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Endo, \u201cEnvironmental electromagnetic engineering (EMC),\u201d Journal of the Institute of Television Engineers of Japan (The Journal of The Institute of Image Information and Television Engineers), vol.32, no.3, pp.11-18, 1979 (in Japanese).","DOI":"10.3169\/itej1978.32.197"},{"key":"3","unstructured":"[3] R. Sato and E. Hiroshi, \u201cStatus quo and prospect of environmental electromagnetic engineering,\u201d Journal of the Institute of Electrical Engineers of Japan, vol.99-1, pp.11-18, 1979 (in Japanese)."},{"key":"4","unstructured":"[4] T. Takagi, \u201cA review of electromagnetic compatibility by an instrumentation and control engineering,\u201d Journal of the Society of Instrument and Control Engineers, vol.18, no.12, pp.1012-1018, 1979 (in Japanese)."},{"key":"5","unstructured":"[5] H. Echigo and T. Takagi, \u201cElectromagnetic compatibility and high reliability,\u201d Journal of the Society of Instrument and Control Engineers, vol.24, no.4, pp.296-300, 1985 (in Japanese)."},{"key":"6","unstructured":"[6] IEEE Standard 100-1992, \u201cThe new IEEE standard dictionary of electrical and electronics terms,\u201d Fifth Edition Newly Revised and Expanded, p.424."},{"key":"7","unstructured":"[7] IEC (International Electrotechnical Commission) website, http:\/\/www.iec.ch\/emc\/ (accessed Sept. 25 2016)."},{"key":"8","unstructured":"[8] J. O&apos;Neil, Editor-in-Chief, IEEE EMC Society newsletter, Issue no.215, Fall 2007."},{"key":"9","unstructured":"[9] R. Sato, Commemorative speech for 30th anniversary of EMCJ on \u201cBeginning of EMC research in Japan,\u201d IEICE Technical Report, EMCJ2007, Oct. 2007 (in Japanese)."},{"key":"10","unstructured":"[10] T. 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Hoolihan, \u201cAn overview of the first 25 IEEE International symposiums on EMC,\u201d http:\/\/www.emcs.org\/acstrial\/newsletters\/summer05\/overview.html (accessed Sept. 25 2016)."},{"key":"17","doi-asserted-by":"crossref","unstructured":"[17] R.B. Schulz, \u201cEMC symposium,\u201d IEEE Trans. Electromagn. Compat., vol.EMC-24, no.3, p.293 Aug. 1982. 10.1109\/temc.1982.304039","DOI":"10.1109\/TEMC.1982.304039"},{"key":"18","unstructured":"[18] R. Koga, \u201cDevelopment and prospects of EMC engineering in Japan,\u201d IEICE Trans. Commun. (Japanese Edition), vol.J90-B, no.11, pp.1083-1088, Nov. 2007."},{"key":"19","unstructured":"[19] O. Fujiwara, \u201cElectromagnetic fields due to electrostatic discharges and their FDTD simulation,\u201d IEICE Trans. Commun. 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Watanabe, \u201cUncertainty of GHz-band whole-body average SARs in infants based on Kaup indicies,\u201d IEICE Technical Report, EMCJ2009-32, June 2009 (in Japanese)."},{"key":"24","unstructured":"[24] H. Miwa, Y. Kazama, A. Hirata, O. Fujiwara, T. Nagaoka, and S. Watanabe, \u201cEstimation of 1-6GHz whole-body averaged SARs in infants using their dielectric properties,\u201d IEICE Technical Report, EMCJ2009-86, Dec. 2009 (in Japanese)."},{"key":"25","unstructured":"[25] J. Wang, O. Fujiwara, K. Wake, and S. Watanabe, \u201cDosimetry analysis of pregnant and new-born rats in a 2-GHz unrestrained whole-body exposure setup,\u201d IEICE Technical Report, EMCJ2006-38, July 2006 (in Japanese)."