Conferences related to Biomedical Electronics

Back to Top

2020 42nd Annual International Conference of the IEEE Engineering in Medicine & Biology Society (EMBC)

The conference program will consist of plenary lectures, symposia, workshops and invitedsessions of the latest significant findings and developments in all the major fields of biomedical engineering.Submitted papers will be peer reviewed. Accepted high quality papers will be presented in oral and postersessions, will appear in the Conference Proceedings and will be indexed in PubMed/MEDLINE


2020 IEEE 17th International Symposium on Biomedical Imaging (ISBI 2020)

The IEEE International Symposium on Biomedical Imaging (ISBI) is the premier forum for the presentation of technological advances in theoretical and applied biomedical imaging. ISBI 2020 will be the 17th meeting in this series. The previous meetings have played a leading role in facilitating interaction between researchers in medical and biological imaging. The 2020 meeting will continue this tradition of fostering cross-fertilization among different imaging communities and contributing to an integrative approach to biomedical imaging across all scales of observation.

  • 2019 IEEE 16th International Symposium on Biomedical Imaging (ISBI)

    The IEEE International Symposium on Biomedical Imaging (ISBI) is the premier forum for the presentation of technological advances in theoretical and applied biomedical imaging.ISBI 2019 will be the 16th meeting in this series. The previous meetings have played a leading role in facilitating interaction between researchers in medical and biological imaging. The 2019 meeting will continue this tradition of fostering cross fertilization among different imaging communities and contributing to an integrative approach to biomedical imaging across all scales of observation.

  • 2018 IEEE 15th International Symposium on Biomedical Imaging (ISBI 2018)

    The IEEE International Symposium on Biomedical Imaging (ISBI) is the premier forum for the presentation of technological advances in theoretical and applied biomedical imaging. ISBI 2018 will be the 15th meeting in this series. The previous meetings have played a leading role in facilitating interaction between researchers in medical and biological imaging. The 2018 meeting will continue this tradition of fostering crossfertilization among different imaging communities and contributing to an integrative approach to biomedical imaging across all scales of observation.

  • 2017 IEEE 14th International Symposium on Biomedical Imaging (ISBI 2017)

    The IEEE International Symposium on Biomedical Imaging (ISBI) is the premier forum for the presentation of technological advances in theoretical and applied biomedical imaging. ISBI 2017 will be the 14th meeting in this series. The previous meetings have played a leading role in facilitating interaction between researchers in medical and biological imaging. The 2017 meeting will continue this tradition of fostering crossfertilization among different imaging communities and contributing to an integrative approach to biomedical imaging across all scales of observation.

  • 2016 IEEE 13th International Symposium on Biomedical Imaging (ISBI 2016)

    The IEEE International Symposium on Biomedical Imaging (ISBI) is the premier forumfor the presentation of technological advances in theoretical and applied biomedical imaging. ISBI 2016 willbe the thirteenth meeting in this series. The previous meetings have played a leading role in facilitatinginteraction between researchers in medical and biological imaging. The 2016 meeting will continue thistradition of fostering crossfertilization among different imaging communities and contributing to an integrativeapproach to biomedical imaging across all scales of observation.

  • 2015 IEEE 12th International Symposium on Biomedical Imaging (ISBI 2015)

    The IEEE International Symposium on Biomedical Imaging (ISBI) is the premier forum for the presentation of technological advances in theoretical and applied biomedical imaging. ISBI 2015 will be the 12th meeting in this series. The previous meetings have played a leading role in facilitating interaction between researchers in medical and biological imaging. The 2014 meeting will continue this tradition of fostering crossfertilization among different imaging communities and contributing to an integrative approach to biomedical imaging across all scales of observation.

  • 2014 IEEE 11th International Symposium on Biomedical Imaging (ISBI 2014)

    The IEEE International Symposium on Biomedical Imaging (ISBI) is the premier forum for the presentation of technological advances in theoretical and applied biomedical imaging. ISBI 2014 will be the eleventh meeting in this series. The previous meetings have played a leading role in facilitating interaction between researchers in medical and biological imaging. The 2014 meeting will continue this tradition of fostering crossfertilization among different imaging communities and contributing to an integrative approach to biomedical imaging across all scales of observation.

  • 2013 IEEE 10th International Symposium on Biomedical Imaging (ISBI 2013)

    To serve the biological, biomedical, bioengineering, bioimaging and other technical communities through a quality program of presentations and papers on the foundation, application, development, and use of biomedical imaging.

  • 2012 IEEE 9th International Symposium on Biomedical Imaging (ISBI 2012)

    To serve the biological, biomedical, bioengineering, bioimaging, and other technical communities through a quality program of presentations and papers on the foundation, application, development, and use of biomedical imaging.

