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#NJIT SOFTWARE RF TOOLBOX MATLAB HOW TO#
This section describes how to use the toolbox to read Spectre simulation results into MATLAB and to use MATLAB to perform some standard RF measurements. 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. The Spectre/RF MATLAB Toolbox The MATLAB® Toolbox provides an interface between both the Spectre and UltraSim® circuit simulation technologies and the MATLAB data manipulation environment. To get more information on a given object run: To get a list of currently available objects with the BSP installed simply run:
#NJIT SOFTWARE RF TOOLBOX MATLAB CODE#
The available code is available in the GitHub repo folder here, where object tests have the naming convention Tests. However, to interact with the more familiar LongsPeak interface, it can be instantiated like above as:įor example usage of certain objects, it can be useful to inspect their related test code which exercises initiations in different configurations. Therefore, it simply uses ADAR300x and ADMV4420 objects under the hood. For example, the LongsPeak Evaluation board contains an AD9680 and AD9144. These System Objects can be access under the “adi” namespace in MATLAB and are followed by their part number or board name and finally Tx or Rx:įor example, to instantiate a ADAR3002 object to control the ADAR3002 beamformer it can be created as follows:Īll supported boards are derived from low level objects based on their parts. Device interfaces which provide control and data streaming are implemented with MATLAB System Objects and Simulink Blocks.
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