Aircraft Lasercom Terminal Compact Optical Module (ALT-COM) Bradley Scoville - ECE Steven Rose Physics Worcester Polytechnic Institute Major Qualifying Project WPI-MITLL MPQ Presentation (1) Advanced Lasercom Systems and Operations Group 66 This work was sponsored by the Department of the Air Force under Air Force Contract FA8721-05-C-0002. Opinions, interpretations, conclusions, and recommendations are those of the author and are not necessarily endorsed by the United States Government.
Acknowledgements We would like to express our gratitude to the following individuals: Dr. Jeffrey Roth Professor Germano Iannacchione Professor William Michalson Robert Murphy Timothy Williams Dr. William Wilcox WPI-MITLL MPQ Presentation (2)
Outline Introduction to Lasercom Current Terminal Project Objectives and Requirements Design Test Results Conclusions WPI-MITLL MPQ Presentation (3)
Free-Space Laser Communication (Lasercom) Benefits of Lasercom High Data Rates 10 40 Gb/s Low Probability of Interception Narrow beam for communication Unregulated Frequency Range No license required Link of focus: Air-to-space WPI-MITLL MPQ Presentation (4)
Tracking Testbed Tracking Testbed emulates aircraft to satellite communications Project focus: Reduce size and weight of existing aircraft terminal Communication and Beacon Beams Collimated beam for high data rates Divergent beam for acquisition Point-Ahead Mirror Leads communication beam ahead of target WPI-MITLL MPQ Presentation (5) TTB Aircraft Terminal Tracking Feedback Loop Stabilizes out platform jitter
Project Objectives Path-to-Flight Design Transition from laboratory-grade hardware Minimize Size, Weight, and Cost Common optics for beacon and communication signals Tracking with one detector (quad-cell) Commercial, off-the-shelf parts used Investigate New Hardware Automated positioning stage for adjustable beacon-to-comm transmitter Compact fast-steering mirror for tracking Characterizing New and Existing Components Tracking feedback loop bandwidth Beam characterization WPI-MITLL MPQ Presentation (6)
Design Requirements Optical Performance and Characterization Beam quality Losses Control Performance and Software Functionality Mirror control Tracking feedback loop New Component Assessment Fast steering mirror (FSM) Jitter rejection Requirement Beam divergence(1/e 2 ) Wavefront Quality Beam Size Tx/Rx Throughput Stroke of Mirror Mode Switch Speed PAM command Tracking Control Loop Spiral Scan Residual Jitter Mirror Steering Parameter 0.53 mrad / 2.67 mrad <0.07 waves rms in comm ~4.4 mm in diameter (1/e 2 ) <3 db loss in both paths +/- 1 mrad in Az and El <50 msec Fixed position +/- 10 mrad Mirror receives command Modify and run <20 μrad to 1 khz At 1 khz WPI-MITLL MPQ Presentation (7)
ALT-COM Layout Combined Tx fiber launch for Beacon + Comm beams New fast-steering mirror Tracking by quad-cell detector 24 x 36 in. 12 x 18 in. (1/4 of original area) Requirement: Layout on 12 x 18 in. optical breadboard Results: Built and tested on required breadboard Requirement satisfied WPI-MITLL MPQ Presentation (8)
Beam Characterization Beacon/Comm. Transmitter Stage Requirement: Switching Speed <50 msec Test: Oscilloscope readings at receive fiber Results: 8.7 ± 1.1 msec for beacon to comm 9.4 ± 0.8 msec for comm to beacon Comm - Collimated Wavefront Error Measurements Test Beam Divergence Beam Size Wavefront Error (1/e 2 ) (1/e 2 ) λ = 1.55 μm Req. 0.53 mrad comm ~4.4 mm <0.07 waves rms Beacon - Diverging 2.67 mrad beacon Result 0.58 mrad comm 3.7 mm <0.03 waves rms 3.02 mrad beacon WPI-MITLL MPQ Presentation (9) Requirements satisfied