  • 2011 IEEE 8th International Symposium on Biomedical Imaging (ISBI 2011)

    To serve the biological, biomedical, bioengineering, bioimaging, and other technical communities through a quality program of presentations and papers on the foundation, application, development, and use of biomedical imaging.

  • 2010 IEEE 7th International Symposium on Biomedical Imaging (ISBI 2010)

    To serve the biological, biomedical, bioengineering, bioimaging, and other technical communities through a quality program of presentations and papers on the foundation, application, development, and use of biomedical imaging.

  • 2009 IEEE 6th International Symposium on Biomedical Imaging (ISBI 2009)

    Algorithmic, mathematical and computational aspects of biomedical imaging, from nano- to macroscale. Topics of interest include image formation and reconstruction, computational and statistical image processing and analysis, dynamic imaging, visualization, image quality assessment, and physical, biological and statistical modeling. Molecular, cellular, anatomical and functional imaging modalities and applications.

  • 2008 IEEE 5th International Symposium on Biomedical Imaging (ISBI 2008)

    Algorithmic, mathematical and computational aspects of biomedical imaging, from nano- to macroscale. Topics of interest include image formation and reconstruction, computational and statistical image processing and analysis, dynamic imaging, visualization, image quality assessment, and physical, biological and statistical modeling. Molecular, cellular, anatomical and functional imaging modalities and applications.

  • 2007 IEEE 4th International Symposium on Biomedical Imaging: Macro to Nano (ISBI 2007)

  • 2006 IEEE 3rd International Symposium on Biomedical Imaging: Macro to Nano (ISBI 2006)

  • 2004 2nd IEEE International Symposium on Biomedical Imaging: Macro to Nano (ISBI 2004)

  • 2002 1st IEEE International Symposium on Biomedical Imaging: Macro to Nano (ISBI 2002)


2020 IEEE Global Engineering Education Conference (EDUCON)

The IEEE Global Engineering Education Conference (EDUCON) 2020 is the eleventh in a series of conferences that rotate among central locations in IEEE Region 8 (Europe, Middle East and North Africa). EDUCON is one of the flagship conferences of the IEEE Education Society. It seeks to foster the area of Engineering Education under the leadership of the IEEE Education Society.


2020 IEEE Nuclear Science Symposium and Medical Imaging Conference (NSS/MIC)

All areas of ionizing radiation detection - detectors, signal processing, analysis of results, PET development, PET results, medical imaging using ionizing radiation


IECON 2020 - 46th Annual Conference of the IEEE Industrial Electronics Society

IECON is focusing on industrial and manufacturing theory and applications of electronics, controls, communications, instrumentation and computational intelligence.


More Conferences

Periodicals related to Biomedical Electronics

Back to Top

Advanced Packaging, IEEE Transactions on

The IEEE Transactions on Advanced Packaging has its focus on the modeling, design, and analysis of advanced electronic, photonic, sensors, and MEMS packaging.


Applied Superconductivity, IEEE Transactions on

Contains articles on the applications and other relevant technology. Electronic applications include analog and digital circuits employing thin films and active devices such as Josephson junctions. Power applications include magnet design as well asmotors, generators, and power transmission


Biomedical Circuits and Systems, IEEE Transactions on

The Transactions on Biomedical Circuits and Systems addresses areas at the crossroads of Circuits and Systems and Life Sciences. The main emphasis is on microelectronic issues in a wide range of applications found in life sciences, physical sciences and engineering. The primary goal of the journal is to bridge the unique scientific and technical activities of the Circuits and Systems ...


Biomedical Engineering, IEEE Reviews in

The IEEE Reviews in Biomedical Engineering will review the state-of-the-art and trends in the emerging field of biomedical engineering. This includes scholarly works, ranging from historic and modern development in biomedical engineering to the life sciences and medicine enabled by technologies covered by the various IEEE societies.


Biomedical Engineering, IEEE Transactions on

Broad coverage of concepts and methods of the physical and engineering sciences applied in biology and medicine, ranging from formalized mathematical theory through experimental science and technological development to practical clinical applications.


More Periodicals

Most published Xplore authors for Biomedical Electronics

Back to Top

Xplore Articles related to Biomedical Electronics

Back to Top

The perspective of biomedical electronics

SENSORS, 2010 IEEE, 2010

The key factors driving both research and market of biomedical electronics are aging populations, rising healthcare costs, the need for access to medical diagnosis and treatment in emerging and remote regions and in homes, and the fast development of biotechnologies. The applications of biomedical electronics in research, design, and development of biomimetic devices/systems, instruments and appliances that treat intractable neurological ...


