State of the science regarding RF dosimetry, measurement and certification

Journal ArticleCellular telephones and wireless personal communication systems (PCS) are being introduced into society at a very rapid rate. Whereas the present-day cellular telephones in the United States operate at midband transmission frequencies of about 835 MHz (about 900 MHz in Europe), higher frequencies on the order of 1900 MHz (1800 MHz in Europe) are to be used for the PCS systems, including mobile telephones, wireless local area networks, pagers, personal health monitoring systems, global positioning systems, etc. This has resulted in public concern about the health hazards of radiofrequency (RF) electromagnetic fields that are emitted by these devices. To allay public concerns, the Federal Communications Commission (FCC) in the United States has decided to require compliance with the ANSI/IEEE RF safety guidelines (American National Standards Institute/Institute of Electrical and Electronics Engineers [ANSI/IEEE], 1992) for uncontrolled environments for all personal wireless devices that use more than 100 mW of time-averaged input power to the antenna

Fabrication and Experimental Evaluation of Simple Tissue-Mimicking Phantoms with Realistic Electrical Properties for Impedance-Based Sensing

Venipuncture is one of the most often performed invasive clinical procedure. Nevertheless, complications still occur. One opportunity to counteract these complications is to indicate the insertion by electrical impedance measurement, which bases on the various electrical properties of different tissues. This paper presents the evaluation and reproducible fabrication of simple tissue-mimicking phantoms for investigation of impedance sensing techniques. Three different tissue-mimicking phantoms, representing blood, fat, and skin, were made on water-based recipes, including agar and gelatin as gelling agents. For evaluation of the electrical properties an electrode probe, made of hypodermic needles, was fabricated and characterized using six sodium chloride (NaCl) solutions of defined concentrations. For characterization of the phantoms, conductances were measured over a frequency range from 20 Hz up to 1 MHz using the self-fabricated electrodes. The calculated conductivities of the tissue-mimicking phantoms showed sufficient agreement with corresponding electrical literature data of native tissue. Tests with a layered tissue structure proved usability for impedance-based venous entry tests. However, the method proposed was not suitable for investigation of relative permittivity, which would be required for full electrical characterization

Wideband phantoms of different body tissues for heterogeneous models in body area networks

[EN] One of the key issues about wireless technologies is their interaction with the human body. The so-called internet of things will comprise many devices that will transmit either around or through the human body. These devices must be tested either in their working medium, when possible, or in the most realistic one. For this purpose, tissue-like phantoms are the best alternative to carry out realistic analyses of the performance of body area networks. In addition, they are the conventional way to certify the compliance of commercial standards by these devices. However, the number of phantoms that work in large bandwidths is limited in literature. This work aims at presenting chemical solutions that will be useful to prepare a variety of wideband tissue phantoms. Besides, the colon was mimicked in two ways, the healthy tissue and the malignant one, taking into account studies that relate changes on the relative permittivity with cancer. They were designed on the basis of acetonitrile in aqueous solutions as described in a previous work. Thus, many scenarios could be developed such as multilayers which imitate parts of the heterogeneous body.Research supported by the Programa de Ayudas de Investigación y Desarrollo (PAID-01-16) from Universitat Politècnica de València, by the Ministerio de Economía y Competitividad, Spain (TEC2014-60258-C2-1- R) and by the European FEDER Funds.Castelló-Palacios, S.; Garcia-Pardo, C.; Fornés Leal, A.; Cardona Marcet, N.; Vallés Lluch, A. (2018). Wideband phantoms of different body tissues for heterogeneous models in body area networks. IEEE. 3032-3035. https://doi.org/10.1109/EMBC.2017.8037496S3032303

