Esempio n. 1
0
func output3D(D [][]complex64, reduce func(complex64) float32, size [3]int, prefix string, deltaF float32) {
	const NCOMP = 1
	for i := 0; i < len(D)/2; i++ {
		d := D[i]
		MHz := int((float32(i) * deltaF) / 1e6)
		fname := fmt.Sprintf("%sf%06dMHz.ovf", prefix, MHz)
		slice := data.NewSlice(NCOMP, size)
		doReduce(slice.Host()[0], d, reduce)
		meta := data.Meta{}
		log.Println(fname)
		f := httpfs.MustCreate(fname)
		oommf.WriteOVF2(f, slice, meta, "binary")
		f.Close()
	}
}
Esempio n. 2
0
func mainSpatial() {

	// time points
	Nt := flag.NArg()
	if Nt < 2 {
		log.Fatal("need at least 2 inputs")
	}

	go loadloop()

	// select one component
	comp := 0 // todo

	// get size, time span from first and last file
	data1, meta1 := oommf.MustReadFile(flag.Args()[0])
	_, metaL := oommf.MustReadFile(flag.Args()[Nt-1])

	t0 := float32(meta1.Time)
	t1 := float32(metaL.Time)
	deltaT := t1 - t0
	deltaF := 1 / deltaT // frequency resolution

	size := data1.Size()
	Nx := size[0]
	Ny := size[1]
	Nz := size[2]

	// allocate buffer for everything
	dataList := make([]complex64, Nt*Nx*Ny*Nz)
	dataLists := matrix.ReshapeC2(dataList, [2]int{Nt, Nz * Ny * Nx})

	// interpolate non-equidistant time points
	// make complex in the meanwhile
	time0 := t0                  // start time, not neccesarily 0
	si := 0                      // source index
	for di := 0; di < Nt; di++ { // dst index
		want := time0 + float32(di)*deltaT/float32(Nt) // wanted time
		for si < Nt-1 && !(time(si) <= want && time(si+1) > want && time(si) != time(si+1)) {
			si++
		}

		x := (want - time(si)) / (time(si+1) - time(si))
		if x < 0 || x > 1 {
			panic(fmt.Sprint("x=", x))
		}
		interp3D(dataLists[di], 1-x, file(si).Host()[comp], x, file(si + 1).Host()[comp])
	}

	log.Println("FFT")
	fftMany(dataList, Nt, Nx*Ny*Nz)

	spectrum := magSpectrum(dataLists)
	freqs := make([]float32, len(spectrum))
	for i := range freqs {
		freqs[i] = float32(i) * deltaF
	}
	header := []string{"f (Hz)", "Mag ()"}
	f := httpfs.MustCreate("spectrum.txt")
	writeTable(f, header, [][]float32{freqs, spectrum})
	f.Close()

	log.Println("normalize")
	normalize(dataLists)

	log.Println("output")
	for _, o := range outputs {
		if *o.Enabled {
			output3D(dataLists, o.Filter, size, "fft_"+o.Name, deltaF)
		}
	}
}
Esempio n. 3
0
File: 1d.go Progetto: callistoaz/3
// FFT a single table file
func processTable(infname, outfname string) {

	// read input file
	in := httpfs.MustOpen(infname)
	defer in.Close()

	header, data := ReadTable(in)

	// Process data
	if *flag_Interp {
		data = interp(data) // interpolate to equidistant times
	}

	// determine frequency step, beware zero padding
	const TIME = 0 // time column
	rows := len(data[TIME])
	deltaT := data[TIME][rows-1] - data[TIME][0]
	deltaT *= float32(*flag_Pad)
	deltaF := 1 / (deltaT)

	// mumax outputs one row too much
	rows--
	for i := range data {
		data[i] = data[i][:rows]
	}

	window := windows[*flag_Win]
	if window == nil {
		panic(fmt.Sprint("invalid window:", *flag_Win, " options:", windows))
	}

	for c := range data {
		applyWindow(data[c], window)
		data[c] = zeropad(data[c], rows*(*flag_Pad))
	}

	transf := FFT(data[1:]) // FFT all but first (time) column

	if *flag_NormCol == 1 {
		errPrintln("-divcol may start at column 2")
		os.Exit(1)
	}

	if *flag_NormCol > 1 {
		divCol(transf, transf[*flag_NormCol-2])
	}

	output := reduce(transf, deltaF)

	outHdr := makeFFTHeader(header)
	if *flag_CleanPhase {
		for c := range output[1:] {
			if strings.HasPrefix(outHdr[c], "Ph_") {
				cleanPhase(output[c])
			}
		}
	}

	// write output file
	var out io.Writer
	if *flag_Stdout {
		out = os.Stdout
	} else {
		o := httpfs.MustCreate(outfname)
		defer o.Close()
		out = o
	}
	writeTable(out, outHdr, output)
}