},{"key":"26","unstructured":"[26] T. Nagaoka, T. Togashi, K. Saito, M. Takahashi, K. Ito, and S. Watanabe, \u201cNumerical dosimetry of a pregnant woman model for plane wave exposures,\u201d IEICE Technical Report, EMCJ2006-101, Jan. 2007 (in Japanese)."},{"key":"27","unstructured":"[27] H. Kawai, T. Nagaoka, S. Watanabe, K. Saito, M. Takahashi, and K. Ito, \u201cSAR dosimetry inside a 4-, 8-, and 12-week pregnant woman model exposed to the plane wave,\u201d IEICE Technical Report, EMCJ2007-82, Nov. 2007 (in Japanese)."},{"key":"28","unstructured":"[28] R. Asayama, J. Wang, and O. Fujiwara, \u201cCalculation of whole-body average SARs in pregnant woman and infant for multiple RF exposure in real environment,\u201d IEICE Technical Report, EMCJ2012-2, April 2012 (in Japanese)."},{"key":"29","unstructured":"[29] T. Nagaoka, T. Niwa, S. Dahdou, J. Wiart, and S. Watanabe, \u201cDevelopment of high-fidelity fetal models based on MRI during the second and third trimesters,\u201d IEICE Technical Report, EMCJ2012-52, Sept. 2012 (in Japanese)."},{"key":"30","unstructured":"[30] T. Asano, A. Hirata, and O. Fujiwara, \u201cFDTD calculation of temperature elevation in the human body due to far-field exposure,\u201d IEICE Technical Report, EMCJ2006-9, June 2006 (in Japanese)."},{"key":"31","unstructured":"[31] T. Asano, A. Hirata, and O. Fujiwara, \u201cUncertainty analysis of temperature-rise in human body for far field exposure,\u201d IEICE Technical Report, EMCJ2006-82, Dec. 2006 (in Japanese)."},{"key":"32","unstructured":"[32] T. Asano, A. Hirata, and O. Fujiwara, \u201cBody-core temperature elevation in human adult and child,\u201d IEICE Technical Report, EMCJ2007-107, Jan. 2008 (in Japanese)."},{"key":"33","unstructured":"[33] K. Wake, S. Watanabe, Y. Yamanaka, and M. Taki, \u201cSAR analysis for a large-scale and long-term animal experiment of exposure to 2-GHz W-CDMA signals,\u201d IEICE Technical Report, EMCJ2006-17, June 2006-06 (in Japanese)."},{"key":"34","unstructured":"[34] Y. Kanai, A. Hirata, O. Fujiwara, H. Masuda, H. Kawai, T. Arima, and S. Watanabe, \u201cAnalysis of temperature rise in rats for 1.5-GHz microwave exposure,\u201d IEICE Technical Report, EMCJ2009-193, June 2009 (in Japanese)."},{"key":"35","unstructured":"[35] J. Wang, K. Wake, T. Arima, S. Watanabe, and O. Fujiwara, \u201cDosimetry analysis for pregnant and new-born rats based on their activity pattern in a 2-GHz whole-body exposure setup,\u201d IEICE Technical Report, EMCJ2010-73, Nov. 2010 (in Japanese)."},{"key":"36","unstructured":"[36] J. Wang, W. Liao, H. Kawai, K. Wake, S. Watanabe, and O. Fujiwara, \u201cDesign and validation of a multi-frequency whole-body exposure system for bio-effect test with rats,\u201d IEICE Technical Report, EMCJ2012-11, May 2012 (in Japanese)."},{"key":"37","unstructured":"[37] A. Hirata, S. Watanabe, M. Taki, O. Fujiwara, M. Kojima, and K. Sasaki, \u201cTemperature elevations in rabbit eye irradiated by 2.45-GHz exposure systems,\u201d IEICE Technical Report, EMCJ2006-50, Sept. 2006 (in Japanese)."},{"key":"38","unstructured":"[38] A. Hirata, S. Watanabe, M. Taki, O. Fujiwara, M. Kojima, and K. Sasaki, \u201cFDTD simulation of temperature elevations in rabbit eye due to microwave energy,\u201d IEICE Technical Report, EMCJ2007-4, April 2007 (in Japanese)."