We going to use the online simulation which represents Wave on the String. The simulation allows changing the amplitude, frequency, set up the string with xed end, loose end and no end. You may adjust the frequency of the source and whether the ends of the medium are xed or free. For some frequencies, you will not be able to establish a standing wave. The simulator builds up the standing waves slowly, so be patient before deciding whether a standing wave has been established, see what happens. Part A: Fixed at both ends 1. Find the lowest frequency that will establish a standing wave. This is the fundamental frequency. 2. Determine the number of nodes, antinodes, and wavelengths for this frequency. Create a data table with 5 colunrms (frequency, 11' frequency, nodes, antinodes, and wavelengths), and enter this data. Be careil with wavelengths; you should gure out how many wavelengths there are in the length of the string. Draw the standing wave and label the Nodes with \"N\" and Antinodes with \"A"- 3. Increase the frequency until you nd the next one that will establish a standing wave. Find the values listed in Step 2 for this standing wave, enter them into the data table, and draw and label the wave- 4- Continue increasing the frequency and entering the data for additional standing waves. 5. Plot the inverse of the frequency on the xaxis, against the wavelength on the yaxis and dene the linear density. If the maximum tension in the simulation is 10.0 N, what is the linear mass density (M) of the string? 6 -The speed of a transverse wave on a string of length L and mass m under tension T is given by the formula UH: mm LL