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Anders, Jens

Jens Anders

Prof. Dr.

Institute Director
Institute of Smart Sensors

Contact

+49 711 685 67250
Email

Pfaffenwaldring 47
70569 Stuttgart
Deutschland
Room: 3.114

Office Hours

By appointment

Please contact Bärbel Groß

Publications

Journals, conferences, and books:

2024
1. L. Marti et al., “Towards optical MAS magnetic resonance using optical traps,” Journal of Magnetic Resonance Open, vol. 18, p. 100145, 2024, doi: https://doi.org/10.1016/j.jmro.2023.100145.
  BibTeX
  @article{MARTI2024100145, abstract = {Higher magic angle spinning (MAS) frequencies than currently available are desirable to improve spectral resolution in NMR and EPR systems. While conventional strategies employ pneumatic spinning limited by fluid dynamics, this paper demonstrates the development of an optical spinning technique in which vacuum quality dictates the maximum achievable spinning frequency. Using optical traps, we levitated a range of micron-sized samples. Under vacuum we achieved optical rotation of a single ∼10 μm diameter particle of vaterite at several mbar up to hundreds of Hz and of 20 μm diameter SiO2 particles at ≤10−2 mbar at several kHz. At ambient conditions, we optically levitated γ-irradiated alanine particles of 20–50 μm diameter. Additionally, using a single chip EPR detector operating at 11 GHz, we measured the EPR spectrum for a 30 μm γ-irradiated alanine particle in contact with the chip surface (i.e., without optical levitation) in a single scan lasting 92 s. These observations suggest that a γ-irradiated alanine particle having a diameter in the order of 30 μm is a promising candidate for our aim of demonstrating the first magnetic resonance experiment on optically levitated samples. Furthermore, we discuss strategies, limitations, and the potential of implementing MAS with optical traps for NMR and EPR.}, author = {Marti, Lea and {Şahin Solmaz}, Nergiz and Kern, Michal and Chu, Anh and Farsi, Reza and Hengel, Philipp and Gao, Jialiang and Alaniva, Nicholas and Urban, Michael A. and Gunzenhauser, Ronny and Däpp, Alexander and Klose, Daniel and Anders, Jens and Boero, Giovanni and Novotny, Lukas and Frimmer, Martin and Barnes, Alexander B.}, doi = {https://doi.org/10.1016/j.jmro.2023.100145}, issn = {2666-4410}, journal = {Journal of Magnetic Resonance Open}, pages = 100145, title = {Towards optical MAS magnetic resonance using optical traps}, url = {https://www.sciencedirect.com/science/article/pii/S2666441023000535}, volume = 18, year = 2024 }
  Link
  https://www.sciencedirect.com/science/article/pii/S2666441023000535
  DOI
  https://doi.org/10.1016/j.jmro.2023.100145
2. Q. Yang et al., “A chip-based C-band ODNP platform,” Journal of Magnetic Resonance, vol. 358, p. 107603, Jan. 2024, doi: 10.1016/j.jmr.2023.107603.
  BibTeX
  @article{Yang_2024, author = {Yang, Qing and Zhao, Jianyu and Dreyer, Frederik and Krüger, Daniel and Chu, Anh and Kern, Michal and Blümich, Bernhard and Anders, Jens}, doi = {10.1016/j.jmr.2023.107603}, issn = {1090-7807}, journal = {Journal of Magnetic Resonance}, month = {01}, pages = 107603, publisher = {Elsevier BV}, title = {A chip-based C-band ODNP platform}, url = {http://dx.doi.org/10.1016/j.jmr.2023.107603}, volume = 358, year = 2024 }
  Link
  http://dx.doi.org/10.1016/j.jmr.2023.107603
  DOI
  10.1016/j.jmr.2023.107603
2023
1. A. Chu, M. Kern, K. Khan, K. LiPS, and J. Anders, “A 263GHz 32-Channel EPR-on-a-Chip Injection-Locked VCO-Array,” in 2023 IEEE International Solid- State Circuits Conference (ISSCC), in 2023 IEEE International Solid- State Circuits Conference (ISSCC). Feb. 2023, pp. 20–22. doi: 10.1109/ISSCC42615.2023.10067623.
  - BibTeX
  - DOI
  BibTeX
  @inproceedings{10067623, abstract = {Electron paramagnetic resonance (EPR) spectroscopy is a powerful technique that uses the spin of an unpaired electron as a nanoscopic probe inside a molecule to extract information about its chemical structure and composition as well as its surroundings via small changes in its resonance frequency, see Fig. 21.4.1 (left). EPR has applications in studying and monitoring a wide range of materials, starting from defects in semiconductors over free radicals in the blood to metal catalysts in hydrogen fuel production. EPR measurements are typically performed in moderate static magnetic fields around 0.3T, corresponding to EPR frequencies around $9\mathsf{GHz}$. This combination of field and frequency is commonly used due to the relative ease of generation of 0 $3\mathsf{T}$ magnetic fields with sufficient homogeneity as well as the required $9\mathsf{GHz}$ frequency signal. However, access to higher frequencies and fields is strongly desirable due to higher spin polarization (with corresponding increased signal amplitude), higher spectral resolution, which allows, e.g., the determination of electronic and geometric structures of active centers in enzymes, and access to higher energy electronic transitions, such as those found in metal complexes or materials interesting for antiferromagnetic spintronics, explaining the ongoing research towards high-frequency EPR (HFEPR) with operating frequencies beyond $90\mathsf{GHz}$. Here, another strong driver of HFEPR is the field of dynamic nuclear polarization (DNP), a method that can be used to boost the relatively poor sensitivity of nuclear magnetic resonance (NMR) by transferring the intrinsically higher electron polarization to the nuclear spins. Today, there are only a few commercial HFEPR-based DNP spectrometers on the market, with the most popular ones operating at an EPR frequency of $263\mathsf{GHz}(9.4\mathsf{T})$, corresponding to a proton NMR frequency of $400\mathsf{MHz}$. These instruments use gyrotron as the source for the mm-wave magnetic field ($\mathsf{B}_{1}$ field) and cost far beyond 1 million €.}, author = {Chu, Anh and Kern, Michal and Khan, Khubaib and LiPS, Klaus and Anders, Jens}, booktitle = {2023 IEEE International Solid- State Circuits Conference (ISSCC)}, doi = {10.1109/ISSCC42615.2023.10067623}, issn = {2376-8606}, month = {02}, pages = {20-22}, title = {A 263GHz 32-Channel EPR-on-a-Chip Injection-Locked VCO-Array}, year = 2023 }
  DOI
  10.1109/ISSCC42615.2023.10067623
2. F. Dreyer, D. Krüger, S. Baas, A. Velders, and J. Anders, “A 5-780-MHz Transceiver ASIC for Multinuclear NMR Spectroscopy in 0.13-µm BiCMOS,” IEEE Transactions on Circuits and Systems I: Regular Papers, vol. 70, pp. 3484–3496, Sep. 2023, doi: 10.1109/TCSI.2023.3279495.
  BibTeX
  @article{dreyer20235, author = {Dreyer, Frederik and Kr{\"u}ger, Daniel and Baas, Sander and Velders, Aldrik and Anders, Jens}, doi = {10.1109/TCSI.2023.3279495}, journal = {IEEE Transactions on Circuits and Systems I: Regular Papers}, month = {09}, pages = {3484-3496}, publisher = {IEEE}, title = {A 5-780-MHz Transceiver ASIC for Multinuclear NMR Spectroscopy in 0.13-µm BiCMOS}, url = {https://ieeexplore.ieee.org/document/10143362}, volume = 70, year = 2023 }
  Link
  https://ieeexplore.ieee.org/document/10143362
  DOI
  10.1109/TCSI.2023.3279495
3. F. Dreyer, Q. Yang, B. Alnajjar, D. Krüger, B. Blümich, and J. Anders, “A portable chip-based NMR relaxometry system with arbitrary phase control for point-of-care blood analysis,” IEEE Transactions on Biomedical Circuits and Systems (Early Access), pp. 1–12, 2023, doi: 10.1109/TBCAS.2023.3287281.
  - BibTeX
  - DOI
  BibTeX
  @article{dreyer2023portable, author = {Dreyer, Frederik and Yang, Qing and Alnajjar, Belal and Kr{\"u}ger, Daniel and Bl{\"u}mich, Bernhard and Anders, Jens}, doi = {10.1109/TBCAS.2023.3287281}, journal = {IEEE Transactions on Biomedical Circuits and Systems (Early Access)}, pages = {1-12}, publisher = {IEEE}, title = {A portable chip-based NMR relaxometry system with arbitrary phase control for point-of-care blood analysis}, year = 2023 }
  DOI
  10.1109/TBCAS.2023.3287281
4. M. Kern, T. Klotz, M. Spiess, P. Mavridis, B. Blümich, and J. Anders, “Dead Time-Free Detection of NMR Signals Using Voltage-Controlled Oscillators,” Applied Magnetic Resonance, Aug. 2023, doi: 10.1007/s00723-023-01599-8.
  BibTeX
  @article{Kern2023, abstract = {In this paper, we introduce voltage-controlled oscillators (VCOs) as a new type of nuclear magnetic resonance (NMR) detector, enabling dead time-free detection of NMR signals after an excitation pulse as well as the real-time inductive detection of Rabi oscillations during the pulse. Together with the theory of operation, we present the details of a custom-designed prototype implementation of a VCO-based NMR detector with an operating frequency around 62 MHz. The proof-of-concept measurements obtained with this prototype clearly demonstrate the possibility of performing dead time-free NMR experiments with coherent spin manipulation. Moreover, we also experimentally verified the capability of VCO-based detectors for performing real-time inductive detection of Rabi oscillations during the excitation pulse.}, author = {Kern, Michal and Klotz, Tobias and Spiess, Maximilian and Mavridis, Petros and Bl{\"u}mich, Bernhard and Anders, Jens}, day = 29, doi = {10.1007/s00723-023-01599-8}, issn = {1613-7507}, journal = {Applied Magnetic Resonance}, month = {08}, title = {Dead Time-Free Detection of NMR Signals Using Voltage-Controlled Oscillators}, url = {https://doi.org/10.1007/s00723-023-01599-8}, year = 2023 }
  Link
  https://doi.org/10.1007/s00723-023-01599-8
  DOI
  10.1007/s00723-023-01599-8
5. K. Khan, M. A. Hassan, M. Kern, and J. Anders, “A 12.2 − 14.9 GHz amplitude-sensitive VCO-based EPR-on-a-chip detector achieving a spin sensitivity of 6 × 109 spins/ √ Hz,” in 2023 18th European Microwave Integrated Circuits Conference (EuMIC), in 2023 18th European Microwave Integrated Circuits Conference (EuMIC). IEEE, Sep. 2023. doi: 10.23919/eumic58042.2023.10288693.
  BibTeX
  @inproceedings{Khan_2023, author = {Khan, Khubaib and Hassan, Mohamed Atef and Kern, Michal and Anders, Jens}, booktitle = {2023 18th European Microwave Integrated Circuits Conference (EuMIC)}, doi = {10.23919/eumic58042.2023.10288693}, month = {09}, publisher = {IEEE}, title = {A 12.2 − 14.9 GHz amplitude-sensitive VCO-based EPR-on-a-chip detector achieving a spin sensitivity of 6 × 109 spins/ √ Hz}, url = {http://dx.doi.org/10.23919/EuMIC58042.2023.10288693}, year = 2023 }
  Link
  http://dx.doi.org/10.23919/EuMIC58042.2023.10288693
  DOI
  10.23919/eumic58042.2023.10288693
6. H. Lotfi et al., “A Diamond Quantum Magnetometer Based on a Chip-Integrated 4-way Transmitter in 130-nm SiGe BiCMOS,” in 2023 IEEE Radio Frequency Integrated Circuits Symposium (RFIC), in 2023 IEEE Radio Frequency Integrated Circuits Symposium (RFIC). Jun. 2023, pp. 253–256. doi: 10.1109/RFIC54547.2023.10186184.
