Micro-fabricated, expandable temperature sensor network for macro-scale deployment in composite structures

Kim, Kyunglok; Lanzara, Giulia; Salowitz, Nathan; Peumans, Peter; Chang, Fu‐Kuo

doi:10.1109/aero.2011.5747597

Cited by 18 publications

(25 citation statements)

References 3 publications

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“…Therefore, the cost per unit area is an important factor when evaluating the applicability in large-area electronics. One way to reduce this cost is using stretchable springs to spread out the functionality of devices over a larger surface [6][7][8][9][10]. Electronic devices can be fabricated close together in high density by modern microelectronics fabrication, and spread out at the time deployment to cover a larger area.…”

Section: Introductionmentioning

confidence: 99%

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Micro devices integration with large-area 2D chip-network using stretchable electroplating copper spring

Sung

Lai

Chen³

et al. 2014

2014 IEEE 27th International Conference on Micro Electro Mechanical Systems (MEMS)

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This study presents a large-area multi-devices integration scheme using stretchable electroplated copper spring. Each device is located on the silicon-node of a 2D chip-network distributed, which are mechanically and electrically connected to surrounding devices by stretchable copper spring. The springs stretch and expand the functional devices by several orders of magnitude area forming a variable-density network of interconnected devices. Advantages of this approach include: (1) using existing process technologies and materials for semiconductor in large-area applications, compatible with foundry fabrication processes; (2) stretchable electroplated copper springs with large maximum strain act as both mechanical and electrical connections between devices; (3) silicon-nodes act as hubs for device implementation and integration; and (4) the chip-network can be applied to 2D-curved (spherical) surfaces. The proposed expandable network using stretchable springs integrated with multiple devices has been implemented and tested.

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Section: Introductionmentioning

confidence: 99%

“…Large-area electronics with stretchable springs have been explored for various applications, such as optical system with a curved image surface [6], temperature sensor network [7], structural health monitoring system [8] and Bio-inspired network [9]. They have been achieved using silicon [6,8,10] or polymer [7,9] stretchable spring.…”

Section: Introductionmentioning

confidence: 99%

Micro devices integration with large-area 2D chip-network using stretchable electroplating copper spring

Sung

Lai

Chen³

et al. 2014

2014 IEEE 27th International Conference on Micro Electro Mechanical Systems (MEMS)

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“…With advances in materials science and manufacturing technology, miniaturized piezo transducers have already been adopted for SHM [5], [6], and micro-fabricated arrays are on the horizon [7], [8], making an embedded SHM system a tangible goal. However, in today's SHM systems, the interface electronics are either based on general purpose lab equipment or PCB assemblies [2], [9], [10].…”

Section: Introductionmentioning

confidence: 99%

A Four-Channel, <formula formulatype="inline"><tex Notation="TeX">${\pm} $</tex></formula>36 V, 780 kHz Piezo Driver Chip for Structural Health Monitoring

Aquino

Zhang

Murmann

2014

IEEE J. Solid-State Circuits

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This paper describes a four-channel piezo driver chip for use in active structural health monitoring. Each channel can drive a piezoelectric transducer with a continuous-wave signal of 36 V and 780 kHz. The waveform is synthesized using filtered pulse-width modulation (PWM), where the pulse transition times are precomputed through a least-square optimization problem. A calibration technique is introduced to achieve subnanosecond timing accuracy and 40.5 dB signal distortion. A 13 mm proof-of-concept IC was fabricated in a 0.25 m BCD process and evaluated within an application test bed.

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“…The beauty of this approach is clearly that the network not only can be used for SHM systems, but it can also be used to monitor environmental parameters, in-flight conditions etc. by simply specializing the miniaturized devices and corresponding electronics [9][10][11][12][13][14][15]. While this is certainly a fascinating approach and a wide effort is currently being devoted toward this research activity to integrate into it for example PZT sensors/actuators [10,13,15], strain gages [6], inorganic diodes [11,14], pressure and flow sensors, the expandable network technology clearly has the disadvantage that the integrated devices need to be powered and this power should be delivered by the already heavy on-board batteries which unavoidably would increase in size and weight adding additional weight to the aircraft and consequently increasing energy consumption.…”

Section: Introductionmentioning

confidence: 99%

Self-Rechargeable Multifunctional Carbon Fiber Composites with CNTs Supercapacitors

Lanzara¹,

Basiricò²

2012

53rd AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics and Materials ConferenceSelf Cite

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Advances toward the development of light-weight fully electric aerospace structures lead to the need of replacing on-board batteries with lighter and more efficient energy storage devices and systems. Here a novel self-rechargeable multifunctional carbon fiber composite is presented. The composite has the capability to monitor internal (such as damage) and external parameters (e.g. flight conditions) with high accuracy, to provide the required energy to the embedded monitoring system as well as to other on-board equipment while keeping its structural integrity and strength, increasing its life-time and power capability and decreasing the global weight of the overall aerospace structure. The self-recharging capability is given by a series of miniaturized supercapacitor cells that are first prefabricated on a strategic support already integrated with the necessary circuitry and then are embedded in a cost-effective manner between the layers of the composite. Here it is also demonstrated that supercapacitor cells made with carbon nanotubes electrodes can become lighter and can provide superior performance by thinning its electrodes. For instance, going from 400μm to 20μm thick CNTs-electrodes a 1246% power increase, a 21% specific capacitance increase and a 60% electrode resistance reduction were recorded. Moreover the ultra-thin supercapacitors were found to provide these high performance responses with a reaction speed about 30% superior than ever reported in the literature and over an extremely wide frequency range (up to 10KHz).

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Micro-fabricated, expandable temperature sensor network for macro-scale deployment in composite structures

Cited by 18 publications

References 3 publications

Micro devices integration with large-area 2D chip-network using stretchable electroplating copper spring

Micro devices integration with large-area 2D chip-network using stretchable electroplating copper spring

A Four-Channel, <formula formulatype="inline"><tex Notation="TeX">${\pm} $</tex></formula>36 V, 780 kHz Piezo Driver Chip for Structural Health Monitoring

Self-Rechargeable Multifunctional Carbon Fiber Composites with CNTs Supercapacitors

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