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Journal articles on the topic 'Micro-devices'

Author: Grafiati
Published: 4 June 2021
Last updated: 14 February 2022

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1

Tien, Arun Majumdar Chang-Lin. "MICRO POWER DEVICES." Microscale Thermophysical Engineering 2, no. 2 (May 1998): 67–69. http://dx.doi.org/10.1080/108939598199982.

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2

Beckel, Daniel, Briand Danick, Jérôme Courbat, Anja Bieberle-Hütter, Nico F. de Rooij, and Ludwig J. Gauckler. "Micro-Hotplate Devices for Micro-SOFC." ECS Transactions 7, no. 1 (December 19, 2019): 421–27. http://dx.doi.org/10.1149/1.2729119.

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3

INOUE, MITSUTERU. "Optical Micro-Magnetic Devices." Journal of the Institute of Electrical Engineers of Japan 123, no. 11 (2003): 730–32. http://dx.doi.org/10.1541/ieejjournal.123.730.

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4

Malsch, Ineke. "Micro devices sense profit." Physics World 15, no. 6 (June 2002): 13. http://dx.doi.org/10.1088/2058-7058/15/6/21.

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5

Hricko, J., Š. Havlík, and Y. L. Karavaev. "Verifying the Performance Characteristics of the (micro) Robotic Devices." Nelineinaya Dinamika 16, no. 1 (2020): 161–72. http://dx.doi.org/10.20537/nd200112.

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6

Pihosh, Yuriy, Ivan Turkevych, Masahiro Goto, Akira Kasahara, Tadashi Takamasu, and Masahiro Tosa. "Micro-Patterned Organic Electroluminescent Devices." Japanese Journal of Applied Physics 47, no. 2 (February 15, 2008): 1263–65. http://dx.doi.org/10.1143/jjap.47.1263.

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7

Ikegami, Kozo. "Strength Problems of Micro-devices." Journal of the Society of Mechanical Engineers 97, no. 905 (1994): 267. http://dx.doi.org/10.1299/jsmemag.97.905_267.

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8

UKITA, Hiroo. "Micromechanical Devices. Micro Octical Tweezers." Journal of the Japan Society for Precision Engineering 65, no. 5 (1999): 647–50. http://dx.doi.org/10.2493/jjspe.65.647.

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9

SAWADA, Renshi. "Micromechanical Devices. Integrated Micro-Encoder." Journal of the Japan Society for Precision Engineering 65, no. 5 (1999): 665–68. http://dx.doi.org/10.2493/jjspe.65.665.

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10

Sato, T., T. Mizoguchi, and M. Sahashi. "Simulation of Micro Magnetic Devices." IEEE Translation Journal on Magnetics in Japan 9, no. 4 (July 1994): 68–75. http://dx.doi.org/10.1109/tjmj.1994.4565895.

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11

KOTERA, Hidetoshi. "K22100 Future of Micro Devices." Proceedings of Mechanical Engineering Congress, Japan 2015 (2015): _K22100–1_—_K22100–2_. http://dx.doi.org/10.1299/jsmemecj.2015._k22100-1_.

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12

Kozlov, D. V., I. P. Smirnov, A. A. Zhukov, and N. N. Bolotnik. "Micro-mechanical Components for the Space Micro Robotic Devices." Nano- i Mikrosistemnaya Tehnika 19, no. 3 (March 20, 2017): 173–80. http://dx.doi.org/10.17587/nmst.19.173-180.

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13

Hibino, Ryo, and Masahiko Yoshino. "Development of a micro-fabrication process for micro devices." Proceedings of International Conference on Leading Edge Manufacturing in 21st century : LEM21 2007.4 (2007): 8E517. http://dx.doi.org/10.1299/jsmelem.2007.4.8e517.

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14

JIMBO, H., and N. MIKI. "Gastric-fluid-utilizing micro battery for micro medical devices." Sensors and Actuators B: Chemical 134, no. 1 (August 28, 2008): 219–24. http://dx.doi.org/10.1016/j.snb.2008.04.049.

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15

Hasegawa, Tadahiro, Toshiyuki Tsuji, and Koji Ikuta. "Pneumatic Micro Dispenser Chip for Portable Micro Analysis Devices." IEEJ Transactions on Sensors and Micromachines 132, no. 7 (2012): 195–202. http://dx.doi.org/10.1541/ieejsmas.132.195.