  - BibTeX
  - DOI
  BibTeX
  @inproceedings{10186184, abstract = {Solid-state magnetometers based on color centers in diamond are emerging as one of the leading quantum sensors due to their outstanding room-temperature properties, such as high sensitivity and calibration-free long-term stability. However, their integration into compact systems is still an active area of research. To tackle this challenge, in this paper, we present a quantum magnetometer based on negatively charged nitrogen-vacancy (NV) centers using a custom-designed, chip-integrated 4-way transmitter. In combination with a custom-designed microcoil array, the 4-way transmitter delivers microwave magnetic fields up to 226 µT for carrier frequencies around 7 GHz with a conversion gain of ≥32 dB to NV centers. The local oscillator (LO) signal required to drive the on-chip quadrature upconversion mixer is generated by a custom-designed quadrature PLL, which provides a 22% tuning range between 6.4 and 8 GHz, and a low phase noise of -122 dBc/Hz at 1 MHz offset from a 7 GHz carrier, to enable broadband, low-noise magnetometry. To verify the excellent performance of the integrated electronics, we have embedded them into a widefield diamond magnetometer using off-chip scanning optics, achieving a state-of-the-art AC-magnetic field limit of detection of 300 pT/Hz1/2.}, author = {Lotfi, Hadi and Kern, Michal and Striegler, Nico and Unden, Thomas and Scharpf, Jochen and Schalberger, Patrick and Schwartz, Ilai and Neumann, Philipp and Anders, Jens}, booktitle = {2023 IEEE Radio Frequency Integrated Circuits Symposium (RFIC)}, doi = {10.1109/RFIC54547.2023.10186184}, issn = {2375-0995}, month = {06}, pages = {253-256}, title = {A Diamond Quantum Magnetometer Based on a Chip-Integrated 4-way Transmitter in 130-nm SiGe BiCMOS}, year = 2023 }
  DOI
  10.1109/RFIC54547.2023.10186184
2022
1. A. Buchau and J. Anders, “CHARACTERIZATION OF VECTOR FIELDS BASED ON AN ANALYSIS OF THEIR LOCAL EXPANSIONS,” in WIT Transactions on Engineering Sciences, A. Cheng, Ed., in WIT Transactions on Engineering Sciences, vol. 134. WIT Press, Aug. 2022, pp. 17–29. doi: 10.2495/be450021.
 BibTeX
 @inproceedings{BUCHAU_2022, author = {Buchau, André and Anders, Jens}, booktitle = {WIT Transactions on Engineering Sciences}, doi = {10.2495/be450021}, editor = {Cheng, A.}, month = {08}, pages = {17-29}, publisher = {WIT Press}, title = {CHARACTERIZATION OF VECTOR FIELDS BASED ON AN ANALYSIS OF THEIR LOCAL EXPANSIONS}, url = {https://doi.org/10.2495%2Fbe450021}, volume = 134, year = 2022 }
 Link
 https://doi.org/10.2495%2Fbe450021
 DOI
 10.2495/be450021
2. F. Dreyer, D. Krüger, S. Baas, A. Velders, and J. Anders, “A broadband transceiver ASIC for X-nuclei NMR spectroscopy in 0.13 $\mu$m BiCMOS,” in 2022 20th IEEE Interregional NEWCAS Conference (NEWCAS), in 2022 20th IEEE Interregional NEWCAS Conference (NEWCAS). IEEE, 2022, pp. 65--69.
 - BibTeX
 BibTeX
 @inproceedings{dreyer2022broadband, author = {Dreyer, Frederik and Kr{\"u}ger, Daniel and Baas, Sander and Velders, Aldrik and Anders, Jens}, booktitle = {2022 20th IEEE Interregional NEWCAS Conference (NEWCAS)}, organization = {IEEE}, pages = {65--69}, title = {A broadband transceiver ASIC for X-nuclei NMR spectroscopy in 0.13 $\mu$m BiCMOS}, year = 2022 }
3. F. Dreyer, D. Krüger, S. Baas, A. Velders, and J. Anders, “A broadband transceiver ASIC for X-nuclei NMR spectroscopy in 0.13 µm BiCMOS,” in 2022 20th IEEE Interregional NEWCAS Conference (NEWCAS), in 2022 20th IEEE Interregional NEWCAS Conference (NEWCAS). IEEE, 2022, pp. 65--69.
 - BibTeX
 BibTeX
 @inproceedings{dreyer2022broadband, author = {Dreyer, Frederik and Kr{\"u}ger, Daniel and Baas, Sander and Velders, Aldrik and Anders, Jens}, booktitle = {2022 20th IEEE Interregional NEWCAS Conference (NEWCAS)}, organization = {IEEE}, pages = {65--69}, title = {A broadband transceiver ASIC for X-nuclei NMR spectroscopy in 0.13 µm BiCMOS}, year = 2022 }
4. F. Dreyer, Q. Yang, D. Krüger, and J. Anders, “A chip-based NMR relaxometry system for point-of-care analysis,” 2022 IEEE Biomedical Circuits and Systems Conference (BioCAS), pp. 183–187, 2022.
 - BibTeX
 BibTeX
 @article{dreyer2022biocas, author = {Dreyer, Frederik and Yang, Qing and Krüger, Daniel and Anders, Jens}, journal = {2022 IEEE Biomedical Circuits and Systems Conference (BioCAS)}, pages = {183-187}, title = {A chip-based NMR relaxometry system for point-of-care analysis}, year = 2022 }
5. T. Elrifai, A. Sakr, H. Lotfi, M. A. Hassan, K. Lips, and J. Anders, “A 7 GHz VCO-based EPR spectrometer incorporating a UWB data link,” in 2022 20th IEEE Interregional NEWCAS Conference (NEWCAS), in 2022 20th IEEE Interregional NEWCAS Conference (NEWCAS). Jun. 2022, pp. 280–284. doi: 10.1109/NEWCAS52662.2022.9842254.
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 BibTeX
 @inproceedings{9842254, abstract = {This paper presents an electron paramagnetic resonance (EPR) detection system that can wirelessly transmit continuous wave (CW) EPR data over distances up to 30 cm with minimal degradations in SNR. The proposed system comprises a VCO-based EPR-on-a-chip (EPRoC) sensor with a spin sensitivity of $2 \times {10^{12}}\;{\text{spins}}/\sqrt {{\text{Hz}}} $, a 14-bit oversampling ΣΔ-modulator, a 7 GHz bandwidth-tunable ultra-wideband (UWB) transmitter chip, and a custom-designed 2 GHz-bandwidth elliptical dipole antenna. On the receiver side, we directly digitize the antenna signal and recover the EPR signal in the digital domain via a discrete Fourier transform (DFT)-based demodulation scheme. The presented platform is the first wirelessly connected EPR detection system that allows for in-situ EPR experiments using EPRoC detectors under variable operation conditions while enabling direct wireless access to the experimental data. The estimated bit error rate (BER) of the link at a distance of 10 cm from the transmitter is 1×10-7.}, author = {Elrifai, Tarek and Sakr, Ayman and Lotfi, Hadi and Hassan, Mohamed Atef and Lips, Klaus and Anders, Jens}, booktitle = {2022 20th IEEE Interregional NEWCAS Conference (NEWCAS)}, doi = {10.1109/NEWCAS52662.2022.9842254}, month = {06}, pages = {280-284}, title = {A 7 GHz VCO-based EPR spectrometer incorporating a UWB data link}, year = 2022 }
 DOI
 10.1109/NEWCAS52662.2022.9842254
6. M. A. Hassan et al., “Towards single-cell pulsed EPR using VCO-based EPR-on-a-chip detectors,” Frequenz, vol. 76, no. 11–12, Art. no. 11–12, 2022, doi: doi:10.1515/freq-2022-0096.
 BibTeX
 @article{HassanKernChuKalraShabratovaTsarapkinMacKinnonLipsTeutloffBittlKorvinkAnders+2022+699+717, author = {Hassan, Mohamed Atef and Kern, Michal and Chu, Anh and Kalra, Gatik and Shabratova, Ekaterina and Tsarapkin, Aleksei and MacKinnon, Neil and Lips, Klaus and Teutloff, Christian and Bittl, Robert and Korvink, Jan Gerrit and Anders, Jens}, doi = {doi:10.1515/freq-2022-0096}, journal = {Frequenz}, number = {11-12}, pages = {699--717}, title = {Towards single-cell pulsed EPR using VCO-based EPR-on-a-chip detectors}, url = {https://doi.org/10.1515/freq-2022-0096}, volume = 76, year = 2022 }
 Link
 https://doi.org/10.1515/freq-2022-0096
 DOI
 doi:10.1515/freq-2022-0096
7. K. Khan et al., “A 12.2 to 14.9 GHz injection-locked VCO array with an on-chip 50 MHz BW semi-digital PLL for transient spin manipulation and detection,” in 2022 IEEE 65th International Midwest Symposium on Circuits and Systems (MWSCAS), in 2022 IEEE 65th International Midwest Symposium on Circuits and Systems (MWSCAS). Aug. 2022, pp. 1–4. doi: 10.1109/MWSCAS54063.2022.9859288.
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 BibTeX
 @inproceedings{9859288, abstract = {We present an injection-locked 12.2 to 14.9 GHz VCO array with an on-chip large bandwidth semi-digital PLL for the real-time manipulation and detection of electron spins. With its large bandwidth of 50 MHz, the on-chip PLL allows for the precise control of the phase of the electron spins from an external reference. Moreover, we demonstrate experimentally that the spin signal can be measured with high sensitivity outside the PLL loop bandwidth by FM demodulation of the frequency-divided VCO output signal. The system was manufactured in 40nm bulk CMOS technology and its versatility and performance are verified in continuous-wave, rapid scan, and pulsed EPR experiments. In these experiments, it achieves a competitive spin sensitivity of $6 \times 10^{10}$ spins/$\surd {Hz}$ over a large sensitive volume of 180 nl. Moreover, the presented system, for the first time, allowed for the real-time inductive detection of Rabi oscillations as well as an intrinsically dead-time-free detection of free induction decays (FIDs) after an excitation pulse.}, author = {Khan, Khubaib and Hassan, Mohamed Atef and Kern, Michal and Lips, Klaus and Schwartz, Ilai and Plenio, Martin and Jelezko, Fedor and Anders, Jens}, booktitle = {2022 IEEE 65th International Midwest Symposium on Circuits and Systems (MWSCAS)}, doi = {10.1109/MWSCAS54063.2022.9859288}, issn = {1558-3899}, month = {08}, pages = {1-4}, title = {A 12.2 to 14.9 GHz injection-locked VCO array with an on-chip 50 MHz BW semi-digital PLL for transient spin manipulation and detection}, year = 2022 }
 DOI
 10.1109/MWSCAS54063.2022.9859288
8. H. Lotfi, M. A. Hassan, M. Kern, and J. Anders, “A Compact C-band EPR-on-a-chip Transceiver in 130-nm SiGe BiCMOS,” in 2022 17th Conference on Ph.D Research in Microelectronics and Electronics (PRIME), in 2022 17th Conference on Ph.D Research in Microelectronics and Electronics (PRIME). Jun. 2022, pp. 157–160. doi: 10.1109/PRIME55000.2022.9816822.
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 - DOI
 BibTeX
 @inproceedings{9816822, abstract = {We present a chip-integrated C-band transceiver for electron paramagnetic resonance (EPR) spectroscopy, implemented in a 130-nm SiGe BiCMOS technology. The presented EPR-on-a-chip transceiver displays an excellent minimum in-band noise Figure of 0.82 dB and a peak in-band output power $P_{\mathrm{sat}}$ of 9.8 dBm. Furthermore, the presented chip provides a wide operating frequency range from 6 GHz to 8 GHz, which is crucial for detecting wideband EPR signals. The receiver and two-stage four-way combined power amplifier provide (conversion) gains of 32.8 dB and 13 dB, respectively. In proof-of-concept EPR measurements using an off-chip PCB coil as a detector and the standard EPR sample BDPA ($\alpha,\gamma$-bisdiphenylene-$\beta$-phenylallyl), the presented chip achieves a competitive spin sensitivity of $8\times 10^{10}$ spins/$\sqrt{\mathrm{Hz}}$ over an active volume of 31 n1.}, author = {Lotfi, Hadi and Hassan, Mohamed Atef and Kern, Michal and Anders, Jens}, booktitle = {2022 17th Conference on Ph.D Research in Microelectronics and Electronics (PRIME)}, doi = {10.1109/PRIME55000.2022.9816822}, month = {06}, pages = {157-160}, title = {A Compact C-band EPR-on-a-chip Transceiver in 130-nm SiGe BiCMOS}, year = 2022 }
 DOI
 10.1109/PRIME55000.2022.9816822
9. A. Mohamed and J. Anders, “An ultra-low-noise frontend for magnetoresistive sensors,” EUROPRACTICE activity report 2021 - 2022, pp. 48–49, Mar. 2022, [Online]. Available: https://europractice-ic.com/wp-content/uploads/2022/03/europractice_ar2021_web_150dpi.pdf
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 - Link
 BibTeX
 @article{mohamedultralownoise, author = {Mohamed, Ayman and Anders, Jens}, journal = {EUROPRACTICE activity report 2021 - 2022}, month = {03}, pages = {48-49}, title = {An ultra-low-noise frontend for magnetoresistive sensors}, url = {https://europractice-ic.com/wp-content/uploads/2022/03/europractice_ar2021_web_150dpi.pdf}, year = 2022 }
 Link
 https://europractice-ic.com/wp-content/uploads/2022/03/europractice_ar2021_web_150dpi.pdf
10. A. Sakr, M. A. Hassan, K. Khan, M. Kern, and J. Anders, “A distributed amplitude control loop for VCO-array-based EPR-on-a-chip detectors,” in 2022 17th Conference on Ph.D Research in Microelectronics and Electronics (PRIME), in 2022 17th Conference on Ph.D Research in Microelectronics and Electronics (PRIME). Jun. 2022, pp. 13–16. doi: 10.1109/PRIME55000.2022.9816840.
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 BibTeX
 @inproceedings{9816840, abstract = {This paper presents an amplitude control loop (ACL) for VCO-array-based electron paramagnetic resonance (EPR) detectors. The proposed ACL enhances the microwave magnetic field (B<inf>1</inf>) stability over the whole VCO frequency sweep range, against different sample environments and at varying experimental conditions. By introducing a distributed amplitude detection scheme, the proposed ACL implementation can regulate B<inf>1</inf> field intensities in injection-locked VCO arrays with reduced loading effects and minimal phase noise degradation. Extracted-level circuit simulations on an example VCO array implementation demonstrate the functionality and excellent achievable performance of the proposed approach.}, author = {Sakr, Ayman and Hassan, Mohamed Atef and Khan, Khubaib and Kern, Michal and Anders, Jens}, booktitle = {2022 17th Conference on Ph.D Research in Microelectronics and Electronics (PRIME)}, doi = {10.1109/PRIME55000.2022.9816840}, month = {06}, pages = {13-16}, title = {A distributed amplitude control loop for VCO-array-based EPR-on-a-chip detectors}, year = 2022 }
 DOI
 10.1109/PRIME55000.2022.9816840
11. Q. Yang, J. Zhao, F. Dreyer, D. Krüger, and J. Anders, “A portable NMR platform with arbitrary phase control and temperature compensation,” Magnetic Resonance, vol. 3, no. 1, Art. no. 1, 2022.
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 BibTeX
 @article{yang2022portable, author = {Yang, Qing and Zhao, Jianyu and Dreyer, Frederik and Kr{\"u}ger, Daniel and Anders, Jens}, journal = {Magnetic Resonance}, number = 1, pages = {77--90}, publisher = {Copernicus GmbH}, title = {A portable NMR platform with arbitrary phase control and temperature compensation}, volume = 3, year = 2022 }
12. Q. Yang, J. Zhao, F. Dreyer, D. Krüger, and J. Anders, “A CMOS-based NMR platform with arbitrary phase control and temperature compensation,” Magnetic Resonance, vol. 3, no. 1, Art. no. 1, 2022, doi: 10.5194/mr-3-77-2022.
 BibTeX
 @article{yang2022cmos, author = {Yang, Qing and Zhao, Jianyu and Dreyer, Frederik and Krüger, Daniel and Anders, Jens}, doi = {10.5194/mr-3-77-2022}, journal = {Magnetic Resonance}, number = 1, pages = {77-90}, publisher = {Copernicus GmbH}, title = {A CMOS-based NMR platform with arbitrary phase control and temperature compensation}, url = {https://mr.copernicus.org/articles/3/77/2022/}, volume = 3, year = 2022 }
 Link
 https://mr.copernicus.org/articles/3/77/2022/
 DOI
 10.5194/mr-3-77-2022
13. J. Zhao, Q. Yang, F. Dreyer, D. Krüger, F. Jelezko, and J. Anders, “A Broadband NMR Magnetometer System with Field Searching and Automatic Tuning Function,” IEEE Transactions on Instrumentation and Measurement, 2022, doi: 10.1109/TIM.2022.3222484.
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 BibTeX
 @article{zhao2022, author = {Zhao, Jianyu and Yang, Qing and Dreyer, Frederik and Krüger, Daniel and Jelezko, Fedor and Anders, Jens}, doi = {10.1109/TIM.2022.3222484}, journal = {IEEE Transactions on Instrumentation and Measurement}, title = {A Broadband NMR Magnetometer System with Field Searching and Automatic Tuning Function}, year = 2022 }
 DOI
 10.1109/TIM.2022.3222484
2021
1. J. Abella et al., “Security, Reliability and Test Aspects of the RISC-V Ecosystem,” in 2021 IEEE European Test Symposium (ETS), in 2021 IEEE European Test Symposium (ETS). May 2021, pp. 1–10. doi: 10.1109/ETS50041.2021.9465449.
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 BibTeX
 @inproceedings{9465449, abstract = {RISC-V has emerged as a viable solution on academia and industry. However, to use open source hardware for safety-critical applications, we need a deep understanding of the way in which well established mechanisms for testing and reliability could be integrated and deployed on the RISC-V ecosystem, and we need a clear knowledge on how such an ecosystem can be leveraged to improve security. This paper includes four contributions presenting the potential of RISC-V in security research, the way in which RISC-V can be hardened against power analysis attacks, how to implement, using RISC-V, software and hardware/software solutions for dual core lock step, and how to perform system-level testing in the RISC-V ecosystem.}, author = {Abella, Jaume and Alcaide, Sergi and Anders, Jens and Bas, Francisco and Becker, Steffen and De Mulder, Elke and Elhamawy, Nourhan and Gürkaynak, Frank K. and Handschuh, Helena and Hernandez, Carles and Hutter, Mike and Kosmidis, Leonidas and Polian, Ilia and Sauer, Matthias and Wagner, Stefan and Regazzoni, Francesco}, booktitle = {2021 IEEE European Test Symposium (ETS)}, doi = {10.1109/ETS50041.2021.9465449}, issn = {1558-1780}, month = {05}, pages = {1-10}, title = {Security, Reliability and Test Aspects of the RISC-V Ecosystem}, year = 2021 }
 DOI
 10.1109/ETS50041.2021.9465449
2. B. M. K. Alnajjar, A. Buchau, L. Baumgärtner, and J. Anders, “NMR magnets for portable applications using 3D printed materials,” vol. 326, p. 106934, May 2021, doi: 10.1016/j.jmr.2021.106934.
 BibTeX
 @article{2021, author = {Alnajjar, Belal M.K. and Buchau, Andr{\'{e}} and Baumgärtner, Lars and Anders, Jens}, doi = {10.1016/j.jmr.2021.106934}, month = {05}, pages = 106934, publisher = {Elsevier {BV}}, title = {{NMR} magnets for portable applications using 3D printed materials}, url = {https://doi.org/10.1016%2Fj.jmr.2021.106934}, volume = 326, year = 2021 }
 Link
 https://doi.org/10.1016%2Fj.jmr.2021.106934
 DOI
 10.1016/j.jmr.2021.106934
3. B. M. K. Alnajjar, A. Buchau, L. Baumgártner, and J. Anders, “NMR magnets for portable applications using 3D printed materials,” Journal of Magnetic Resonance, p. 106934, Feb. 2021, doi: 10.1016/j.jmr.2021.106934.
 BibTeX
 @article{alnajjar2021magnets, author = {Alnajjar, Belal M.K. and Buchau, Andr{\'{e}} and Baumg{\'{a}}rtner, Lars and Anders, Jens}, doi = {10.1016/j.jmr.2021.106934}, journal = {Journal of Magnetic Resonance}, month = {02}, pages = 106934, publisher = {Elsevier {BV}}, title = {{NMR} magnets for portable applications using 3D printed materials}, url = {https://doi.org/10.1016%2Fj.jmr.2021.106934}, year = 2021 }
 Link
 https://doi.org/10.1016%2Fj.jmr.2021.106934
 DOI
 10.1016/j.jmr.2021.106934
4. J. Anders, “spins-to-go – Miniaturisierte magnetresonanzspektrometer Die Kernspinresonanzspektroskopie,” 2021, doi: 10.26125/HTFF-4J02.
 BibTeX
 @article{https://doi.org/10.26125/htff-4j02, author = {Anders, Jens}, doi = {10.26125/HTFF-4J02}, language = {de}, publisher = {Deutsche Bunsen-Gesellschaft für physikalische Chemie e.V.}, title = {spins-to-go – Miniaturisierte magnetresonanzspektrometer Die Kernspinresonanzspektroskopie}, url = {https://bunsen.de/bmo/spins-to-go}, year = 2021 }
 Link
 https://bunsen.de/bmo/spins-to-go
 DOI
 10.26125/HTFF-4J02
5. J. Anders, F. Dreyer, D. Krüger, I. Schwartz, M. B. Plenio, and F. Jelezko, “Progress in miniaturization and low-field nuclear magnetic resonance,” Journal of Magnetic Resonance, vol. 322, p. 106860, 2021, doi: 10.1016/j.jmr.2020.106860.
 BibTeX
 @article{anders322progress, author = {Anders, Jens and Dreyer, Frederik and Kr{\"u}ger, Daniel and Schwartz, Ilai and Plenio, Martin B and Jelezko, Fedor}, doi = {10.1016/j.jmr.2020.106860}, journal = {Journal of Magnetic Resonance}, pages = 106860, publisher = {Elsevier}, title = {Progress in miniaturization and low-field nuclear magnetic resonance}, url = {https://www.sciencedirect.com/science/article/pii/S1090780720301786}, volume = 322, year = 2021 }
 Link
 https://www.sciencedirect.com/science/article/pii/S1090780720301786
 DOI
 10.1016/j.jmr.2020.106860
6. J. Anders, F. Dreyer, D. Krüger, I. Schwartz, M. B. Plenio, and F. Jelezko, “Progress in miniaturization and low-field nuclear magnetic resonance,” vol. 322, p. 106860, Jan. 2021, doi: 10.1016/j.jmr.2020.106860.
 BibTeX
 @article{2021, author = {Anders, Jens and Dreyer, Frederik and Krüger, Daniel and Schwartz, Ilai and Plenio, Martin B. and Jelezko, Fedor}, doi = {10.1016/j.jmr.2020.106860}, month = {01}, pages = 106860, publisher = {Elsevier {BV}}, title = {Progress in miniaturization and low-field nuclear magnetic resonance}, url = {https://doi.org/10.1016%2Fj.jmr.2020.106860}, volume = 322, year = 2021 }
 Link
 https://doi.org/10.1016%2Fj.jmr.2020.106860
 DOI
 10.1016/j.jmr.2020.106860
7. B. Blümich and J. Anders, “When the MOUSE leaves the house,” vol. 2, no. 1, Art. no. 1, Apr. 2021, doi: 10.5194/mr-2-149-2021.
 BibTeX
 @article{2021, author = {Blümich, Bernhard and Anders, Jens}, doi = {10.5194/mr-2-149-2021}, month = {04}, number = 1, pages = {149--160}, publisher = {Copernicus {GmbH}}, title = {When the {MOUSE} leaves the house}, url = {https://doi.org/10.5194%2Fmr-2-149-2021}, volume = 2, year = 2021 }
 Link
 https://doi.org/10.5194%2Fmr-2-149-2021
 DOI
 10.5194/mr-2-149-2021
8. H. Bürkle, T. Klotz, R. Krapf, and J. Anders, “A 0.1 MHz to 200 MHz high-voltage CMOS transceiver for portable NMR systems with a maximum output current of 2.0 A<inf>pp</inf>,” in ESSCIRC 2021 - IEEE 47th European Solid State Circuits Conference (ESSCIRC), in ESSCIRC 2021 - IEEE 47th European Solid State Circuits Conference (ESSCIRC). Sep. 2021, pp. 327–330. doi: 10.1109/ESSCIRC53450.2021.9567823.
