Gustavo Martins

1. A Level Shifter With Almost Full Immunity to Positive dv/dt for Buck Converters
   Yang, Y.; Huang, M.; Du, S.; Martins, R. P.; Lu, Y.;
   IEEE Transactions on Circuits and Systems I: Regular Papers,
   Volume 70, Issue 11, pp. 4595-4604, 2023. DOI: 10.1109/TCSI.2023.3307869

2. An RF Energy Harvesting and Power Management Unit Operating over -24 to +15 dBm Input Range
   Gustavo C. Martins; Wouter A. Serdijn;
   IEEE Transactions on Circuits and Systems I: Regular Papers,
   Volume 68, Issue 3, pp. 1342-1353, March 2021. DOI: 10.1109/TCSI.2020.3041175
   document

3. Introduction to RF Energy Harvesting, in: WEARABLE SENSORS: Fundamentals, Implementation and Applications, Second Edition
   Gustavo C. Martins; Andre L. Mansano; Mark Stoopman; Wouter A. Serdijn;
   Edward Sazonov (Ed.);
   Academic Press (Elsevier), Chapter 11, , pp. 311-336, Nov. 20 2020. ISBN : 978-0-12-819246-7.
   document

4. Go with the flow: advances and trends in magnetic flow cytometry
   Soares, Rita; Martins, Verónica C; Macedo, Rita; Cardoso, Filipe Arroyo; Martins, Sofia AM; Caetano, Diogo M; Fonseca, Pedro H; Silvério, Vânia; Cardoso, Susana; Freitas, Paulo P;
   Analytical and bioanalytical chemistry,
   Volume 411, pp. 1839-1862, 2019.

5. Biosensors for on-farm diagnosis of mastitis
   Martins, Sofia AM; Martins, Ver{\'o}nica C; Cardoso, Filipe Arroyo; Germano, José; Rodrigues, Mónica; Duarte, Carla; Bexiga, Ricardo; Cardoso, Susana; Freitas, Paulo P;
   Frontiers in bioengineering and biotechnology,
   Volume 7, pp. 186, 2019.

6. An RF Energy Harvester with MPPT Operating Across a Wide Range of Available Input Power
   Gustavo C. Martins; Wouter A. Serdijn;
   In proc. International Symposium on Circuits and Systems,
   Florence, Italy, May, 27-30 2018.
   document

7. Lab-on-chip devices: gaining ground losing size
   Romao, Veronica C; Martins, Sofia AM; Germano, Jose; Cardoso, Filipe Arroyo; Cardoso, Susana; Freitas, Paulo P;
   ACS nano,
   Volume 11, Issue 11, pp. 10659-10664, 2017.

8. Adaptive Power Convertor for Wireless Power Transfer in Biomedical Applications
   Gustavo C. Martins; Wouter A. Serdijn;
   In Book of Abstracts, 6th Dutch Bio-Medical Engineering Conference, 26 and 27 January 2017, Egmond aan Zee, The Netherlands.,
   2017.
   document

9. Energy-Efficient Low-Power Circuits for Wireless Energy and Data Transfer in IoT Sensor Nodes
   G.C. Martins; A. Urso; A. Mansano; Y. Liu; W.A. Serdijn;
   April 28 2017. Prepublication.
   document

10. Multistage Complex-Impedance Matching Network Analysis and Optimization
    Gustavo Campos Martins; Wouter Serdijn;
    IEEE Transactions on Circuits and Systems II: Express Briefs,
    2016. DOI: 10.1109/TCSII.2016.2534738.
    document

11. Effects of Mg doping on Cu2O thin films and their behavior on the TiO2/Cu2O heterojunction solar cells
    K. Kardarian; D. Nunes; P. M. Sberna; A. Ginsburg; D. A. Keller; J. Vas Pinto; J. Deuermeier; A. Y. Anderson; A. Zaban; R. Martins; E. Fortunato;
    Solar Energy Materials & Solar Cells,
    Volume 147, pp. 27-36, 2016.
    document

12. Implementing a strategy for on-chip detection of cell-free DNA fragments using GMR sensors: A translational application in cancer diagnostics using ALU elements
    Dias, TM; Cardoso, Filipe Arroyo; Martins, SAM; Martins, VC; Cardoso, S; Gaspar, JF; Monteiro, G; Freitas, PP;
    Analytical Methods,
    Volume 8, Issue 1, pp. 119-128, 2016.