},{"key":"39","unstructured":"[39] H. Sugiyama, A. Hirata, O. Fujiwara, H. Kawai, M. Kojima, Y. Yamashiro, S. Watanabe, and K. Sasaki, \u201cStudy of body-core temperature rise in a rabbit for 2.45GHz microwave exposure,\u201d IEICE Technical Report, EMCJ2007-31, June 2007 (in Japanese)."},{"key":"40","unstructured":"[40] Y. Nagaya, A. Hirata, O. Fujiwara, T. Nagaoka, and S. Watanabe, \u201cCorrelation between absorption cross section and body surface area of human for far-field exposure in GHz bands,\u201d IEICE Technical Report, EMCJ2006-81, Dec. 2006 (in Japanese)."},{"key":"41","unstructured":"[41] T. Suzuki, A. Hirata, O. Fujiwara, T. Nagaoka, and S. Watanabe, \u201cEstimation of whole-body average SARs in human for vertical polarized far-field exposure at frequencies over 1GHz using spatially averaged squares of induced currents,\u201d IEICE Technical Report, EMCJ2010-24, July 2010 (in Japanese)."},{"key":"42","unstructured":"[42] N. Kobayashi, Y. Kawamura, T. Hikage, T. Nojima, T. Nagaoka, and S. Watanabe, \u201cEstimation of direction-of-arrival dependence of whole-body averaged SAR in Japanese human models exposed to plane-wave,\u201d IEICE Technical Report, EMCJ2010-43, Sept. 2010 (in Japanese)."},{"key":"43","unstructured":"[43] J. Chakarothai, J. Wang, O. Fujiwara, K. Wake, and S. Watanabe, \u201cExperimental validation of MoM-derived electric field distribution in reverberation chamber for bio-effect testing,\u201d IEICE Technical Report, EMCJ2012-10, May 2012 (in Japanese)."},{"key":"44","unstructured":"[44] J. Chakarothai, J. Wang, O. Fujiwara, K. Wake, and S. Watanabe, \u201cNumerical dosimetry of small animal in reverberation chamber,\u201d IEICE Technical Report, EMCJ2012-86, Dec. 2012 (in Japanese)."},{"key":"45","unstructured":"[45] J. Chakarothai, J. Wang, O. Fujiwara, K. Wake, and S. Watanabe, \u201cA dosimetry design of reverberation chamber for whole-body exposure of small animals,\u201d IEICE Technical Report, EMCJ2013-15, pp.31-36, 2013-05 (in Japanese)."},{"key":"46","doi-asserted-by":"crossref","unstructured":"[46] K. Harima, \u201cEstimation of absorbed power in human body using a reverberation chamber,\u201d IEICE Technical Report, EMCJ2011-106, Dec. 2011 (in Japanese).","DOI":"10.1109\/ISEMC.2012.6351753"},{"key":"47","unstructured":"[47] T. Suzuki, J. Wang, and O. Fujiwara, \u201cCalculation of GHz-band whole-body average SARs in children models for electromagnetic field exposure inside reverberation chamber,\u201d IEICE Technical Report, EMCJ2011-109, Nov. 2011 (in Japanese)."},{"key":"48","unstructured":"[48] T. Suzuki, J. Wang, and O. Fujiwara, \u201cMeasurement and validation of GHz-band whole-body Average SAR in human volunteer using reverberation chamber,\u201d IEE Japan, Paper of Technical meeting on Electromagnetic Compatibility, Reference no.EMC-11-22, pp.17-22, 2011-10 (in Japanese)."},{"key":"49","unstructured":"[49] J. Wang, T. Suzuki, O. Fujiwara and K. Harima, \u201cMeasurement and validation of GHz-band whole-body average SAR in a human volunteer using reverberation chamber,\u201d Physics in Medicine and Biology, vol.57, no.23, pp.7893-7903, 2012."