# Import the OSCARS SR module import oscars.sr # Import basic plot utilities (matplotlib). You don't need these to run OSCARS, but it's used here for basic plots from oscars.plots_mpl import * # Create a new OSCARS object. Default to 8 threads and always use the GPU if available osr = oscars.sr.sr(nthreads=8, gpu=1) # Phase difference between fields in [rad] phase = osr.pi()/2. # Clear any existing fields (just good habit in notebook style) and add an undulator field osr.clear_bfields() osr.add_bfield_undulator(bfield=[0, 0.7, 0], period=[0, 0, 0.049], nperiods=21, phase=-phase/2.) osr.add_bfield_undulator(bfield=[0.7, 0, 0], period=[0, 0, 0.049], nperiods=21, phase=+phase/2.) # Just to check the field that we added seems visually correct plot_bfield(osr) # Setup beam similar to NSLSII osr.clear_particle_beams() osr.set_particle_beam( type='electron', name='beam_0', energy_GeV=3, x0=[0, 0, -1], current=0.500, sigma_energy_GeV=0.001*3, beta=[1.5, 0.8], emittance=[0.9e-9, 0.008e-9] ) # Set the start and stop times for the calculation osr.set_ctstartstop(0, 2) # Run the particle trajectory calculation for the ideal particle # First must load the ideal particle initial conditions osr.set_new_particle(particle='ideal') trajectory = osr.calculate_trajectory() # Plot the trajectory position and velocity plot_trajectory_position(trajectory) plot_trajectory_velocity(trajectory) # Calculate spectrum zoom for ideal particle. In reality you may want to run the multi-particle # spectrum calculation, then pick from there what energy we want to see the spectrum at osr.set_new_particle(particle='ideal') spectrum = osr.calculate_spectrum(obs=[0, 0, 30], energy_range_eV=[140, 170], npoints=200) plot_spectrum(spectrum) # Calculate the multi-particle Flux. We'll pick a point around 154 [eV] # Although 5 particles are used here, you shuold use a lot more. flux = osr.calculate_flux_rectangle( plane='XY', energy_eV=154, width=[0.01, 0.01], npoints=[101, 101], translation=[0, 0, 30], nparticles=5 ) plot_flux(flux)