13. Adaptive Buck-Boost Converter for RF Energy Harvesting and Transfer in Biomedical Applications
    Gustavo C. Martins; Wouter A. Serdijn;
    In proc. 2016 IEEE Biomedical Circuits and Systems Symposium (BioCAS'2016),
    IEEE, Oct. 17-19 2016.
    document

14. An 8-bit 0.7-GS/s single channel flash-SAR ADC in 65-nm CMOS technology
    D. G. Muratore; A. Akdikmen; E. Bonizzoni; F. Maloberti; U.-F. Chio; S.-W. Sin; R. P. Martins;
    In IEEE European Solid-State Circuits Conference (ESSCIRC),
    2016. DOI: 10.1109/ESSCIRC.2016.7598331
    document

15. Detecting antibody-labeled BCG MNPs using a magnetoresistive biosensor and magnetic labeling technique
    Barroso, Teresa RG; Martins, Verónica C; Cardoso, Filipe Arroyo; Cardoso, Susana; Pedrosa, Jorge; Correia-Neves, Margarida; Rivas, Jos{\'e}; Freitas, Paulo P;
    In Journal of Nano Research,
    Trans Tech Publications Ltd, pp. 92-103, 2016.

16. TiO2/Cu2O All-Oxide Heterojunction Solar Cells Produced by Spray Pyrolysis
    M. Pavan; S. Rühle; A. Ginsburg; D. A. Keller; H. Barad; P. M. Sberna; D. Nunes; R. Martins; A. Y. Anderson; A. Zaban; E. Fortunato;
    Solar Energy Materials & Solar Cells,
    Volume 132, pp. 549-556, Jan. 2015.
    document

17. Rectifier Automatic Impedance Matching for Biomedical Implants
    Gustavo Martins; Wouter Serdijn;
    In Book of Abstracts, 5th Dutch Bio-Medical Engineering Conference,
    Egmond aan Zee, the Netherlands, January 22-23 2015.
    document

18. A bacteriophage detection tool for viability assessment of Salmonella cells
    Fernandes, E; Martins, VC; Nóbrega, Cláudia; Carvalho, CM; Cardoso, Filipe Arroyo; Cardoso, S; Dias, J; Deng, D; Kluskens, LD; Freitas, PP; others;
    Biosensors and Bioelectronics,
    Volume 52, pp. 239-246, 2014.

19. Customized design of magnetic beads for dynamic magnetoresistive cytometry
    Vila, Ana; Martins, Veronica C; Chícharo, Alexandre; Rodriguez-Abreu, Carlos; Fernandes, Ana Carolina; Cardoso, Filipe Arroyo; Cardoso, Susana; Rivas, Jose; Freitas, Paulo;
    IEEE Transactions on Magnetics,
    Volume 50, Issue 11, pp. 1-4, 2014.

20. Challenges in spintronic platforms for biomedical applications
    Freitas, PP; Cardoso, FA; Martins, VC; Fernandes, Elisabete Ramos; Martins, SAM; Dias, T; Amaral, JP; Cardoso, S; Germano, J; Costa, T; others;
    2013.

21. Spintronic devices for biomedical applications
    Freitas, PP; Cardoso, S; Cardoso, FA; Dias, T; Martins, VC; Fernandes, Elisabete Ramos; Carvalho, Carla AOCM; Azeredo, Joana; Amaral, JP; Pinto, V{\'\i}tor; others;
    2013.

22. Spintronic platforms for biomedical applications
    Freitas, PP; Cardoso, Filipe Arroyo; Martins, VC; Martins, SAM; Loureiro, J; Amaral, J; Chaves, RC; Cardoso, S; Fonseca, LP; Sebastião, AM; others;
    Lab on a Chip,
    Volume 12, Issue 3, pp. 546-557, 2012.

23. Waterborne pathogen detection using a magnetoresistive immuno-chip
    Martins, Sofia SA; Martins, Verónica C; Cardoso, Filipe Arroyo; Freitas, Paulo P; Fonseca, Luís P;
    Molecular biological technologies for ocean sensing,
    pp. 263-288, 2012.

24. Optimization and integration of magnetoresistive sensors
    Freitas, Paulo P; Cardoso, Susana; Ferreira, Ricardo; Martins, Verónica C; Guedes, André; Cardoso, Filipe Arroyo; Loureiro, Joana; Macedo, Rita; Chaves, Rui C; Amaral, José;
    In Spin,
    World Scientific Publishing Company, pp. 71-91, 2011.

25. Challenges and trends in the development of a magnetoresistive biochip portable platform
    Martins, Verónica C; Germano, José; Cardoso, Filipe Arroyo; Loureiro, Joana; Cardoso, Susana; Sousa, Leonel; Piedade, Moisés; Fonseca, Luís P; Freitas, PP;
    Journal of Magnetism and Magnetic Materials,
    Volume 322, Issue 9-12, pp. 1655-1663, 2010.

26. Picomolar detection limit on a magnetoresistive biochip after optimization of a thiol-gold based surface chemistry
    Martins, VC; Cardoso, Filipe Arroyo; Freitas, PP; Fonseca, LP;
    Journal of nanoscience and nanotechnology,
    Volume 10, Issue 9, pp. 5994-6002, 2010.

27. Spintronic microfluidic platform for biomedical and environmental applications
    Cardoso, Filipe Arroyo; Martins, VC; Fonseca, LP; Germano, J; Sousa, LA; Piedade, MS; Freitas, PP;
    In Fourth European Workshop on Optical Fibre Sensors,
    SPIE, pp. 55-57, 2010.

