14 results on '"Vermeeren, Günter"'
Search Results
2. Radiofrequency exposure near an attocell as part of an ultra-high density access network.
- Author
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Thielens A, Vermeeren G, Caytan O, Torfs G, Demeester P, Bauwelinck J, Rogier H, Martens L, and Joseph W
- Subjects
- Absorption, Radiation, Humans, Models, Theoretical, Phantoms, Imaging, Wireless Technology, Computer Communication Networks, Radiation Exposure analysis, Radio Waves
- Abstract
In the future, wireless radiofrequency (RF) telecommunications networks will provide users with gigabit-per-second data rates. Therefore, these networks are evolving toward hybrid networks, which will include commonly used macro- and microcells in combination with local ultra-high density access networks consisting of so-called attocells. The use of attocells requires a proper compliance assessment of exposure to RF electromagnetic radiation. This paper presents, for the first time, such a compliance assessment of an attocell operating at 3.5 GHz with an input power of 1 mW, based on both root-mean-squared electric field strength (E
rms ) and peak 10 g-averaged specific absorption rate (SAR10g ) values. The Erms values near the attocell were determined using finite-difference time-domain (FDTD) simulations and measurements by a tri-axial probe. They were compared to the International Commission on Non-Ionizing Radiation Protection's (ICNIRP) reference levels. All measured and simulated Erms values above the attocell were below 5.9 V/m and lower than reference levels. The SAR10g values were measured in a homogeneous phantom, which resulted in an SAR10g of 9.7 mW/kg, and used FDTD simulations, which resulted in an SAR10g of 7.2 mW/kg. FDTD simulations of realistic exposure situations were executed using a heterogeneous phantom, which yielded SAR10g values lower than 2.8 mW/kg. The studied dosimetric quantities were in compliance with ICNIRP guidelines when the attocell was fed an input power <1 mW. The deployment of attocells is thus a feasible solution for providing broadband data transmission without drastically increasing personal RF exposure. Bioelectromagnetics. 38:295-306, 2017. © 2017 Wiley Periodicals, Inc., (© 2017 Wiley Periodicals, Inc.)- Published
- 2017
- Full Text
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3. Assessment of contribution of other users to own total whole-body RF absorption in train environment.
- Author
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Plets D, Joseph W, Aerts S, Vermeeren G, Varsier N, Wiart J, and Martens L
- Subjects
- Cell Phone, Humans, Absorption, Radiation, Radiation Monitoring, Radio Waves, Transportation
- Abstract
For the first time, the contribution of radio-frequent radiation originating from other people's devices to total own whole-body absorption is assessed in a simulation study. Absorption in a train environment due to base station's downlink is compared with absorption due to uplink (UL) of the user's own mobile device and absorption due to the UL of 0, 1, 5, or 15 other nearby active users. In a Global System for Mobile Communications (GSM) macro cell connection scenario, UL of 15 other users can cause up to 19% of total absorption when calling yourself and up to 100% when not calling yourself. In a Universal Mobile Telecommunications System (UMTS) femtocell connection scenario, UL of 15 other users contributes to total absorption of a non-calling user for no more than 1.5%. For five other users in the train besides the considered person, median total whole-body Specific Absorption Rate is reduced by a factor of about 400000 when deploying a UMTS femtocell base station instead of relying on the GSM macrocell., (© 2015 Wiley Periodicals, Inc.)
- Published
- 2015
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4. SAR compliance assessment of PMR 446 and FRS walkie-talkies.
