Your search keyword '"Trebbels, D."' showing total 5 results

1. Online Tissue Discrimination for Transcutaneous Needle Guidance Applications Using Broadband Impedance Spectroscopy

Author

Trebbels, D., primary, Fellhauer, F., additional, Jugl, M., additional, Haimerl, G., additional, Min, M., additional, and Zengerle, R., additional

Published

2012

2. TDR application for moisture content estimation in agri-food materials

Author

Egidio De Benedetto, Christof Huebner, Andrea Cataldo, Dennis Trebbels, Cataldo, Andrea, De Benedetto, Egidio, Huebner, Christof, Trebbels, Dennis, Cataldo, A., De Benedetto, E., Huebner, C., and Trebbels, D.

Subjects

business.industry, media_common.quotation_subject, 020208 electrical & electronic engineering, 010401 analytical chemistry, Use of time, 02 engineering and technology, Agricultural engineering, Raw material, 01 natural sciences, 0104 chemical sciences, Product (business), Agriculture, 0202 electrical engineering, electronic engineering, information engineering, Food processing, Environmental science, Food material, Quality (business), Electrical and Electronic Engineering, business, Water content, Instrumentation, media_common

Abstract

Cereals and legumes are invaluable resources, as they represent the raw materials of many foods and beverages. Cereals are also largely used as livestock feeds, thus indirectly influencing the quality of dairy products and meat. Because of their key role in human nutrition and well-being, the safety and quality of these agri-food materials are extremely important topics in food science. In this regard, moisture content is one of the ultimate factors influencing the quality, safety and price of the final food product; hence, it is crucial to monitor water content of materials in the food production line. Starting from these considerations, this paper describes the use of time domain reflectometry (TDR) for both in-line and off-line moisture content sensing of agrifood materials. In particular, after a brief description of the basic principles of TDR, two representative application cases for moisture content measurements of agri-food materials are reported and commented on.

Published

2017

3. Performance comparison of TDR-based systems for permanent and diffused detection of water content and leaks

Author

E. De Benedetto, Andrea Cataldo, Christof Huebner, G. Cannazza, Dennis Trebbels, Cataldo, A., De Benedetto, E., Cannazza, G., Huebner, C., Trebbels, D., Cataldo, Andrea Maria, DE BENEDETTO, Egidio, Cannazza, Giuseppe, and Huebner, C

Subjects

Applied Mathematics, Instrumentation, 020208 electrical & electronic engineering, Real-time computing, 02 engineering and technology, Soil moisture content, 01 natural sciences, Time domain reflectometry, 010309 optics, Water leak detection, Dielectric permittivity, Performance comparison, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Time domain, Reflectometry, Engineering (miscellaneous), Water content, time domain reflectometry, soil moisture content, water leak detection, dielectric permittivity

Abstract

In this work, the performance of three time domain reflectometry (TDR) instruments (with different hardware architectures, specifications and costs) is comparatively assessed. The goal is to evaluate the performance of low-cost TDR instrumentation, in view of the development of a completely permanent TDR-based monitoring solution, wherein the costs of the instrument is so low, that it can be left on-site, even unguarded, and controlled remotely. Without losing generality, the applications considered for the comparative experiments are the TDR-based detection of leaks in underground pipes and, more in general, of soil water content variations. For this reason, both laboratory and in-the-field experiments are carried out by comparatively using three TDR instruments, in conjunction with wire-like sensing elements (SEs).

Published

2017

4. Controlling the irrigation process in agriculture through elongated TDR-sensing cables

Author

Giuseppe Maria D'Aucelli, Dennis Trebbels, Christof Huebner, Egidio De Benedetto, Nicola Giaquinto, Giuseppe Cannazza, Andrea Cataldo, Cataldo, Andrea, De Benedetto, Egidio, Cannazza, Giuseppe, Huebner, Christof, Trebbels, Denni, Giaquinto, Nicola, D'Aucelli, Giuseppe M., Cataldo, A., De Benedetto, E., Cannazza, G., Huebner, C., Trebbels, D., Giaquinto, N., and D'Aucelli, G. M.

Subjects

Engineering, Irrigation, Sensor networks, business.industry, 020208 electrical & electronic engineering, 010401 analytical chemistry, Bifilar coil, Process (computing), Biomedical Engineering, Agriculture, 02 engineering and technology, 01 natural sciences, 0104 chemical sciences, Soil water, Signal Processing, 0202 electrical engineering, electronic engineering, information engineering, Soil moisture, Time domain, Reflectometry, business, Water content, Wireless sensor network, Instrumentation, Remote sensing

Abstract

In this work, time domain reflectometry (TDR) is used in conjunction with an innovative type of low-cost, wirelike diffused sensor for diffused soil water content monitoring in agriculture. Thanks to its wire-like configuration, these passive, maintenance-free sensors can be rolled out and buried along the perimeter/path to be monitored (for example, along a row of plants/trees). A single sensor can be long up to 150 meters, and several sensors can be simultaneously installed in a large area, thus creating a diffused sensor network which can be controlled through a single measurement instrument. To assess the practical feasibility of the proposed TDR-based system, a practical experiment was carried out by employing a bifilar, wire-like sensing element (SE) for monitoring soil water content in a watermelon cultivation. For comparative purposes, also in view of continuous remote monitoring, measurements were carried out through three TDR instruments with different specifications and costs.

Published

2017

5. Robust Soil Water Potential Sensor to Optimize Irrigation in Agriculture.

Author

Menne D, Hübner C, Trebbels D, and Willenbacher N

Subjects

Agriculture, Porosity, Soil, Water analysis

Abstract

Extreme weather phenomena are on the rise due to ongoing climate change. Therefore, the need for irrigation in agriculture will increase, although it is already the largest consumer of water, a valuable resource. Soil moisture sensors can help to use water efficiently and economically. For this reason, we have recently presented a novel soil moisture sensor with a high sensitivity and broad measuring range. This device does not measure the moisture in the soil but the water available to plants, i.e., the soil water potential (SWP). The sensor consists of two highly porous (>69%) ceramic discs with a broad pore size distribution (0.5 to 200 μm) and a new circuit board system using a transmission line within a time-domain transmission (TDT) circuit. This detects the change in the dielectric response of the ceramic discs with changing water uptake. To prove the concept, a large number of field tests were carried out and comparisons were made with commercial soil water potential sensors. The experiments confirm that the sensor signal is correlated to the soil water potential irrespective of soil composition and is thus suitable for the optimization of irrigation systems.

Published

2022