechanical shock and wear [27]. In addition, their vertical resolution is fixed and dependent on the number of transmitter and receiver channels, so a high vertical resolution is always at the price of high cost.…”

Section: Motorized Optomechanical Scanning Lidarmentioning

confidence: 99%

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MEMS Mirrors for LiDAR: A Review

2020

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In recent years, Light Detection and Ranging (LiDAR) has been drawing extensive attention both in academia and industry because of the increasing demand for autonomous vehicles. LiDAR is believed to be the crucial sensor for autonomous driving and flying, as it can provide high-density point clouds with accurate three-dimensional information. This review presents an extensive overview of Microelectronechanical Systems (MEMS) scanning mirrors specifically for applications in LiDAR systems. MEMS mirror-based laser scanners have unrivalled advantages in terms of size, speed and cost over other types of laser scanners, making them ideal for LiDAR in a wide range of applications. A figure of merit (FoM) is defined for MEMS mirrors in LiDAR scanners in terms of aperture size, field of view (FoV) and resonant frequency. Various MEMS mirrors based on different actuation mechanisms are compared using the FoM. Finally, a preliminary assessment of off-the-shelf MEMS scanned LiDAR systems is given.

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Section: Motorized Optomechanical Scanning Lidarmentioning

confidence: 99%

Section: Motorized Optomechanical Scanning Lidarmentioning

confidence: 99%

MEMS Mirrors for LiDAR: A Review

2020

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“…Mechanical LiDAR is one of the most common types of LiDAR, and has the characteristics of remote detection and large FOV [18,19]. However, such types of LiDAR are bulky, power-hungry, and vulnerable to mechanical shock [20]. Although many miniaturization efforts have been reported, it is still difficult to meet the requirements of robotic mobile platforms [11].…”

Section: Mems-opamentioning

confidence: 99%

All-Solid-State Beam Steering via Integrated Optical Phased Array Technology

2022

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Light detection and ranging (LiDAR), combining traditional radar technology with modern laser technology, has much potential for applications in navigation, mapping, and so on. Benefiting from the superior performance, an all-solid-state beam steering realized by integrated optical phased array (OPA) is one of the key components in the LiDAR system. In this review, we first introduce the basic principle of OPA for beam steering. Then, we briefly review the detailed advances of different solutions such as micro-electromechanical system OPA, liquid crystal OPA, and metasurface OPA, where our main focus was on the recent progress of OPA in photonic integrated chips. Finally, we summarize the different solutions and discuss the challenges and perspectives of all-solid-state beam steering for LiDAR.

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“…Thus the motorized optomechanical LiDAR sensors can have a horizontal field of view up to 360° [4,5]. Because of the mechanical movable part, this sensor type is vulnerable to mechanical shock and wear [7]. Besides the motorized optomechanical LiDAR sensors, there are also the solid-state LiDARs, which do not have any movable parts.…”

Section: Introductionmentioning

confidence: 99%

Generation of synthetic Point Clouds for MEMS LiDAR Sensor

Berens¹,

Reischl²,

Elser³

2022

Preprint

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Sensory data is essential for the training of methods in autonomous driving like object detection, odometry, or SLAM. MEMS LiDAR sensors can be very valuable for autonomous vehicles because they are less prone to shock and wear compared to motorized optomechanical LiDAR sensors. Recording real-world data is complicated and expensive. An alternative is simulated data, but for MEMS LiDAR sensors there is no publicly available software to simulate this type of sensor. With this paper, we introduce a method to simulate data recorded by a MEMS LiDAR sensor like the Blickfeld Cube~1 (and other MEMS LiDAR sensors as well). For this, we use the open-source autonomous driving simulation environment CARLA (our method is available online\footnote[1]{https://github.com/BerensRWU/MEMS-LiDAR-Generator}). We compare our synthetic point cloud with a real-world point cloud and evaluate the similarity. Moreover, we demonstrate the application of our method on the problem of the optimal sensor configuration.

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Large aperture at low cost three-dimensional time-of-flight range sensor using scanning micromirrors and synchronous detector switching

Cited by 8 publications

References 25 publications

MEMS Mirrors for LiDAR: A Review

MEMS Mirrors for LiDAR: A Review

All-Solid-State Beam Steering via Integrated Optical Phased Array Technology

Generation of synthetic Point Clouds for MEMS LiDAR Sensor

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