05-10-2010, 09:08 AM
Abstract
This paper describes an innovative work for nanorobot design and manufacturing, using a computer simulation and system on chip prototyping approach. The use of CMOS as integrated circuits, with the miniaturization from micro towards nanoelectronics, and the respective advances of nanowires are considered into the proposed model design and discussed as a practical pathway to enable embedded sensors for manufacturing nanorobots. The proposed nanorobot model is applied to hydrology monitoring. It can be useful for agriculture or environmental monitoring and management.
Introduction
This work presents an innovative approach to evaluate hydraulic conductivity, considering nanorobots as a new paradigm to enable more precise analysis in the field of hydrology monitoring. The application of nanorobots for agricultural purposes and monitoring water and soil qualities may result in impressive impact towards environmental control and decreasing the damages caused by pollution to many different natural species. Applications of nanorobots are expected to provide remarkable possibilities. Over the past 15 years, insight was gained into the hydraulic conductivity of fractured and karstic rocks by introducing particles of different size, charge, and chemical composition into a flow field and monitoring the breakthrough of these particles in space and time. From this information, it is possible to infer the hydraulic aperture of the smallest throats in a flow path. Therefore, this concept can be extended to porous media using nanorobots .
A computational approach is described for the investigation of nanorobots manufacturing design, which aims to enable better tools for hydraulic conductivity interpretation. A total market for nanotechnology-based environmental applications in 2005 was evaluated in $374.9 million, and by 2010 this market will have reached more than $6.1 billion . Advantages of using nanorobots for environmental tasks are quite clear: more control in measuring microorganisms, better detection of pollutants, and improved control of water temperature, just to quoting some positive aspects.
The nanorobots hardware feasibility may be observed as the result of most recent advances in a broad range of manufacturing techniques. Inside the miniaturization trends, it is reasonable to even quote some examples such as VLSI chips, including here Complementary Metal Oxide Semiconductor (CMOS) based on current technology, which could be observed as one possible way for manufacturing embedded control computation on molecular machines in near future. Meanwhile these manufacturing methodologies may advance progressively the use of computational nanomechatronics and virtual reality could help in the process of transducers investigation. Thus, this work aims to outline the ways to manufacture nanorobots system on chip to prepare its use for upcoming applications which may concern agricultural, industrial and environmental issues.
For more details, please visit
http://www.nanorobotdesignpapers/manufacturing.pdf
This paper describes an innovative work for nanorobot design and manufacturing, using a computer simulation and system on chip prototyping approach. The use of CMOS as integrated circuits, with the miniaturization from micro towards nanoelectronics, and the respective advances of nanowires are considered into the proposed model design and discussed as a practical pathway to enable embedded sensors for manufacturing nanorobots. The proposed nanorobot model is applied to hydrology monitoring. It can be useful for agriculture or environmental monitoring and management.
Introduction
This work presents an innovative approach to evaluate hydraulic conductivity, considering nanorobots as a new paradigm to enable more precise analysis in the field of hydrology monitoring. The application of nanorobots for agricultural purposes and monitoring water and soil qualities may result in impressive impact towards environmental control and decreasing the damages caused by pollution to many different natural species. Applications of nanorobots are expected to provide remarkable possibilities. Over the past 15 years, insight was gained into the hydraulic conductivity of fractured and karstic rocks by introducing particles of different size, charge, and chemical composition into a flow field and monitoring the breakthrough of these particles in space and time. From this information, it is possible to infer the hydraulic aperture of the smallest throats in a flow path. Therefore, this concept can be extended to porous media using nanorobots .
A computational approach is described for the investigation of nanorobots manufacturing design, which aims to enable better tools for hydraulic conductivity interpretation. A total market for nanotechnology-based environmental applications in 2005 was evaluated in $374.9 million, and by 2010 this market will have reached more than $6.1 billion . Advantages of using nanorobots for environmental tasks are quite clear: more control in measuring microorganisms, better detection of pollutants, and improved control of water temperature, just to quoting some positive aspects.
The nanorobots hardware feasibility may be observed as the result of most recent advances in a broad range of manufacturing techniques. Inside the miniaturization trends, it is reasonable to even quote some examples such as VLSI chips, including here Complementary Metal Oxide Semiconductor (CMOS) based on current technology, which could be observed as one possible way for manufacturing embedded control computation on molecular machines in near future. Meanwhile these manufacturing methodologies may advance progressively the use of computational nanomechatronics and virtual reality could help in the process of transducers investigation. Thus, this work aims to outline the ways to manufacture nanorobots system on chip to prepare its use for upcoming applications which may concern agricultural, industrial and environmental issues.
For more details, please visit
http://www.nanorobotdesignpapers/manufacturing.pdf