1995 - US President's National Medal of Science "For his fundamental and seminal research contributions to the field of quantum electronics, noise and ultra-fast optics; and for his service to the engineering profession through teaching.", Awarded by President Clinton at a White House ceremony on October 18, 1995.
1994 - Frederic Ives Medal, The Optical Society For his fundamental and seminal contribution to the understanding of quantum noise in optical systems and for a lifetime of dedication to science and engineering education.
1991 - Fellow of American Physical Society (APS) Citation For pioneering and sustained contributions to the understanding of laser modelocking, optical waveguide devices, and quantum optics
1987 - Member of the National Academy of Sciences
1959 - Fellow of John Simon Guggenheim Memorial Foundation
The scientist’s investigation covers issues in Optics, Laser, Mode-locking, Optoelectronics and Optical fiber. Optics is represented through his Resonator, Fiber laser, Coupled mode theory, Nonlinear optics and Optical filter research. His work deals with themes such as Pulse, Pulse-width modulation, Laser linewidth, Self-phase modulation and Pulse duration, which intersect with Mode-locking.
His work carried out in the field of Optoelectronics brings together such families of science as Ultrashort pulse and Beam splitter. The concepts of his Optical fiber study are interwoven with issues in Dispersion, Soliton, Injection locking, Local oscillator and Reflector. Hermann A. Haus interconnects Electronic engineering, Quantum, Amplifier and Optical amplifier in the investigation of issues within Soliton.
His primary areas of investigation include Optics, Laser, Optoelectronics, Optical fiber and Mode-locking. His study in Fiber laser, Resonator, Pulse, Interferometry and Dispersion is done as part of Optics. His Fiber laser research is multidisciplinary, incorporating perspectives in Polarization-maintaining optical fiber, Bandwidth-limited pulse and Phase modulation.
His Laser research incorporates themes from Wavelength and Soliton. His research on Optical fiber frequently connects to adjacent areas such as Soliton. His biological study spans a wide range of topics, including Self-phase modulation and Saturable absorption.
His primary areas of study are Optics, Optoelectronics, Electronic engineering, Laser and Resonator. His studies deal with areas such as Quantum noise and Jitter as well as Optics. He combines subjects such as Drop and Picosecond with his study of Optoelectronics.
The Electronic engineering study combines topics in areas such as Concatenation, Communication channel, Polarization mode dispersion and Topology. His Resonator study combines topics in areas such as Interferometry, Optical cavity, Optical filter and Optical switch. The various areas that Hermann A. Haus examines in his Optical filter study include Coupled mode theory and Refractive index.
Hermann A. Haus spends much of his time researching Optics, Optoelectronics, Phase noise, Laser and Resonator. Hermann A. Haus frequently studies issues relating to Jitter and Optics. His study on Coupled mode theory is often connected to Diagonal as part of broader study in Optoelectronics.
His Phase noise research is multidisciplinary, relying on both Quantum noise, Noise, Noise generator and Bandwidth-limited pulse. His Semiconductor laser theory study in the realm of Laser connects with subjects such as Slip, Phase slip and Laser oscillator. His research investigates the connection between Resonator and topics such as Optical filter that intersect with issues in Optical switch, Drop and Electronic engineering.
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Microring resonator channel dropping filters
B.E. Little;S.T. Chu;H.A. Haus;J. Foresi.
Journal of Lightwave Technology (1997)
Waves and fields in optoelectronics
Hermann A. Haus.
Mode-locking of lasers
IEEE Journal of Selected Topics in Quantum Electronics (2000)
Random walk of coherently amplified solitons in optical fiber transmission
James P. Gordon;Hermann A. Haus.
Optics Letters (1986)
77-fs pulse generation from a stretched-pulse mode-locked all-fiber ring laser
K Tamura;E P Ippen;H A Haus;L E Nelson.
Optics Letters (1993)
Ultrashort-pulse fiber ring lasers
L.E. Nelson;D.J. Jones;K. Tamura;H.A. Haus.
Applied Physics B (1997)
Channel Drop Tunneling through Localized States
Shanhui Fan;Pierre R. Villeneuve;J. D. Joannopoulos;H. A. Haus.
Physical Review Letters (1998)
H.A. Haus;W. Huang.
Proceedings of the IEEE (1991)
Sub-two-cycle pulses from a Kerr-lens mode-locked Ti:sapphire laser.
U Morgner;F X Kärtner;S H Cho;Y Chen.
Optics Letters (1999)
Coupling of modes analysis of resonant channel add-drop filters
C. Manolatou;M.J. Khan;S. Fan;P.R. Villeneuve.
IEEE Journal of Quantum Electronics (1999)
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