Design of high-efficiency antennas for mobile communications devices

This thesis deals with the design of high-efficiency antennas for small mobile communications devices. Owing to the continuously stricter requirements set for multisystem mobile terminals, the ongoing need for efficient antennas in personal mobile communications is evident. In this work, the entire system consisting of the antenna; the mobile terminal working actually as part of the antenna; and the user of the terminal is considered. The ratio between the power radiated into the free space and the antenna input power, i.e. the total efficiency of this system, forms a general concept for the studies. The total efficiency is partly affected by the losses in the antenna element. As the antenna efficiency, bandwidth, and volume are strongly interrelated exchangeable quantities, it is essential to find other approaches for enhancing the antenna efficiency than simply sacrificing other performance. Further, the metal chassis of a mobile terminal has to be part of the antenna element design because of its considerable effect on antenna performance. In addition, the total efficiency of the entire system is partly affected by the losses owing to the user. Thus, the evaluation of antenna performance is equally important when the mobile terminal is located near a user or when it is in free space. The main goal of this work is to provide novel and useful information for the design of mobile terminal antennas with special emphasis placed on the maximization of the total efficiency. To obtain necessary background understanding for the design of antennas with minimized user interaction, the general energy-absorption mechanism in the human tissue is studied in this thesis. It is shown that the peak SAR (specific absorption rate) is not actually related to the antenna current, as has been commonly believed. Instead, the SAR maximums can be explained by inspecting the antenna's quasi-static electric near field components perpendicular and parallel to the surface of the tissue at the air-tissue interface and utilizing the boundary conditions of quasi-static fields at the interface. As SAR is directly proportional to the total electric field in the tissue, the SAR distributions caused by a certain antenna differ considerably in tissues with different permittivity values, e.g. brain and fat. The bandwidth, efficiency in talk position, and SAR performance of a typical monoblock handset antenna-chassis combination is comprehensively investigated in this work for clarifying the roles of different parts of the radiating system. The system is treated as a combination of the separate wavemodes of the antenna element and the chassis. Based on the results, guidelines are given to control or analyze the combined performance both in the sense of radiation properties (bandwidth, efficiency) and user interaction (SAR). It is also demonstrated that there is a connection between the studied three performance parameters: a local maximum in SAR values and a local minimum in radiation efficiency occur when the bandwidth reaches its maximum and the resonant frequency of the chassis equals that of the antenna. The suitability of dielectric resonator antennas (DRA) for mobile terminals is studied theoretically and experimentally with the main attention paid to the loss characteristics. It is observed that DRAs are appropriate for this purpose especially when very small antenna elements are needed. As an application example, a novel means to realize a high-performance dual-resonant antenna design for mobile terminals is presented. In addition, losses in the frequency-tuning circuits of small resonant antennas are systematically investigated. Design guidelines for tuning circuits with minimized losses with respect to the achievable tuning range are given. Based on the proposed theory, a low-loss tuning circuit with suitable characteristics for mobile terminal antennas is introduced.reviewe

Wireless Signals and Male Fertility

Rapid advances in wireless technology have increased the number of users of mobile devices. As of 2011, the number of cell phone subscribers have reached 5.3 billion worldwide. Mobile devices have saturated our environment with radio frequency (RF) signals. This situation has created public concern over the effect of such signals on human health. This dissertation focuses on the correlation of RF signals emitted by cell phones with male infertility. A thorough discussion is provided on the effects of RF signals on the development of central nervous system (CNS) neoplasm, the design of these mobile devices, the range of the RF frequencies they emit, the power with which they operate, their specific absorption rate (SAR), the distance between the user and the device while in use, how and where the devices are used, the duration of usage, and the accumulated exposure associated with the use of multiple RF devices. The results of our reviews and experimental in vitro studies show a significant correlation between the usage of mobile phones and human semen parameters, with a decrease in motility and viability, and an increase in the reactive oxygen species (ROS) score. However, in daily usage, a cell phone kept in proximity to the groin is separated from the testes by multiple layers of tissue. To explore this effect, a computational model of scrotal tissues was designed. Our results show that during in vitro experimentation, an effect equivalent to real-life conditions can be obtained by placing the cell phone a few centimeters farther away from the semen sample. The results of our study can be used to calculate the equivalent distance between a radiation source and a semen sample, and to set up in vitro experiments that mimic real-life condition