File:Wigner quasiprobability distribution of squeezed states.webm

From HandWiki

Wigner_quasiprobability_distribution_of_squeezed_states.webm (file size: 1.13 MB, MIME type: video/webm)

This file is from a shared repository and may be used by other projects. The description on its file description page there is shown below.

Summary

Description
English: Wigner quasiprobability distribution of squeezed states, for varying amount of phase shift and displacement.


Matplotlib

import matplotlib.pyplot as plt
import matplotlib as mpl
import numpy as np
from IPython.display import display
from qutip import (about, basis, coherent, coherent_dm, displace, fock, ket2dm,
                   plot_wigner, squeeze, thermal_dm, wigner_cmap, wigner)

import scipy.ndimage
import os
from tqdm import tqdm

def rotate_and_crop(array, angle, xvec, yvec):
    rotated_array = scipy.ndimage.rotate(array, -angle, reshape=False)
    rows, cols = rotated_array.shape
    center_row, center_col = rows // 2, cols // 2
    target_rows, target_cols = len(yvec), len(xvec)
    start_row = center_row - target_rows // 2
    end_row = start_row + target_rows
    start_col = center_col - target_cols // 2
    end_col = start_col + target_cols
    return rotated_array[start_row:end_row, start_col:end_col]

def plot_wigner_marginals(W, xvec, yvec, marginal_max, resolution=200, angle=0):
    wmap = wigner_cmap(W)
    wlim = np.abs(W).max()
    cmap = plt.colormaps['RdBu']

    fig = plt.figure()
    n, m = 5, 1
    fig, axes = plt.subplot_mosaic(
        [ ["top"] * n + ["3d"] * m ] * m + [ ["mid"] * n + ["right"] * m] * n,
    figsize=(20, 20),
    layout="constrained",
    width_ratios=[1.05] * (n+m))

    ax = axes["mid"]
    norm = mpl.colors.Normalize(-wlim, wlim)
    ax.contourf(xvec, yvec, W, resolution // 3, norm=norm, cmap=cmap)
    

    ax = axes["top"]
    x_marginal = np.sum(W, axis=0)
    y_marginal = np.sum(W, axis=1)
    ax.fill_between(xvec, x_marginal, 0, color='#938fba', alpha=0.5)
    ax.plot(xvec, x_marginal, color='#4a5a90')
    ax.set_xlim(min(xvec), max(xvec))
    ax.set_ylim(0, marginal_max * 1.05)
    ax.set_xticks([])
    ax.set_yticks([])

    ax = axes["right"]
    ax.fill_betweenx(yvec, np.sum(W, axis=1), 0, color='#938fba', alpha=0.5)
    ax.plot(y_marginal, yvec, color='#4a5a90')
    ax.set_xlim(0, marginal_max * 1.05)
    ax.set_ylim(min(yvec), max(yvec))
    ax.set_xticks([])
    ax.set_yticks([])

    ax = axes["3d"]
    ax.axis('off')

    return fig

def plot_wigner_with_marginals(psi, **kwargs):
    
    radius = kwargs.get('radius', 5) 
    resolution = kwargs.get('resolution', 500)
    angles = kwargs.get('angles', np.linspace(0, 2*np.pi, 100))
    dir_path = kwargs.get('dir_path', './output')
    
    xvec_upscaled = np.linspace(-radius*1.5, radius*1.5, int(resolution*1.5))
    yvec_upscaled = np.linspace(-radius*1.5, radius*1.5, int(resolution*1.5))
    xvec = np.linspace(-radius, radius, int(resolution))
    yvec = np.linspace(-radius, radius, int(resolution))