28. A portable and autonomous magnetic detection platform for biosensing
    Germano, José; Martins, Verónica C; Cardoso, Filipe Arroyo; Almeida, Teresa M; Sousa, Leonel; Freitas, Paulo P; Piedade, Moisés S;
    Sensors,
    Volume 9, Issue 6, pp. 4119-4137, 2009.

29. Femtomolar limit of detection with a magnetoresistive biochip
    Martins, VC; Cardoso, Filipe Arroyo; Germano, J; Cardoso, S; Sousa, L; Piedade, M; Freitas, PP; Fonseca, LP;
    Biosensors and Bioelectronics,
    Volume 24, Issue 8, pp. 2690-2695, 2009.

30. Magnetoresistive biochip-based portable platforms for biomolecular recognition detection
    Martins, V; Cardoso, Filipe Arroyo; Freitas, P; Germano, J; Cardoso, S; Sousa, L; Piedade, M; Fonseca, L;
    New Biotechnology,
    Issue 25, pp. S358-S359, 2009.

31. Detection of 130 nm magnetic particles by a portable electronic platform using spin valve and magnetic tunnel junction sensors
    Cardoso, Filipe Arroyo; Germano, J; Ferreira, R; Cardoso, S; Martins, VC; Freitas, PP; Piedade, MS; Sousa, L;
    Journal of Applied Physics,
    Volume 103, Issue 7, pp. 07A310, 2008.

32. Integrated spintronic platforms for biomolecular recognition detection
    Martins, VC; Cardoso, Filipe Arroyo; Loureiro, J; Mercier, M; Germano, J; Cardoso, S; Ferreira, R; Fonseca, LP; Sousa, L; Piedade, MS; others;
    In AIP Conference Proceedings,
    American Institute of Physics, pp. 150-175, 2008.

33. Nanotechnology and the Detection of Biomolecular Recognition Using Magnetoresistive Transducers
    Freitas, Paulo P; Ferreira, Hugo A; Cardoso, Filipe Arroyo; Cardoso, Susana; Ferreira, Ricardo; Almeida, José; Guedes, Andre; Chu, Virginia; Conde, João P; Martins, Verónica; others;
    In A Portrait of State-of-the-Art Research at the Technical University of Lisbon,
    Springer Netherlands, pp. 3-22, 2007.

34. A new methodology in power estimation in CMOS combinational circuits at logic level (U-SP-2-I-ICT)
    A.L. Aita; L.L. De Oliveira; J.P. Dos Santos Martins;
    In s.n. (Ed.), Proceedings of the 48th IEEE International Midwest Symposium On Circuits And Systems (MWSCAS2005),
    IEEE, pp. 1127-1130, 2006.

35. Scalable Magnetoresistive Biochips For Biomolecular recognition
    Cardoso, Filipe Arroyo; Ferreira, H; Freitas, P; Conde, J; Chu, V; Germano, J; Sousa, L; Piedade, M; Martins, V; Fonseca, L; others;
    In 2006 IEEE International Magnetics Conference (INTERMAG),
    IEEE, pp. 249-249, 2006.

36. An array of Fabry-Perot optical-channels for biological fluids analysis
    G. Minas; J.C. Ribeiro; J.S. Martins; R.F. Wolffenbuttel; J.H. Correia;
    Sensors and Actuators A: Physical: an international journal devoted to research and development of physical and chemical transducers,
    Volume 115, pp. 362-367, 2004. ed. is niet bekend.

37. Biological microsystems for measuring uric acid in biological fluids
    G. Minas; J.S. Martins; J.C. Ribeiro; R.F. Wolffenbuttel; J.H. Correia;
    Sensors and Actuators A: Physical: an international journal devoted to research and development of physical and chemical transducers,
    Volume 110, pp. 33-38, 2004. ed. is niet bekend.

38. A 16 fabry-perot optical-channels array for biological fluids analysis using white light
    G. Minas; J.C. Ribeiro; J.S. Martins; R.F. Wolffenbuttel; J.H. Correia;
    s.n. (Ed.);
    University of Minho, , pp. 28-30, 2003.

39. Lab-on-a-chip for measuring uric acid in biological fluids
    G. Minas; J.S. Martins; C. Pereira; C. Lima; R.F. Wolffenbuttel; J.H. Correia;
    Czech Technical University, , pp. 66-69, 2002.

40. Magnetoresistive Sensors for Biological and Biomedical Applications
    Freitas, PP; Cardoso, FA; Martins, VC; Loureiro, J; Amaral, J; Chaves, RC; Cardoso, S;
    

41. BIOLOGICAL DETECTION LIMIT OF A GMR-BASED BIOCHIP FOR PATHOGENIC ANALYSIS
    Martins, VC; Cardoso, FA; Cardoso, S; Fonseca, LP; Freitas, PP;
    

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