- π General Information
- π¨ Installation
- β‘ Lightning-start - PyPulseq in your browser!
- πββ Quickstart - example scripts
- π€Ώ Deep dive - custom pulse sequences
- π₯ Contributing and Community guidelines
- π References
Pulse sequence design is a significant component of MRI research. However, multi-vendor studies require researchers to be acquainted with each hardware platform's programming environment.
PyPulseq enables vendor-neutral pulse sequence design in Python [1,2]. The pulse sequences can be
exported as a .seq
file to be run on Siemens, GE, Bruker and now also Philips hardware by leveraging their respective Pulseq interpreters. This tool is targeted at MRI pulse sequence designers, researchers, students and other interested
users. It is a translation of the Pulseq framework originally written in Matlab [3].
π Currently, PyPulseq is compatible with Pulseq >= 1.4.0. π
It is strongly recommended to first read the Pulseq specification before proceeding. The specification document defines the concepts required for pulse sequence design using PyPulseq.
If you use PyPulseq in your work, please cite the publications listed under References.
PyPulseq is available on the python Package Index PyPi and can be installed using the command
pip install pypulseq
To use the sigpy functionality of make_sigpy_pulse.py
run pip install pypulseq[sigpy]
to install the required dependencies and enable this functionality.
The latest features and minor bug fixes might not be included in the latest release version. If you want to use the bleeding edge version of PyPulseq, you can install it directly from the development branch of this repository using the command
pip install git+https://github.com/imr-framework/pypulseq@dev
π PyPulseq is not yet available on conda, but this is planned for the future π
- Create a new notebook on Google Colab
- Install PyPulseq using
pip install pypulseq
- Get going!
The PyPulseq repository contains several example sequences in the seq_examples folder. Every example script or example notebook creates a pulse sequence, plots the pulse timing diagram and finally saves the sequence as a .seq
file to disk.
Getting started with pulse sequence design using PyPulseq
is simple:
-
First, define system limits in
Opts
and then create aSequence
object with it:import pypulseq as pp system = pp.Opts(max_grad=32, grad_unit='mT/m', max_slew=130, slew_unit='mT/m/ms') seq = pp.Sequence(system=system)
-
Then, design gradient, RF or ADC pulse sequence events:
Nx, Ny = 256, 256 # matrix size fov = 220e-3 # field of view delta_k = fov / Nx # RF sinc pulse with a 90 degree flip angle rf90 = pp.make_sinc_pulse(flip_angle=90, duration=2e-3, system=system, slice_thickness=5e-3, apodization=0.5, time_bw_product=4) # Frequency encode, trapezoidal event gx = pp.make_trapezoid(channel='x', flat_area=Nx * delta_k, flat_time=6.4e-3, system=system) # ADC readout adc = pp.make_adc(num_samples=Nx, duration=gx.flat_time, delay=gx.rise_time, system=system)
-
Add these pulse sequence events to the
Sequence
object. One or more events can be executed simultaneously, simply pass them all to theadd_block()
method. For example, thegx
andadc
pulse sequence events need to be executed simultaneously:seq.add_block(rf90) seq.add_block(gx, adc)
-
Visualize plots:
seq.plot()
-
Generate a
.seq
file to be executed on a real MR scanner:seq.write('demo.seq')
PyPulseq
adheres to a code of conduct adapted from the Contributor Covenant code of conduct.
Contributing guidelines can be found here.
- Ravi, Keerthi, Sairam Geethanath, and John Vaughan. "PyPulseq: A Python Package for MRI Pulse Sequence Design." Journal of Open Source Software 4.42 (2019): 1725.
- Ravi, Keerthi Sravan, et al. "Pulseq-Graphical Programming Interface: Open source visual environment for prototyping pulse sequences and integrated magnetic resonance imaging algorithm development." Magnetic resonance imaging 52 (2018): 9-15.
- Layton, Kelvin J., et al. "Pulseq: a rapid and hardwareβindependent pulse sequence prototyping framework." Magnetic resonance in medicine 77.4 (2017): 1544-1552.