- Author
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Vermeeren G, Joseph W, and Martens L
- Subjects
- Computer Simulation, Consumer Product Safety, Equipment Design, Equipment Safety, Wireless Technology instrumentation, Radio standards, Radio Waves, Wireless Technology standards
- Abstract
The vast amount of studies on radiofrequency dosimetry deal with exposure due to mobile devices and base station antennas for cellular communication systems. This study investigates compliance of walkie-talkies to exposure guidelines established by the International Commission on Non-Ionizing Radiation Protection and the Federal Communications Committee. The generic walkie-talkie consisted of a helical antenna and a ground plane and was derived by reverse engineering of a commercial walkie-talkie. Measured and simulated values of antenna characteristics and electromagnetic near fields of the generic walkie-talkie were within 2% and 8%, respectively. We also validated normalized electromagnetic near fields of the generic walkie-talkie against a commercial device and observed a very good agreement (deviation <6%). We showed that peak localized specific absorption rate (SAR) induced in the oval flat phantom by the generic walkie-talkie is in agreement with four commercial devices if input power of the generic walkie-talkie is rescaled based on magnetic near field. Finally, we found that SAR of commercial devices is within current SAR limits for general public exposure for a worst-case duty cycle of 100%, that is, about 3 times and 6 times lower than the limit on the 1 g SAR (1.6 W/kg) and 10 g SAR (2 W/kg), respectively. But, an effective radiated power as specified by the Private Mobile Radio at 446 MHz (PMR 446) radio standard can cause localized SAR exceeding SAR limits for 1 g of tissue., (© 2015 Wiley Periodicals, Inc.)
- Published
- 2015
- Full Text
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5. Experimental Path Loss Models for In-Body Communications Within 2.36-2.5 GHz.
- Author
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Chávez-Santiago R, Garcia-Pardo C, Fornes-Leal A, Vallés-Lluch A, Vermeeren G, Joseph W, Balasingham I, and Cardona N
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- Equipment Design, Humans, Models, Theoretical, Muscles physiology, Telemetry instrumentation, Monitoring, Physiologic instrumentation, Phantoms, Imaging, Prostheses and Implants, Radio Waves, Wireless Technology instrumentation
- Abstract
Biomedical implantable sensors transmitting a variety of physiological signals have been proven very useful in the management of chronic diseases. Currently, the vast majority of these in-body wireless sensors communicate in frequencies below 1 GHz. Although the radio propagation losses through biological tissues may be lower in such frequencies, e.g., the medical implant communication services band of 402 to 405 MHz, the maximal channel bandwidths allowed therein constrain the implantable devices to low data rate transmissions. Novel and more sophisticated wireless in-body sensors and actuators may require higher data rate communication interfaces. Therefore, the radio spectrum above 1 GHz for the use of wearable medical sensing applications should be considered for in-body applications too. Wider channel bandwidths and smaller antenna sizes may be obtained in frequency bands above 1 GHz at the expense of larger propagation losses. Therefore, in this paper, we present a phantom-based radio propagation study for the frequency bands of 2360 to 2400 MHz, which has been set aside for wearable body area network nodes, and the industrial, scientific, medical band of 2400 to 2483.5 MHz. Three different channel scenarios were considered for the propagation measurements: in-body to in-body, in-body to on-body, and in-body to off-body. We provide for the first time path loss formulas for all these cases.
- Published
- 2015
- Full Text
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6. Prediction and comparison of downlink electric-field and uplink localised SAR values for realistic indoor wireless planning.
- Author
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Plets D, Joseph W, Aerts S, Vanhecke K, Vermeeren G, and Martens L
- Subjects
- Algorithms, Cell Phone, Computer Simulation, Electromagnetic Fields adverse effects, Environmental Exposure, Humans, Models, Theoretical, Radiation Monitoring statistics & numerical data, Radio Waves adverse effects, Wireless Technology instrumentation, Wireless Technology statistics & numerical data
- Abstract
In this paper, for the first time a heuristic network calculator for both whole-body exposure due to indoor base station antennas or access points (downlink exposure) and localised exposure due to the mobile device (uplink exposure) in indoor wireless networks is presented. As an application, three phone call scenarios are investigated (Universal Mobile Telecommunications System (UMTS) macrocell, UMTS femtocell and WiFi voice-over-IP) and compared with respect to the electric-field strength and localised specific absorption rate (SAR) distribution. Prediction models are created and successfully validated with an accuracy of 3 dB. The benefits of the UMTS power control mechanisms are demonstrated. However, dependent on the macrocell connection quality and on the user's average phone call connection time, also the macrocell solution might be preferential from an exposure point of view for the considered scenario., (© The Author 2014. Published by Oxford University Press. All rights reserved. For Permissions, please email: journals.permissions@oup.com.)