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16

Tokeshi, Manabu, and Kiichi Sato. "Micro/Nano Devices for Chemical Analysis." Micromachines 7, no. 9 (September 9, 2016): 164. http://dx.doi.org/10.3390/mi7090164.

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17

Uenishi, Yuji. "Micro-machines Application to Optical Devices." Journal of SHM 12, no. 5 (1996): 29–32. http://dx.doi.org/10.5104/jiep1993.12.5_29.

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18

Shin, Woosuck, Kazuki Tajima, Yeongsoo Choi, Maiko Nishibori, Noriya Izu, Ichiro Matsubara, and Norimitsu Murayama. "Micro-thermoelectric devices with ceramic combustors." Sensors and Actuators A: Physical 130-131 (August 2006): 411–18. http://dx.doi.org/10.1016/j.sna.2006.01.006.

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19

Li, Hengyu, Junkao Liu, Kai Li, and Yingxiang Liu. "Piezoelectric micro-jet devices: A review." Sensors and Actuators A: Physical 297 (October 2019): 111552. http://dx.doi.org/10.1016/j.sna.2019.111552.

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20

Tabata, Osamu, Satoshi Konishi, Pierre Cusin, Yuichi Ito, Fumie Kawai, Shinichi Hirai, and Sadao Kawamura. "Micro fabricated tunable bending stiffness devices." Sensors and Actuators A: Physical 89, no. 1-2 (March 2001): 119–23. http://dx.doi.org/10.1016/s0924-4247(00)00538-0.

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21

Hänel, Jens, Bernd Keiper, Karsten Bleul, Christian Kaufmann, and Jens Bonitz. "Laser Trimming of Micro Mirror Devices." Laser Technik Journal 5, no. 1 (January 2008): 36–39. http://dx.doi.org/10.1002/latj.200790204.

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22

Hayashi, Kazutaka, Shuhei Nomura, and Yusuke Sakai. "Glass substrate for micro display devices." Journal of the Society for Information Display 25, no. 2 (February 2017): 71–75. http://dx.doi.org/10.1002/jsid.529.

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23

MATSUO, Tadayuki. "Micro Devices Using Integrated Circuit Technology." Journal of the Society of Mechanical Engineers 90, no. 819 (1987): 206–11. http://dx.doi.org/10.1299/jsmemag.90.819_206.

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24

REN, TIAN-LING, YI-PING ZHU, YI YANG, XIAO-MING WU, NING-XIN ZHANG, LI-TIAN LIU, and ZHI-JIAN LI. "MICRO ACOUSTIC DEVICES USING PIEZOELECTRIC FILMS." Integrated Ferroelectrics 80, no. 1 (November 2006): 331–40. http://dx.doi.org/10.1080/10584580600660116.

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25

Tran, A. T. T. D., G. L. Christenson, Z. H. Zhu, D. Haronian, and Y. H. Lo. "Micromachined Micro-Optic and Optoelectronic Devices." International Journal of High Speed Electronics and Systems 08, no. 02 (June 1997): 299–323. http://dx.doi.org/10.1142/s0129156497000111.

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Rencent progress on micromachined micro-optic and optoelectronic devices is discussed. We describe a low temperature (240°C) surface micromachining process that can be used to fabricate a variety of micro-optic components on micromachined membranes integrated with microactuators. The devices discussed in this paper include Fabry-Pérot tunable filters with a 341 nm tuning range, wavelength tunable transmitters at 1.55 micron wavelength, high-sensitivity integrated sensors using optical Moiré patterns, and movable microlenses. Such devices represent a new class of micro-optic circuits that will find important applications in many areas including optical communication and sensing.
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26

Krawczyk, S. K. "Senso-opto-micro-electronic (somet) devices." Sensors and Actuators 11, no. 3 (April 1987): 289–97. http://dx.doi.org/10.1016/0250-6874(87)80008-2.

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27

Gobinath, N., J. Cecil, and Derek Powell. "Micro devices assembly using virtual environments." Journal of Intelligent Manufacturing 18, no. 3 (July 3, 2007): 361–69. http://dx.doi.org/10.1007/s10845-007-0034-8.

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28

Kirchner, R., M. Rodriguez de Rivera, J. Seidel, and V. Torra. "Identification of micro-scale calorimetric devices." Journal of Thermal Analysis and Calorimetry 82, no. 1 (September 2005): 179–84. http://dx.doi.org/10.1007/s10973-005-0861-9.

