Lasers and LIDAR
RPMC has many years of experience supplying LIDAR laser sources
Key Laser Source Specifications for Various Types of LIDAR
LIDAR lasers are available in a vast range of configurations, tailored for different sets of end-use applications. The main determining factor for which type of LIDAR laser you need depends on whether your application is measuring a moving or stationary target.
Stationary LIDAR / 3D Scanning Target:
- Short pulses (few nanoseconds down to the picosecond range)
- High pulse energy
- Excellent beam quality
- ‘Eye-safe’ wavelengths recommended
Moving LIDAR Target – Measuring Speed:
- Short pulses (few nanoseconds down to the picosecond range)
- High pulse energy
- Excellent beam quality
- Frequency modulation
- Single-frequency (narrow linewidth)
- ‘Eye-safe’ wavelengths recommended
Bathymetric LIDAR (Bathymetry):
- Short pulses (few nanoseconds down to the picosecond range)
- High pulse energy
- Excellent beam quality
- Single-frequency (narrow linewidth)
- ≈ 440 nm for clean water / ≈ 532 for dirty water
- ≈ 1064 nm for measuring to surface of water
LIDAR Pain Points
Depending on the type of LIDAR system employed, there are some known challenges involved:
Segregation and exclusion of reflected signal from the source beam – The radiance of the source beam is typically much higher than that of any return beam or signal. It is critical to mitigate any reflected or scattered beam from re-entering the receiver, which may saturate the detector, rendering it unable to properly detect external targets.
False signal returns from atmospheric debris and particles between the transmitter and targets of interest – These ‘contaminants’ can cause false signals to be detected by the receiver and cause noise or false readings rather than properly detecting your targets.
Limited optical power – While they tend to come at a higher price point, a laser source which provides a higher output power can provide higher accuracy when collecting data from the target.
Scanning speed – Safety is always a critical factor when working with lasers, and especially with applications like LIDAR, where other people are more likely to come into contact with the beam, as opposed to a laboratory application. Even moreso, working with a wavelength outside the ‘eye-safe’ region (≈ 1.5 µm or ≈ 1540 nm) increases risk. Newer methods, such as flash LIDAR, which illuminates a larger area at once (typiclly using ‘eye-safe’ wavelengths) help to mitigate risk.
Noise / interference – When there are multiple LIDAR devices in an area, there is an increased chance that the receiver detects signals from on of the other devices. This can be a major problem for automotive LIDAR, for example. Some solutions to this problem are being tested, such as signal chirping and isolation, in an effort to differentiate the various signals.
Price point and required maintenance – LIDAR systems have traditionally been very expensive, and can require maintenance to continually achieve the same performance. However, newer technological developments, miniturization, and ruggedization have led to smaller, cheaper, and more robust devices, requiring less maintenance.
Let Us Help
If you have any questions, or if you would like some assistance please Contact Us here. Furthermore, you can email us at info@rpmcdev.maxdroplet4.maxburst.dev to talk to a knowledgeable Product Manager.
Alternatively, use the filters on this page to assist in narrowing down the selection of LIDAR lasers for sale. Finally, head to our Knowledge Center with our Lasers 101 page and Blogs, Whitepapers, and FAQ pages for further, in-depth reading.
Finally, check out our Limited Supply – In Stock – Buy Now page: This page contains an ever-changing assortment of various types of new lasers at marked-down/discount prices.
Additional Resources
Blogs:
Whitepapers: