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IntroductionThe paper - unlike the many technical manuscripts we presented over the last two decades - is dedicated to a more non-technical, organizational and social subject: conducting university courses in optics and optronics for students who are integrated not only in their university program, but also in an extremely demanding professional environment. In our case, these are young officers of the Federal Armed Forces of Germany, studying mechanical engineering at the Helmut-Schmidt-University Hamburg. A short discussion of the time line of their education and the subjects the program is based on, reveals the conflicts between academic demands, hands-on education needs and compact structure of the university programm, which are arising for the Department of Measurement and Information Technology. As a consequence, the evolution of the optronics courses shows a convergence with subjects such as defense technology and ballistics. The academic education of officers is not the only case in which the students are exposed to the high stress caused by a dually interacting environment, consisting of university program and an employer. The transition of the optronics course concept to a dual bachelor course in electrical engineering at the bbw Hochschule Berlin shows similar interesting effects, which shall be discussed in short. Academic education in the Federal Armed ForcesThe career of the officers of the German Federal Armed Forces, demands an academic degree. The necessary academic programs for the majority of the officers are conducted at two dedicated universities of the Federal Armed Forces. The subjects do not necessarily correlate with the later disposition in the forces. About half of every year’s young officers study at the Helmut Schmidt* University University of the Federal Armed Forces Hamburg. The HSU offers a full variety of subjects, from economics, over history, social sciences, to engineering. After secondary school and about 1 year of basic military training the young officers, who are committed to 12 years of military service, are facing a compact academic program:
The students live on campus and in close surrounding, most of the time they act like civil persons, and so the university acts like any civil university †. Mechanical Engineering program at the HSUThe HSU offers consecutive engineering programs in both electrical and mechanical engineering. The Chair for Measurement and Information Technology is part of the Department for Mechanical Engineering, thus being responsible for the basic courses in Informatics and Metrology for the Bachelor program in mechanical engineering, which both are accompanied by extensive lab practice. Further, their responsibility includes the higher courses for ballistics, optronics, defense and ammunition technology and micro-controller engineering during the mechanical engineering Master program. The optronics course shall be subject to further discussion. To understand the approach of the optronics course, a look into the curricula of the mechanical engineering consecutive program is useful. The following list covers the full program, only the subjects are excerpted:
Obviously this is the typical curriculum for a mechanical engineering Bachelor program, only one has to keep in mind that this is conducted in 2 years and 3 months with very low tolerance in the time line, which means the academic follows the military timing, especially there is little space for any extensions. The Master program offers the special sub-programs
of which only Mechatronics and Defense Technology shall be considered here, due to their inclusion of the Optronics course. To give a further overview on the Master program, we extracted only the compulsory subjects, and the compulsory elective subjects which are fundamental for the Optronics course‡.
We see that the academic background necessary for extensive Optronics is delivered with certain compulsory elective subjects, such as Systems Identification and Technical Electronics. Although the contents might not reach the level one would expect in a comparable electrical engineering course, usually they tend to proof to be sufficient. Certain basics, as for instance Fourier theory, have to be repeated and extended during the course. Evolution of the Optronics courseFigure 1 illustrates the evolution of the Optronics course over three decades. Initially, a course in digital image processing with theoretical lectures and a PC lab part based on C routines and a theoretical course in optics were conducted. Over the years, basics on sensors optics were included into the image processing course, due to the fact that students not necessarily had to choose the optics course, too. On the other hand, military technology was included in the optics course to meet the demands of the officers. The annual night vision hands-on event, in which the students could use state of the art technology, moved from the sports ground of the HSU on late evenings to - due to earlier sunset - wintertime full day sessions at an outdoor shooting range. These night vision excursions were conducted with real shooting sessions using original gear. Gaining interest by students and the introduction of high speed video technology at the MIT chair triggered the combination with the Ballistics and Ammunition courses, which lead to extended multi-day sessions at an in-door shooting range, were high-speed video technology could be experienced beside special ballistic instructions. The Image Processing course switched to Matlab based PC lab sessions, which lead to better focus on the principle methods due to easier visualization. Around that time we introduced lab sessions practical applications such as metrological image processing. Also optics and opto-electronics became part of the lab sessions. When an analogue CCD cam is used with a monitor screen, the composite video signal is observed using an oscilloscope, and finally a CCD element is assembled from a photodiode and a capacitor and illuminated while the capacitor voltage is checked on the oscilloscope. Later on the Image Processing and the Optics courses were merged under the names Optronics I+II, due to the fact that an Image Processing course was claimed by another chair for the Mechatronics branch of the Master program. Soon it turned out that Optronics I and Image Processing for Mechatronics had a very different philosophy and were more of a complimentary pair, so many students ended up choosing both courses. Complexity vs. academical background vs. hands-on practiceWhat can we expect to put into only two trimesters of Optronics, which is optics, photonics, systems theory, signal and image processing, materials and physical basics? There are several hard boundary conditions to be taken into account.