A low-power fully differential reconfigurable biomedical electronics interface to detect heart signals

2010 Asia Pacific Conference on Postgraduate Research in Microelectronics and Electronics (PrimeAsia), 2010

A biomedical electronics interface to detect heart signals is presented including a reconflgurable full differential fifth-order Bessel Gm-C filter and a 12 bit low-power fully differential successive approximation register analog-to-digital converter (SAR ADC). The total fully differential structure reduces the input signal noise and distortion effectively. A switch array is used in Gm-C filter to realize three low cutoff frequencies ...


Cooperative education and internships for biomedical electronics students

Proceedings of the Annual International Conference of the IEEE Engineering in Medicine and Biology Society, 1988

The author provides information on the development and implementation of cooperative internship programs for biomedical electronics technology students. The advantages and disadvantages of paid and nonpaid positions are discussed. An analysis is given from the standpoint of the student, employer and the educational institution. It is also shown that there are many considerations that must be explored by the educational ...


A teacher education curriculum for biomedical electronics technology education

FIE'99 Frontiers in Education. 29th Annual Frontiers in Education Conference. Designing the Future of Science and Engineering Education. Conference Proceedings (IEEE Cat. No.99CH37011, 1999

It is a very big problem for biomedical equipment technology and technician schools to find teachers to teach biomedical equipment technology courses. Here, the authors describe how a teacher education curriculum has been designed and developed to overcome this problem.


Biomedical electronics-update

Proceedings of the IEEE, 2000

Lusted's brief paper, "Biomedical electronics: 2012 A.D." [1961], remains a shrewd prediction. Lusted focuses on three aspects of organ replacement and then on genetics. The physiological control systems for human organs have proved to be considerably more complex than the simple "feedback loop" of 1961. In his prediction, Lusted quite reasonably names "heart, kidneys, stomach, and even liver" as logical ...


More Xplore Articles

Educational Resources on Biomedical Electronics

Back to Top

IEEE-USA E-Books

  • The perspective of biomedical electronics

    The key factors driving both research and market of biomedical electronics are aging populations, rising healthcare costs, the need for access to medical diagnosis and treatment in emerging and remote regions and in homes, and the fast development of biotechnologies. The applications of biomedical electronics in research, design, and development of biomimetic devices/systems, instruments and appliances that treat intractable neurological disorders, restore health and extend life, and enable biotechnology development is an exciting area of future growth for the electronics industry. It is an area that bridge engineering, biology, and medicine. Great opportunities and challenges of biomedical electronics have attracted tremendous research efforts in both academia and industry. The major future trends in biomedical electronics are portability, miniaturization, connectivity, humanization, security, and reliability. Portability requires accurate bio-signal sensors/actuators, efficient system power management, ultra-low power electronics, and energy harvesters. Miniaturization requires advanced integration technologies like CMOS integrated circuits or heterogeneous integration of CMOS, MEMS, and/or flexible technologies. Connectivity requires low power RF wireless communication technologies. Humanization of biomedical devices requires design considerations from patients and clinical experiences. Data security requires more hardware and software tools to support medical data security in RF transmission and storage. Reliability requires enforcement of regulations and standards. All the leading technologies to meet the major trends will be described. The general architecture of a biomedical electronic system may include microsystems, biomaterials, packaging/integration, and biotic-abiotic interface. A microsystem may consist of sensors/actuators, bio-signal processing units, power harvesting and management unit, and/or RF communication units, that involves many cutting-edge research topics. The research of biomaterials is related to biocompatibility, biophysics, bio- adhesives and organics. Packing and integration requires technologies in high- density interconnect, flexible substrates, inert coating, and thin-film polymers. Biotic-abiotic interface requires research on tissue response, neuroscience, electrophysiology, cell growth, and biomarkers. The applications of biomedical electronic systems in the treatment of intractable neurological disorders and chronic diseases, healthcare, telemedicine, preventive medicine, etc. will also be addressed. As demonstrative examples, two biomedical electronic systems will be presented. One is the sub-retinal implantation system for visual prostheses and the other is close-loop deep brain stimulation (DBS) system for epilepsy. The sub-retinal implantation system includes intraocular and extraocular units. The former contains photo-sensors and electrodes for optical receiver and stimulation, and the latter one is equipped with processor and optical transmitter. Successful ERG signal recorded after the implantation indicated that the method is promising. A divisional power supply technique enabling three times larger the output stimulating current is also proposed to solve limited power supply problem. The DBS system consists of intraocular chips with sensors/stimulators, bio- signal processing, RF transceiver, and inductive power unit and extraocular part with RF transceiver and inductive coils. The system detects patient's EEG and automatically generates DBS electrical pulses to suppress epilepsy. Finally, some research challenges and future development of biomedical electronics will be presented and discussed.

