64bit technology for the Transient solver (machines with up to 8 Gbyte and problemsizes of less than 30e6 mesh cells are covered by commercial licenses free of charge) NOTE: due to Windows driver issues, 64bit is currently only available for floating licenses. An understanding of the key features of the New Zealand radio Frequency exposure standards (in accordance with NZS2772:Part 1: 1999 New Zealand Standard Radio-frequency Fields Part 1 - Maximum Exposure Levels - 3kHz to 300 GHz).Here the changes in 5.1 between 5.1 to 5.1.1 only little bug fix.ġ. An understanding of how the radio spectrum is utilized/allocated, especially from a New Zealand perspective.
An understanding of the key characteristics that underpin the behaviour of coaxial cables, rectangular waveguides, and radio/microwave hardware. SYSTEMS AND STANDARDS: An ability to design single stub tuners, double stub tuners, alternated line transformers, and quarter-wave matching sections. An understanding of the behaviour of non-linear systems in regard to large signal behaviour, frequency doubler/triplers, mixers, superheterodyne receivers, intermodulation distortion, and dynamic range. An ability to describe the key characteristics and behaviour of a range of antennas including infinitesimal, short and half-wave dipoles, arrays, aperture antennas, horn antennas and parabolic dish antennas. An ability to perform calculations involving thermal noise, minimum discernible signal, and noise figure.ĮNGA07: environment and sustainability (1)ĬOMPUTATIONAL ELECTROMAGNETICS, ANTENNAS AND RECEIVER DESIGN: An understanding of the fundamental principles of time domain analysis for computational electromagnetics, with an ability to perform calculations with the Finite-Difference Time-Domain (FDTD) method. An ability to calculate link budgets and undertake design of point-to-point and area coverage systems. An understanding of the causes of and methods for characterising fading in mobile radio systems. PROPAGATION: An ability to perform calculations involving radio links in free space, over a plane-earth, through the troposphere, in the presence of terrain obstacles, diffraction over a knife-edge, multiple diffraction geometries, and for clearance paths involving Fresnel zones. Outcome mapping Intended learning outcomes In this course, students will undertake a Self-Study Module, assessed via a dedicated question in final examination. In any event all laboratories must be completed by 5pm on Friday 9 June 2017. Further details can be found in the instruction sheet for Experiment E721/737元. The third experiment (E721/737元) is to be undertaken by each student individually and without assistance or supervision, and concerns the design of a double-stub matching network. The commercial electromagnetic modelling package CST Microwave Studio will be used to analyse the single-stub configuration and its performance investigated. The second laboratory experiment (E721/737L2) also considers a single-stub matching network, but from an analytical perspective. In this lab students will be presented with an unknown load and will design and build a single-stub matching network and test its performance. The first laboratory experiment (E721/737L1) concerns the design of a single-stub matching network. Students will be expected to undertake three laboratories as part of the ELECTENG721 and ELECTENG737 courses. ELECTENG721 is intended for undergraduate students enrolled in the BE(Hons) Part IV, whereas ELECTENG737 is intended for postgraduate students enrolled in the PGCertEng/MEngSt/ME. They follow on from the Part III course ELECTENG307 Transmission Lines and Systems, and are prerequisites for the follow-on Part IV course ELECTENG701 Wireless Communication. The courses ELECTENG721 and ELECTENG737 deal with aspects of the design of radio systems.