Vehicle audio feature extraction method based on lmd and energy projection method
A technology of audio features and extraction methods, applied in speech analysis, speech recognition, instruments, etc., can solve problems such as the inability to directly and effectively identify the characteristic frequency of the signal, and the lack of consideration of the difference in the frequency components of the signal.
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Embodiment 1
[0037] Step 1: Use the sound sensor to measure the moving truck and obtain the audio signal of the truck , the sampling frequency is 44100, and the number of sampling points is 4096;
[0038] Step 2: Analyze the collected truck audio signal by local mean decomposition (LMD) method To decompose, the steps are as follows
[0039] (1) Find the local mean function . find truck audio signal All local extreme points , find the average value of all adjacent local extremum points
[0040]
[0041] Among them, i=1,2,...M; M is the number of local extremum points of the original signal. Then, all adjacent mean points Connected by a straight line and smoothed by the moving average method, we get
[0042] (2) Find the envelope estimation function . The envelope estimate is
[0043]
[0044] All two adjacent envelope estimates Connected by a straight line, and then smoothed by the moving average method to obtain .
[0045] (3) The local mean function from th...
Embodiment 2
[0075] Step 1: Use the sound sensor to measure the driving tractor and obtain the audio signal of the tractor , the sampling frequency is 44100, and the number of sampling points is 4096;
[0076] Step 2: Analyze the collected tractor audio signal by local mean decomposition (LMD) method To decompose, the steps are as follows
[0077] (1) Find the local mean function . Find out the tractor audio signal All local extreme points , find the average value of all adjacent local extremum points
[0078]
[0079] Among them, i=1,2,...M; M is the number of local extremum points of the original signal. Then, all adjacent mean points Connected by a straight line and smoothed by the moving average method, we get
[0080] (2) Find the envelope estimation function . The envelope estimate is
[0081]
[0082] All two adjacent envelope estimates Connected by a straight line, and then smoothed by the moving average method to obtain .
[0083] (3) The local mean ...
Embodiment 3
[0111] Step 1: Use the sound sensor to measure the moving car and obtain the audio signal of the car , the sampling frequency is 44100, and the number of sampling points is 4096;
[0112] Step 2: Decompose by local mean Method for the collected car audio signal To decompose, the steps are as follows
[0113] (1) Find the local mean function . find car audio signal All local extreme points , find the average value of all adjacent local extremum points
[0114]
[0115] Among them, i=1,2,...M; M is the number of local extremum points of the original signal. Then, all adjacent mean points Connected by a straight line and smoothed by the moving average method, we get
[0116] (2) Find the envelope estimation function . The envelope estimate is
[0117]
[0118] All two adjacent envelope estimates Connected by a straight line, and then smoothed by the moving average method to obtain .
[0119] (3) The local mean function from the original signal ...
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