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29

Auguet, C., J. L. Seguin, F. Martorell, F. Moll, V. Torra, and J. Lerchner. "Identification of micro-scale calorimetric devices." Journal of Thermal Analysis and Calorimetry 86, no. 2 (August 1, 2006): 521–29. http://dx.doi.org/10.1007/s10973-005-7255-x.

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30

Huang, Wen‐Sheh, Kung‐Ei Tzeng, Ming‐Cheng Cheng, and Ruey‐Shing Huang. "A silicon mems micro power generator for wearable micro devices." Journal of the Chinese Institute of Engineers 30, no. 1 (January 2007): 133–40. http://dx.doi.org/10.1080/02533839.2007.9671236.

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31

Suzuki, Toshio, Yoshihiro Funahashi, Zahir Hasan, Toshiaki Yamaguchi, Yoshinobu Fujishiro, and Masanobu Awano. "Fabrication of needle-type micro SOFCs for micro power devices." Electrochemistry Communications 10, no. 10 (October 2008): 1563–66. http://dx.doi.org/10.1016/j.elecom.2008.08.016.

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32

Hira, Shin-Ichiro, and Masato Yoshioka. "Micro-Cutting of Polytetrafluoroetylene (PTFE) for Application of Micro-Fluidic Devices." Key Engineering Materials 329 (January 2007): 577–82. http://dx.doi.org/10.4028/www.scientific.net/kem.329.577.

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This report describes fabrication of polytetrafluoroethylene (PTFE) to make up a micro-fluidic device for the application to a Micro-Total Analysis System ( -TAS). This material is chosen as a material of the device because of many excellent properties such as high chemical resistance and high heat resistance in comparison with the other polymers. Mechanical micro-cutting process is employed for the fabrications of the required elemental micro-structures such as a micro-channel and a micro-reservoir for the device. In general, burrs are easily generated in the cutting of soft materials such as PTFE. It is thought to be the most important to find how to prevent the burr generation and how to clean the generated burrs to assure the device quality. Therefore, in order to obtain the fundamental information about the burr generation in the micro-cutting of PTFE, through hole drilling, groove milling and face milling are performed. As a result, the elemental micro-structures without burrs are fabricated on PTFE plate. Furthermore the plate is sealed by sealing film assisted with pressure. By testing leakage with fluid sample, it is confirmed that the pressure-aided sealing is useful.
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33

Yuan, Xichen, Louis Renaud, Marie-Charlotte Audry, and Pascal Kleimann. "Electrokinetic Biomolecule Preconcentration Using Xurography-Based Micro-Nano-Micro Fluidic Devices." Analytical Chemistry 87, no. 17 (August 14, 2015): 8695–701. http://dx.doi.org/10.1021/acs.analchem.5b01352.

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34

Serizawa, Masaki, and Takashi Matsumura. "28pm3-B-5 Micro drilling on thin wires for micro devices." Proceedings of the Symposium on Micro-Nano Science and Technology 2015.7 (2015): _28pm3—B—5—_28pm3—B—5. http://dx.doi.org/10.1299/jsmemnm.2015.7._28pm3-b-5.

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35

Yoo, Dong-Yoon, Sun-Kyu Lee, and Dong-Ho Lee. "Ultraprecision Machining-based Micro-Hybrid lens design for micro scanning devices." International Journal of Precision Engineering and Manufacturing 16, no. 4 (April 2015): 639–46. http://dx.doi.org/10.1007/s12541-015-0085-2.

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36

Xie, Baocheng, Jianguo Liu, and Yongqiu Chen. "Recent Patents on Micro-EDM Milling." Recent Patents on Mechanical Engineering 13, no. 3 (August 26, 2020): 219–29. http://dx.doi.org/10.2174/2212797613666200213120209.

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Background: Micro-Electrical Discharge Machining (EDM) milling is widely used in the processing of complex cavities and micro-three-dimensional structures, which is a more effective processing method for micro-precision parts. Thus, more attention has been paid on the micro-EDM milling. Objective : To meet the increasing requirement of machining quality and machining efficiency of micro- EDM milling, the processing devices and processing methods of micro-EDM milling are being improved continuously. Methods: This paper reviews various current representative patents related to the processing devices and processing methods of micro-EDM milling. Results: Through summarizing a large number of patents about processing devices and processing methods of micro-EDM milling, the main problems of current development, such as the strategy of electrode wear compensation and the development trends of processing devices and processing methods of micro-EDM milling are discussed. Conclusion: The optimization of processing devices and processing methods of micro-EDM milling are conducive to solving the problems of processing efficiency and quality. More relevant patents will be invented in the future.
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37

Rav Acha, Moshe, Elina Soifer, and Tal Hasin. "Cardiac Implantable Electronic Miniaturized and Micro Devices." Micromachines 11, no. 10 (September 29, 2020): 902. http://dx.doi.org/10.3390/mi11100902.