Power Measurements Requirement: <3 db loss in both Tx and Rx paths Test: Free-space and fiber-coupled power measurements Results: Tx Component Associated Loss (db) Rx Component Associated Loss (db) Waveplates 0.06 FSM 0.20 PAM 0.14 PBS1 0.22 PBS1 0.22 PBS2 0.22 FSM 0.20 Insertion Loss 3.7 Total Loss = 0.62 Total Loss = 4.34 Satisfied for Tx path Unsatisfied for Rx path WPI-MITLL MPQ Presentation (10)
Power [db] WPI-MITLL MPQ Presentation (11) Fast-Steering Mirror Characteristics Requirement: Angular range of mirror ±1 mrad Test: Stepped voltage to fast-steering mirror input Results: Azimuth limited by ±0.85 mrad Requirement satisfied within tolerance 10 5 0-5 -10 FSM Frequency Response Magnitude Azimuth axis Elevation axis 3dB loss -15 10 0 10 1 10 2 10 3 Frequency [Hz] Angle [μrad] 500 0-500 -1000-1500 FSM Voltage Response -2000 0 2 4 6 8 Voltage [Volts] Requirement : Mirror steering at 1 khz (with 25-mm mirror) Test: Swept sinusoid on fast-steering mirror Result: Bandwidth of 200 Hz Does not satisfy requirement Azimuth axis Elevation axis Note: Elevation resonances after 200 Hz
Tracking Loop Performance Requirement: Fast-steering mirror responds to QC drive signals Test: Feedback enabled, applied platform jitter with point-ahead mirror Results: Tracking successful Requirement satisfied Requirement: Residual jitter <20 µrad to 1kHz Test: Command point-ahead mirror in random fashion to 0.5, 1.5 and 4 in. beam platform jitter models Results: 0.5, 1.5 in. residual jitter <20 µrad Jitter Applied Residual Az 109.5 13.9 El 131.5 13.8 Units µrad (rms) µrad (rms) Az 211% 27% El 254% 27% Units % Beamwidth (4/π)*(λ/D) Applied jitter of 2.5 beamwidths cut to 0.25 beamwidth Requirement satisfied for 0.5, 1.5-in. cases Power [db] PSD [Volts/sqrt(Hz)] TFL Rejection Frequency Magnitude 20 0-20 -40 Azimuth axis Elevation axis 3dB loss -60 10 0 10 1 10 2 10 3 Frequency [Hz] -20-40 -60-80 -100 Jitter PSD in Azimuth (1.5-inch beam) Applied Jitter Residual Jitter -120 10 0 10 1 10 2 10 3 Frequency [Hz] WPI-MITLL MPQ Presentation (12)
Lessons Beam coupling for flat and angled connectors Alignment Throughput Flat Easy Higher power Angled Difficult Lower power Interference Strong Oscillating regulator Bad component Problem found by frequency response Fast-Steering Mirror Works for lower bandwidth applications Negligible Potential improvement with smaller mirror Relative Power (db) 0-1 -2-3 -4-5 Quad-Cell Frequency Response -6 10 2 10 3 10 4 10 5 Frequency (Hz) Azimuth axis Elevation axis WPI-MITLL MPQ Presentation (13)
Conclusions Built and tested terminal Beacon control system functional and switches fast enough Tracking loop successful Evaluated Fast Steering Mirror Future work: Nutator for fiber alignment Investigate additional FSM Requirement Beam divergence (1/e 2 ) Wavefront Quality Beam Size Tx/Rx Throughput Stroke of Mirror Mode Switch Speed PAM command Tracking Control Loop Spiral Scan Residual Jitter Mirror Bandwidth Met? / WPI-MITLL MPQ Presentation (14)
4-inch Beam Platform Jitter Test PSD [Volts/sqrt(Hz)] PSD [Volts/sqrt(Hz)] 0-20 -40-60 -80 Jitter PSD in Az (4-inch beam) -100 10 0 10 1 10 2 10 3 0-20 -40-60 -80 Frequency [Hz] Jitter PSD in El (4-inch beam) Applied Jitter Residual Jitter Applied Jitter Residual Jitter Voltage [Volts] 8 7 6 5 4 3 2 1 0 FSM Throw Limitation in Az (4-inch beam) Quad-cell Az output GTI Az output -1-1 -0.5 0 0.5 1 Time [Seconds] -100 10 0 10 1 10 2 10 3 Frequency [Hz] WPI-MITLL MPQ Presentation (15)