As others have hinted at your signals must have a large nonzero component. A peak at 0 (DC) indicates the average value of your signal. This is derived from the Fourier transform itself. This cosine function cos(0)*ps(0) indicates a measure of the average value of the signal. Other Fourier transform components are cosine waves of varying amplitude which show frequency content at those values.
Note that stationary signals will not have a large DC component as they are already zero mean signals. If you do not want a large DC component then you should compute the mean of your signal and subtract values from that. Regardless of whether your data is 0,...,999 or 1,...,1000, or even 1000, ..., 2000 you will get a peak at 0Hz. The only difference will be the magnitude of the peak since it measures the average value.
data1 = arange(1000)
data2 = arange(1000)+1000
dataTransformed3 = data - mean(data)
data4 = numpy.zeros(1000)
data4[::10] = 1 #simulate a photon counter where a 1 indicates a photon came in at time indexed by array.
# we could assume that the sample rate was 10 Hz for example
ps1 = np.abs(np.fft.fft(data))**2
ps2 = np.abs(np.fft.fft(data))**2
ps3 = np.abs(np.fft.fft(dataTransformed))**2
plot(ps1) #shows the peak at 0 Hz
plot(ps2) #shows the peak at 0 Hz
plot(ps3) #shows the peak at 1 Hz this is because we removed the mean value but since
#the function is a step function the next largest component is the 1 Hz cosine wave.
#notice the order of magnitude difference in the two plots.