Process tomography: Difference between revisions
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'''Process tomography''' consists of [[tomography|tomographic]] imaging of systems, such as process pipes in industry. In tomography the [[Three-dimensional space|3D]] distribution of some physical quantity in the object is determined. There is a widespread need to get tomographic information about process. This information can be used, for example, in the design and control of processes. |
'''Process tomography''' [1] consists of [[tomography|tomographic]] imaging of systems, such as process pipes in industry. In tomography the [[Three-dimensional space|3D]] distribution of some physical quantity in the object is determined. There is a widespread need to get tomographic information about process. This information can be used, for example, in the design and control of processes. |
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Tomography involves taking measurements around the periphery of an object (e.g. process vessel or patient) to determine what is going on inside. |
Tomography involves taking measurements around the periphery of an object (e.g. process vessel or patient) to determine what is going on inside. |
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The best known technique is [[CAT]] scanning in [[medicine]], however process tomography instrumentation needs to be cheaper, faster and more robust. |
The best known technique is [[CAT]] scanning in [[medicine]], however process tomography instrumentation needs to be cheaper, faster and more robust. |
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Many different imaging methods are used in process tomography, e.g. [[ultrasonic]] imaging, [[positron emission tomography]] (PET), [[electrical resistance tomography]] (ERT) and [[electrical impedance tomography]] (EIT). In all cases external sensors are used to detect signals from boundary of the object, and the three dimensional material distribution or the velocity field is computed using the measured data. |
Many different imaging methods are used in process tomography, e.g. [[ultrasonic]] imaging, [[positron emission tomography]] (PET), [[electrical resistance tomography]] (ERT) and [[electrical impedance tomography]] (EIT), electrical capacitance tomography (ECT), magnetic induction tomography (MIT). In all cases external sensors are used to detect signals from boundary of the object, and the three dimensional material distribution or the velocity field is computed using the measured data. |
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Process tomography is an area of rapid growth both in terms of research and applications. There are number of challanges remaning in this area including data processing an image reconstruction [2], and application of imaging modalities in a real applications. |
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References |
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1)T York, Status of electrical tomography in industrial applications |
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- Journal of Electronic Imaging, 2001 - link.aip.org |
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2)Soleimani, M., 2008. Computational aspects of low frequency electrical and electromagnetic tomography: A review study. International Journal of Numerical Analysis and Modeling, 5 (3), pp. 407-440. |
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[[Category:Imaging]] |
[[Category:Imaging]] |
Revision as of 09:44, 27 April 2009
Process tomography [1] consists of tomographic imaging of systems, such as process pipes in industry. In tomography the 3D distribution of some physical quantity in the object is determined. There is a widespread need to get tomographic information about process. This information can be used, for example, in the design and control of processes.
Tomography involves taking measurements around the periphery of an object (e.g. process vessel or patient) to determine what is going on inside.
The best known technique is CAT scanning in medicine, however process tomography instrumentation needs to be cheaper, faster and more robust.
Many different imaging methods are used in process tomography, e.g. ultrasonic imaging, positron emission tomography (PET), electrical resistance tomography (ERT) and electrical impedance tomography (EIT), electrical capacitance tomography (ECT), magnetic induction tomography (MIT). In all cases external sensors are used to detect signals from boundary of the object, and the three dimensional material distribution or the velocity field is computed using the measured data. Process tomography is an area of rapid growth both in terms of research and applications. There are number of challanges remaning in this area including data processing an image reconstruction [2], and application of imaging modalities in a real applications.
References 1)T York, Status of electrical tomography in industrial applications
- Journal of Electronic Imaging, 2001 - link.aip.org
2)Soleimani, M., 2008. Computational aspects of low frequency electrical and electromagnetic tomography: A review study. International Journal of Numerical Analysis and Modeling, 5 (3), pp. 407-440.