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 BibTeX
 @inproceedings{9567823, abstract = {This paper presents a single-chip high-voltage transceiver ASIC for low-field NMR spectroscopy. The chip integrates an adjustable high-voltage (HV) H-bridge power amplifier (PA) with a PLL frequency synthesizer and a quadrature low intermediate frequency (low-IF) receiver, achieving a measured input-referred voltage noise density of 1.1 nV / ✓Hz. The operating frequency of the chip is from 0.1 MHz to 200 MHz, supporting all relevant Larmor frequencies for low-field mobile and portable NMR. The PA consists of four isolated 50 V NMOS transistors, isolated gate drivers with a digitally adjustable deadtime control, high-frequency level shifters, and a TX-control logic that supports bootstrapping of the integrated high-side drivers. The output current can be defined by an adjustable voltage supply from 0 V to 50 V, delivering a maximum current of 2.0 App into a non-tuned 3 mm NMR coil and up to 8.3 App into a parallel tuned NMR coil. Inside a custom-designed 1.1 T portable NMR magnet, the system achieves a spin sensitivity of 1.1 × 1016spins/ ✓Hz and a concentration sensitivity of 1mM/✓Hz.}, author = {Bürkle, Heiko and Klotz, Tobias and Krapf, Reiner and Anders, Jens}, booktitle = {ESSCIRC 2021 - IEEE 47th European Solid State Circuits Conference (ESSCIRC)}, doi = {10.1109/ESSCIRC53450.2021.9567823}, month = {09}, pages = {327-330}, title = {A 0.1 MHz to 200 MHz high-voltage CMOS transceiver for portable NMR systems with a maximum output current of 2.0 A<inf>pp</inf>}, year = 2021 }
 DOI
 10.1109/ESSCIRC53450.2021.9567823
9. Y. Chae, Y.-S. Shu, J. Anders, V. Schaffer, T. Oshima, and M. Corsi, “F2: Pushing the Frontiers in Accuracy for Data Converters and Analog Circuits,” in 2021 IEEE International Solid- State Circuits Conference (ISSCC), in 2021 IEEE International Solid- State Circuits Conference (ISSCC), vol. 64. Feb. 2021, pp. 517–519. doi: 10.1109/ISSCC42613.2021.9365818.
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 BibTeX
 @inproceedings{9365818, abstract = {Summary form only given, as follows. The complete presentation was not made available for publication as part of the conference proceedings. The advances in high-precision analog front-end and data conversion circuits have opened up new opportunities in diverse application spaces. To keep fueling the evolution of emerging applications, such as health monitoring, industry 4.0, and internet of things, advanced sensing technology is required to further improve resolution, speed, as well as power and area efficiency of the system. This forum highlights the fundamental challenges with an emphasis on techniques to achieve the ultimate accuracy in analog circuits and data converters. Following an overview of analog-circuit challenges, a series of discussions start with essential high-accuracy voltage and frequency references along with the compensation techniques for their long-term drift, and then move on to the system-level functions of high-precision amplifiers, digital-to-analog converters, as well as overasampling and Nyquist-rate analog-to-digital converters, which are required to construct the overall signal chain.}, author = {Chae, Youngcheol and Shu, Yun-Shiang and Anders, Jens and Schaffer, Viola and Oshima, Takashi and Corsi, Marco}, booktitle = {2021 IEEE International Solid- State Circuits Conference (ISSCC)}, doi = {10.1109/ISSCC42613.2021.9365818}, issn = {2376-8606}, month = {02}, pages = {517-519}, title = {F2: Pushing the Frontiers in Accuracy for Data Converters and Analog Circuits}, volume = 64, year = 2021 }
 DOI
 10.1109/ISSCC42613.2021.9365818
10. A. Chu et al., “On the modeling of amplitude-sensitive electron spin resonance (ESR) detection using voltage-controlled oscillator (VCO)-based ESR-on-a-chip detectors,” Magnetic Resonance, vol. 2, no. 2, Art. no. 2, Sep. 2021, doi: 10.5194/mr-2-699-2021.
 BibTeX
 @article{2021, author = {Chu, Anh and Schlecker, Benedikt and Kern, Michal and Goodsell, Justin L. and Angerhofer, Alexander and Lips, Klaus and Anders, Jens}, doi = {10.5194/mr-2-699-2021}, journal = {Magnetic Resonance}, month = {09}, number = 2, pages = {699--713}, publisher = {Copernicus {GmbH}}, title = {On the modeling of amplitude-sensitive electron spin resonance ({ESR}) detection using voltage-controlled oscillator ({VCO})-based {ESR}-on-a-chip detectors}, url = {https://doi.org/10.5194%2Fmr-2-699-2021}, volume = 2, year = 2021 }
 Link
 https://doi.org/10.5194%2Fmr-2-699-2021
 DOI
 10.5194/mr-2-699-2021
11. D. Djekic, M. Häberle, A. Mohamed, L. Baumgärtner, and J. Anders, “A 440-kOhm to 150-GOhm Tunable Transimpedance Amplifier based on Multi-Element Pseudo-Resistors,” in ESSCIRC 2021 - IEEE 47th European Solid State Circuits Conference (ESSCIRC), in ESSCIRC 2021 - IEEE 47th European Solid State Circuits Conference (ESSCIRC). Sep. 2021, pp. 403–406. doi: 10.1109/ESSCIRC53450.2021.9567831.
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 BibTeX
 @inproceedings{9567831, abstract = {In this paper, we present a widely tunable transimpedance amplifier (TIA) with a dc servo loop and an optional bandwidth extension. All resistors are implemented as multielement pseudo-resistors, which feature high linearity, robustness against process and temperature variations, and a very wide tuning range of more than five decades. While state-of-the-art TIAs are mainly implemented with either resistive or capacitive feedback, the proposed TIA uses a capacitive-resistive feedback network to combine the best of both topologies. The TIA features a noise floor of 0.6 fA/✓Hz at its maximum transimpedance of 150 GΩ and a bandwidth of 2.9 MHz at its minimum transimpedance of 440 kΩ. A subsequent inverting amplifier stage provides an optional pole-zero compensation to extend the TIA's overall bandwidth by a factor of up to 180 or with an absolute limit of 2.3 MHz. An additional dc servo loop, which incorporates a tunable integrator and a tunable dc feedback resistor, can be used to prevent large dc currents from flowing through the main signal path. Its dc transimpedance can be adjusted separately from the ac transimpedance, and the crossover frequency is adjustable over a range of more than five decades. The TIA occupies 0.3 mm2 of chip area and has a power consumption of 40 mW from a 1.8-V supply.}, author = {Djekic, Denis and Häberle, Matthias and Mohamed, Ayman and Baumgärtner, Lars and Anders, Jens}, booktitle = {ESSCIRC 2021 - IEEE 47th European Solid State Circuits Conference (ESSCIRC)}, doi = {10.1109/ESSCIRC53450.2021.9567831}, month = {09}, pages = {403-406}, title = {A 440-kOhm to 150-GOhm Tunable Transimpedance Amplifier based on Multi-Element Pseudo-Resistors}, year = 2021 }
 DOI
 10.1109/ESSCIRC53450.2021.9567831
12. F. Dreyer, D. Krüger, and J. Anders, “Breitbandiger Transceiver ASIC für heteronukleare NMR Spektroskopie,” in MikroSystemTechnik Kongress 2021, in MikroSystemTechnik Kongress 2021. VDE Verlag, 2021, pp. 258–261.
 - BibTeX
 BibTeX
 @inproceedings{dreyer2021broadband, author = {Dreyer, Frederik and Kr\"{u}ger, Daniel and Anders, Jens}, booktitle = {MikroSystemTechnik Kongress 2021}, isbn = {978-3-8007-5656-8}, organization = {VDE GMM}, pages = {258-261}, publisher = {VDE Verlag}, title = {Breitbandiger Transceiver ASIC für heteronukleare NMR Spektroskopie}, year = 2021 }
13. M. Elsobky, A. Mohamed, T. Deuble, J. Anders, and J. N. Burghartz, “A 12-to-15 b, 100-to-25 kS/s Resolution Reconfigurable, Power Scalable Incremental ADC Using Ultrathin Chips,” IEEE Sensors Letters, vol. 5, no. 2, Art. no. 2, Feb. 2021, doi: 10.1109/LSENS.2021.3051259.
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 BibTeX
 @article{9321383, abstract = {Resolution reconfigurable Nyquist-rate analog-to-digital converters (ADCs) are able to deliver an optimized end-to-end power efficiency when a single ADC is time-multiplexed between different sensors. In this letter, a 12-to-15b resolution reconfigurable power scalable Nyquist-rate incremental ΔΣ (I-ΔΣ) ADC, operating at sampling rates from 100 to 25 kS/s, is proposed. A widely reconfigurable dynamic range (DR) (73-92 dB) with fine selection granularity is achieved by incorporating a scalable first integrator and optimally setting the oversampling ratio (OSR) of the ΔΣ modulator. A 2.5× power reduction is measured for the proposed technique in comparison to a pure OSR-based resolution scaling. A Walden figure-of-merit (FoM W) of 880 fJ/conv.-step and Schreier (FoM S) of 160.3 dB are measured in the 14b mode. The I-ΔΣ ADC is fabricated in a 180-nm CMOS technology and consumes 0.48 and 0.93 mW from a supply voltage of 3 V at the 12b and 15b modes, respectively. By exploiting the back-thinning of the ADC chips, the presented 30-μm-thick ADC becomes readily available for integration into hybrid flexible sensor systems.}, author = {Elsobky, Mourad and Mohamed, Ayman and Deuble, Thomas and Anders, Jens and N. Burghartz, Joachim}, doi = {10.1109/LSENS.2021.3051259}, issn = {2475-1472}, journal = {IEEE Sensors Letters}, month = {02}, number = 2, pages = {1-4}, title = {A 12-to-15 b, 100-to-25 kS/s Resolution Reconfigurable, Power Scalable Incremental ADC Using Ultrathin Chips}, volume = 5, year = 2021 }
 DOI
 10.1109/LSENS.2021.3051259
14. M. A. Hassan, T. Elrifai, A. Sakr, M. Kern, K. Lips, and J. Anders, “A 14-channel 7 GHz VCO-based EPR-on-a-chip sensor with rapid scan capabilities,” in 2021 IEEE Sensors, in 2021 IEEE Sensors. Oct. 2021, pp. 1–4. doi: 10.1109/SENSORS47087.2021.9639513.
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 BibTeX
 @inproceedings{9639513, abstract = {This paper presents a VCO-based EPR-on-a-chip (EPRoC) sensor for portable, battery-operated electron paramagnetic resonance (EPR) spectrometers. The proposed chip contains an array of 14 injection-locked VCOs as the sensing element for an improved sensitive volume and phase noise performance. By cointegrating a high-bandwidth PLL, the presented design allows for continuous-wave and rapid-scan EPR experiments with a minimum number of external components. The active loop filter introduces an assisted replica charge pump that mitigates the slewing requirements on the loop-filter amplifier. The measured spin sensitivity of 2×109 spins/$\sqrt {{\text{Hz}}} $ together with the large active volume of 210 nl lead to an 8-fold improvement in concentration sensitivity compared to the state-of-the-art in EPRoC detectors.}, author = {Hassan, Mohamed Atef and Elrifai, Tarek and Sakr, Ayman and Kern, Michal and Lips, Klaus and Anders, Jens}, booktitle = {2021 IEEE Sensors}, doi = {10.1109/SENSORS47087.2021.9639513}, issn = {2168-9229}, month = {10}, pages = {1-4}, title = {A 14-channel 7 GHz VCO-based EPR-on-a-chip sensor with rapid scan capabilities}, year = 2021 }
