LiDAR-based T&M technology can research Earth's atmosphere in broad daylight

12 December 2018

The Leibniz Institute for Atmospheric Physics (IAP) have solved this problem, by developing the world’s only portable instrument that can be used during the daytime, and it has already provided new insights into Antarctic atmospheric conditions.

Atmospheric research uses pulsed laser beams to measure temperature and wind speed along the beams by measuring the Doppler shifted and backscattered light at 100 km height in the atmosphere. However, in traditional laser-based atmosphere-monitoring technology, returning light signals are very weak and can be blocked by sunlight.

Now, the IAP's new generation of compact and reliable systems uses a novel, diode-pumped laser and, at its heart, are a spectrum instrumentation arbitrary waveform generator (AWG) and two digitisers that provide the extremely high-speed, sensitivity and real-time capability required.

The measuring technique is called Doppler resonance LiDAR as the light is backscattered by tuning the laser precisely to a resonance transition of a metal atom. The backscattered signals are extremely weak (single photons per laser pulse) and are almost completely drowned out by solar radiation during the day. The difference between night and day measurements is that there is 100,000,000 times more background noise during the day from the sun.

Understanding temperature distributions in the atmosphere at altitudes between 80 and 110 km, called the MLT (mesosphere and lower thermosphere), is crucial for performing numerical simulations of the Earth’s climate.

One well-established approach to provide such data is to measure the Doppler broadened line width of metal atoms: consider, for instance, the potassium resonance line at 770 nm and the iron resonance line at 372 nm or 386 nm, by means of resonance LiDAR systems through pulsed lasers.

Until now, these lasers have used flashlamp-pumps, but this project is the first to develop a novel laser system using a highly efficient, tunable, diode-pumped, alexandrite laser that is better able to cope with rough environmental conditions such as on research ships or in polar regions.

With such technology, a concentration of about one atom per cubic centimetre is sufficient for temperature and wind measurements at a height of 100 km, which is an altitude where the atmospheric pressure is so low than only rockets can access it.

Said the project lead, Dr. Josef Höffner: “The aim of the project is to create compact mobile measurement systems that we can take around the world. Such systems require automatic operation under extreme environment conditions like [that of] Antarctica, without access to them for long periods of times.

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“We therefore need components that are very robust and reliable as well as being able to provide the levels of sensitivity, speed and flexibility required under these challenging conditions. Spectrum’s five-year warranty gives us peace of mind that these critical items can be relied on.”

There are several aspects to improving the measurements in this project. The first is the suppressing of background noise by having an extremely small field of view for high resolution, optical filtering and small field of views. This means that the laser has to be stabilised in the field of view as well as all filters. The laser itself require a complex and fast real-time stabilisation system with nanosecond timing. This is controlled by the Spectrum M2i.6012 20 MS/s AWG and fires at 500 pulses a second for 24 hours a day.

The signals from the backscattered light are processed by the Spectrum M4i.4421 250 MS/s 16 bit digitiser. The conditions within the laser are measured with a M4i.2221 2.5 GS/s 8 bit digitiser cardm and the system itself handles more than 1 GByte/sec for 24 hours a day – with a response time of about 1 ms, after processing the measured data in real time. In total, 21 signals are managed by a software package developed at the IAP.

Continued Dr. Höffner: “We have achieved a compact, highly-integrated solution by combining fast, flexible electronics with real-time capability, which is an impressive improvement compared to the previous, large and difficult-to-handle solutions that were many times bigger.

“Our old system needed a 10-tonne, 6m container and this has been shrunk to a 1500 kg system that uses the Spectrum cards and a novel laser. We have nearly finished shrinking this even further to fit into a one-metre cubed box of only 250 kg, which will use the same electronics and a more compact and advanced laser.”

The sensitivity and portability of this new, highly compact device is enabling new temperature data to be obtained with unprecedented resolution and accuracy in remote places. As Dr. Höffner concludes: “Our measurements have already had a big impact on our understanding of the atmosphere and, what’s really exciting, is that we have proven that we can design a system that is reliable, lightweight, compact and efficient enough for future space missions.”

Dr. Höffner presented the latest results from this project at the International Conference on Space Optics, which was held on the 9th to 12th October in Chania, Greece. His paper will be uploaded to the conference website in early 2019, at www.atpi.eventsair.com/QuickEventWebsitePortal/icso-2018/icso; and further details on the work of the IAP can be found at: www.iap-kborn.de/en/home.


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