func TestSubtract() {
a := []float64{3, 5, 7, 9}
b := make([]float64, len(a))
copy(b, a)
util.DumpSlice("a", a)
util.DumpSlice("b", b)
//c:= make([]float64, len(a)
util.SliceSub(a, b, a)
util.DumpSlice("result", a)
util.DumpSlice("b", b)
}
func Decompose(f []float64, maxImf int) int {
h := make([]float64, len(f))
residual := make([]float64, len(f))
copy(h, f)
copy(residual, f)
const eps = 0.05
imfCount := 0
loopCount := 0
rmin := 0.0
rmax := 0.0
monotonic := false
n := len(f)
imfs := algebra.NewMat(n, maxImf)
for {
fmt.Printf("loop %d\n", loopCount)
loopCount = loopCount + 1
util.DumpSlice("current h", h)
fmt.Printf("Sifting...\n")
minMean, zeroCrossings, minCount, maxCount := Sift(h)
extrema := minCount + maxCount
fmt.Printf("found minMean of %f\n", minMean)
fmt.Printf("min mean %f zc %d ex %d %d\n", minMean, zeroCrossings, minCount, maxCount)
pointMatch := ((zeroCrossings-extrema < 2) || (extrema-zeroCrossings < 2))
if (minMean < eps) && pointMatch {
fmt.Printf("storing imf at index %d\n", imfCount)
for i := 0; i < n; i++ {
imfs[i][imfCount] = h[i]
}
imfCount = imfCount + 1
fmt.Printf("found imf number %d\n", imfCount)
util.SliceSub(residual, h, residual)
copy(h, residual)
if imfCount >= maxImf {
break
}
rmin, rmax, monotonic = util.SliceStats(residual)
if monotonic {
fmt.Printf("terminating with monotonic residual\n")
}
if (rmax - rmin) < eps {
fmt.Printf("terminating with small residual %f\n", rmax-rmin)
}
}
}
algebra.MatInfo(imfs)
return imfCount
}
