Range (80% Lambertian reflectivity, 1024 @ 10 Hz mode) | 75 m @ 100 klx sunlight, >90% detection probability |
Range (10% Lambertian reflectivity, 1024 @ 10 Hz mode) | 35 m @ 100 klx sunlight, >90% detection probability |
Minimum Range | 0.0 m (0.3 m optional, and 0.5 m default) |
Vertical Resolution | 32, 64, or 128 channels |
Horizontal Resolution | 512, 1024, or 2048 (configurable) |
Rotation Rate | 10 or 20 Hz (configurable) |
Field of View | Vertical: 90.8° ± 1.0° (+45.4° to -45.4°) Horizontal: 360° |
Angular Sampling Accuracy | Vertical: ±0.01° / Horizontal: ±0.01° |
False Positive Rate | 1/10,000 |
Range Resolution | 0.1 cm |
# of Returns | up to 2 |
Return Order | Strongest to Weakest, Farthest to Nearest, and Nearest to Farthest |
OUSTER OS0
Sku:
Ultra-wide 90° field of view short-range digital lidar sensor.
OUSTER OS0
Powered by the L3 chip and engineered to provide superior object classification and mapping capabilities, the OS0 excels at 3D scanning near-range distances within dense, cluttered environments.
ESSENTIAL FEATURES OS0: |
|
35m Range at 10% |
100m Max Range |
90º Vertical Field of View |
128 Channels of Resolution |
5,2M Max Points Per Second |
20 Hz Max Frame Rate |
-40°C Min. Operating Temperature |
60°C Max. Operating Tempture |
IP68 e IP69K Ingress protection |
Powered by sensor L3
New L3 sensor with 21.47 Gmac of signal processing and 125 million transistors on chip enables 5.2 million maximum points per second. High-precision 3D scanning for sharp focus on even the smallest details.
Integrated SLAM technology, this is a mapping method that uses lidar to simultaneously locate an object and create a map of its environment.
Ouster places the greatest emphasis on quality and reliability testing. Over the past year, the company has subjected OS0 to a series of rigorous tests under a variety of conditions as part of a structured process designed to ensure product quality and reliability.
The boundary between lidar sensor and camera becomes blurred.
The OS sensor's optical system has a larger aperture than most DSLRs, and the photon-counting ASIC we developed has enough low-light sensitivity to enable us to collect environmental images even in low-light conditions.