 DOI
 10.1109/SENSORS47087.2021.9639513
15. D. Krüger, F. Dreyer, M. Kern, and J. Anders, “An S-band EPR-on-a-chip Receiver in 0.13 µm BiCMOS,” in 2021 28th IEEE International Conference on Electronics, Circuits, and Systems (ICECS), in 2021 28th IEEE International Conference on Electronics, Circuits, and Systems (ICECS). Nov. 2021, pp. 1–5. doi: 10.1109/ICECS53924.2021.9665504.
 - BibTeX
 - DOI
 BibTeX
 @inproceedings{9665504, abstract = {In this paper, we present a chip-integrated receiver for electron paramagnetic resonance (EPR), designed for operation in the S-band (2-4 GHz). This EPR-on-a-chip receiver consists of a low-noise amplifier, followed by quadrature downconversion mixers and intermediate-frequency variable gain amplifiers. It also incorporates a frequency generation block. The chip is realized in a <tex>$0.13-\mu \mathrm{m}$</tex> SiGe BiCMOS technology and occupies an area of <tex>$1100 \times 900\ \mu \mathrm{m}^{2}$</tex>. The receiver's measured input-referred voltage noise density within the band of interest is <tex>$720 \text{pV}/\sqrt{\text{Hz}}$</tex>. Proof-of-concept EPR measurements validate the proposed approach.}, author = {Krüger, Daniel and Dreyer, Frederik and Kern, Michal and Anders, Jens}, booktitle = {2021 28th IEEE International Conference on Electronics, Circuits, and Systems (ICECS)}, doi = {10.1109/ICECS53924.2021.9665504}, month = {11}, pages = {1-5}, title = {An S-band EPR-on-a-chip Receiver in 0.13 µm BiCMOS}, year = 2021 }
 DOI
 10.1109/ICECS53924.2021.9665504
16. D. Krüger, F. Dreyer, M. Kern, and J. Anders, “An S-band EPR-on-a-chip Receiver in 0.13 μm BiCMOS,” in 2021 28th IEEE International Conference on Electronics, Circuits, and Systems (ICECS), in 2021 28th IEEE International Conference on Electronics, Circuits, and Systems (ICECS). IEEE, Nov. 2021, pp. 1–5. doi: 10.1109/ICECS53924.2021.9665504.
 - BibTeX
 - DOI
 BibTeX
 @inproceedings{9665504, abstract = {We present a chip-integrated receiver for electron paramagnetic resonance (EPR), designed for operation in the S-band (2-4 GHz). This EPR-on-a-chip receiver consists of a low-noise amplifier, followed by quadrature downconversion mixers and intermediate-frequency variable gain amplifiers. It also incorporates a frequency generation block. The chip is realized in a $0.13-\mu \mathrm{m}$ SiGe BiCMOS technology and occupies an area of $1100 \times 900\ \mu \mathrm{m}^{2}$. The receiver's measured input-referred voltage noise density within the band of interest is $720 \text{pV}/\sqrt{\text{Hz}}$. Proof-of-concept EPR measurements validate the proposed approach.}, author = {Krüger, Daniel and Dreyer, Frederik and Kern, Michal and Anders, Jens}, booktitle = {2021 28th IEEE International Conference on Electronics, Circuits, and Systems (ICECS)}, doi = {10.1109/ICECS53924.2021.9665504}, month = {11}, pages = {1-5}, publisher = {IEEE}, title = {An S-band EPR-on-a-chip Receiver in 0.13 μm BiCMOS}, year = 2021 }
 DOI
 10.1109/ICECS53924.2021.9665504
17. D. Krüger, F. Dreyer, M. Kern, and J. Anders, “An S-band EPR-on-a-chip Receiver in <tex>$0.13\,\mum$</tex> BiCMOS,” in 2021 28th IEEE International Conference on Electronics, Circuits, and Systems (ICECS), in 2021 28th IEEE International Conference on Electronics, Circuits, and Systems (ICECS). Nov. 2021, pp. 1–5. doi: 10.1109/ICECS53924.2021.9665504.
 - BibTeX
 - DOI
 BibTeX
 @inproceedings{9665504, abstract = {In this paper, we present a chip-integrated receiver for electron paramagnetic resonance (EPR), designed for operation in the S-band (2-4 GHz). This EPR-on-a-chip receiver consists of a low-noise amplifier, followed by quadrature downconversion mixers and intermediate-frequency variable gain amplifiers. It also incorporates a frequency generation block. The chip is realized in a <tex>$0.13-\mu \mathrm{m}$</tex> SiGe BiCMOS technology and occupies an area of <tex>$1100 \times 900\ \mu \mathrm{m}^{2}$</tex>. The receiver's measured input-referred voltage noise density within the band of interest is <tex>$720 \text{pV}/\sqrt{\text{Hz}}$</tex>. Proof-of-concept EPR measurements validate the proposed approach.}, author = {Krüger, Daniel and Dreyer, Frederik and Kern, Michal and Anders, Jens}, booktitle = {2021 28th IEEE International Conference on Electronics, Circuits, and Systems (ICECS)}, doi = {10.1109/ICECS53924.2021.9665504}, month = {11}, pages = {1-5}, title = {An S-band EPR-on-a-chip Receiver in <tex>$0.13\,\mu\mathrm{m}$</tex> BiCMOS}, year = 2021 }
 DOI
 10.1109/ICECS53924.2021.9665504
18. S. Künstner et al., “Rapid-scan electron paramagnetic resonance using an EPR-on-a-Chip sensor,” vol. 2, no. 2, Art. no. 2, Aug. 2021, doi: 10.5194/mr-2-673-2021.
 BibTeX
 @article{2021, author = {Künstner, Silvio and Chu, Anh and Dinse, Klaus-Peter and Schnegg, Alexander and McPeak, Joseph E. and Naydenov, Boris and Anders, Jens and Lips, Klaus}, doi = {10.5194/mr-2-673-2021}, month = {08}, number = 2, pages = {673--687}, publisher = {Copernicus {GmbH}}, title = {Rapid-scan electron paramagnetic resonance using an {EPR}-on-a-Chip sensor}, url = {https://doi.org/10.5194%2Fmr-2-673-2021}, volume = 2, year = 2021 }
 Link
 https://doi.org/10.5194%2Fmr-2-673-2021
 DOI
 10.5194/mr-2-673-2021
19. S. M. Leitao et al., “Time-resolved scanning ion conductance microscopy for three-dimensional tracking of nanoscale cell surface dynamics,” bioRxiv, 2021, doi: 10.1101/2021.05.13.444009.
 BibTeX
 @article{Leitao2021.05.13.444009, abstract = {Nanocharacterization plays a vital role in understanding the complex nanoscale organization of cells and organelles. Understanding cellular function requires high-resolution information about how the cellular structures evolve over time. A number of techniques exist to resolve static nanoscale structure of cells in great detail (super-resolution optical microscopy1, EM2, AFM3). However, time-resolved imaging techniques tend to either have lower resolution, are limited to small areas, or cause damage to the cells thereby preventing long-term time-lapse studies. Scanning probe microscopy methods such as atomic force microscopy (AFM) combine high-resolution imaging with the ability to image living cells in physiological conditions. The mechanical contact between the tip and the sample, however, deforms the cell surface, disturbs the native state, and prohibits long-term time-lapse imaging. Here, we develop a scanning ion conductance microscope (SICM) for high-speed and long-term nanoscale imaging. By utilizing recent advances in nanopositioning4, nanopore fabrication5, microelectronics6, and controls engineering7 we developed a microscopy method that can resolve spatiotemporally diverse three-dimenional processes on the cell membrane at sub-5nm axial resolution. We tracked dynamic changes in live cell morphology with nanometer details and temporal ranges of sub-second to days, imagining diverse processes ranging from endocytosis, micropinocytosis, and mitosis, to bacterial infection and cell differentiation in cancer cells. This technique enables a detailed look at membrane events and may offer insights into cell-cell interactions for infection, immunology, and cancer research.Competing Interest StatementThe authors have declared no competing interest.}, author = {Leitao, Samuel M. and Drake, Barney and Pinjusic, Katarina and Pierrat, Xavier and Navikas, Vytautas and Nievergelt, Adrian P. and Brillard, Charl{\`e}ne and Djekic, Denis and Radenovic, Aleksandra and Persat, Alex and Constam, Daniel B. and Anders, Jens and Fantner, Georg E.}, doi = {10.1101/2021.05.13.444009}, elocation-id = {2021.05.13.444009}, eprint = {https://www.biorxiv.org/content/early/2021/05/15/2021.05.13.444009.full.pdf}, journal = {bioRxiv}, publisher = {Cold Spring Harbor Laboratory}, title = {Time-resolved scanning ion conductance microscopy for three-dimensional tracking of nanoscale cell surface dynamics}, url = {https://www.biorxiv.org/content/early/2021/05/15/2021.05.13.444009}, year = 2021 }
 Link
 https://www.biorxiv.org/content/early/2021/05/15/2021.05.13.444009
 DOI
 10.1101/2021.05.13.444009
20. A. Mohamed, H. Heidari, and J. Anders, “A readout circuit for tunnel magnetoresistive sensors employing an ultra-low-noise current source,” in ESSCIRC 2021 - IEEE 47th European Solid State Circuits Conference (ESSCIRC), in ESSCIRC 2021 - IEEE 47th European Solid State Circuits Conference (ESSCIRC). Sep. 2021, pp. 331–334. doi: 10.1109/ESSCIRC53450.2021.9567752.
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 - DOI
 BibTeX
 @inproceedings{9567752, abstract = {We present a tunneling magnetoresistive (TMR) sensing microsystem consisting of a low flicker noise TMR sensor and a custom integrated readout frontend. The proposed sensor readout circuit introduces a novel ultra-low-noise current biasing scheme for the TMR sensor, which achieves a very low current noise floor of 2.2 pA√Hz for a 1 mA biasing current. The TMR output voltage is processed by a differential readout scheme to improve the baseline-to-signal ratio. The microsystem also features an on-chip 10-bit current DAC that allows compensating for the large process variations in the TMR base resistance value. The readout chip is manufactured in a 180 nm SOI CMOS technology and heterogeneously integrated with the TMR sensor. The readout chain provides a thermal noise floor of 4nV/√Hz, while, together with the biasing scheme, consuming a total power of 38 mW. The complete sensor system consisting of the TMR and the readout circuit provides a state-of-the-art magnetic field noise floor of 120 pT/√Hz.}, author = {Mohamed, Ayman and Heidari, Hadi and Anders, Jens}, booktitle = {ESSCIRC 2021 - IEEE 47th European Solid State Circuits Conference (ESSCIRC)}, doi = {10.1109/ESSCIRC53450.2021.9567752}, month = {09}, pages = {331-334}, title = {A readout circuit for tunnel magnetoresistive sensors employing an ultra-low-noise current source}, year = 2021 }
 DOI
 10.1109/ESSCIRC53450.2021.9567752
21. A. Sakr, M. A. Hassan, and J. Anders, “A 93.1-dB SFDR, 90.3-dB DR, and 1-MS/s CT Incremental Sigma-Delta Modulator Incorporating a Resistive Dual-RTZ FIR DAC,” in ESSCIRC 2021 - IEEE 47th European Solid State Circuits Conference (ESSCIRC), in ESSCIRC 2021 - IEEE 47th European Solid State Circuits Conference (ESSCIRC). Sep. 2021, pp. 211–214. doi: 10.1109/ESSCIRC53450.2021.9567762.
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 - DOI
 BibTeX
