pyskyline/demo/demo.py

import matplotlib.pyplot as plt
import numpy as np
import cv2 as cv
import os
import pyskyline

import pyskyline.localization

FILE = 'terrain'
SIZE = 256
X    = SIZE//2
Y    = SIZE//2+80

if __name__ == '__main__':
    if os.path.isfile(f'{FILE}_{SIZE}.npz'):
        print("Save detected, loading ...")
        terrain = pyskyline.Terrain.load(f'{FILE}_{SIZE}')
    else:
        print("No save detected, generating new terrain ...")
        terrain = pyskyline.Terrain.generate(size=SIZE)
        terrain.compute_all_skylines()
        terrain.save(f'{FILE}_{SIZE}')
        print(f"Done, terrain saved as {FILE}_{SIZE}.npz")

    # Output elevation map
    cv.imwrite('elevation_map.jpg', terrain.dem.elevation)

    # Output color map
    cv.imwrite('color_map.jpg', terrain.dem.color)

    # Ouput field of view visualization
    cv.imwrite('fov.jpg', terrain.compute_fov(X, Y))

    # Ouput skyline
    skyline = terrain.compute_skyline(X, Y)
    plt.figure()
    plt.grid(False)
    plt.plot(np.arange(-180,180,360/256),skyline)
    plt.title('Skyline')
    plt.savefig('skyline.svg')

    # Generate heatmap
    skyline  = np.roll(skyline, 8)           # Add heading error
    skyline += np.random.normal(0,0.5, 256)  # Add random noise
    mosse_correlation = pyskyline.MosseCorrelation(terrain, skyline)
    scoremap = mosse_correlation.generate_scoremap()

    plt.figure()
    plt.grid(False)
    fig = plt.imshow(scoremap)
    plt.title('Score map')
    plt.colorbar(fig)
    plt.savefig('scoremap.svg')
mosse correlation 2024-07-22 16:04:55 +02:00			`import matplotlib.pyplot as plt`
			`import numpy as np`
			`import cv2 as cv`
			`import os`
			`import pyskyline`

			`import pyskyline.localization`

			`FILE = 'terrain'`
			`SIZE = 256`
			`X = SIZE//2`
readme.md 2024-08-19 15:13:14 +02:00			`Y = SIZE//2+80`
mosse correlation 2024-07-22 16:04:55 +02:00
			`if __name__ == '__main__':`
			`if os.path.isfile(f'{FILE}_{SIZE}.npz'):`
			`print("Save detected, loading ...")`
			`terrain = pyskyline.Terrain.load(f'{FILE}_{SIZE}')`
			`else:`
			`print("No save detected, generating new terrain ...")`
			`terrain = pyskyline.Terrain.generate(size=SIZE)`
			`terrain.compute_all_skylines()`
			`terrain.save(f'{FILE}_{SIZE}')`
			`print(f"Done, terrain saved as {FILE}_{SIZE}.npz")`

			`# Output elevation map`
			`cv.imwrite('elevation_map.jpg', terrain.dem.elevation)`

			`# Output color map`
			`cv.imwrite('color_map.jpg', terrain.dem.color)`

			`# Ouput field of view visualization`
			`cv.imwrite('fov.jpg', terrain.compute_fov(X, Y))`

			`# Ouput skyline`
			`skyline = terrain.compute_skyline(X, Y)`
			`plt.figure()`
			`plt.grid(False)`
			`plt.plot(np.arange(-180,180,360/256),skyline)`
			`plt.title('Skyline')`
			`plt.savefig('skyline.svg')`

			`# Generate heatmap`
			`skyline = np.roll(skyline, 8) # Add heading error`
			`skyline += np.random.normal(0,0.5, 256) # Add random noise`
			`mosse_correlation = pyskyline.MosseCorrelation(terrain, skyline)`
			`scoremap = mosse_correlation.generate_scoremap()`

			`plt.figure()`
			`plt.grid(False)`
			`fig = plt.imshow(scoremap)`
			`plt.title('Score map')`
			`plt.colorbar(fig)`
			`plt.savefig('scoremap.svg')`