High-Power, Multi-Channel Laser for LiDAR Systems


High Power, LIDAR, Optoelectronics

@GaNSystems @OSRAMAmericas #lidar #laserdriver #psd


Osram Opto Semiconductors announced an ultrafast laser driver with a high-power, multi-channel Surface Mount (SMT) laser for LiDAR (Light detection and ranging) systems. Osram, the leader in LiDAR lasers, and GaN Systems, the leader in GaN power semiconductors, partnered to develop the breakthrough in laser driver technology that enables longer range and higher resolution LiDAR architectures.

Osram has continuously expanded its laser portfolio for LiDAR to accommodate the needs of customers, including increasing the peak power of the SPL DS90A_3 to 120 W at 40 A. In addition, Osram plans to release a four-channel SMT laser in 2019. The additional channels increase the field of view and total peak power, with each channel being capable of generating 120 W. 

One of the issues with LiDAR technology has been its inability to transmit lasers at short pulses, while maintaining high peak power, which is necessary to ensure that the LiDAR is eye safe with a long range and high resolution. To address this need, Osram worked with GaN Systems to develop a laser driver with a one nanosecond pulse rise time, while driving all four channels at 40 A each to deliver 480 W peak power. This peak power then can be modulated at low-duty cycles to produce high resolution 3D cloud points at long range for new LiDAR designs.

Scanning LiDAR is a key technology for Advanced Driver-Assistance Systems (ADAS), which is designed to increase road safety and enable autonomous driving. These electronic devices react instantly to potential collisions without wasting precious seconds of reaction time. Scanning LiDAR creates high-resolution 3D images of a car’s surroundings and registers obstacles early enough for ADAS or self-driving cars to initiate the appropriate driving maneuvers, such as automatic braking to prevent collisions.




GaN Systems


Related articles

 800V Bus Converter Module Features 97% Peak Efficiency
 Clean Energy Through Photocatalyst Optimization
 'Hot Spots' Increase Efficiency of Solar Desalination