## RF Toolbox |

- Provides read and write access to industry-standard file formats for network parameters
- Defines RF filters, transmission lines, amplifiers, and mixers by their experimental or theoretical network parameters and physical properties
- Calculates network parameters for RF components in series, parallel, cascade, hybrid, and inverse hybrid configurations
- Builds models using the rational function fitting method
- Exports rational function models to Simulink or as Verilog-A modules
- Calculates noise figures and third-order intercept points for cascaded components
- Converts among S, Y, Z, ABCD, h, g, and T network parameters
- Includes rectangular and polar plots and Smith
^{®}charts for visualizing data

You can execute RF Toolbox functions from the MATLAB command line or the RF Design and Analysis app. You can also call the toolbox functions from your own MATLAB scripts and functions. The toolbox includes rectangular, polar, and Smith^{®} charts for visualizing data.

A key challenge in RF engineering is accounting for impedance difference and reflection effects that occur when components are configured into a network. RF Toolbox represents an RF component by its network parameters, which are sufficient to determine its small signal response. From the individual network parameters of a set of components, RF Toolbox can determine the network parameters and small signal response of any configuration containing these components.

RF Toolbox enables you to use network parameters to specify RF filters, transmission lines, amplifiers, and mixers, either directly or by their physical properties. Network parameters can be generated from within MATLAB or read in from external data. You can read and write industry-standard data file formats, such as Touchstone .snp. You can also specify components by their physical properties, such as RLC topology and values and transmission line properties. RF Toolbox calculates the corresponding network parameters.

Using RF Toolbox, you can define components in the following ways:

- Passive networks and general circuit elements, using data from Touchstone .snp, .ynp, .znp, and .hnp files
- Amplifiers and mixers, using data from Touchstone file formats (.s2p, .y2p, .z2p, and .h2p) and MathWorks file format (.amp)
- Transmission lines, using the lines' geometries and electrical properties
- LC ladder filters, using the filters' topology and values

RF Toolbox helps you build complex RF networks from simpler components in a visual environment. Using the RF Toolbox, you connect components in series, parallel, cascade, hybrid, and inverse hybrid configurations by calling the appropriate toolbox function with the components as arguments. The return value is a new object that represents the configuration's behavior. This object can be passed in turn as an argument to other toolbox functions.

In addition to calculating the small signal frequency response, RF Toolbox calculates input and output reflection coefficients, stability factors, noise figures, and third-order intercept points for cascaded components. It also enables you to de-embed S-parameters from cascaded networks.

You can use RF Toolbox to model single-ended and differential high-speed transmission lines using rational functions. This type of model is useful in signal integrity engineering, where the goal is the reliable connection of high-speed semiconductor devices using, for example, backplanes and printed circuit boards.

Rational function fitting provides the following advantages over traditional techniques, such as inverse fast Fourier transform:

- Simpler models for a given accuracy
- Model order reduction, letting you trade off complexity and accuracy
- Zero phase on extrapolation to DC, avoiding the need to write elaborate constraint algorithms
- Physical correspondence between the model and transmission line characteristics, providing greater insight

In the typical signal integrity workflow, you use RF Toolbox after you characterize the backplane with 4-port network parameters and before you begin the design of the high-speed semiconductor I/O circuitry. Specifically, you:

- Measure the network parameters with a vector network analyzer
- Import the Touchstone data file
- Convert the single-ended 4-port S-parameters to 2-port differential S-parameters
- Compute the transfer function
- Fit the transfer function to a closed-form rational function model, reducing the order as needed
- Export the model to Simulink or in Verilog-A format for use as a test environment in the SPICE-like analog circuit simulator, which you use to design the I/O circuitry

The RF Toolbox lets you choose the appropriate format for your task by converting among S, Y, Z, ABCD, h, g, and T network parameter formats. Y-parameters are convenient for calculating network parameters of RLC circuits, while S-parameters are better for visualizing the frequency responses. In addition, you can convert S-parameters to S-parameters with different reference impedance.

The RF Toolbox provides specialized charts and plots for visualizing component and network behavior, including:

- Smith charts
- Rectangular plots
- Polar plots

You can also create these charts and plots from the RF Design and Analysis app.