1. Build a model for the equation below. (Use the procedure steps in the extra sheet as a guide ONLY and change the parameters there to macth the parameters of this test! PP X(t) = [1 + 1.4V sin(27(2 x 103):)] 4v, sin(2n(100 x 10)) [10 marks on the connections and adjustments] 2. Capture the X(t) signal using an oscilloscope to (Channel A) and the signal 1.4Vpp sin(21(2 x 103)t) to (Channel B), make sure to adjust the oscilloscope parameters to have a clear view of the two signals. Call your instructor to check your connection and oscilloscope screen! [10 marks on clear view of the signals] 3. What is the operation implemented by this model and why it is needed? [2.5 marks] 4. What do we call the signal X(t) in the equation above and what is her type? (2.5 marks] 5. Measure the modulation index m from the oscilloscope screen explaining the calculations. [7.5 marks] 1. Build a model for the equation below. (Use the procedure steps in the extra sheet as a guide ONLY and change the parameters there to macth the parameters of this test! PP X(t) = [1 + 1.4V sin(27(2 x 103):)] 4v, sin(2n(100 x 10)) [10 marks on the connections and adjustments] 2. Capture the X(t) signal using an oscilloscope to (Channel A) and the signal 1.4Vpp sin(21(2 x 103)t) to (Channel B), make sure to adjust the oscilloscope parameters to have a clear view of the two signals. Call your instructor to check your connection and oscilloscope screen! [10 marks on clear view of the signals] 3. What is the operation implemented by this model and why it is needed? [2.5 marks] 4. What do we call the signal X(t) in the equation above and what is her type? (2.5 marks] 5. Measure the modulation index m from the oscilloscope screen explaining the calculations. [7.5 marks]