Each ADC operates at 1 GHz rate, set by the MATLAB® variable Fs_adc defined in the initialization callback of this model. The operating rate of the ADCs is indicated by the green signals and blocks in the diagram. The input signal of the second ADC is delayed by an amount equal to...
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AnN-bit flash ADC uses $${2^{Nbits}}$ comparators in parallel. The Flash ADC Comparators subsystem itself is based on MATLAB® code. Before the simulation starts, the comparators calculate the individual reference voltages and store them in a vector. On every specified edge, the input is ...
MATLAB Simulink Signal Processing Toolbox DSP System Toolbox To complete the second and third steps of this tutorial, you also need the following MathWorks products: Simscape Simscape Electrical Control System Toolbox Simulink Control Design To complete the fourth step of this tutorial, you also need...
Use the adeDataReader class to read an adeInfo object or a .mat file to extract metrics and waveform data to MATLAB® base workspace. You can then visualize and analyze the metrics and waveform data from MATLAB command prompt without launching the Mixed-Signal Analyzer app. The adeInfo obje...
Notice that in this model, the clock of the ADC is specified in the ideal zero-order hold block, and it is equal to 1/Fs, where Fs is a MATLAB® variable defined in the model initialization callback and equal to 1.024 GHz. set_param([model '/Aperture Jitter'],'sw','0'); As...
Use the adeDataReader class to read an adeInfo object or a .mat file to extract metrics and waveform data to MATLAB® base workspace. You can then visualize and analyze the metrics and waveform data from MATLAB command prompt without launching the Mixed-Signal Analyzer app. The adeInfo obje...