},{"key":"50","unstructured":"[50] H. Tarao, K. Kirita, N. Hayashi, and K. Isaka, \u201cRelation between ELF magnetic fields and induced currents inside tissues of human Body,\u201d IEICE Technical Report, EMCJ2007-90, Nov. 2007-11 (in Japanese)."},{"key":"51","unstructured":"[51] M. Ikehata, S. Yoshie, Y. Suzuki, M. Taki, and T. Hayakawa, \u201cEffects of combined magnetic fields with static and 50Hz on mutagenesis,\u201d IEICE Technical Report, EMCJ2007-91, Nov. 2007 (in Japanese)."},{"key":"52","unstructured":"[52] Y. Takano, A. Hirata, and O. Fujiwara, \u201cInduced current density\/electric field in human body for ELF electric and magnetic field exposures at reference level\/MPE,\u201d IEICE Technical Report, EMCJ2009-85, Dec. 2009 (in Japanese)."},{"key":"53","doi-asserted-by":"crossref","unstructured":"[53] Y. Yoshino, S. Igo, M. Katsuragi, and M. Taki, \u201cAssessment of human exposure to electromagnetic field from an intra-body communication device using intermediate-frequency electric field,\u201d IEICE Technical Report, EMCJ2012-9, May 2012 (in Japanese).","DOI":"10.1109\/EMCEurope.2012.6396783"},{"key":"54","unstructured":"[54] Y. Kamimura, D. Yamaura, A. Yamashita, and K. Sato, \u201cMeasurement of exposure level around an IH cooker (second report),\u201d IEICE Technical Report, EMCJ2015-2, April 2015 (in Japanese)."},{"key":"55","unstructured":"[55] H. Tarao, N. Hayashi, and K. Isaka, \u201cCalculation of induced currents in adult and child human models by intermeadiate frequency magnetic fields from an induction heater,\u201d IEICE Technical Report, EMCJ2006-15, June 2006-06 (in Japanese)."},{"key":"56","unstructured":"[56] Y. Kamimura, M. Kouno, Y. Yamada, S. Nishizawa, and F. Landstorfer, \u201cStudy on equivalent magnetic source of ac drive electric shaver,\u201d IEICE Technical Report, EMCJ2006-16, June 2006 (in Japanese)."},{"key":"57","doi-asserted-by":"crossref","unstructured":"[57] International Commission on Non-Ionizing Radiation Protection (ICNIRP), \u201cGuidelines for limiting exposure to time-varying electric, magnetic and electromagnetic fields (1Hz to 100kHz),\u201d Health Physics, vol.99, no.6, pp.818-836, Dec. 2010.","DOI":"10.1097\/HP.0b013e3181f06c86"},{"key":"58","unstructured":"[58] R. Munakata and Y. Kamimura, \u201cA study on equivalent circuit for contact current measurement,\u201d IEICE Technical Report, EMCJ2015-6, April 2015 (in Japanese)."},{"key":"59","doi-asserted-by":"crossref","unstructured":"[59] S. Ishihara, T. Onishi, and A. Hirata, \u201cMagnetic field measurement near wireless power transfer systems for information household appliances,\u201d IEICE Technical Report, EMCJ2014-19, July 2014-07 (in Japanese).","DOI":"10.1109\/URSIGASS.2014.6930140"},{"key":"60","unstructured":"[60] T. Iwamoto, J. Chakarothai, K. Wake, K. Fujii, T. Arima, and S. Watanabe, and T. Uno, \u201cComparison of human exposure from two different wireless power transfer systems at MHz-band,\u201d IEICE Technical Report, EMCJ2014-88, Jan. 2015 (in Japanese)."},{"key":"61","unstructured":"[61] Y. Keita and M. Taki \u201cA consideration on numerical analysis of human exposure by the intermediate frequency band wireless power transfer system,\u201d IEICE Technical Report, EMCJ2016-68, Jan. 2016 (in Japanese)."