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Advancement in the miniaturization of high-density power sources, electronic circuits, and communication technologies enabled the construction of miniaturized electronic devices, implanted directly in the heart. These include pacing devices to prevent low heart rates or terminate heart rhythm abnormalities (‘arrhythmias’), long-term rhythm monitoring devices for arrhythmia detection in unexplained syncope cases, and heart failure (HF) hemodynamic monitoring devices, enabling the real-time monitoring of cardiac pressures to detect and alert for early fluid overload. These devices were shown to prevent HF hospitalizations and improve HF patients’ life quality. Pacing devices include permanent pacemakers (PPM) that maintain normal heart rates, defibrillators that are capable of fast detection and the termination of life-threatening arrhythmias, and cardiac re-synchronization devices that improve cardiac function and the survival of HF patients. Traditionally, these devices are implanted via the venous system (‘endovascular’) using conductors (‘endovascular leads/electrodes’) that connect the subcutaneous device battery to the appropriate cardiac chamber. These leads are a potential source of multiple problems, including lead-failure and systemic infection resulting from the lifelong exposure of these leads to bacteria within the venous system. One of the important cardiac innovations in the last decade was the development of a leadless PPM functioning without venous leads, thus circumventing most endovascular PPM-related problems. Leadless PPM’s consist of a single device, including a miniaturized power source, electronic chips, and fixating mechanism, directly implanted into the cardiac muscle. Only rare device-related problems and almost no systemic infections occur with these devices. Current leadless PPM’s sense and pace only the ventricle. However, a novel leadless device that is capable of sensing both atrium and ventricle was recently FDA approved and miniaturized devices that are designed to synchronize right and left ventricles, using novel intra-body inner-device communication technologies, are under final experiments. This review will cover these novel implantable miniaturized cardiac devices and the basic algorithms and technologies that underlie their development. Advancement in the miniaturization of high-density power sources, electronic circuits, and communication technologies enabled the construction of miniaturized electronic devices, implanted directly in the heart. These include pacing devices to prevent low heart rates or terminate heart rhythm abnormalities (‘arrhythmias’), long-term rhythm monitoring devices for arrhythmia detection in unexplained syncope cases, and heart failure (HF) hemodynamic monitoring devices, enabling the real-time monitoring of cardiac pressures to detect and alert early fluid overload. These devices were shown to prevent HF hospitalizations and improve HF patients’ life quality. Pacing devices include permanent pacemakers (PPM) that maintain normal heart rates, defibrillators that are capable of fast detection and termination of life-threatening arrhythmias, and cardiac re-synchronization devices that improve cardiac function and survival of HF patients. Traditionally, these devices are implanted via the venous system (‘endovascular’) using conductors (‘endovascular leads/electrodes’) that connect the subcutaneous device battery to the appropriate cardiac chamber. These leads are a potential source of multiple problems, including lead-failure and systemic infection that result from the lifelong exposure of these leads to bacteria within the venous system. The development of a leadless PPM functioning without venous leads was one of the important cardiac innovations in the last decade, thus circumventing most endovascular PPM-related problems. Leadless PPM’s consist of a single device, including a miniaturized power source, electronic chips, and fixating mechanism, implanted directly into the cardiac muscle. Only rare device-related problems and almost no systemic infections occur with these devices. Current leadless PPM’s sense and pace only the ventricle. However, a novel leadless device that is capable of sensing both atrium and ventricle was recently FDA approved and miniaturized devices designed to synchronize right and left ventricles, using novel intra-body inner-device communication technologies, are under final experiments. This review will cover these novel implantable miniaturized cardiac devices and the basic algorithms and technologies that underlie their development.
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38

Santra, Tuhin, and Fan Tseng. "Micro/Nanofluidic Devices for Single Cell Analysis." Micromachines 5, no. 2 (April 3, 2014): 154–57. http://dx.doi.org/10.3390/mi5020154.