 @inproceedings{9567762, abstract = {This paper presents a high-bandwidth, high-resolution continuous-time incremental ΣΔ-modulator employing a 6-tap finite impulse response (FIR) feedback digital-to-analog converter (DAC) for improved clock jitter immunity. Resetting the FIR filter internal states in the incremental mode introduces initial transient overshoots, which can cause instability at high input amplitudes. To solve this problem, we propose the use of a purely resistive feedthrough path from the overall input to the second integrator input. This additional path alleviates the large transient swings associated with the incremental operation and extends the modulator's dynamic range (DR). Furthermore, we introduce a novel implementation of a fully differential dual return-to-zero (RTZ) resistive FIR DAC that eliminates inter-symbol interference (ISI) signal-dependent errors and, thereby, improves modulator linearity. The presented design is fabricated in a 180-nm SOI CMOS technology and achieves a DR of 90.3 dB and a peak spurious-free DR of 93.1 dB at a Nyquist conversion rate of 1 MS/s. The power dissipated from a 1.8-V power supply is 8.06 mW, resulting in a Schreier FoM of 168.3 dB.}, author = {Sakr, Ayman and Hassan, Mohamed Atef and Anders, Jens}, booktitle = {ESSCIRC 2021 - IEEE 47th European Solid State Circuits Conference (ESSCIRC)}, doi = {10.1109/ESSCIRC53450.2021.9567762}, month = {09}, pages = {211-214}, title = {A 93.1-dB SFDR, 90.3-dB DR, and 1-MS/s CT Incremental Sigma-Delta Modulator Incorporating a Resistive Dual-RTZ FIR DAC}, year = 2021 }
 DOI
 10.1109/ESSCIRC53450.2021.9567762
2020
1. J. Anders, F. Dreyer, and D. Krüger, “On-Chip Nuclear Magnetic Resonance,” in Handbook of Biochips: Integrated Circuits and Systems for Biology and Medicine, M. Sawan, Ed., in Handbook of Biochips: Integrated Circuits and Systems for Biology and Medicine. , New York, NY: Springer New York, 2020, pp. 1--32. doi: 10.1007/978-1-4614-6623-9_23-1.
 BibTeX
 @inbook{Anders2020, abstract = {Nuclear magnetic resonance (NMR) is one of the prime modalities for probing molecular structure in the biomedical context and analyzing bulk material properties for quality control, food product analysis, and nondestructive testing. Conventional state-of-the-art NMR spectroscopy systems utilize bulky superconducting magnets, have a room-filling size, and cost millions of euros. Over the past decade, advances in permanent magnet technology have led to the availability of benchtop NMR spectrometers and even smaller NMR relaxometers for analyzing bulk material properties and performing immunoassays. With the availability of these smaller NMR magnets, NMR electronics have entered the focus of attention as a key component for miniaturized, portable NMR devices. Here, the on-chip NMR approach, in which all required electronics are realized on a single integrated circuit, allows for a realization in an ultra-small form factor and offers great promise for reducing the overall system cost. In this chapter, a comprehensive and self-contained overview of the on-chip NMR approach in the biomedical context will be given. After an introduction into the topic, the physical origin of the NMR signal will be discussed together with means of exciting and detecting it. This is followed by a review of conventional NMR electronics, including its key performance metrics. In the main part of this chapter, the NMR-on-a-chip approach is introduced, and its advantages and disadvantages are highlighted. Finally, the chapter is concluded with a summary and an outlook on the possibility of enhancing the achievable performance of the NMR-on-a-chip approach with on-chip dynamic nuclear polarization (DNP) capabilities.}, address = {New York, NY}, author = {Anders, Jens and Dreyer, Frederik and Kr{\"u}ger, Daniel}, booktitle = {Handbook of Biochips: Integrated Circuits and Systems for Biology and Medicine}, doi = {10.1007/978-1-4614-6623-9_23-1}, editor = {Sawan, Mohamad}, isbn = {978-1-4614-6623-9}, pages = {1--32}, publisher = {Springer New York}, title = {On-Chip Nuclear Magnetic Resonance}, url = {https://doi.org/10.1007/978-1-4614-6623-9_23-1}, year = 2020 }
 Link
 https://doi.org/10.1007/978-1-4614-6623-9_23-1
 DOI
 10.1007/978-1-4614-6623-9_23-1
2. M. Brunet Cabré, D. Djekic, T. Romano, N. Hanna, J. Anders, and K. McKelvey, “Microscale Electrochemical Cell on a Custom CMOS Transimpedance Amplifier for High Temporal Resolution Single Entity Electrochemistry**,” ChemElectroChem, vol. 7, no. 23, Art. no. 23, 2020, doi: https://doi.org/10.1002/celc.202001083.
 BibTeX
 @article{https://doi.org/10.1002/celc.202001083, abstract = {Abstract Stochastic collision electrochemistry requires high-resolution and high-bandwidth current amplification due to the low magnitude and short duration of the current signals. However, increasing the current amplifier bandwidth leads to increased current noise levels, which in turn obscures the current signal generated from stochastic collision electrochemistry experiments. The key to minimizing current noise is an experimental configuration that minimizes the input capacitance to the current amplifier. Here, we report a new strategy to minimize the input capacitance to a current amplifier by using a movable microscale electrochemical cell, formed at the end of a micropipette using a scanning electrochemical cell microscopy approach, to conduct electrochemical experiments in close proximity (∼300 μm) to a transimpedance amplifier. We demonstrated this via electro-oxidation of single Ag nanoparticles detected at a bandwidth of 1 MHz.}, author = {Brunet Cabré, Marc and Djekic, Denis and Romano, Timothée and Hanna, Nadim and Anders, Jens and McKelvey, Kim}, doi = {https://doi.org/10.1002/celc.202001083}, eprint = {https://onlinelibrary.wiley.com/doi/pdf/10.1002/celc.202001083}, journal = {ChemElectroChem}, number = 23, pages = {4724-4729}, title = {Microscale Electrochemical Cell on a Custom CMOS Transimpedance Amplifier for High Temporal Resolution Single Entity Electrochemistry**}, url = {https://onlinelibrary.wiley.com/doi/abs/10.1002/celc.202001083}, volume = 7, year = 2020 }
 Link
 https://onlinelibrary.wiley.com/doi/abs/10.1002/celc.202001083
 DOI
 https://doi.org/10.1002/celc.202001083
3. M. Brunet Cabré, D. Djekic, T. Romano, N. Hanna, J. Anders, and K. McKelvey, “Cover Feature: Microscale Electrochemical Cell on a Custom CMOS Transimpedance Amplifier for High Temporal Resolution Single Entity Electrochemistry (ChemElectroChem 23/2020),” ChemElectroChem, vol. 7, no. 23, Art. no. 23, 2020, doi: https://doi.org/10.1002/celc.202001360.
 BibTeX
 @article{https://doi.org/10.1002/celc.202001360, abstract = {The Cover Feature shows high bandwidth single entity electrochemistry. More information can be found in the Article by M. Brunet Cabré et al.}, author = {Brunet Cabré, Marc and Djekic, Denis and Romano, Timothée and Hanna, Nadim and Anders, Jens and McKelvey, Kim}, doi = {https://doi.org/10.1002/celc.202001360}, eprint = {https://onlinelibrary.wiley.com/doi/pdf/10.1002/celc.202001360}, journal = {ChemElectroChem}, number = 23, pages = {4692-4692}, title = {Cover Feature: Microscale Electrochemical Cell on a Custom CMOS Transimpedance Amplifier for High Temporal Resolution Single Entity Electrochemistry (ChemElectroChem 23/2020)}, url = {https://onlinelibrary.wiley.com/doi/abs/10.1002/celc.202001360}, volume = 7, year = 2020 }
 Link
 https://onlinelibrary.wiley.com/doi/abs/10.1002/celc.202001360
 DOI
 https://doi.org/10.1002/celc.202001360
4. H. Bürkle, K. Schmid, T. Klotz, R. Krapf, and J. Anders, “A High Voltage CMOS Transceiver for Low-Field NMR with a Maximum Output Current of 1.4 A<inf>pp</inf>,” in 2020 IEEE International Symposium on Circuits and Systems (ISCAS), in 2020 IEEE International Symposium on Circuits and Systems (ISCAS). Oct. 2020, pp. 1–5. doi: 10.1109/ISCAS45731.2020.9181025.
 - BibTeX
 - DOI
 BibTeX
 @inproceedings{9181025, abstract = {In this paper, we present a fully integrated transceiver ASIC for low field NMR spectroscopy. The chip integrates a conventional low intermediate frequency (low-IF) receiver together with a high-voltage (HV) H-bridge power amplifier (PA) and a PLL frequency synthesizer. The receiver consists of a low noise amplifier (LNA), a quadrature down-conversion mixer and a baseband amplifier. It achieves a measured input-referred voltage noise density of 1.1 nV/√Hz;. The integrated PLL frequency synthesizer supports operating frequencies between 4 MHz and 100 MHz, covering all relevant Larmor frequencies of benchtop and portable NMR. The on-chip PA can drive up to 1.4 App into a 1Ω resistor and 1.6 App into a 3mm, parallel-tuned NMR coil. When operating with a 3mm NMR coil inside a 1.45T unshimmed NMR magnet, the system achieves a spin sensitivity of 9.2 × 1015 spins/√Hz and a concentration sensitivity of 1.79 mM/√Hz.}, author = {Bürkle, Heiko and Schmid, Kevin and Klotz, Tobias and Krapf, Reiner and Anders, Jens}, booktitle = {2020 IEEE International Symposium on Circuits and Systems (ISCAS)}, doi = {10.1109/ISCAS45731.2020.9181025}, issn = {2158-1525}, month = {10}, pages = {1-5}, title = {A High Voltage CMOS Transceiver for Low-Field NMR with a Maximum Output Current of 1.4 A<inf>pp</inf>}, year = 2020 }
 DOI
 10.1109/ISCAS45731.2020.9181025
5. L. Gohlke, F. Dreyer, M. P. Álvarez, and J. Anders, “An IoT based low-cost heart rate measurement system employing PPG sensors,” in 2020 IEEE SENSORS, in 2020 IEEE SENSORS. Oct. 2020, pp. 1–4. doi: 10.1109/SENSORS47125.2020.9278844.
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 - DOI
 BibTeX
 @inproceedings{9278844, abstract = {In this paper, we present a low-cost system for heart rate measurements. The device is easily usable without medical knowledge or training, and it works without prior calibration. The sensor mainly targets for health monitoring people in rural areas of emerging countries, who do not have easy access to medical examinations. While there are already many devices on the market that can perform heart rate and blood pressure measurements, the focus of the presented work is on reducing the cost while maintaining sufficient accuracy and providing online access to the measured data for medical personnel. The presented prototype uses commercial PPG sensors and can measure heart rates between 30bpm and 200bpm with an absolute accuracy of ±10bpm. The total cost of the prototype is below 30USD.}, author = {Gohlke, Lena and Dreyer, Frederik and Álvarez, Monica Pimiento and Anders, Jens}, booktitle = {2020 IEEE SENSORS}, doi = {10.1109/SENSORS47125.2020.9278844}, issn = {2168-9229}, month = {10}, pages = {1-4}, title = {An IoT based low-cost heart rate measurement system employing PPG sensors}, year = 2020 }
 DOI