},{"key":"62","unstructured":"[62] S. Shimoyama, J. Chakarothai, K. Wake, L. Hamada, T. Arima, T. Uno, and S. Watanabe, \u201cAn investigation on SAR measurement method for MHz-band wireless power transfer systems,\u201d IEICE Technical Report, EMCJ2016-46, July 2016 (in Japanese)."},{"key":"63","unstructured":"[63] K. Matsubara, H. Yoshino, K. Wada, and Y. Suzuki, \u201cDesign of magnetic field generator to evaluate biological effects for electrical vehicle WPT system,\u201d IEICE Technical Report, EMCJ2016-53, Sept. 2016-09 (in Japanese)."},{"key":"64","doi-asserted-by":"crossref","unstructured":"[64] M. Takashima, T. Tobana, T. Sasamori, and K. Abe, \u201cAnalysis of emission from printed circuit board with linear conductor,\u201d IEICE Technical Report, EMCJ2006-18, July 2006 (in Japanese).","DOI":"10.1109\/ISEMC.2007.115"},{"key":"65","unstructured":"[65] F. Ga, T. Watanabe, and Y. Iizuka, \u201cSimulation of electromagnetic emissions from LSIs on printed circuit boards,\u201d IEICE Technical Report, EMCJ2006-40, July 2006-07 (in Japanese)."},{"key":"66","unstructured":"[66] T. Tsuda, T. Uno, and K. Ichikawa, \u201cEMI model improvement taking LSI package structure into consideration,\u201d IEICE Technical Report, EMCJ2006-84, Dec. 2006-12 (in Japanese)."},{"key":"67","unstructured":"[67] A. Sadatoshi, Y. Sakai, T. Watanabe, Y. Toyota, K. Iokibe, R. Koga, and O. Wada, \u201cEstimation of electromagnetic-emission from PCBs with a connector through the common-mode antenna Model,\u201d IEICE Technical Report, EMCJ2007-9, pp.19-54, April 2007 (in Japanese)."},{"key":"68","unstructured":"[68] K. Fukumasu, T. Watanabe, Y. Toyota, K. Iokibe, R. Koga, and O. Wada, \u201cEstimation of radiated emissions with common-mode antenna model of printed circuit board-superposition of common-mode excitation sources-,\u201d IEICE Technical Report, EMCJ2007-25, June 2007 (in Japanese)."},{"key":"69","unstructured":"[69] R. Kobayashi, N. Nakamura, and K. Tajima, \u201cSimultaneous measurement method for conducted common-mode voltage and current,\u201d IEICE Technical Report, EMCJ2008-5, April 2008 (in Japanese)."},{"key":"70","unstructured":"[70] Y. Kayano, and H. Inoue, \u201cAn equivalent circuit model for predicting CM radiation from a surface-microstrip line structure,\u201d IEICE Technical Report, EMCJ2007-58, Oct. 2007 (in Japanese)."},{"key":"71","doi-asserted-by":"crossref","unstructured":"[71] K. Matsumoto, Y. Toyota, K. Iokibe, and R. Koga, \u201cDevelopment of an equivalent circuit model with transmission line model for designing filter formed on printed circuit boards,\u201d IEICE Technical Report, EMCJ2009-112, Jan. 2010 (in Japanese).","DOI":"10.1109\/ISEMC.2010.5711287"},{"key":"72","unstructured":"[72] A. Osaki, K. Iokibe, Y.T., R. Koga, and O. Wada, \u201dDetermination of impedances in LECCS-I\/O model by 3-port VNA measurement for higher frequency range,\u201d IEICE Technical Report, EMCJ2006-21, July 2006 (in Japanese)."},{"key":"73","doi-asserted-by":"crossref","unstructured":"[73] A. Koyama, T. Hisakado, and O. Wada, \u201cLinear time-invariant analysis of CMOS output buffer with LECCS model using time-variant resistors,\u201d IEICE Technical Report, EMCJ2007-8, April 2007-04 (in Japanese).","DOI":"10.1109\/ISEMC.2007.137"},{"key":"74","unstructured":"[74] R. Higashi, K. Iokibe, T. Tsuda, K. Ichikawa, K. Nakamura, Y. Toyota, and R. Koga, \u201cEvaluation of multiple power-supply pin LECCS-core model with different pattern design boards,\u201d IEICE Technical Report, EMCJ2008-33, July 2008 (in Japanese)."