The main method that generates signals is ~setigen.frame.Frame.add_signal
. This allows us to pass in an functions or arrays that describe the shape of the signal over time, over frequency within individual time samples, and over a bandpass of frequencies. setigen
comes prepackaged with common functions (setigen.funcs), but you can write your own!
The most basic signal that you can generate is a constant intensity, constant drift-rate signal. Note that as in the Getting started example, you can also use frame.add_constant_signal
, which is simpler and more efficient for signal injection into large data frames.
from astropy import units as u
import numpy as np
import setigen as stg
# Define time and frequency arrays, essentially labels for the 2D data array
fchans = 1024
tchans = 16
df = 2.7939677238464355*u.Hz
dt = 18.25361108*u.s
fch1 = 6095.214842353016*u.MHz
# Generate the signal
frame = stg.Frame(fchans=fchans,
tchans=tchans,
df=df,
dt=dt,
fch1=fch1)
signal = frame.add_signal(stg.constant_path(f_start=frame.get_frequency(200),
drift_rate=2*u.Hz/u.s),
stg.constant_t_profile(level=1),
stg.box_f_profile(width=20*u.Hz),
stg.constant_bp_profile(level=1))
setigen.Frame.add_signal
returns a 2D numpy array containing only the synthetic signal. To visualize the resulting frame, we can use matplotlib.pyplot.imshow
:
import matplotlib.pyplot as plt
fig = plt.figure(figsize=(10, 6))
plt.imshow(frame.get_data(), aspect='auto')
plt.colorbar()
fig.savefig("basic_signal.png", bbox_inches='tight')
In setigen
, we use astropy.units
to exactly specify where signals should be in time-frequency space. Astropy automatically handles unit conversions (MHz -> Hz, etc.), which is a nice convenience. Nevertheless, you can also use normal SI units (Hz, s) without additional modifiers, in which case the above code would become:
from astropy import units as u
import numpy as np
import setigen as stg
# Define time and frequency arrays, essentially labels for the 2D data array
fchans = 1024
tchans = 16
df = 2.7939677238464355
dt = 18.25361108
fch1 = 6095.214842353016 * 10**6
# Generate the signal
frame = stg.Frame(fchans=fchans,
tchans=tchans,
df=df,
dt=dt,
fch1=fch1)
signal = frame.add_signal(stg.constant_path(f_start=frame.get_frequency(200),
drift_rate=2),
stg.constant_t_profile(level=1),
stg.box_f_profile(width=20),
stg.constant_bp_profile(level=1))
So, it isn't quite necessary to use astropy.units
, but it's an option to avoid manual unit conversion and calculation.
With setigen
's pre-written signal functions, you can generate a variety of signals right off the bat. The main signal parameters that customize the synthetic signal are path
, t_profile
, f_profile
, and bp_profile
.
path
describes the path of the signal in time-frequency space. The path
function takes in a time and outputs 'central' frequency corresponding to that time.
t_profile
(time profile) describes the intensity of the signal over time. The t_profile
function takes in a time and outputs an intensity.
f_profile
(frequency profile) describes the intensity of the signal within a time sample as a function of relative frequency. The f_profile
function takes in a frequency and a central frequency and computes an intensity. This function is used to control the spectral shape of the signal (with respect to a central frequency), which may be a square wave, a Gaussian, or any custom shape!
bp_profile
describes the intensity of the signal over the bandpass of frequencies. Whereas f_profile
computes intensity with respect to a relative frequency, bp_profile
computes intensity with respect to the absolute frequency value. The bp_profile
function takes in a frequency and outputs an intensity as well.
All these functions combine to form the final synthetic signal, which means you can create a host of signals by switching up these parameters!
Here are just a few examples of pre-written signal functions. To see all of the included functions, check out setigen.funcs. To avoid needless repetition, each example script will assume the same basic setup:
from astropy import units as u
import numpy as np
import setigen as stg
# Define time and frequency arrays, essentially labels for the 2D data array
fchans = 1024
tchans = 16
df = 2.7939677238464355*u.Hz
dt = 18.25361108*u.s
fch1 = 6095.214842353016*u.MHz
# Generate the signal
frame = stg.Frame(fchans=fchans,
tchans=tchans,
df=df,
dt=dt,
fch1=fch1)
A constant path is a linear Doppler-drifted signal. To generate this path, use ~setigen.funcs.paths.constant_path
and specify the starting frequency of the signal and the drift rate (in units of frequency over time, consistent with the units of your time and frequency arrays):
signal = frame.add_signal(stg.constant_path(f_start=frame.get_frequency(200),
drift_rate=2*u.Hz/u.s),
stg.constant_t_profile(level=1),
stg.box_f_profile(width=20*u.Hz),
stg.constant_bp_profile(level=1))
This path is a sine wave, controlled by a starting frequency, drift rate, period, and amplitude, using ~setigen.funcs.paths.sine_path
.
