Continuous Wave Laser Source for Injection Seeding
instrumentation
Continuous Wave Laser Source for Injection Seeding (LAR-TOPS-331)
Precise, Fast Tuning, Frequency Agile, Offset Wavelength Control
Overview
Innovators at the NASA Langley Research Center have developed a new technique for generating a continuous wave (CW) laser source with agile wavelength switching capabilities that is suitable for injection seeding high-energy pulsed lasers. Laser output radiation spectral linewidth control is an essential feature for scientific applications, such as atmospheric active remote sensing. Generally, high energy lasers do not readily produce spectrally narrow linewidth output. In order to achieve a high energy output radiation that matches the spectroscopic features of desired measurement objectives, this CW laser source was developed to injection seed and control the wavelength of a high energy laser. NASA's CW laser source can provide multiple wavelengths suitable for single and multi-pulsed lasers using a low-power radiation source. This results in a compact, lightweight, and low power consumption injection seeder that is suitable for airborne and space-borne applications including, but not limited to Lidar applications, atmospheric observation instruments, and optical signal generators.
The Technology
NASA's CW Laser Source for Injection Seeding uses a single laser diode (LD) to produce multiple wavelengths. Depending on the application, the seed laser may or may not be locked to a wavelength reference. For example, in atmospheric differential absorption lidar (DIAL) active remote sensing applications, the seed laser has to be locked and referenced to the species of interest using gas cells. In this context, the seed laser source is first locked to an absorption feature and the generated wavelength is used as a reference from which other offset wavelengths are generated. However, if the requirement calls only to avoid atmospheric absorption then locking may not be required.
Using this new technology, an airborne 2-micron triple pulse integrated path differential absorption (IPDA) LIDAR instrument has been developed at NASA Langley Research Center to measure the column content of atmospheric H2O and CO2 simultaneously and independently. This is achieved by transmitting three successive high-energy pulses, seeded at three different wavelengths, through the atmosphere. The three pulses are emitted 200 microseconds apart and repeated at 50 Hz. The seeding wavelengths were selected to achieve minimum measurement interference from one molecule to the other. Typically, this requires four different CW lasers for seeding. A part of that effort focused on adaptive targeting, which is based on the tuning capability of the on-line wavelength to meet a certain measurement objective depending on observational time and location. The off-line wavelength was assumed constant. The tuning capability can be achieved using the claimed seeding technique using a voltage-controlled oscillator for the on-line and fixed oscillator for the off-line.
Benefits
- Increased reliability compared to competing systems: existing systems rely on optical switching and are incapable of operation at high frequencies while providing a consistent, reliable, spectrally pure wavelength like NASA's technology (the RF switches work at GHz rates)
- Requires only one seed laser for multiple frequencies: the CW laser source can operate across up to four frequencies with narrow bandwidth within 200 microseconds using a single laser, saving on size, complexity, and system costs
- Lower power requirements: the system does not require high power, only needing 0.5 to 1 watt at most
- Flight proven technology: this seed laser has flown successfully in an aircraft
Applications
- Aerospace: Lidar for spacecraft navigation
- Automotive: Lidar for autonomous vehicles
- Communications: optical signal generator for discrete and precise frequencies
- Environmental monitoring: atmospheric observation instruments that require precise laser frequencies and terrestrial (geology, seismology, forestry) mapping
- Marine: oceanic mapping applications
- Remote sensing: Lidar applications requiring multiple narrow linewidth lasers with rapid switching
Technology Details
instrumentation
LAR-TOPS-331
LAR-19257-1
"Wavelength Locking to CO2 Absorption Line-Center for 2-Micron Pulsed IPDA Lidar Application," Refaat, Tamer F. et al., April 04, 2016,
https://ntrs.nasa.gov/search.jsp?R=20160009160
"Evaluation of 2-µm Pulsed Integrated Path Differential Absorption Lidar for Carbon Dioxide Measurement - Technology Developments, Measurements, and Path to Space," Singh, Upendra N. et al., January 23, 2018, https://ntrs.nasa.gov/search.jsp?R=20190026469.
https://ntrs.nasa.gov/search.jsp?R=20160009160
"Evaluation of 2-µm Pulsed Integrated Path Differential Absorption Lidar for Carbon Dioxide Measurement - Technology Developments, Measurements, and Path to Space," Singh, Upendra N. et al., January 23, 2018, https://ntrs.nasa.gov/search.jsp?R=20190026469.