},{"key":"75","unstructured":"[75] M. Yasuhara, Y. Funato, Y. Saito, U. Paoletti, T. Hisakado, and O. 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Tanaka, \u201cEffect of adding bypass capacitors between partially formed power and ground layers and resulting PCB noise reduction,\u201d IEICE Technical Report, EMCJ2014-26, July 2014 (in Japanese)."},{"key":"80","doi-asserted-by":"crossref","unstructured":"[80] F. Nakamoto, Y. Sasaki, Y. Watanabe, C. Miyazaki, and N. Oka, \u201cPractical model of an on-board type common mode choke coil for 3D EMC simulation,\u201d IEICE Technical Report, EMCJ2012-109, Jan. 2013 (in Japanese).","DOI":"10.1109\/ISEMC.2012.6351690"},{"key":"81","unstructured":"[81] K. Mizui, O. Wada, U. Paoletti, and T. Hisakado, \u201cBalance control of power-supply interconnection in printed circuit boards and ICs for reduction of common-mode current flowing on attached cables,\u201d IEICE Technical Report, EMCJ2007-45, Sept. 2007 (in Japanese)."},{"key":"82","unstructured":"[82] N. Ando, H. Toyao, T. Tsukagoshi, and T. 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Yoneda, T. Kumamoto, C. Miyazaki, and N. Oka, \u201cA study on shield structure of a connector substrate with single point ground plane connection,\u201d IEICE Technical Report, EMCJ2009-28, June 2009 (in Japanese)."},{"key":"87","unstructured":"[87] Y. Shiraki, Y. Yamanaka, and N. Abe, \u201cMoments analysis of EM noise caused by power\/ground noise of electric unit,\u201d IEICE Technical Report, EMCJ2006-53, Oct. 2006 (in Japanese)."},{"key":"88","unstructured":"[88] M. Torigoe, Y. Tsuchie, Y. Yahagi, T. Suga, H. Osaka, and T. Inagaki, \u201cEstimation of conducted emission from automotive components by using noise equivalent circuit,\u201d IEICE Technical Report, EMCJ2013-92, Nov. 2013 (in Japanese)."},{"key":"89","doi-asserted-by":"crossref","unstructured":"[89] T. Maeno, T. Uno, K. Ichikawa, and O. 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Fujiwara, \u201cSize dependence of return ground patterns on FM-band cross-talks between two parallel signal traces on printed circuit boards for vehicles,\u201d IEICE Technical Report, EMCJ2010-38, July 2010 (in Japanese)."},{"key":"93","doi-asserted-by":"crossref","unstructured":"[93] M. Iida, T. Maeno, J. Wang, and O. Fujiwara, \u201cDependence on ground patterns size of FM-band cross-talks between two parallel signal traces on printed circuit boards for vehicles,\u201d IEICE Technical Report, EMCJ2010-126, March 2011 (in Japanese).","DOI":"10.1109\/APEMC.2012.6237820"},{"key":"94","doi-asserted-by":"crossref","unstructured":"[94] M. Taki, \u201cEMC&apos;14\/Tokyo report,\u201d IEEE Trans. Electromagn. Compat., vol.3, no.3, pp.95-99 2014. 10.1109\/memc.2014.6924335","DOI":"10.1109\/MEMC.2014.6924335"},{"key":"95","doi-asserted-by":"publisher","unstructured":"[95] O. Fujiwara, \u201cA technical trend seen in the latest international EMC symposia,\u201d IEEJ Trans. 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