The answers are as natural as pragmatical:
Figure 3 shows still images from footage which was recorded during combined hands-on sessions§. As one might see, there is essential experience for the soldier, such as the myth of the handgun which should explode when fired under water, but also the funny side of life. Transition to dual program in electrical engineeringIn 2013 bbw Hochschule Berlin started a dual bachelor program in electrical engineering for Deutsche Bahn AG, a major German logistics provider¶. The program is designed for a 6 semester duration with the students alternating between university and their working places in 3 month periods. While the design of the courses already showed the need for extreme compactness, soon after the first semester started, it turned out that there are other clear similarities and parallels to the HSU students in terms of the dual demands they are exposed to. The curriculum contains a course in Optics and Opto-electronics, which is conducted parallel to a course in RF technology. Beside their theoretical content – due to the academic background after 4 semesters of Electrical Engineering less problematic than in the case of Mechanical Engineering – both courses merge into combined hands-on sessions after half a semester. For the final examination student projects are developed out of these sessions, thus avoiding written exams, which usually lead to excessive learning overhead and zero sustain. Meanwhile, the first run finished their Bachelor theses successfully, some of which actually base on topics from the Optics and RF lessons. Conclusion and outlookAn insight into special educational problems arising with the conduction of demanding courses like optics and optronics under the special conditions academic courses addressing of military and dual students was given. The experiences of over three decades resulted in the development of special concepts, which might be useful in similar situations and not only for optics. It should be emphasized that the inclusion of the students into the research activities is also documented in a series of SPIE papers, from HSU1–5 as well as from bbw6–10 and also in collaboration.11 Notes[2] For extensive information visit www.hsu-hh.de. [4] In electronic version: Video 1 http://dx.doi.org/10.1117/12.2238055.1; Video 2 http://dx.doi.org/10.1117/12.2238055.2; Video 3 http://dx.doi.org/10.1117/12.22380553; Video 4 http://dx.doi.org/10.1117/12.2238055.4. [5] “For further information visit www-bbw-hochschule.de. REFERENCESHahlweg, C., Skaloud, D., Gutzmann, H., Kutz, S., and Rothe, H.,
“Visualization of sound generation - special imaging techniques,”
in Novel Optical Systems Design and Optimization XVI Proceedings of SPIE Proceedings of SPIE,
8842-16
(2013). Google Scholar
Hahlweg, C., Weyer, C., Gercke-Hahn, H., Gutzmann, H., Brahmann, A., and Rothe, H.,
“Perception of power modulation of light in conjunction with acoustic stimulation,”
in Novel Optical Systems Design and Optimization XVI Proceedings of SPIE Proceedings of SPIE,
8842-17
(2013). Google Scholar
Hahlweg, C., Zhao, W., Vogeler, H., and Rothe, H.,
“Imaging of short time microscopic scenes with strong light emission: revisited,”
in Instrumentation, Metrology, and Standards for Nanomanufacturing, Optics, and Semiconductors VI Proceedings of SPIE,
(2012). Google Scholar
Hahlweg, C., Wilhelm, E., and Rothe, H.,
“Laser based imaging of time depending microscopic scenes with strong light emission,”
in Instrumentation, Metrology, and Standards for Nanomanufacturing, Optics, and Semiconductors V Proceedings of SPIE,
(2011). Google Scholar
Wilhelm, E., Chalupka, U., Hahlweg, C., Zhao, W., and Rothe, H.,
“A stereoscopic imaging system for laser back scatter based trajectory measurement in ballistics,”
(2010). Google Scholar
Dannenberg, F., Pescoller, L., Weiß, J., and Hahlweg, C.,
“A rugged stereoscopical device for surface inspection,”
in Proc. SPIE,
(2015). Google Scholar
Dannenberg, F., Uebeler, D., Weiß, J., and Hahlweg, C.,
“Extended volume and surface scatterometer for characterization of 3d-printed objects,”
in Proc. SPIE,
(2015). Google Scholar
Uebeler, D., Pescoller, L., and Hahlweg, C.,
“Further development of imaging near-field scatterometer,”
in Proc. SPIE,
(2015). Google Scholar
Dannenberg, F., Hahlweg, C., Pescoller, L., and Zhao, W.,
“Near-field imaging techniques for surface inspection,”
in Proc. SPIE,
(2014). Google Scholar
Hahlweg, C., Dannenberg, F., Dörfler, J., Weber, B., Weyer, C., Gercke-Hahn, H., Heucke, S., Freimuth, S., and Gutzmann, H. L.,
“Chords and harmonies in mixed optical and acoustical stimuli,”
in Proc. SPIE,
(2014). Google Scholar
Kleebereg, F.P., Gutzmann, H. L., Weyer, C., Weiß, J., Dörfler, J., and Hahlweg, C.,
“Investigation of correlation of lf power modulation of light in natural and artificial illumination situations and acoustic immission,”
in Thirteenth International Conference on Solid State Lighting Proc. SPIE,
(2014). Google Scholar
|