    W_upscaled = wigner(psi, xvec_upscaled, yvec_upscaled)
    marginal_max = max(max(np.sum(W_upscaled, axis=0)), max(np.sum(W_upscaled, axis=1)))
    print(f"outputting to {dir_path}")
    for N, angle in tqdm(enumerate(angles)):
        W = rotate_and_crop(W_upscaled, angle, xvec, yvec)
        fig = plot_wigner_marginals(W, xvec, yvec, marginal_max=marginal_max, resolution=resolution, angle=angle)

        if not os.path.exists(dir_path):
            os.makedirs(dir_path)
        fig.savefig(f"{dir_path}/{N:03d}.png",bbox_inches='tight')
        plt.close(fig)
    
mpl.use('agg')
configs = {
    "N_dim" : 40,
    "radius" : 3.5,
    "resolution" : 500,
    "angles" : [i * 2 for i in range(180)],
    "dir_path" : ""
}

for phase_shift in [0, 30, 60, 90]:
    for displacement in [0, 0.5, 1]:
        psi = displace(configs["N_dim"], displacement) * squeeze(configs["N_dim"], 0.5 * np.exp(1j * (2*phase_shift)/180*np.pi)) * basis(configs["N_dim"], 0)
        configs["dir_path"] = f"./squeezed/squeezed_{displacement:.1f}_{phase_shift:02d}"
        plot_wigner_with_marginals(psi, **configs)

Sh

#!/bin/bash

# First loop to process each directory and create individual webm files
for dir in ./*/; do
    folder_name=$(basename "$dir")
    output_path="./${folder_name}.webm"
    echo "Processing $folder_name into $output_path"
    ffmpeg -y -framerate 24 -i "$dir"%03d.png -c:v libvpx-vp9 -b:v 0 -crf 30 -pix_fmt yuva420p "$output_path"
done

# Create an array with the desired input file order
input_files=(
  "squeezed_0.0_00.webm"
  "squeezed_0.0_30.webm"
  "squeezed_0.0_60.webm"
  "squeezed_0.0_90.webm"
  "squeezed_0.5_00.webm"
  "squeezed_0.5_30.webm"
  "squeezed_0.5_60.webm"
  "squeezed_0.5_90.webm"
  "squeezed_1.0_00.webm"
  "squeezed_1.0_30.webm"
  "squeezed_1.0_60.webm"
  "squeezed_1.0_90.webm"
)

# Construct the filter complex dynamically
filter_complex=""
for i in $(seq 0 11); do
  filter_complex+="[${i}:v]scale=800:800[v${i}];"
done

filter_complex+="[v0][v1][v2][v3]hstack=inputs=4[row0];"
filter_complex+="[v4][v5][v6][v7]hstack=inputs=4[row1];"
filter_complex+="[v8][v9][v10][v11]hstack=inputs=4[row2];"
filter_complex+="[row0][row1][row2]vstack=inputs=3[out]"

# Build the ffmpeg command
ffmpeg_cmd="ffmpeg -y "

# Add input files to the command
for file in "${input_files[@]}"; do
  ffmpeg_cmd+="-i ./${file} "
done

# Add the filter complex and output settings
ffmpeg_cmd+="-filter_complex \"${filter_complex}\" -map \"[out]\" -c:v libvpx-vp9 -b:v 0 -crf 30 -pix_fmt yuva420p output_grid.webm"

# Execute the command
eval $ffmpeg_cmd

Date
Source Own work
Author Cosmia Nebula

Licensing

I, the copyright holder of this work, hereby publish it under the following license:
w:en:Creative Commons
attribution share alike
This file is licensed under the Creative Commons Attribution-Share Alike 4.0 International license.
You are free:
  • to share – to copy, distribute and transmit the work
  • to remix – to adapt the work
Under the following conditions:
  • attribution – You must give appropriate credit, provide a link to the license, and indicate if changes were made. You may do so in any reasonable manner, but not in any way that suggests the licensor endorses you or your use.
  • share alike – If you remix, transform, or build upon the material, you must distribute your contributions under the same or compatible license as the original.

Captions

Add a one-line explanation of what this file represents

Items portrayed in this file

depicts

inception

30 August 2024

media type

video/webm

File history

Click on a date/time to view the file as it appeared at that time.

Date/TimeDimensionsUserComment
current22:24, 30 August 2024 (1.13 MB)imagescommonswiki>Cosmia NebulaUploaded while editing "Wigner quasiprobability distribution" on en.wikipedia.org

The following file is a duplicate of this file (more details):

The following page uses this file:

Retrieved from "https://handwiki.org/wiki/File:Wigner_quasiprobability_distribution_of_squeezed_states.webm"