![]() The functions were developed with R11.1, but they work with R13. Usage examples are found throughout the above text. RF Toolbox lets you build networks of RF components such as filters, transmission lines, matching networks. The toolbox supports wireless communications, radar, and signal integrity projects. The toolbox includes functions for the design and analysis of multilayer film structures, antireflection coatings, polarizers, omnidirectional mirrors, narrow-band transmission filters, birefringent multilayer films and giant birefringent optics impedance matching methods, quarter-wavelength multisection Chebyshev transformers, stub matching, and L, Pi and T-section reactive matching networks analysis of transmission lines and waveguides S-parameters, Smith charts, stability and gain circles, noise figure circles, and microwave amplifier design computation of directivities and patterns of linear and aperture antennas horn design computation of diffraction integrals and knife-edge diffraction coefficients antenna array design methods for sector and narrow beams numerical methods for the Hallen and Pocklington integral equations computation of self and mutual antenna impedances coupled antennas various types of azimuthal and polar gain plots and several movies showing the propagation of pulses on terminated transmission lines and on cascaded lines, reflections from reactive terminations, fault location by TDR, crosstalk signals on coupled lines, and time-evolution of the field radiated by a Hertzian dipole antenna. RF Toolbox provides functions, objects, and apps for designing, modeling, analyzing, and visualizing networks of radio frequency (RF) components. The book may be downloaded from the web page We may also share this information with third parties for this purpose.A toolbox of functions to accompany the author's online book on "Electromagnetic Waves & Antennas". We will use this information to make the website and the advertising displayed on it more relevant to your interests. If the reference impedance is a vector and the number of ports N equals the number of data frequencies K, N K, then the sparameters object will assign each element of the vector to each port of the network. Targeting/Profiling Cookies: These cookies record your visit to our website and/or your use of the services, the pages you have visited and the links you have followed. Loss of the information in these cookies may make our services less functional, but would not prevent the website from working. This enables us to personalize our content for you, greet you by name and remember your preferences (for example, your choice of language or region). ![]() Functionality Cookies: These cookies are used to recognize you when you return to our website. This helps us to improve the way the website works, for example, by ensuring that users are easily finding what they are looking for. Analytics/Performance Cookies: These cookies allow us to carry out web analytics or other forms of audience measuring such as recognizing and counting the number of visitors and seeing how visitors move around our website. They either serve the sole purpose of carrying out network transmissions or are strictly necessary to provide an online service explicitly requested by you. Automated workflows enable scale-up testing, validating scenarios, extracting statistical information on device performance, and easily sharing results with customers and colleagues. The cookies we use can be categorized as follows: Strictly Necessary Cookies: These are cookies that are required for the operation of or specific functionality offered. RF Toolbox and Instrument Control Toolbox allow you to combine S-parameter measurements and data analysis. ![]()
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