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I'm trying to implement Python method that generates sine wave, which ramps up between two freq exponentially. Linear change was solved in [this question] with following Python code:

from math import pi, sin

def sweep(f_start, f_end, interval, n_steps):    
    for i in range(n_steps):
        delta = i / float(n_steps)
        t = interval * delta
        phase = 2 * pi * t * (f_start + (f_end - f_start) * delta / 2)
        print t, phase * 180 / pi, 3 * sin(phase)

sweep(1, 10, 5, 1000)

How to change this linear accumulative phase/delta approach to expotential frequency sweep and be smooth to human ear.

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I think this question is more about math than programming, see: – aIKid Nov 4 '13 at 15:43
This question has the math, and a python implementation: possible duplicate of sine wave that slowly ramps up frequency from f1 to f2 for a given time – Dave Swersky Nov 4 '13 at 15:44
This platform is for asking programming-related question. If you ask your question like as you have asked above, it can be just answered by somebody who knows the particular branch of engineering. Please try to make it as much generic as possible. – Jack_of_All_Trades Nov 4 '13 at 15:45
if the linear question was acceptable, why isn't the log one? i'll answer this when i have some free time. i don't think it can be that hard.… – andrew cooke Nov 4 '13 at 15:50
@andrewcooke: I don't see any point in saying this question do not fit here but I strongly suggest that OPs should be encouraged to ask questions that reflects the question in programming terms so that anybody willing to answer will less have to deal with the obscure physics of the problem and focus more and to the point to the programming aspect. – Jack_of_All_Trades Nov 4 '13 at 16:01
up vote 4 down vote accepted

Bas's answer is great, but doesn't actually give an analytic solution, so here's that part...

As far as I can tell, you want something like sin(Aexp(Bt)) where A and B are constants. I'll assume time starts at 0 and continues to C (if it starts at some other time, subtract that from both).

Then, as Bas said, I think, if we have sin(g(t)) frequency f is such that 2 * pi * f = dg / dt. And we want that to be f0 at time 0 and fC at time C.

If you go through the maths, which is easy (it really is - last year of school level), you get:

B = 1/C * log(fC/f0)
A = 2 * pi * f0 / B

and here's some code that goes from 1 to 10Hz in 5 seconds using 1000 samples:

from math import pi, sin, log, exp

def sweep(f_start, f_end, interval, n_steps):
    b = log(f_end/f_start) / interval
    a = 2 * pi * f_start / b
    for i in range(n_steps):
        delta = i / float(n_steps)
        t = interval * delta
        g_t = a * exp(b * t)
        print t, 3 * sin(g_t)

sweep(1, 10, 5, 1000)

which gives:

a pretty plot

(and you can add in a constant - sin(g_t + k) - to get the starting phase wherever you want).


To show that the issue you are seeing is an artefact of sampling, here's a version that does oversampling (if you set it as an argument):

from math import pi, sin, log, exp

def sweep(f_start, f_end, interval, n_steps, n_oversample=1):
    b = log(f_end/f_start) / interval
    a = 2 * pi * f_start / b
    for i in range(n_steps):
        for oversample in range(n_oversample):
            fractional_step = oversample / float(n_oversample)
            delta = (i + fractional_step) / float(n_steps)
            t = interval * delta
            g_t = a * exp(b * t)
            print t, 3 * sin(g_t)

sweep(16000.0, 16500.0, 256.0/48000.0, 256)      # looks strange
sweep(16000.0, 16500.0, 256.0/48000.0, 256, 4)   # looks fine with better resolution

If you check the code you'll see that all that setting n_oversample to 4 does (the second call) is add a higher resolution to the timesteps. In particular, the code when oversample = 0 (ie fractional_step = 0) is identical to before, so the second plot includes the points in the first plot, plus extra ones that "fill in" the missing data and make everything look much less surprising.

