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--- milestone_2_task_3 [2016/01/26 01:26]
nealb [Specifications]
+++ milestone_2_task_3 [2023/01/15 00:38] (current)
scott [Pass Off]
@@ Line 13: / Line 13: @@
   * Filter the resulting 10 ksamples/s signal using the 10 IIR bandpass filters
   * Calculate and display the signal energy of each of the 10 resulting filtered signals
 ===== General Notes =====
@@ Line 31: / Line 30: @@
     - Each filter is described by 11 'b' coefficients and 11 'a' coefficients
     - The center-of-passband frequencies for the filters are the ten player frequencies
-    - For this task, you should read in you 'b' and 'a' coefficients from the file you saved them in when you designed the filter in Task 1
+    - For this task, you should read in your 'b' and 'a' coefficients from the file(s) you saved them in when you designed the filter in Task 1
-===== Pass Off =====
-Show the following plots for a shot by player 1.
-  - Square wave for player 1
-    - f=1471Hz
-    - Amplitude of 0.1V (square wave with voltage of either 0 or 0.1V)
-    - x-axis of 4 ms near the middle of the spectrum
-    - y-axis of -1V to 1V
-    - Sampling frequency of Fs=100kHz
-  - Optical noise (from lights.mat)
-    - Same axis as square wave
-  - Sum of optical noise and square wave
-    - Same axis as square wave
-  - Decimated signal
-    - Low pass filtered and then down-sampled to Fs=10kHz
-    - Same axis as square wave
-  - Signal filtered by bandpass filter centered at f=1471Hz
-  - The power for the signal through all 10 bandpass filters
-    - Signal length of 200ms
 ===== Resources =====
@@ Line 73: / Line 52: @@
 After creating the signal you will be using the MATLAB code that you developed as part of Task 1 and Task 2.
+===== What is Needed in the Lab Report =====
+Please include the following in the Lab Report for Milestone 2, Task 3:
+  - Clearly labeled versions of the graphs required for pass off, with a brief description for each graph of exactly what we are looking at, and how we can tell from the graph that things are working correctly.  (For example, on the frequency domain plot of noise + the player 1 square wave signal, note where the fundamental player 1 frequency peak from the square wave appears in the plot, and note the major noise peaks that we see in the spectrum.)
+  - A 1-paragraph summary of what was accomplished in this task
+===== Pass Off =====
+Show the following plots for a shot by player 1:
+  - Time-domain plot of square wave for player 1
+    - f = 1471Hz
+    - Amplitude of 0.1V (square wave with voltage of either 0 or 0.1V)
+    - Zoom in on a section of the x-axis 4ms wide when you are showing this for pass off
+    - y-axis of -1V to 1.5V
+    - Sampling frequency of Fs = 100kHz
+  - Time-domain plot of optical noise (from lights.mat)
+    - Same axis as square wave
+  - Time-domain plot showing sum of optical noise and square wave
+    - Same axis as square wave
+  - Frequency-domain plot of sum of optical noise and square wave (on an axis going from 0 to 50 kHz)
+  - Frequency-domain plot of decimated signal (on an axis going from 0 to 5 kHz)
+    - Low pass filter signal and then down-sampled to Fs = 10kHz
+    - Then use fft to view in frequency domain
+  - Frequency-domain signal filtered by bandpass filter centered at f = 1471Hz
+  - Frequency-domain signal filtered by bandpass filter centered at another player frequency
+  - The signal energy for the signal through all 10 bandpass filters
+    - Signal length of 200ms

ECEN 390 - Laser Tag Project

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