  • A low-power fully differential reconfigurable biomedical electronics interface to detect heart signals

    A biomedical electronics interface to detect heart signals is presented including a reconflgurable full differential fifth-order Bessel Gm-C filter and a 12 bit low-power fully differential successive approximation register analog-to-digital converter (SAR ADC). The total fully differential structure reduces the input signal noise and distortion effectively. A switch array is used in Gm-C filter to realize three low cutoff frequencies for different biomédical signals processing. In SAR ADC, hybrid 9-bit charge-redistribution and 3-bit resistor binary-weighted DAC techniques and dynamic latch comparator are adopted to achieve optimization of resolution, area and power consumption. Fabricated in SMIC 0.18-μm 1P6M mixed-signal CMOS technology, the proposed biomédical electronics detecting interface only consume below 100μW under 1.8V supply voltage.

  • Cooperative education and internships for biomedical electronics students

    The author provides information on the development and implementation of cooperative internship programs for biomedical electronics technology students. The advantages and disadvantages of paid and nonpaid positions are discussed. An analysis is given from the standpoint of the student, employer and the educational institution. It is also shown that there are many considerations that must be explored by the educational institution as well as the employer when trying to choose a training program. The many programs in place today-alternating terms in school and work or part days in school and on the job, paid positions or nonpaid positions (internships)-provide options that must be considered in order to institute a successful program of work experience in the curriculum of a school or in a biomedical department of a hospital or company. Topics that must be addressed when exploring a cooperative program are outlined.<<ETX>>

  • A teacher education curriculum for biomedical electronics technology education

    It is a very big problem for biomedical equipment technology and technician schools to find teachers to teach biomedical equipment technology courses. Here, the authors describe how a teacher education curriculum has been designed and developed to overcome this problem.

  • Biomedical electronics-update

    Lusted's brief paper, "Biomedical electronics: 2012 A.D." [1961], remains a shrewd prediction. Lusted focuses on three aspects of organ replacement and then on genetics. The physiological control systems for human organs have proved to be considerably more complex than the simple "feedback loop" of 1961. In his prediction, Lusted quite reasonably names "heart, kidneys, stomach, and even liver" as logical candidates for successful replacement by 2012 with artificial devices. Of course, none of the devices is yet available, nor in sight. The author of the present paper reexamines artificial organs and control, genetics and the evolution of biomedical electronics.

  • Developing e-learning functionalities on electrical bioimpedance for the biomedical electronics course

    In this paper the development of the electrical bioimpedance topic as a part of the traditional master's course of Biomedical Electronics is discussed. A description of this part of the course and analysis of it is given together with explanations to the way of discussing the electrical properties of the biological objects, tissues and organs in the course. Discussion of measurement of the Electrical Bioimpedance, and of the electronic means for this purpose are also presented. All this is done in connection with the problematics of providing the students the e-learning facilities over the Internet.

  • Innovative devices in biomedical electronics

    In this paper we present our principal projects in biomedical electronics, especially applied to telemedicine. The designed systems are characterized by originality and by plainness of use, as they planned with a very high level of automation (so called ldquointelligentrdquo devices).

  • Screen printed conductive pastes for biomedical electronics

    This paper describes the evaluation of screen printed materials fabricated with an additive manufacturing process for flexible biomedical applications. Five different conductive polymeric thick film pastes, printed on a polyimide substrate have been investigated. For the intended biocompatible applications, the cytotoxicity of the used materials was tested through adherent cell test. Furthermore, the electrical resistance, the printed structure thickness, the surface energy and roughness have been examined. Additionally, the mechanical resilience of the printed materials was tested through a bending test. During the bending the electrical resistance of printed meander structures could be monitored indicating failures. Two out of five materials were qualified as non-toxic, all of the materials are useable for flexible electronics, as they provide good electrical and mechanical properties.

  • A power efficient programmable gain boosting current mirror for biomedical electronics

    In this paper, a power efficient gain boosting current mirror with fast stand- by recovery (4.5μs) and a maximum gain of 80dB is proposed in a 0.35μm CMOS process with 3V power supply. The gain is achieved from the aspect ratios in transistors and deployed closed loop amplifier. In active mode, it can deliver upto 1mA from 0.1μA input current with approximately 1.2μA in biasing circuits. It consumes only 0.8μW during stand-by mode. A digital calibration circuit is employed to overcome device mismatch and process variation. This generates accurate output currents within a range of ±8%, whereas without calibration, the variation of ±33% at output currents is observed. This technique can be used in biomedical devices, which seek high power efficiency.

  • Energy-efficient switching scheme in SAR ADC for biomedical electronics

    An energy-efficient switching scheme for a low-power successive approximation register (SAR) analogue-to-digital converter (ADC) is proposed. Taking the parasitic capacitance of the capacitor array into consideration, the average switching energy of the proposed scheme can be reduced by 97.4% compared with the conventional architecture. The proposed scheme also reduces the number of capacitors in the capacitor array by 75.5% and hence achieves area efficiency with high performance.




Jobs related to Biomedical Electronics

Back to Top