Of the same
numpy array, calculating
np.cos takes 3.2 seconds, wheras
np.sin runs 548 seconds (nine minutes) on Linux Mint.
See this repo for full code.
I've got a pulse signal (see image below) which I need to modulate onto a HF-carrier, simulating a Laser Doppler Vibrometer. Therefore signal and its time basis need to be resampled to match the carrier's higher sampling rate.
In the following demodulation process both the in-phase carrier
cos(omega * t) and the phase-shifted carrier
sin(omega * t) are needed.
Oddly, the time to evaluate these functions depends highly on the way the time vector has been calculated.
The time vector
t1 is being calculated using
t2 uses the method implemented in
pulse = np.load('data/pulse.npy') # 768 samples pulse_samples = len(pulse) pulse_samplerate = 960 # 960 Hz pulse_duration = pulse_samples / pulse_samplerate # here: 0.8 s pulse_time = np.linspace(0, pulse_duration, pulse_samples, endpoint=False) carrier_freq = 40e6 # 40 MHz carrier_samplerate = 100e6 # 100 MHz carrier_samples = pulse_duration * carrier_samplerate # 80 million t1 = np.linspace(0, pulse_duration, carrier_samples) # method used in scipy.signal.resample # https://github.com/scipy/scipy/blob/v0.17.0/scipy/signal/signaltools.py#L1754 t2 = np.arange(0, carrier_samples) * (pulse_time - pulse_time) \ * pulse_samples / float(carrier_samples) + pulse_time
As can be seen in the picture below, the time vectors are not identical. At 80 million samples the difference
t1 - t2 reaches
Calculating the in-phase and shifted carrier of
t1 takes 3.2 seconds each on my machine.
t2, however, calculating the shifted carrier takes 540 seconds. Nine minutes. For nearly the same 80 million values.
omega_t1 = 2 * np.pi * carrier_frequency * t1 np.cos(omega_t1) # 3.2 seconds np.sin(omega_t1) # 3.3 seconds omega_t2 = 2 * np.pi * carrier_frequency * t2 np.cos(omega_t2) # 3.2 seconds np.sin(omega_t2) # 9 minutes
I can reproduce this bug on both my 32-bit laptop and my 64-bit tower, both running Linux Mint 17. On my flat mate's MacBook, however, the "slow sine" takes as little time as the other three calculations.
I run a Linux Mint 17.03 on a 64-bit AMD processor and Linux Mint 17.2 on 32-bit Intel processor.