- Published
- 2014
- Full Text
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7. Personal distributed exposimeter for radio frequency exposure assessment in real environments.
- Author
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Thielens A, De Clercq H, Agneessens S, Lecoutere J, Verloock L, Declercq F, Vermeeren G, Tanghe E, Rogier H, Puers R, Martens L, and Joseph W
- Subjects
- Confidence Intervals, Humans, Male, Environment, Phantoms, Imaging, Radio Waves, Radiometry instrumentation
- Abstract
For the first time, a personal distributed exposimeter (PDE) for radio frequency (RF) measurements is presented. This PDE is designed based on numerical simulations and is experimentally evaluated using textile antennas and wearable electronics. A prototype of the PDE is calibrated in an anechoic chamber. Compared to conventional exposimeters, which only measure in one position on the body, an excellent isotropy of 0.5 dB (a factor of 1.1) and a 95% confidence interval of 7 dB (a factor of 5) on power densities are measured., (© 2013 Wiley Periodicals, Inc.)
- Published
- 2013
- Full Text
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8. Determination of the duty cycle of WLAN for realistic radio frequency electromagnetic field exposure assessment.
- Author
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Joseph W, Pareit D, Vermeeren G, Naudts D, Verloock L, Martens L, and Moerman I
- Subjects
- Body Burden, Computer Simulation, Humans, Electromagnetic Fields, Environmental Exposure analysis, Environmental Exposure statistics & numerical data, Models, Theoretical, Radiation Monitoring methods, Radio Waves, Wireless Technology statistics & numerical data
- Abstract
Wireless Local Area Networks (WLANs) are commonly deployed in various environments. The WLAN data packets are not transmitted continuously but often worst-case exposure of WLAN is assessed, assuming 100% activity and leading to huge overestimations. Actual duty cycles of WLAN are thus of importance for time-averaging of exposure when checking compliance with international guidelines on limiting adverse health effects. In this paper, duty cycles of WLAN using Wi-Fi technology are determined for exposure assessment on large scale at 179 locations for different environments and activities (file transfer, video streaming, audio, surfing on the internet, etc.). The median duty cycle equals 1.4% and the 95th percentile is 10.4% (standard deviation SD = 6.4%). Largest duty cycles are observed in urban and industrial environments. For actual applications, the theoretical upper limit for the WLAN duty cycle is 69.8% and 94.7% for maximum and minimum physical data rate, respectively. For lower data rates, higher duty cycles will occur. Although counterintuitive at first sight, poor WLAN connections result in higher possible exposures. File transfer at maximum data rate results in median duty cycles of 47.6% (SD = 16%), while it results in median values of 91.5% (SD = 18%) at minimum data rate. Surfing and audio streaming are less intensively using the wireless medium and therefore have median duty cycles lower than 3.2% (SD = 0.5-7.5%). For a specific example, overestimations up to a factor 8 for electric fields occur, when considering 100% activity compared to realistic duty cycles., (Copyright © 2012 Elsevier Ltd. All rights reserved.)
- Published
- 2013
- Full Text
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9. Between-country comparison of whole-body SAR from personal exposure data in Urban areas.
- Author
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Joseph W, Frei P, Röösli M, Vermeeren G, Bolte J, Thuróczy G, Gajšek P, Trček T, Mohler E, Juhász P, Finta V, and Martens L
- Subjects
- Absorption, Adult, Body Burden, Environment, Humans, Infant, Male, Phantoms, Imaging, Cities statistics & numerical data, Electromagnetic Fields, Environmental Exposure analysis, Radio Waves, Whole-Body Irradiation
- Abstract
In five countries (Belgium, Switzerland, Slovenia, Hungary, and the Netherlands), personal radio frequency electromagnetic field measurements were performed in different microenvironments such as homes, public transports, or outdoors using the same exposure meters. From the mean personal field exposure levels (excluding mobile phone exposure), whole-body absorption values in a 1-year-old child and adult male model were calculated using a statistical multipath exposure method and compared for the five countries. All mean absorptions (maximal total absorption of 3.4 µW/kg for the child and 1.8 µW/kg for the adult) were well below the International Commission on Non-Ionizing Radiation Protection (ICNIRP) basic restriction of 0.08 W/kg for the general public. Generally, incident field exposure levels were well correlated with whole-body absorptions (SAR(wb) ), although the type of microenvironment, frequency of the signals, and dimensions of the considered phantom modify the relationship between these exposure measures. Exposure to the television and Digital Audio Broadcasting band caused relatively higher SAR(wb) values (up to 65%) for the 1-year-old child than signals at higher frequencies due to the body size-dependent absorption rates. Frequency Modulation (FM) caused relatively higher absorptions (up to 80%) in the adult male., (Copyright © 2012 Wiley Periodicals, Inc.)