Here's a close-up of the original and the oversampled curve near the start, showing what is happening in detail:

enter image description here

Finally, this kind of thing is completely normal and does not indicate any kind of error. When an analogue signal is generated from the digital waveform you'll get "the right" result (assuming the hardware is working right). This excellent video will explain things if they are not clear.

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I did all the math and now I understand it, but I think I'm missing some nuance. When I call sweep(16000.0, 16500.0, 256.0/48000.0, 256) I get strange beginning of sweep: – Ethan Smith Nov 7 '13 at 14:10
[please ignore my earlier replies if you saw them] i am pretty sure this is just an artefact of the sampling. the 16kHz signal is quite close to the nyquist frequency of 24kHz so you're getting poorly sampled sine waves which are giving that strange envelope. if you reduce the frequency range to 8000 to 8500 then it looks better, but you still see something. so it's just "normal" sampling artefacts and not a problem. – andrew cooke Nov 7 '13 at 16:53
see update - if you oversample the same scan it looks much better. – andrew cooke Nov 8 '13 at 0:19
Thank You for such comprehensive answer! Now I am facing something different. I want to start my signal at different time because I want to sweep it back and forth f1 to f2 to f1. When I start from 0 to t the k-parameter (in f_inst(t) = f1 * exp(k * t)) is chosen such that f_inst(t2) = f2 and automatically for f_inst(0) = f1 because of exp(k*0) == 1. Now when t > 0 there is no option to start exactly from initial frequency. My second question is if I want to continue with end frequency do I have to add the phase calculated from sweep ? – Ethan Smith Nov 11 '13 at 23:23
i don't understand the question. but if you want the curves to "join up" then yes, just add the phases as required (see comment just before Update) – andrew cooke Nov 11 '13 at 23:40

The trick in this sort of problems is to understand the relation between frequency modulation and phase modulation, these two are closely related. A sine with a constant frequency f and amplitude A can be described as (formulas, not python code):

x(t) = A sin(2 * pi * f * t)

but a different way to write this is by first defining a phase phi as a function of time:

phi(t) = 2 * pi * f * t
x(t) = A sin(phi(t))

The thing to note here is that frequency f is the derivative of the phase, divided by 2*pi: f = d/dt(phi(t)) / (2*pi).

For a signal which has a frequency that is varying in time, you can similarly define an instantaneous frequency f_inst:

x(t) = A sin(phi(t))
f_inst = d/dt(phi(t)) / (2*pi)

What you want to do is the opposite of this, you have a given instantaneous frequency (your logarithmic sweep), which you need to convert into a phase. Since the opposite of derivation is integration, you can calculate the appropriate phase like this (still formulas):

phi(t) = 2 * pi * Integral_0_to_t {f_inst(t) dt}
x(t) = A sin(phi(t))

What you are doing here is some sort of phase modulation of a signal (with zero frequency) to obtain the required instantaneous frequency. This is pretty easy to do in numpy:

from pylab import *
n = 1000 # number of points
f1, f2 = 10, 30 # frequency sweep range in Hertz

t = linspace(0,1,1000)
dt = t[1] - t[0] # needed for integration

# define desired logarithmic frequency sweep
f_inst = logspace(log10(f1), log10(f2), n)
phi = 2 * pi * cumsum(f_inst) * dt # integrate to get phase

# make plot
plot(t, sin(phi))
xlabel('Time (s)')
ylim([-1.2, 1.2])

Resulting image:

Logarithmic frequency sweep

But (as also noted in the dupe mentioned by Dave), you probably don't want a logarithmic sweep, but an exponential one. Your ear has a logarithmic perception of frequency, so a smooth/linear musical scale (think the keys on a piano) are therefore spaced exponentially. This can be achieved by simply redefining your instantaneous frequency f_inst(t) = f1 * exp(k * t), where k is chosen such that f_inst(t2) = f2.

If you want to use amplitude modulation at the same time, you can simply change A to a time dependent A(t) in the formulas.

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