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39

Kawata, Satoshi, and Hong-Bo Sun. "Two-Photon Photopolymerization of Functional Micro-Devices." Journal of Photopolymer Science and Technology 15, no. 3 (2002): 471–74. http://dx.doi.org/10.2494/photopolymer.15.471.

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40

Kaigham, J. Gabriel. "Prospects for IC-based micro electromechanical devices." Journal of the Robotics Society of Japan 8, no. 4 (1990): 439–44. http://dx.doi.org/10.7210/jrsj.8.4_439.

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41

Burris, Jennifer. "Micro-Optical Devices Dry Etched into Diamond." MRS Bulletin 27, no. 1 (January 2002): 6. http://dx.doi.org/10.1557/mrs2002.6.

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42

Carney, Hayden, Amelia Schendel, and Justin Williams. "Chronic Brain Stimulation Using Micro-Electrocortiographic Devices." Journal of Purdue Undergraduate Research 5, no. 1 (August 13, 2015): 86–87. http://dx.doi.org/10.5703/1288284315661.

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43

Miki, Norihisa. "Jisso Technologies for Micro/Nano Medical Devices." IEEJ Transactions on Sensors and Micromachines 137, no. 10 (2017): 318–21. http://dx.doi.org/10.1541/ieejsmas.137.318.

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44

Dong, Hai Feng, and B. Zhou. "Combining Micro-Nanotechnology with Atomic Spin Devices." Key Engineering Materials 562-565 (July 2013): 1088–91. http://dx.doi.org/10.4028/www.scientific.net/kem.562-565.1088.

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In recent year, the sensitivities of atomic spin devices are improved greatly with the realization of spin exchange relaxation free (SERF) regime. Usually the SERF regime is realized using orthogonal beams scheme, i.e. one pump beam to polarize the atoms and the other orthogonal probe beam to measure the polarization. Due to the requirement of four optical windows for the atomic vapor cell, the orthogonal beams scheme has difficulties for micro fabrication. In this paper, we research a new scheme for SERF realization using only one beam, which facilitates the micro fabrication greatly. Furthermore, the fabrication processes of the MEMS atomic vapor cell with two out-of-plane optical windows are designed and performed. In the end, the possibility of increasing the relaxation time by nanotechnology is discussed.
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45

SUGIOKA, Hideyuki. "Electro-kinetic Phenomena in Micro-Fluidic Devices." Oleoscience 13, no. 7 (2013): 321–28. http://dx.doi.org/10.5650/oleoscience.13.321.

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46

YOSHIDA, SHIGEYOSHI. "Micro EMC Devices Using Magnetic Lossy Materials." Journal of the Institute of Electrical Engineers of Japan 123, no. 11 (2003): 733–35. http://dx.doi.org/10.1541/ieejjournal.123.733.

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47

Ilic, D., J. Heydecke, M. Kilb, I. Knop, and G. Schulz. "VARTA micro batteries for wireless telecommunication devices." Journal of Power Sources 96, no. 1 (June 1, 2001): 145–50. http://dx.doi.org/10.1016/s0378-7753(00)00686-8.

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48

NAGAI, Hidenori, and Shunsuke FURUTANI. "Clinical applications of micro/nano fluidic devices." Denki Kagaku 88, no. 4 (December 5, 2020): 305–10. http://dx.doi.org/10.5796/denkikagaku.20-fe0028.

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49

Havlík, Štefan, and Jaroslav Hricko. "Mechanisms for Small and Micro Robotic Devices." Applied Mechanics and Materials 613 (August 2014): 11–20. http://dx.doi.org/10.4028/www.scientific.net/amm.613.11.

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The paper deals with problems of designing and evaluation of compliant mechanisms for small and micro robotic devices. These kinematic mechanisms are usually made from a piece of elastic material in case of positioning systems, or, create the flexural body for multi-component sensing devices. The compliance characteristics mechanical segments: joints, arms, are discussed and the procedure for evaluation / comparing characteristics of particular segments, as well as whole elastic structures is proposed. It is briefly discussed that mechanisms for this kind of devices should integrate functional features of positioning and sensing systems. The concept of the x – y micro positioning mechanisms with two-component force sensing capability is presented as an illustrative example.
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50

Vermeersch, B., and G. De Mey. "Thermal impedance plots of micro-scaled devices." Microelectronics Reliability 46, no. 1 (January 2006): 174–77. http://dx.doi.org/10.1016/j.microrel.2005.05.014.

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