signal = frame.add_signal(stg.sine_path(f_start=frame.get_frequency(200),
drift_rate=2*u.Hz/u.s,
period=100*u.s,
amplitude=100*u.Hz),
stg.constant_t_profile(level=1),
stg.box_f_profile(width=20*u.Hz),
stg.constant_bp_profile(level=1))
This path is a very simple quadratic with respect to time, using ~setigen.funcs.paths.squared_path
.
signal = frame.add_signal(stg.squared_path(f_start=frame.get_frequency(200),
drift_rate=0.01*u.Hz/u.s),
stg.constant_t_profile(level=1),
stg.box_f_profile(width=20*u.Hz),
stg.constant_bp_profile(level=1))
To generate a signal with the same intensity over time, use ~setigen.funcs.t_profiles.constant_t_profile
, specifying only the intensity level:
signal = frame.add_signal(stg.constant_path(f_start=frame.get_frequency(200),
drift_rate=2*u.Hz/u.s),
stg.constant_t_profile(level=1),
stg.box_f_profile(width=20*u.Hz),
stg.constant_bp_profile(level=1))
To generate a signal with sinusoidal intensity over time, use ~setigen.funcs.t_profiles.sine_t_profile
, specifying the period, amplitude, and average intensity level. The intensity level is essentially an offset added to a sine function, so it should be equal or greater than the amplitude so that the signal doesn't have any negative values.
Here's an example with equal level and amplitude:
signal = frame.add_signal(stg.constant_path(f_start=frame.get_frequency(200),
drift_rate=2*u.Hz/u.s),
stg.sine_t_profile(period=100*u.s,
amplitude=1,
level=1),
stg.box_f_profile(width=20*u.Hz),
stg.constant_bp_profile(level=1))
And here's an example with the level a bit higher than the amplitude:
signal = frame.add_signal(stg.constant_path(f_start=frame.get_frequency(200),
drift_rate=2*u.Hz/u.s),
stg.sine_t_profile(period=100*u.s,
amplitude=1,
level=3),
stg.box_f_profile(width=20*u.Hz),
stg.constant_bp_profile(level=1))
To generate a signal with the same intensity over frequency, use ~setigen.funcs.f_profiles.box_f_profile
, specifying the width of the signal:
signal = frame.add_signal(stg.constant_path(f_start=frame.get_frequency(200),
drift_rate=2*u.Hz/u.s),
stg.constant_t_profile(level=1),
stg.box_f_profile(width=40*u.Hz),
stg.constant_bp_profile(level=1))
To generate a signal with a Gaussian intensity profile in the frequency direction, use ~setigen.funcs.f_profiles.gaussian_f_profile
, specifying the width of the signal:
signal = frame.add_signal(stg.constant_path(f_start=frame.get_frequency(200),
drift_rate=2*u.Hz/u.s),
stg.constant_t_profile(level=1),
stg.gaussian_f_profile(width=40*u.Hz),
stg.constant_bp_profile(level=1))
The profile ~setigen.funcs.f_profiles.multiple_gaussian_f_profile
, generates a symmetric signal with three Gaussians; one main signal and two smaller signals on either side.
signal = frame.add_signal(stg.constant_path(f_start=frame.get_frequency(200),
drift_rate=2*u.Hz/u.s),
stg.constant_t_profile(level=1),
stg.multiple_gaussian_f_profile(width=40*u.Hz),
stg.constant_bp_profile(level=1))
Currently, all the synthetic noise routines packaged with setigen
are based on Gaussian noise. Every time synthetic noise is added to an image, setigen
will try to estimate the noise properties of the frame, and you can get these via ~setigen.Frame.get_total_stats
and ~setigen.Frame.get_noise_stats
.
Important note: over a range of many frequency channels, real radio data has complex systematic structure, such as coarse channels and bandpass shapes. Adding purely synthetic Gaussian noise as the background for your frames is therefore most appropriate when your frame size is somewhat limited in frequency, in which case you can mostly ignore these systematic artifacts. As usual, whether this is something you should care about just depends on your use cases.
A minimal working example for adding noise is:
import matplotlib.pyplot as plt
import numpy as np
from astropy import units as u
import setigen as stg
# Define time and frequency arrays, essentially labels for the 2D data array
fchans = 1024
tchans = 16
df = -2.7939677238464355*u.Hz
dt = 18.25361108*u.s
fch1 = 6095.214842353016*u.MHz
# Generate the signal
frame = stg.Frame(fchans=fchans,
tchans=tchans,
df=df,
dt=dt,
fch1=fch1)
noise = frame.add_noise(x_mean=5, x_std=2)
fig = plt.figure(figsize=(10,6))
plt.imshow(frame.get_data(), aspect='auto')
plt.colorbar()
plt.show()
This adds Gaussian noise with mean 5 and standard deviation 2 to an empty frame. ~setigen.frame.Frame.add_noise
returns a 2D numpy array containing only the synthetic noise.
In addition, we can truncate the noise at a lower bound specified by parameter `x_min`:
noise = frame.add_noise(x_mean=5, x_std=2, x_min=0)
This may be useful depending on the use case; you might not want negative intensities, or simply any intensity below a reasonable threshold, to occur in your synthetic data.
