3. Wafer Scale Cameras – Visible and Long Wave Infrared, optics, camera electronics, and advanced processing. Designed and implemented for wafer process manufacturing.
4. Visible to NIR Cameras – Image intensifiers(I2), I2 coupled to CMOS/CCD, Electron Bombarded Active Pixel Sensor (EBAPS), CCD, CMOS, HAD, EMCCD, and range gated
5. Targeting– Neural network, optical , discriminating optical augmentation, multi-sensor: analog and digital fusion, and ballistic computers
6. Lasers Systems – Optically augmented systems, range gated systems, illuminators, range finders, aiming, markers, and designators
7. Lasers – Semiconductor, Solid State (rod), and gas (HeNe, Ar, CO2)
9. Wireless – ad hoc, GIG, BreadCrumb, SWARM routing/healing, and UWB imaging.More – See additional technical information at ItP Technology
10.
11. Image Performance Modeling– MTF, US Army and other DoD models (NVThermIP, MRTSim, SSCamIP, IICamIP, ICCD, INVD, MAVIISS), and various models published by OSA, IEEE, SPIE and others
12. Imaging – Hyperspectral, discriminating optical augmentation, modulated range gating, 3D, imaging performance models, real-time image processing, and satellite space-based imaging and instrumentation
14. Optical Coatings – Anti-reflection, superhydrophobic, oxide layer and metallic thin films, and nanoparticle-based (self-assembled nanoparticles)
15. Applied Mathematics – Statistics (linear, 6σ, Bayesian, advanced), optimization (min-max, variational, simplicial, Kalman, evolutionary, DOE, agent based), cryptography (SSL/TLS, PGP, RSA, AES, elliptic curve), group theory, and artificial intelligenceMore – See additional technical information at ItP Technology
16. Timothy Ostromek, Ph.D. ItP Technology LLCview résumé USPTO Link ↓Patents↓ Google Patents Link 7,564,015System and method for processing and displaying light energy #2 7,528,355System and method for processing and displaying light energy #1 7,373,023Method and system for generating an image 7,274,830System for multi-sensor image fusion 7,177,485Method and system for combining image data 7,176,963Method and system for real-time image fusion 7,129,462Digitally enhanced image intensification camera 7,098,436Method and system for generating an image having multiple hues 7,092,013InGaAs image intensifier camera 7,091,930Centerline mounted sensor fusion device 7,053,928Method and system for combining multi-spectral images of a scene 6,970,190Event synchronization for detector systems 6,861,638Method and system for generating an image having multiple hues 6,760,062Synchronizing subsystems of an electro-optical system 6,747,821Method and system for mounting a detector 6,674,062Method and system for gating a sensor using a gated power signal 6,593,561Method and system for gathering image data using multiple sensors 6,576,884Method and system for gating a sensor using a gating signal 6,449,295Method and system for generating laser light 6,548,805Method and system for detecting radiation Active Applications Combining multiple spectral bands to generate an imageUS Pat. 10759959 - Filed Jan 16, 2004 DIGITALLY ENHANCED NIGHT VISION DEVICEUS Pat. 11308461 - Filed Mar 28, 2006 Image processing using optically transformed lightUS Pat. 10699985 - Filed Nov 3, 2003
17. Timothy Ostromek, Ph.D. ItP Technology LLCview résumé Papers 1 of 2 "Evaluation of matrix elements of the 8*8 k.p Hamiltonian with k-dependent spin-orbit contributions for the zinc-blende structure of GaAs,". T.E. Ostromek. Physical Review B-Condensed Matter, 54, pg 14467 (1996). "Photoreflectance of Zn:AlxGa1-xAs at the E1 transition energy as a function of carrier concentration and aluminum composition,", Abdul-Basit A. Saleh, Mary Rector, T. E. Ostromek, Jana Julien, J.P. Estrera and R. Glosser, PhysicaScripta, vol 64, pg 386 (2001). “MBE grown InGaAs photocathodes,”Proceedings of SPIE Vol. #4796-02 Low-Light-Level and Real-Time-Imaging Systems, Components, and Applications, 2002. Northrop Grumman Electro-Optical Systems: D. R. Chasse, J. P. Estrera, R. G. Hetter, T. E. Ostromek, T. W. Sinor University of Texas/Dallas: L. E. Bourree, R Glosser U.S. Army Night Vision & Electronic Sensors Directorate: E. J. Bender, M. W. Grenn. “Comparison of the optical characteristics of GaAs photocathodes grown using MBE and MOCVD,”Proceedings of SPIE Vol. #4796-03 Low-Light-Level and Real-Time-Imaging Systems, Components, and Applications, 2002. Northrop Grumman Electro-Optical Systems: D. R. Chasse, J. P. Estrera, R. G. Hetter, T. E. Ostromek, T. W. Sinor University of Texas/Dallas: L. E. Bourree, R. Glosser, J. K. Schaefers U.S. Army Night Vision & Electronic Sensors Directorate: E. J. Bender, M. W. Grenn .
18. Timothy Ostromek, Ph.D. ItP Technology LLCview résumé Papers 2 of 2 “Advanced image intensifier night vision system technologies: status and summary 2002,” Proceedings of SPIE Vol. #4796-08 Low-Light-Level and Real-Time-Imaging Systems, Components, and Applications, 2002. Northrop Grumman Electro-Optical Systems: J. Estrera, T. Ostromek, A. Bacarella, W. Isbell, M. Iosue, T. Beystrum. “Fused reflected/emitted radiation sensors,” (Invited Paper), Proceedings of SPIE Vol. #4369-01, Infrared Technology and Applications XXVII, April 2001. U.S. Army Night Vision & Electronic Sensors Directorate: S. B. Horn, J. Campbell, Jr., R. Driggers, T. Soyka, P. Norton, P. Perconti,; Litton Eletctro-Optical Systems: T. E. Ostromek, J. P. Estrera, A. Bacarella, T. Beystrum. “Photoreflectance Pump Frequency Effects in GaAsackslash In_x Ga_1-xAs Quantum Well nipi Structures,” American Physical Society, Semiconductor Heterostructures: III-V Optical Properties: Experiment, March , 1995, O14. University of Texas at Dallas: T. E. Ostromek, R. Glosser U.S. Army Research Laboratory, Adelphi, MD: R. Tober. “Electro-Optic Characterization of Excitonic Transitions and Electric Fields in InGaAs/GaAs Strained Layer Multiple Quantum Wells,” Ph.D. Dissertation, University of Texas at Dallas, Department of Physics, September, 1996, T. E. Ostromek.