Publications

Salton, Jonathan R.; Buerger, Stephen B.; Marron, Lisa C.; Feddema, John T.; Fischer, Gary J.; Little, Charles; Spletzer, Barry L.; Xavier, Patrick G.

Abstract not provided.

Olsson, Roy H.; Buerger, Stephen B.; Wojciechowski, Kenneth W.; Yepez, Esteban Y.; Novick, David K.; Wheeler, Jason W.; Rohrer, Brandon R.; Kholwadwala, Deepesh K.

Abstract not provided.

Rohde, Steven B.; Okandan, Murat O.; Pfeifer, Kent B.; De Smet, Dennis J.; Patel, Kamlesh P.; Ho, Clifford K.; Nordquist, Christopher N.; Walker, Charles A.; Rohrer, Brandon R.; Buerger, Stephen B.; Wroblewski, Brian W.

Low Temperature Cofired Ceramic (LTCC) has proven to be an enabling medium for microsystem technologies, because of its desirable electrical, physical, and chemical properties coupled with its capability for rapid prototyping and scalable manufacturing of components. LTCC is viewed as an extension of hybrid microcircuits, and in that function it enables development, testing, and deployment of silicon microsystems. However, its versatility has allowed it to succeed as a microsystem medium in its own right, with applications in non-microelectronic meso-scale devices and in a range of sensor devices. Applications include silicon microfluidic ''chip-and-wire'' systems and fluid grid array (FGA)/microfluidic multichip modules using embedded channels in LTCC, and cofired electro-mechanical systems with moving parts. Both the microfluidic and mechanical system applications are enabled by sacrificial volume materials (SVM), which serve to create and maintain cavities and separation gaps during the lamination and cofiring process. SVMs consisting of thermally fugitive or partially inert materials are easily incorporated. Recognizing the premium on devices that are cofired rather than assembled, we report on functional-as-released and functional-as-fired moving parts. Additional applications for cofired transparent windows, some as small as an optical fiber, are also described. The applications described help pave the way for widespread application of LTCC to biomedical, control, analysis, characterization, and radio frequency (RF) functions for macro-meso-microsystems.

Byrne, Raymond H.; Neely, Jason C.; Buerger, Stephen B.; Feddema, John T.; Novick, David K.; Rose, Scott E.; Spletzer, Barry L.; Sturgis, Beverly R.

This report contains the results of a research effort on advanced robot locomotion. The majority of this work focuses on walking robots. Walking robot applications include delivery of special payloads to unique locations that require human locomotion to exo-skeleton human assistance applications. A walking robot could step over obstacles and move through narrow openings that a wheeled or tracked vehicle could not overcome. It could pick up and manipulate objects in ways that a standard robot gripper could not. Most importantly, a walking robot would be able to rapidly perform these tasks through an intuitive user interface that mimics natural human motion. The largest obstacle arises in emulating stability and balance control naturally present in humans but needed for bipedal locomotion in a robot. A tracked robot is bulky and limited, but a wide wheel base assures passive stability. Human bipedal motion is so common that it is taken for granted, but bipedal motion requires active balance and stability control for which the analysis is non-trivial. This report contains an extensive literature study on the state-of-the-art of legged robotics, and it additionally provides the analysis, simulation, and hardware verification of two variants of a proto-type leg design.