Similar Results
Pulsed 2-Micron Laser Transmitter
The new NASA LaRC Pulsed 2-Micron Laser Transmitter for Coherent 3-D Doppler Wind Lidar Systems is an innovative concept and architecture based on a Tm:Fiber laser end-pumped Ho:YAG laser transmitter. This transmitter meets the requirements for space-based coherent Doppler wind lidar while reducing the mission failure risks. A key advantage of this YAG based transmitter technology includes the fact that the design is based on mature and low-risk space-qualified YAG host crystal. The transmitter operates at a 2096 nm wavelength using Ho:YAG, resulting in high atmospheric transmission (>99%), versus a transmitter operating at 2053 nm using co- doped Tm:Ho:LuLiF, which suffers limited transmission (90%) due to water vapor interference. In-band pumping through Tm:Fiber pump Ho:YAG architecture offers lower quantum defect from 1908 to 2096 nm (9.1%) compared to traditionally used co-doped Tm:Ho:LuLiF of 792 to 2051 nm (61%). The transmitter has an efficient pump compared to LuLF, since YAG has 27% higher pump absorption and 52% lower reabsorption of the emitted 2-micron, resulting in higher efficiency and lower heat load. Being isotropic, YAG is amenable for spatial-hole burning mitigation which supports linear cavity architecture without compromising injection seeding quality. This attribute is important in designing a compact, stable, high seeding efficiency laser. A folded linear cavity for long pulse (>200 ns), transform limited line-width (2.2 MHz) and high beam quality (M2 = 1.04) - the most critical parameters for coherent detection - are easier to achieve using YAG compared to LuLF. Lower heat load results in high repetition rate (>300 Hz) operation, which allows higher probability of wind measurements through broken clouds, off clouds, and below clouds, thus reducing errors and increasing science data product quantity and quality.
Receiver for Long-distance, Low-backscatter LiDAR
The NASA receiver is specifically designed for use in coherent LiDAR systems that leverage high-energy (i.e., > 1mJ) fiber laser transmitters. Within the receiver, an outgoing laser pulse from the high-energy laser transmitter is precisely manipulated using robust dielectric and coated optics including mirrors, waveplates, a beamsplitter, and a beam expander. These components appropriately condition and direct the high-energy light out of the instrument to the atmosphere for measurement. Lower energy atmospheric backscatter that returns to the system is captured, manipulated, and directed using several of the previously noted high-energy compatible bulk optics. The beam splitter redirects the return signal to mirrors and a waveplate ahead of a mode-matching component that couples the signal to a fiber optic cable that is routed to a 50/50 coupler photodetector. The receiver’s hybrid optic design capitalizes on the advantages of both high-energy bulk optics and fiber optics, resulting in order-of-magnitude enhancement in performance, enhanced functionality, and increased flexibility that make it ideal for long-distance or low-backscatter LiDAR applications.
The related patent is now available to license. Please note that NASA does not manufacturer products itself for commercial sale.
Laser Linear Frequency Modulation System
For decades, frequency modulation has been used to generate chirps, the signals produced and interpreted by sonar and radar systems. Traditionally, a radio or microwave signal is transmitted toward the target and reflected back to a detector, which records the time elapsed and calculates the targets distance. Reflected signals can be heterodyned (combined) with output signals to determine the Doppler frequency shift and the target velocity. Accuracy of these systems can be enhanced by increasing the bandwidth of the chirp, but noise generated during heterodyning at high frequencies decreases the signal-to-noise ratio, increasing measurement error.
Previous attempts at laser frequency modulation that relied on adjusting the laser cavity length have resulted in only sine wave or imperfect triangle waveforms. Heterodyning of imperfect, non-linear waveforms or sine waveforms will significantly degrade the effective signal-to-noise ratio, making such systems impractical. In contrast, the current technology produces a single, high-frequency laser that is passed to an electro-optical modulator, which generates a series of harmonics. This range of frequencies is then passed through a band-pass optical filter so the desired harmonic frequency can be
isolated and directed toward the target. By modulating the electrical signal applied to the electro-optical modulator, a near perfect triangular waveform laser beam can be produced. Transmission and detection of this highly linear triangular waveform facilitates optical heterodyning for the calculation of precise frequency and phase shifts between the output and reflected signals with a high signal-to-noise ratio. By combining this information with the time elapsed, the location and velocity of the target can be determined to within 1 mm or 1 mm/s.
Recirculating Advanced Coupled-cavity Etalon Receiver (RACER)
Advanced Coupled-cavity Etalon (ACE) significantly improves both in-band transmission and out-of-band rejection. In some cases, 12% more light is transmitted inside the passband and >3x more light is rejected outside the passband. Incorporating ACE into the recirculating etalon receiver (RER) improves performance significantly. ACE increases the wavelength resolution and enables closer channel spacing resulting in a very efficient, high resolution spectrometer. RACER has both high resolution and a high photon efficiency which allows flexibility for trading different combinations of reduced cross-talk and closer channel spacing.
Self-Phase-Locked Distributed Gain Laser Architecture
NASA Goddard Space Flight Center has developed a laser architecture to coherently combine energy from spatially distributed gain sources. Using a combination of lenslet arrays (to split and combine separate beams) or diffractive optical elements, each source can be phase-matched into an effective single source.