Fast and precise data acquisition for broadband microwave tomography systems

Mallach, Malte; Musch, Thomas

doi:10.1088/1361-6501/aa6a86

Cited by 4 publications

(6 citation statements)

References 32 publications

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“…These quantitative imaging techniques are also known as "inverse scattering methods". The microwave tomography technique can be applied for imaging of multiphase flows, e.g., in oil-gas-water flows in metal pipes [131,132], measurement of moisture distribution [133] or for measurement of density or material composition as well as detection of defects in materials [134]. Further information about these tomographic techniques and potential applications can be found in Ref.…”

Section: Electrical Process Tomographymentioning

confidence: 99%

Overview of Electric Field Applications in Energy and Process Engineering

Zigan

2018

Energies

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Heat and mass transfer as well as chemical reactions in technical processes can be enhanced by using electric fields. This paper provides an overview of current fundamental and applied research as well as potential technical applications of electric fields in energy and process engineering. This includes electrosprays, technical combustors as well as electrochemical reforming and plasma gasification of waste or biomass. Other emerging fields are plasma technologies for treatment of water, surfaces and gases including flue gases. In particle or aerosol-laden flows, plasmas are used to promote particle nucleation and surface growth for controlled nanomaterial synthesis. Furthermore, non-invasive diagnostics based on electromagnetic fields and electric fluid properties are relevant techniques for online control and optimization of technical processes. Finally, an overview of laser-based techniques is provided for studying electro-hydrodynamic effects, temperature, and species concentrations in plasma and electric-field enhanced processes.

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Section: Electrical Process Tomographymentioning

confidence: 99%

Overview of Electric Field Applications in Energy and Process Engineering

Zigan

2018

Energies

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“…These systems offer a high measurement precision and dynamic range, but the system error reduction of multiport MWT systems is complicated and the achievable measurement rate low in the case of a high number of required frequency samples. To overcome these drawbacks, we examined the applicability of the frequency-modulated continuous waves (FMCW) network analysis technique [30] for multiport MWT systems [31], which offers robust and computationally inexpensive system error reduction, resulting in an improved imaging accuracy and reconstruction stability.…”

Section: Data Acquisition and Signal Processingmentioning

confidence: 99%

Fast and Precise Soft-Field Electromagnetic Tomography Systems for Multiphase Flow Imaging

et al. 2018

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In the process industry, measurement systems are required for process development and optimization, as well as for monitoring and control. The processes often involve multiphase mixtures or flows that can be analyzed using tomography systems, which visualize the spatial material distribution within a certain measurement domain, e.g., a process pipe. In recent years, we studied the applicability of soft-field electromagnetic tomography methods for multiphase flow imaging, focusing on concepts for high-speed data acquisition and image reconstruction. Different non-intrusive electrical impedance and microwave tomography systems were developed at our institute, which are sensitive to the local contrasts of the electrical properties of the materials. These systems offer a very high measurement and image reconstruction rate of up to 1000 frames per second in conjunction with a dynamic range of up to 120 dB. This paper provides an overview of the underlying concepts and recent improvements in terms of sensor design, data acquisition and signal processing. We introduce a generalized description for modeling the electromagnetic behavior of the different sensors based on the finite element method (FEM) and for the reconstruction of the electrical property distribution using the Gauss-Newton method and Newton's one-step error reconstructor (NOSER) algorithm. Finally, we exemplify the applicability of the systems for different measurement scenarios. They are suitable for the analysis of rapidly-changing inhomogeneous scenarios, where a relatively low spatial resolution is sufficient.

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“…It can be observed, e.g., in [10] and [11] as well as in Section III. This is beneficial, as ( 5) and ( 4) are multiplied in (2). Thus, the realization of CN as a simple linear network generating…”

Section: Conceptmentioning

confidence: 99%

“…are distance and velocity measurements by means of FMCW radar systems [1] as well as fast vector network analysis [2]. Moreover, this measurement principle can also be applied for various applications, such as material characterization [3], biomedical sensing [4], or plasma diagnostics [5].…”

mentioning

confidence: 99%

An Ultra-Wideband Fast Frequency Ramp Synthesizer at 60 GHz With Low Noise Using a New Loop Gain Compensation Technique

Delden

Pohl

Musch

2018

IEEE Trans. Microwave Theory Techn.

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Phase-locked loops (PLLs) for ultra-wideband, low noise, and linear frequency ramp synthesis exhibit a wide variation of the loop gain, if no compensation method is applied. This impairs the performance of the PLL and the corresponding microwave measurement systems. To overcome the disadvantages of existing compensation techniques, we present a new compensation method based on a phase-frequency detector gain modulation. This offers low hardware complexity and avoids additional noise. Furthermore, we present an ultra-wideband, low noise monolithic microwave-integrated circuit for 60-GHz PLLs. Based on this, a 60-GHz frequency synthesizer with a modulation bandwidth of 22 GHz and a jitter of less than 79 fs at the center frequency are realized. The new compensation technique reduces the variation of the loop gain from 14.2:1 to 1.67:1 and is compared with an existing compensation technique utilizing a voltage-dependent damping network, which reduces the variation of the loop gain to 1.78:1. Due to the reduction of the variation of the loop gain, the maximum ramp slope increases from 22 GHz/2.9 ms up to 22 GHz/0.35 ms. In addition, the time jitter of the output signal of the PLL decreases by up to 18%. Furthermore, the PLL performance is constant in the temperature range from 0 • C to 70 • C.

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Fast and precise data acquisition for broadband microwave tomography systems

Cited by 4 publications

References 32 publications

Overview of Electric Field Applications in Energy and Process Engineering

Overview of Electric Field Applications in Energy and Process Engineering

Fast and Precise Soft-Field Electromagnetic Tomography Systems for Multiphase Flow Imaging

An Ultra-Wideband Fast Frequency Ramp Synthesizer at 60 GHz With Low Noise Using a New Loop Gain Compensation Technique

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