 10.1109/SENSORS47125.2020.9278844
6. L. Gohlke, F. Dreyer, M. P. Alvarez, and J. Anders, “An IoT based low-cost heart rate measurement system employing PPG sensors,” in 2020 IEEE Sensors, in 2020 IEEE Sensors. IEEE, 2020, pp. 1--4. doi: 10.1109/SENSORS47125.2020.9278844.
 BibTeX
 @inproceedings{gohlke2020iot, author = {Gohlke, Lena and Dreyer, Frederik and Alvarez, Monica Pimiento and Anders, Jens}, booktitle = {2020 IEEE Sensors}, doi = {10.1109/SENSORS47125.2020.9278844}, organization = {IEEE}, pages = {1--4}, title = {An IoT based low-cost heart rate measurement system employing PPG sensors}, url = {https://ieeexplore.ieee.org/abstract/document/9278844}, year = 2020 }
 Link
 https://ieeexplore.ieee.org/abstract/document/9278844
 DOI
 10.1109/SENSORS47125.2020.9278844
7. A. Mohamed and J. Anders, “Stability Analysis of Incremental ΣΔ Modulators using Mixed-Logic Dynamical Systems and Optimal Control Theory,” in 2020 IEEE International Symposium on Circuits and Systems (ISCAS), in 2020 IEEE International Symposium on Circuits and Systems (ISCAS). Oct. 2020, pp. 1–5. doi: 10.1109/ISCAS45731.2020.9180952.
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 - DOI
 BibTeX
 @inproceedings{9180952, abstract = {In this paper, we present a mixed-logic dynamical (MLD) system model that allows for an iron-clad prediction of the stability of Incremental Sigma Delta (I-ΣΔ) modulators. The model extends the mixed logic dynamical description of freely-running Sigma-Delta (ΣΔ) modulators with single-bit quantizers presented in [1] to the multibit case. Moreover, we use the derived model to compare I-ΣΔs with different loop filter orders and different number of quantizer levels concerning their stability.}, author = {Mohamed, Ayman and Anders, Jens}, booktitle = {2020 IEEE International Symposium on Circuits and Systems (ISCAS)}, doi = {10.1109/ISCAS45731.2020.9180952}, issn = {2158-1525}, month = {10}, pages = {1-5}, title = {Stability Analysis of Incremental ΣΔ Modulators using Mixed-Logic Dynamical Systems and Optimal Control Theory}, year = 2020 }
 DOI
 10.1109/ISCAS45731.2020.9180952
8. A. Mohamed, M. Schmid, A. Tanwear, H. Heidari, and J. Anders, “A Low Noise CMOS Sensor Frontend for a TMR-based Biosensing Platform,” in 2020 IEEE SENSORS, in 2020 IEEE SENSORS. Oct. 2020, pp. 1–4. doi: 10.1109/SENSORS47125.2020.9278826.
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 @inproceedings{9278826, abstract = {In this paper, we propose a low noise CMOS frontend for a Point-of-Care (PoC) biosensing platform based on tunnel magnetoresistance (TMR) as sensors. The integration of a low noise and low power integrated circuit (IC) with the TMR sensors reduces power consumption compared to a realization with discrete electronics, and thereby paves the way towards a portable diagnostic system. The proposed chip uses a DCcoupled fully differential difference amplifier (FDDA) to amplify the minute signals generated by magnetic nanotags (MNTs) that will be used as biomarkers in the target biosensing application. The FDDA features a gain of around 60dB with a suitable offset calibration scheme to deal with the large DC offsets caused by TMR and/or magnetic field variations. The ability to deal with changing DC fields is crucial for a portable setup that is intended to be used in unshielded environments outside the lab. The offset cancellation is achieved by two on-chip current steering DACs that can accommodate TMR resistances between 535 Ω and 4.7kΩ. The presented chip is manufactured in a 180nm SOI CMOS technology and features a thermal noise floor of 7 nV/√Hz. It consumes a total of 7.7 mA from a 1.8V supply.}, author = {Mohamed, Ayman and Schmid, Matthias and Tanwear, Asfand and Heidari, Hadi and Anders, Jens}, booktitle = {2020 IEEE SENSORS}, doi = {10.1109/SENSORS47125.2020.9278826}, issn = {2168-9229}, month = {10}, pages = {1-4}, title = {A Low Noise CMOS Sensor Frontend for a TMR-based Biosensing Platform}, year = 2020 }
 DOI
 10.1109/SENSORS47125.2020.9278826
9. I. Polian et al., “Exploring the mysteries of system-level test.,” in to appear in Proceedings of the 29th IEEE Asian Test Symposium (ATS’20), in to appear in Proceedings of the 29th IEEE Asian Test Symposium (ATS’20). Nov. 2020.
 - BibTeX
 BibTeX
 @inproceedings{polian2020exploring, abteilung = {hocos}, author = {Polian, Ilia and Anders, Jens and Becker, Stefan and Bernardi, Paolo and Chakrabarty, Krishnendu and Elhamawy, Nourhan and Sauer, Matthias and Singh, Adith and Sonza Reorda, Matteo and Wagner, Stefan}, booktitle = {to appear in Proceedings of the 29th IEEE Asian Test Symposium (ATS'20)}, month = {11}, title = {Exploring the mysteries of system-level test.}, year = 2020 }
10. J. Zhao, A. Mohamed, and J. Anders, “An Active CMOS NMR Field Probe with Custom Transceiver and ΣΔ Modulator ASICs and an Optical Link,” in 2020 IEEE International Symposium on Circuits and Systems (ISCAS), in 2020 IEEE International Symposium on Circuits and Systems (ISCAS). Oct. 2020, pp. 1–5. doi: 10.1109/ISCAS45731.2020.9181026.
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 - DOI
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 @inproceedings{9181026, abstract = {In this paper, we present a CMOS-based miniaturized magnetic resonance (MR) system for magnetic field and trajectory mapping incorporating an electromagnetic interference (EMI) robust optical link. The system consists of a custom-designed, CMOS-based active NMR field probe, a custom-designed, single-bit ΣΔ modulator and a commercial optical link. The low-IF architecture of the transceiver ASIC, reduces the required bandwidth in the digitizer to a few hundred kilohertz, enabling the use of a single-bit ΣΔ modulator, whose high frequency, one bit data stream is ideally suited for feeding the following optical link. The custom ΣΔ modulator uses a third order loop filter and employs a 12-tap FIR DAC to increase its robustness against clock jitter. It is manufactured in a 0.18 μm CMOS technology and achieves an SNDR of 72.19 dB over a Nyquist bandwidth of 800 kHz. In the proposed setup, the 1-bit output stream of the ΣΔ modulator directly feeds the driver of a commercial optical fiber link to transmit the NMR data from inside the NMR magnet to the remotely located digital signal processing unit with a very high robustness against EMI. In-situ NMR experiments with a 1.45 T benchtop magnet using a silicone sample demonstrate the very good performance of the overall system, achieving a frequency resolution of 12.6 Hz or 200 ppb in the estimation of the sample's NMR resonance frequency. This corresponds to an effective magnetic field resolution of 290 nT.}, author = {Zhao, Jianyu and Mohamed, Ayman and Anders, Jens}, booktitle = {2020 IEEE International Symposium on Circuits and Systems (ISCAS)}, doi = {10.1109/ISCAS45731.2020.9181026}, issn = {2158-1525}, month = {10}, pages = {1-5}, title = {An Active CMOS NMR Field Probe with Custom Transceiver and ΣΔ Modulator ASICs and an Optical Link}, year = 2020 }
 DOI
 10.1109/ISCAS45731.2020.9181026
2019
1. B. M. K. Alnajjar, A. Buchau, J. Anders, and B. Blümich, “An H-shaped low-field magnet for NMR spectroscopy designed using the finite element method,” International Journal of Applied Electromagnetics and Mechanics, vol. 60, pp. S3–S14, May 2019, doi: 10.3233/JAE-191101.
  BibTeX
  @article{Alnajjar_Buchau_Anders_Blümich_2019, author = {Alnajjar, Belal M.K. and Buchau, André and Anders, Jens and Blümich, Bernhard}, doi = {10.3233/JAE-191101}, issn = {1383-5416}, journal = {International Journal of Applied Electromagnetics and Mechanics}, month = {05}, pages = {S3–S14}, publisher = {IOS Press}, title = {An H-shaped low-field magnet for NMR spectroscopy designed using the finite element method}, url = {http://doi.org/10.3233/JAE-191101}, volume = 60, year = 2019 }
  Link
  http://doi.org/10.3233/JAE-191101
  DOI
  10.3233/JAE-191101
2. M. Eschelbach et al., “Comparison of prospective head motion correction with NMR field probes and an optical tracking system,” Magnetic Resonance in Medicine, vol. 81, no. 1, Art. no. 1, 2019, doi: 10.1002/mrm.27343.
  BibTeX
  @article{doi:10.1002/mrm.27343, author = {Eschelbach, Martin and Aghaeifar, Ali and Bause, Jonas and Handwerker, Jonas and Anders, Jens and Engel, Eva-Maria and Thielscher, Axel and Scheffler, Klaus}, doi = {10.1002/mrm.27343}, eprint = {https://onlinelibrary.wiley.com/doi/pdf/10.1002/mrm.27343}, journal = {Magnetic Resonance in Medicine}, number = 1, pages = {719-729}, title = {Comparison of prospective head motion correction with NMR field probes and an optical tracking system}, url = {https://onlinelibrary.wiley.com/doi/abs/10.1002/mrm.27343}, volume = 81, year = 2019 }
  Link
  https://onlinelibrary.wiley.com/doi/abs/10.1002/mrm.27343
  DOI
  10.1002/mrm.27343
3. J. Handwerker et al., “A CMOS NMR needle for probing brain physiology with high spatial and temporal resolution,” Nature Methods, vol. 17, no. 1, Art. no. 1, Nov. 2019, doi: 10.1038/s41592-019-0640-3.
  BibTeX
  @article{Handwerker_2019, author = {Handwerker, Jonas and P{\'{e}}rez-Rodas, Marlon and Beyerlein, Michael and Vincent, Franck and Beck, Armin and Freytag, Nicolas and Yu, Xin and Pohmann, Rolf and Anders, Jens and Scheffler, Klaus}, doi = {10.1038/s41592-019-0640-3}, journal = {Nature Methods}, month = {11}, number = 1, pages = {64--67}, publisher = {Springer Science and Business Media {LLC}}, title = {A {CMOS} {NMR} needle for probing brain physiology with high spatial and temporal resolution}, url = {https://doi.org/10.1038%2Fs41592-019-0640-3}, volume = 17, year = 2019 }
  Link
  https://doi.org/10.1038%2Fs41592-019-0640-3
  DOI
  10.1038/s41592-019-0640-3
4. M. Spiess, A. Buchau, and J. Anders, “Precision finite element method simulations of a chip-integrated magnetic resonance coil for in-situ MR applications,” in 2019 22nd International Conference on the Computation of Electromagnetic Fields (COMPUMAG), in 2019 22nd International Conference on the Computation of Electromagnetic Fields (COMPUMAG). IEEE, Jul. 2019. doi: 10.1109/compumag45669.2019.9032724.
  BibTeX
  @inproceedings{spiess2019precision, author = {Spiess, Maximilian and Buchau, André and Anders, Jens}, booktitle = {2019 22nd International Conference on the Computation of Electromagnetic Fields (COMPUMAG)}, doi = {10.1109/compumag45669.2019.9032724}, month = {07}, publisher = {{IEEE}}, title = {Precision finite element method simulations of a chip-integrated magnetic resonance coil for in-situ MR applications}, url = {https://doi.org/10.1109%2Fcompumag45669.2019.9032724}, year = 2019 }
  Link
  https://doi.org/10.1109%2Fcompumag45669.2019.9032724
  DOI
  10.1109/compumag45669.2019.9032724