- Published
- 2012
- Full Text
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10. In situ occupational and general public exposure to VHF/UHF transmission for air traffic communication.
- Author
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Joseph W, Goeminne F, Verloock L, Vermeeren G, and Martens L
- Subjects
- Electromagnetic Radiation, Humans, Occupational Exposure prevention & control, Radiation Protection, Aviation instrumentation, Occupational Exposure analysis, Public Health, Radiation Monitoring, Radio Waves
- Abstract
Occupational and general public exposure due to very high frequency (VHF)/ultra high frequency (UHF) transmission centres for verbal communication for air traffic control is investigated in situ for the first time. These systems are used for communication with aircraft, resulting in different human exposure from that of classical broadcasting. Measurement methods are proposed for the exposure assessment, and a measurement campaign is executed in three transmission centres. By investigating the temporal behaviour of the VHF signals for 6 d, a realistic worst-case duty cycle of 29 % is determined. Periods of high exposures corresponding with high aircraft traffic are from 7 a.m. to 1 p.m. and in the evening. All measured electric-field values satisfy the International Commission on Non-ionizing Radiation Protection guidelines. Fields vary from 0.2 to 21.1 V m(-1) for occupational exposure and from 0.007 to 8.0 V m(-1) for general public exposure. The average fields equal 5.2 V m(-1) for workers, and 0.7 V m(-1) for general public.
- Published
- 2012
- Full Text
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11. In situ LTE exposure of the general public: Characterization and extrapolation.
- Author
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Joseph W, Verloock L, Goeminne F, Vermeeren G, and Martens L
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- Cities statistics & numerical data, Data Interpretation, Statistical, Environmental Exposure adverse effects, Time Factors, Environmental Exposure analysis, Public Health, Radio Waves adverse effects, Telecommunications
- Abstract
In situ radiofrequency (RF) exposure of the different RF sources is characterized in Reading, United Kingdom, and an extrapolation method to estimate worst-case long-term evolution (LTE) exposure is proposed. All electric field levels satisfy the International Commission on Non-Ionizing Radiation Protection (ICNIRP) reference levels with a maximal total electric field value of 4.5 V/m. The total values are dominated by frequency modulation (FM). Exposure levels for LTE of 0.2 V/m on average and 0.5 V/m maximally are obtained. Contributions of LTE to the total exposure are limited to 0.4% on average. Exposure ratios from 0.8% (LTE) to 12.5% (FM) are obtained. An extrapolation method is proposed and validated to assess the worst-case LTE exposure. For this method, the reference signal (RS) and secondary synchronization signal (S-SYNC) are measured and extrapolated to the worst-case value using an extrapolation factor. The influence of the traffic load and output power of the base station on in situ RS and S-SYNC signals are lower than 1 dB for all power and traffic load settings, showing that these signals can be used for the extrapolation method. The maximal extrapolated field value for LTE exposure equals 1.9 V/m, which is 32 times below the ICNIRP reference levels for electric fields., (Copyright © 2012 Wiley Periodicals, Inc.)
- Published
- 2012
- Full Text
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12. Comparison of personal radio frequency electromagnetic field exposure in different urban areas across Europe.
