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220822 ||| eng |
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|a 9783036535531
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|a 9783036535548
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|a books978-3-0365-3554-8
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1 |
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|a Schmidt, Gerhard
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245 |
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|a Magnetoelectric Sensor Systems and Applications
|h Elektronische Ressource
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260 |
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|a Basel
|b MDPI - Multidisciplinary Digital Publishing Institute
|c 2022
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300 |
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|a 1 electronic resource (200 p.)
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653 |
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|a delta-E effect
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653 |
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|a application specific signal evaluation
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|a magnetoelectric sensors
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|a surface acoustic wave sensor
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|a interdisciplinary/multidisciplinary
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|a magnetron sputter deposition
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|a magnetoelectric
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|a MEMS
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|a deep brain stimulation (DBS)
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|a MEG
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|a AlScN
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|a real time
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|a resonator
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|a magnetometer
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|a exchange bias
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|a laminated structure
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|a Barkhausen noise
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|a Flicker noise
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|a torsion mode
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|a localization
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|a XRD
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|a medical sensing
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|a directional DBS electrode
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|a public understanding/outreach
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|a imaging
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|a SAW
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|a direct magnetoelectric effect
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|a magnetoactive elastomer
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|a SQUID
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|a magnetic domain networks
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|a current sensor
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|a biomagnetic sensing
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|a delay line sensor
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|a rotational orientation detection
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|a FeCoSiB
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|a magnetostriction
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|a magnetic field sensor
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|a bending mode
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|a Electricity, electromagnetism & magnetism / bicssc
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|a piezoelectric polymer
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|a sensor array
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|a surface acoustic wave
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|a phase noise
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|a quantitative sensor system characterization
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|a sensor system performance
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|a pose estimation
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|a Research & information: general / bicssc
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|a film stress
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|a Physics / bicssc
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|a cantilever
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|a magnetic nanoparticle
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|a motion tracking
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|a magnetoelastic delta-E effect
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|a magnetic field measurement
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|a electrode localization
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|a magnetic modeling
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|a magnetic domains
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|a artificial fields
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|a blind deconvolution
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|a magnetoelectric sensor
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|a magnetic properties
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|a magnetoelastic
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|a thin film
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|a magnetic noise
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|a FEM
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|a ME sensors
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|a ERDA
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|a inverse problem
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|a surface acoustic waves
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|a Kerr microscopy
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700 |
1 |
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|a Quandt, Eckhard
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700 |
1 |
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|a Sun, Nian X.
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700 |
1 |
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|a Bahr, Andreas
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041 |
0 |
7 |
|a eng
|2 ISO 639-2
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989 |
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|b DOAB
|a Directory of Open Access Books
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500 |
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|a Creative Commons (cc), https://creativecommons.org/licenses/by/4.0/
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024 |
8 |
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|a 10.3390/books978-3-0365-3554-8
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856 |
4 |
2 |
|u https://directory.doabooks.org/handle/20.500.12854/81178
|z DOAB: description of the publication
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856 |
4 |
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|u https://www.mdpi.com/books/pdfview/book/5210
|7 0
|x Verlag
|3 Volltext
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|a 000
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|a 530
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|a 700
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|a In the field of magnetic sensing, a wide variety of different magnetometer and gradiometer sensor types, as well as the corresponding read-out concepts, are available. Well-established sensor concepts such as Hall sensors and magnetoresistive sensors based on giant magnetoresistances (and many more) have been researched for decades. The development of these types of sensors has reached maturity in many aspects (e.g., performance metrics, reliability, and physical understanding), and these types of sensors are established in a large variety of industrial applications. Magnetic sensors based on the magnetoelectric effect are a relatively new type of magnetic sensor. The potential of magnetoelectric sensors has not yet been fully investigated. Especially in biomedical applications, magnetoelectric sensors show several advantages compared to other concepts for their ability, for example, to operate in magnetically unshielded environments and the absence of required cooling or heating systems. In recent years, research has focused on understanding the different aspects influencing the performance of magnetoelectric sensors. At Kiel University, Germany, the Collaborative Research Center 1261 "Magnetoelectric Sensors: From Composite Materials to Biomagnetic Diagnostics", funded by the German Research Foundation, has dedicated its work to establishing a fundamental understanding of magnetoelectric sensors and their performance parameters, pushing the performance of magnetoelectric sensors to the limits and establishing full magnetoelectric sensor systems in biological and clinical practice.
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