Jens Anders received the master’s degree from the University of Michigan, Ann Arbor, MI, USA, in 2005, the Dipl.-Ing. degree from the Leibniz University of Hannover in 2007, and the Ph.D. degree from the École polytechnique fédérale de Lausanne in 2011.

From 2013 to 2017, he was an Assistant Professor of biomedical integrated sensors with the Institute of Microelectronics at the University of Ulm. Dr. Anders is currently a Full Professor and the Director of the Institute of Smart Sensors at the University of Stuttgart. Since October 2022, he is also the Co-Director of the Institute for Microelectronics Stuttgart (IMS CHIPS).

He has authored or co-authored several books and book chapters as well as more than 150 journal and conference papers.

His current research interests include multiphysics problems and circuit design for sensing applications, including materials science as well as biomedical and quantum sensing.

He is a fellow of the “Center for Integrated Quantum Science and Technology” (IQST, https://www.iqst.org), a fellow of the “Stuttgart Research Center of Photonic Engineering” (SCoPE, https://www.scope.uni-stuttgart.de/), and a member of the Executive Board of the Carl-Zeiss-Stiftung Center for Quantum Photonics (QPhoton, https://www.acp.uni-jena.de/qphoton).

Dr. Anders served/is serving as a Program Committee Member of ISSCC, ESSCIRC, ESSDERC and the IEEE Sensors conference. He received the 2003 President’s Award of the Leibniz University of Hannover, the 2006 Best Thesis Award of the VDE Chapter Hannover, the E.ON Future Award 2007, the VDE ITG ISS Study Award 2008, the VDE ITG Outstanding Publication Award 2012, the ICBME 2008 Outstanding Paper Award, the IEEE Sensors 2017 Best Live Demo Award, and one of the 2021 Sony Europe Research Awards.

Jens Anders

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