References
- Komarov IV, Smolskiy SM. Fundamentals of short-range FM radar. New York (NY): Artech House; 2003.
- Russell ME, Crain A, Curran A, et al. Millimeter-wave radar sensor for automotive intelligent cruise control (ICC). IEEE Trans Microw Theory Tech. 1997;45(12):2444–2453.
- Skolnik MI. Radar handbook. New York (NY): McGraw-Hill; 2008.
- Skolnik MI. Introduction to radar systems. New York (NY): McGraw-Hill; 2003.
- Ozturk H, Yegin K. Predistorter based K-band FMCW radar for vehicle speed detection. Proceedings of the 17th IEEE International Radar Symposium Conference; 2016. p. 1–4.
- Gale RAN, Hong L. Automated traffic surveillance using fusion of Doppler radar and video information. Math Comp Model. 2011;54(1):53–43.
- Siversima. FMCW radar sensors. App. Notes. 2011.
- Giubbolini L. A multistatic microwave radar sensor for short range anticollision warning. IEEE Trans Veh Technol. 2000;49(6):2270–2275.
- Steinhauer M, Ruo H, Irion H, et al. Millimeter-wave-radar sensor based on a transceiver array for automotive applications. IEEE Trans Microw Theory Tech. 2008;56(2):261–269.
- Fujimori S, Uebo T, Iritani T. Short-range high-resolution radar utilizing standing wave for measuring of distance and velocity of a moving target. Electr Com Japan. 2006;89(5):52–60.
- Lin JJ, Li YP, Hsu WC, et al. Design of an FMCW radar baseband signal processing system for automotive application. SpringerPlus. 2016;5(1):42.
- Villeval S, Bilik I, Gurbuz S. Application of a 24 GHz FMCW automotive radar for urban target classification. Proceedings of IEEE Radar Conference; 2014. p. 1237–1240.
- Lee TY, Jeon SY, Han J, et al. A Simplified technique for distance and velocity measurements of multiple moving objects using a linear frequency modulated signal. IEEE Sens J. 2006;16(15):5912–5920.
- Ash M, Ritchie M, Chetty K. On the application of digital moving target indication techniques to short-range FMCW radar data. IEEE Sens J. 2018;18(10):4167–4175.
- Choudhary PK, EI-Nasr AM. Insight into remote monitoring systems. J Electromagn Waves Appl. 2019;33(7):795–798.
- Ibanez JG, Zeadally S, Castillo CJ. Sensor technologies for intelligent transportation systems. Sensors. 2018;18(4):1212.
- Ganapathi P, Shanmugapriya D, Kalaivani M. A study on vehicle detection and tracking using wireless sensor networks. Wirel Sens Netw. 2010;2(02):173–185.
- Mimbela LEY, Klein LA. Summary of vehicle detection and surveillance technologies used in intelligent transportation systems. 2007. https://www.fhwa.dot.gov/policyinformation/pubs/ vdstits2007/vdstits2007.pdf.
- Yulianto B. Detector technology for demand responsive traffic signal control under mixed traffic conditions. Proceedings of the AIP Conference; 2008. p. 040021.
- Santi F, Pieralice F, Pastina D. Joint detection and localization of vessels at sea with a GNSS-based multistatic radar. IEEE Trans Geosci Remote Sens. 2019;57(8):5894–5913.
- Thiel S, Ferber S, Fischer T, et al. A case study in applying a product line approach for car periphery supervision systems. SAE Trans. 2001;110:50–62.
- Chaulya SK, Prasad GM. Sensing and monitoring technologies for mines and hazardous areas. New York: Elsevier; 2006.
- Kassim AM, Jaya AKRA, Azahar AH, et al. Performance analysis of acceleration sensor for movement detection in vehicle security system. Int J Adv Comput Sci Appl. 2019;10(10):395–401.
- Fan Y, Xiang K, An J, et al. A new method of multi-target detection for FMCW automotive radar. Proceedings of the IET International Conference; 2013. p. 1–4.
- Kazuhiro YM, Saito M, Miyasaka K, et al. Design and performance of a 24 GHz Band FM-CW radar system and its application. Proceedings of the IEEE Asia Pacific Conference on Wireless and Mobile; 2014. p. 28–30.
- Yamaguchi K, Mitumasa S, Takuya A, et al. A 24 GHz FM-CW radar system for detecting closed multiple targets and its applications in actual scenes. Open J Internet Things. 2016;2(1):1–15.
- Ayhan S, Pauli M, Kayser T, et al. FMCW radar system with additional phase evaluation for high accuracy range detection. Proceedings of the 8th European Radar Conference; 2011. p. 117–120.
- Peng Z, Ran L, Li C. A K-band portable FMCW radar with beam forming array for short-range localization and vital-Doppler targets discrimination. IEEE Trans Microw Theory Tech. 2017;65(9):3443–3452.
- KurniawanD WC, Miftahushudur T, et al. Implementation of automatic I/Q imbalance correction for FMCW radar system. Proceedings of the 2nd IEEE International Conference on Information Systems and Electrical Engineering; 2017. p. 100–105.
- Kaminski P, Slomin I, Wincza K, et al. Fully integrated, multipurpose low-cost K-band FMCW radar module with sub-millimeter measurement precision. Int J Info Electr Eng. 2015;5(2):74.
- Hyun E, Kim S, Ju Y, et al. FPGA based signal processing module design and implementation for FMCW vehicle radar systems. Proceedings of the IEEE CIE International Radar Conference; 2011. p. 273–275.
- Peng Z, Li C. A portable 24-GHz FMCW radar based on six-port for short range human tracking. Proceedings of the IEEE International Microwave Workshop Series on RF and Wireless Technologies for Biomedical and Healthcare Applications (IMWS-BIO); 2015. p. 81–82.
- Sediono W, Lestari A. Software design to simulate FMCW radar signal: a case study of INDERA. Proceedings of the International Centre for Telecommunications and Radar Indonesian Branch (IMMAC); 2010.
- Sediono W. Method of measuring Doppler shift of moving targets using FMCW maritime radar. Proceedings of the IEEE International Conference on Teaching, Assessment and Learning in Engineering (TALE); 2013. p. 78–381.
- Ayhan S, Scherr S, Pahl P, et al. Radar-based high-accuracy angle measurement sensor operating in the K-band. IEEE Sens J. 2015;15(2):937–945.
- Hyun E, Jin Y, Lee J. Design and implementation of 24 GHz multichannel FMCW surveillance radar with a software-reconfigurable baseband. J Sens 2017;2017:1–11.