Daniel W. Bliss (born 1966)[1] is an American professor, engineer, and physicist. He is a
Fellow of the
IEEE[2] and was awarded the
IEEE Warren D. White award for outstanding technical advances in the art of radar engineering in 2021 for his contributions to
MIMO radar,[3]Multiple-Function Sensing and Communications Systems, and Novel Small-Scale Radar Applications.[4] He is a professor in the School of Electrical, Computer and Energy Engineering at
Arizona State University.[5] He is also the director of the Center for Wireless Information Systems and Computational Architecture (WISCA).[6]
He has also served as a member of the [[IEEE [Aerospace and Electronic Systems Society|IEEE AESS]] Radar System Panel and as a Senior Editor of the IEEE Signal Processing Magazine.[12]
In 1989, Bliss was employed by
General Dynamics, where he designed avionics for the
Atlas-Centaur launch vehicle and also worked on particle accelerator engineering.[5][14] In 1997, Bliss was employed at
MIT Lincoln Laboratory, where he developed
MIMO radar literature and developed an airborne
GMTI MIMO radar system that demonstrated the validity of theoretical results.[3][15][16][17] In 2012, he joined Arizona State University as a professor and the director of BLISS Lab.[14][2] He also established the Center for Wireless Information Systems and Computational Architecture (WISCA) at ASU, where he currently serves as the director.[18]
Research
Bliss' research contributions have included system design based on information theory, detection and estimation theory, and statistical signal processing.[12] His research has been applied to various topics such as
MIMO wireless communications, MIMO radar,
cognitive radios, radio network performance bounds,
geolocation techniques, channel phenomenology, and signal processing and machine learning for anticipatory physiological monitoring.[5] His research has attracted over 9,000 total citations.[19] He has also authored two books on the field of wireless communications.[20][21]
He is responsible for formative work in electronic protection, adaptive MIMO communications,[9][22][23][24] MIMO radar,[3][15][16][17] distributed-coherent systems, and
RF convergence.[10][25][26] He has also made contributions to medical and physiological analytics.[11][27] He has made contributions to robust multiple-antenna communications including important theoretical results, multiple patents, and the development of advanced fieldable prototype systems. He has been the principal investigator on numerous programs including sponsored programs with DARPA, ONR, Google, Airbus, and others, with applications to radio, radar, and medical monitoring.[28][29][30][31]
^Bergin, Jamie; Guerci, J. R. (2018). MIMO radar: theory and application. Artech House radar series. Boston London: Artech House.
ISBN978-1-63081-522-6.
^
abForsythe, K. W.; Bliss, D. W. (2005-12-01).
"Waveform correlation and optimization issues for MIMO radar". Conference Record of the Thirty-Ninth Asilomar Conference on Signals, Systems and Computers. Conference Record - Asilomar Conference on Signals, Systems and Computers: 1306–1310.