We can also generate synthetic noise whose parameters are sampled from real observations. Specifically, we can select the mean, standard deviation, and minimum from distributions of parameters estimated from observations.
If no distributions are specified explicitly, noise parameters are sampled by default from pre-loaded distributions in setigen
. These were estimated from GBT C-Band observations on frames with (dt, df) = (1.4 s, 1.4 Hz) and (tchans, fchans) = (32, 1024). Behind the scenes, the mean, standard deviation, and minimum intensity over each sub-frame in the observation were saved into three respective numpy arrays. The frame.add_noise_from_obs
function selects a mean, standard deviation, and minimum from these arrays (not necessarily all corresponding to the same original observational sub-frame), and populates your frame with Gaussian noise accordingly. You can also set the share_index
parameter to True, to force these random noise parameter selections to all correspond to the same original observational sub-frame.
Note that these pre-loaded observations only serve as approximations and real observations vary depending on the noise temperature and frequency band. To be safe, you can generate your own parameters distributions from observational data.
Without specifying distributions:
noise = frame.add_noise_from_obs(share_index=False)
We can readily see that the intensities are similar to a real GBT observation's.
We can also specify the distributions from which to sample parameters, one each for the mean, standard deviation, and minimum, as below. Note: just as in the pure noise generation above, you don't need to specify an x_min_array from which to sample if there's no need to truncate the noise at a lower bound.
noise = frame.add_noise_from_obs(x_mean_array=[3,4,5],
x_std_array=[1,2,3],
x_min_array=[1,2])
When using custom distribution arrays, if they all have the same size, you can set share_index=True
to force the random noise parameter selections to use the same indices (as opposed to randomly choosing a parameter from each array).
There are a few functions included in Frame
that can help in constructing synthetic signals.
To just grab the underlying intensity data, you can do
data = frame.get_data(use_db=False)
As it implies, if you switch the use_db
flag to true, it will express the intensities in terms of decibels. This can help visualize data a little better, depending on the application.
Examples of the built-in plotting utilities are on the Getting started page:
frame.render()
frame.bl_render()
Note that both of these methods use matplotlib.pyplot.imshow
behind the scenes, which means you can still control plot parameters before and after these function calls, e.g.
fig = plt.figure(figsize=(10, 6))
frame.render()
plt.title('My awesome title')
plt.savefig('frame.png')
plt.show()
If a frame has background noise, we can calculate intensities corresponding to different signal-to-noise (SNR) values. Here, the SNR of a signal is obtained from integrating over the entire time axis, e.g. so that it reduces noise by sqrt(tchans)
.
For example, the included signal parameter functions in setigen
all calculate signals based on absolute intensities, so if you'd like to include a signal with an SNR of 10, you would do:
intensity = frame.get_intensity(snr=10)
Alternately, you can get the SNR of a given intensity by doing:
snr = frame.get_snr(intensity=100)
Another useful conversion is between frequencies and frame indices:
index = frame.get_index(frequency)
frequency = frame.get_frequency(index)
For some injection tasks, you might want to define signals based on where they start and end on the frequency axis. Furthermore, this might not depend on frequency per se. In these cases, you can calculate a drift frequency using the get_drift_rate
method:
start_index = np.random.randint(0, 1024)
end_index = np.random.randint(0, 1024)
drift_rate = frame.get_drift_rate(start_index, end_index)
The Frame object includes a custom metadata property that allows you to manually track injected signal parameters. Accordingly, frame.metadata
is a simple dictionary, making no assumptions about the type or number of signals you inject, or even what information to store. This property is mainly included as an easy way to save the data with the information you care about if you save and load frames with pickle.
new_metadata = {
'snr': 10,
'drift_rate': 2,
'f_profile': 'lorentzian'
}
# Sets custom metadata to an input dictionary
frame.set_metadata(new_metadata)
# Appends input dictionary to custom metadata
frame.add_metadata(new_metadata)
# Gets custom metadata dict
metadata = frame.get_metadata()
There are a few different ways to save information from frames.
Pickle lets us save and load entire Frame objects, which is helpful for keeping both data and metadata together in storage:
# Saving to file
frame.save_pickle(filename='frame.pickle')
# Loading a Frame object from file
loaded_frame = stg.Frame.load_pickle(filename='frame.pickle')
Note that load_pickle
is a class method, not an instance method.
If you would only like to save the frame data as a numpy array, you can do:
frame.save_npy(filename='frame.npy')
This just uses the numpy.save
and numpy.load
functions to save to .npy
. If needed, you can also load in the data using
frame.load_npy(filename='frame.npy')
If you are interfacing with other Breakthrough Listen or astronomy codebases, outputting setigen
frames in filterbank or HDF5 format can be very useful. Note that saving to HDF5 can have some difficulties based on your bitshuffle
installation and other dependencies, but saving as a filterbank file is stable.
We provide the following methods:
frame.save_fil(filename='frame.fil')
frame.save_hdf5(filename='frame.hdf5')
frame.save_h5(filename='frame.h5')
To get an equivalent blimpy
Waterfall object in the same Python session, use
waterfall = frame.get_waterfall()