- Author
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Joseph W, Frei P, Roösli M, Thuróczy G, Gajsek P, Trcek T, Bolte J, Vermeeren G, Mohler E, Juhász P, Finta V, and Martens L
- Subjects
- Europe, Humans, Electromagnetic Fields, Environmental Exposure, Radio Waves, Urban Population
- Abstract
Background: Only limited data are available on personal radio frequency electromagnetic field (RF-EMF) exposure in everyday life. Several European countries performed measurement studies in this area of research. However, a comparison between countries regarding typical exposure levels is lacking., Objectives: To compare for the first time mean exposure levels and contributions of different sources in specific environments between different European countries., Methods: In five countries (Belgium, Switzerland, Slovenia, Hungary, and the Netherlands), measurement studies were performed using the same personal exposure meters. The pooled data were analyzed using the robust regression on order statistics (ROS) method in order to allow for data below the detection limit. Mean exposure levels were compared between different microenvironments such as homes, public transports, or outdoor., Results: Exposure levels were of the same order of magnitude in all countries and well below the international exposure limits. In all countries except for the Netherlands, the highest total exposure was measured in transport vehicles (trains, car, and busses), mainly due to radiation from mobile phone handsets (up to 97%). Exposure levels were in general lower in private houses or flats than in offices and outdoors. At home, contributions from various sources were quite different between countries., Conclusions: Highest total personal RF-EMF exposure was measured inside transport vehicles and was well below international exposure limits. This is mainly due to mobile phone handsets. Mobile telecommunication can be considered to be the main contribution to total RF-EMF exposure in all microenvironments., (Copyright 2010 Elsevier Inc. All rights reserved.)
- Published
- 2010
- Full Text
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13. Assessment of general public exposure to LTE and RF sources present in an urban environment.
- Author
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Joseph W, Verloock L, Goeminne F, Vermeeren G, and Martens L
- Subjects
- Electromagnetic Fields adverse effects, Environmental Exposure adverse effects, Environmental Exposure standards, Public Health statistics & numerical data, Radiation Protection standards, Sweden, Wireless Technology statistics & numerical data, Cities, Environmental Exposure statistics & numerical data, Radiation Monitoring, Radio Waves adverse effects, Urban Health statistics & numerical data, Wireless Technology instrumentation
- Abstract
For the first time, in situ electromagnetic field exposure of the general public to fields from long term evolution (LTE) cellular base stations is assessed. Exposure contributions due to different radiofrequency (RF) sources are compared with LTE exposure at 30 locations in Stockholm, Sweden. Total exposures (0.2-2.6 V/m) satisfy the International Commission on Non-Ionizing Radiation Protection (ICNIRP) reference levels (from 28 V/m for frequency modulation (FM), up to 61 V/m for LTE) at all locations. LTE exposure levels up to 0.8 V/m were measured, and the average contribution of the LTE signal to the total RF exposure equals 4%.
- Published
- 2010
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14. Procedure for assessment of general public exposure from WLAN in offices and in wireless sensor network testbed.
- Author
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Verloock L, Joseph W, Vermeeren G, and Martens L
- Subjects
- Belgium, Electromagnetic Fields, Environmental Exposure adverse effects, Geography, Guidelines as Topic, Humans, Risk Assessment methods, Time Factors, Environmental Exposure analysis, Local Area Networks, Public Health, Radiation Monitoring methods, Radio Waves adverse effects
- Abstract
A fast and accurate measurement procedure to determine experimentally wireless local area network (WLAN) radiofrequency (RF) exposure and to test compliance with international guidelines for the general public is proposed. This is the first paper where all optimal settings for the measurement equipment (sweep time, resolution bandwidth, etc.) are investigated, selected, and validated. The exposure to WLAN access points is determined for 222 locations with 7 WLAN networks present in office environments. The WLAN exposure is also characterized for the first time in a wireless sensor lab environment (WiLab) at IBBT-Ghent University in Belgium. Average background exposure to WLAN (WiLab off) is 0.12 V m(-1), with a 95 percentile of 0.90 V m(-1). With the WiLab in operation, average exposure increases to 1.9 V m(-1), with a 95 percentile of 4.7 V m(-1). All values are well below the International Commission on Non Ionizing Radiation Protection guidelines of 61 V m(-1) in the 2.4 GHz band (at least 9.1 times for distances of more than 1 m from the access points) but a significant increase of exposure is possible in WiLabs due to high duty cycles. By applying the proposed measurement method a relevant reduction in measurement time is obtained.
- Published
- 2010
- Full Text
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