As the "eyes of machines," LiDAR has gained enormous attention with the rapid rise of autonomous driving and robotics. It is a sensor used to obtain precise positional information, capable of determining an object’s location, size, orientation, and more. Compared with other types of sensors, LiDAR excels in measurement accuracy and human detection, making it a cornerstone of robotic perception systems.
At the same time, millimeter-wave radar (mmWave) has not been abandoned in fields such as autonomous driving. What advantages allow mmWave radar to compete with LiDAR? Let’s explore their respective characteristics and differences.
Millimeter-Wave Radar
Millimeter-wave radar operates in the mmWave frequency band (10–200 GHz), between radio waves and infrared light. It can measure an object’s relative distance, speed, and azimuth.
Originally applied in the military, advances in radar technology have brought mmWave radar into widespread use in autonomous vehicles, drones, and intelligent transportation. Its biggest advantage lies in its all-weather capability: it can penetrate dust, fog, rain, and snow without being affected by adverse conditions, making it highly reliable for outdoor applications.
However, mmWave radar has an inherent weakness in resolution. Radar relies on transmitted pulses and their echoes to acquire information; the higher the frequency, the greater the resolution. In this respect, mmWave radar falls short of LiDAR.
Lidar
LiDAR works by emitting laser beams toward a target and comparing the reflected signals with the original transmissions. After processing, the system can derive parameters such as distance, azimuth, altitude, speed, orientation, and even shape. Because it enables 3D environmental perception, LiDAR is particularly favored in the autonomous driving field.
Key Differences Between LiDAR and mmWave Radar
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Operating principle: Both are echo-based detection systems. The difference lies in emission: LiDAR emits linear laser beams (photons), while mmWave radar emits a cone-shaped electromagnetic beam.
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Precision and range: LiDAR offers higher detection accuracy, broader coverage, and stable modeling capabilities, directly generating detailed 3D maps of surroundings. In contrast, mmWave radar’s range is limited by frequency-band attenuation, and it cannot model obstacles or detect pedestrians with high precision.
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Resistance to interference: LiDAR is highly sensitive to environmental factors. When beams are blocked, it fails to operate properly, making it unreliable in rain, snow, fog, or dust storms. mmWave radar, however, penetrates such conditions easily, maintaining stable performance.
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Processing requirements: LiDAR produces a far larger volume of data compared with mmWave radar, requiring more powerful processors to handle it—thus driving up system costs.
Both LiDAR and mmWave radar have unique strengths and cannot fully replace one another.
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Autonomous driving: LiDAR is favored for its accuracy in distance measurement and obstacle recognition, but high costs remain a barrier to widespread deployment.
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Service robotics: LiDAR adoption has been faster here, as performance requirements are lower and cost pressures less severe. SLAMTEC’s LiDAR, combined with its proprietary SLAM technology, has already been widely deployed in service robots across restaurants, shopping malls, banks, and hospitals, enabling autonomous localization, mapping, and path planning.
Overall, LiDAR and mmWave radar each have strengths and weaknesses, making them complementary rather than mutually exclusive.
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In the autonomous driving sector, LiDAR is preferred for its accuracy in ranging and obstacle detection, but its high cost remains a barrier to widespread adoption.
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In the service robotics sector, LiDAR adoption has been faster. With lower performance requirements and reduced cost constraints, LiDAR (such as SLAMTEC’s RPLIDAR) has been widely deployed in restaurants, shopping malls, banks, hospitals, and other service venues. Combined with SLAMTEC’s proprietary SLAM navigation technology, LiDAR enables robots to achieve autonomous localization, mapping, and path planning.
Characteristics and Differences Between LiDAR and Millimeter-Wave Radar
Characteristics and Differences Between LiDAR and Millimeter-Wave Radar
