For a series of angle values in (-pi, pi) range, I make a histogram. Is there an effective way to calculate a mean and modal (post probable) value? Consider following examples:
import numpy as N, cmath deg = N.pi/180. d = N.array([-175., 170, 175, 179, -179])*deg i = N.sum(N.exp(1j*d)) ave = cmath.phase(i) i /= float(d.size) stdev = -2. * N.log(N.sqrt(i.real**2 + i.imag**2)) print ave/deg, stdev/deg
Now, let's have a histogram:
counts, bins = N.histogram(data, N.linspace(-N.pi, N.pi, 360))
Is it possible to calculate mean, mode having counts and bins? For non-periodic data, calculation of a mean is straightforward:
ave = sum(counts*bins[:-1])
Calculations of a modal value requires more effort. Actually, I'm not sure my code below is correct: firstly, I identify bins which occur most frequently and then I calculate an arithmetic mean:
cmax = bins[N.argmax(counts)] mode = N.mean(N.take(bins, N.nonzero(counts == cmax)))
I have no idea, how to calculate standard deviation from such data, though. One obvious solution to all my problems (at least those described above) is to convert histogram data to a data series and then use it in calculations. This is not elegant, however, and inefficient.
Any hints will be very appreciated.
This is the partial solution I wrote.
import numpy as N, cmath import scipy.stats as ST d = [-175, 170.2, 175.57, 179, -179, 170.2, 175.57, 170.2] deg = N.pi/180. data = N.array(d)*deg i = N.sum(N.exp(1j*data)) ave = cmath.phase(i) # correct and exact mean for periodic data wrong_ave = N.mean(d) i /= float(data.size) stdev = -2. * N.log(N.sqrt(i.real**2 + i.imag**2)) wrong_stdev = N.std(d) bins = N.linspace(-N.pi, N.pi, 360) counts, bins = N.histogram(data, bins, normed=False) # consider it weighted vector addition nz = N.nonzero(counts) weight = counts[nz] i = N.sum(weight * N.exp(1j*bins[nz])/len(nz)) pave = cmath.phase(i) # correct and approximated mean for periodic data i /= sum(weight)/float(len(nz)) pstdev = -2. * N.log(N.sqrt(i.real**2 + i.imag**2)) print print 'scipy: %12.3f (mean) %12.3f (stdev)' % (ST.circmean(data)/deg, \ ST.circstd(data)/deg)
When run, it gives following results:
mean: 175.840 85.843 175.360 stdev: 0.472 151.785 0.430 scipy: 175.840 (mean) 3.673 (stdev)
A few comments now: the first column gives mean/stdev calculated. As can be seen, the mean agrees well with scipy.stats.circmean (thanks JoeKington for pointing it out). Unfortunately stdev differs. I will look at it later. The second column gives completely wrong results (non-periodic mean/std from numpy obviously does not work here). The 3rd column gives sth I wanted to obtain from the histogram data (@JoeKington: my raw data won't fit memory of my computer.., @dmytro: thanks for your input: of course, bin size will influence result but in my application I don't have much choice, i.e. I have to reduce data somehow). As can be seen, the mean (3rd column) is properly calculated, stdev needs further attention :)